JP2021037357A - Game machine - Google Patents

Abstract

To provide a game machine capable of reducing product cost.SOLUTION: A displacement unit 395 is attached to a base member 392 by elastic deformation of a regulation piece 392f, and, after attachment, displacement of the displacement unit 395 is regulated by the elastically recovered regulation piece 392f. Namely, the displacement unit 395 is held by the base member 392. Consequently, not only a different component such as a collar or a lid member for preventing falling of the displacement unit 395 from the base member 392 becomes unnecessary but also a fitting step (coupling and fixing step by a screw) of such a different component also becomes unnecessary, to thereby reduce product cost by that amount.SELECTED DRAWING: Figure 32

Description

The present invention relates to a gaming machine such as a pachinko machine.

There is known a gaming machine in which a displacement member is slidably displaced on a base member (Patent Document 1).

Japanese Unexamined Patent Publication No. 2012-130539

However, the above-exemplified gaming machine has a problem that the product cost increases.

The present invention has been made to solve the above-exemplified problems, and an object of the present invention is to provide a gaming machine capable of reducing product costs.

In order to achieve this object, the gaming machine according to claim 1 has a base member, a displacement member displaceable on the base member, and a holding means for holding the displacement member on the base member. The holding means is provided with an elastic portion formed so as to be elastically deformable, and when the displacement member is attached to the base member, the elastic portion in contact with the displacement member is elastically deformed. Then, when the displacement member is allowed to be mounted on the base member and the displacement member mounted on the base member is brought into contact with the elastic portion, the displacement of the displacement member in the abutting direction is caused. It is regulated by the elastic part.

The gaming machine according to claim 2 is the gaming machine according to claim 1, wherein the displacement member is displaced between the first position and the second position, and the displacement member is the first position and the second position. It is mounted on the base member by being displaced in a direction orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus when being displaced with and then displaced in accordance with the displacement regulation. Displacement.

The gaming machine according to claim 3 is the gaming machine according to claim 2, wherein a protrusion projecting from one of the base member or the displacement member and the protrusion are formed so as to pass through the base member or the displacement member. A recessed portion is provided on the other side of the displacement member, and the protrusion is passed through the recess so that the displacement member is orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus. Is displaced to.

According to the gaming machine according to claim 1, the product cost can be reduced.

According to the gaming machine according to the second aspect, in addition to the effect of the gaming machine according to the first aspect, the space on the base member required for mounting the displacement member can be reduced.

According to the gaming machine according to claim 3, in addition to the effect of the gaming machine according to claim 2, the space on the base member required for mounting the displacement member can be made smaller.

It is a front view of the slot machine in 1st Embodiment. It is a perspective front view of the slot machine with the front door closed. It is a perspective front view of the slot machine with the front door open. It is a perspective rear view of the front door in a state where the reel unit is opened from the front door to the rear side. It is a rear view of the front door. It is a front view of a housing. It is an exploded perspective view of a frame unit. It is a schematic diagram which shows the symbol arrangement. It is a figure which shows the internal structure of a selector. It is a block diagram which shows the electrical structure of a slot machine. It is an exploded perspective front view of a front door. It is an exploded perspective rear view of the front door. (A) is a front view of the displacement unit, (b) is a side view of the displacement unit in the XIIIb direction of FIG. 13 (a), and (c) is a line XIIIc-XIIIc of FIG. 13 (a). It is a cross-sectional model diagram of the displacement unit in. It is an exploded perspective front view of a displacement unit. It is an exploded perspective rear view of the displacement unit. (A) is a front view of the operation unit, (b) is a side view of the operation unit in the XVIb direction view of FIG. 16 (a), and (c) is a rear view of the operation unit. (A) is a perspective front view of the operation unit, and (b) is a perspective rear view of the operation unit. It is an exploded perspective front view of an operation unit. It is an exploded perspective view of the gripping unit. (A) is a front view of the guide unit, (b) is a perspective front view of the guide unit, (c) is a perspective rear view of the guide unit, and (d) is FIG. 20 (a). It is sectional drawing of the guide unit in line XXd-XXd of). (A) is an exploded perspective front view of the guide unit, and (b) is an exploded sectional view of the guide unit. (A) is a perspective front view of the operation unit and the guide unit, (b) is a front view of the operation unit and the guide unit, and (c) is the XXIIc- of FIG. 22 (b). It is sectional drawing of the operation unit and the guide unit in line XXIIc, and (d) is the sectional view of the operation unit and guide unit in line XXIId-XXIId of FIG. 22 (a). (A) is a perspective front view of the operation unit and the guide unit, (b) is a front view of the operation unit and the guide unit, and (c) is the XXIIIc- of FIG. 23 (b). It is sectional drawing of the operation unit and the guide unit in line XXIIIc, and (d) is the sectional view of the operation unit and guide unit in line XXIIId-XXIIId of FIG. 23A. (A) is a perspective front view of the operation unit and the guide unit, (b) is a front view of the operation unit and the guide unit, and (c) is the XXIVc- of FIG. 24 (b). It is sectional drawing of the operation unit and the guide unit in line XXIVc, and (d) is the sectional view of the operation unit and guide unit in line XXIVd-XXIVd of FIG. 24 (a). It is sectional drawing of the operation unit and the guide unit. It is sectional drawing of the operation unit and the guide unit. (A) is a front view of the base unit, (b) is a perspective front view of the base unit, and (c) is a cross-sectional view of the base unit in the XXVIIc-XXVIIc line of FIG. 27 (a). .. It is an exploded perspective front view of a base unit. (A) is a front view of the base unit, and (b) is a cross-sectional view of the base unit in the line XXIXb-XXIXb of FIG. 29 (a). (A) is a front view of the displacement unit, (b) is a rear view of the displacement unit, and (c) is a cross-sectional view of the displacement unit on the XXXc-XXXc line of FIG. 30 (a). It is a front view of a base unit. (A) is a partial cross-sectional schematic diagram of the base unit in the line XXXIIa-XXXIIa of FIG. 31, and (b) is a partial cross-sectional schematic diagram of the base unit in the line XXXIIb-XXXIIb of FIG. 31. (A) is a partial cross-sectional drawing of the base unit in the line XXXIIIa-XXXIIIa of FIG. 27 (a), and (b) is a partial cross-sectional drawing of the base unit in the line XXXIIIb-XXXIIIb of FIG. 27 (a). It is a figure. It is a perspective exploded view of a displacement unit. (A) to (c) are front views of the base unit. It is a front view of a base unit. It is a partially enlarged front view of a base unit. It is a partially enlarged front view of a base unit. (A) to (c) are front views of the base unit in the second embodiment. (A) to (c) are cross-sectional schematic views of the base unit in the XLa-XLa line of FIG. 39 (a). (A) is a front view of the base unit in the third embodiment, (b) is a schematic cross-sectional view of the base unit in the XLIb-XLIb line of FIG. 41 (a), and FIG. 41 (c) is a sectional view of the base unit. It is sectional drawing of the base unit in the XLIc-XLIc line of (a). (A) is a front view of the base unit in the fourth embodiment, and (b) is a schematic cross-sectional view of the base unit in line XLIIb-XLIIb of FIG. 42 (a). (A) is a front view of the base unit in the fifth embodiment, and (b) is a cross-sectional schematic view of the base unit in line XLIIIb-XLIIIb of FIG. 43 (a). (A) is a front view of the displacement unit, (b) is a rear view of the displacement unit, and (c) is a cross-sectional view of the displacement unit of XLIVc-XLIVc of FIG. 44 (a). (A) to (c) are front views of the base unit. (A) to (c) are cross-sectional views of the base unit in the XLVIa-XLVIa line of FIG. 45 (a), and (d) is a cross-sectional view of the base unit in the XLVId-XLVId line of FIG. 46 (a). is there. (E) is a cross-sectional view of the base unit in the XLVIe-XLVIe line of FIG. 46 (a). (A) is a front view of the base unit in the sixth embodiment, (b) is a front view of the base unit, and (c) is a front view of the base unit in the XLVIIc-XLVIIc line of FIG. 47 (b). It is a cross-sectional model diagram. It is sectional drawing of the base unit in 7th Embodiment. (A) is an exploded perspective front view of the operation unit according to the eighth embodiment, and (b) is a cross-sectional view of the operation unit and the guide unit. (A) is a front view of the operation unit and the guide unit, (b) is a side view of the operation unit and the guide unit, and (c) is a cross section of the operation unit and the guide unit. It is a schematic diagram. (A) is a front view of the operation unit and the guide unit, (b) is a side view of the operation unit and the guide unit, and (c) is a cross section of the operation unit and the guide unit. It is a schematic diagram. (A) is a front view of the operation unit and the guide unit, (b) is a side view of the operation unit and the guide unit, and (c) is a cross section of the operation unit and the guide unit. It is a schematic diagram. (A) is a front view of the operation unit and the guide unit, (b) is a side view of the operation unit and the guide unit, and (c) is a cross section of the operation unit and the guide unit. It is a schematic diagram. (A) to (c) are sectional views of the operation unit and the guide unit according to the ninth embodiment. (A) is a side view of the operation unit according to the tenth embodiment, and (b) is a schematic cross-sectional view of the operation unit in the LVb-LVb line of FIG. 55 (a). It is an exploded perspective view of the gripping unit. (A) and (b) are front views of the operation unit and the guide unit, and (c) and (d) are sectional views of the operation unit. (A) and (b) are side views of the operation unit and the guide unit, and (c) and (d) are cross-sectional views of the operation unit. (A) is a front view of the guide unit in the eleventh embodiment, and (b) is a cross-sectional view of the guide unit in the LIXb-LIXb line of FIG. 59 (a). (A) is a cross-sectional view of the guide unit according to the twelfth embodiment, and (b) is an exploded cross-sectional view of the guide unit. (A) is a cross-sectional view of the guide unit according to the thirteenth embodiment, and (b) is an exploded cross-sectional view of the guide unit according to the thirteenth embodiment. (A) is a cross-sectional view of the guide unit according to the 14th embodiment, and (b) is a cross-sectional view of the guide unit according to the 15th embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, with reference to FIGS. 1 to 38, as a first embodiment, an embodiment when the present invention is applied to the slot machine 10 will be described. FIG. 1 is a front view of the slot machine 10 according to the first embodiment. FIG. 2 is a perspective front view of the slot machine 10 with the front door 12 closed, and FIG. 3 is a perspective front view of the slot machine 10 with the front door 12 open. FIG. 4 is a perspective rear view of the front door 12 in a state where the reel unit 41 is opened from the front door 12 to the rear side. FIG. 5 is a rear view of the front door 12, and FIG. 6 is a front view of the housing 11. Note that FIG. 1 shows a state in which the game panel 30 arranged on the front side of the auxiliary display unit 15 is removed. Further, in FIG. 1, each effective line display unit 32, 33, 34 described later is illustrated by a two-dot chain line.

Further, in the following description, with respect to the slot machine 10 in the state shown in FIG. 1, the front side of the paper surface will be referred to as the front (front) side, and the back side of the paper surface will be described as the rear (back) side. Further, with respect to the slot machine 10 in the state shown in FIG. 1, the upper side is the upper (upper) side, the lower side is the lower (lower) side, the right side is the right side (right) side, and the left side is the left side (left). ) Side will be explained respectively. The arrows UD, LR, and FB in the drawing indicate the vertical direction, the horizontal direction, and the front-rear direction of the slot machine 10, respectively.

As shown in FIGS. 1 to 6, the slot machine 10 includes a housing 11 that forms an outer shell thereof. As shown in FIGS. 3 and 6, the housing 11 is composed of a top plate 11a, a bottom plate 11b, a back plate 11c, a left side plate 11d, and a right side plate 11e formed in a wooden plate shape, and each adjacent plate 11a 11e is fixed by a fixing means such as adhesive, so that one surface on the front side (arrow F direction side) is open as a whole to form a box shape. In addition to being made of wooden panels, each of the plates 11a to 11e may be made of a synthetic resin material or a metal material to form an integral box. The housing 11 configured as described above is attached by hitting a nail against the so-called island equipment at the time of installation in the game hall.

Further, on the bottom plate 11b of the housing 11, a metal plate 11b1 made of a plate-like body is arranged on the inner surface of the housing 11 on the open side (arrow F direction side). As a result, when the front door 12, which will be described later, is arranged on the front (open) side of the housing 11, a part of the front door 12 can be mounted on the metal plate 11b1 and arranged at this time. It is possible to prevent the bottom plate 11b of the door from rubbing and becoming brittle. Further, by disposing a part of the front door 12 on the front side of the metal plate 11b1, the front door 12 can be supported by the bottom surface 11b of the housing 11 (that is, the metal plate 11b1 can be used as reinforcement). ). As a result, it is possible to prevent the support shafts 25a and 25b of the housing 11 and the support metal fittings 26a and 26b of the front door 12 from being damaged, which will be described later.

A front door 12 as a front opening / closing door is attached to the front side (arrow F direction side) of the housing 11 so as to be openable / closable. That is, as shown in FIG. 6, the left side plate 11d of the housing 11 is provided with a pair of upper and lower support shafts 25a and 25b. The support shafts 25a and 25b are provided with a tapered shaft portion that protrudes upward. On the other hand, as shown in FIG. 5, the front door 12 is provided with support metal fittings 26a and 26b having shaft support holes into which the shaft portions of the support shafts 25a and 25b are inserted corresponding to the shafts 25a and 25b. Has been done. Then, by arranging the support metal fittings 26a and 26b above the support metal fittings 25a and 25b and lowering the front door 12, the shaft portions of the support metal fittings 25a and 25b are inserted into the insertion holes of the support metal fittings 26a and 26b. It is said that it has been done. As a result, the front door 12 is rotatably supported about the opening / closing axis extending in the vertical direction (arrow UD direction) connecting the support shafts 25a and 25b with respect to the housing 11, and the housing is rotated by the rotation. It is configured so that the front open side of 11 can be opened or closed.

In the following description, as shown in FIG. 2, a state in which the front door 12 is closed with respect to the housing 11 (a state in which the front door 12 is arranged on the open surface of the housing 11) is defined as a closed state. As shown in FIG. 3, a state in which the front door 12 is open to the housing 11 (a state in which the open surface of the housing 11 is open) will be described as an open state. Further, in the following description, unless otherwise specified, the description will be made in a closed state in which the front door 12 is closed with respect to the housing 11.

The front door 12 is locked so that it cannot be opened by the locking device provided on the back surface thereof. Further, as shown in FIG. 1, a key cylinder 20 of an unlocking operation unit is provided at a lower portion (a portion in the arrow D direction) of the front door 12 on the right end side (arrow R direction side). The key cylinder 20 is integrated with the locking device, and is configured so that the locked state is unlocked by a predetermined key operation on the key cylinder 20. Therefore, the lock mechanism including the locking device will be outlined.

A locking device is provided on the right end side of the front door 12, that is, on the opposite side (arrow R direction side) of the opening / closing shaft of the front door 12 on the back surface thereof. As shown in FIGS. 3 and 5, the locking device includes a base frame extending in the vertical direction and fixed to the front door 12, and a key cylinder 20 provided so as to extend from the upper part of the base frame to the front of the front door 12. It is provided with a long interlocking rod 21 that is assembled so as to be movable in the vertical direction with respect to the base frame. Of the locking devices, only the key cylinder 20 is provided so as to project forward of the front door 12. In the present embodiment, the key cylinder 20 is an omlock (trade name) having a high function of preventing unauthorized unlocking.

The interlocking rod 21 is moved downward by operating the key inserted in the key cylinder 20 clockwise. The interlocking rod 21 is provided with a pair of upper and lower hook metal fittings 22 having a hook shape, and when the front door 12 is closed with respect to the housing 11 (closed state), the hook metal fittings 22 are on the housing 11 side. It is locked to the support metal fitting 23 (see FIG. 6) and locked. The hook metal fitting 22 is provided with an urging member such as a coil spring that urges the side that maintains the locked state. When the key is operated clockwise with respect to the key cylinder 20, the interlocking rod 21 moves downward, and the hook fitting 22 is moved against the urging force of the urging member, so that the hook fitting 22 and the hook fitting 22 are moved. The locked state with the support metal fitting 23 is released, and the locked state of the front door 12 with respect to the housing 11 is released.

An auxiliary display unit 15 and a reel unit 41 below the auxiliary display unit 15 are arranged via the game panel 30 on the upper side of the central portion of the front door 12 (closer to the arrow U direction) (see FIG. 1). .. In the following description, the area where the reel unit 41 can be visually recognized from the lower side of the liquid crystal frame member 600 (see FIG. 12) on which the auxiliary display unit 15 is arranged via the game panel 30 is referred to as a “visible area”. Called.

As shown in FIG. 4, the reel unit 41 is attached to the inside of the frame unit 45 formed by combining a plurality of plate members in a frame shape. A speaker 46 that outputs sound is arranged above the frame unit 45. Further, the speaker 46 is arranged so that the sound output surface faces the back side, and the sound output from the speaker 46 is echoed inside the housing 11. As a result, the sound can be transmitted from the entire slot machine 10 to the player, and it is possible to easily give the player a hobby by the sound.

A pair of upper and lower second support shafts 45a and 45b are provided on the left side of the frame unit 45 (on the side in the direction of arrow L) (see FIG. 7). The second support shafts 45a and 45b include a tapered shaft portion that protrudes downward. On the other hand, as shown in FIG. 5, the front door 12 is provided with support metal fittings 26c and 26d having shaft support holes for inserting the shaft portions of the support shafts 45a and 45b corresponding to the shafts 45a and 45b. Has been done. Then, by arranging the support shafts 45a and 45b above the support metal fittings 26c and 26d and lowering the frame unit 45, the shaft portions of the support shafts 45a and 45b are inserted into the insertion holes of the support metal fittings 26c and 26d. It is said that it has been done. As a result, the frame unit 45 is rotatably supported about the (parallel) opening / closing axis along the vertical direction (arrow UD direction) connecting the support shafts 45a and 45b to the front door 12. Therefore, as shown in FIG. 4, the front door 12 is rotated to the front side (arrow F direction side) with respect to the housing 11, and then the frame unit 45 is rotated to the back side (arrow B direction side). The front side of the frame unit 45 (reel unit 41) can be opened.

The reel unit 41 includes a left reel 42L, a middle reel 42M, and a right reel 42R, which are formed in a cylindrical shape (annular shape), respectively. It should be noted that each reel 42L, 42M, 42R may be configured as at least an endless belt, and is not limited to a cylindrical shape (annular ring). Each reel 42L, 42M, 42R is rotatably supported so that its central axis is the rotation axis of the reel. The rotation axes of the reels 42L, 42M, and 42R are arranged on the same axis extending in the substantially horizontal direction. Further, when the reels 42L, 42M, 42R rotate in the forward direction, the surfaces of the reels 42L, 42M, 42R are visually recognized by the player through the game panel 30 as if they are moving from top to bottom.

Each of these reels 42L, 42M, 42R is connected to stepping motors 61L, 61M, 61R, and each reel 42L, 42M, 42R is individually driven by the stepping motors 61L, 61M, 61R, that is, independently of each other. It is configured so that it can be driven to rotate. Since each of these reels 42L, 42M, and 42R has the same configuration, the right reel 42R will be described here with reference to FIG. 7 as an example. FIG. 7 is an exploded perspective view of the frame unit 45.

The right reel 42R includes a cylindrical skeleton member 50 that forms a cage on a cylinder, and a strip-shaped belt that is wound endlessly on the outer peripheral surface thereof. Then, it is attached to the cylindrical skeleton member 50 via a pair of sealing portions formed along both sides of the long side of the belt so as to maintain the wound state. A large number of symbols as identification information are printed on the outer peripheral surface of the belt at equal intervals. A boss portion 51 is formed in the central portion of the cylindrical skeleton member 50, and is attached to the drive shaft of the right reel stepping motor 61R via a disc-shaped boss reinforcing plate 52. Therefore, when the drive shaft of the right reel stepping motor 61R rotates, the cylindrical skeleton member 50 rotates about the drive shaft so that the right reel 42R orbits along the reel surface on the annulus. It has become.

The right reel stepping motor 61R is fixed to the side surface of the motor plate 53 arranged in an upright state in the reel unit 41 (FIG. 4) with screws 54. The motor plate 53 is provided with a reel index sensor (rotational position detection sensor) 55 in which the light emitting element 55a and the light receiving element 55b are held at predetermined intervals. On the other hand, the base end portion 56b of the sensor cut van 56 extending in the radial direction is fixed to the boss reinforcing plate 52 integrated with the right reel 42R with a screw 57. The tip portion 56a of the sensor cut van 56 is bent at a substantially right angle and is aligned so that it can pass between both elements 55a and 55b of the reel index sensor 55. Then, each time the left reel 42R makes one rotation, the reel index sensor 55 detects the passage of the tip portion 56a of the sensor cut van 56, and each time the detection is performed, a detection signal is output to the main control device 131 described later. Therefore, the main control device 131 can confirm and correct the angular position of the left reel 42L for each rotation based on this detection signal.

The stepping motor 61R is set to rotate once by giving, for example, a drive signal of 504 pulses (also referred to as an excitation signal or an excitation pulse; the same applies hereinafter), and the rotation position of the stepping motor 61R, that is, the left side by this excitation pulse. The rotation position of the reel 42L is controlled.

On each belt of each reel 42L, 42M, 42R, a plurality of symbols, specifically 21 symbols, are drawn in the long side direction (circumferential direction) thereof. Therefore, it takes 24 pulses (= 504 pulses ÷ 21 symbols) to switch from one symbol to the next at a predetermined position. Then, based on the number of pulses from the time when the detection signal of the reel index sensor 55 is output, it is possible to recognize which symbol is visible from the visible region, or to make any symbol visible from the visible region. It is possible to perform control such as recognizing whether or not it is, and making an arbitrary symbol visible from a visible region.

Among the symbols attached to the reels 42L, 42M, 42R, the number of symbols that can be visually recognized as a whole from below the liquid crystal frame member 600, which will be described later, via the game panel 30, mainly depends on the length of the visible region in the vertical direction. Limited to a predetermined number to be determined. In this embodiment, there are three reels each. Therefore, when all the reels 42L, 42M, and 42R are stopped, 3 × 3 = 9 symbols are visible to the player.

Here, the symbols attached to the reels 42L, 42M, and 42R will be described. FIG. 8 shows a pattern arrangement drawn on a belt wound around each of the left reel 42L, the middle reel 42M, and the right reel 42R. As shown in the figure, each reel 42L, 42M, 42R is provided with 21 symbols in a row. Numbers 1 to 21 are assigned to each reel 42L, 42M, 42R, but this is for convenience of explanation and is not actually attached to the reels 42L, 42M, 42R. .. However, in the following description, the number will be used for explanation.

As the symbols, there are a "7" symbol (for example, the 20th left belt) and a "youth" symbol (for example, the 19th left belt) as the first special symbol for shifting to the big bonus game. In addition, there is a "BAR" symbol (for example, the 14th left belt) as a second special symbol for shifting to the regular bonus game. In addition, there is a "replay" symbol (for example, the eleventh left belt) as a third special symbol for shifting to a replay game in which the next game can be executed without inserting medals. In addition, the "watermelon" symbol (for example, the 9th left belt), the "bell" symbol (for example, the 8th left belt), and the "cherry" symbol (for example, the left) as the small winning combination symbols for which the small winning combination is paid out. There is a fourth belt). As shown in FIG. 7, the number and arrangement order of various symbols are completely different in the belts wound around the reels 42L, 42M, and 42R.

The reels 42L, 42M, and 42R of the reel unit 41 are examples of display devices that display identification information in a variable manner, and the display devices may have other configurations. For example, it may be another mechanical reel configuration such as a type in which the belt rotates instead of rotating, and instead of or in addition to the mechanical reel configuration, a liquid crystal display, a dot matrix display, etc. It is possible to provide a variable display of the identification information by an electric display such as, and in this case, it is possible to have abundant variations in the display form.

The game panel 30 is connected to the symbols of the reels 42L, 42M, and 42R that are visible from the visible region, and is a combination line of three reels in parallel in the horizontal direction and two in the diagonal direction, for a total of five. Is attached. Of course, the maximum number of combination lines may be 6 or more, less than 5, and the maximum number of combination lines may be changed according to a predetermined condition. Each effective line display unit 32, 33, 34 is provided corresponding to each of these combination lines. The first effective line display unit 32 is notified by lighting or the like when the central horizontal line (center line) of the combination lines is activated. The second effective line display unit 33 is notified by lighting or the like when the upper and lower horizontal lines (upper line and lower line) of the combination lines are activated. The third effective line display unit 34 is notified by lighting or the like when a pair of diagonal lines (a downward-sloping line and an upward-sloping line) of the combination lines are enabled. Then, when the symbols stop at the activated combination line, that is, the valid line in a predetermined combination, a prize is won, and a predetermined medal payout process, a transfer process to a specific game, and the like are executed.

In this embodiment, when each effective line display unit 32, 33, 34 is activated, each effective line is supported by an issuing device such as an LED arranged on the motor plate 53 of the reel unit 41. The part to be light is emitted.

Here, the number of payouts for each symbol in the case of winning a prize will be described. Regarding small role symbols, if the "watermelon" symbol is aligned with the left, middle, and right on the effective line, 15 medals will be paid out, and if the "bell" symbol is aligned with the left, middle, and right on the effective line, Eight medals are paid out, and two medals are paid out when the "cherry" symbol on the left reel 42L stops on the effective line. That is, the "cherry" symbols on the middle reel 42M and the right reel 42R are irrelevant to medal payout. In addition, as far as the "cherry" symbol is concerned, medals are paid out regardless of the combination with other symbols, so that the "cherry" symbol is placed at the position where the plurality of effective lines of the left reel 42L overlap (specifically, the upper or lower row). When the "cherry" symbol is stopped, medals are paid out by multiplying the number of overlapping effective lines, and as a result, four medals are paid out in the present embodiment.

Regarding other symbols, if the "7" symbol or the "youth" symbol, which is a combination of the first special symbol (big bonus symbol), is aligned with the left, middle, and right on the effective line with the same symbol, 15 medals are paid out, and 15 medals are also paid out when the "BAR" symbol, which is a combination of the second special symbol (regular bonus symbol), is aligned with the left, middle, and right on the effective line. In the present embodiment, for example, the "7" symbol and the "cherry" symbol may be established at the same time, and in such a case, 15 medals are paid out. This is because the maximum number of medals to be paid out at one time is set to 15.

Furthermore, if the "replay" symbol, which is a combination of the third special symbols, is aligned with the left, middle, and right on the effective line, the medal will not be paid out. In other cases, that is, when the "cherry" symbol on the left reel 42L does not stop on the effective line and the same symbols as left, middle, and right are not aligned on the effective line, it is out of the question. Is not done.

As shown in FIG. 1, a start lever 71 operated to start rotation of the reels 42L, 42M, and 42R all at once (not necessarily at the same time) is provided on the lower left side of the game panel 30. .. The start lever 71 constitutes a starting operation means in which a starting operation is performed so as to start rotating the reels 42L, 42M, 42R, that is, to start the variable display of the symbol. The start lever 71 is a lever that is pushed and operated by the player when the player starts the game, and is automatically returned to the original position after the hand is released by the built-in spring. If the start lever 71 is operated while the medal is being inserted, the reels 42L, 42M, and 42R start rotating all at once.

As shown in FIG. 1, button-shaped stop switches 72, 73, 74 operated to individually stop the rotating reels 42L, 42M, 42R are provided on the right side of the start lever 71. There is. The stop switches 72, 73, and 74 are arranged directly below the reels 42L, 42M, and 42R to be stopped, respectively. The stop switches 72, 73, 74 constitute a stop operation means operated to stop the variation display based on the rotation of the reels 42L, 42M, 42R. Each of the stop switches 72, 73, 74 is in a state where it can be stopped after a predetermined time has elapsed from the start of rotation of the left reel 42L, and during such a state, a lamp (not shown) is lit and displayed to stop. It is notified that the operation is possible, and it is turned off when the rotation stops.

As shown in FIG. 1, a medal insertion slot 75 for inserting a medal as a game medium for playing a game is provided on the lower right side of the visible region. The medal slot 75 constitutes an entrance that can accept game media. Further, paying attention to the fact that the medal insertion slot 75 is accompanied by an operation of directly inserting medals by the player, it can be said that it constitutes a direct input means for directly inputting the game medium.

As shown in FIG. 4, the medals inserted from the medal insertion slot 75 are guided to either the storage passage 81 or the discharge passage 82 by the selector 83 provided on the back surface of the front door 12. The selector 83 is provided with a medal passage switching member 84, which will be described later, so that the passing direction of the medal can be switched between the discharge passage 82 side and the storage passage 81 side according to the state of the medal passage switching member 84. It has become. The medal guided to the storage passage 81 is guided to the hopper device 91 housed inside the housing 11. On the other hand, the medals guided to the discharge passage 82 are guided to the medal tray 18 from the medal discharge port 17 provided in the lower front portion of the front door 12, and are returned to the player.

As shown in FIG. 6, the hopper device 91 as a payout means for awarding medals to the player is arranged below the reel unit 41. Further, as shown in FIG. 3, the hopper device 91 includes a storage tank 92 for storing medals and a payout device 93 for paying out medals to the player. The payout device 93 discharges the medal to the opening 94 provided in the center right portion of the discharge passage 82, and pays out the medal to the medal tray 18 through the discharge passage 82.

As shown in FIG. 6, a spare tank 95 is provided on the right side of the hopper device 91 to prevent medals from being stored in the storage tank 92 from being stored in a predetermined amount or more. Inside the storage tank 92 of the hopper device 91, a guide plate 96 for discharging medals from the storage tank 92 to the spare tank 95 is provided. Therefore, when medals are stored above the height at which the guide plate 96 is provided, the medals are stored in the spare tank 95.

As shown in FIG. 2, a button-shaped return switch 76 is provided below the medal insertion slot 75. The return switch 76 is a switch that is pressed when a medal inserted into the medal insertion slot 75 is jammed in the selector 83, and when the return switch 76 is pressed, the selector 83 is mechanically interlocked and operated. The medals packed in the selector 83 are returned from the medal ejection port 17.

As shown in FIG. 2, a button-shaped first credit insertion switch 77 for inserting three virtual medals credited as a game medium at a time is provided on the lower left side of the display windows 31L, 31M, 31R. There is. Further, on the left side of the first credit insertion switch 77, a second credit insertion switch 78 formed in a button shape smaller than the switch 77 and a third credit insertion switch 79 are provided. The second credit insertion switch 78 is for inserting two credited virtual medals at a time, and the third credit insertion switch 79 is for inserting one virtual medal.

Each of the credit insertion switches 77 to 79 constitutes an input means for inputting a game medium together with the medal insertion slot 75. Further, it should be noted that while the medal insertion slot 75 involves an operation of directly inserting medals by the player, each credit insertion switch 77 to 79 only involves an operation of inserting a virtual medal based on the stored memory. , It can be said that it constitutes an indirect input means for indirectly inputting the investment value.

The first credit insertion switch 77 has a built-in lamp as a light emitting member (not shown) in order to encourage that the maximum number of medals (3 medals) that can be inserted per game has not been reached. The lamp is lit when the switch operation of the first credit insertion switch 77 is valid to prompt the operation of the switch 77, but when there is no credited virtual medal or three medals have already been inserted. It is turned off under the condition that it is. Here, instead of the above lighting, it may be blinked to make it easier for the player to understand the prompt for inserting the medal.

As shown in FIG. 2, a button-shaped changeover switch 80 is provided on the left side of the start lever 71. The changeover switch 80 is configured as a toggle type that turns on when pressed once, turns off when pressed again, and switches on and off each time a subsequent pressing operation is performed. The changeover switch 80 is operated to change the handling format of the inserted medals inserted into the medal insertion slot 75 in excess of the required amount and the acquired medals returned to the player as a result of the predetermined game.

When the changeover switch 80 is on, the "credit mode" is set so that the surplus inserted medals and the medals won at the time of winning are stored and stored as credit medals until the predetermined maximum value (for example, 50 medals) is reached. ". When the changeover switch 80 is in the off state, the "direct mode" is set so that the surplus inserted medals and the winning medals at the time of winning are paid out as actual medals. If there is a credit medal when the mode is switched from the credit mode to the direct mode, the credit medal for that amount is paid out as an actual medal. In this way, the player can execute the game in a format according to his / her preference by switching between the credit mode and the direct mode. The changeover switch 80 constitutes a changeover operation means for switching between the input value and the handling type of the game value. Further, paying attention to the function of paying out the credited virtual medal as an actual medal, it can be said that the changeover switch 80 constitutes a settlement operation means for actually paying out the stored and stored game value. In addition to being configured to switch between "credit mode" and "direct mode" by operating the changeover switch 80, the virtual medal stored and stored is paid out when the changeover switch 80 is operated by always setting the "credit mode". It may function as a payment switch only.

Below the game panel 30, there is a remaining number display unit 35 that displays the number of medals that are activated and stored in the credit mode, and for example, the number of remaining games in a special game state such as a big bonus or a regular bonus. The number of games display unit 36 for displaying the above and the number of acquired medals display unit 37 for displaying the number of acquired medals are provided. These display units 35 to 37 are composed of a 7-segment display, but it is naturally possible to replace them with a liquid crystal display or the like.

Here, the procedure for betting medals will be described. In both the direct mode and the credit mode, when a medal is inserted from the medal insertion slot 75 at the start of the game, a bet is placed.

That is, when the first medal is inserted into the medal insertion slot 75, the first effective line display unit 32 lights up, and the corresponding central line becomes the effective line, and the second medal is the medal insertion slot. When it is inserted into 75, the second effective line display unit 33 lights up, and the corresponding upper line and the lower line, including the lower line, become effective lines, respectively, and the third medal. Is inserted into the medal insertion slot 75, the third effective line display unit 34 is further lit, and all five combination lines including the corresponding pair of diagonal lines become effective lines.

When four or more medals are inserted into the medal slot 75, the surplus medals exceeding three are switched to the discharge passage 82 by the selector 83 if the mode at that time is the direct mode. It is returned from the discharge port 17 to the medal tray 18. On the other hand, in the credit mode, the number of saved cards is displayed inside the slot machine and the remaining number display unit 35 displays the number of saved cards. An upper limit is set for the number of stored medals (for example, 50), and when more medals are inserted, the medals are returned from the medal ejection port 17 to the medal tray 18.

Further, when the game is played in the credit mode and the number of stored sheets is displayed on the remaining number display unit 35, it is virtual even when any of the first to third credit insertion switches 77 to 79 is pressed. It is a bet because the medal has been inserted.

When the third credit insertion switch 79 is pressed, one numerical value displayed on the remaining number display unit 35 is decremented as if one virtual medal has been inserted, and the first effective line display unit 32 displays. It lights up and the center line becomes the effective line. When the second credit insertion switch 78 is pressed, two numerical values displayed on the remaining number display unit 35 are decremented as if two virtual medals have been inserted, and the first effective line display unit 32, Then, the second effective line display unit 33 lights up, and a total of three combination lines become effective lines. When the first credit insertion switch 77 is pressed, three numerical values displayed on the remaining number display unit 35 are decremented as if three virtual medals have been inserted, and all the effective line display units 32 to 34 lights up and a total of 5 combination lines become effective lines.

When any of the first to third credit insertion switches 77 to 79 is pressed and the virtual medals to be inserted are not stored, for example, when the display of the remaining number display unit 35 is 2, the first When the credit insertion switch 77 is pressed, all the numerical values of the remaining number display unit 35 are decremented to 0, and only the virtual medals that can be inserted are bet.

An upper lamp unit 13 is arranged above the front door 12. The upper lamp unit 13 includes an upper lamp 13a formed in a horizontally long shape along the upper side (upper base member 27) of the slot machine 10 inside the upper lamp unit 13. The upper lamp 13a includes a plurality of LEDs (light emitting devices) capable of emitting light, and the LEDs can be turned on or blinked as the game progresses.

In the present embodiment, the auxiliary display unit 15 is composed of a liquid crystal display for the purpose of diversifying the display contents and increasing the weight of the display effect, but another display such as a dot matrix display is used. You may. The auxiliary display unit 15 is for executing various display effects as the game progresses, and the game by each reel 42L, 42M, 42R can be considered to be due to the main display unit. Therefore, in the present embodiment, the auxiliary display unit 15 is used. It is called an auxiliary display unit 15. On the back surface of the auxiliary display unit 15, an upper lamp 13a, a speaker 14, and a display control device 111 for driving the auxiliary display unit 15 are provided. The shapes, positions, numbers, and the like of the lamp 13 and the speaker 14 are not particularly limited to those described above.

As shown in FIG. 2, a lower plate 16 on which a model name, characters related to the game, and the like are displayed is mounted above the medal tray 18.

As shown in FIG. 6, a power supply box 121 is provided on the back side (arrow B direction side) of the hopper device 91 inside the housing 11. The power supply box 121 includes a power supply switch 122, a reset switch 123, a setting key insertion hole 124, and the like. The power switch 122 is a start switch for supplying power to each unit including the main control device 131.

The reset switch 123 is a switch for resetting various states of the slot machine 10. This slot machine 10 has a backup function for various data, maintains the state at the time of power failure even in the unlikely event of a power failure, and returns to the state at the time of power failure when recovering from the power failure (recovery of power). You can do it. Therefore, if the power is shut off in the normal procedure, for example, when the game hall is closed, the state before the shutoff is stored in memory, but if the power switch 122 is turned on while pressing the reset switch 123, the backup data is reset. It has become so. If the reset switch 123 is pressed while the power switch 122 is on, the error state is reset.

The setting key insertion hole 124 is for a hole manager or the like to adjust the output of medals. That is, the hall manager or the like can change the setting state (winning probability setting process) of the slot machine 10 from "setting 1" to "setting 6" by inserting the setting key into the setting key insertion hole 124 and operating the slot machine 10. It has become.

As shown in FIG. 6, the main control device 131 is attached to the back plate 11c of the housing 11 above the reel unit 41. The main control device 131 has a CPU that controls the main control, a ROM that stores a game program, a RAM that temporarily stores necessary data according to the progress of the game, a port for contacting various devices, and time counting and synchronization. It is provided with a main board including a clock circuit or the like used for planning, and the main board is housed in a board box as an encapsulation means made of a transparent resin material or the like. The substrate box includes a box base having a substantially rectangular parallelepiped shape and a box cover that covers an opening of the box base. The box base and the box cover are unopenably connected by a sealing unit as a sealing means, whereby the substrate box is sealed. The box base and the box cover may be connected to each other by using a key member so as not to be opened.

FIG. 9 is a diagram showing the internal structure of the selector 83. The two-dot chain line in the figure shows the passage route of the medal for easy understanding. The selector 83 is formed with a guide passage 85 for guiding the medals inserted from the medal insertion port 75 to the storage passage 81. The guide passage 85 is formed in a curved shape that draws an arc from the upper end to the lower right of the figure so that medals can pass in one row. More specifically, the selector body constituting the selector 83 is provided with a ridge 85a protruding toward the front side in the drawing, and a guide passage 85 is formed along the ridge 85a. As a result, the medals that have reached the guide passage 85 will flow in the downstream direction so as to roll on the ridge 85a.

The medal passage switching member 84 has a passage switching piece 84a provided upstream of the guide passage 85 and capable of appearing and disappearing from the guide passage 85, and a solenoid (not shown) for operating the passage switching piece 84a. doing. When the solenoid is not excited, the passage switching piece 84a protrudes into the guide passage 85, and the flow of medals to the storage passage 81 is obstructed. As a result, the medal falls downward so as to get over the ridge 85a and is guided to the discharge passage 82. Further, when the solenoid is excited, the passage switching piece 84a sinks outside the guide passage 85. As a result, the medal flows along the guide passage 85 and is guided to the storage passage 81.

On the downstream side of the passage switching piece 84a, the first inserted medal detection sensor 86 for detecting the passage of medals and the second inserted medal detection sensor 87 are arranged close to each other so as to line up upstream and downstream of the guide passage 85. (The proximity state is such that the same medal is detected at the same time at least for one period). When the solenoid of the medal passage switching member 84 is not excited, the medal falls downward from the middle of the guide passage 85, so that the passage of the medal is not detected by the inserted medal detection sensors 86 and 87. On the other hand, when the medal passage switching member 84 is solenoid-excited, the passage of medals is sequentially detected by the inserted medal detection sensors 86 and 87.

Next, the electrical configuration of the slot machine 10 will be described with reference to the block diagram of FIG. FIG. 10 is a block diagram showing an electrical configuration of the slot machine 10.

The main control device 131 is equipped with a microcomputer centered on the CPU 151, which is an arithmetic processing means. In addition to the power supply device 161 provided inside the power supply box 121, a clock circuit 154 that outputs a rectangular wave having a predetermined frequency, an input / output port 155, and the like are connected to the CPU 151 via an internal bus. The main control device 131 functions as a main board built in the slot machine 10.

On the input side of the main controller 131, there are a start detection sensor 71a that detects the operation of the start lever 71, a stop detection sensor 72a, 73a, 74a that individually detects the operation of each of the stop switches 72, 73, 74, and a medal insertion slot. The first inserted medal detection sensor 86 that detects the medals inserted from 75, the second inserted medal detection sensor 87 (hereinafter, when these sensors are collectively referred to as the inserted medal detection sensors 86, 87), each credit The credit insertion detection sensors 77a, 78a, 79a that individually detect the operation of the closing switches 77, 78, 79, the switching detection sensor 80a that detects the operation of the changeover switch 80, and the rotation position (origin position) of each reel 42 are individually set. The reel index sensor 55 to detect, the payout detection sensor 91a to detect the medal paid out from the hopper device 91, the reset detection sensor 123a to detect the operation of the reset switch 123, and the setting key insertion hole 124 to detect that the setting key has been inserted. Various sensors such as the setting key detection sensor 124a are connected, and signals from these various sensors are output to the CPU 151 via the input / output port 155.

Further, the detection signals of the input medal detection sensors 86 and 87 are also input to the detection signal latch circuit 88. The detection signal latch circuit 88 inputs a signal detection circuit unit for inputting a detection signal from the first insertion medal detection sensor 86 and a detection signal from the second insertion medal detection sensor 87, and an output signal of the signal detection circuit unit. A latch circuit unit for latching is provided. The signal detection circuit unit has an OR circuit as a main configuration, and by inputting at least one of the detection signals from the first insertion medal detection sensor 86 and the detection signal from the second insertion medal detection sensor 87, A signal corresponding to the logical sum is output to the latch circuit unit, and further, a latch signal is output from the latch circuit unit to the main control device 131. The latch signal output state of the detection signal latch circuit 88 is held until a signal release command is input from the main control device 131. Details will be described later.

Further, a power failure monitoring circuit 161b provided in the power supply device 161 is connected to the input side of the main control device 131 via the input / output port 155. The power supply device 161 is equipped with a power supply unit 161a that supplies drive power to each electronic device of the slot machine 10 including the main control device 131, a power failure monitoring circuit 161b described above, and the like.

The power failure monitoring circuit 161b monitors the power cutoff state and generates a power failure signal not only when the power is cut off but also when the power supply is cut off by the power switch 122. Therefore, the power failure monitoring circuit 161b monitors the stabilized drive voltage of DC 12 volt in this example output from the power supply unit 161a, and determines that the power supply is cut off when this drive voltage drops to less than, for example, 10 volt. It is configured to output a power failure signal. The power failure signal is supplied to each of the CPU 151 and the input / output port 155, and the CPU 151 recognizes the power failure signal to execute the power failure processing described later.

Even if the output voltage drops to less than 10 volts from the power supply unit 161a, a regulated voltage of 5 volts, which is used as a drive voltage in a control system such as the main controller 131, is output. As the time for which the regulated voltage is output, a sufficient time is secured for executing the power failure processing by the main controller 131.

To rotate each effective line display unit 32, 33, 34, remaining number display unit 35, game number display unit 36, acquired number display unit 37, and reels 42L, 42M, 42R on the output side of the main control device 131. External centralized terminal board 171 that can transmit information to each stepping motor 61 (61L, 61M, 61R), a medal passage switching member 84 provided in the selector 83, a hopper device 91, a display control device 111, a hole management device (not shown), and the like. Etc. are connected via the input / output port 155.

The display control device 111 is a control device for driving the upper lamp 13a, the closing abnormality lamp 13b, the speaker 14, and the auxiliary display unit 15 constituting the lamp 13, and includes a CPU, ROM, RAM, and the like for driving these. It has an integrated substrate. Then, after receiving the signal from the main control device 131, the display control device 111 independently drives and controls the lamps 13a and 13b, the speaker 14, and the auxiliary display unit 15. Therefore, the display control device 111 is a sub-board that executes auxiliary control in relation to the main control device 131, which is the main board that centrally manages the game. That is, the burden on the main board is reduced by providing a sub board for voices, lamps, and displays related to indirect games. The display control device 111 may control the various display units 32 to 37.

The CPU 151 described above has a ROM 152 that stores various control programs and fixed value data executed by the CPU 151, and an operation that temporarily stores various data when executing the control program stored in the ROM 152. In addition to the RAM 153 for securing the area, as is well known, various processing circuits required in the slot machine 10 such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit, and a credit counter for counting the number of credits, as is not shown, Various counters such as are built-in. A main memory as a storage means is configured by the ROM 152 and the RAM 153, and a program for executing the processes shown in various flowcharts shown in FIGS. 10 and 10 and later is stored in the ROM 152 described above as a part of the control program.

The RAM 153 has a configuration in which a backup voltage is supplied from the power supply device 161 provided in the power supply box 121 to hold (backup) data even after the power supply of the slot machine 10 is cut off. A backup area is provided in addition to a memory and an area for temporarily storing various data and the like.

In the backup area, when the power is cut off due to a power failure or the like, the stack pointer at the time of power cutoff (including power cutoff by operating the power switch 122; the same applies hereinafter), each register, the value of I / O, etc. It is an area for storing the above, and when the power failure is resolved (including turning on the power by operating the power switch 122. The same applies hereinafter), the state of the slot machine 10 is set to the state before the power is cut off based on the information in the backup area. It is possible to return to the state. Writing to the backup area is executed when the power is cut off by a power failure process (see FIG. 10), and restoration of each value written in the backup area is executed in the main process (see FIG. 10) when the power is turned on. The NMI terminal (non-maskable interrupt terminal) of the CPU 151 is configured to input a power failure signal from the power failure monitoring circuit 161b when the power is cut off due to a power failure or the like. The NMI interrupt process as the flag generation process is immediately executed.

Next, the displacement unit 300 arranged on the front door 12 will be described with reference to FIGS. 11 to 37. First, with reference to FIGS. 11 and 12, the overall configuration of the front door 12 on which the displacement unit 300 is arranged will be described. FIG. 11 is an exploded perspective front view of the front door 12, and FIG. 12 is an exploded perspective rear view of the front door 12.

As shown in FIGS. 11 and 12, the upper portion of the front door 12 is located on the front side (arrow F direction side) of the top plate 11a of the housing 11 described above, and extends in the left-right direction (arrow LR direction). An upper base member 27 to be provided, a pair of left and right left base members 28 extending downward from both ends of the upper base member 27 in the extending direction, and a right base member 29 are provided. The upper base member 27, the left base member 28, and the right base member 29 form a portal shape in a front view.

Further, in the front door 12, a game panel 30 is arranged on the front side of an inner region formed in a gate shape by the above-mentioned upper base member 27, the left base member 28, and the right base member 29. The upper lamp unit 13, the left lamp unit 38, and the right lamp unit 39 are arranged at positions surrounding the periphery of the game panel 30.

The upper lamp unit 13 is arranged on the front side of the upper base member 27, the left lamp unit 38 is arranged on the front side of the left base member 28, and the right lamp unit 39 is arranged on the front side of the right base member 29. Will be done.

Further, the game panel 30 includes a gate-shaped upper base member 27, a left base member 28, a right base member 29, an upper lamp unit 13 arranged on the front side thereof, and a left lamp. It is interposed between the unit 38 and the right lamp unit 39. As a result, the game panel 30 is attached to the front door 12.

The upper lamp unit 13 is provided with an upper lamp 13a, the left lamp unit 38 is provided with a left lamp 38a, and the right lamp unit 39 is provided with a right lamp 39a, respectively, from the lamps 13a, 38a, 39a. The emitted light can cause the surroundings of the slot machine 10 to emit light. The lamps 13a, 38a, and 39a can individually emit different colors.

Further, in the right lamp unit 39, a displacement unit 300 described later is arranged on the front side, and the light emitted from the right lamp 39a passes through the inside of the displacement unit 300 to the front side of the displacement unit 300 (game). It is configured so that it can be emitted from the person side). That is, the displacement unit 300 can be made to emit light by the right lamp 39a.

On the back side (arrow B direction side) of the upper base member 27, the left base member 28, and the right base member 29 formed in a portal shape, the upper side (see FIG. 3) is higher than the above-mentioned reel unit 41 (see FIG. 3). A liquid crystal frame member 600 arranged in the direction of the arrow U) and an auxiliary display unit 15 arranged on the back side of the liquid crystal frame member 600 are provided.

The liquid crystal frame member 600 is a member for making it easy for the player to visually recognize the image displayed on the auxiliary display unit 15, and is formed in a frame shape surrounding the periphery of the image display surface of the auxiliary display unit 15. Further, the liquid crystal frame member 600 is fastened and fixed to the above-mentioned upper base member 27, the left base member 28, and the right base member 29, and the front door is in contact with the back side of the game panel 30. It is arranged in 12. That is, the formation of a gap between the game panel 30 and the liquid crystal frame member 600 is suppressed. As a result, the image displayed on the auxiliary display unit 15 is reflected at the portion where a gap is formed between the game panel 30 and the liquid crystal frame member 600 (the back surface of the game panel 30 and the front surface of the liquid crystal frame member 600). , It is possible to suppress the reflected light (image) from being visually recognized by the player. As a result, it is possible to make it easier for the player to visually recognize the image displayed on the auxiliary display unit 15.

The entire liquid crystal frame member 600 is formed in black. As a result, the light emitted from the outside of the slot machine 10 to the liquid crystal frame member 600 can be easily absorbed by the liquid crystal frame member 600 as compared with the case where the liquid crystal frame member 600 is formed in white. As a result, it is possible to prevent the light emitted from the outside of the slot machine 10 on the liquid crystal frame member 600 from being reflected by the liquid crystal frame member 600 and the reflected light from being incident on the auxiliary display unit 15. Therefore, it is possible to prevent the image displayed on the auxiliary display unit 15 from becoming difficult to be visually recognized by the player.

Further, as described above, the liquid crystal frame member 600 is formed in a front view frame shape that surrounds the periphery of the image display surface of the auxiliary display unit 15, and is arranged above the reel unit 41 (see FIG. 3). The image display surface of the auxiliary display unit 15 visually recognized via the game panel 30 and the reels 42L, 42M, 42R of the reel unit 41 can be divided into two regions, upper and lower.

Next, the overall configuration of the displacement unit 300 will be described with reference to FIGS. 13 to 15. 13 (a) is a front view of the displacement unit 300, FIG. 13 (b) is a side view of the displacement unit 300 in the XIIIb direction of FIG. 13 (a), and FIG. 13 (c) is a side view of the displacement unit 300. It is sectional drawing of the displacement unit 300 in the XIIIc-XIIIc line of (a). FIG. 14 is an exploded perspective front view of the displacement unit 300. FIG. 15 is an exploded perspective rear view of the displacement unit 300.

As shown in FIGS. 13 to 15, the displacement unit 300 is a base unit 390 arranged on the front side (arrow F direction side) of the right lamp unit 39 (see FIG. 11) described above, and the base unit 390 thereof. An intermediate member 380 arranged with a coil spring SP1 sandwiched between them, an operation unit 320 arranged on the front side of the intermediate member 380, and a part of the operation unit 320 (rotating unit 340). A guide unit 350 for guiding the displacement of the operation unit 320, and an annular member 310 for accommodating the operation unit 320, the guide unit 350, the intermediate member 380, the coil spring SP1, and the base unit 390 inside. And mainly prepare.

The annular member 310 includes an annular portion 311 formed in a hollow annular (cylindrical shape) penetrating in the front-rear direction (arrow FB direction), and an annular portion from the inner peripheral surface of the front end portion of the annular portion 311. A regulation wall 312 erected toward the inside of the 311 is provided.

The annular portion 311 is formed in a size capable of accommodating the guide unit 350 and the base unit 390, which will be described later, inside. Further, the annular portion 311 is formed with a plurality of fastening holes for fastening the guide unit 350 and the screw inserted into the base unit 390 from the back side. As a result, the guide unit 350 and the base unit 390 can be fastened and fixed to the annular member 310.

The annular portion 311 is formed so that the inner edge (inner peripheral surface) penetrating in the front-rear direction (in the direction of arrow FB) is inclined upward from the back side toward the front side (FIG. 13 (c)). reference). As a result, the operation unit 320, the guide unit 350, the intermediate member 380, the coil spring SP1, and the base unit 390 arranged inside the annular portion 311 are also arranged so as to be inclined upward toward the front side. However, in the following description, for ease of understanding, the stacking direction of the operation unit 320, the guide unit 350, the intermediate member 380, the coil spring SP1, and the base unit 390 will be described as the front-rear direction.

The regulation wall 312 is formed in a disk shape, has an opening 312a, and has an outer peripheral portion connected to the inner peripheral surface of the annular portion 311. The opening 312a is formed in a circular shape, and the opening width (inner diameter) thereof is set to be smaller than the outer diameter of the guide unit 350 described later. As a result, when the guide unit 350 is arranged on the annular member 310, the guide unit 350 is inserted from the back side of the annular member 310 into the inside of the annular member 310, and the front side of the guide unit 350 is set on the regulation wall 312. Can be brought into contact with the back side of the.

The operation unit 320 includes a gripping unit 330 arranged on the front side and a rotating unit 340 connected to the back side (arrow B direction side) of the gripping unit 330.

The gripping unit 330 is formed long in the front-rear direction (arrow FB direction) in the side view. Further, the gripping unit 330 is a portion to be gripped by the player, and the end portion on the front side (arrow F direction side) is on the front side (front side) of the ring member 310 through the opening 312a of the ring member 310 described above. It is projected toward the player side), and the player can grip (operate) the end portion on the front side.

The mode of operation of the player with respect to the gripping unit 330 is not limited to the mode of gripping the gripping unit 330, for example, the mode of pushing the gripping unit 330 in the direction of arrow B or the direction of arrow F without gripping the gripping unit 330. It may be a mode of pulling out to.

The rotating unit 340 is formed in a substantially columnar shape having (parallel) axes along the front-rear direction (arrow FB direction), and has a rear side (arrow B) of the gripping unit 330 on the end surface on the front side (arrow F direction side). The end (on the directional side) is connected. As a result, the rotating unit 340 can be displaced in conjunction with the gripping unit 330 being gripped (operated) and displaced by the player.

Further, the rotating unit 340 is housed inside the guide unit 350, which will be described later, and its displacement is regulated (guided) by the guide groove 351 formed inside the guide unit 350. Therefore, the displacement of the gripping unit 330 linked to the rotating unit 340 is regulated (guided) by the guide groove 351 formed in the guide unit 350. A detailed description of the guide groove 351 will be described later.

The guide unit 350 is arranged on the front side (arrow F direction side) of the rotating unit 340, and regulates the displacement of the rotating unit 340 to the front side. A rear side guide unit 370, which is arranged on the side in the direction of arrow B) and regulates the displacement of the rotating unit 340 to the rear side, is provided.

The front side guide unit 360 is formed in a substantially cylindrical shape having (parallel) axes along the front-rear direction (arrow FB direction), and its inner diameter is formed larger than the outer diameter of the rotating unit 340. Further, the external dimension of the front side guide unit 360 in the front-rear direction is set to be larger than the external dimension of the rotating unit 340, and the rotating unit 340 can be accommodated inside the front side guide unit 360.

The rear side guide unit 370 includes a first portion 371 formed in a substantially annular shape having (parallel) axes along the front-rear direction (arrow FB direction), and the inner diameter of the first portion 371 is the rotating unit 340. It is formed smaller than the outer diameter of. Therefore, by accommodating the rotary unit 340 inside the front guide unit 360 and then fastening the front guide unit 360 and the rear guide unit 370, the rotary unit 340 is accommodated inside the guide unit 350. A detailed description of the configuration of the rear guide unit 370 and the displacement of the rotating unit 340 will be described later.

The intermediate member 380 is a member that transmits the urging force of the coil spring SP1 to the rotating unit 340, and is arranged at a position adjacent to the back surface side (arrow B direction side) of the rotating unit 340. Further, the intermediate member 380 is formed in a disk shape, and its outer diameter is set to be smaller than the inner diameter of the back side guide unit 370 of the guide unit 350. As a result, the intermediate member 380 can be displaced inside the guide unit 350.

The intermediate member 380 has a first opening 381 that opens in a circular shape at the center position of the disk, and an opening in the front-rear direction (arrow FB direction) at a position that is radially outward from the center of the first opening 381. A second opening 382, a third opening 383 that opens in the front-rear direction at a position different from the second opening 382 in the circumferential direction, and a projecting portion that protrudes radially outward from a part of the outer peripheral portion. 384 and.

The first opening 381 is an opening for aligning (positioning) the intermediate member 380 with respect to the rotating unit 340. The position of the intermediate member 380 with respect to the rotating unit 340 is adjusted by inserting the insertion portion 342a protruding from the back surface side of the rotating unit 340, which will be described later, into the first opening 381.

Further, the intermediate member 380 includes a cylindrical erection portion 385 that is erected from the back surface side (arrow B direction side) along the inner edge of the first opening 381. The upright portion 385 is a portion on which the front side (arrow F direction side) of the coil spring SP1 is fitted, and the outer diameter is set to be smaller than the inner diameter of the coil spring SP1. Therefore, since the coil spring SP1 is fitted on the vertical portion 385, it is possible to prevent the position of the coil spring SP1 with respect to the intermediate member 380 from being displaced due to elastic deformation.

The second opening 382 has an elongated hole-shaped opening curved along an arc centered on the axis of the intermediate member 380 (that is, a ring shape concentric with the axis of the intermediate member 380 is divided in the circumferential direction. It is formed as an opening). The second opening 382 is an opening through which the engaging piece 342b of the rotating unit 340, which will be described later, is inserted, and is formed in a size (region) that does not interfere with the displacement locus of the engaging piece 342b.

The third opening 383 is an opening through which a wiring (not shown) extending from the right lamp unit 39 described above passes through the base unit 390 and extends inside the rotating unit 340 (operation unit 320). Further, the intermediate member 380 includes a wall portion 386 erected from the back surface side (arrow B direction side) along the inner edge of the third opening 383. The wall portion 386 is formed as a continuous wall portion along the inner edge of the third opening 383.

As a result, the wiring extending from the base unit 390 can be connected to the inside of the rotating unit 340 (operation unit 320) via the third opening 383 (through). Further, when the intermediate member 380 is displaced, the wall portion 386 suppresses the wiring connected to the inside of the rotating unit 340 from being sandwiched between the intermediate member 380 and the base unit 390, so that the wiring is broken. Can be suppressed.

The protrusion 384 is a protrusion that is inserted inside the recess 371a of the guide unit 350, which will be described later, and engages with the guide unit 350. The outer shape of the protrusion 384 is the inner surface shape of the recess 371a. Is formed in a shape corresponding to. Therefore, in the state where the projecting portion 384 is inserted inside the recessed portion 371a, even if an external force that rotationally displaces the intermediate member 380 with respect to the guide unit 350 about the axis is input to the intermediate member 380, the projecting portion 384 is projected. Since the portion 384 is in contact with the inner surface of the recessed portion 371a, the rotation of the intermediate member 380 with respect to the guide unit 350 is suppressed (regulated).

The base unit 390 covers the back side (arrow B direction side) of the ring member 310, and the operation unit 320, the guide unit 350, and the intermediate member 380 housed inside the ring member 310 come out to the back side. It is a member that regulates this, and the inner edge shape and the outer edge of the annular member 310 in the rear view are formed to be substantially the same, and are fastened and fixed inside the annular member 310 on the rear surface side.

Further, the base unit 390 is provided with a plurality of fastening holes 392a3 on the back surface side into which the tips of the screws inserted from the back surface side are screwed into the insertion holes of the right base member 29 described above. Therefore, by screwing the screw inserted from the back side of the right base member 29 (see FIG. 11) into the fastening hole 392a3, the displacement unit 300 in which a plurality of components are integrated is arranged in the front door 12. Will be done. Therefore, since the head of the screw that fastens the displacement unit 300 to the front door 12 can be positioned on the back side of the right base member 29, it is possible to prevent the displacement unit 300 from being illegally removed from the player side.

Next, the gripping unit 330 of the operating unit 320 and the rotating unit 340 will be described with reference to FIGS. 16 to 19. 16 (a) is a front view of the operation unit 320, FIG. 16 (b) is a side view of the operation unit 320 in the XVIb direction view of FIG. 16 (a), and FIG. 16 (c) is an operation. It is a rear view of the unit 320. FIG. 17A is a perspective front view of the operation unit 320, and FIG. 17B is a perspective rear view of the operation unit 320. FIG. 18 is an exploded perspective front view of the operation unit 320, and FIG. 19 is an exploded perspective view of the gripping unit 330.

As shown in FIGS. 16 to 19, the gripping unit 330 includes a right side cover member 331 arranged on the right side in the front view, a left side cover member 332 arranged on the left side in the front view, their right side cover member 331, and the right side cover member 331. , A vibrating device 333 disposed between the left side cover members 332, and the like.

The right side cover member 331 is a circular portion 331a formed in a circular plate shape located on the front side (arrow F direction side) of the gripping unit 330 formed long in the front-rear direction (arrow FB direction), and a circular portion thereof. A projecting portion 331b projecting from the outer edge of the portion 331a toward the radial outward side of the circular shape (arrow B direction side) and located on the back surface side (arrow B direction side) of the gripping unit 330, and an inner surface of the circular portion 331a. An annular right first wall portion 331c projecting (standing) from (opposing surface to the left side cover member 332) toward the left side cover member 332 side (arrow L direction side), and front and rear of the projecting portion 331b. The right second wall portion 331d projecting (standing) from the outer edge extending in the direction (arrow FB direction) toward the left side cover member 332 side and the inside (circular center) of the right first wall portion 331c. The third wall portion 331e on the right side, which is located on the side) and is projected (erected) in an annular shape substantially concentric with the first wall portion 331c on the right side from the inner surface of the circular portion 331a, and the rear end portion of the projecting portion 331b. A projecting portion 331f projecting from the back side is provided.

The left side cover member 332 is formed to have substantially the same shape (a shape symmetrical to the right side with the mating surface with the right side cover member 331 as a symmetrical surface) by reversing the right side cover member 331 in the left-right direction (arrow LR direction). Will be done. Therefore, the left side cover member 332 and the circular portion 332a formed in a circular plate shape are located on the front side (arrow F direction side) of the gripping unit 330 formed long in the front-rear direction, similarly to the right side cover member 331. , A projecting portion 332b projecting from the outer edge of the circular portion 332a toward the outward side in the radial direction (arrow B direction side) of the circular shape and located on the back surface side (arrow B direction side) of the gripping unit 330, and a circular portion. The left first wall portion 332c projecting from the inner surface of 332a (the surface facing the right side cover member 331) toward the right side cover member 331 side (arrow R direction side), and the front-rear direction (arrow F) of the projecting portion 332b. Positioned on the inside (center side of the circular shape) of the left side second wall part 332d and the left side first wall part 332c projecting (standing) from the outer edge extending in the −B direction) toward the right side cover member 331 side. From the inner surface of the circular portion 332a, the left third wall portion 332e is projected (erected) in an annular shape substantially concentric with the right first wall portion 331c, and the projecting portion 332b is from the back side end to the back side. It includes a protruding portion 332f that protrudes toward the direction.

Therefore, in the following description, the right side cover member 331 will be described as a representative example, and the description of the left side cover member 332 will be omitted. The differences between the right side cover member 331 and the left side cover member 332 will be described later.

The circular portion 331a is the right side surface when the player grips the gripping unit 330, the central portion of the circular shape is formed in a flat shape, and the annular portion outside (outer edge side) from the central portion covers the left side. It is formed so as to be inclined toward the member 332 side. As a result, the thickness of the gripping unit 330 at the portion gripped by the player can be increased at the central portion, so that the player can easily grip the gripping unit 330. That is, since the outer annular portion of the circular portion 331a is inclined, the thickness of the outer portion of the gripping unit 330 can be reduced. As a result, when the player grips the gripping unit 330, it is possible to prevent the player's hand from being caught by the end of the circular portion 331a, and it is possible to facilitate the player to rotate the gripping unit 330.

The projecting portion 331b is a portion that secures an amount in which the circular portion 331a of the gripping unit 330 is displaced to the back side when the operation unit 320 is displaced to the back side, and the guide unit 350 whose dimensions in the vertical direction will be described later. It is set smaller than the inner diameter of the reduced diameter portion 361b of. As a result, the protruding portion 331b can be inserted into the guide unit 350 by inserting the reduced diameter portion 361b. Further, when the operation unit 320 is displaced to the back side by the length of the protrusion 331b protruding from the reduced diameter portion 361b to the front side (arrow F direction side), the circular portion 331a becomes the guide unit 350. It is possible to suppress contact.

The right side first wall portion 331c and the right side second wall portion 331d of the right side cover member 331 are erected toward the left side cover member 322 side, and the left side first wall portion 332c and the left side first wall portion 332c of the left side cover member 332. The two wall portions 332d are erected toward the right side cover member 321 side, and when the right side cover member 331 and the left side cover member 332 are combined, the erected tip surfaces of the wall portions come into contact with each other. Therefore, a gap (space) is formed between the circular portion 331a and the projecting portion 331b, the circular portion 332a, and the projecting portion 332b, and the vibration device 333 is arranged in the gap.

The right first wall portion 331c includes an engaging portion 331c1 and a positioning projection 331c2. The engaging portion 331c1 is located on the front side (arrow F direction side, opposite side of the projecting portion 331b) of the right first wall portion 331c, and is located on the erection tip side (arrow L direction side) of the right first wall portion 331c. It is projected from the inner peripheral surface of the above to the inside in the radial direction (arrow B direction side, projecting portion 331b side). The positioning projection 331c2 is connected to the inner peripheral surface of the right side first wall portion 331c, and projects toward the left side cover member 332 side from the standing tip of the right side first wall portion 331c.

On the other hand, the left first wall portion 332c includes an engaged portion 332c1 and a positioning projection 332c2. The engaged portion 332c1 is located on the front side (arrow F direction side, opposite side of the protruding portion 332b) of the left side first wall portion 332c, and is located on the erection tip side (arrow R direction side) of the left side first wall portion 332c. ) Inward in the radial direction (arrow B direction side, projecting portion 332b side). The engaged portion 332c1 projects from the inner peripheral surface of the left first wall portion 332c to the right side cover member 331 side from the first portion protruding inward in the radial direction and the protruding tip of the first portion. From the second part and the third part that is folded back toward the front side (arrow F direction side) from the protruding tip of the second part and extends substantially parallel to the first part, the cross section is substantially U-shaped. It is formed. The positioning protrusion 332c2 is connected to the inner peripheral surface of the left side first wall portion 332c, and projects toward the right side cover member 331 side from the standing tip of the left side first wall portion 332c.

The engaging portion 331c1 and the engaged portion 332c1 are arranged at corresponding positions (in the same phase), and the right side cover member 331 and the left side are in a state where the engaging portion 331c1 and the engaged portion 332c1 are engaged. It can be combined with the cover member 332. Specifically, when the right side cover member 331 and the left side cover member 332 are fastened in combination, the engaging portion 331c1 is inserted (arranged) between the first portion and the second portion of the engaged portion 332c1. As a result, the front side (player side) of the mating surface of the right side cover member 331 and the left side cover member 332 can be engaged with each other, and it is possible to prevent the mating surface from being opened.

Further, when the right side cover member 331 and the left side cover member 332 are combined, the positioning protrusion 331c2 of the right side cover member 331 is inscribed in the inner peripheral surface of the left side first wall portion 332c of the left side cover member 332, and the left side cover member 332 The positioning protrusion 332c2 of the above is inscribed in the inner peripheral surface of the right first wall portion 331c of the right side cover member 331. Thereby, the right side cover member 331 and the left side cover member 332 can be positioned in the radial direction.

The positioning protrusions 331c2 and the positioning protrusions 332c2 are formed at different positions (different phases) in the circumferential direction of the first wall portions 331c and 332c, and when the right side cover member 331 and the left side cover member 332 are combined, the positioning protrusions 331c2 And the positioning protrusion 332c2 are suppressed from interfering with each other.

The third wall portion 331e on the right side is a wall portion (projection) for accommodating the vibrating device 333 inside, and is formed in a ring shape along the outer shape of the vibrating device 333. As a result, when electric power is applied to the vibrating device 333 and the vibrating device 333 is vibrated, the vibration is transmitted to the outside of the gripping unit 330 (the gripping unit 330) via the right third wall portion 331e and the circular portion 331a. It can be transmitted to the operating player's hand). As a result, the vibrating device 333 can be vibrated to make the player recognize that it is the timing to operate the displacement unit 300, or to recognize that the gaming state is advantageous to the player.

The protruding portion 331f is a portion to be fastened to the rotating unit 340, and fastening holes (not shown) into which screws inserted from the rotating unit 340 side (rear side) are screwed are formed at a plurality of positions of the protruding tip portion. Will be done. Further, the protruding portion 331f is formed in an outer shape corresponding to the concave shape of the recessed portion 341a1 described later. Therefore, the gripping unit 330 is fastened to the rotating unit 340 in a state where the protruding portion 331f is accommodated in the recessed portion 341a1 of the rotating unit 340.

Further, a through hole 331f1 penetrating in the left-right direction (arrow LR direction) is formed in the protruding portion 331f of the right side cover member 331. On the other hand, a fastening hole 332f1 for screwing a screw is formed in the protruding portion 332f of the left side cover member 332. Further, the through hole 331f1 and the fastening hole 332f1 are formed coaxially in the left-right direction, and the screw through which the through hole 331f1 is inserted is screwed into the fastening hole 332f1 to fasten the right side cover member 331 and the left side cover member 332. Will be done.

That is, by screwing the through hole 331f1 and the fastening hole 332f1, the back side of the right side cover member 331 is fastened to the back side (arrow B direction side) of the left side cover member 332. As described above, the right side cover member 331, the left side cover member 332, and the (grip unit 330) are engaged with each other on the front side by the engaging portion 331c1 and the engaged portion 332c1. Therefore, the right side cover member 331 and the left side cover member 332 can be removed by screwing the screw inserted through the through hole 331f1 into the fastening hole 332f1 while the engaging portion 331c1 and the engaged portion 332c1 are engaged. It is considered impossible.

In this case, when the gripping unit 330 is connected to the rotating unit 340, the screws (protruding portions 331f and 332f) for fastening the right side cover member 331 and the left side cover member 332 are housed in the recessed portion 341a1 of the rotating unit 340. Therefore, when the displacement unit 300 is assembled, the gripping unit 330 can be hardly disassembled. As a result, it is possible to prevent the gripping unit 330 from being illegally disassembled by the player.

The rotating unit 340 surrounds the front side member 341 connected to the gripping unit 330, the columnar shaft member 343 projecting radially outward from the back side member 342 thereof, and the shaft member 343. It mainly includes an annular guided member 344, which is arranged in a state (rotatably fitted).

The front side member 341 is located on the gripping unit 330 side (front side) and is formed in a circular shape in the front view toward the back side (arrow B direction side) along the outer edge of the connecting portion 341a. It is provided with a cylindrical erection wall 341b to be erected.

The connecting portion 341a has a recessed portion 341a1 recessed toward the inside (back side) of the vertical wall 341b and an opening 341a2 formed through the inner portion recessed by the recessed portion 341a1. Be prepared.

The recessed portion 341a1 is a portion to which the above-mentioned gripping unit 330 is connected, and a plurality of insertion holes (not shown) are bored in the bottom surface of the recessed portion. The insertion holes of the recessed portions 341a1 are opened at positions facing each of the fastening holes (not shown) formed at a plurality of locations (four locations in the present embodiment) of the protruding portions 331f and 332f of the gripping unit 330. Therefore, the gripping unit 330 and the rotating unit 340 (front side member 341) are fastened by fastening the screw through which the insertion hole of the recessed portion 341a1 is inserted to the fastening holes formed in the protruding portions 331f and 332f. ..

The opening 341a2 is an opening through which the wiring (not shown) connected to the vibrating device 333 of the gripping unit 330 described above is inserted from the rotating unit 340 side to the gripping unit 330 side, and the protrusion 331b and the protrusion of the gripping unit 330. It is communicated with the space between the facing portions of the installation portion 332b. Therefore, the wiring inserted through the opening 341a2 is inserted inside the gripping unit 330 from the space between the projecting portion 331b and the projecting portion 332b facing each other, and is connected to the vibrating device 333.

The erection wall 341b is a portion that regulates the posture of the rotating unit 340 (operation unit 320) with respect to the guide unit 350 described later, and has a cylindrical shape having a predetermined length in the front-rear direction (arrow FB direction). Is formed in. The outer diameter of the erection wall 341b is a virtual circle (virtual line KS1 (see FIG. 21A)) that circumscribes each of the plurality of projecting portions 362a1 in the second annular member 362 of the guide unit 350, which will be described later. The diameter is set to be slightly smaller than the diameter of. As a result, when the rotating unit 340 is housed inside the guide unit 350, the outer peripheral surface of the erection wall 341b becomes the tip (outer peripheral surface) of the plurality of protrusions 362a1 in the second annular member 362 of the guide unit 350. Upon contact, the posture of the operation unit 320 with respect to the guide unit 350 is restricted.

Further, the erection wall 341b includes a regulation piece 341b1 projecting outward in the radial direction from the outer peripheral surface. The regulation piece 341b1 is a portion that defines the rotation range (rotation amount) of the rotation unit 340 with respect to the guide unit 350, and is arranged inside the accommodating recess 362a5 of the second annular member 362 of the guide unit 350, which will be described later. When the rotary unit 340 is rotationally displaced relative to the guide unit 350, the regulation piece 341b1 comes into contact with one inner surface or the other inner surface of the accommodating recess 362a5, so that the guide unit of the rotary unit 340 Rotation in one direction or rotation in the other direction with respect to 350 is restricted. Thereby, the rotation range (rotation amount) of the rotation unit 340 is defined.

The back side member 342 is formed in a disk shape having substantially the same diameter as the outer diameter of the erection wall 341b, and is arranged on the erection wall 341b at a position where the central axis is coaxial with the axis of the erection wall 341b. Will be done. Further, the back surface side member 342 is located at a columnar insertion portion 342a projecting from the center (shaft portion) of the back surface (the surface opposite to the front surface side member 341) and radially outward from the insertion portion 342a. It includes an engaging piece 342b protruding from the back surface, an insertion opening 342c that opens at a position different from that of the engaging piece 342b in the circumferential direction, and an annular standing portion 342d that is erected from the front.

As described above, the insertion portion 342a is a portion to be inserted into the first opening 381 of the intermediate member 380, and its outer diameter is set to a diameter equal to or slightly smaller than the inner diameter of the first opening 381. Therefore, by inserting the insertion portion 342a into the first opening portion 381, it is possible to prevent the position of the intermediate member 380 from shifting in the radial direction (direction perpendicular to the axis) with respect to the rotating unit 340. That is, the rotating unit 340 and the intermediate member 380 are connected so as to be relatively rotatable with their relative positions in the radial direction positioned.

The engaging piece 342b is a portion that engages with the first displacement member 396 of the base unit 390 described later and transmits the displacement of the rotating unit 340 to the displacement unit 395. The length dimension of the engaging piece 342b is such that the inserted tip is the back surface of the intermediate member 380 in the state of being inserted into the second opening 382 of the intermediate member 380 (see FIG. 15) (the assembled state of the displacement unit 300). It is set to a dimension that protrudes from the base unit to the 390 side.

Further, the engaging piece 342b is formed from the first piece 342b1 and the second piece 342b2 in a substantially T-shaped cross section. The first piece 342b1 is formed in a cross-sectional shape extending in the circumferential direction about the center (axis) side of the front side member 341, and is erected from the back surface of the front side member 341 while maintaining the cross-sectional shape. The second piece 342b2 is formed to have a rectangular cross section, and projects from the inner peripheral surface of the first piece 342b1 toward the insertion portion 342a. That is, the second piece 342b2 extends along the longitudinal direction of the first piece 342b1. As a result, the rigidity of the engaging piece 342b can be increased, and it is possible to prevent the engaging piece 342b from being damaged (broken) when the engaging piece 342b is engaged with the first displacement member 396.

As described above, the insertion opening 342c is an opening for inserting the wiring (not shown) inserted into the rotation unit 340 side through the third opening 383 of the intermediate member 380 into the inside of the rotation unit 340. As a result, the wiring inserted from the right lamp unit 39 (see FIG. 11) to the rotating unit 340 via the base unit 390 and the intermediate member 380 is inserted through the opening 341a2 of the front side member 341 of the rotating unit 340. Therefore, it can be connected to the vibrating device 333 of the gripping unit 330.

The standing portion 342d is a cylindrical portion that is erected from a position that is radially inward from the outer edge of the back side member 342 toward the front side member 341 side (front side), and its outer diameter is the back surface. The size is set to be smaller than the outer diameter of the side member 342. Further, the outer diameter of the standing portion 342d is formed to be slightly smaller than the inner diameter of the standing wall 341b of the front side member 341, and when the front side member 341 and the back side member 342 are combined, the standing portion 342d Is arranged (internally fitted) inside the erection wall 341b of the front side member 341. Therefore, when the front side member 341 and the back side member 342 are combined, the standing portion 342d can be inserted into the standing wall 341b to facilitate positioning of the back side member 342 with respect to the front side member 341. Further, by inserting (internally fitting) the erection portion 342d into the erection wall 341b, the connection between the two can be strengthened, the rigidity of the rotating unit 340 can be secured, and the front side member 341 and the back side member 342 can be connected to each other. It is possible to prevent foreign substances such as wires and piano wires from being inserted into the internal space from the mating surface.

The upright portion 342d includes a shaft support hole 342d1 that penetrates in the radial direction (the plate thickness direction (direction orthogonal to the axis of the back surface side member 342)). The shaft support hole 342d1 is a hole through which the shaft member 343, which will be described later, is inserted. Further, the shaft support holes 342d1 are formed at positions where a pair of the shaft support holes 342d1 face each other across the shaft of the back surface side member 342 (positions that are 180 degrees out of phase).

The shaft member 343 has a cylindrical portion, a diameter-expanded portion 343a formed by expanding the diameter of the columnar portion on one end side in the axial direction toward the outside in the radial direction, and a shaft of the columnar portion. A groove portion 343b, which is recessed in a groove shape on the other end side in the direction, is provided. The shaft member 343 is inserted into the guided member 344 and the shaft support hole 342d1, which will be described later, in a posture in which the other end side in the axial direction in which the groove portion 343b is formed is directed toward the center of the back surface side member 342.

The diameter-expanded portion 343a is a regulating portion that regulates the guided member 344 from coming out to one end side in the axial direction, and its outer diameter is set to a diameter larger than the inner diameter of the guided member 344.

The groove portion 343b is formed as a concave groove continuous all around in the circumferential direction, and an E-ring C having an outer diameter larger than the inner diameter of the shaft support hole 342d1 of the back side member 342 is fitted into the concave groove (groove portion 343b). .. As a result, the shaft member 343 cannot be removed from the shaft support hole 342d1.

The guided member 344 is a cylindrical (roller-shaped) member guided by a guide groove 351 (see FIG. 22D) of the guide unit 350 described later, and as described above, the shaft member 343 is on the inner peripheral side. Is inserted into. The inner diameter of the guided member 344 is set to be larger than the outer diameter of the portion (the portion formed in a columnar shape) excluding the enlarged diameter portion 343a of the shaft member 343.

As a result, the guided member 344 is rotatably held (shaft supported) by the shaft member 343. Therefore, when the guided member 344 is guided by the guide groove 351 of the guide unit 350, the guided member 344 is rotated (rolled) with respect to the inner surface of the guide groove 351 to cause the back side member 342 (rotating unit). 340) can be displaced.

Next, the guide unit 350 will be described with reference to FIGS. 20 and 21. 20 (a) is a front view of the guide unit 350, FIG. 20 (b) is a perspective front view of the guide unit 350, and FIG. 20 (c) is a perspective rear view of the guide unit 350. 20 (d) is a cross-sectional view of the guide unit 350 in the line XXd-XXd of FIG. 20 (a). 21 (a) is an exploded perspective front view of the guide unit 350, and FIG. 21 (b) is an exploded sectional view of the guide unit 350. Note that FIG. 21 corresponds to the cross-sectional view of FIG. 20 (d).

As described above, the guide unit 350 is arranged on the front side guide unit 360 arranged on the front side (arrow F direction side) and on the back side (arrow B direction side) of the front side guide unit 360. It is provided with a rear side guide unit 370.

As shown in FIGS. 20 and 21, the front side guide unit 360 is formed by combining two cylindrical members formed in an annular shape in the front view in the axial direction, and is arranged on the front side (arrow F direction side). The first ring member 361 is provided, and the second ring member 362 arranged on the back surface side (arrow B direction side) of the first ring member 361.

The diameter of the first annular member 361 is reduced from the cylindrical tubular portion 361a and the end portion of the tubular portion 361a on the front side (arrow F direction side) (protruding inward in the radial direction in a flange shape). The diameter-reduced portion 361b and the attachment portion 361c formed by partially bulging (overhanging) outward in the radial direction from the end portion on the back surface side (arrow B direction side) of the tubular portion 361a are provided. ..

The outer diameter of the tubular portion 361a is set to be substantially the same as or slightly smaller than the inner diameter of the opening 312a of the annular member 310 (see FIG. 14) described above. As a result, when the guide unit 350 is arranged in the annular member 310, the tubular portion 361a (guide unit 350) is internally fitted in the opening 312a of the annular member 310, and the inner peripheral surface of the opening 312a and the tubular shape are formed. It is possible to suppress the formation of a gap between the portion 361a and the outer peripheral surface. As a result, it is possible to prevent the player from inserting an illegal member (for example, a wire, a piano wire, etc.) into the displacement unit 300 from the front side of the slot machine 10 (see FIG. 1).

The inner diameter of the reduced diameter portion 361b is set to be smaller than the diameter of the circular portions 331a and 332a (see FIG. 17) of the gripping unit 330 described above. Therefore, for example, when the rotating unit 340 is damaged and the rotating unit 340 is displaced more than the specified displacement amount, the circular portions 331a and 332a of the gripping unit 330 are brought into contact with the reduced diameter portion to the inner edge of 361b. This makes it possible to prevent the entire gripping unit 330 (circular portions 331a, 332a) from being pushed inside the guide unit 350.

A screw hole (not shown) into which a screw for fastening the first ring member 361 and the second ring member 362 is screwed is formed in the attachment portion 361c on the back surface side.

The second annular member 362 includes a first cylindrical portion 362a formed in a cylindrical shape, and a cylindrical second cylindrical portion 362b located on the outer peripheral side of the first cylindrical portion 362a and surrounding the first cylindrical portion 362a. A connecting portion for connecting the outer peripheral surface of the first cylindrical portion 362a and the inner peripheral surface of the second cylindrical portion 362b is provided.

The first cylindrical portion 362a is located at a plurality of projecting portions 362a1 protruding from the inner peripheral surface and at the back end side (arrow B direction side) end of the first cylindrical portion 362a, and is located on the inner peripheral surface of the first cylindrical portion 362a. It is provided with a recessed portion 362a2 to be recessed and a storage recess 362a5.

As described above, the protruding portion 362a1 is a portion that comes into contact with the outer peripheral surface of the vertical wall 341b of the rotating unit 340 and regulates the posture (position) of the rotating unit 340 (operating unit 320) with respect to the guide unit 350. A plurality of (11 in this embodiment) are dispersedly arranged in the circumferential direction of the first cylindrical portion 362a at predetermined intervals. The plurality of projecting portions 362a1 are formed so that the virtual circle circumscribes the tip surface (outer peripheral surface) of the plurality of projecting portions 362a1 in the front view (axial view of the second annular member 362). The diameter of the virtual circle (virtual line KS1) is set to a diameter substantially equal to or slightly larger than the outer diameter of the erection wall 341b of the rotating unit 340.

As a result, when the rotary unit 340 (operation unit 320) is displaced, the area where the vertical wall 341b of the rotary unit 340 and the first cylindrical portion 362a of the guide unit 350 come into contact with each other can be reduced. Therefore, the resistance when the rotating unit 340 (operation unit 320) is displaced can be reduced, and the rotating unit 340 can be easily displaced.

The recessed portion 362a2 is a portion in which the guided member 344 of the rotating unit 340 is arranged inside, and corresponds to the guided member 344 arranged in a pair on the rotating unit 340, and the shaft of the first cylindrical portion 362a. A pair is formed at positions opposite to each other (positions that are 180 degrees out of phase). In the assembled state of the displacement unit 300, the recessed portion 362a2 accommodates the guided member 344 of the rotating unit 340, and the guided member 344 is moved (rolled) along the inner wall of the recessed portion 362a2 to operate the displacement unit 300. The operation direction (displacement direction) of the unit 320 is guided.

As described above, the accommodating recess 362a5 is a portion in which the restricting piece 341b1 of the rotating unit 340 is accommodated inside, and when the rotating unit 340 is displaced, the accommodating recess 362a5 is restricted to the inner wall facing the circumferential direction of the accommodating recess 362a5. The pieces 341b1 are brought into contact with each other to regulate the rotation of the rotating unit 340 within a predetermined range. In the present embodiment, the accommodating recess 362a5 is recessed in a range of about 45 degrees at a central angle about the axis of the first cylindrical portion 362a, and the rotatable range (angle) of the rotating unit 340 (operation unit 320) is set. It is set to approximately 45 degrees.

In the second cylindrical portion 362b, the end portion on the front side (arrow F direction side) is connected to the outer peripheral surface of the first cylindrical portion 362a, and the portion connecting the second cylindrical portion 362b and the first cylindrical portion 362a is formed. , A through hole (not shown) for inserting a screw is formed. By screwing the screw inserted through the through hole into the attachment portion 361c of the first annular member 361, the first annular member 361 and the second annular member 362 are fastened and fixed (front side guide unit). 360 is assembled).

The rear side guide unit 370 stands on the front side along the outer edge of the first part 371 formed in an annular shape, the second part 372 protruding from the first part 371 to the front side, and the first part 371. It is formed with a third part 373 to be provided.

The outer diameter of the first portion 371 is set to a diameter larger than the outer diameter of the first cylindrical portion 362a described above, and the inner diameter is set to a diameter smaller than the outer diameter of the erection wall 341b described above. Further, the first portion 371 is formed with a recessed portion 371a that is recessed from a part of the inner edge toward the outer side in the radial direction.

As described above, the recessed portion 371a is a portion in which the protruding portion 384 of the intermediate member 380 is accommodated, and by accommodating the protruding portion 384 in the recessed portion 371a, the intermediate member 380 rotates with respect to the guide unit 350. Is regulated.

The second portion 372 is located along the inner edge of the first portion 371 and projects toward the second annular member 362 side (front side). As shown in FIG. 20D, the second portion 372 is a portion arranged in the recessed portion 362a2 of the second annular member 362 described above, and the protruding tip surface thereof is the inner wall of the recessed portion 362a2. It is in contact with a stepped surface that connects the inner peripheral surface of the recessed portion 362a2 and the inner peripheral surface of the first cylindrical portion 362a).

As a result, as shown in FIG. 20 (d), the guide unit 350 in the assembled state has a connecting surface of the concave bottom surface of the recessed portion 362a2 and the inner peripheral surface of the first cylindrical portion 362a, and the back side guide unit 370. A pair of guide grooves 351 in which a part of the recessed portion 362a2 is surrounded by the first portion 371 and the second portion 372 of the above is formed at positions facing each other with the center of the first cylindrical portion 362a interposed therebetween.

The guide groove 351 is a groove that guides the guided member 344 of the rotating unit 340 described above, and the groove width is set to be larger than the outer diameter of the guided member 344. A detailed description of the guide groove 351 will be described later.

The inner diameter of the third part 373 is set to be substantially the same as or slightly larger than the outer diameter of the first cylindrical part 362a of the second ring member 362, and the back surface of the second ring member 362 (front side guide unit 360). When the back side guide unit 370 is arranged on the side, it is fitted onto the first cylindrical portion 362a. As a result, positioning when disposing the back side guide unit 370 on the front side guide unit 360 can be simplified. Further, the rigidity of the guide unit 350 can be ensured by fitting the third portion 373 to the first cylindrical portion 362a. In particular, the rigidity of the second annular member 362 can be ensured, and the deformation of the guide groove 351 can be suppressed. Therefore, the guidance of the guided member 344 by the guide groove 351 can be stabilized, and the operability of the operation unit 320 can be improved.

Next, with reference to FIGS. 22 to 24, a guide structure when the operation unit 320 is displaced with respect to the guide unit 350 will be described.

22 (a), 23 (a) and 24 (a) are perspective front views of the operation unit 320 and the guide unit 350, and are views of FIGS. 22 (b), 23 (b) and 24 (a). b) is a front view of the operation unit 320 and the guide unit 350, and FIGS. 22 (c), 23 (c) and 24 (c) are FIGS. 22 (b), 23 (b) and It is sectional drawing of the operation unit 320 and the guide unit 350 in the XXIIc-XXIIc line, the XXIIIc-XXIIIc line and the XXIVc-XXIV line of FIG. 24 (b), and is a cross-sectional view of FIGS. 22 (d), 23 (d) and 24. (D) is a cross-sectional view of the operation unit 320 and the guide unit 350 in the XXIId-XXIId line, the XXIIId-XXIIId line and the XXIVd-XXIVd line of FIGS. 22 (a), 23 (a) and 24 (a). Is.

In FIGS. 22 (c), 23 (c), and 24 (c), only the outer line of the operation unit 320 arranged in the guide unit 350 is shown by a two-dot chain line. Further, FIGS. 22 to 24 show the transition states of the operation unit 320 with respect to the guide unit 350 in order. FIG. 22 shows a state in which the operation unit 320 is arranged at the initial position without being operated by the player, and FIG. 24 shows a position where the operation unit 320 is operated by the player and becomes the end of the movable range. The state of being arranged at (hereinafter referred to as "termination position") is illustrated, and in FIG. 23, the state in which the operation unit 320 is arranged at a position between the initial position and the end position (hereinafter referred to as "intermediate position"). Is illustrated.

As shown in FIG. 22, when the operation unit 320 is arranged at the initial position with respect to the guide unit 350, the center lines of the circular portions 331a and 332a of the right side cover member 331 and the left side cover member 332 of the gripping unit 330 are horizontal. It is parallel to the direction (arrow LR direction) (that is, the flat surface at the center of the circular portions 331a and 332a is orthogonal to the arrow LR direction), and the front side of the rotating unit 340 of the operation unit 320 is the first ring. It is arranged at a position where it abuts on the back surface of the reduced diameter portion 361b of the member 361 (see FIG. 23 (c)).

As described above, in the operation unit 320, the guided member 344 of the rotating unit 340 is arranged in the guide groove 351 of the guide unit 350, and the guided member 344 is displaced (guided) along the guide groove 351. This defines the displacement of the operating unit 320 with respect to the guide unit 350.

Here, the guide groove 351 will be described. As shown in FIG. 22D, the guide groove 351 is formed by the second ring member 362 of the front side guide unit 360 and the back side guide unit 370, and the second ring member 362 and the back surface thereof. It extends in the circumferential direction of the side guide unit 370. A part of the guide groove 351 is formed so as to be inclined.

The guide groove 351 is formed by the first guide surface 351a and the second guide surface 351b formed by the second annular member 362 and the back side guide unit 370 as an inner wall for guiding the movement (rolling) of the guided member 344. It includes a third guide surface 351c and a fourth guide surface 351d to be formed. Further, the guide groove 351 has a first end portion 351e formed by the back side guide unit 370 and a second ring member 362 formed as an inner wall for restricting the movement (rolling) of the guided member 344. It includes two ends 351f.

Here, in a gaming machine including a base member and a displacement member that is displaced along a groove formed in the base member, it is necessary to insert a protrusion formed in the displacement member into the groove of the base member. In this case, when the protrusion of the displacement member is inserted into the groove of the base member, if the other member is arranged at a position where it interferes with the displacement member, the displacement member is placed on the base member while avoiding interference with the other member. Since it is necessary to dispose of the members, the shapes of the base member, the displacement member, and other members are limited, and the degree of freedom in design is reduced.

On the other hand, in the present embodiment, since the guide groove 351 is formed of the second ring member 362 and the back side guide unit 370, the guided member 344 arranged inside the guide groove 351. After arranging the (operation unit 320) on the second annular member 362 (front side guide unit 360), the operation unit 320 is assembled to the guide unit 350 by combining the second annular member 362 and the rear side guide unit 370. be able to.

That is, by disposing the guided member 344 in the guide groove 351 on the second ring member 362 side, it is possible to prevent the arrangement of the operation unit 320 in the second ring member 362 from interfering with other members. .. As a result, the degree of freedom in designing the guide unit 350 and the operation unit 320 can be increased.

In particular, when the guide groove 351 is molded into the guide unit 350 formed in an annular shape with a mold, the structure of the mold becomes complicated, and the guide groove 351 is formed on the second annular member 362 and the back surface. The guide unit 350 can be formed in an annular shape by forming the side guide unit 370 with two members, forming a guide groove 351 on the dividing surface thereof, and setting the dividing direction of the two members to the drawing direction of the mold. Further, the structure of each mold can be simplified, and further, the die can be easily removed from the mold after the guide groove 351 is molded.

Although the case where the guide groove 351 is formed on the inner peripheral surface of the guide unit 350 (second annular member 362) is described, the guide groove 351 is formed so as to penetrate the guide unit 350 in the radial direction. It may be a thing.

Further, when the operation unit 320 that is displaced along the guide unit 350 is arranged inside the guide unit 350 formed in an annular shape, the guided member 344 is formed in the guide groove 351 formed in the guide unit 350. Since it is necessary to insert the operation unit 320 inside the guide unit 350 while inserting the above, the assembly work between the operation unit 320 and the guide unit 350 becomes complicated, and the displacement is arranged inside the guide groove 351. After arranging the guide member 344 (operation unit 320) on the second ring member 362 (front side guide unit 360), the second ring member 362 and the back side guide unit 370 are combined to guide the operation unit 320. Since it can be assembled to the 350, the assembly work can be simplified.

The first guide surface 351a and the third guide surface 351c are arranged so as to face each other with a predetermined interval. The facing distance between the first guide surface 351a and the third guide surface 351c is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 is guided to move by either the first guide surface 351a or the third guide surface 351c. In the following description, the region (moving region of the guided member 344) formed between the first guide surface 351a and the third guide surface 351c of the guide groove 351 is referred to as the “first guide region”. It will be explained as.

The first guide region (first guide surface 351a and third guide surface 351c) goes around while advancing from the initial position (away from the first end portion 351e) and approaching the back side (arrow B direction side). It is formed as an inclined guideway extending in the direction. Therefore, by guiding the guided member 344 along the first guide region, the operation unit 320 rotates around the axes of the second ring member 362 and the back side guide unit 370, and the second ring is formed. The member 362 and the back side guide unit 370 are displaced in the axial direction (arrow FB direction).

When the external force to the operation unit 320 is not input (the operation by the player is not performed), the rotation unit 340 is directed toward the front side (arrow F direction side) by the coil spring SP1 described above. Along with being urged, the base unit 390 (coil spring SP2), which will be described later, urges the vehicle in the counterclockwise direction (rotational direction for returning to the initial position). Therefore, when the external force to the operation unit 320 is not input (for example, when the player releases the operation unit 320) while the guided member 344 is in the first guide region, the coil springs SP1 and SP2 The guided member 344 is guided along the first guide surface 351a to the first end portion 351e by the urging force of, and is returned to the initial position. Further, in the initial position, the guided member 344 is maintained at a position where it comes into contact with the first end portion 351e by the urging force of the coil springs SP1 and SP2.

The second guide surface 351b and the fourth guide surface 351d are formed so as to face each other. Further, the fourth guide surface 351d is extended in a direction in which the guide surface is parallel to the horizontal direction. On the other hand, the second guide surface 351b is formed as a guide surface that inclines toward the front side as it approaches the connecting portion with the first guide surface 351a in the circumferential direction of the second ring member 362 and the first portion 371. To.

The second guide surface 351b and the fourth guide surface 351d are on the back side (arrow B direction side, that is, the first end portion 351e) of the first guide region (first guide surface 351a and third guide surface 351c). Is connected to the end (opposite to). As a result, when the guided member 344 is moved toward the back surface side (arrow B direction side) of the first guide region, the guided member 344 moves the second guide surface 351b and the fourth guide surface 351d. Accepted between opposites.

The second guide surface 351b and the fourth guide surface 351d are arranged so as to face each other with a predetermined interval. The minimum facing distance between the second guide surface 351b and the fourth guide surface 351d is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 is guided to move by either the second guide surface 351b or the fourth guide surface 351d. In the following description, the region (moving region of the guided member 344) formed between the second guide surface 351b and the fourth guide surface 351d facing each other in the guide groove 351 is referred to as the “second guide region”. It will be explained as.

The second guide surface 351b is extended in the circumferential direction while approaching the front side (arrow F direction side) as it approaches the connecting portion with the first guide surface 351a (that is, as it separates from the second end portion 351f). The fourth guide surface 351d is formed as an inclined guide surface, and the guide surface extends in the circumferential direction in a posture parallel to the virtual surface perpendicular to the axes of the second annular member 362 and the back side guide unit 370. It is formed as a guide surface to be formed.

Therefore, when the guided member 344 is guided along the second guide surface 351b of the second guide region, the operation unit 320 rotates about the axes of the second ring member 362 and the back side guide unit 370. While doing so, the second ring member 362 and the back side guide unit 370 are displaced in the axial direction (arrow FB direction).

The inclination angle of the second guide surface 351b is set to be smaller than the inclination angle of the first guide surface 351a. Therefore, the amount of axial displacement of the operation unit 320 per unit rotation is such that the guided member 344 is guided along the first guide surface 351a as compared with the case where the guided member 344 is guided along the second guide surface 351b. The amount of displacement is larger when guided.

On the other hand, when the guided member 344 is guided along the fourth guide surface 351d of the second guide region, the operation unit 320 is in the axial direction of the second ring member 362 and the back side guide unit 370 (arrow F). It is not displaced in the −B direction), and only the rotation around the axis of the second ring member 362 and the back side guide unit 370 is performed.

When the guided member 344 is located in the second guide region and no external force is input to the operation unit 320 (for example, when the player releases his / her hand from the operation unit 320), the coil springs SP1 and SP2 The urging force guides the guided member 344 toward the first guide region along the second guide surface 351b, and then returns to the initial position. In this case, since the second guide surface 351b is inclined in the second guide region, it is possible to smoothly return to the initial position.

The first end portion 351e is formed at the start end of the first guide region (the end on the side opposite to the connection side with the second guide region) and forms an initial position. That is, the displacement of the guided member 344 is regulated by the first end portion 351e, so that the operation unit 320 is positioned at the initial position.

The second end portion 351f is formed at the end of the second guide region (the end on the side opposite to the connection side with the first guide region) and forms the end position. That is, the displacement of the guided member 344 is regulated by the second end portion 351f, so that the operation unit 320 is positioned at the terminal position.

As shown in FIG. 23, the operation unit 320 is rotated clockwise in the front view by the player's operation (for example, the circular portions 331a and 332a of the gripping unit 330 gripped by the player are rotated), or The operation unit 320 is operated by the player (for example, the outer peripheral surface of the mating surface (outer peripheral surface) of the right side cover member 331 and the left side cover member 332 of the gripping unit 330 facing the player is pushed by the player). Is pushed toward the front side (arrow B direction side) when viewed from the player, the guided member 344 of the operation unit 320 (rotating unit 340) is guided by the first guide area of the guide groove 351.

In this case, regardless of the operation (rotation or pushing), the guided member 344 is guided by the guide groove 351 (first guide area), so that the operation unit 320 is rotated in the circumferential direction and is rearward. It is displaced (sliding) to the side (arrow B direction side).

That is, when the gripping unit 330 (circular portions 331a, 332a) is rotated clockwise in the front view (when only the rotation operation is performed), it is brought into contact with the first guide surface 351a by the urging force of the coil spring SP1. The (pressed) guided member 344 is guided (rolled) along the first guide surface 351a, and the operation unit 320 is displaced toward the back side (arrow B direction side) while being rotated in the circumferential direction. Slide).

On the other hand, when the gripping unit 330 is pushed toward the back side (the side in the direction of arrow B) (when only the pushing operation is performed), the guided member 344 resists the urging force of the coil spring SP1 and the third guide surface 351c The guided member 344 is guided (rolled) along the third guide surface 351c, so that the operation unit 320 is rotated in the circumferential direction and is on the back side (arrow B). It is displaced (sliding) to the direction side).

As described above, according to the present embodiment, the operation unit 320 is operated even when the player's gripping unit 330 is operated in different directions (in the present embodiment, the circumferential direction during the rotation operation and the arrow B direction during the pushing operation). A similar displacement can be applied to (grip unit 330). As a result, the player can arbitrarily select the direction in which the operation unit 320 is operated. As a result, it is possible to easily enhance the interest of the player.

In addition, when a button or lever is pressed in one direction or tilted in one direction and is displaced in one direction or rotated in one direction, the operation tends to be monotonous. In contrast to the problem that it is difficult to give interest to the operation, in the present embodiment, the operation unit 320 has a rotational displacement or slide in a direction different from the displacement direction due to the operation due to the slide displacement or the rotational displacement due to the pushing operation or the rotational operation. Since the displacement can be formed, it is possible to easily give an interest to the operation of the operation unit 320.

The direction of pushing the operation unit 320 toward the back side and the direction of the rotation axis during the rotation operation of the operation unit 320 are set to be parallel. As a result, the operation unit 320 (grip unit 330) is displaced even when the player's gripping unit 330 is operated in different directions (in the present embodiment, the circumferential direction during the rotation operation and the arrow B direction during the pushing operation). It can be done easily.

When the operation unit 320 (grip unit 330) is further operated from the state shown in FIG. 23, the guided member 344 reaches the connecting portion between the first guide region and the second guide region. From this state, the gripping unit 330 (circular portions 331a, 332a) is rotated clockwise by a rotation operation (or an operation combining rotation and pushing), so that the guided member 344 is guided to the second guide. You will be guided to the area. After that, the guided member 344 is brought into contact with the second end portion 351f, so that the operation unit 320 (grip unit 330) is arranged at the terminal position as shown in FIG. 24.

In this case, in the second guide region, when the operation unit 320 (grip unit 330) is rotationally operated (that is, when only the rotational force around the axis is applied), the second guide surface is driven by the urging force of the coil spring SP1. The guided member 344 abutted (pressed) on the 351b is guided (rolled) along the second guide surface 351b, so that the operation unit 320 is rotated in the circumferential direction and the second guide member 320 is rotated. 2 As the guide surface 351b is tilted, it is also displaced (sliding) toward the back surface side (arrow B direction side).

Further, when the operation unit 320 (grip unit 330) is operated by an operation combining rotation and pushing, the guided member 344 abutting (pressed) on the fourth guide surface 351d by the pushing force of the operation. However, by being guided (rolled) along the fourth guide surface 351d, the operation unit 320 is only rotated in the circumferential direction.

On the other hand, in the second guide region, the operation unit 320 (grip unit 330) is not displaced only by the pushing operation. That is, in the second guide region, the fourth guide surface 351d is formed as a guide surface perpendicular to the axis of the second annular member 362 and the back side guide unit 370 as a guide surface parallel to the virtual surface, so that the gripping unit 330 is on the back surface. Even if the guided member 344 is abutted (pressed) on the fourth guide surface 351d against the urging force of the coil spring SP1 by being pushed to the side (arrow B direction side), the guided member 344 is guided to the fourth guide. A force component that rolls along the surface 351d (that is, a force component in the direction of rotating the operation unit 320 (grip unit 330)) is not generated. Therefore, the guided member 344 stays at the connecting portion (or on the fourth guide surface 351d) between the first guide region and the second guide region, and the operation unit 320 (grip unit 330) is pushed in the pushing direction (arrow B direction). And is not displaced in any direction of rotation.

As described above, according to the present embodiment, by providing the second guide region, the direction in which the player's gripping unit 330 is operated (in the present embodiment, the circumferential direction during the rotation operation and the arrow B direction during the pushing operation). ) Are different, the displacement mode of the operation unit 320 (grip unit 330) can be changed (in the present embodiment, the operation unit 320 is rotated in the rotation operation (or the operation combining rotation and pushing). , The operation unit 320 is stopped only by pushing operation). As a result, the player can arbitrarily select the direction in which the operation unit 320 is operated. As a result, it is possible to easily enhance the interest of the player.

Further, in the present embodiment, the operation unit 320 is pushed toward the back side from the initial position and operated, and after being guided in the first guide area and reaching the second guide area, the operation direction is changed (that is, rotation). By (operating), the operation unit 320 (grip unit 330) can be displaced to the terminal position. Therefore, the player can change the operation direction between the initial position and the end position (on the way). As a result, it is possible to prevent the player from getting tired of operating the operation unit 320.

When the operation unit 320 is pushed (sliding) toward the back side, the guided member 344 is guided while being in contact with the third guide surface 351c and the fourth guide surface 351d of the back side guide unit 370. On the other hand, when the operation unit 320 is rotated clockwise in the front view, the guided member 344 is guided while being in contact with the first guide surface 351a and the second guide surface 351b of the second annular member 362.

That is, the member with which the guided member 344 comes into contact can be changed in the operating direction of the operation unit 320. Thereby, the contact surface with the guided member 344 can be set to a shape and a material suitable for the operation direction of the operation unit 320.

For example, during the pushing operation of the operation unit 320, when the guided member 344 is guided to the fourth guide surface 351d, it comes into contact with the fourth guide surface 351d and its displacement is regulated, so that the impact when the displacement is regulated is regulated. Places a large effect on the rear guide unit 370, and the rear guide unit 370 is set to a material that is resistant to impact. On the other hand, when the operation unit 320 is rotated, the guided member 344 easily slides along the first guide surface 351a and the second guide surface 351b and is easily displaced. Therefore, the second ring member 362 is made of a material resistant to wear. Set. As a result, it is possible to prevent only a part of the guide surface of the guide groove 351 from being concentratedly deformed (deteriorated). As a result, the durability of the guide groove 351 can be improved.

Alternatively, the guide surface of the guide groove 351 may be formed in a stepped shape, and the vibration sliding on the guide surface may be transmitted to the player who operates the operation unit 320. In this case, assuming that the third guide surface 351c and the fourth guide surface 351d and the first guide surface 351a and the second guide surface 351b have different inner surface shapes, vibration when sliding the respective guide surfaces is generated. It may be set so that the frequencies are different when they are displaced at the same speed. As a result, the operation feeling of operating the operation unit 320 can be made different on each guide surface.

Further, the guide surface on which the guided member 344 is guided by the case where the operation unit 320 is pushed (sliding) and the case where the operation unit 320 is rotated is provided with the third guide surface 351c of the rear side guide unit 370 and the guide surface. It can be divided into a fourth guide surface 351d and a first guide surface 351a and a second guide surface 351b of the second ring member 362.

As a result, the guided member 344 can be guided along different guide surfaces according to the displacement mode of the operation unit 320, and the load received by the guide surfaces can be dispersed. That is, when the displacement member displaced along the guide surface formed on the base member is always moved along a part of the guide surface, the load is concentrated on a part of the guide surface and the guide surface becomes In the present embodiment, the guided member 344 can be guided along different guide surfaces according to the displacement mode of the operation unit 320, so that the load is concentrated on a part of the guide surfaces. Can be suppressed. As a result, it is possible to prevent the back side guide unit 370 and the second ring member 362 on which the guide groove 351 is formed from being damaged.

Further, the connecting portion between the second annular member 362 of the guide groove 351 formed of the two members and the back side guide unit 370 is formed at a position different from the guide surface of the guided member 344. To be precise, the connecting portion between the second annular member 362 and the back side guide unit 370 is the connecting portion (connecting portion) of the first end portion 351e and the first guide surface 351a, and the second end portions 351f and the fourth. It is set to the connecting portion (connecting portion) of the guide surface 351d.

Here, when the connecting portion between the second ring member 362 and the back side guide unit 370 is set on the guide surface of the guide groove 351, when the second ring member 362 and the back side guide unit 370 are combined. Due to factors such as the error (assembly tolerance) and the processing accuracy (dimensional tolerance) of the second ring member 362 and the back side guide unit 370, there is a risk that a step may be formed on the guide surface of the guide groove 351. When the guided member 344 guided through the 351 passes through the step, it may be caught in the step and easily worn.

On the other hand, the connecting portion between the second annular member 362 of the guide groove 351 formed of the two members and the back side guide unit 370 is formed at a position different from the guide surface of the guided member 344, so that the guide groove is formed. It is possible to prevent the guided member 344 guided by 351 from becoming worn faster.

The connecting portion between the second ring member 362 and the back side guide unit 370 may be set at a position where it does not abut when the guided member 344 is guided. For example, the second ring member 342 may be connected. Even if the connecting portion between the member 362 and the back side guide unit 370 is formed on the first guide surface 351a or the third guide surface 351c at a position separated from the first end portion 351e by a value smaller than the radius of the guided member 344. It may be formed at the first end portion 351e and the second end portion 351f.

Further, the operation unit 320 can be guided along different guide surfaces during the rotation operation and the push operation, and the guide surfaces are formed of different members. Therefore, when the design of the guide groove 351 is changed, the guide surface can be guided. Design changes can be made easily. For example, when changing the displacement mode of the operation unit 320 at the time of pushing, it is not necessary to change the shape of the second ring member 362, and the third guide surface 351c and the fourth guide surface 351d of the rear side guide unit 370 do not need to be changed. It is only necessary to change the shape of.

The operation direction of the operation unit 320 (grip unit 330) may be appropriately selected by the player, or the operation direction is transmitted to the player according to the effect content of the slot machine 10 (auxiliary display unit 15). (Display on or by voice), and the player may be made to change the operation direction based on the transmission.

Next, with reference to FIGS. 25 and 26, the guide mode (change in the contact surface) of the guided member 344 by the guide groove 351 when the operation unit 320 (grip unit 330) is displaced from the initial position to the terminal position. explain.

25 (a) to 25 (c) and 26 (a) to 26 (c) are cross-sectional schematic views of the operation unit 320 and the guide unit 350, and FIGS. 25 (a) and 25 (a) and 25 (c). (B) and FIG. 25 (c) and FIGS. 26 (a), 26 (b) and 26 (c) are shown in FIGS. 22 (c), 23 (c) and 24 (c), respectively. Correspond.

It should be noted that in FIGS. 25 (a) to 25 (c), the transition states of the guided member 344 when the player rotates the operation unit 320 (grip unit 330) are shown in order from FIG. 26 (a). In FIG. 26C, the player is guided when the operation unit 320 (grip unit 330) is pushed toward the guide unit 450 side (rear side (arrow B direction side)) and then the operation unit 320 is rotated. The transition states of the members 344 are shown in order.

Further, in FIGS. 25 (a) and 26 (a), the operation unit 320 is arranged at the initial position, and in FIGS. 26 (c) and 26 (c), the operation unit 320 is arranged at the terminal position. Each state is illustrated. Further, in FIGS. 25 (b) and 26 (b), the guided member 344 is located at a position (hereinafter referred to as "first position") at the start end (end portion on the first guide region side) of the second guide region. The arranged state is illustrated.

As shown in FIGS. 25 (a) and 25 (b), when the operation unit 320 (grip unit 330) is rotationally operated by the player (when only the rotational force around the axis is applied to the grip unit 330). In the guided member 344, as described above, since the operation unit 320 (rotating unit 340) is urged to the front side (arrow F direction side) by the coil spring SP1, the first guide groove 351 is used. It comes into contact with the guide surface 351a and moves along the first guide surface 351a in the circumferential direction (left-right direction in FIG. 25) to guide the first guide region.

As shown in FIG. 25B, the guided member 344 that has passed through the first guide region and reached the first position of the second guide region has a surface on the front side of the second guide region (that is, the second guide region). It is arranged at a position where it comes into contact with the guide surface 351b).

As shown in FIGS. 25 (b) and 25 (c), the operation unit 320 is in a state where the guided member 344 is located at the first position of the second guide region (in this case, the starting end of the second guide surface 351b). When the (grip unit 330) is further rotated by the player (only the rotational force around the axis is applied to the grip unit 330), the guided member 344 receives the operation unit 320 (rotation unit 340) as described above. ) Is urged to the front side (arrow F direction side) by the coil spring SP1, so that it comes into contact with the second guide surface 351b of the guide groove 351 and goes around the guide groove 351 along the second guide surface 351b. It moves in the direction (left-right direction in FIG. 25) and guides the second guide region to the end position (the position where it abuts on the second end portion 351f).

As described above, the second guide surface 351b of the guide groove 351 extends in the circumferential direction (left-right direction in FIG. 25C) of the second ring member 362 and the first portion 371, and the first guide surface It is formed so as to be inclined toward the front side toward the connecting side with 351a.

Therefore, when the operation unit 320 is displaced by the rotational operation from the initial position to the terminal position (that is, when only the rotational force around the axis is applied to the gripping unit 330), the first guide surface 351a and the second guide With the inclination of the surface 351b, the operation unit 320 is displaced to the back surface side (the arrow B direction side) while being rotated (displaced in the circumferential direction).

In this way, when the operation unit 320 is rotated from the initial position to the terminal position, the guided member 344 is guided to the first guide area and the second guide area, which have different extension directions. The amount of slide displacement toward the rear side with respect to the amount of rotation of the operation unit 320 is changed. That is, while the operation unit 320 is rotationally displaced, the displacement mode toward the rear surface is changed. As a result, the operation of the operation unit 320 can be enjoyed.

As shown in FIGS. 26 (a) and 26 (b), when the operation unit 320 (grip unit 330) is pushed toward the back side (only the axial pushing force is applied to the grip unit 330). Or, when a pushing force in the axial direction is applied to the gripping unit 330 and a rotational force around the axis is also applied), the guided member 344 comes into contact with the third guide portion 351c of the guide groove 351 and takes such a th. 3 The guide groove 351 is moved in the circumferential direction (left-right direction in FIG. 26) along the guide surface 351c to guide the first guide region.

As shown in FIG. 26B, the guided member 344 that has passed through the first guide region and reached the first position of the second guide region has a surface on the back surface side of the second guide region (that is, the fourth guide region). It is arranged at a position where it abuts on the guide surface 351d).

Here, when only the pushing force in the axial direction is applied to the operation unit 320 (grip unit 330) and the rotational force around the axis is not applied, the guided member 344 is subjected to the first guide region (third guide surface). When the first position of the second guide region (in this case, the start end of the fourth guide surface 351d) is reached after passing through 351c), the guided member 344 reaches the fourth guide surface 351d (second guide region). Immediately after being guided, the displacement of the operation unit 320 (grip unit 330) is stopped.

That is, as described above, the fourth guide surface 351d extends in the circumferential direction in a posture perpendicular to the axis of the second annular member 362 and the back side guide unit 370 in a posture parallel to the virtual surface. Since it is formed as a guide surface to be guided, when the guided member 344 reaches the first position of the second guide region (the starting end of the fourth guide surface 351d) only by the pushing operation, the force acting on the guided member 344. Since the direction of the fourth guide surface 351d and the extension direction of the fourth guide surface 351d are substantially orthogonal to each other and no force component is generated in the rotation direction (circumferential direction, left and right direction in FIG. 26B), the operation unit 320 (grip unit) 330) cannot be displaced.

The third guide surface 351c and the fourth guide surface 351d have their respective guide surfaces linear in the circumferential direction (left-right direction in FIG. 25B) of the second ring member 362 and the first part 371. It is formed, and the intersection angle between the third guide surface 351c and the fourth guide surface 351d is set to a predetermined angle (preferably about 165 degrees or more and about 135 degrees or less, and in this embodiment, about 150 degrees).

As a result, when the guided member 344 is guided from the third guide surface 351c (first guide region) to the start end of the fourth guide surface 351d (first position of the second guide region), the generation of impact is suppressed. At the same time, it is possible to reliably guide to the first position. That is, if the tolerance angle is too large, the impact when the guided member 344 reaches the second guide region becomes large, while if the tolerance angle is too small, the guided member 344 is displaced in the circumferential direction (rotational direction). The force component for this is insufficient, and the guided member 344 is not smoothly transferred from the first guide region to the second guide region. On the other hand, by setting the tolerance angle, the transition of the guided member 344 from the first guide region to the second guide region is performed while suppressing the impact when the guided member 344 reaches the second guide region. It can be done smoothly.

As a result, when only the pushing force in the axial direction is applied to the operation unit 320 (grip unit 330) and the rotational force around the axis is not applied, the guided member 344 is placed at the same position (first position) each time. It can be easily stopped. As a result, the operation feeling (operation amount) of the player who operates the operation unit 320 can be made the same, so that it is possible to suppress the player from feeling a sense of discomfort in the operation of the operation unit 320.

As shown in FIGS. 26 (b) and 26 (c), the operation unit 320 is in a state where the guided member 344 is located at the first position of the second guide region (in this case, the starting end of the fourth guide surface 351d). When the (grip unit 330) is further operated by the player (the grip unit 330 is subjected to an axial pushing force and an axial rotational force), the guided member 344 is subjected to the fourth guide groove 351. It comes into contact with the guide surface 351d, moves the guide groove 351 (second guide region) in the circumferential direction (left-right direction in FIG. 26) along the fourth guide surface 351d, and ends the second guide region at the terminal position (second end). It is guided to the position where it comes into contact with the portion 351f).

When the player does not operate the operation unit 320 after operating the operation unit 320 to a position where the guided member 344 comes into contact with the second end portion 351f by pushing and sliding the operation unit 320, the operation unit 320 is used. The urging force of the acting coil springs SP1 and SP2 guides the guided member 334 to the starting position along the second guide surface 351b and the first guide surface 351a.

Therefore, when the operation unit 320 is pushed and slid, the guide surfaces (third guide surface 351c and fourth guide surface 351d) to which the guided member 344 is guided by those operations, and the coil spring SP1, By making the guide surface (second guide surface 351b, first guide surface 351a) on which the guided member 344 is guided by the urging force of SP2 different from each other, the load received by the contact of the guided member 344 is efficiently applied. Can be dispersed.

The operation unit 320 (grip unit 330) is rotationally operated (that is, the axis of the grip unit 330) from the state where the guided member 344 is located at the first position of the second guide region (the starting end of the fourth guide surface 351d). (Only the rotational force around it is applied), as described above, the operation unit 320 (rotational unit 340) of the guided member 344 is urged to the front side (arrow F direction side) by the coil spring SP1. Therefore, the guide groove 351 comes into contact with the second guide surface 351b, the guide groove 351 is moved in the circumferential direction along the second guide surface 351b, and the second guide region is set to the terminal position (the second end portion 351f). It is guided to the abutting position) (see FIG. 25 (c)).

Next, the base unit 390 will be described with reference to FIGS. 27 to 30. 27 (a) is a front view of the base unit 390, FIG. 27 (b) is a perspective front view of the base unit 390, and FIG. 27 (c) is a line XXVIIc-XXVIIc of FIG. 27 (a). It is sectional drawing of the base unit 390 in. FIG. 28 is an exploded perspective front view of the base unit 390. 29 (a) is a front view of the base unit 391, and FIG. 29 (b) is a cross-sectional view of the base unit 391 in line XXIXb-XXIXb of FIG. 29 (a). 30 (a) is a front view of the displacement unit 395, FIG. 30 (b) is a rear view of the displacement unit 395, and FIG. 30 (c) is the line XXXc-XXXc of FIG. 30 (a). It is sectional drawing of the displacement unit 395.

In FIGS. 27 (a) to 27 (c), the displacement unit 395 is urged by the coil spring SP2, and the displacement unit 395 is brought into contact with the second displacement member 397 with the regulation piece 392f of the base unit 391. The state of being placed at the position (hereinafter referred to as "initial urging position") is shown.

As shown in FIGS. 27 to 30, the base unit 390 includes a base unit 391, a displacement unit 395 disposed on the base unit 391, and a coil spring SP2 for urging the displacement unit 395 with respect to the base unit 391. And mainly prepare.

The base unit 391 is formed in an outer shape (outer peripheral edge shape) corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300 described above, and is formed on the inner peripheral edge side thereof. It mainly includes a base member 392 that is arranged (internally fitted), and a leaf spring 393 and a detection device 394 that are arranged on the base member 392.

The base member 392 is erected from the base plate 392a and the front side (arrow F direction side) of the base plate 392a, and is formed in a front view arc shape (substantially C-shaped), and a first wall portion 392b thereof. With the second wall portion 392c which is coaxial with the first wall portion 392b and has a larger diameter than the first wall portion 392b and is formed in a front view arc shape (approximately C shape) and is erected from the front side of the base plate 392a. The third wall portion 392h, which is coaxial with the second wall portion 392c and has a diameter larger than that of the second wall portion 392c and is erected from the front side of the base plate 392a, and the base plate. A spring engaging piece 392k projecting from the front side of the 392a, an inner first engaging piece 392d1 and an inner second engaging piece 392d2, and a base plate 392a are formed inside the base plate 392a cut out in a substantially U-shape in the front view. The regulation piece 392f and the like are mainly provided.

The first wall portion 392b is a portion that accommodates (holds) the rear end portion of the coil spring SP1 arranged between the first wall portion 392b and the intermediate member 380 (see FIG. 14), and the inner diameter of the inner peripheral surface thereof is the coil spring. It is set larger than the outer diameter of SP1 and is formed (erected) at a position coaxial with the standing portion 385 (see FIG. 15) of the intermediate member 380. The inner portion of the first wall portion 392b of the base plate 392a (the portion surrounded by the first wall portion 392b) is retracted to the back side (arrow F direction side) of the other portion of the base plate 392a. .. As a result, the depth dimension of the space surrounded by the first wall portion 392b can be secured, so that the coil spring SP1 having a large free length can be adopted, and the durability and the operability can be improved. Even a coil spring SP1 having a long free length can be stably accommodated (held).

The diameter of the second wall portion 392c is set to be larger than the diameter of the first wall portion 392b, and the second wall portion 392c is formed (erected) at a position separated from the first wall portion 392b by a predetermined distance. The second wall portion 392c is a wall portion that guides the displacement of the first displacement member 396 (displacement unit 395), which will be described later, and extends along the displacement locus of the first displacement member 396. That is, the inner diameter of the second wall portion 392c is set to be the same as or slightly larger than the outer diameter of the displacement locus of the first displacement member 396. Although detailed description will be described later, the displacement unit 395 is arranged in a displaceable state between the first wall portion 392b and the second wall portion 392c facing each other.

The second wall portion 392c includes an outer first engaging piece 392e1 and an outer second engaging piece 392e2 projecting radially inward from the inner peripheral surface on the erection tip side. The outer first engaging piece 392e1 and the outer second engaging piece 392e2 are located on the displacement locus of the displacement unit 395 (positions overlapping the displacement locus in the front view), and are located along the circumferential direction of the second wall portion 392c. It is formed at positions separated by a predetermined interval.

The outer first engaging piece 392e1 and the outer second engaging piece 392e2 are protrusions that regulate the displacement unit 395 attached (mounted) to the base unit 391 toward the front side (arrow F direction side). , The facing distance from the base plate 391a is formed at a position that is the same as or slightly larger than the thickness of the displacement unit 395 (first displacement member 396) in the front-rear direction (arrow FB direction). As a result, the displacement unit 395 arranged in front of the base plate 391a can be displaceably arranged between the base plate 391a and the outer first engaging piece 392e1 and the outer second engaging piece 392e2 (FIG. 27). (C).

The outer diameter of the third wall portion 392h is set to substantially the same as the outer diameter of the second cylindrical portion 362b (see FIG. 14) of the second annular member 362, and is coaxial with the second cylindrical portion 362b. Is formed at the position of. As a result, in the assembled state of the displacement unit 300, the front side end portion (standing tip surface) of the third wall portion 392h is brought into contact with the back side end portion of the second cylindrical portion 362b. As a result, unauthorized access to the inside of the displacement unit 300 from the outside can be suppressed.

The spring engaging piece 392k is a portion for engaging one end of the coil spring SP2 for urging the displacement unit 395, which will be described later, and is projected from the front side of the base plate 392a and the protruding tip is opposite to the displacement unit 395. It is formed in an L-shape in a lateral view that is bent toward the side.

The inner first engaging piece 392d1 and the inner second engaging piece 392d2 are members that guide the displacement of the displacement unit 395, which will be described later, and regulate the detachment (removal) of the displacement unit 395. The inner first engaging piece 392d1 and the inner second engaging piece 392d2 are located inward in the radial direction of the displacement locus of the displacement unit 395 in the front view, and stand from the front side (arrow F direction side) of the base plate 392a. It is projected inward in the radial direction from the first part (standing part) to be installed and the protruding tip of the first part, and overlaps the displacement locus on the displacement locus of the displacement unit 395 (in front view, it overlaps with the displacement locus). It is provided with a second portion (protruding portion) located at the position).

The first portion (standing portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 is arranged at a position facing the inner peripheral surface of the displacement unit 395. The portion (standing portion) guides the displacement of the displacement unit 395 in the circumferential direction and regulates the displacement of the displacement unit 395 in the radial direction.

The outer peripheral surface (the surface facing the displacement unit 395) of the first portion (standing portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 is the first in front view. It is formed as a circular circumferential surface concentric with the wall portion 392b. As a result, the displacement of the displacement unit 395 in the circumferential direction can be smoothly guided.

The facing distance between the second portion (protruding portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 and the base plate 391a is the front-rear direction of the displacement unit 395 (first displacement member 396). The thickness is set to be the same as or slightly larger than the thickness (in the direction of arrow FB). As a result, the displacement unit 395 arranged in front of the base plate 391a is placed between the base plate 391a and the second portion (protruding portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2. Can be displaceably arranged (see FIG. 27 (c)).

The regulation piece 392f is a member that regulates the displacement of the displacement unit 395 to one side (defines the initial biasing position), and is between the first wall portion 392b and the second wall portion 392c in the front view. , It is formed at a position where it overlaps with the displacement locus of the displacement unit 395 in the front view.

The regulation piece 392f is an elastic piece in which the base plate 392a is cut out in a substantially U shape in front view so that the base end is connected to the base plate 392a and one end side extending from the base end is a free end. Is formed as. The direction in which one end side of the regulation piece 392f extends from the base end side is opposite to the urging direction of the coil spring SP2 (the direction of the force urging the displacement unit 395 toward the initial urging position). To. The regulation piece 392f includes a convex portion 392f1 projecting from the front surface (the surface on the arrow F direction side) on one end side thereof, and the convex portion 392f1 is brought into contact with the displacement unit 395 (second displacement member 397). Therefore, the displacement of the displacement unit 395 to one side is regulated (the displacement unit 395 is arranged at the initial biasing position).

The base plate 392a includes an upright portion 392j that protrudes from the front side (arrow F direction side) and is located between the outer peripheral surface of the first wall portion 392b and the inner peripheral surface of the second wall portion 392c. The erection portion 392j is a portion that regulates the displacement of the displacement unit 395 to the other side (defines the end of the displacement of the displacement unit 395), and is formed at a position facing the end of the displacement locus of the displacement unit 395. ..

An opening 392g is formed in the base plate 392a on the inner peripheral side of the third wall portion 392h (between the third wall portion 392h and the coil spring SP2 facing each other). The wiring (not shown) extending from the vibrating device 333 (see FIG. 18) can be routed to the back surface side (outside) of the displacement unit 300 through the opening 392 g.

The leaf spring 393 is a plate-shaped spring (leaf spring) that is elastically deformed by contact with the second displacement member 397 when the displacement unit 395 is displaced, and is at a position adjacent to the displacement locus of the displacement unit 395 (the leaf spring 393). It is arranged on the inner peripheral side of the displacement locus). Further, the leaf spring 393 includes a protrusion 393a projecting toward the base plate 392a.

The protrusion 393a is inserted into a recess 392m recessed in the base plate 392a. As a result, when the leaf spring 393 is elastically deformed by the contact with the second displacement member 397, and then the leaf spring 393 is elastically recovered with the passage of the second displacement member 397, the protrusion 393a is formed into the recess 392m. It can be brought into contact (collision) with the inner surface.

The leaf spring 393 is arranged on the base plate 392a in a state of being elastically deformed. That is, in a state where the displacement unit 395 (second displacement member 397) is not in contact with the leaf spring 393, the leaf spring 393 abuts (presses) the protrusion 393a on the inner surface of the recess 392m due to its elastic recovery force. It is said that it is in a state of being made.

Further, the leaf spring 393 is at a position where the leaf spring 393 comes into contact with the displacement unit 395 (first displacement member 396) in a state where the protrusion 393a is not in contact with the inner surface of the recess 392m (pressing is released) and the elasticity is restored. Be placed. As a result, when the protrusion 393a of the leaf spring 393 is damaged, the leaf spring 393 can be brought into contact with the first displacement member 396. Therefore, even if the protrusion 393a of the leaf spring 393 is damaged, the leaf spring 393 is elastically deformed by the contact with the second displacement member 397, and then the leaf spring 393 elastically recovers with the passage of the second displacement member 397. By doing so, the leaf spring 393 can be brought into contact (collision) with the first displacement member 396.

The detection device 394 is a sensor device that detects the position of the displacement unit 395, and includes an irradiation unit that irradiates light and a light receiving unit that is arranged so as to be able to receive the light emitted from the irradiation unit, and faces each other. The position of the displacement unit 395 is detected based on the fact that the detection piece 396f of the displacement unit 395 is arranged between them and the light is blocked.

The displacement unit 395 mainly includes a first displacement member 396 and a second displacement member 397 rotatably supported by the first displacement member 396.

The first displacement member 396 has a main body portion 396a and a main body portion 396a formed in a shape curved in an arc shape in a front view (a shape in which the ring shape is divided at two points (positions where the phases are different by 180 degrees)). The spring engaging portion 396c formed in a substantially C shape on one end side in the longitudinal direction (circumferential direction) of the main body portion 396a, and the arc center (inward in the radial direction) of the main body portion 396a on the other end side in the longitudinal direction (circumferential direction) of the main body portion 396a. ), The engaging portion 396b that is located along the inner edge of the main body portion 396a and is formed as a thinner portion than the other portions, and the outer peripheral edge of the main body portion 396a. An outer recessed portion 396e formed by cutting out a portion, a detection piece 396f projecting radially outward from the outer peripheral edge portion of the main body portion 396a, and a columnar protrusion on the back surface of the main body portion 396a. Mainly includes a shaft portion 396h to be provided.

The outer diameter of the main body portion 396a is set to be smaller than the inner diameter of the second wall portion 392c of the base plate 392a, and the inner diameter (inner diameter of the engaging portion 396d) is outside the first wall portion 392b of the base plate 392a. The diameter is set to be larger than the diameter. Thereby, the first displacement member 396 can be arranged between the first wall portion 392b and the second wall portion 392c of the base plate 392a.

Specifically, the inner diameter of the main body portion 396a (engagement portion 396d) is a virtual circle concentric with the first wall portion 392b, and is the first of the inner first engaging piece 392d1 and the inner second engaging piece 392d2. The diameter is set to be the same as or slightly larger than the diameter of the virtual circle passing through the outer peripheral surface of the portion (standing portion). As a result, the inner peripheral side of the engaging portion 396d slides on the outer peripheral surface of the first portion (standing portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2, thereby causing the first displacement. The displacement of the member 396 in the circumferential direction is guided.

Further, the back surface (the surface on the arrow B side) of the main body portion 396a is the front surface of the first surface 396a1 which is the back surface of the other end side (protruding portion 396b side) in the longitudinal direction (circumferential direction) and the front surface of the first surface 396a1. It is located on the side (arrow F direction side) and is formed from the second surface 396a2 which is the back surface of one end side (spring engaging portion 396c side) in the longitudinal direction (circumferential direction), and these first surface 396a1 and second surface 3996a2. A step in the front-rear direction (arrow FB direction) is connected by a wall surface of 396 g. The first surface 396a1 and the second surface 396a2 are formed parallel to each other.

The wall surface 396 g is formed by being bent like a crank in the rear view, and is a portion that regulates the displacement of the second displacement member 397 by engaging the second displacement member 397 with the crank portion, and is a portion of the first crank surface 396 g1. And a second crank surface 396 g2, and a contact surface 396 g3 connecting them.

The first crank surface 396g1 is located on the radial outer side (outer peripheral side) of the main body portion 396a, and the second crank surface 396g2 is located on the radial inner side (inner peripheral side) of the main body portion 396a. The second crank surface 396g2 is positioned so as to recede from the first crank surface 396g1 toward one end side (spring engaging portion 396c side) of the main body portion 396a in the longitudinal direction (circumferential direction), so that the first crank surface 396g1 and the first crank surface 396g1 are located. A step is formed between the second crank surface and the second crank surface of 396 g2, and the step is connected by the contact surface of 396 g3.

The projecting portion 396b is on the displacement locus of the engaging piece 342b of the operating unit 320, and is on the displacement direction side (traveling direction) of the engaging piece 342b when the operating unit 320 is displaced from the initial position to the terminal position. It is arranged at the position (front side).

Therefore, when the operation unit 320 (grip unit 330) is displaced from the initial position to the terminal position, the projecting portion 396b is pushed by the engaging piece 342b in the displacement direction of the engaging piece 342b. Interlocked, the displacement unit 395 is displaced from the initial bias position. As a result, the coil spring SP2 is elastically stretched, and the urging force of the coil spring SP2 gives a predetermined feeling of operation to the operation of the operation unit 320 (grip unit 330).

On the other hand, when the operation of the operation unit 320 (grip unit 330) is released at the end position (or between the start position and the end position) (for example, when the player releases his / her hand from the grip unit 330). The displacement unit 395 is displaced (returned) toward the initial biasing position by the elastic recovery force of the elastically stretched coil spring SP2. As a result, contrary to the case described above, the engaging piece 342b is pushed by the projecting portion 396b and is interlocked in the displacement direction of the projecting portion 396b, so that the operation unit 320 (grip unit 330) is in the initial position. Displaced (returned) to.

One end of the coil spring SP2 is engaged with the spring engaging piece 392k of the base plate 392a, and the other end is engaged with the spring engaging portion 396c of the displacement unit 395 (first displacement member 396). In the urging position, it is arranged in an elastically stretched state. Therefore, the displacement unit 395 (first displacement member 396) is urged toward the initial urging position by the elastic recovery force of the coil spring SP2.

The thickness of the engaging portion 396d in the front-rear direction (arrow FB direction) is set to be smaller than the thickness of the main body portion 396a in the front-rear direction, and the back surface (the surface on the arrow B direction side) is set to the main body portion 396a. It is formed by connecting with the back of the. That is, the front surface of the engaging portion 396d (the surface on the side in the direction of arrow F) is positioned so as to recede toward the back surface (side in the direction of arrow B) from the front surface of the main body portion 396a.

Here, when the first displacement member 396 (displacement unit 395) is arranged (attached) to the base member 392 (base unit 391), the engaging portion 396d is attached to the base plate 392a and the inner first engaging piece. It is arranged between 392d1 and the inner second engaging piece 392d2 facing the second portion (protruding portion). Therefore, the thickness of the engaging portion 396d is formed to be smaller (thinner) than the thickness of the main body portion 396a, so that the inner first engaging piece 392d1 and the inner second engaging piece 392d2 are projected from the base plate 392a. The installation dimensions (the height of the first portion (erection part)) can be reduced (shortened). As a result, the rigidity of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 is ensured, and the inner first engaging piece 392d1 and the inner second engaging piece 392d2 are elastically deformed or damaged. Can be suppressed. As a result, the first displacement member 396 can be stably displaced.

The engaging portion 396d is partially cut out from the edge portion on the radial inner side (first wall portion 392b side) toward the main body portion 396a side (diameter outer side) to form a substantially rectangular shape in the front view. The inner first recessed portion 396d1 and the inner second recessed portion 396d2 are provided. The inner first recessed portion 396d1 and the inner second recessed portion 396d2 are inner first when the first displacement member 396 (displacement unit 395) is arranged (attached) to the base member 392 (base unit 391). It is a notch for inserting the first engaging piece 392d1 and the second portion (protruding portion) of the inner second engaging piece 392d2 into the front side of the engaging portion 396d, and the inner first concave portion thereof. The circumferential separation dimension of the inner second engaging piece 396d1 and the inner second engaging piece 396d2 is set to be the same as the circumferential separation dimension of the inner first engaging piece 392d1 and the inner second engaging piece 392d2. ..

The outer recessed portion 396e attaches the outer second engaging piece 392e2 to the first displacement member 396 when the first displacement member 396 (displacement unit 395) is arranged (attached) to the base member 392 (base unit 391). It is a notch for inserting into the front side of the main body portion 396a. Therefore, the outer recessed portion 396e is used when the inner first engaging piece 392d1 and the inner second engaging piece 392d2 of the base member 392 are inserted into the inner first recessed portion 396d1 and the inner second recessed portion 396d2, respectively. , The outer second engaging piece 392e2 is formed at a position where it can be received (inserted).

The inner first engaging piece 392d1, the inner second engaging piece 392d2, and the outer second engaging piece 392e2 are inserted into the inner first concave portion 396d1, the inner second concave portion 396d2, and the outer concave portion 396e, respectively. When the first displacement member 396 (displacement unit 395) is arranged at a position where it is possible, the outer first engaging piece 392e1 is adjacent to the other end side of the first displacement member 396 in the longitudinal direction (circumferential direction). It is arranged (that is, at a position that does not overlap the first displacement member 396 in the front view) (see FIG. 31).

Further, the outer recessed portion 396e is formed between the inner first recessed portion 396d1 and the inner second recessed portion 396d2 in the extending direction of the main body portion 396a. As a result, the portion whose rigidity is lowered by being recessed can be dispersed in the extending direction of the main body portion 396a. As a result, it is possible to prevent the main body 396a from being damaged by concentrating the low-rigidity portion on a part of the main body 396a.

The thickness of the detection piece 396f is set to be smaller (thinner) than the thickness of the main body 396a, and the front surface of the detection piece 396f is raised to the front side (arrow F direction side) of the front surface of the first displacement member 396. Will be done. In the second wall portion 392c of the base member 392, a recessed portion 392c1 is formed (recessed) in a region overlapping the displacement locus of the detection piece 396f in the front view, and the detection piece is formed through the recessed portion 392c1. 396f is projected outward in the radial direction of the second wall portion 392c. Thereby, the interference between the second wall portion 392c and the detection piece 396f can be suppressed.

The shaft portion 396h is a columnar shaft that rotatably supports the second displacement member 397, and projects from the second surface 396a2 of the main body portion 396a toward the back surface side.

The protrusion dimension (protrusion height) of the shaft portion 396h from the second surface 396a2 is from the distance T1 in the front-rear direction from the first surface 396a1 to the rear end of the main body portion 396a (see FIG. 30C). Is also set to a small size. As a result, when the first displacement member 396 (displacement unit 395) is displaced with respect to the base member 392, it is possible to prevent the protruding tip of the shaft portion 396h from coming into contact with the base plate 392a of the base member 392. As a result, breakage of the shaft portion 396h can be suppressed. Further, the frictional resistance can be suppressed and the displacement of the first displacement member 396 can be stabilized.

The second displacement member 397 is formed in a plate shape having a substantially triangular shape in the front view, and a shaft support hole 397a is formed through the plate shape in the substantially center in the front-rear direction. In the following description, the three tip portions (corner portions) of the second displacement member 397 in the front view are referred to as a first corner portion 397b, a second corner portion 397c, and a third corner portion 397d.

The shaft support hole 397a is a hole into which the shaft portion 396h of the first displacement member 396 is inserted, and the inner diameter thereof is set to be substantially the same as or slightly larger than the outer diameter of the shaft portion 396h. As a result, the second displacement member 397 can be rotated around the shaft portion 396h.

The thickness dimension T2 (see FIG. 30C) of the second displacement member 397 in the front-rear direction (arrow FB direction) is the distance in the front-rear direction from the first surface 396a1 to the back end of the main body 396a. The dimensions are set to be smaller than T1 (see FIG. 30C) (T2> T1).

As a result, when the second displacement member 397 is arranged on the first displacement member 396, the second displacement member 397 is located between the second surface 396a2 of the first displacement member 396 and the base plate 392a of the base member 392. It is possible to suppress being pinched by. As a result, the second displacement member 397 can be reliably rotated.

The first corner portion 397b is arranged on the radial inward side of the main body portion 396a of the first displacement member 396 (center side of the arc of the main body portion 396a, side of the first wall portion 392b). When the second displacement member 397 is displaced (rotated) with respect to the first displacement member 396, the first corner portion 397b is radially inward (diameterally inward) from the radial inward inner edge of the main body portion 396a in front view. A position (first position (see FIG. 37 (b))) protruding toward the center side of the arc of the main body portion 396a and the first wall portion 392b side) and a position radially outside the first position (second position). (See FIG. 38 (c))) and is displaced. At the first position, a part of the displacement locus of the first corner portion 397b when the first displacement member 396 is displaced is set at a position where it overlaps with the leaf spring 393 of the base unit 391, and at the second position, the second position. 1 The displacement locus of the first corner portion 397b when the displacement member 396 is displaced is set at a position that does not overlap (different) with the leaf spring 393 of the base unit 391.

The second corner portion 397c is arranged on the wall surface 396 g side of the shaft support hole 397a (shaft portion 396h). In front view, the distance T3 (see FIG. 30B) from the center of the shaft support hole 397a (shaft portion 396h) to the tip of the second corner portion 397c is the shaft support hole from the first crank surface 396g1 of the wall surface 396g. The dimension is set to be smaller than the distance T4 (see FIG. 30B) to the center of 397a (shaft portion 396h) (T4> T3), and the shaft support hole 397a (shaft) is set from the second crank surface 396g2 of the wall surface 396g. The dimension is set to be larger than the distance T5 (see FIG. 30B) to the center of the portion 396h) (T3> T5).

As a result, the displacement locus of the second corner portion 397c when the second displacement member 397 is rotated about the shaft support hole 397a (shaft portion 396h) with respect to the first displacement member 396 is set to the contact surface 396g3 of the wall surface 396g. Can be set to the position where it overlaps with. As a result, the side wall of the second corner portion 397c on the first corner portion 397b side can be brought into contact with the contact surface 396g3 to regulate the rotation (displacement) of the second displacement member 397 with respect to the first displacement member 396.

Therefore, the rotation (displacement) of the second displacement member 397 can be regulated by using the wall surface 396 g formed by the step between the first surface 396a1 and the second surface 396a2 of the main body 396a. It is not necessary to form a portion that regulates the displacement of the second displacement member 397. Therefore, it is possible to prevent the displacement unit 395 from becoming large in size and to easily secure the arrangement space of the displacement unit 395.

The third corner portion 397d sandwiches the shaft support hole 397a (shaft portion 396h) and is opposite to the first corner portion 397b (the arc on the radial outer side of the main body portion 396a of the first displacement member 396 (arc of the main body portion 396a). It is arranged on the side opposite to the center of the second wall portion 392c side)).

The distance from the tip of the third corner portion 397d to the center of the shaft support hole 397a (shaft portion 396h) is from the shaft support hole 397a (shaft portion 396h) to the radial outer edge of the main body portion 396a. The size is set to be larger than the distance, and due to the rotation (displacement) of the second displacement member 397 with respect to the first displacement member 396, the position protruding from the radial outer edge of the main body 396a and the position of the main body 396a. It is displaced between the two surfaces 396a2 and the position where they overlap in the front-rear direction (arrow FB direction).

Next, a mounting method for mounting the displacement unit 395 to the base unit 391 will be described with reference to FIGS. 31 to 33. FIG. 31 is a front view of the base unit 390. 32 (a) is a partial cross-sectional drawing of the base unit 390 in the line XXXIIa-XXXIIa of FIG. 31, and FIG. 32 (b) is a partial cross-sectional drawing of the base unit 390 in the line XXXIIb-XXXIIb of FIG. 31. It is a figure. 33 (a) is a partial cross-sectional schematic diagram of the base unit 390 in line XXXIIIa-XXXIIIa of FIG. 27 (a), and FIG. 33 (b) is a schematic diagram of the base unit in line XXXIIIb-XXXIIIb of FIG. 27 (a). It is a partial cross-sectional model drawing of 390.

In addition, in FIG. 31, FIG. 32 (a) and FIG. 32 (b), the position where the displacement unit 395 is pushed toward the back side (the side in the direction of arrow B) with respect to the base unit 391 (hereinafter referred to as “positioning position”). (That is, the state before being placed in the initial urging position) is shown, and in FIGS. 33 (a) and 33 (b), the displacement unit 395 is placed in the initial urging position. Is illustrated.

As shown in FIGS. 31 and 32, in order to attach (arrange) the displacement unit 395 to the base unit 391, first, the inner first recessed portion 396d1 of the first displacement member 396 (displacement unit 395), The inner second recessed portion 396d2 and the outer recessed portion 396e form an inner first engaging piece 392d1, an inner second engaging piece 392d2, and an outer second engaging piece of the base member 392 (base unit 391). The first displacement member 396 (displacement unit 395) is arranged at a position overlapping the 392e2 in the front view, and the first displacement member 396 (displacement unit 395) is directed toward the base plate 392a of the base member 392 (base unit 391). And push it in (in the direction of arrow B).

As shown in FIGS. 32 (a) and 32 (b), the displacement unit 395 places the second displacement member 397 on the front side (in the direction of arrow F) at the protruding tip of the convex portion 392f1 of the regulation piece 392f of the base plate 392a. It is brought into contact from the side), and is pushed toward the base plate 392a while elastically deforming the regulation piece 392f toward the back surface side (arrow B direction side). As a result, the first displacement member 396 (displacement unit 395) is arranged at the positioning position.

Here, in the second displacement member 397, only the shaft portion 396h of the first displacement member 396 is inserted into the shaft support hole 397a (that is, the retaining member is not arranged), and the shaft is formed from the shaft portion 396h. It can be displaced in the direction. Therefore, when the displacement unit 395 is attached (arranged) to the base unit 391, it is necessary to assemble the second displacement member 397 so that the second displacement member 397 does not fall off from the first displacement member 396 (does not fall off from the shaft portion 396h). In this case, if the operator works while holding the second displacement member 397 with his / her fingers, the work efficiency becomes poor.

On the other hand, in the present embodiment, when the displacement unit 395 is arranged at the positioning position, the displacement unit 395 is used as the base unit while the protruding tip of the convex portion 392f1 of the regulation piece 392f is brought into contact with the second displacement member 397. It can be assembled to 391, whereby it is possible to prevent the second displacement member 397 from falling off from the shaft portion 396h of the first displacement member 396. As a result, it is not necessary for the operator to hold the second displacement member 397 with his / her fingers, and the work efficiency can be improved accordingly.

In particular, since the convex portion 392f1 of the regulation piece 392f protrudes toward the displacement unit 395 side, when the displacement unit 395 is assembled to the base unit 391, the convex portion 392f1 of the regulation piece 392f is projected from an early stage. The tip can be brought into contact with the second displacement member 397. Therefore, the workability when assembling the displacement unit 395 to the base unit 391 can be further improved.

After arranging the displacement unit 395 in the positioning position (see FIG. 32), the displacement unit 395 is then placed on the other end side in the circumferential direction of the main body portion 396a (the side on which the projecting portion 396b is formed, FIG. 33 (a). ) And the lower side of FIG. 33B) are displaced in a direction close to the upright portion 392j of the base plate 329a.

In this case, the displacement unit 395 moves while bringing the second displacement member 397 into contact with the convex portion 392f1 of the regulation piece 392f, and when the second displacement member 397 passes through the convex portion 392f1 of the regulation piece 392f, it is shown in FIG. 33. As described above, the elastically deformed regulation piece 392f is restored to the initial shape (returned to the state where it is not elastically deformed), and the displacement unit 395 is arranged at the initial biasing position.

When the displacement unit 395 is arranged at the initial biasing position, the side surface of the convex portion 392f1 of the regulation piece 392f comes into contact with the side surface of the second displacement member 397, so that the displacement unit 395 is positioned (shown in FIG. 32). Displacement to position) is regulated.

At the initial urging position, as described above, the coil spring SP2 is displaced toward the positioning position by its elastic recovery force (the side surface of the second displacement member 397 is a convex portion of the regulation piece 392f). The direction of contact with the side surface of 392f1 (upper side of FIGS. 33 (a) and 33 (b)) is urged.

When the displacement unit 395 is arranged at the initial biasing position, the inner first recessed portion 396d1, the inner second recessed portion 396d2, and the outer recessed portion 396e of the first displacement member 396 (displacement unit 395) are arranged. Is a position (different) that does not overlap with each of the inner first engaging piece 392d1, the inner second engaging piece 392d2, and the outer second engaging piece 392e2 of the base member 392 (base unit 391) in the front view. Position).

As a result, the engaging portion 396d of the displacement unit 395 is arranged between the inner first engaging piece 392d1 and the second portion (protruding portion) of the inner second engaging piece 392d2 and the base plate 392a. Will be done. Further, the main body portion 396a of the displacement unit 395 is arranged between the outer first engaging piece 392e1 and the outer second engaging piece 392e2 and the base plate 392a.

That is, in the front view, the second portion (protruding portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 is inside the engaging portion 396d of the displacement unit 395 (first displacement member 396). In the non-formed region of the first recessed portion 396d1 and the inner second recessed portion 396d2, the outer first engaging piece 392e1 and the outer second engaging piece 392e2 are located in the main body of the displacement unit 395 (first displacement member 396). It is arranged at a position overlapping each other in the non-formed region of the outer recessed portion 396e in the 396a.

As a result, the displacement of the displacement unit 395 (first displacement member 396) with respect to the base unit 391 toward the front side (in the direction of arrow F) is such that the inner first engaging piece 392d1 and the inner second engaging piece 392d2 are displaced by the displacement unit 395 (in the direction of arrow F). The outer first engaging piece 392e1 and the outer second engaging piece 392e2 are engaged with the engaging portion 396d of the first displacement member 396), respectively, with the main body portion 396a of the displacement unit 395 (first displacement member 396). By that, it is regulated. As a result, the displacement unit 395 is held by the base unit 391 in a state where only the displacement in the circumferential direction is allowed.

Here, for example, in a structure in which the inner first concave portion 396d1, the inner second concave portion 396d2, and the outer concave portion 396e are not formed on the first displacement member 396, the displacement unit 395 is engaged with the inner first first engagement. Push the regulation piece 392f into the base unit 390 (base plate 392a) at a position where the piece 392d1, the inner second engaging piece 392d2, the outer first engaging piece 392e1 and the outer second engaging piece 392e2 do not overlap in front view. It needs to be elastically deformed (see FIG. 32). Therefore, the amount of displacement of the displacement unit 395 from the pushed-in position to the initial urging position becomes large, and the workability of the assembling work is lowered. Further, it is necessary to secure a space for pushing the displacement unit 395 into the base unit 390 (base plate 392a) by that amount, and it becomes impossible to erect ribs or form other parts. Space efficiency is reduced.

On the other hand, in the present embodiment, the inner first recessed portion 396d1, the inner second recessed portion 396d2, and the outer recessed portion 396e are formed on the first displacement member 396, and these recessed portions 396d1, 396d2, 396e are formed. The inner first engaging piece 392d1, the inner second engaging piece 392d2, and the outer second engaging piece 392e2 of the base member 392 are inserted into the base member 392. That is, the overlap margin between the displacement unit 395 and the displacement locus of the displacement unit 395 at the position where the displacement unit 395 is pushed into the base unit 390 (base plate 392a) can be increased. As a result, the amount of displacement of the displacement unit 395 from the pushed position (positioning position) to the initial biasing position can be reduced, and the workability of the assembling work can be improved. Further, the space reserved in the base unit 390 (base plate 392a) for pushing the displacement unit 395 can be reduced by that amount, so that the space efficiency can be improved (the space for erecting ribs and forming other parts). Can be secured).

Further, the second surface 396a2 of the main body portion 396a is arranged on the front side of the regulation piece 392f, and the regulation piece 392f is invisible in the front view. As a result, it is possible to make it difficult to access the regulation piece 392f from the front side of the base unit 391, and it is possible to prevent the regulation of the displacement unit 395 by the regulation piece 392f from being illegally released.

The distance from the contact position between the convex portion 392f1 of the regulation piece 392f and the second displacement member 397 in the extending direction of the main body portion 396a to the tip end portion (spring engaging portion 396c side end portion) of the second surface 396a2 is , The first displacement member 396 (displacement unit 395) is set to be larger than the displaceable distance. As a result, even after the first displacement member (displacement unit 395) is displaced, it is possible to make it difficult to access the regulation piece 392f from the front side of the base unit 391.

Further, the convex portion 392f1 of the regulation piece 392f is projected into the space formed by the step between the first surface 396a1 and the second surface 396a2 of the main body portion 396a. As a result, it is possible to prevent the base unit 391 from becoming thicker in the front-rear direction when the displacement unit 395 is arranged on the base member 392.

Next, the displacement of the displacement unit 395 will be described with reference to FIGS. 34 and 35. FIG. 34 is a perspective exploded view of the displacement unit 300, and FIGS. 35 (a) to 35 (c) are front views of the base unit 390.

In FIG. 34, the displacement unit 300 is disassembled between the base unit 390 and the intermediate member 380, and the coil spring SP1 disposed between the base unit 390 and the intermediate member 380 is not shown. Further, in FIGS. 35 (a) to 35 (c), the outer shape of the engaging piece 342b of the back surface member 342 of the operation unit 320 is shown by a chain line.

FIG. 35 (a) shows a state in which the operation unit 320 is arranged at the initial position and the displacement unit 395 is arranged at the initial biasing position. In FIG. 35 (c), the operation unit 320 is arranged at the terminal position. , The state in which the displacement unit 395 is arranged at the position where the displacement unit 395 is maximally displaced from the initial urging position (hereinafter referred to as “termination interlocking position”) is shown, and in FIG. 35 (b), the operation unit 320 is displaced from the initial position. , The state in which the engaging piece 342b of the operation unit 320 is arranged at a position where it abuts on the displacement unit 395 (hereinafter referred to as “contact position”) is shown.

As shown in FIGS. 34 and 35A, the tip of the engaging piece 342b of the back surface member 342 is the side surface (inside) of the projecting portion 396b of the first displacement member 396 in the assembled state of the displacement unit 300. It is arranged at a position facing the first recessed portion (side surface connected to 396d1). In the state where the operation unit 320 is arranged at the initial position, the engaging piece 342b is arranged at a predetermined distance from the side surface of the projecting portion 396b.

As shown in FIG. 35 (b), when the operation unit 320 is displaced with respect to the guide unit 350, the engaging piece 342b is rotated (displaced) in the same direction as the operation unit 320. As a result, the engaging piece 342b is brought into contact with the side surface of the projecting portion 396b.

The position of the operation unit 320 when the projecting portion 396b is brought into contact with the engaging piece 342b is set between the initial position and the first position. As a result, as described above, when the player pushes the operation unit 320 from the initial position, the guided member 344 comes into contact with the fourth guide surface 351d (see FIG. 26B) of the second guide region. Prior, the engaging piece 342b can be brought into contact with the projecting portion 396b. Therefore, before the guided member 344 reaches the first position (the guided member 344 reaches the fourth guide surface 351d), a resistance force (a urging force of the coil spring SP2) opposed to the pushing direction of the gripping unit 330 is applied. be able to. As a result, the impact when the guided member 344 comes into contact with the fourth guide surface 351d can be suppressed, and damage to the guided member 344 and the fourth guide surface 351d can be suppressed.

As shown in FIGS. 35 (b) and 35 (c), after the engaging piece 342b is brought into contact with the projecting portion 396b, the engaging piece 342b is displaced while the operating unit 320 is displaced to the terminal position. It is rotated (displaced) in the same direction as the operation unit 320. That is, since the contact between the engaging piece 342b and the projecting portion 396b is maintained, the urging force (elastic recovery force) of the coil spring SP2 can continue to act as an operation feeling when operating the operation unit 320. it can.

It should be noted that the operation unit 320 stands up from the base plate 392a at a position adjacent to the projecting portion 396b when it is arranged at the terminal position (on the front side in the traveling direction of the projecting portion 396b when traveling toward the terminal position). The erection part 392j to be installed is arranged. As a result, when the coil spring SP2 or the guided member 344 of the displacement unit 395 is damaged, the displacement unit 395 is brought into contact with the standing portion 392j, and the displacement unit 395 is displaced beyond the end interlocking position. It can be suppressed.

A leaf spring 393 disposed on the base unit 391 is arranged on the displacement locus of the second displacement member 397 of the displacement unit 395. Therefore, when the displacement unit 395 is displaced from the initial biasing position to the terminal interlocking position, the second displacement member of the displacement unit 395 is in the middle of the displacement (immediately before reaching the terminal interlocking position in the present embodiment). The 397 comes into contact with the leaf spring 393 to elastically deform the leaf spring 393. The details of the leaf spring 393 will be described later.

As described above, the displacement unit 395 is urged toward the initial urging position side by the urging force (elastic recovery force) of the coil spring SP2. Therefore, when the operation of the operation unit 320 is released (for example, when the player releases the grip unit 330), the displacement unit 395 is displaced toward the initial urging position and is displaced. The engaging piece 342b is pushed back by the protruding portion 396b of the unit 395, and as a result, the operating unit 320 is returned to the initial position.

Next, the leaf spring 393 will be described with reference to FIGS. 36 to 38. 36 is a front view of the base unit 390, and FIGS. 37 and 38 are partially enlarged front views of the base unit 390.

In FIGS. 36 to 38, the first displacement member 396 is shown transparently, and the outer shape of the first displacement member 396 is shown by a two-dot chain line. Further, in FIG. 36, a state in which the displacement unit 395 is arranged at the initial biasing position is shown.

37 (a) to 38 (d) show the transition states when the displacement unit 395 is displaced from the initial biasing position to the terminal interlocking position, and FIGS. 38 (a) to 38 (d) show the transition states. , The transition state when the displacement unit 395 is displaced from the terminal interlocking position to the initial biasing position is shown in order.

As shown in FIG. 36, the leaf spring 393 has a free end on the other end side opposite to the one end side fixed to the base member 392, and the plate surface faces the displacement unit 395 (first displacement member 396). Is arranged with. Therefore, the leaf spring 393 can be elastically deformed in a direction in which the other end side is brought close to or separated from the displacement unit 395. The leaf spring 393 is arranged so that one end side is closer to the coil spring SP2 than the other end side.

The leaf spring 393 is formed by being bent in a substantially triangular shape in front view between one end side and the other end side, and includes a protruding portion that projects the bent tip toward the displacement unit 395 (first displacement member 396). At least a part of the bending tip side of the protruding portion of the leaf spring 393 is arranged at a position overlapping the displacement locus of the second displacement member 397 in the front view, and when the displacement unit 395 is displaced, as will be described later. , The side surface of the protruding portion is brought into contact with (pressing) the second displacement member 397, whereby the leaf spring 393 is elastically deformed.

The leaf spring 393 includes a protrusion 393a projecting from the edge on the other end side toward the back surface side (direction of arrow B). The protrusion 393a is inserted inside the recess 392m of the base plate 392a, and in a state where the leaf spring 393 is arranged at the initial position (a state in which the leaf spring 393 is unloaded), the protrusion 393a hits the inner surface of the recess 392m. Be touched.

As shown in FIGS. 36 and 37 (a), when the displacement unit 395 is arranged at the initial urging position, the urging force of the coil spring SP2 causes the second side wall 397f (first angle) of the second displacement member 397. The side surface connecting the portion 397b and the third corner portion 397d) is in contact with the regulation piece 392f (convex portion 392f1) of the base plate 392a. As a result, the second displacement member 397 is arranged in a posture in which the tip end portion of the first corner portion 397b is projected inward in the radial direction of the first displacement member 396 (main body portion 396a) in the front view.

When the displacement unit 395 is displaced from the initial biasing position toward the terminal interlocking position by the operation of the operation unit 320, as shown in FIGS. 37 (b) and 37 (c), the second displacement member 397 is the second. The portion of one side wall 397e (the side surface connecting the first corner portion 397b and the second corner portion 397c) on the first corner portion 397b side abuts on the leaf spring 393 (side surface of the protruding portion), and the leaf spring The 393 is elastically deformed.

In this case, the second displacement member 397 is elastically deformed because the second corner portion 397c (the first side wall 397e on the second corner portion 397c side) is in contact with the contact surface 396g3 of the first displacement member 396. The second displacement member 397 is restricted from being rotated about the shaft support hole 397a (shaft portion 396h) by receiving the elastic recovery force of the leaf spring 393. That is, the amount of protrusion of the tip of the first corner portion 397b inward in the radial direction of the first displacement member 396 (main body portion 396a) does not change.

Therefore, when the displacement unit 395 is displaced to the terminal interlocking position, the first corner portion 397b elastically deforms the leaf spring 393 to the opposite side to the displacement unit 395 by pressing the side surface of the protruding portion of the leaf spring 393. Then, as shown in FIG. 37 (d), when the first corner portion 397b gets over the protruding portion (protruding tip) of the leaf spring 393, the elastic deformation of the leaf spring 393 is recovered (the leaf spring 393 is in a no-load state). (Returned to the shape in). The amount of elastic deformation of the leaf spring 393 is maximized when the first corner portion 397b of the second displacement member 397 gets over the protruding portion (protruding tip) of the leaf spring 393.

In this case, the protrusion 393a is separated from the inner surface of the recess 392m of the base plate 392a due to the elastic deformation of the leaf spring 393, and when the elastic deformation of the leaf spring 393 is recovered, the protrusion 393a abuts on the inner surface of the recess 392m ( Collision). As a result, when the operation unit 320 (displacement unit 395) is displaced to the terminal position (terminal interlocking position), an impact due to contact (collision) between the protrusion 393a and the recess 392m can be generated. As a result, the vibration can be transmitted to the hand of the player who operates (grips) the operation unit 320 (grip unit 330), and the player can easily recognize that the operation unit 320 has been displaced to the terminal position.

Further, when the operation unit 320 is operated to the terminal position, the vibration can be transmitted to the player's hand, so that the operation feeling can be improved.

Similarly, when the first corner portion 397b of the second displacement member 397 gets over the protruding portion (protruding tip) of the leaf spring 393, the player who operates the operation unit 320 before and after the overcoming operation receives from the leaf spring 393. The reaction force (elastic recovery force) can be reversed. That is, the reaction force from the leaf spring 393 is gradually increased until the first corner portion 397b reaches the protruding tip (top) of the protruding portion of the leaf spring 393, and the maximum reaction force is generated when overcoming the reaction force. On the other hand, the reaction force can be sharply reduced immediately after overcoming it. As a result, when operating the operation unit 320, a click feeling can be formed and the operation feeling can be improved. In particular, when this click feeling is formed, the vibration due to the collision of the protrusion 393a with the recess 392m can be transmitted, so that the operation feeling can be further improved by these combinations.

As shown in FIGS. 38 (a) to 38 (d), when the displacement unit 395 is displaced from the terminal interlocking position to the initial biasing position, the second side wall 397f (first corner portion) of the second displacement member 397 The portion of the side surface connecting the 397b and the third corner portion 397d on the first corner portion 397b side is brought into contact with the side surface of the protruding portion of the leaf spring 393.

In this case, as the displacement unit 395 is displaced toward the initial biasing position, the second displacement member 397 first displaces the second corner portion 397c (the first side wall 397e on the second corner portion 397c side). The displacement member 396 is rotated in the rotation direction (counterclockwise in FIGS. 38 (a) to 38 (c)) separated from the contact surface 396 g3. As a result, the first corner portion 397b of the second displacement member 397 is retracted in the direction away from the leaf spring 393. As a result, the leaf spring 393 is hardly elastically deformed. Therefore, the displacement unit 395 (operation unit 320) can be smoothly returned to the initial biasing position (initial position).

When the displacement unit 395 reaches the initial biasing position, as shown in FIGS. 38 (c) and 38 (d), the first corner portion 397b passes through the protruding portion (bending tip) of the leaf spring 393. After that, the portion of the second side wall 397f (the side surface connecting the first corner portion 397b and the third corner portion 397d) of the second displacement member 397 on the third corner portion 397d side is the regulation piece 392f (convex portion 392f1). ). As a result, the rotation direction of the second displacement member 397 to bring the second corner portion 397c (the first side wall 397e on the second corner portion 397c side) into contact with the contact surface 396g3 of the first displacement member 396 (FIG. 38 (d)). ), The first corner portion 397b is advanced (protruded) in a direction close to the leaf spring 393. That is, the second displacement member 397 can be returned to the initial position. As a result, as described above, it is possible to reliably form the transmission of vibration and the click feeling when the displacement unit 395 is displaced from the initial biasing position toward the terminal interlocking position.

Since the displacement (return) of the displacement unit 395 from the terminal interlocking position to the initial urging position is performed by the elastic recovery force of the coil spring SP2, when the initial urging position is reached, the second displacement member 397 (return) The second side wall 397f) is brought into contact with (collision) with the regulation piece 392f (convex portion 392f1). As described above, in the present embodiment, since the target to be abutted (collised) with the second displacement member 397 (second side wall 397f) is the regulation piece 392f (convex portion 392f1), the regulation piece 392f (convex portion) 392f1) can be elastically deformed to alleviate the impact at the time of contact (collision). As a result, damage (bending or breakage) of the shaft portion 396h that pivotally supports the second displacement member 397 can be suppressed.

Next, the displacement unit 2395 in the second embodiment will be described with reference to FIGS. 39 and 40. In the first embodiment, the case where the displacement unit 395 is rotationally displaced has been described, but in the second embodiment, the case where the displacement unit 2395 is linearly displaced will be described. The same parts as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

39 (a) to 39 (c) are front views of the base unit 2390 in the second embodiment, and FIGS. 40 (a) to 40 (c) are the XLa-XLa lines of FIG. 39 (a). It is sectional drawing of the base unit 2390 in the above.

Note that FIG. 39 (a) shows a state in which the operation unit 320 (see FIG. 16 (a)) is arranged at the initial position and the displacement unit 2395 is arranged at the initial bias position. FIG. 39 (c) shows the state. , The state in which the operation unit 320 is arranged at the terminal position and the displacement unit 2395 is arranged at the terminal interlocking position is illustrated. In FIG. 39 (b), the operation unit 320 is displaced from the initial position and the operation unit 320 is engaged. The state in which the piece 342b is arranged at the contact position where it abuts on the displacement unit 2395 (protruding portion 396b) is shown. Further, in FIGS. 39 and 40, only the outer shape of the engaging piece 342b of the operation unit 320 is shown by a chain line. Further, FIG. 40 (a) is shown in FIG. 39 (a), FIG. 40 (b) is shown in FIG. 39 (b), and FIG. 40 (c) is shown in FIG. 39 (c).

As shown in FIGS. 39 and 40, the base unit 2390 in the second embodiment has a base unit 2391, a displacement unit 2395 disposed on the base unit 2391, and a displacement unit 2395 with respect to the base unit 2391. It mainly includes a coil spring SP2 and a force coil spring SP2.

The base unit 2391 is a base member 2392 arranged inside the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and a leaf spring arranged on the base member 2392. It mainly includes a 393 and a detection device 394 disposed on the base member 2392.

The base member 2392 includes a base plate 2392a, a first wall portion 392b that is erected from the base plate 2392a toward the front side (the side in the direction of arrow F) and is formed in a semicircular arc shape in the front view, and the first wall portion thereof. The second wall portion 2392c erected radially outside the first wall portion 392b with respect to the 392b, the third wall portion 2392h erected from the base plate 2392a toward the front side, and the front side from the base plate 2392a. Mainly, the spring engaging piece 2392k projecting toward the direction, the inner first engaging piece 2392d1, and the regulating piece 2392f formed inside the base plate 2392a cut out in a substantially U-shape in the front view. Prepare for.

The base plate 2392a in the second embodiment is formed in a vertically long rectangular shape when viewed from the front. Further, the annular member 310 on which the base member 2392 is arranged has an inner peripheral edge shape larger than the outer shape (outer peripheral edge shape) of the base plate 2392a.

The second wall portion 2392c is a wall portion that guides the displacement of the displacement unit 2395, which will be described later, is formed at a position adjacent to the displacement unit 2395 in the front view, and is formed in a straight line in the front view along the displacement locus of the displacement unit 2395. It will be extended.

Further, an outer first engaging piece 2392e1 and an outer second engaging piece 2392e2 are projected from the standing tip side (front side) toward the displacement unit 2395 side on the second wall portion 2392c. The outer first engaging piece 2392e1 and the outer second engaging piece 2392e2 are portions for restricting the displacement unit 2395 arranged in the base unit 2391 from falling off toward the front side (arrow F direction), respectively. It is formed at a position separated by a predetermined distance along the extending direction of the second wall portion 2392c (displacement direction of the displacement unit 2395).

The outer first engaging piece 2392e1 and the outer second engaging piece 2392e2 are portions for restricting the displacement unit 2395 arranged in the base unit 2391 from falling off toward the front side (arrow F direction), and are the base unit. The displacement unit 2395 (first displacement member 2396) arranged in 2391 is formed at a position separated from the base plate 2392a by the thickness in the front-rear direction (arrow FB direction). Thereby, the displacement unit 2395 (first displacement member 2396) can be arranged in a state of being sandwiched between the base plate 2392a and the outer first engaging piece 2392e1 and the outer second engaging piece 2392e2 (FIG. 40 (a). )reference).

The third wall portion 2392h is formed along the edge portion of the base plate 2392a, and the front view shape on the upper side (upper side in FIG. 39) is curved into a semicircular shape coaxial with the first wall portion 392b. Further, the second cylindrical portion 362b (not shown) of the second annular member 362 to which the base unit 2390 is fastened is formed so that the outer shape in the rear view is the same as the outer shape of the third wall portion 2392h. As a result, when the base unit 2390 is fastened to the operation unit 320, the back side of the second cylindrical portion 362b and the third wall portion 2392h are brought into contact with each other, and the inside of the second cylindrical portion 362b is brought into contact with the inside of the second cylindrical portion 362b from the outside of the slot machine 10. It is possible to prevent an illegal member from being inserted into the.

The spring engaging piece 2392k is a portion for engaging one end of the coil spring SP2 for urging the displacement unit 2395, is projected from the front side of the base plate 2392a, and is directed toward the side opposite to the displacement direction of the displacement unit 2395. It is formed in an L-shape when viewed from the side with a bent tip.

The inner first engaging piece 2392d1 is a member that prevents the displacement unit 2395 from falling off (removing) toward the front side (arrow F direction), and is located at a position along the displacement locus of the displacement unit 2395 (a position that overlaps in the front view). It is formed. The inner first engaging piece 2392d1 has a first portion (standing portion) erected from the front side (arrow F direction side) of the base plate 2392a and a second wall from the protruding tip of the first portion. A second portion (protruding portion) that is projected toward the portion 2392c and is located on the displacement locus of the displacement unit 2395 (a position that overlaps the displacement locus in the front view) is provided. As a result, the displacement unit 2395 arranged in front of the base plate 2392a can be arranged in a state of being sandwiched between the base plate 2392a and the second portion (protruding portion) of the inner first engaging piece 2392d1 (protruding portion). (See FIG. 40 (a)).

The restricting piece 2392f is a portion that regulates the displacement of the displacement unit 2395 to one side (initial urging position side), and is formed on the back side of the displacement unit 2395 arranged along the second wall portion 2392c. It is formed at a position where it overlaps with the displacement locus of the displacement unit 2395 in front view.

The regulation piece 2392f is formed by cutting out the base plate 2392a in a substantially U shape when viewed from the front, and is formed as an elastic piece having one end connected to the base plate 2392a and the other end having a free end. The other end side of the regulation piece 2392f is provided with a convex portion 392f1 projecting toward the front side (displacement unit 2395 side, arrow F direction side), and the displacement unit 2395 is brought into contact with the convex portion 392f1. Therefore, the displacement of the displacement unit 2395 to one side is regulated.

The displacement unit 2395 mainly includes a first displacement member 2396 that is formed in a straight line (a substantially rectangular shape in the front view) in the front view, and a second displacement member 397 that is pivotally supported by the first displacement member 2396. Prepare for.

The first displacement member 2396 includes a main body portion 2396a extending in a straight line, a spring engaging portion 396c formed on one end side of the main body portion 2396a in the longitudinal direction in a substantially C shape in a front view, and a main body portion 2396a. A protruding portion 396b projecting from the side surface on the other end side in the longitudinal direction toward the first wall portion 392b of the base plate 2392a, and a engaging portion projecting from the side surface of the main body portion 2396a opposite to the second wall portion 2392c. Detection that the joint portion 2396d, the outer recessed portion 2396e formed by cutting out the edge portion of the main body portion 2396a on the second wall portion 2392c side, and the main body portion 2396a projecting from the side surface on the second wall portion 2392c side. It mainly includes a piece 396f and a shaft portion 396h that protrudes from the back surface of the main body portion 2396a and is formed in a columnar shape.

The length of the main body portion 2396a in the longitudinal direction (direction extending in a straight line shape) is set to be shorter than the extension dimension of the second wall portion 2392c. Further, the displacement amount of the displacement unit 2395 is set to a dimension (displacement amount) smaller than the difference between the extension dimension of the second wall portion 2392c and the longitudinal length of the main body portion 2396a. As a result, when the first displacement member 2396 (displacement unit 2395) is displaced along the second wall portion 2392c, the main body portion 2396a can always be arranged at a position adjacent to the second wall portion 2392c.

Further, the main body portion 2396a has a first surface 396a1 forming a back surface on the other end side in the longitudinal direction and a second surface 396a2 located on the front side of the first surface 396a1 and forming a back surface on one end side in the longitudinal direction. , 396 g of a wall surface connecting the first surface 396a1 and the second surface 396a2 in the front-rear direction (arrow FB direction).

In the second embodiment, the spring engaging piece 2392k of the base plate 2392a to which the coil spring SP2 is engaged is formed on an extension of the displacement locus of the displacement unit 2395. The coil spring SP2 is engaged with the spring engaging piece 2392k at a position in a posture along the displacement direction of the displacement unit 2395 (longitudinal direction of the first displacement member 2396), and is arranged in a state of being elastically pulled and deformed. Will be done. Therefore, the coil spring SP2 can apply an urging force (elastic recovery force) in the direction toward the initial urging position to the displacement unit 2395.

The thickness dimension of the engaging portion 2396d in the front-rear direction (arrow FB direction) is set to be smaller than the thickness dimension of the main body portion 2396a, and is formed at a position connected to the back surface of the main body portion 2396a. That is, the front surface of the engaging portion 2396d is located on the back surface side of the front surface of the main body portion 2396a.

Further, the engaging portion 2396d is a second portion (protruding) of the base plate 2392a and the inner first engaging piece 2392d1 in a state where the first displacement member 2396 is arranged on the base member 2392 (base unit 2391). It is a part arranged between facing the part). Therefore, since the thickness dimension of the engaging portion 2396d is set to be smaller (thinner) than the thickness dimension of the main body portion 2396a, the protrusion distance (first portion) of the inner first engaging piece 2392d1 from the base plate 2392a. The height of the (standing part) can be shortened. As a result, the rigidity of the inner first engaging piece 2392d1 can be ensured, and the reaction force applied from the first displacement member 2396 (displacement unit 2395) can prevent the inner first engaging piece 2392d1 from being damaged.

The engaging portion 2396d includes an inner first recessed portion 2396d1 formed by partially cutting out an outer edge along the longitudinal direction of the main body portion 2396a. When the first displacement member 2396 is arranged on the base member 2392 (base unit 2391), the inner first recessed portion 2396d1 engages the second portion (protruding portion) of the inner first engaging piece 2392d1. It is a notch to be inserted into the front side of the 2396d, and the notch is formed with an inner edge shape larger than the front view shape of the bent portion of the inner first engaging piece 2392d1.

When the first displacement member 2396 is arranged on the base member 2392 (base unit 2391), the outer recessed portion 2396e inserts the outer second engaging piece 2392e2 into the front side of the main body portion 2396a of the first displacement member 2396. It is a notch, and at the outer edge along the longitudinal direction of the main body portion 2396a opposite to the inner first concave portion 2396d1, a notch is formed with an inner edge shape larger than the front view shape of the outer second engaging piece 2392e2. ..

The distance between the outer recessed portion 2396e and the inner first recessed portion 2396d1 in the extending direction (longitudinal direction) of the main body portion 2396a is the outer second engaging piece 2392e2 in the displacement direction of the displacement unit 2395. , It is set to be substantially the same as the separation distance of the inner first engaging piece 2392d1.

As a result, as in the case of the first embodiment, the inner first engaging piece 2392d1 of the base member 2392 and the outer second engaging piece 392e2 are placed on the inner first recessed portion 2396d1 of the first displacement member 2396. The first displacement member 2396 (displacement unit 2395) can be arranged in the base member 2392 (base unit 2391) by inserting the first displacement member 2396 (displacement unit 2395) into the outer recessed portion 396e, respectively.

In the base unit 2390, as shown in FIGS. 39 (a) and 40 (a), the tip of the engaging piece 342b of the operation unit 320 (see FIG. 15) projects from the main body 2396a of the first displacement member 2396. When the operation unit 320 is arranged in the initial position in the area surrounded by the portion 396b, the projecting portion 396b and the tip of the engaging piece 342b are arranged at a predetermined interval.

When the operating unit 320 (see FIG. 15) is operated by the player from the initial position and the engaging piece 342b of the operating unit 320 is rotated (displaced), as shown in FIGS. 39 (b) and 40 (b). The engaging piece 342b is brought into contact with the projecting portion 396b of the displacement unit 2395.

In the second embodiment, as in the case of the first embodiment, the position where the engaging piece 342b comes into contact with the projecting portion 396b is such that the operation unit 320 is displaced between the initial position and the first position. It is considered to be a position. As a result, when the player pushes the operation unit 320 from the initial position, the guided member 344 engages before coming into contact with the fourth guide surface 351d (see FIG. 26B) in the second guide region. The piece 342b can be brought into contact with the projecting portion 396b.

Therefore, before the guided member 344 reaches the first position (the guided member 344 reaches the fourth guide surface 351d), a resistance force (a urging force of the coil spring SP2) opposed to the pushing direction of the gripping unit 330 is applied. be able to. As a result, the impact when the guided member 344 comes into contact with the fourth guide surface 351d can be suppressed, and damage to the guided member 344 and the fourth guide surface 351d can be suppressed.

When the operation unit 320 is displaced from the contact position to the end position (that is, the operation unit 320 is further rotationally displaced from the position where the engaging piece 342b abuts on the projecting portion 396b), FIGS. 39 (c) and FIG. As shown in 40 (c), the displacement unit 2395 (first displacement member 2396) is linearly displaced (linearly moved) along its longitudinal direction with the displacement of the engaging piece 342b. As a result, the displacement unit 2395 is placed at the displacement end position.

In this case, as in the case of the first embodiment, after the engaging piece 342b is brought into contact with the projecting portion 396b, the engaging piece 342b stays in the operating unit 320 while the operating unit 320 is displaced to the terminal position. Is displaced in the same direction as. That is, since the contact between the engaging piece 342b and the projecting portion 396b is maintained, the urging force (elastic recovery force) of the coil spring SP2 can continue to act as an operation feeling when operating the operation unit 320. it can.

A leaf spring 393 disposed on the base unit 2391 is arranged on the displacement locus of the second displacement member 397 of the displacement unit 2395. Therefore, when the displacement unit 2395 is displaced from the initial biasing position to the terminal interlocking position, the displacement unit 2395 is in the middle of the displacement (immediately before reaching the terminal interlocking position as in the case of the first embodiment). The second displacement member 397 of the above can be brought into contact with the leaf spring 393 to elastically deform the leaf spring 393. Since the elastic deformation of the leaf spring 393 due to the displacement of the displacement unit 2395 is the same as in the case of the first embodiment, the description thereof will be omitted.

As described above, the displacement unit 2395 is urged toward the initial urging position side by the urging force (elastic recovery force) of the coil spring SP2. Therefore, when the operation of the operation unit 320 is released (for example, when the player releases the grip unit 330), the displacement unit 2395 is displaced toward the initial urging position and is displaced. The engaging piece 342b is pushed back by the protruding portion 396b of the unit 395, and as a result, the operating unit 320 is returned to the initial position.

As described above, in the second embodiment, the engaging piece 342b of the operation unit 320 that is rotationally displaced is brought into contact with the first displacement member 2396 (displacement unit 2395) that is linearly displaced (linearly moved). Since the first displacement member 2396 is displaced (the engaging piece 342b slides on the projecting portion 396b), it is displaced with respect to the circumferential displacement distance of the engaging piece 342b when the operating unit 320 is displaced. The displacement distance of the unit 2395 in the linear direction can be reduced. As a result, the force required to operate the operation unit 320 when the displacement unit 2395 is displaced can be reduced. As a result, the player can easily operate the operation unit 320. Further, since the space required for arranging the displacement unit 2395 can be reduced, the size of the base unit 2390 can be reduced.

The contact surface of the projecting portion 396b to which the engaging piece 342b is in contact is formed as a flat surface having a linear front view, and the displacement direction of the displacement unit 2395 (longitudinal length of the first displacement member 2396) in the front view. It is formed at an angle with respect to the direction). The inclination direction of the contact surface of the projecting portion 396b is set to be inclined in a direction away from the engaging piece 342b toward the projecting tip side (opposite side of the main body portion 396a) of the projecting portion 396b. Further, the side surface of the engaging piece 342b that abuts on the projecting portion 396b is formed by being curved in an arc shape that is convex toward the projecting portion 396b in the front view. As a result, even when the engaging piece 342b is displaced in the rotational direction and the projecting portion 396b is displaced in the linear direction, the engaging piece 432b can be easily slid with respect to the projecting portion 396b. Displacement can be stabilized.

Here, in the second embodiment, in a state where the operation unit 320 (displacement unit 2395) is arranged at the end position (end interlocking position), the engaging piece 342b comes into contact with the projecting portion 396b, and the operation unit 320 (engagement). The direction connecting the center of rotation of the combined piece 342b) and the engaging piece 342b is parallel to the direction of the linear displacement (linear motion) of the displacement unit 2395 in front view, and the engaging piece 342b of the projecting portion 396b The surface to be abutted may be configured to be orthogonal to the direction of the linear displacement (linear motion) of the displacement unit 2395 in the front view. That is, the rotational direction of the engaging piece 342b and the linear displacement direction of the displacement unit 2395 may be orthogonal to each other. According to this, the player can set the second guide surface 351b (see FIG. 22D) of the guide unit 350 in a direction orthogonal to the pushing direction (arrow FB direction) of the operation unit 320. The operation unit 320 can be maintained at the terminal position after the operation unit 320 is rotationally displaced to the terminal position. That is, it is possible to prevent the operation unit 320 from returning to the initial position by the urging force of the coil spring SP1 (see FIG. 14) and the coil spring SP2. As a result, it is possible to improve the interest of the player by giving a variation to the operation method of the operation unit 320.

Next, the base unit 3390 according to the third embodiment will be described with reference to FIG. 41. In the first embodiment, the inner first engaging piece 392d1 and the inner first engaging piece 392d1 of the base member 392 are attached to the inner first recessed portion 396d1, the inner second recessed portion 396d2 and the outer recessed portion 396e of the first displacement member 396. 2 At a position (phase) where the engaging piece 392d2 and the outer second engaging piece 392e2 can be inserted, the displacement unit 395 is elastically deformed to the back side (arrow B direction) with respect to the base member 392 while elastically deforming the regulation piece 392f. The case where the displacement unit 395 is arranged on the base unit 391 by rotating the displacement unit 395 (sliding displacement along the second wall portion 392c) after pushing in has been described, but in the third embodiment, the displacement unit By simply pushing the 3395 toward the back side (in the direction of arrow B) with respect to the base member 3392 (that is, the inner first locking portion 3392d3, the inner second locking portion 3392d4, the outer first locking portion 3392e3, and the outer second displacement). The displacement unit 3395 is arranged in the base unit 3391 (only by elastically deforming the stop 3392e4). The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

41 (a) is a front view of the base unit 3390 according to the third embodiment, and FIG. 41 (b) is a schematic cross-sectional view of the base unit 3390 in the XLIb-XLIb line of FIG. 41 (a). 41 (c) is a cross-sectional schematic diagram of the base unit 3390 in the XLIc-XLIc line of FIG. 41 (a).

As shown in FIG. 41, the base unit 3390 according to the third embodiment includes a base unit 3391, a displacement unit 3395 disposed on the base unit 3391, and a coil for urging the displacement unit 3395 with respect to the base unit 3391. It mainly includes a spring SP2.

The base unit 3391 is formed in an outer shape corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and is arranged inside the annular member 310. It mainly includes a base member 3392, a leaf spring 393 disposed on the base member 3392, and a detection device 394 disposed on the base member 3392.

The base member 3392 includes a base plate 3392a, a first wall portion 392b erected in a semi-circular shape toward the front side (arrow F direction side) of the base plate 3392a, and a center of the first wall portion 392b. A ring shape coaxially with the second wall portion 3392c, the first wall portion 392b, and the second wall portion 392c, which are formed in a semi-arc shape on the same axis and are erected from the base plate 3392a toward the front side. A third wall portion 392h formed in the base plate 3392a and erected toward the front side, a spring engaging piece 392k projecting from the base plate 3392a toward the front side, and an inner first locking portion 3392d3. , The inner second locking portion 3392d4, the convex portion 3392f1, and the regulation piece 392f are mainly provided.

The second wall portion 3392c is set to a diameter larger than the diameter of the first wall portion 392b, and is formed at a position separated from the first wall portion 392b by a predetermined distance. The second wall portion 3392c is a wall portion that guides the displacement of the first displacement member 3396 (displacement unit 3395), which will be described later, and is curved in an arc shape having a diameter along the displacement locus of the first displacement member 3396 (displacement unit 3395). Is formed.

Further, the second wall portion 3392c includes a plurality of cutout portions 3392c2 formed in a slit shape at a predetermined depth (notch size) from the erection tip side thereof toward the base plate 3392a side. In the present embodiment, the cutouts 3392c2 are formed with a pair of notches 3392c2 that are separated by a predetermined distance in the circumferential direction along the second wall portion 3392c at two places (a total of four places) in the circumferential direction.

The pair of notch portions 3392c2 are formed with notches extending from the radially inner side to the radial outer side of the second wall portion 3392c. That is, each notch portion 3392c2 is formed so as to penetrate the second wall portion 3392c in the plate thickness direction (diameter direction).

The notch dimension (depth) of the pair of notch portions 3392c2 toward the base plate 3392a side (arrow B direction side) is set to be smaller than the vertical dimension of the second wall portion 3392c from the base plate 3392a. That is, each cutout portion 3392c2 does not reach the base end of the second wall portion 3392c, and the second wall portion 3392c is in a state in which the base end side thereof is continuous along the circumferential direction (displacement direction of the displacement unit 3395). Is (formed continuously).

The second wall portion 3392c has a first outer portion from the inner peripheral surface of the second wall portion 3392c located between the pair of cutout portions 3392c2 toward the radial inside (displacement unit 3395 side) of the second wall portion 3392c. The stop portion 3392e3 and the outer second locking portion 3392e4 are projected.

The outer first locking portion 3392e3 and the outer second locking portion 3392e4 allow the displacement unit 3395 to be attached to the base member 3392 (base unit 3391), which will be described later, while allowing the displacement unit 3395 to fall off (remove). It is a protrusion that regulates, and is projected to a position that overlaps the displacement locus of the displacement unit 3395 in the front view.

The outer first locking portion 3392e3 and the outer second locking portion 3392e4 are inclined downward to the back side (arrow B direction side) as the front surface (plane on the arrow F direction side) is separated from the second wall portion 3392c. On the other hand, the back surface (the surface on the side in the direction of arrow B) is formed on a plane parallel to the front surface of the base plate 3392a.

The facing distance (dimension in the arrow FB direction) between the back surface of the outer first locking portion 3392e3 and the outer second locking portion 3392e4 and the front surface of the base plate 3392a is the displacement unit 3395 (first displacement member 3396). ) Is set to be substantially the same as or slightly larger than the thickness dimension in the front-rear direction (arrow FB direction). Thereby, the displacement unit 3395 can be displaceably arranged in a state of being sandwiched between the front surface of the base plate 3392a and the back surface of the outer first locking portion 3392e3 and the outer second locking portion 3392e4 (FIG. 41 (c)).

The inner first locking portion 3392d3 and the inner second locking portion 3392d4 are members that regulate the detachment (removal) of the displacement unit 3395 while allowing the displacement unit 3395 to be attached to the base member 3392 (base unit 3391). There is, and it is erected from the front surface of the base plate 3392a toward the same direction as the second wall portion 3392c (direction of arrow F).

At the erection tips of the inner first locking portion 3392d3 and the inner second locking portion 3392d4, a claw portion is projected from the inner peripheral surface toward the second wall portion 3392c side. The claw portion (the portion protruding from the inner peripheral surface at the erection tip toward the second wall portion 3392c side) is projected to a position overlapping the displacement locus of the displacement unit 3395 in the front view.

In the inner first locking portion 3392d3 and the inner second locking portion 3392d4, the front surface (the surface on the arrow F direction side) of the claw portion (protruding portion) is on the second wall portion 3392c side (protruding portion of the claw portion). It is formed so as to be inclined downward toward the back surface side (arrow B direction side) toward the front end side in the direction), while the back surface (plane on the arrow B direction side) is formed on a plane parallel to the front surface of the base plate 3392a.

The facing distance (dimension in the arrow FB direction) between the back surface of the claw portion (protruding portion) of the inner first locking portion 3392d3 and the inner second locking portion 3392d4 and the front surface of the base plate 3392a is the displacement unit 3395. It is set to be substantially the same as or slightly larger than the thickness dimension in the front-rear direction (arrow FB direction) of (engaging portion 396d of the first displacement member 3396). As a result, the displacement unit 3395 (engagement portion 396d of the first displacement member 3396) is placed between the front surface of the base plate 3392a, the outer first locking portion 3392e3, and the back surface of the outer second locking portion 3392e4. It can be displaceably arranged in a sandwiched state (see FIG. 41 (c)).

The base member 3392 (base plate 3392a) is formed of a resin material, and has an outer first locking portion 3392e3, an outer second locking portion 3392e4, an inner first locking portion 3392d3, and an inner second locking portion. 3392d4 is elastically deformable.

The thickness of the inner first locking portion 3392d3 and the standing portion (the portion erected from the base plate 3392a) of the inner second locking portion 3392d4 (dimension in the left-right direction in FIG. 41 (c)) is the base plate 3392a. It is formed to be smaller than the plate thickness (dimension in the front-rear direction (arrow FB direction)). As a result, the inner first locking portion 3392d3 and the inner second locking portion 3392d4 can be easily elastically deformed in the direction in which the claw portion is brought close to or separated from the displacement unit 3395.

The thickness of the second wall portion 3392c of the inner portion of the pair of cutout portions 3392c2 (the portion where the outer first locking portion 3392e3 and the outer second locking portion 3392e4 are formed) (FIG. 41 (FIG. 41). c) The dimension in the left-right direction) may be set to a dimension smaller than the plate thickness (dimension in the front-rear direction (arrow FB direction)) of the base plate 3392a. As a result, the second wall portion 3392c of the inner portion of the pair of cutout portions 3392c2 can be easily elastically deformed in the direction in which the outer first locking portion 3392e3 and the outer second locking portion 3392e4 are brought close to or separated from the displacement unit 3395. ..

The convex portion 3392f1 is formed at a position adjacent to the second displacement member 397 of the displacement unit 3395 arranged at the initial biasing position in front view, and when the displacement unit 3395 is arranged at the initial biasing position, the second By abutting on the displacement member 397, it functions as a portion that defines the arrangement of the second displacement member 397 with respect to the first displacement member 3396. That is, the convex portion 3392f1 is arranged at the same position as the convex portion 392f1 of 392f in the first embodiment, and the action (regulation of arrangement) on the second displacement member 397 at the initial biasing position is the first embodiment described above. Since it is the same as the case of the form (convex portion 392f1), detailed description thereof will be omitted.

The displacement unit 3395 is urged to the initial urging position side by the coil spring SP2, and the second displacement member 397 comes into contact with the convex portion 3392f at the initial urging position, and the displacement unit 3395 is maintained at the initial urging position. (The displacement unit 3395 is suppressed from being displaced beyond the initial biasing position).

The displacement unit 3395 mainly includes a first displacement member 3396 and a second displacement member 397 rotatably supported by the first displacement member 3396.

The first displacement member 3396 has a main body portion 396a and a main body portion 396a formed in a shape curved in an arc shape in a front view (a shape in which the ring shape is divided at two positions (positions in which the phases are 180 degrees out of phase)). The spring engaging portion 396c formed in a substantially C shape on one end side in the longitudinal direction (circumferential direction) of the main body portion 396a, and the arc center (diameter inward) of the main body portion 396a on the other end side in the longitudinal direction (circumferential direction) of the main body portion 396a ), An engaging portion 3396d located along the inner edge of the main body portion 396a and formed as a thinner portion than the other portions, and an outer peripheral edge of the main body portion 396a. An outer recessed portion 396e formed by cutting out a portion, a detection piece 396f projecting radially outward from the outer peripheral edge portion of the main body portion 396a, and a columnar protrusion on the back surface of the main body portion 396a. Mainly includes a shaft portion 396h to be provided.

The thickness of the engaging portion 3396d in the front-rear direction (arrow FB direction) is set to be smaller than the thickness of the main body portion 396a in the front-rear direction, and the back surface (the surface on the arrow B direction side) is set to the main body portion 396a. It is formed by connecting with the back of the. That is, the front surface of the engaging portion 396d (the surface on the side in the direction of arrow F) is positioned so as to recede toward the back surface (side in the direction of arrow B) from the front surface of the main body portion 396a.

When the first displacement member 3396 is arranged on the base member 3392 (base unit 3391), the engaging portion 3392d is formed on the front surface of the base plate 3392a, the inner first locking portion 3392d3, and the inner second locking portion 3392d4. It is arranged between the back surface of the claw portion and the opposite surface. Therefore, since the thickness of the engaging portion 3396d is formed to be smaller (thinner) than the thickness of the main body portion 3396a, the inner first locking portion 3392d3 and the inner second locking portion 3392d4 are separated from the base plate 3392a. The standing height can be lowered.

As a result, the rigidity of the inner first locking portion 3392d3 and the inner second locking portion 3392d4 can be secured. Therefore, it is possible to prevent the displacement unit 3395 from falling off from the base member 3392 toward the front side (arrow F direction side). Further, the inner first locking portion 3392d3 and the inner second locking portion 3392d4 are damaged (broken) due to the load (impact) when the displacement unit 3395 in the radial direction (to the right in FIG. 41C) is received. Can be suppressed. The radial outward displacement of the displacement unit 3395 can be received by the entire second wall portion 3392c, whereas the radial inward displacement of the displacement unit 3395 can be received by the inner first locking portion 3392d3 and the inner side. Since it is necessary to receive only by the second locking portion 3392d4, it is particularly effective to increase the rigidity of the inner first locking portion 3392d3 and the inner second locking portion 3392d4.

The displacement unit 3395 in the third embodiment has recessed portions (inner first recessed portion 396d1, inner second recessed portion d2, outer recessed portion 396e) in the first displacement member 396 as in the first embodiment. ) Is not recessed, but the other configurations are the same as the displacement unit 395.

To attach the displacement unit 3395 to the base unit 3390 (base unit 3391), the displacement unit 3395 is arranged in front of the base unit 3391, and then the displacement unit 3395 is pushed into the back side (base plate 3392a side).

In this case, the back surface (inclined surface) of the radial outer edge of the first displacement member 3396 is the outer first locking portion 3392e3 and the outer second locking portion 3392e4 of the base member 3392. The outer first locking portion 3392e3 and the outer second locking portion 3392e4 are extruded radially outward of the second wall portion 3392c so as to be in contact with the front surface, and the second wall portion 3392c (between the pair of notched portions 3392c2). Part) is elastically deformed outward in the radial direction.

Similarly, the radial inner edge of the first displacement member 3396 (engagement portion 3396d) is the front surface of the inner first locking portion 3392d3 of the base member 3392 and the claw portion of the inner second locking portion 3392d4. The claws of the inner first locking portion 3392d3 and the inner second locking portion 3392d4 are extruded radially inward of the second wall portion 3392c so as to be abutted against the inclined surface). The locking portion 3392d3 and the upright portion of the inner second locking portion 3392d4 are elastically deformed.

After that, the radial outer edge of the first displacement member 3396 is the claws of the outer first locking portion 3392e3 and the outer second locking portion 3392e4, and the inner first locking portion 3392d3 and the inner second locking portion 3392d4. When passing through the portions, the second wall portion 3392c (the portion between the pair of notched portions 3392c2) and the standing portions of the inner first locking portion 3392d3 and the inner second locking portion 3392d4 are elastically recovered. It returns to the initial position (position in the no-load state). This completes the attachment of the displacement unit 3395 to the base unit 3391.

As described above, according to the base unit 3390, when the displacement unit 3395 is arranged in the base unit 3391 as in the first embodiment, it is necessary to align the displacement unit 3395 at a specified position (positioning position). Instead, the displacement unit 3395 can be attached (arranged) to the base unit 3391 only by pushing the displacement unit 3395 from the front side (arrow F direction side) to the back side (arrow B direction side) of the displacement region. Further, as in the case of the first embodiment, it is not necessary to slide the displacement unit 3395 (rotate along the displacement locus) after pushing it toward the back surface side (arrow B direction side). As a result, the operation (assembly work) when arranging the displacement unit 3395 on the base unit 3391 can be simplified.

Further, in the third embodiment, since the displacement unit 3395 can be arranged from the front side in the displacement locus (the region through which the displacement unit 3395 passes from the initial biasing position to the terminal interlocking position), the first embodiment is described above. It is not necessary to secure the arrangement space of the displacement unit 395 outside the displacement region of the displacement unit 395 as in the embodiment (in the first embodiment, a part of the displacement unit 395 protrudes out of the displacement region at the positioning position). Therefore, it is possible to easily secure a space for arranging other parts (for example, coil spring SP2 or detection device 394, or ribs for reinforcement).

As described above, each notch 3392c2 does not reach the base end of the second wall portion 3392c, and the base end side of the second wall portion 3392c is continuous along the circumferential direction (displacement direction of the displacement unit 3395). (Continuously formed).

Therefore, when the displacement unit 3395 (first displacement member 3396) is displaced, the displacement can be received at the proximal end side of the second wall portion 3392c (the region where the notch portion 3392c2 is not formed). Therefore, the portion of the second wall portion 3392c where the outer first locking portion 3392e3 and the outer second locking portion 3392e4 are projected (the portion located between the pair of notched portions 3392c2) is damaged (broken). Can be suppressed.

Further, the displacement unit 3395 (first displacement member 3396) can be guided on the proximal end side of the second wall portion 3392c (the region where the notch 3392c2 is not formed) (the inner peripheral surface on the proximal end side continuous in the circumferential direction). Since it can be slid), it is possible to prevent the outer edge of the first displacement member 3396 from being caught by the inner edge of the notch 3392c2 and being chipped or worn.

Next, the base unit 4390 according to the fourth embodiment will be described with reference to FIG. 42. In the first embodiment, a protrusion formed on the base plate 392a in a recessed portion (inner first recessed portion 396d1, etc.) recessed in the radial inner portion and the radial outer portion of the first displacement member 396. The case where the displacement unit 395 is arranged on the base unit 391 by inserting the installation portion (inner first engaging piece 392d1, etc.) has been described, but in the fourth embodiment, only on one side of the first displacement member 4396. A case where the recessed portion is formed will be described. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

42 (a) is a front view of the base unit 4390 in the fourth embodiment, and FIG. 42 (b) is a schematic cross-sectional view of the base unit 4390 in the XLIIb-XLIIb line of FIG. 42 (a).

As shown in FIG. 42, the base unit 4390 according to the fourth embodiment has a base unit 4391, a displacement unit 4395 disposed on the base unit 4391, and a coil for urging the displacement unit 4395 with respect to the base unit 4391. It mainly includes a spring SP2.

The base unit 4391 is a base member 4392 arranged inside the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and a leaf spring arranged on the base member 4392. It mainly includes a 393 and a detection device 394 disposed on the base member 4392.

The base member 4392 has a base plate 2392a, a first wall portion 392b erected in a semi-circular shape from the base plate 2392a toward the front side (arrow F direction side), and a first wall portion 392b thereof. The second wall portion 2392c erected on the radial outer side of the first wall portion 392b, the third wall portion 2392h erected from the base plate toward the front side, and the protrusion from the base plate 2392a toward the front side. The spring engaging piece 2392k and the inner first engaging piece 4392d1 and the restricting piece 2392f formed on the inner side of the base member 2392 notched in a substantially U shape in the front view (see FIG. 40 (a)). , Is mainly provided.

The inner first engaging piece 4392d1 is a member for preventing the displacement unit 4395, which will be described later, from falling off (removing), and is projected at a position along the displacement locus of the displacement unit 4395. Further, the inner first engaging piece 4392d1 is projected from the base plate 2392a toward the front side, and the protruding tip is bent toward the second wall portion 2392c side.

Further, the inner first engaging piece 4392d1 has a distance between the bent portion and the base plate 2395a facing each other in the front-rear direction (arrow FB direction) of the displacement unit 4395 (engaging portion 4396d of the first displacement member 4396). It is projected longer than the thickness dimension in.

The extension distance T6 of the inner first engaging piece 4392d1 to the second wall portion 2392c side in the bent portion is larger than the distance T7 between the bent portion of the inner first engaging piece 4392d1 and the base plate 2392a facing each other. It is set small (T7> T6).

The second wall portion 4392c is a wall portion that guides the displacement of the displacement unit 4395, which will be described later, is formed at a position adjacent to the displacement unit 4395 in the front view, and extends along the displacement locus of the displacement unit 2395.

Further, the second wall portion 4392c includes a plurality of cutout portions 4392c2 formed by notches from the erection tip side thereof to the base plate 2392a side. In the present embodiment, the notch 4392c2 is formed by forming a pair of notches 4392c2 that are separated by a predetermined distance along the extension direction of the second wall 4392c at two locations (a total of four locations) in the extension direction.

The pair of notch portions 4392c2 are notched in a direction orthogonal to the extending direction of the second wall portion 4392c. Further, in the pair of cutout portions 4392c2, the notch dimension toward the base plate 2392a side (arrow B direction side) is set to be smaller than the vertical dimension of the second wall portion 4392c from the base plate 2392a. That is, the second wall portion 4392c is in a state in which the base end side (base plate 2392a side) is connected.

Further, the outer first locking portion 4392e3 and the outer second locking portion are projected from the side surface of the second wall portion 4392c located between the pair of cutout portions 4392c2 on the displacement unit 4395 side toward the displacement unit 4395 side. The portion 4392e4 is formed.

The outer first locking portion 4392e3 and the outer second locking portion 4392e4 allow the displacement unit 4395 to be attached to the base member 4392 (base unit 4391), which will be described later, while allowing the displacement unit 4395 to fall off (remove). It is a protrusion that regulates, and is projected at a position along the displacement locus of the displacement unit 4395.

Further, the outer first locking portion 4392e3 and the outer second locking portion 4392e4 are inclined toward the back side (arrow B direction side) as the front side (arrow F direction side) is separated from the second wall portion 4392c. Is formed. On the other hand, the outer first locking portion 4392e3 and the outer second locking portion 4392e4 are formed on the back surface side in a plane parallel to the front surface of the base plate 4392a.

Further, the back surfaces of the outer first locking portion 4392e3 and the outer second locking portion 4392e4 are formed at positions separated from the thickness dimension of the displacement unit 4395 (first displacement member 4396) in the front-rear direction. As a result, the displacement unit 4395 arranged in front of the base plate 4392a is arranged in a state of being sandwiched between the base plate 4392a, the outer first locking portion 4392e3, and the outer second locking portion 4392e4. Yes (see FIG. 42 (b)).

Further, the thickness of the second wall portion 4392c of the inner portion of the pair of cutout portions 4392c2 (the portion where the outer first locking portion 4392e3 and the outer second locking portion 4392e4 are formed) is the plate of the base plate 2392a. It is formed smaller than the thickness (thickness of the base plate 2392a in the front-rear direction). As a result, the second wall portion 4392c of the inner portion of the pair of cutout portions 4392c2 can be easily elastically deformed in the radial direction.

The displacement unit 4395 mainly includes a first displacement member 4396 that is formed linearly as a whole when viewed from the front, and a second displacement member 397 that is pivotally supported by the first displacement member 4396.

The first displacement member 4396 has a linear main body portion 2396a and a spring engaging portion 396c formed in a substantially C shape on one end side of the linearly extending main body portion 2396a. A protruding portion 396b projecting toward the center of the first wall portion 392b of the base plate 2392a on the other end side of the extended main body portion 2396a, and a second wall portion 2392c formed along the displacement unit 4395. The engaging portion 4396d projecting from the side surface opposite to the main body portion 2396a, the detection piece 396f projecting from the side surface of the second wall portion 2392c side of the main body portion 2396a, and the detection piece 396f projecting from the back surface of the main body portion 2396a in a columnar shape Mainly includes a shaft portion 396h and a shaft portion 396h.

Since the engaging portion 4396d has a shape in which the inner first concave portion 2396d1 is omitted from the engaging portion 2396d in the second embodiment, detailed description thereof will be omitted.

In the method of attaching the displacement unit 3395 to the base unit 4391 of the base unit 4390 configured as described above, first, the engaging portion 4396d side of the displacement unit 4395 is brought close to the base plate 2392a, and the displacement unit 4395 is attached to the base plate. The engaging portion 4396d is pushed into the inside of the bent portion of the inner first engaging piece 4391d1 in a state of being slanted with respect to the front surface of the 2392a.

As described above, the inner first engaging piece 4391d1 has an extension distance T6 (see FIG. 42B) in the bent portion of the inner first engaging piece 4392d1 toward the second wall portion 2392c. Since the distance T7 (see FIG. 42 (b)) between the bent portion of the first engaging piece 4392d1 and the base plate 4391a is set smaller (shorter), the engaging portion 4396d is arranged diagonally. After pushing the inner first engaging piece 4391d1 inside the bent portion in the state, the displacement unit 4395 can be rotated toward the base plate 4392a about the engaging portion 4396d side.

Next, the displacement unit 4395 in a state of being diagonally arranged with respect to the front surface of the base plate 2392a is rotated around the engaging portion 4396d side as the axis, and the displacement unit 4395 is rotated toward the base plate 4392a side, and the side opposite to the engaging portion 4396d. Is displaced toward the base plate 4392a.

As a result, the edge portion of the first displacement member 4396 opposite to the engaging portion 4396d comes into contact with the outer first locking portion 4392e3 and the outer second locking portion 4392e4, and the outer first locking portion 4392e3. , And the outer second locking portion 4392e4 is pushed out toward the second wall portion 3392c to elastically deform the second wall portion 3392c.

As a result, a space for displacing the side of the displacement unit 4395 opposite to the engaging portion 4396d toward the base plate 4392a can be secured, and the displacement unit 4395 can be attached to the base unit 3391.

Further, as described above, the plate thickness of the main body portion 4396a in the front-rear direction is set smaller than the distance from the outer first locking portion 4392e3 and the outer second locking portion 4392e4 to the front surface of the base plate 2392a.

Therefore, when the displacement unit 4395 is pushed to the front surface of the base plate 2392a, the contact between the outer first locking portion 3392e3, the outer second locking portion 3392e4, and the first displacement member 4396 is released, and the outer first engaging portion is released. The elastic deformation of the stop portion 3392e3 and the outer second locking portion 3392e4 is returned (released).

According to the base unit 4390 configured as described above, one side (engaging portion 4396d side) of the displacement unit 4395 is engaged with the inside of the bent portion of the inner first engaging piece 4391d1, and the engaging side is engaged. As a fulcrum, the displacement unit 4395 can be arranged on the base unit 4391 by pushing the other side of the displacement unit 4395 toward the base plate 4392a side.

Therefore, when the displacement unit 3395 is arranged on the base unit 4391 as in the third embodiment, the outer first locking portion 3392e3, the outer second locking portion 3392e4, and the inner side formed on both sides of the displacement unit 3395. It is not necessary to elastically displace the first locking portion 3392d3 and the inner second locking portion 3392d4, respectively. That is, it is not necessary to push the locking portions 3392e3, 33992d3 and the like on both sides of the displacement unit 3395 while uniformly elastically deforming them. Therefore, the displacement unit 4395 can be easily arranged on the base unit 4391.

Further, since it is not necessary to elastically deform the inner first engaging piece 4391d, the rigidity of the inner first engaging piece 4391d is relatively high (compared to the inner first locking portion 4391d3 of the third embodiment). It is possible to prevent the inner first engaging piece 4391d from being deformed when the displacement unit 4395 is displaced.

In particular, by adopting a configuration in which the inner first engaging piece 4391d is not elastically deformed, it is possible not only to improve the holding performance (performance to prevent falling off) of the displacement unit 4395, but also to improve an illegal member (for example, a wire or a wire). By using the piano wire), it is possible to easily prevent the displacement unit 4395 from being illegally removed. In this case, the arrangement position of the inner first engaging piece 4391d is closer to the side where the illegal member is inserted than the arrangement position of the outer first locking portion 4392e3 and the outer second locking portion 4392e4. Is preferable.

Next, the base unit 5390 according to the fifth embodiment will be described with reference to FIGS. 43 to 46. In the first embodiment, the case where the displacement unit 395 is displaced by the operation of the operation unit 320 by the player has been described. However, in the base unit 5390 in the fifth embodiment, the displacement unit 5395 is moved by the drive device 5398. It is made displaceable, and the operation unit 320 is displaced by the displacement of the displacement unit 5395. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

First, the configuration of the base unit 5390 according to the fifth embodiment will be described with reference to FIGS. 43 and 44. FIG. 43 (a) is a front view of the base unit 5391 according to the fifth embodiment, and FIG. 43 (b) is a sectional view of the base unit 5391 taken along the line XLIIIb-XLIIIb of FIG. 43 (a). 44 (a) is a front view of the displacement unit 5395, FIG. 44 (b) is a rear view of the displacement unit 5395, and FIG. 44 (c) is the displacement of XLIVc-XLIVc of FIG. 44 (a). It is sectional drawing of the unit 5395.

As shown in FIGS. 43 and 44, the base unit 5390 according to the fifth embodiment has a base unit 5391, a displacement unit 5395 disposed on the base unit 5391, and a displacement unit 5395 with respect to the base unit 5391. It mainly includes a coil spring SP2 (see FIG. 45 (a)) and a drive device 5398 (see FIG. 46 (a)) arranged on the back side of the base unit 5391.

The base unit 5391 is formed in an outer shape corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300 described above, and is arranged inside the annular member 310. The base member 5392 is mainly provided with a leaf spring 393 disposed on the base member 5392, and a detection device 394 disposed on the base member 392.

The base member 5392 is formed on the base plate 5392a and its base plate 5392a in a semicircular shape, and is erected toward the front side (arrow F direction side) of the base plate 5392a and its first wall portion 392b and its first. A third wall portion formed in a semicircular shape coaxially with the center of the one wall portion 392b, formed in a ring shape coaxially with the first wall portion 392b, and erected from the base plate 392a toward the front side. The 392h, the spring engaging piece 392k and the convex portion 3392f1 projecting from the base plate 5392a toward the front side, and the first wall portion 5392b are located on the outer side in the radial direction and are formed through the base plate 5392a in a long hole shape. The sliding groove 5392a2 is mainly provided.

The insertion hole 5392a1 is a hole through which the shaft of the drive device 5398 (see FIG. 46 (a)) arranged on the back surface side of the base unit 5391 is inserted, and is formed at a position corresponding to the drive device 5398. In the drive device 5398, the pinion 5398a is mounted on the shaft through which the insertion hole 5392a1 is inserted, and the pinion 5398a is engaged with the tooth portion 5396k of the displacement unit 5395 described later to drive the drive device 5398 and the displacement unit. The 5395 can be displaced.

The sliding groove 5392a2 is a groove that guides the displacement of the displacement unit 5395, which will be described later, and the roller 5396j of the displacement unit 5395 is inserted into the sliding groove 5392a2. Further, the sliding groove 5392a2 is formed in an arc shape coaxial with the first wall portion 392b.

The displacement unit 5395 mainly includes a first displacement member 5396 which is formed in a substantially semi-circular shape as a whole when viewed from the front, and a second displacement member 397 which is pivotally supported by the first displacement member 5396.

The first displacement member 5396 includes a main body portion 396a formed in an arc shape, a spring engaging portion 396c formed in a substantially C shape in front view on one end side of the main body portion 396a extending in an arc shape, and a circle. A plurality of ridges 5396b projecting toward the center of the arc of the main body 396a on the other end side of the main body 396a extending in an arc shape and a plurality of rows along the outer peripheral edge of the main body 396a are provided. The tooth portion 5396k to be formed, the detection piece 396f projecting radially outward from the outer peripheral edge portion of the main body portion 396a, and the shaft portion 396h projecting in a columnar shape on the back surface of the main body portion 396a. Mainly prepared.

Further, on the first surface 396a1 of the main body portion 396a, a rotating shaft portion 5396i projecting in a columnar shape from two positions different in the circumferential direction toward the back side, and a state in which the rotating shaft portion 5396i can rotate around the rotating shaft portion 5396i. A ring-shaped roller 5396j arranged in the above direction and a hook portion 5396m projecting from two locations in the circumferential direction different from the rotating shaft portion 5396i toward the back surface side in a hook shape are provided.

The rotating shaft portion 5396i is a shaft that holds the roller 5396j, is set to an outer diameter smaller than the inner diameter of the roller 5396j, and is set to have a longer axial length than the roller 5396j. Further, the rotating shaft portion 5396i is formed with a hole for screwing a screw in the center. As a result, the roller 5396j is arranged around the rotating shaft portion 5396i, and then the screw is screwed into the rotating shaft portion 5396i, so that the roller 5396j is arranged on the rotating shaft portion 5396i in a rotatable state.

The roller 5396j is a portion arranged inside the sliding groove 5392a2 of the base plate 5392a as described above, and the outer diameter is set to be smaller than the width dimension of the sliding groove 5392a2. Further, each roller 5396j arranged on the two rotating shaft portions 5396i has a sliding groove at an angle θ1 (see FIG. 44 (b)) that is separated in the circumferential direction about the center of the arc of the main body portion 396a. It is set smaller than the angle θ2 (see FIG. 43A) extending in the circumferential direction about the center of the arc of 5392a2. As a result, the two rollers 5396j can be displaced along the sliding groove 5392a2, the difference between the angle θ1 and the angle θ2, and the displacement unit 5395 can be rotationally displaced.

The projecting portion 5396b is formed on the displacement locus of the engaging piece 342b of the operating unit 320 (see FIG. 15). Further, an engaging hole 5396b1 penetrating in the front-rear direction (arrow FB direction) is formed in the projecting portion 5396b.

The engagement hole 5396b1 is a hole into which the engagement piece 342b of the operation unit 320 is inserted, and when the displacement unit 5395 is arranged at the initial biasing position, the engagement piece of the operation unit 320 arranged at the initial position is inserted. It is formed at a position corresponding to 342b (see FIG. 16B). Therefore, in the fifth embodiment, when the operation unit 320 and the base unit 5390 are assembled, the engagement piece 342b is inserted into the engagement hole 5396b1.

Further, the size of the engaging hole 5396b1 about the center of the main body 396a in the circumferential direction is set to be substantially the same as the size of the engaging piece 342b about the center of the main body 396a in the circumferential direction. As a result, the displacement unit 5395 and the operation unit 320 can always be interlocked with each other.

A plurality of (11 in this embodiment) rows of tooth portions 5396k are arranged along the radial outer edge of the main body portion 396a from the other end of the main body portion 396a extending in an arc shape toward one end side. Will be set up. The tooth portion 5396k is a portion that meshes with the pinion 5398a arranged on the shaft of the drive device 5398 arranged in the base unit 5391. As a result, the displacement unit 5395 is displaced when the pinion 5398a is rotated by driving the drive device 5398.

The two hook portions 5396m are projected from the main body portion 396a with their tips bent in a substantially L shape. Further, the two hook portions 5396m are formed between the two rotating shaft portions 5396i arranged at different positions in the circumferential direction about the center of the arc of the main body portion 396a, and are formed from the center of the arc of the main body portion 396a. It is projected at different positions in the radial direction.

Further, the two hook portions 5396 m are bent in opposite directions in the radial direction from the center of the arc of the main body portion 396a, and the one hook portion 5396 m that bends inward in the radial direction is the above-mentioned slide. The other hook portion 5396m, which is projected from a position along the inner diameter side edge of the moving groove 5392a2 and bends outward in the radial direction, is projected from a position along the outer diameter side edge of the sliding groove 5392a2. (See FIG. 46 (e)).

Further, the hook portion 5396m is a member that engages with the base plate 5392a to prevent the displacement unit 5395 from falling off to the front side, and the bent portion at the tip of the hook portion 5396m is a base around the sliding groove 5392a2. It is set at a position where it overlaps with the plate 5392a in the front-rear direction, and the distance between the bent portions and the first surface 396a1 is set to be larger than the plate thickness of the base plate 5392a.

Further, the hook portion 5396m is formed so that the projecting tip surface is inclined toward the front side toward the bending tip side. As a result, when the displacement unit 5395 is arranged in the base unit 5391, the hook portion 5396 m in which the bent portion at the tip overlaps with the base plate 5392a around the sliding groove 5392a2 in the front-rear direction is formed on the protruding tip surface of the hook portion 5396 m. Can be elastically deformed inside the sliding groove 5392a2 by utilizing the inclination of. Further, by arranging the bent portion of the hook portion 5396 m beyond the back surface of the base plate 5392a, the elastic deformation of the hook portion 5396 m is restored and the bent portion at the tip of the hook portion 5396 m is placed on the base around the sliding groove 5392a2. It can be arranged at a position where it overlaps with the plate 5392a in the front-rear direction. That is, the hook portion 5396m allows the displacement unit 5935 to be arranged in the base unit 5391, and can prevent the displacement unit 5935 from falling off from the base unit 5391.

Further, the two hook portions 5396m are set so that the distance between the outer diameters of the main body portion 396a side (base end side) in the radial direction facing each other is smaller than the outer diameter of the roller 5396j described above. As a result, when the displacement unit 5395 is displaced with respect to the base plate 5392a, it is possible to prevent the hook portion 5396m arranged inside the sliding groove 5392a2 from being rubbed against the inner surface of the sliding groove 5392a2 and damaged.

According to the base unit 5390 configured as described above, the first displacement member 5396 (displacement unit 5395) configured as a rack is arranged in the base unit 5391 only by engaging the hook portion 5396 m with the sliding groove 5392a2. Will be set up. That is, no operation after disposing the displacement unit 5395 on the base unit 5391 (for example, an operation of fastening the screws) is required. Therefore, the work of the operator who assembles the base unit 5390 can be simplified.

Further, the sliding groove 5392a2 can be provided with (combined with) a role as a guide portion for guiding the displacement of the displacement unit 5395 and a role as an engaged portion for engaging the hook portion 5396 m. Therefore, it is not necessary to separately form the guide portion for guiding the displacement unit 5395 and the engaged portion for engaging the hook portion 5396 m on the base plate 5392a, and other members are arranged on the base plate 5392a. It is easy to secure space.

Further, as in the case of the first embodiment, the inner first engaging piece 392d1 and the outer first engaging piece 392e1 are provided on the base plate 392a, and the inner first engaging piece 392d1 and the outer first engaging piece 392e1 are provided. Is engaged with the displacement unit 395 (first displacement member 396), of the outer edges of the first displacement member 396, the inner first engaging piece 392d1 or the outer first engaging piece when the displacement unit 395 is displaced. The tooth portion 5396k cannot be provided in the portion facing (interfering with) the 392e1.

On the other hand, according to the fifth embodiment, since the hook portion 5396m is projected from the back surface side of the first displacement member 5396 and the hook portion 5396m is engaged with the sliding groove 5392a2, the first displacement member 5396 It is possible to easily secure a region where the tooth portion 5396k can be arranged on the outer edge of the.

Next, the displacement of the displacement unit 5395 in the fifth embodiment will be described with reference to FIGS. 45 and 46. 45 (a) to 45 (c) are front views of the base unit 5390, and FIGS. 46 (a) to 46 (c) are the base unit 5390 in the XLVIa-XLVIa line of FIG. 45 (a). It is a cross-sectional view, and FIG. 46 (d) is a cross-sectional view of the base unit 5390 in the XLVId-XLVId line of FIG. 46 (a). FIG. 46 (e) is a cross-sectional view of the base unit 5390 in the XLVIe-XLVIe line of FIG. 46 (a).

In FIGS. 45 (a) to 45 (c) and 46 (a) to 46 (c), the outer shape of the engaging piece 342b (see FIG. 16 (b)) of the operation unit 320 is shown by a chain line. To. Further, in FIGS. 45 (a) and 46 (a), the base unit 5390 in the state of being arranged at the initial biasing position is shown, and in FIGS. 45 (c) and 46 (c), the terminal interlocking position is shown. The base unit 5390 in the state of being arranged in is illustrated, and in FIGS. 45 (b) and 46 (b), the base unit 5390 in the state of being arranged at an intermediate position between the initial biasing position and the terminal interlocking position is shown. Will be done.

As shown in FIGS. 45 and 46, the displacement unit 5395 is driven by the pinion 5398a, which is rotated by the drive of the drive device 5398, via the tooth portion 5396k. In the fifth embodiment, the displacement unit 5395 is displaced from the initial biasing position to the terminal interlocking position side by rotating the pinion 5398a counterclockwise in the front view. On the other hand, when the pinion 5398a is rotated clockwise in the front view, the displacement unit 5395 is displaced from the terminal interlocking position to the initial biasing position side.

In the initial urging position, the roller 5396j arranged on one end side of the main body portion 396a of the two rollers 5396j is arranged at a position adjacent to the end portion on the one end side in the circumferential direction of the sliding groove 5392a2. .. Further, at the interlocking terminal position, the roller 5396j arranged on the other end side of the main body portion 396a of the two rollers 5396j is arranged at a position adjacent to the end portion on the other end side in the circumferential direction of the sliding groove 5392a2. To. As a result, it is possible to prevent the displacement unit 5395 from being displaced beyond the initial biasing position or the terminal interlocking position.

Further, the rotation angle of the displacement unit 5395 from the initial urging position to the end interlocking position is set to be the same as the rotation angle of the operation unit 320 from the initial position to the end position. As described above, since the engagement piece 342b of the operation unit 320 arranged at the initial position is inserted into the engagement hole 5396b1 of the displacement unit 5395 arranged at the initial biasing position, the displacement unit 5395 reaches the end interlocking position. When rotated, the operating unit 320 is rotated to the terminal position.

Next, the base unit 6390 according to the sixth embodiment will be described with reference to FIG. 47. In the first embodiment, the case where the side of the regulation piece 392f connected to the base plate 392a is set in the direction in which the displacement unit 395 is urged by the coil spring SP2 has been described, but in the sixth embodiment, the regulation is performed. The side of the piece 6392f connected to the base plate 6392a is set in the direction opposite to the direction in which the displacement unit 395 is urged by the coil spring SP2. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

47 (a) is a front view of the base unit 6391 according to the sixth embodiment, FIG. 47 (b) is a front view of the base unit 6390, and FIG. 47 (c) is a front view of FIG. 47 (b). It is a sectional drawing of the base unit 6390 in the XLVIIc-XLVIIc line.

As shown in FIG. 47, the base unit 6390 according to the sixth embodiment includes a base unit 6391, a displacement unit 395 disposed on the base unit 6391, and a coil for urging the displacement unit 395 with respect to the base unit 391. It mainly includes a spring SP2.

The base unit 6391 is formed in an outer shape corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and is arranged inside the annular member 310. It mainly includes a base member 392, a leaf spring 393 disposed on the base member 6392, and a detection device 394 disposed on the base member 392.

The base member 6392 is formed on the base plate 6392a and its base plate 6392a in a semicircular shape, and is erected toward the front side (arrow F direction side) of the base plate 392a and its first wall portion 392b and its first. A second wall portion 392c formed in a semicircular shape coaxial with the center of the first wall portion 392b and erected from the base plate 392a toward the front side, a first wall portion 392b, and a second wall portion 392c. A third wall portion 392h formed in a ring shape coaxial with the base plate 392a and erected toward the front side from the base plate 392a, and a spring engaging piece 392k projecting from the base plate 392a toward the front side. It mainly includes an inner first engaging piece 392d1, an inner second engaging piece 392d2, and a regulating piece 6392f formed inside the base plate 392a cut out in a substantially U-shape in the front view.

The restricting piece 6392f is a member that regulates the displacement of the displacement unit 395 to one side, which will be described later, and is formed between the first wall portion 392b and the second wall portion 392c in a front view. Further, the regulation piece 6392f is formed at a position overlapping the displacement locus of the displacement unit 395 arranged between the first wall portion 392b and the second wall portion 392c.

The regulation piece 6392f is formed by cutting out the base plate 6392a in a substantially U shape when viewed from the front, and one end side connected to the base plate 6392a is in the direction in which the displacement unit 395 is urged by the coil spring SP2. Set in the opposite direction. Further, the regulation piece 6392f is provided with a convex portion 392f1 projecting toward the front side (displacement unit 395 side) at the other end, and the convex portion 392f1 is brought into contact with the displacement unit 395 to bring the convex portion 392f1 into contact with the displacement unit 395 on one side of the displacement unit 395. Displacement to can be regulated.

According to the regulation piece 6392f in the sixth embodiment, when the displacement unit 395 is displaced from the terminal interlocking position side to the initial biasing position side, the second displacement member 397 is brought into contact with the convex portion 392f1 of the regulation piece 6392f. Therefore, the displacement unit 395 can be maintained in the initial biasing position.

The regulation piece 6392f is regulated while the displacement unit 395 is displaced to the initial biasing position side because one end side connected to the base plate 6392a is set in the direction opposite to the direction in which the displacement unit 395 is urged by the coil spring SP2. The force when the piece 6392f comes into contact with the piece 6392f can act as a force in the direction of pulling the regulation piece 6392f in the extending direction.

Therefore, like the regulation piece 392f in the first embodiment, when the displacement unit 395 comes into contact with the regulation piece 6392f, the regulation piece 6392f is elastically deformed into a posture of bending with its base side (connecting portion with the base plate 392a) as a fulcrum. Can be suppressed. That is, the burden on the base side of the regulation piece 6392f can be reduced, and the durability can be improved.

Further, in the state where the convex portion 392f1 of the regulation piece 6392f is brought into contact with the second displacement member 397 and the displacement unit 395 is maintained at the initial biasing position, in the case of the first embodiment, the base side (base plate 392a). There is a risk that the regulation piece 392f will have a habit of bending with the fulcrum as the fulcrum. When such a habit is formed, the relative position of the regulation piece 392f (convex portion 392f1) with respect to the second displacement member 397 changes, and the second displacement member 397 cannot be brought into contact with the convex portion 392f1 of the regulation piece 6392f. Alternatively, the contact causes the base of the restricting piece 6392f to bend more. On the other hand, the posture of the regulation piece 392f can be maintained in the initial posture by being pulled and deformed as in the sixth embodiment.

When the displacement unit 395 is arranged on the base unit 6391, the regulation piece 6392f is elastically deformed to the back side in the same manner as the regulation piece 392f in the first embodiment, and the displacement unit 395 is arranged on the base unit 6391. it can. In this case, the position of the convex portion 392f1 with respect to the second displacement member 397 is the same as in the case of the first embodiment. Therefore, also in the sixth embodiment, when the displacement unit 395 is arranged on the base unit 6391, it is convex. By using (contacting) the portion 3921f1, it is possible to prevent the second displacement member 397 from falling off (pulling out from the shaft portion 396h).

Next, the base unit 7390 according to the seventh embodiment will be described with reference to FIG. 48. In the first embodiment, the case where the second side wall 397f of the second displacement member 397 is formed on a flat surface has been described, but in the seventh embodiment, the recess 7397f1 is formed in the second side wall 7397f of the second displacement member 7397. It is recessed. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 48 is a cross-sectional schematic view of the base unit 7390 according to the seventh embodiment. Note that FIG. 48 corresponds to the cross-sectional view of the base unit 390 in FIG. 33 (a).

As shown in FIG. 48, the base unit 7390 according to the seventh embodiment has a base unit 391, a displacement unit 7395 disposed on the base unit 7391, and a coil for urging the displacement unit 395 with respect to the base unit 391. It mainly includes a spring SP2.

The base unit 7391 is formed in an outer shape corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and is arranged inside the annular member 310. It mainly includes a base member 7392, a leaf spring 393 disposed on the base member 7392, and a detection device 394 disposed on the base member 392.

The base member 7392 is formed on the base plate 392a and the base plate 392a in a semicircular shape, and is erected toward the front side (arrow F direction side) of the base plate 392a and the first wall portion 392b and the first wall portion 392b thereof. A second wall portion 392c formed in a semicircular shape coaxial with the center of the first wall portion 392b and erected from the base plate 392a toward the front side, a first wall portion 392b, and a second wall portion 392c. A third wall portion 392h formed in a ring shape coaxial with the base plate 392a and erected toward the front side from the base plate 392a, and a spring engaging piece 392k projecting from the base plate 392a toward the front side. It mainly includes an inner first engaging piece 392d1, an inner second engaging piece 392d2, and a regulating piece 7392f formed inside the base plate 392a cut out in a substantially U-shape in the front view.

The restricting piece 7392f is a member that regulates the displacement of the displacement unit 395 to one side, which will be described later, and is formed between the first wall portion 392b and the second wall portion 392c in a front view. Further, the regulation piece 7392f is formed at a position overlapping the displacement locus of the displacement unit 395 arranged between the first wall portion 392b and the second wall portion 392c.

The regulation piece 7392f is formed by cutting out the base plate 392a in a substantially U shape when viewed from the front, and one end thereof is connected to the base plate 392a. Further, the regulation piece 7392f is provided with a convex portion 7392f1 projecting toward the front side (displacement unit 7395 side) at the other end, and the convex portion 7392f1 is brought into contact with the displacement unit 7395 to bring the convex portion 7392f1 into contact with the displacement unit 7395 to one side of the displacement unit 7395. Displacement to can be regulated.

Further, the convex portion 7392f1 includes a second convex portion 7392f2 having a triangular cross section in which the contact surface with the displacement unit 7395 projects toward the contact surface (second side wall 7397f) side of the displacement unit 7395. The second convex portion 7392f2 has a triangular cross section formed along the plane of the base plate 7392a over the entire contact surface of the convex portion 7391f with the displacement unit 7395.

The displacement unit 7395 mainly includes a first displacement member 396 formed in a substantially semicircular shape in the front view, and a second displacement member 7397 axially supported by the first displacement member 396.

The first displacement member 396 includes a main body portion 396a formed in an arc shape, a spring engaging portion 396c formed in a substantially C shape in front view on one end side of the main body portion 396a extending in an arc shape, and a circle. A protruding portion 396b projecting toward the center of the arc of the main body 396a on the other end side of the main body 396a extending in an arc shape, and an engaging portion 396d projecting along the inner edge of the main body 396a. The outer concave portion 396e formed by cutting out the outer peripheral edge portion of the main body portion 396a, and the detection piece 396f projecting radially outward from the outer peripheral side edge portion of the main body portion 396a. It mainly includes a shaft portion 396h projecting in a columnar shape on the back surface of the main body portion 396a.

Similar to the second displacement member 397 in the first embodiment, the second displacement member 7397 is formed in a substantially triangular shape as a whole in the front view. Further, the second displacement member 7397 includes a shaft support hole 397a penetrating in the front-rear direction. In the second displacement member 7397, as in the case of the second displacement member 397 in the first embodiment, the first corner portion 397b, the second corner portion 397c, and the third corner portion 397d are attached to the tip portions of each of the three locations. It will be described with reference to.

The second side wall 7397f of the side wall connecting the first corner portion 397b and the third corner portion 397d is brought into contact with the regulation piece 7392f of the base plate 7392a when the displacement unit 7395 is arranged at the initial biasing position. It is a surface, and includes a recess 7397f1 in which the cross-sectional shape of the side surface thereof is recessed in a triangular shape corresponding to the cross-sectional shape of the second convex portion 7392f2 of the regulation piece 7392f.

As a result, when the displacement unit 7395 is arranged at the initial urging position and the displacement unit 7395 is urged to the regulation piece 7392f side by the coil spring SP2, the second convex portion 7392f2 is inserted inside the concave portion 7397f1. The regulation piece 7392f and the second displacement member 7397 can be engaged with each other. Therefore, in the state where the displacement unit 7395 is arranged at the initial biasing position, the regulation piece 7392f is elastically deformed to the back side (arrow B direction side) by using an illegal member (for example, a wire or a piano wire). , It is possible to prevent the regulation of the displacement unit 7395 by the regulation piece 7392f from being illegally lifted. As a result, it is possible to prevent the displacement unit 7395 from being displaced to the positioning position and illegally removing the displacement unit 7395 from the base plate 392a.

Further, by engaging the regulation piece 7392f and the second displacement member 7397, the displacement unit 7395 is maintained at the initial fulcrum position by the urging force of the coil spring SP2, and the base side (base plate 392a) is maintained. It is possible to prevent the regulation piece 7392f from having a habit of being in a bent posture with the connecting portion) as a fulcrum.

Next, the operation unit 8320 according to the eighth embodiment will be described with reference to FIGS. 49 to 53. In the first embodiment, the case where the guided member 344 is formed in a perfect circular ring shape has been described, but in the operation unit 8320 in the eighth embodiment, the guided member 8345 is formed in an elliptical ring shape. .. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

First, with reference to FIG. 49, the overall configuration of the operation unit 8320 and the guide unit 8350 in the eighth embodiment will be described. FIG. 49 (a) is an exploded perspective front view of the operation unit 8320 according to the eighth embodiment, and FIG. 49 (b) is a cross-sectional view of the operation unit 8320 and the guide unit 8350. The cross-sectional view of FIG. 49 (b) corresponds to the cross-sectional view of the operation unit 320 and the guide unit 350 in FIG. 22 (d).

As shown in FIG. 49, the operation unit 8320 according to the eighth embodiment includes a gripping unit 330 arranged on the front side and a rotating unit 8340 connected to the back side (arrow B direction side) of the gripping unit 330. , Equipped with.

The rotating unit 8340 is arranged on the gripping unit 330 side and is connected to the gripping unit 330 on the front side member 341, the back side member 342 arranged on the back side of the front side member 341, and the back side member thereof. A shaft member 343 projecting radially outward from 342, an annular guided member 344 arranged so as to surround the shaft member 343, and a guided member 8345. Mainly prepared.

In the eighth embodiment, the guided member 344 is arranged on one side of the shaft member 343 projecting from two locations facing outward in the radial direction from the back surface side member 342, and the other side of the shaft member 343. The guided member 8345 is arranged in the.

The guided member 8345 has an elliptical outer shape and a perfect circular inner shape. Further, the guided member 8345 is arranged in a state of being fastened and fixed to the shaft member 343, and is arranged in a state of being non-rotatable about the shaft member 343. Further, the guided member 8345 is arranged inside the guide groove 8351 of the guide groove 351 and the guide groove 8351 formed in the guide unit 8350 described later. A guided member 344 is arranged inside the guide groove 351.

The guide unit 8350 is arranged on the front side of the rotating unit 340 to regulate the displacement of the rotating unit 340 to the front side, and is arranged on the back side of the rotating unit 340 and is arranged on the back side of the rotating unit 340. It is provided with a rear side guide unit 370 that regulates displacement to the rear side.

Further, the guide unit 8350 is recessed by a connecting surface of the recessed bottom surface of the recessed portion 362a2 and the inner peripheral surface of the first cylindrical portion 362a, and the first portion 371 and the second portion 372 of the rear side guide unit 370. A guide groove 351 and a guide groove 8352 that partially surround the setting portion 362a2 are formed. The guide groove 351 and the guide groove 8352 are formed at opposite positions of the guide unit 8350, respectively.

As shown in FIG. 49B, the guide groove 8352 extends in the circumferential direction of the second annular member 362 of the front side guide unit 360 and the first portion 371 of the back side guide unit 370. The portion is formed in a shape that is inclined toward the back surface side.

Further, the guide groove 8352 includes a first guide surface 351a and a second guide surface 351b which are guide surfaces (wall surfaces for restricting the movement of the guided member 8344) of the guided member 8344 on the second ring member 362 side. The third guide surface 8351c and the fourth guide surface 8351d, which are the guide surfaces of the guided member 8344 on the back side guide unit 370 side, the second ring member 362 of the front side guide unit 360, and the back side guide. A first end portion 351e and a second end portion 351f, which are end portions in the circumferential direction of the first portion 371 of the unit 370, are mainly provided.

The first guide surface 351a and the third guide surface 8351c are formed so as to face each other. Further, the distance between the first guide surface 351a and the third guide surface 8351c facing each other is set to be larger than the external dimensions of the guided member 8344 in the lateral direction. As a result, the guided member 8344 can be moved by the first guide surface 351a and the third guide surface 8351c while restricting the moving direction. In the following description, the moving region of the guided member 344 formed between the first guide surface 351a and the third guide surface 8351c facing each other will be referred to as a "first guide region".

Further, the first guide surface 351a and the third guide surface 8351c extend in the circumferential direction of the second ring member 362 and the first portion 371, and are formed as a wall surface inclined in the front-rear direction. Therefore, the guided member 8344 that moves in the first guide region is moved in the front-rear direction of the guide unit 350 while being moved in the circumferential direction of the second ring member 362 and the first portion 371. Therefore, the operation unit 320 is displaced so as to rotate about the center of the erection wall 341b of the rotation unit 340 and move in the axial direction of the erection wall 341b.

When no force is input to the operation unit 320 from the outside of the slot machine 10 (see FIG. 1) (the player does not operate the operation unit 320), the rotation unit 340 is directed toward the front side by the coil spring SP1 described above. By being urged, the guided member 344 is guided along the first guide surface 351a to the first end portion 351e. As a result, in the initial position, the guided member 344 is maintained at a position where it abuts on the first end portion 351e.

The second guide surface 351b and the fourth guide surface 8351d are formed so as to face each other. Further, the second guide surface 351b is extended in a direction in which the guide surface is parallel to the horizontal direction. On the other hand, the fourth guide surface 8351d is formed as a guide surface toward the front side as it approaches the connecting portion with the first guide surface 351a in the circumferential direction of the second ring member 362 and the first portion 371.

The second guide surface 351b and the fourth guide surface 8351d are connected to the end portion of the first guide region (first guide surface 351a and third guide surface 351c) on the back surface side (arrow B direction side). .. As a result, the guided member 8344 that has moved the first guide region to the back side (arrow B direction side) can be received between the second guide surface 351b and the fourth guide surface 8351d.

Further, the second guide surface 351b and the fourth guide surface 8351d are formed so as to face each other. Further, the minimum distance between the second guide surface 351b and the fourth guide surface 8351d is set to be larger than the external dimensions of the guided member 8344 in the lateral direction. As a result, the guided member 8344 can be moved by the second guide surface 351b and the fourth guide surface 8351d while restricting the moving direction. In the following description, the moving region of the guided member 8344 formed between the second guide surface 351b and the fourth guide surface 8351d facing each other will be referred to as a "second guide region".

The second guide surface 351b is extended in a direction in which the guide surface is parallel to the horizontal direction, and the fourth guide surface 8351d is the first guide in the circumferential direction of the second annular member 362 and the first part 371. It is formed as a guide surface toward the front side as it approaches the connecting portion with the surface 351a. Therefore, when the guided member 8344 moves on the second guide surface 351b side (front side) of the second guide region, the guided member 8344 moves in the circumferential direction of the second ring member 362 and the first part 371. The guided member 8344 is moved in the front-rear direction (arrow FB direction) with respect to the guide unit 350 by the amount of inclination of the second guide surface in the front-rear direction.

Further, when the guided member 8344 moves on the fourth guide surface 8351d side (rear side) of the second guide region, the guided member 8344 moves in the circumferential direction of the second ring member 362 and the first part 371. Moved to. In this case, since the guide surface of the fourth guide surface 8351d extends parallel to the horizontal direction, the guided member 8344 is not displaced in the front-rear direction (arrow FB direction) with respect to the guide unit 350. To.

Further, the connecting portion with the third guide surface 8351c and the fourth guide surface 8351d is provided with an accommodating portion 8351 m recessed on the back side guide unit 370 side along the guide surface of the third guide surface 8351c. The accommodating portion 8351m is an area for receiving the guided member 8344 guided in the first guide area and rotating the guided member 8344 in order to allow the guided member 8344 to enter the second guided area. The displacement of the guided member 8344 from the first guide region to the second guide region will be described later.

Next, the operation of the operation unit 8320 in the eighth embodiment will be described with reference to FIGS. 50 to 53. 50 (a), 51 (a), 52 (a) and 53 (a) are front views of the operation unit 8320 and the guide unit 8350, and FIGS. 50 (b) and 51 (b). 52 (b) and FIG. 53 (b) are side views of the operation unit 8320 and the guide unit 8350, which are 50 (c), 51 (c), 52 (c) and 53. (C) is a cross-sectional schematic view of the operation unit 8320 and the guide unit 8350.

In addition, in FIGS. 50 to 53, the transition state of the operation unit 8320 with respect to the guide unit 8350 is shown in order, and in FIGS. 50 (a) to 50 (c), the state in which the operation unit 8320 is arranged at the initial position is shown. 51 (a) to 51 (c) show the state in which the operation unit 8320 is arranged at the first position, and FIGS. 52 (a) to 52 (c) show the operation unit 8320 arranged at the first position. The state in which the operation unit 8320 is rotated with respect to the axial direction of the guide unit 8350 is shown, and FIGS. 53 (a) to 53 (b) show the state in which the operation unit 8320 is arranged at the terminal position. ..

As shown in FIG. 50, when the operation unit 8320 is arranged at the initial position, the circular portions 331a of the left and right cover members 331 and 332 of the gripping unit 330 of the operation unit 8320 and the center lines of the 331b are in the horizontal direction. Is placed parallel to. Further, the guided member 8344 arranged inside the guide groove 8351 is arranged on the first end portion 351e side of the first guide region.

Next, the operation unit 8320 is operated by the player, and the center lines of the circular portions 331a and 332a of the left and right cover members 331 and 332 of the gripping unit 330 are rotated clockwise in the front view, or the operation unit 320. Is operated by the player and the gripping unit 330 is pushed toward the back side (arrow B direction side), the guided member 334 of the rotating unit 340 fastened to the gripping unit 330 moves in the first guide region of the guide groove 351. To do.

As a result, as shown in FIG. 51, the gripping unit 330 is rotated clockwise in the front view. Further, the guided member 8344 disposed inside the guide groove 8351 slides in the first guide region and is arranged in the connecting portion (inside the accommodating portion 8351 m) between the first guide region and the second guide region. Will be done.

Third, when the operating unit 8320 is operated by the player and the gripping unit 330 is displaced in the extending direction of the center lines of the circular portions 331a and 332a of the left and right cover members 331 and 332 of the gripping unit 330, the gripping unit 330 is gripped. The guided member 8344 is rotated inside the guide groove 7244 with the displacement of the unit 330, and is arranged in a direction in which the longitudinal direction of the guided member 8344 is parallel to the extending direction of the second guide region. As a result, the guided member 8344 can be slidable in the second guide region.

Further, in the present embodiment, the displacement direction of the center lines of the circular portions 331a and 332a of the left and right cover members 331 and 332 of the gripping unit 330 of the operation unit 8320 in the extending direction is set upward. As a result, when the player stops the operation of the operation unit 8320 in the middle, the operation unit 8320 is moved to the first position (FIGS. 41 (a) to 41 (c)) by utilizing the load of the gripping unit 330. Can be displaced to position).

Finally, when the operating unit 8320 is further operated by the player and the gripping unit 330 is rotated clockwise in the front view, the guided member 8334 of the rotating unit 8340 to be fastened to the gripping unit 330 is formed in the guide groove 351. The second guide region is moved and arranged at a position where it comes into contact with the second end portion 351f.

In the second guide region, unlike the first guide region, the guide surface on the back side of the guide groove 351 to which the guided member 344 is guided extends in parallel with the horizontal direction, so that the player can hold the grip unit 330. When the guide unit side (back side (arrow B direction side)) is pushed, the guided member 344 does not move in the second guide area, and the guided member 344 stays in the connecting portion with the first guide area. It is considered to be in a state.

According to the operation unit 8320 of the eighth embodiment displaced as described above, the operation when the guided member 8344 moves in the first guide area and the operation when the guided member 8344 moves in the second guide area. An operation is required when the guided member 8344 makes the second guide area movable between the operations. As a result, it is possible to prevent the operation unit 8320 from being inadvertently displaced to the terminal position.

Next, the operation unit 320 and the guide unit 9350 according to the ninth embodiment will be described with reference to FIG. 54. In the first embodiment, the case where the guided member 344 moves between the first guide area and the second guide area has been described, but in the ninth embodiment, the guided member 344 moves between the first guide area and the second guide area. And 3 guide areas. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

54 (a) to 54 (c) are cross-sectional schematic views of the operation unit 320 and the guide unit 9350 according to the ninth embodiment. It should be noted that FIGS. 54 (a) to 54 (c) correspond to the cross sections of the operation unit 320 and the guide unit 9350 in FIG. 22 (d).

As shown in FIG. 54, the guide groove 9351 formed in the guide unit 9350 in the ninth embodiment includes the second annular member 362 of the front side guide unit 360 and the first part 371 of the back side guide unit 370. A portion extending in the circumferential direction, a portion extending in the axial direction (arrow FB direction) of the front side guide unit 360 and the rear side guide unit 370, and a portion extending in the circumferential direction on the front side. It includes a portion formed in a shape inclined toward.

Further, the guide groove 9351 includes a first guide surface 351a and a second guide surface 351b that serve as a guide surface (a wall surface that regulates the movement of the guided member 344) of the guided member 344 on the second ring member 362 side. , The third guide surface 351c and the fourth guide surface 351d which are the guide surfaces of the guided member 344 on the back side guide unit 370 side, the second ring member 362 of the front side guide unit 360, and the back side guide. From the connecting portion of the first end portion 351e and the second end portion 351f, the third guide surface 351c, and the fourth guide surface 351d, which are the peripheral ends of the first portion 371 of the unit 370, to the back side. It mainly includes a back-side recessed portion 9351k that is recessed toward the rear.

The back surface side recessed portion 9351k is formed with a groove width larger than the outer shape of the guided member 344, and extends toward the back surface side. Further, the back-side recessed portion 9351k is capable of moving the guided member 344 in the extending direction thereof, and the moving area thereof will be referred to as a "third guide area". The third guide region is formed so as to be connected to the connecting portion between the first guide region and the second guide region, and can accept the guided member 344 moving in the first guide region or the second guide region. To.

As a result, as shown in FIG. 54B, when the operating unit 320 is operated by the player and the gripping unit 330 is pushed toward the back side (arrow B direction side), the rotating unit 340 is fastened to the gripping unit 330. Guided member 334 moves in the first guide region of the guide groove 351. In this case, the guided member 344 is guided along the third guide surface 351c on the back side, and is inserted inside the recessed portion 9351k on the back side at the connecting portion between the first guide area and the third guide area. To. As a result, the guided member 344 that moves in the first guide region can be moved to the third guide region.

On the other hand, as shown in FIG. 54 (c), the operation unit 320 is operated by the player, and the center lines of the circular portions 331a and 332a of the left and right cover members 331 and 332 of the gripping unit 330 are rotated clockwise in the front view. When rotated, the guided member 334 of the rotating unit 340 fastened to the gripping unit 330 moves in the first guide region of the guide groove 351. In this case, the guided member 344 is guided along the first guide surface 351a on the front side, and is guided between the second guide surface 351b and the fourth guide surface 351d. As a result, the guided member 344 that moves in the first guide region can be moved to the second guide region.

According to the guide unit 9350 configured as described above, the displacement of the operation unit 320 can be changed by the difference in the operation direction of the operation unit 320 (selection of push operation or rotation operation). As a result, a plurality of operation patterns can be formed to make it easier for the player to enjoy the hobby.

A sensor device for detecting the displacement position of the operation unit 320 is provided, and whether the operation unit 320 is displaced to the second guide area (rotation operation is performed) or displaced to the third guide area (push operation is performed). It may be configured to detect at least.

Specifically, a detection unit (detection piece) is formed in the operation unit 320, and a sensor device that detects the detection unit (for example, an irradiation unit that irradiates light and light emitted from the irradiation unit can be received. (A device that detects the displacement position of the operation unit 320 based on the fact that the light receiving unit is provided so as to face each other and the detected portion of the operation unit 320 is arranged between them to block light). There are two locations, one on the displacement locus of the detected part when the operation unit 320 is displaced to the second guide area, and the other on the displacement locus of the detected part when the operation unit 320 is displaced to the third guide area. The configuration in which each is arranged is exemplified.

As a result, even with one operation unit 320, two types of inputs can be formed by the difference in the operation direction of the operation unit 320 (selection of push operation or rotation operation). Therefore, it is not necessary to provide the same number of operators (operation units 320) as the types of inputs (two in this embodiment), and the component cost can be reduced. Further, since a plurality of inputs (two types in the present embodiment) can be formed by one operator (operation unit 320), the operability of the player is improved (that is, it is not necessary to take the hand off the grip unit 330). It can be done) and it can be easily given to the player.

Next, the operation unit 10320 according to the tenth embodiment will be described with reference to FIGS. 55 to 57. In the first embodiment, the case where the gripping unit 330 and the rotating unit 340 are interlocked has been described, but in the tenth embodiment, the interlocking between the gripping unit 10330 and the rotating unit 340 can be released. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

First, the overall configuration of the operation unit 10320 will be described with reference to FIGS. 55 and 56. FIG. 55 (a) is a side view of the operation unit 10320 according to the tenth embodiment, and FIG. 55 (b) is a schematic cross-sectional view of the operation unit 10320 in the LVb-LVb line of FIG. 55 (a). FIG. 56 is an exploded perspective view of the gripping unit 10330.

As shown in FIGS. 55 and 56, the operation unit 10320 according to the tenth embodiment is a rotation connected to the gripping unit 10330 arranged on the front side and the back side (arrow B direction side) of the gripping unit 10330. It includes a unit 340 and.

The gripping unit 10330 is composed of an operator 10335 which is located on the front side and is formed in a circular shape in a side view, and a connecting member 10336 which is connected to the back side of the operator 10335.

The operator 10335 is arranged between the right side cover member 10331 arranged on the right side in the front view, the left side cover member 10332 arranged on the left side in the front view, the right side cover member 10331, and the left side cover member 10332. The vibration device 333 and the vibration device 333 are mainly provided.

The right side cover member 10331 includes a circular portion 331a formed in a circular plate shape and a right first wall portion 331c projecting from the outer edge of the circular portion 331a toward the left side cover member 10332 side (arrow L direction side). , The third wall portion 331e on the right side, which is located inside the first wall portion 331c on the right side and is erected in an annular shape from the circular portion 331a, and the shaft protruding from the circular portion 331a toward the back side in a semicircular columnar shape. The portion 10331g and the engaging portion 10331h projecting from the periphery of the shaft portion 10331g toward the back surface side are mainly provided.

The left side cover member 10332 is formed in substantially the same shape by reversing the right side cover member 10331 in the left-right direction (arrow LR direction), and the left side cover member 10332 is also a circular plate like the right side cover member 10331. More than the circular portion 332a formed in a shape, the left first wall portion 332c projecting from the outer edge of the circular portion 332a toward the right side cover member 10331 side (arrow R direction side), and the left side first wall portion 332c. The left third wall portion 332e located inside and erected in an annular shape from the circular portion 332a, the shaft portion 10332 g protruding from the circular portion 332a toward the back side in a semicircular columnar shape, and the shaft portion 10332 g. It mainly includes an engaging portion 10332h that protrudes from the periphery toward the back surface side.

Therefore, in the following description, the right side cover member 10331 will be described as a representative, and the description of the left side cover member 332 will be omitted. The differences between the right side cover member 331 and the left side cover member 332 will be described later.

The outer shape of the shaft portion 10331 g is made cylindrical by being combined with the shaft portion 10332 g of the left side cover member 10332. Further, the portion formed in a columnar shape by the shaft portions 10331 g and 10332 g is a shaft pivotally supported by the connecting member 10336 described later, and is a bulging portion that bulges outward in the radial direction at the tip on the insertion side (back surface side). It includes 10331 g1 and 10332 g1.

The outer diameters of the bulging portions 10331g1 and 10332g1 are larger than the inner diameters of the recessed portions 10331i and 10332i that are recessed in the connecting member 10336 described later in a semicircular shape. As a result, the connecting member 10336 is arranged from the outside of the shaft portions 10331g and 10332g, and the base end side of the shaft portions 10331g and 10332g is accommodated inside the recessed portions 10331i and 10332i. The operator 10335 can be pivotally supported in a rotatable state.

The engaging portion 10331h formed on the right side cover member 10331 projects below the shaft portion 10331g (in the direction of arrow D). On the other hand, the engaging portion 10332h formed on the left side cover member 10332 is projected above the shaft portion 10332g (in the direction of arrow U).

The connecting member 10336 mainly includes a right side connecting member 10336a arranged on the right side in the front view and a left side connecting member 10336b arranged on the left side in the front view. The right side connecting member 10336a is located on the back side of the above-mentioned right side cover member 10331, and the left side connecting member 10336b is located on the back side of the above-mentioned left side cover member 10332.

The right side connecting member 10336a has a protrusion 331b extending toward the back side (arrow B direction side) and a left side connecting member 10336b from an edge extending in the front-rear direction (arrow FB direction) of the protrusion 331b. The right second wall portion 331d projecting toward the side, the projecting portion 331f projecting from the back side end portion of the projecting portion 331b toward the back side, and the left side connection from the front side end portion of the projecting portion 331b. It includes a third wall portion 10331j on the right side that protrudes toward the member 10336b side.

The left side connecting member 10336b is formed to have substantially the same shape as the right side connecting member 10336a inverted in the left-right direction, and has a protrusion 332b extending toward the back side (arrow B direction side). The left second wall portion 332d projecting from the edge extending in the front-rear direction (arrow FB direction) of the setting portion 332b toward the right side connecting member 10336a, and the rear side end portion to the rear side of the projecting portion 332b. It includes a projecting portion 331f projecting toward the right side, and a left third wall portion 10332j projecting from the front side end portion of the projecting portion 331b toward the right side connecting member 10336a side. Therefore, in the following description, the right side connecting member 10336a will be described as a representative, and the description of the left side connecting member 10336b will be omitted.

The right third wall portion 10331j is formed at a position facing the back side of the right cover member 10331, and includes a recessed portion 10331i recessed in a semicircular shape at a position corresponding to the shaft portion 10331 g of the right cover member 10331. .. Further, an engaged portion 10331k is provided above the recessed portion 10331i.

The engaged portion 10331k is a protrusion that engages the right side cover member 10331 of the gripping unit 10330 and the engaging portion 10332h of the left side cover member 10332 when the left side cover member 10332 is rotated, and is a protrusion of the engaging portion 10332h. It is formed at a position that overlaps the displacement locus. When the operation unit 10320 is arranged at the initial position, the engaged portion 10331k and the engaging portion 10332h are arranged at adjacent positions (see FIG. 16B).

Further, as described above, since the operator 10335 is pivotally supported with respect to the connecting member 10336 in a rotatable state, when the operator 10335 is gripped by the player and is rotated clockwise in the front view. Is engaged with the engaged portion 10331k and the engaging portion 10332h (engaged portion 10332k and the engaging portion 10331h), and the connecting member 10336 is rotationally displaced as the operator 10335 rotates.

On the other hand, when the connecting member 10336 is rotated clockwise in the front view, the engagement between the engaged portion 10331k and the engaging portion 10332h (engaged portion 10332k and the engaging portion 10331h) is released, and the connecting member is released. Only 10336 is rotationally displaced.

Next, with reference to FIG. 57, the displacement of the operation unit 10320 when the player rotationally displaces the operation unit 10320 will be described. 57 (a) and 57 (b) are front views of the operation unit 10320 and the guide unit 350, and FIGS. 57 (c) and 57 (d) are cross-sectional views of the operation unit 10320. Note that FIGS. 57 (c) and 57 (d) correspond to the cross sections of the operation unit 10320 and the guide unit 350 in FIG. 55 (b). Further, in FIGS. 57 (a) and 57 (c), the operation unit 10320 at the initial position is shown, and in FIGS. 57 (b) and 57 (d), the operation unit 10320 at the first position is shown.

As shown in FIG. 57, when the operator 10335 of the operation unit 10320 is rotationally displaced, the engaged portion 10331k and the engaging portion 10332h (engaged portion 10332k and the engaging portion 10331h) are engaged with each other. The connecting member 10336 is rotationally displaced as the operator 10335 rotates. As a result, the rotating unit 340 to be fastened to the connecting member 10336 is rotationally displaced, and the guided member 344 of the rotating unit 340 is displaced along the guide groove 351 of the guide unit 350.

Next, with reference to FIG. 58, the displacement of the operation unit 10320 when the player pushes (slides) the operation unit 10320 toward the back side will be described. 58 (a) and 58 (b) are side views of the operation unit 10320 and the guide unit 350, and FIGS. 58 (c) and 58 (d) are cross-sectional views of the operation unit 10320. Note that FIGS. 58 (c) and 58 (d) correspond to the cross sections of the operation unit 10320 and the guide unit 350 in FIG. 55 (b). Further, in FIGS. 58 (a) and 58 (c), the operation unit 10320 at the initial position is shown, and in FIGS. 58 (b) and 58 (d), the operation unit 10320 at the position is shown.

As shown in FIG. 58, when the operator 10335 of the operation unit 10320 is pushed (sliding) toward the back side, the connecting member 10336 is pushed toward the back side in conjunction with the pushing operation. When the connecting member 10336 is pushed toward the back surface side, the rotating unit 340 to be fastened to the connecting member 10336 is pushed toward the back surface side. As a result, the guided member 344 of the rotating unit 340 is guided by the guide groove 351 of the guide unit 350, and the rotating unit 340 is rotated. Therefore, the connecting member 10336 to which the rotating unit 340 is fastened is also rotated as the rotating unit 340 rotates.

On the other hand, since the connecting member 10336 and the operator 10335 are not fastened, only the connecting member 10336 is rotated clockwise with respect to the operator 10335 in the front view. Therefore, in the tenth embodiment, when the player pushes the operation unit 10320, the operator 10335 is not rotated. Therefore, the operator 10335 opposes the hand or finger that the player presses the operator 10335. Is not rotated. Therefore, it is possible to make it easier for the player to operate the operation unit 10320.

Next, a case where the player rotates and displaces the operation unit 10320 counterclockwise will be described. When the operation unit 10320 is rotationally displaced counterclockwise, the engagement between the engaged portion 10331k and the engaging portion 10332h (engaged portion 10332k and the engaging portion 10331h) is released, and only the operator 10335 is released. It is rotated counterclockwise when viewed from the front.

Thereby, for example, when the player mistakenly rotates the operation unit 10320 counterclockwise in the front view, the player can be notified that the operation direction is wrong. Further, when the player who has finished the game stands up by grasping the operation unit 10320 as an aid when standing up, the front-view counterclockwise force input to the operator 10335 causes the operator 10335 to idle counterclockwise in the front view. Therefore, it is possible to prevent the force from being transmitted to the rotating unit 340. As a result, when the player grips the operator 10335 for a purpose other than operating the operation unit 10320, it is possible to prevent the operation unit 10320 from being damaged.

The counterclockwise idle rotation of the operator 10335 can be rotated to a position where the engaged portion 10331k and the engaging portion 10331h (engaged portion 10332k and the engaging portion 10332h) come into contact with each other (this implementation). In the form, the operator 10335 can be rotated approximately 160 degrees counterclockwise in the front view).

Further, the return of the operator 10335 rotated counterclockwise in the front view to the initial position is performed by a spring member (shown) interposed between the shaft portions 10331 g and 10332 g of the operator 10335 and the connecting member 10336. It is done by the urging force of (Z). As a result, it is possible to return the operator 10335 rotated counterclockwise in the front view to the initial position and maintain the operator 10335 in the initial position.

Next, the guide unit 11350 according to the eleventh embodiment will be described with reference to FIG. 59. In the first embodiment, the case where the guided member 344 is guided in the same region of the guide groove 351 by the displacement from the initial position to the terminal position of the operation unit 320 and the displacement from the terminal position to the initial position will be described. However, in the guide unit 11350 according to the eleventh embodiment, the guided member 344 covers different regions of the guide groove 11351 depending on the displacement of the operation unit 320 from the initial position to the terminal position and the displacement from the terminal position to the initial position. You will be guided. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

59 (a) is a front view of the guide unit 11350 according to the eleventh embodiment, and FIG. 59 (b) is a cross-sectional view of the guide unit 11350 in the LIXb-LIXb line of FIG. 59 (a).

As shown in FIG. 59, the guide unit 11350 according to the eleventh embodiment includes a front side guide unit 11360 arranged on the front side and a back side guide unit 11370 arranged on the back side of the front side guide unit 11360. And.

The front side guide unit 360 is formed by combining two members formed in an annular shape, and is a first annular member 361 arranged on the front side (arrow F direction side) and the first annular member 361 thereof. A second annular member 11362, which is arranged on the back surface side (the side in the direction of arrow B), is provided.

The second annular member 11362 includes a first cylindrical portion 11362a formed in a cylindrical shape, and a cylindrical second cylindrical portion 362b protruding from the outer peripheral surface of the first cylindrical portion 11362a and surrounding the first cylindrical portion 11362a. To be equipped.

The first cylindrical portion 11362a is located at a plurality of protruding portions 362a1 projecting from the inner peripheral surface and at the back end side (arrow B direction side) end of the first cylindrical portion 11362a, and is located on the inner peripheral surface side of the first cylindrical portion 11362a. The recessed portion 11362a2 is recessed toward the radial outer side of the first cylindrical portion 11362a, and is recessed from the inner peripheral surface side of the first cylindrical portion 11362a toward the radial outer side of the first cylindrical portion 11362a. It is provided with a storage recess 362a5.

The recessed portion 11362a2 is a portion in which the guided member 344 of the rotating unit 340 is arranged inside, and is formed over the entire circumference of the inner peripheral surface of the first cylindrical portion of 11362a. Further, the recessed portion 11362a2 is formed with points A (see FIG. 59 (b)) having a maximum distance recessed from the rear end side end portion to the front side at regular intervals in the circumferential direction. In the present embodiment, the intervals of the points A are formed at intervals of approximately 45 degrees in the circumferential direction.

Further, the recessed portion 11362a2 is formed so that one side connected to the point A is formed in a straight line toward the back surface side (the side in the direction of arrow B) and the other side is inclined in a straight line connected to the back surface side end portion on the one side. ..

The rear side guide unit 11370 stands on the front side along the outer edge of the first part 371 formed in an annular shape, the second part 11372 protruding from the first part 371 to the front side, and the outer edge of the first part 371. It is formed with a third part 373 to be provided.

The second portion 11372 projects toward the second annular member 362 side (front side) along the inner edge side of the first portion 371. The protruding tip surface of the second portion 11372 is predeterminedly spaced in the front-rear direction (arrow FB direction) from the end portion of the recessed portion 11362a2 of the second annular member 11362 described above (more than the diameter of the guided member 344). It is set at a position that separates it (a large distance).

As a result, the guide unit 11350 is formed with a guide groove 11351 that is recessed outward in the radial direction on a part of the inner peripheral surface. The guide groove 11351 is a groove for guiding the rotating unit 340 (see FIG. 16B), and the groove width is set to be larger than the outer shape of the guided member 344.

Further, a plurality of guide grooves 11351 are continuously formed in a predetermined shape in the circumferential direction, and are formed around the inner peripheral surface of the guide unit 11350.

The guide groove 11351 is a first guide surface 351a and a second guide surface that serve as a guide surface (a wall surface that regulates the movement of the guided member 344) of the guided member 344 on the second ring member 11362 side (front side). The 351b, the third guide surface 351c which is the guide surface of the guided member 344 on the back side guide unit 370 side (rear side), the fourth guide surface 351d, and the guide surface from the fourth guide surface 11351d to the front side. The fifth guide surface 11351 g and the sixth guide surface 11351h of the guide surface facing the front side from the second guide surface are mainly provided.

The fifth guide surface 11351 g and the sixth guide surface 11351 h are formed so as to face each other. Further, the distance between the fifth guide surface 11351 g and the sixth guide surface 11351 h facing each other is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 can be moved by the fifth guide surface 11351 g and the sixth guide surface 11351 h while restricting the moving direction. In the following description, the moving region of the guided member 344 formed between the fifth guide surface 11351 g and the sixth guide surface 11351 h facing each other will be referred to as a "third guide region".

Further, one end of the 5th guide surface 11351g is connected to the 4th guide surface 351d at the end opposite to the connection side with the 3rd guide surface 351c, and the end portion opposite to the connection side with the 4th guide surface 351d. The other end side is connected to the third guide surface 351c. That is, the fifth guide surface 11351 g connects the third guide surface 351c and the fourth guide surface 351d formed at positions adjacent to each other in the circumferential direction in the front-rear direction.

One end of the sixth guide surface 11351h is connected to the second guide surface 351b at the end opposite to the connection side with the first guide surface 351a, and the first end portion opposite to the connection side with the second guide surface 351b. The other end side is connected to the guide surface 351a. That is, the sixth guide surface 11351h connects the first guide surface 351a and the second guide surface 351b formed at positions adjacent to each other in the circumferential direction in the front-rear direction.

Therefore, one end of the third guide region formed between the fifth guide surface 11351 g and the sixth guide surface 11351 h is connected to the second guide region at the end opposite to the first guide region. , The other end side is connected to the first guide area at the end opposite to the connection side with the second guide area. As a result, a plurality of the first guide region to the third guide region can be continuously formed in the circumferential direction.

According to the guide groove 11351 formed as described above, the operation unit 320 (see FIG. 16A) receives no force from the outside of the slot machine 10 (see FIG. 1) into the operation unit 320 (by the player). In the case of non-operation), the rotating unit 340 is urged toward the front side (arrow F direction side) by the coil spring SP1 (see FIG. 14), so that the guided member 344 is the first guide surface. The guide is guided along the 351a (first guide region) or the third guide region to the connecting portion (point A side) between the first guide region and the third guide region. As a result, when the operation unit 320 is not operated, the operation unit 320 is stopped (maintained) at a position pushed out to the front side.

The sixth guide surface 11351h is provided with an inclined surface 11351h1 at a connecting portion with the first guide region (first guide surface 351a). The inclined surface 11351h1 is a surface that guides the guided member 344, which guides the third guide region from the back side to the front side, to the first guide region by using the urging force of the coil spring SP1 toward the front side. , The operation unit 320 is formed so as to be inclined in a direction opposite to the inclination direction of the first guide surface 351a with respect to the pushing (sliding) direction. Further, the guided member 344, which is guided by the inclined surface 11351h1 and is arranged in the first guide region, is arranged at a position where the center thereof overlaps with the third guide surface 351c in the pushing (sliding) direction of the operation unit 320. As a result, when the operation unit 320 after the guided member 344 is guided from the third guide area to the first guide area along the inclined surface 11351h1 is pushed toward the back side, the guided member 344 is pushed into the second guide member 344. 3 It is possible to guide along the guide surface 351c.

Next, the operation unit 320 is operated by the player to rotate the grip unit 330 clockwise in the front view, or the operation unit 320 is operated by the player and the grip unit 330 is on the back side (arrow B direction side). When pushed into, the guided member 334 of the rotating unit 340 fastened to the gripping unit 330 moves in the first guide region of the guide groove 11351.

Therefore, when the gripping unit 330 is rotated clockwise in the front view, the guided member 344 of the rotating unit 340 fastened to the gripping unit 330 is moved in the first guide region of the guide groove 11351. In this case, the rotating unit 340 (operation unit 320) is inserted inside the guide unit 11350 as the guided member 344 is moved to the back side (arrow B direction side) with respect to the guide unit 11350. It is displaced in the direction (back side).

After the guided member 344 moves in the first guide region, when the gripping unit 330 is continuously rotated clockwise in the front view, the guided member 334 of the rotating unit 340 to be fastened to the gripping unit 330 is moved to the guide groove 11351. The second guide region of the above is moved and comes into contact with the fifth guide surface 11351 g. As a result, the clockwise rotation of the operation unit 320 in the front view is restricted.

When the player does not operate the operation unit 320 from the position where the clockwise rotation of the operation unit 320 is restricted (the position where the guided member 344 comes into contact with the fifth guide surface 11351 g), the operation unit 320 is not operated. The rotating unit 340 is pushed out to the front side by the urging force of the coil spring SP1, and the guided member 344 moves in the third guide region. Therefore, the operation unit 320 can be pushed out to the front side at a position where the clockwise rotation of the operation unit 320 is restricted, and the operation unit 320 can be arranged at the initial position. That is, each time the operation unit 320 is rotated clockwise in the front view, the initial position of the operation unit 320 is changed to a position rotated clockwise by a certain amount.

In this case, since the third guide region is formed so that the distance for moving the guided member 344 is shorter than the region where the first guide region and the second guide region are combined, the operation unit 320 is continuously played a plurality of times. When a person operates the operation unit 320, the time required for the operation unit 320 to return to the initial position can be shortened so that the operation unit 320 can be continuously rotated clockwise in the front view a plurality of times. As a result, it is possible to suppress a decrease in the interest of the player.

On the other hand, the player rotates the operation unit 320 on the opposite side (counterclockwise in the front view) from the position where the clockwise rotation of the operation unit 320 is restricted (the position where the guided member 344 comes into contact with the fifth guide surface 11351 g). When the operation of the operation unit 320 is not operated after rotating to, the rotation unit 340 is pushed out to the front side by the urging force of the coil spring SP1, and the guided member 344 is pushed to the second guide surface 351b and the second guide surface 351b. It is moved to the front side along the first guide surface 351a. Therefore, the operation unit 320 that is moved to the initial position is arranged at the same rotation position (phase) in the front view of the operation unit 320 before the operation.

Therefore, in the eleventh embodiment, the operation unit 320 is frontally operated depending on whether or not the player operates the operation unit 320 counterclockwise in the front view at a position where the rotation operation of the operation unit 320 in the clockwise direction in the front view is restricted. The rotation position when pushed out toward the side can be changed. As a result, since the operation of the operation unit 320 can be given a variation, it is possible to easily give the player an interest.

Further, when the operation unit 320 at the initial position is pushed toward the back side (arrow B direction side) by the player and the guided member 344 moves in the first guide area, the guided member 344 moves to the second guide area. The movement of the guided member 344 is restricted at the connecting portion between the first guide region and the second guide region in contact with the fourth guide surface 351d.

After the guided member 344 comes into contact with the fourth guide surface 351d in the second guide region and its movement is restricted, when the player does not operate the operation unit 320, the rotation unit 340 is a coil spring. The guided member 344 is pushed to the front side by the urging force of SP1 and is moved to the front side along the first guide surface 351a. Therefore, the operation unit 320 that is moved to the initial position is arranged at the same rotation position (phase) in the front view of the operation unit 320 before the operation.

On the other hand, when the operation unit 320 is rotated clockwise in the front view after the guided member 344 comes into contact with the fourth guide surface 351d in the second guide region and its movement is restricted, the operation is performed from the initial position. Similar to the case where the unit 320 is rotated, the guided member 334 moves in the second guide region of the guide groove 11351 and comes into contact with the fifth guide surface 11351 g, so that the operation unit 320 rotates clockwise in the front view. Be regulated.

Therefore, in the eleventh embodiment, the operation of the operation unit 320 in which the rotation position (phase) of the operation unit 320 arranged at the initial position changes in the front view and the rotation position of the operation unit 320 arranged in the initial position in the front view The operation of the operation unit 320 having the same (phase) can be performed. Therefore, since variations can be provided in the operation method of the operation unit 320, the interest of the player can be enhanced.

In the eleventh embodiment, in order to detect the position of the operation unit 320 in the front-rear direction, a columnar detection piece (not shown) is projected from the back side of the rotation unit 340 at the rotation center of the operation unit 320. A sensor device (not shown) for detecting the detection piece at a position where the operation unit 320 is moved to the rear side is arranged in the base unit 391 (see FIG. 14). Thereby, the movement of the operation unit 320 to the rear side can be detected regardless of the phase in which the operation unit 320 is arranged in the front view.

Further, the rotating unit 340 is provided with a plurality of protrusions (not shown) projecting toward the front side on the same circumference centered on the rotating shaft of the operating unit 320. Further, the plurality of protrusions are distributed and arranged over a half circumference around the rotation axis of the operation unit 320. Further, the plurality of protrusions are formed at a distance from the adjacent protrusions by the amount that the initial position of the operation unit 320 is rotated in the front view by one rotation operation of the operation unit 320.

On the other hand, in the reduced diameter portion 361b of the front side guide unit 360 of the guide unit 11350, a plurality of detection sensors for detecting the protrusions are arranged at positions facing the plurality of protrusions of the operation unit 320 arranged at the initial position. Will be done. As a result, the detection positions and the number of detections of the plurality of protrusions can be detected by the plurality of detection sensors, and the phase of the operation unit 320 at the initial position can be detected.

Further, in order to prevent the wiring connected to the operation unit 320 from being entangled due to the rotational displacement of the operation unit 320, the wiring is connected to the operation unit 320 after passing through the rotation center position of the rotation unit 340. A rotary connector or a slip ring is provided in a part of the wiring.

Next, the guide groove 12351 of the guide unit 12350 in the twelfth embodiment will be described with reference to FIG. 60. In the first embodiment, the case where the first end portion 351e and the second end portion 351f of the guide groove 351 are formed as separate members (front side guide unit 360 and back side guide unit 370) has been described. In the twelfth embodiment, the first end portion 12351e and the second end portion 351f of the guide groove 12351 are formed in the same member (rear side guide unit 370). The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 60 (a) is a cross-sectional view of the guide unit 12350 according to the twelfth embodiment, and FIG. 60 (b) is an exploded cross-sectional view of the guide unit 12350.

As shown in FIG. 60, the guide groove 12351 of the guide unit 12350 in the twelfth embodiment has the second ring member 362 of the front side guide unit 360 and the back surface thereof, similarly to the guide groove 351 of the first embodiment. The side guide unit 370 extends in the circumferential direction of the first portion 371, and a part of the side guide unit 370 is formed in a shape inclined toward the back surface side.

Further, the guide groove 12351 is a first guide surface 351a and a second guide surface 351a serving as a guide surface (a wall surface for restricting the movement of the guided member 344) of the guided member 344 on the second annular member 362 side (front side). The guide surface 351b, the third guide surface 351c which is the guide surface of the guided member 344 on the back side guide unit 370 side (rear side), the fourth guide surface 351d, and the second ring of the front side guide unit 360. Mainly includes a member 362, a first end portion 12351e which is an end portion in the circumferential direction of the first portion 371 of the rear side guide unit 370, and a second end portion 351f.

The first end portion 12351e in the twelfth embodiment is formed on the front side guide unit 360. Similarly, the second end portion 351f is also formed on the front side guide unit 360. These both end portions (first end portion 12351e and second end portion 351f) are portions that define the operation end point of the operation unit 320, and are easily damaged because the guided member 344 collides with them. Therefore, both ends (first end 12351e and second end 351f) are formed on the same member (front side guide unit 360), so that both ends (first end 12351e and second end) are used. When the portion 351f) is damaged, only one member (front side guide unit 360) needs to be replaced, and it is not necessary to replace two members of the front side guide unit 360 and the back side guide unit 370. As a result, both ends of the guide groove 12351 can be replaced.

In particular, the front side guide unit 360 has a higher rigidity than the back side guide unit 370 because it is formed in a cylindrical shape continuous in the circumferential direction and a plurality of protrusions 362a1 are extended at predetermined intervals. Therefore, it is easy to suppress damage when the guided member 344 collides with both end portions (first end portion 12351e and second end portion 351f). Therefore, the exchange cycle can be lengthened.

Next, the guide groove 13351 of the guide unit 13350 in the thirteenth embodiment will be described with reference to FIG. 61. In the first embodiment, the case where the first end portion 351e and the second end portion 351f of the guide groove 351 are formed as separate members (front side guide unit 360 and back side guide unit 370) has been described. In the thirteenth embodiment, the first end portion 351e and the second end portion 13351f of the guide groove 13351 are formed in the same member (rear side guide unit 370). The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 61 (a) is a cross-sectional view of the guide unit 13350 according to the thirteenth embodiment, and FIG. 61 (b) is an exploded cross-sectional view of the guide unit 13350 according to the thirteenth embodiment.

As shown in FIG. 61, the guide groove 13351 of the guide unit 13350 in the thirteenth embodiment has the second annular member 362 of the front side guide unit 360 and the back surface thereof, similarly to the guide groove 351 of the first embodiment. The side guide unit 370 extends in the circumferential direction of the first portion 371, and a part of the side guide unit 370 is formed in a shape inclined toward the back surface side.

Further, the guide groove 13351 is a first guide surface 351a and a second guide surface 351a serving as a guide surface (a wall surface for restricting the movement of the guided member 344) of the guided member 344 on the second annular member 362 side (front side). The guide surface 351b, the third guide surface 351c which is the guide surface of the guided member 344 on the back side guide unit 370 side (rear side), the fourth guide surface 351d, and the second ring of the front side guide unit 360. It mainly includes a member 362, a first end portion 351e which is an end portion in the circumferential direction of the first portion 371 of the rear side guide unit 370, and a second end portion 13351f.

The second end portion 13351f in the thirteenth embodiment is formed on the back side guide unit 370. Similarly, the first end portion 351e is also formed on the back side guide unit 370. These both end portions (first end portion 12351e and second end portion 351f) are portions that define the operation end point of the operation unit 320, and are easily damaged because the guided member 344 collides with them. Therefore, both ends (first end 12351e and second end 351f) are formed on the same member (rear side guide unit 370), so that both ends (first end 12351e and second end) are used. When the portion 351f) is damaged, only one member (rear side guide unit 370) needs to be replaced, and it is not necessary to replace two members of the front side guide unit 360 and the back side guide unit 370.

In particular, since the back side guide unit 370 is a member forming the back side of the guide unit 13350, it is easy to replace only the back side guide unit 370. For example, in a configuration in which both ends (first end 12351e and second end 351f) are formed on the front guide unit 360, the back guide unit 370 is removed and the front guide unit 360 is a first ring member. It is also necessary to disassemble the 361 and the second ring member 362, and to remove the operation unit 320 at the time of this disassembly.

On the other hand, if both ends (first end 12351e and second end 351f) are formed on the back guide unit 370, only the back guide unit 370 may be removed, and the front guide unit 360 may be removed. It is not necessary to disassemble the first ring member 361 and the second ring member 362, and it is not necessary to remove the operation unit 320. Therefore, the replacement man-hours can be reduced and the replacement cost can be reduced.

Next, the guide unit 14350 according to the 14th embodiment will be described with reference to FIG. 62 (a). In the first embodiment, the case where the displacement directions of the first guide region and the second guide region of the guide groove 351 in the circumferential direction are set to be the same has been described, but the guide groove 14351 in the 14th embodiment is the first. The displacement directions of the first guide region and the second guide region in the circumferential direction are set to be opposite to each other. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 62A is a cross-sectional view of the guide unit 14350 according to the 14th embodiment. The cross section of FIG. 62 (a) corresponds to the cross section of FIG. 23 (d).

As shown in FIG. 62 (a), the guide groove 14351 of the guide unit 14350 in the 14th embodiment is the second annular member 362 of the front side guide unit 360 and the first part 371 of the back side guide unit 370. It extends in the circumferential direction, and a part of it is formed in a shape that inclines toward the back side.

Further, the guide groove 14351 is a first guide surface 351a and a second guide surface that serve as a guide surface (a wall surface that regulates the movement of the guided member 344) of the guided member 344 when the operation unit 320 is rotated. 14351b, the third guide surface 351c which becomes the guide surface (the wall surface which regulates the movement of the guided member 344) of the guided member 344 when the operation unit 320 is pushed in, and the fourth guide surface 14351d and the circumference. It includes three first end portions 351e, a second end portion 14351f, and a third end portion 14351i formed at the end portions in the direction.

The second guide surface 14351b and the fourth guide surface 14351d are formed so as to face each other. Further, the second guide surface 14351b and the fourth guide surface 14351d are the ends of the first guide region (first end portion 351e) formed between the first guide surface 351a and the third guide surface 351c facing each other. It is connected to the end on the opposite side of the first guide region and extends in the horizontal direction (direction orthogonal to the rotation axis of the operation unit 320) from the end of the first guide region. That is, the second guide region formed between the second guide surface 14351b and the fourth guide surface 14351d facing each other is formed with the second end portion 14351f as the start end and the third end portion 14351i as the end end.

The minimum distance between the second guide surface 14351b and the fourth guide surface 14351d is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 can be moved on the second guide surface 14351b and the fourth guide surface 14351d while restricting the moving direction.

In the fourteenth embodiment, the moving direction of the guided member 344 in the circumferential direction when moving the first guide area toward the second plan area and the second guide area toward the end (third end portion 14351i). The moving direction of the guided member 344 in the circumferential direction is set to be opposite to that of the guided member 344.

Therefore, in order to displace the operation unit 320 from the initial position to the end position, the player needs to switch the rotation direction of the operation unit 320 to the opposite direction (for example, from right rotation to left rotation) on the way. As a result, it is possible to make the player perform complicated operations of the operation unit, and it is possible to suppress the deterioration of the player's interest.

Further, since the second guide region (fourth guide surface 14351d) extends in the horizontal direction (direction orthogonal to the rotation axis of the operation unit 320), the guided member 344 is operated by pushing the operation unit 320. Cannot be moved along the second guide region to the third end 14351i.

Further, the moving direction of the guided member 344 from the start end to the end in the second guide region is set to be the same as the moving direction of the guided member 344 by the urging force of the coil spring SP2 (see FIG. 27A). Since the second guide surface 14351b, which is pushed out to the front side by the urging force of the coil spring SP1 (see FIG. 14) and comes into contact with the guided member 344, extends in the horizontal direction, it is guided to the end of the second guide region. The guided member 344 can be maintained in contact with the third end portion 14351i.

As a result, when returning the operation unit 320 in a state where the guided member 344 is guided to a position where the guided member 344 comes into contact with the third end portion 14351i to the initial position, the player operates the operation of rotating the operation unit 320 clockwise in the front direction. Can be made to. Therefore, the operation of the operation unit 320 can be complicated, and it is possible to prevent the operation of the operation unit 320 from becoming monotonous and deteriorating the interest of the player.

Further, since the rotation direction when the operation unit 320 arranged at the terminal position is returned and the rotation direction when the operation unit 320 arranged at the initial position is displaced can be the same direction, the player can use the same direction. It is possible to prevent the operation unit 320 from making a mistake in the rotation direction.

In this way, the operation of displacementing the operation unit 320 from the initial position (the position where the guided member 344 is arranged at the first end portion 351e) to the terminal position (the position where the guided member 344 reaches the third end portion 14351i). As a result, the player can be required to perform a two-step operation (an operation of switching the rotation direction in the middle). Therefore, it is possible to prevent the operation feeling from becoming monotonous. Further, it is possible to prevent the operation unit 320 from being displaced to the terminal position (the position where the guided member 344 reaches the third end portion 14351i) only by the pushing operation. That is, the operation unit 320 can be prevented from being displaced to the terminal position by a careless operation of the player.

Next, the guide unit 15350 according to the fifteenth embodiment will be described with reference to FIG. 62 (b). In the first embodiment, the case where the displacement directions of the first guide region and the second guide region of the guide groove 351 in the circumferential direction are set to be the same has been described, but the guide groove 15351 in the fifteenth embodiment is the first. The displacement directions of the first guide region and the second guide region in the circumferential direction are set to be opposite to each other. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 62B is a cross-sectional view of the guide unit 15350 according to the fifteenth embodiment. The cross section of FIG. 62 (b) corresponds to the cross section of FIG. 23 (d).

As shown in FIG. 62B, the guide groove 15351 of the guide unit 15350 in the fifteenth embodiment is formed by the second annular member 362 of the front side guide unit 360 and the first part 371 of the back side guide unit 370. It extends in the circumferential direction and is formed in a shape that inclines toward the back side as a whole.

The guide groove 15351 includes a first guide surface 351a and a second guide surface 15351b that serve as a guide surface (a wall surface that regulates the movement of the guided member 344) of the guided member 344 when the operation unit 320 is rotated. The third guide surface 351c and the fourth guide surface 15351d, which are the guide surfaces of the guided member 344 (the wall surface that regulates the movement of the guided member 344) when the operation unit 320 is pushed in, are in the circumferential direction. It includes three first end portions 351e, a second end portion 15351f, and a third end portion 15351i formed on the end portions.

The second guide surface 15351b and the fourth guide surface 15351d are formed so as to face each other. Further, the second guide surface 15351b and the fourth guide surface 15351d are the ends of the first guide region (first end portion 351e) formed between the first guide surface 351a and the third guide surface 351c facing each other. It is connected to the end on the opposite side to the first guide region) and extends in the circumferential direction while inclining from the end of the first guide region to the side opposite to the first guide region. That is, the second guide region formed between the second guide surface 15351b and the fourth guide surface 15351d facing each other is formed with the second end portion 15351f as the start and the third end portion 15351i as the end.

The minimum distance between the second guide surface 15351b and the fourth guide surface 15351d is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 can be moved on the second guide surface 15351b and the fourth guide surface 15351d while restricting the moving direction.

When the player pushes (slides) the operation unit 320 toward the back side, the third guide surface 351c in the first guide area and the fourth guide surface 15351d in the second guide area are used. , The guided member 344 can be moved. Therefore, when the player pushes the operation unit 320 toward the back side and displaces it, the operation unit 320 can be displaced from the initial position to the end position without having to change the displacement direction of the operation unit 320.

In the fifteenth embodiment, the moving direction of the guided member 344 in the circumferential direction when moving the first guide area toward the second plan area and the second guide area toward the end (third end portion 14351i). The moving direction of the guided member 344 in the circumferential direction is set to be opposite to that of the guided member 344.

Therefore, in order to displace the operation unit 320 from the initial position to the end position, the player needs to switch the rotation direction of the operation unit 320 to the opposite direction (for example, from right rotation to left rotation) on the way. As a result, it is possible to make the player perform complicated operations of the operation unit, and it is possible to suppress the deterioration of the player's interest.

Further, in the fifteenth embodiment, since the second guide region (fourth guide surface 14351d) is inclined and extended, the guided member 344 can be pushed along the second guide region even by the pushing operation of the operation unit 320. It can be moved to the third end 14351i.

In this way, the operation of displacementing the operation unit 320 from the initial position (the position where the guided member 344 is arranged at the first end portion 351e) to the terminal position (the position where the guided member 344 reaches the third end portion 14351i). As for the rotation operation, the player can be required to perform a two-step operation (an operation of switching the rotation direction in the middle). Therefore, it is possible to prevent the operation feeling from becoming monotonous. On the other hand, in the case of the pushing operation, the operation unit 320 is moved from the initial position (the position where the guided member 344 is arranged at the first end 351e) to the end position (the position where the guided member 344 reaches the third end 14351i). ) Can be displaced by one-way operation.

That is, in either the rotation operation or the pushing operation, the operation unit 320 is moved from the initial position (the position where the guided member 344 is arranged at the first end portion 351e) to the end position (the guided member 344 is the third). Since it can be displaced to the end (position reaching the end 14351i), the player can arbitrarily select the type of operation. As a result, it is possible to give a variation to the operation feeling.

Although the present invention has been described above based on the above-described embodiment, the present invention is not limited to the above-described embodiment, and it is easy to make various modifications and improvements within a range that does not deviate from the gist of the present invention. It can be inferred.

In each of the above embodiments, a game machine may be configured by replacing or combining a part or all of one embodiment with a part or all of another one or a plurality of other embodiments.

In the first embodiment, the case where the back side guide unit 370 is formed of one member in which the first part 371 and the second part 372 are connected has been described, but the present invention is not necessarily limited to this. For example, the back side guide unit 370 may form the first part 371 and the second part 372 from different members, and assemble the first part 371 and the second part 372.

In this case, by forming the first part 371 and the second part 372 separately, the shapes of the first part 371 and the second part 372 can be easily complicated. As a result, the degree of freedom in designing the back side guide unit 370 can be improved, and the variation in the moving direction of the guided member 344 displaced along the back side guide unit 370 can be increased.

In the first embodiment, the second guide surface 351b of the guide groove 351 is inclined so as to approach the front side (arrow F direction side) and extend in the circumferential direction as it approaches the connecting portion with the first guide surface 351a. When the operation unit 320, which is formed as a guide surface and is guided to a position where the guided member 344 comes into contact with the second end portion 351f, is not operated, the urging force on the front side of the coil spring SP1 causes the first operation unit 320. 2 The case where the guided member 344 is guided to the first guide region along the guide surface 351b has been described, but the present invention is not necessarily limited to this.

For example, the extension direction of the second guide surface 351b in the circumferential direction of the second annular member 362 may be extended in parallel with the horizontal direction, or the second guide surface in the circumferential direction of the second annular member 362 may be extended. The extension direction of the 351b may be extended in a direction close to the front side while being away from the first guide surface 351a.

In this case, it is possible to prevent the guided member 344 from moving to the first guide region side due to the urging force on the front side of the coil spring SP1. That is, the guided member 344 can be maintained at a position where it abuts on the second end portion 351f. Therefore, when returning the operation unit 320 in the state where the guided member 344 is guided to the position where the guided member 344 comes into contact with the second end portion 351f to the initial position, the player is required to rotate the operation unit 320 counterclockwise in the front direction. Can be made to. Therefore, the operation of the operation unit 320 can be complicated, and it is possible to prevent the operation of the operation unit 320 from becoming monotonous and deteriorating the interest of the player.

When the guided member 344 of the rotating unit 340 is guided toward the first guide region side by the urging force of the coil spring SP2 of the base unit 391, the second guide in the circumferential direction of the second annular member 362 By increasing the inclination angle of the surface 351b toward the front side, the guided member 344 can be maintained at a position where it abuts on the second end portion 351f.

Further, when the extension direction of the second guide surface 351b in the circumferential direction of the second ring member 362 is extended in parallel with the horizontal direction, when the operation unit 320 is rotated from the initial position to the end position, By guiding the guided member 344 to the first guide area and the second guide area, which have different extension directions, the slide displacement to the rear side with respect to the rotation amount of the operation unit 320 is not generated during the rotation of the operation unit 320. It is considered to be displacement. That is, the slide displacement to the rear side is not formed while the operation unit 320 is rotationally displaced. As a result, the operation of the operation unit 320 can be enjoyed.

In the fifth embodiment, the case where the displacement unit 5395 is suppressed from being displaced to the front side of the base plate 5392a by the two hook portions 5396m has been described, but the present invention is not necessarily limited to this. For example, one end side (rear side) of the roller 5396j formed in an annular shape in the axial direction is expanded in diameter beyond the width of the sliding groove 5392a2, and the displacement unit 5395 is displaced to the front side of the base plate 5392a by the roller 5396j. You may suppress doing. In this case, after the displacement unit 5395 is arranged in front of the base plate 5392a, the roller 5396j is attached and the displacement unit 5395 is arranged on the base unit 5391.

In the fifth embodiment, the size of the engagement hole 5396b1 about the center of the main body 396a in the circumferential direction is substantially the same as the size of the engagement piece 342b about the center of the main body 396a in the circumferential direction. The case where the displacement unit 5395 and the displacement unit 320 are set and the displacements of the displacement unit 5395 and the operation unit 320 are always linked has been described, but the present invention is not necessarily limited to this.

For example, the size of the engaging hole 5396b1 about the center of the main body 396a in the circumferential direction may be set larger than the size of the engaging piece 342b about the center of the main body 396a in the circumferential direction. In this case, the gap between the engaging hole 5396b1 and the engaging piece 342b in the circumferential direction about the center of the main body 396a is provided with a difference between the timing at which the displacement unit 5395 is operated and the timing at which the operation unit 320 is operated. Can be done.

In the fifth embodiment, the roller 5396j arranged on the rotating shaft portion 5396i of the first displacement member 5396 and the sliding groove 5392a2 of the base member 5392 are used to determine the displacement direction of the first displacement member 5396 (displacement unit 5395). The case of regulation has been explained, but it is not necessarily limited to this.

For example, assuming that the rotating shaft portion 5396i of the first displacement member 5396 is not formed (the roller 5396j is not mounted), the displacement directions of the first displacement member 5396 (displacement unit 5395) are set at two hook portions 5396m and the base member 5392. It may be regulated by the sliding groove 5392a2. In this case, since the two hook portions 5396m are formed so as to be elastically deformable, the tooth portion 5396k of the first displacement member 5396 and the pinion 5398a are in a poorly engaged state, and the resistance between the tooth portion 5396k and the pinion 5398a is large. When this is done, the tooth portion 5396m can be elastically deformed to stabilize the tooth engagement between the tooth portion 5396k and the pinion 5398a.

In this case, it is preferable that the distance between the two hook portions 5396m in the radial direction of the main body portion 396a on the outer side in the opposite direction is set to be substantially the same as the width direction of the sliding groove 5392a2. As a result, when the hook portion 5396m is elastically deformed in the direction in which the hook portion 5396m is disengaged from the sliding groove 5392a2, it is possible to prevent the tip of the hook portion 5396m and the base plate 5392a from being overlapped in the front-rear direction. .. As a result, it is possible to prevent the hook portion 5396 m from being disengaged from the sliding groove 5392a2.

Further, the two hook portions 5396m are in a state in which the hook portions 5396m are elastically deformed by setting the distance between the outer sides of the main body portion 396a in the radial direction facing each other to be larger than the width direction of the sliding groove 5392a2. May be engaged with the sliding groove 5392a2. In this case, since the force required for elastic deformation of the hook portion 5396m in the direction of disengaging the sliding groove 5392a2 can be increased, the engagement between the hook portion 5396m and the sliding groove 5392a2 is released. Can be suppressed.

In the seventh embodiment, the case where the second convex portion 7392f2 is formed on the regulation piece 7392f and the concave portion 7397f1 is formed on the second displacement member 7397 has been described, but the present invention is not necessarily limited to this. For example, a concave portion may be formed in the regulation piece 7392f and a convex portion may be formed in the second displacement member 7397. When the displacement unit 7395 is arranged at the initial biasing position, the regulation piece 7392f and the second displacement member may be formed. Anything that engages with 7397 will do.

In the tenth embodiment, the case where the operator 10335 is formed so as to be able to rotate counterclockwise in the front view with respect to the connecting member 10336 has been described, but the present invention is not necessarily limited to this. For example, when the bulging portion 10331g1, 10332g1 of the operator 10335 is deformed and the operating operator 10335 is rotated counterclockwise in the front view, the bulging portion 10331g1, 10332g2 is attached to the protruding portions 331b and 332b of the connecting member 10336. It may be abutted to regulate the counterclockwise rotation of the operator 10335 in the front view.

In this case, since it is not necessary for the operation unit 10320 to have a means (for example, a spring member) for returning the operator 10335 to the initial position, the number of parts of the operation unit 10320 can be reduced. Moreover, the assembly of the operation unit 10320 can be simplified.

In the tenth embodiment, the case where the operator 10335 rotated counterclockwise in the front view is returned to the initial position by the urging force of the spring member has been described, but the present invention is not necessarily limited to this, and for example, the operation. The center of gravity of the child 10335 is set to the lower position of the operator 10335 arranged at the initial position, and the operator 10335 rotated counterclockwise in the front view is returned to the initial position by its own weight. It may be.

In the eleventh embodiment, the case where the guide groove 11351 is formed from the first guide region, the second guide region, and the third guide region has been described, but the present invention is not necessarily limited to this, and for example, the second guide region is not limited to this. The guide groove 111351 may be formed only by the first guide region and the third guide region.

In this case, when the player pushes the operation unit 320 toward the back side, the guided member 344 that moves in the first guide area is moved along the third guide surface 351c, and the third guide is moved from the first guide area. Moved to the area. Therefore, when the player does not operate the operation unit 320 after pushing the operation unit 320, the rotating unit 340 is pushed out to the front side by the urging force of the coil spring SP1 and the guided member 344 is guided to the third guide. Move the area towards the front.

Since the third guide area is formed so that the distance for moving the guided member 344 is shorter than that in the first guide area, the initial position of the operation unit 320 when the player operates the operation unit 320 a plurality of times in succession. The time required for returning to is shortened, and the operation unit 320 can be easily operated a plurality of times in succession. As a result, it is possible to suppress a decrease in the interest of the player.

In the eleventh embodiment described above, in order to detect the position of the operation unit 320 in the front-rear direction, a case where a columnar detection piece is projected from the back side of the rotation unit at the center of rotation of the operation unit 320 has been described, but it is not always the case. It is not limited to this. For example, an annular protrusion about the center of rotation of the operation unit 320 may be projected from the back surface side of the rotation unit 340, and the sensor device may be arranged at a position where the protrusion can be detected.

In the first, third to fifth, and seventh embodiments, the case where the displacement units 395, 3395, 5395, and 7395 are rotationally displaced when viewed from the front has been described. However, the displacement units 395, 3395, 5395, and 7395 have been described in the above-mentioned first embodiment. The displacement units 2395 and 4395 in the 2nd and 4th embodiments may be linearly displaced. On the contrary, in the second and fourth embodiments, the case where the displacement units 2395 and 4395 are linearly displaced has been described, but the displacement units 395, 3395, 5395 and 7395 in the first, third to fifth and seventh embodiments have been described. It may be rotationally displaced.

The displacement units 395, 2395, 3395, 4395, 5395, and 7395 in the first to seventh embodiments may be combined, respectively.

In the above embodiment, an example in which the present invention is embodied with respect to the slot machine 10 is shown, but the present invention may be applied to a gaming machine in which a slot machine and a pachinko machine are fused. That is, among the slot machines, instead of the medal insertion and medal payout functions, a gaming machine having ball throwing and ball payout functions such as a pachinko machine may be used. If such a game machine is used instead of a slot machine, only the ball can be treated as a game value in the game hall. Therefore, a medal that is a game value in the current game hall where pachinko machines and slot machines are mixed. It is possible to solve problems such as the burden on the equipment and restrictions on the location of the gaming machine due to the separate handling of the ball and the ball.

It is also possible to apply the present invention to pachinko machines. In the case of a pachinko machine, the game machine main body is attached to the outer frame, and a door member is provided on the front side of the game machine main body. The game machine main body is equipped with a game board in which a game area as a game ball flight area is formed and an operation port and a liquid crystal display device are installed. The display device is visible. Then, as the game ball launched by the game ball launcher wins a prize in the operating port, an internal lottery is performed and a variable display of the pattern is performed on the liquid crystal display device. Even when the configuration of the display control device and the sub control device of the above embodiment is applied to such a pachinko machine, it is clear that the same functions and effects as those of the above embodiment are exhibited.

Further, in addition to the pachinko machine, it may be implemented as various game machines such as a pachinko machine, a sparrow ball, a slot machine, a so-called pachinko machine and a slot machine.

As a specific example of a gaming machine in which a pachinko machine and a slot machine are fused, a display device for displaying a variable display of a sequence of symbols consisting of a plurality of symbols and then confirming the symbol is provided, and a handle for launching a ball is not provided. Things can be mentioned. In this case, after a predetermined amount of balls are thrown in based on a predetermined operation (button operation), the symbol variation is started due to, for example, the operation of the operation lever, and for example, due to the operation of the stop button or a predetermined amount. As time elapses, the fluctuation of the symbol is stopped, and a special game is generated that gives the player a predetermined game value on the condition that the confirmed symbol at the time of the stop is a so-called jackpot symbol, and the player is given a predetermined game value. Is for paying out a large amount of balls to the lower saucer.

The concepts of various inventions included in the above-described embodiments in addition to the gaming machine of the present invention are shown below.

<Concept of the invention using the base unit 390 as an example>
In a gaming machine including a base member, a displacement member displaceably arranged on the base member, and a holding means for holding the displaced member on the base member, the holding means is formed so as to be elastically deformable. When the displacement member is attached to the base member, the elastic portion in contact with the displacement member is elastically deformed, and the displacement member is allowed to be attached to the base member. The gaming machine A1 is characterized in that when the displacement member mounted on the base member is brought into contact with the elastic portion, the displacement of the displacement member in the abutting direction is regulated by the elastic portion.

Here, there is known a gaming machine in which a displacement member is slidably displaced on a base member (for example, Japanese Patent Application Laid-Open No. 2012-130539). In such a technique, a groove is opened in the base member, and a protrusion of the displacement member is inserted into the groove. Therefore, the end point of the slide displacement of the displacement member is defined by abutting the protrusion at the end of the groove. A collar larger than the groove width is fastened and fixed to the tip of the protrusion. As a result, the displacement member is held by the base member and is prevented from falling off.

Further, there is also known a gaming machine that defines the end point of slide displacement by locating a wall portion erected from a base member on the displacement locus of the displacement member and bringing the displacement member into contact with the wall portion. For example, Japanese Patent Application Laid-Open No. 2017-29609). A lid member is arranged on the base member, and a displacement member is housed between the base member and the lid member. As a result, the displacement member is held by the base member and is prevented from falling off.

However, in the conventional gaming machine illustrated above, not only separate parts such as a collar and a lid member are required, but also these separate parts need to be fastened and fixed to the base member with screws, which increases man-hours. Therefore, there is a problem that the product cost increases.

On the other hand, according to the game machine A1, the elastic portion is elastically deformed so that the displacement member is attached to the base member, and after the attachment, the displacement of the displacement member is regulated by the elastic portion whose elasticity is restored. .. That is, the displacement member is held by the base member. Therefore, not only the separate parts are unnecessary, but also the process of attaching the separate parts can be eliminated, so that the product cost can be reduced accordingly.

In the game machine A1, the displacement member is displaced between the first position and the second position, and the displacement member is at least a displacement locus when the displacement member is displaced between the first position and the second position. The gaming machine A2 is characterized in that it is mounted on the base member by being displaced in a direction orthogonal to the displacement locus at a position overlapping a part and then being displaced in accordance with the displacement regulation.

According to the game machine A2, in addition to the effect of the game machine A1, the displacement member is orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus when the displacement member is displaced between the first position and the second position. After being displaced in the direction of displacement, the displacement member is mounted on the base member by being displaced according to the displacement regulation. Therefore, when the displacement member is mounted on the base member, the displacement member can be overlapped with the displacement locus of the displacement member. it can. Therefore, the space on the base member required for mounting the displacement member can be reduced by the amount of the overlapping allowance.

In the game machine A2, a protrusion that is projected from one of the base member or the displacement member and a recess that is formed so that the protrusion can pass through and is recessed in the other of the base member or the displacement member. The gaming machine A3 is characterized in that, when the protrusion passes through the recess, the displacement member is displaced in a direction orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus.

According to the game machine A3, in addition to the effect of the game machine A2, the displacement member is displaced in the direction orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus by passing the protrusion through the recess. Therefore, it is possible to increase the overlap margin between the displacement locus of the displacement member and the displacement member when the displacement member is mounted on the base member. Therefore, the space on the base member required for mounting the displacement member can be made smaller.

In the game machine A2 or A3, the game machine A4 is characterized in that the elastic portion is engaged with the base member or the displacement member in a state where the displacement member is arranged at the first position.

According to the game machine A4, in addition to the effect of the game machine A2 or A3, the elastic part is engaged with the base member or the displacement member in the state where the displacement member is arranged at the first position, so that the elastic part is the base. It is possible to suppress elastic deformation in the contact direction each time the member or the displacement member is contacted. Therefore, it is possible to prevent the elastic portion from becoming deformed.

The gaming machine A4 is characterized by comprising an urging means for applying an urging force in a direction of holding the displacement member to the first position to the displacement member.

According to the game machine A5, in addition to the effect of the game machine A4, an urging means for applying a urging force in the direction of holding the displacement member to the first position is provided to the displacement member, so that the elastic portion is a base member or It is possible to maintain a state in which the displacement member is in contact with the displacement member (a state in which elastic deformation of the elastic portion is restricted). Therefore, it is possible to prevent the elastic portion from being illegally elastically deformed and the displacement member from being removed.

<Concept of the invention using the base unit 390 as an example>
In a gaming machine including a base member, a displacement member displaceable on the base member, and a holding means for holding the displaced member on the base member, the holding means is the base member or the above. The gaming machine B1 is characterized in that one of the displacement members is provided with an elastic portion that is elastically deformably arranged, and the displacement member is held by the elastic portion on the base member.

Here, there is known a gaming machine in which a displacement member is slidably displaced on a base member (for example, Japanese Patent Application Laid-Open No. 2012-130539). In such a technique, a groove is opened in the base member, and a protrusion of the displacement member is inserted into the groove. Therefore, the end point of the slide displacement of the displacement member is defined by abutting the protrusion at the end of the groove. A collar larger than the groove width is fastened and fixed to the tip of the protrusion. As a result, the displacement member is held by the base member and is prevented from falling off.

Further, there is also known a gaming machine that defines the end point of slide displacement by locating a wall portion erected from a base member on the displacement locus of the displacement member and bringing the displacement member into contact with the wall portion. For example, Japanese Patent Application Laid-Open No. 2017-29609). A lid member is arranged on the base member, and a displacement member is housed between the base member and the lid member. As a result, the displacement member is held by the base member and is prevented from falling off.

However, in the conventional gaming machine illustrated above, there is a problem that assembly is complicated because it is necessary to fasten and fix another part such as a collar and a lid member to the base member with screws.

On the other hand, according to the game machine B1, the holding means is provided with an elastic portion that is elastically deformably arranged on one of the base member and the displacement member, and the displacement member is held by the elastic portion on the base member. , It is not necessary to fasten and fix other parts such as collars and lid members with screws. Therefore, it can be easily assembled.

In the game machine B1, the displacement member is displaced in one direction and is held by the elastic portion on the base member.

According to the game machine B2, in addition to the effect of the game machine B1, the displacement member is displaced in one direction and is held by the elastic portion on the base member, so that it is not necessary to perform a complicated operation. That is, the displacement member can be held by the base member by a simple operation such as pushing in one direction. Therefore, it can be easily assembled.

In the game machine B2, the holding means includes an engaging portion that is arranged on one of the base member or the displacement member and is formed so as to be engageable with the base member or the other of the displacement members. A gaming machine characterized in that the base member or the other of the displacement members is displaced in one direction while being engaged with the engaging portion, so that the base member is held by the elastic portion. B3.

According to the game machine B3, the holding means includes an engaging portion disposed on one of the base member or the displacement member and formed to be engageable with the other of the base member or the displacement member, and the displacement member is the base member or the displacement member. The other side of the displacement member is displaced in one direction while being engaged with the engaging portion, so that the displacement member is held by the elastic portion on the base member. Therefore, since the portion engaged with the engaging portion can be used as a fulcrum to be displaced in one direction, the assembly can be facilitated in addition to the effect of the game machine B2.

Further, as a portion for holding the displacement member on the base member, an engaging portion can be used in addition to the elastic portion, so that the holding strength can be improved. Therefore, it is possible to prevent the displacement member from falling off from the base member.

In any of the game machines B1 to B3, the holding means includes an opening opened in the base member or the other of the displacement members and extended along the displacement direction of the displacement member, and the opening includes the opening. A game machine B4 characterized in that an elastic portion is inserted.

According to the game machine B4, in addition to the effect of any of the game machines B1 to B3, the holding means has an opening opened in the other of the base member or the displacement member and extended along the displacement direction of the displacement member. Since the elastic portion is inserted through the opening, space efficiency can be improved. That is, the opening and the elastic portion can have both a function of guiding the displacement of the displacement member with respect to the base member and a function of causing the base member to hold the displacement member. Therefore, space efficiency can be improved as compared with the case where both functions are provided separately.

In the game machine B4, the displacement member is formed as a rack in which teeth are engraved along the outer edge of the game machine B5.

According to the game machine B5, in addition to the effect of the game machine B4, the displacement member is formed as a rack in which teeth are carved along the outer edge thereof, so that the tooth carving range can be easily secured. That is, as described above, the function of guiding the displacement and the function of holding the displacement can be provided to the opening and the elastic portion, and it is not necessary to provide both of these functions on the outer edge of the displacement member. Therefore, it is possible to secure a tooth engraving range on the outer edge of the displacement member.

<Concept of the invention using the base unit 390 as an example>
In a game machine including an operator that is formed to be displaceable by the operation of a player, a first member that comes into contact with the operator in a predetermined displacement region is provided, and the operator is operated by contact with the first member. A game machine C1 characterized in that the feeling is changed.

Here, a game machine provided with an operator is known (for example, Japanese Patent Application Laid-Open No. 2017-29609). Examples of the operator include a button that can be pressed and a lever that can be rotated.

However, the gaming machine illustrated above has a problem that it is difficult to grasp the operation position of the operator.

On the other hand, according to the game machine C1, a first member that comes into contact with the operator in a predetermined displacement region is provided, and the operation feeling of the operator is changed by the contact with the first member. It is possible to easily grasp the operation position of the operator based on the change in the operation feeling.

In the game machine C1, the first member is characterized in that the reaction force acting on the operator increases as the operator approaches a predetermined position.

According to the game machine C2, in addition to the effect of the game machine C1, the first member increases the reaction force acting on the operator as the operator approaches the predetermined position, so that the operator approaches the predetermined position. Can be easily recognized by the player.

The game machine C2 includes a base member in which the operator is displaceably arranged, and the first member collides with the operator or the base member when the operator exceeds the predetermined position. A game machine C3 characterized by.

According to the game machine C3, in addition to the effect of the game machine C2, a base member in which the operator is displaced is provided, and the first member is the operator or the base member when the operator exceeds a predetermined position. Since it collides with the operator, vibration can be transmitted to the operator by the collision. This makes it easier for the player to recognize that the operator has been displaced to a predetermined position.

In the game machine C3, the first member of the game machine C4 collides with the base member when the operator exceeds the predetermined position.

According to the game machine C4, in addition to the effect of the game machine C3, the first member collides with the base member when the operator exceeds a predetermined position, so that damage to the operator can be suppressed. Since the operator is arranged on the base member, the vibration due to the collision of the first member can be transmitted to the operator via the base member.

In any of the game machines C2 to C4, the first member is formed as an elastic body that is elastically deformed by contact with the operator, and when the operator exceeds the predetermined position, the first member with the operator The gaming machine C5, characterized in that the contact is released and the elastic recovery causes the collision with the base member or the operator.

According to the game machine C5, in addition to the effect of any of the game machines C2 to C4, the first member is formed as an elastic body that is elastically deformed by contact with the operator, and the operator exceeds a predetermined position. Then, the contact with the operator is released, and the elastic recovery causes the collision with the base member or the operator, so that the structure can be simplified. That is, by elastic deformation of the first member and its elastic recovery, it is possible to form a reaction force acting on the actuator and a displacement of the first member due to a collision with the actuator or the base member, and the reaction force is formed. It is not necessary to separately provide an actuator for colliding with each other.

In the game machine C5, when the operator is displaced beyond a predetermined position, the first member is released from contact with the operator and collides with the operator or the base member due to its elastic recovery. A game machine C6 characterized by this.

According to the game machine C6, in addition to the effect of the game machine C5, when the operator is displaced beyond a predetermined position, the first member is released from contact with the operator, and the elastic recovery of the first member causes the operator. Alternatively, since it collides with the base member, that is, it has a mechanical structure that utilizes the elastic deformation of the first member and its elastic recovery, the reliability is improved as compared with the case of electrically controlling by using an actuator, for example. Can be improved.

In the game machine C5 or C6, the first member includes a collision portion that collides with either the base member or the operator, and when the collision portion is damaged, the other portion of the first member is said. A gaming machine C7 characterized in that it collides with a base member or the operator.

According to the game machine C7, in addition to the effect of the game machine C5 or C6, the first member includes a collision portion that collides with either the base member or the operator, and when the collision portion is damaged, the first member Since the other part of the member collides with the base member or the operator, the transmission of vibration to the operator can be reliably formed. That is, even if the collision portion is damaged, the player can be made to recognize that the operator has been displaced to a predetermined position.

In any of the game machines C5 to C7, the operator is a displaceable displacement between the first position capable of contacting the first member and the second position not contacting the first member. When a member is provided and the operator is displaced in the first direction, the displacement member is arranged at the first position and the operator is displaced in a second direction opposite to the first direction. In this case, the game machine C8 is characterized in that the displacement member is arranged at the second position.

According to the game machine C8, in addition to the effect of any of the game machines C5 to C7, the operator has a first position capable of contacting the first member and a second position in which the operator is not in contact with the first member. A second position is provided with a displacement member displaceable from a position, and when the operator is displaced in the first direction, the displacement member is placed in the first position and the operator is in the direction opposite to the first direction. When the displacement member is displaced in the direction, the displacement member is arranged at the second position. Therefore, when the operator is displaced in the first direction, the operation feeling is changed, and when the operator is displaced in the second direction, the operation feeling is changed. The operation feeling can be unchanged. Therefore, it is possible to prevent the operation feeling from being changed when the operator is displaced in any direction, and it is possible to prevent the player's interest from being lowered.

In the game machine C8, the displacement member is displaced from the first position to the second position by being brought into contact with the first member when the operator is displaced in the second direction. Characteristic gaming machine C9.

According to the game machine C9, in addition to the effect of the game machine C8, the displacement member is moved from the first position to the second position by being brought into contact with the first member when the operator is displaced in the second direction. Since it is displaced, it is not necessary to separately provide a configuration for displacementing the displacement member, and such a configuration can also be used for the first member. Therefore, the number of parts can be reduced accordingly.

In the game machine C9, the base member includes an engaging piece that displaces the displacement member from the second position to the first position when the operator is arranged at the end in the second direction. Game machine C10.

According to the game machine C10, in addition to the effect of the game machine C9, the base member engages to displace the displacement member from the second position to the first position when the operator is placed at the end in the second direction. Since the piece is provided, the displacement member can be brought into contact with the first member when the operator is displaced in the first direction.

In the game machine C10, the engaging piece is formed so as to be elastically deformable.

According to the game machine C11, in addition to the effect of the game machine C10, the engaging piece is formed so as to be elastically deformable, so that the displacement member engages when the operator is arranged at the end in the second direction. Even if it collides with a piece, the impact caused by the collision can be absorbed by the elastic deformation of the engaging piece. Therefore, damage to the displacement member can be suppressed.

<Concept of the invention using the displacement unit 300 (operation unit 320) as an example>
In a gaming machine provided with an operator that is displaceably formed from the first position to the second position by the operation of the player, the operation in the first direction or the second direction, which is a direction different from the first direction. The gaming machine D1 is characterized in that the operator is displaced from the first position to the second position in any direction of the operation.

Here, a game machine provided with an operator is known (for example, Japanese Patent Application Laid-Open No. 2017-29609). Examples of the operator include a button that can be pressed and a lever that can be rotated.

However, the conventional gaming machine illustrated above has a problem that the operation feeling is monotonous.

On the other hand, according to the game machine D1, the operator moves from the first position to the first position in either the operation in the first direction or the operation in the second direction, which is a direction different from the first direction. Since it is displaced to two positions, the player can arbitrarily select the type of operation. As a result, it is possible to give a variation to the operation feeling.

In the game machine D1, the operator is formed so as to be displaceable from the second position to the third position, and the operator is displaced from the second position to the third position by the operation in the second direction. The gaming machine D2 is characterized in that in the operation in the first direction, the displacement of the operator from the second position to the third position is restricted.

According to the game machine D2, in addition to the effect of the game machine D1, the operator is displaced from the second position to the third position by the operation in the second direction, and the second operation of the operator is caused by the operation in the first direction. Since the displacement from the position to the third position is regulated, the operation of displacing the operator from the first position to the third position can be complicated (a mixture of one-step operation and two-step operation can be formed). That is, in the operation in the first direction, the displacement of the actuator from the first position to the third position cannot be completed (after that, it is necessary to further perform the operation in the second direction in the second position), while the first If the operation is in two directions, the displacement of the operator from the first position to the third position can be completed in one operation.

In the game machine D1, the operator is formed so as to be displaceable from the second position to the third position, and is operated in the third direction, which is a direction different from both the first direction and the second direction. The operator is displaced from the second position to the third position, and in the operations in the first direction and the second direction, the displacement of the operator from the second position to the third position is restricted. A game machine D3 characterized by this.

According to the game machine D3, in addition to the effect of the game machine D1, the operator moves from the second position to the third position by operating in the third direction, which is a direction different from both the first direction and the second direction. In the operation of being displaced and described in the first and second directions, the displacement of the operator from the second position to the third position is restricted, so that the operation is to displace the operator from the first position to the third position. , Two-step operation can be required. Therefore, it is possible to prevent the operation feeling from becoming monotonous. Further, it is possible to prevent the operator from being inadvertently displaced (operated) from the second position to the third position.

That is, after the operator is displaced from the first position to the second position by the operation in the first direction or the operation in the second direction, the third direction is different from the first or second direction. The operator cannot be displaced to the third position unless the operation is performed in the direction.

In any of the game machines D1 to D3, one of the operation in the first direction and the operation in the second direction is an operation for rotating the operator, and the operation in the first direction or the operation in the second direction. The other is the gaming machine D4, which is an operation of directly moving the operator.

According to the game machine D4, in addition to the effect of any of the game machines D1 to D3, one of the operation in the first direction and the operation in the second direction is an operation for rotating the operator, and the operation in the first direction. Alternatively, since the other operation in the second direction is an operation in which the operator is directly moved, the difference in the operation direction can be noticeable. Therefore, it is possible to clarify the change in the operation feeling due to the operation in different directions.

In the game machine D4, the direction of the rotation axis of rotation in one of the operations in the first direction or the operation in the second direction, and the direction of linear motion in the other of the operations in the first direction or the operation in the second direction. A game machine D5 characterized in that

According to the game machine D5, in addition to the effect of the game machine D4, the direction of the rotation axis of rotation in either the operation in the first direction or the operation in the second direction, and the operation in the first direction or the operation in the second direction. Since the direction of linear motion on the other side is parallel, the operator can be easily displaced from the first position to the second position in either the operation in the first direction or the operation in the second direction.

In the game machine D5, the base member in which the operator is displaceably arranged, a guide portion formed on one of the base member or the operator, and the other of the base member or the operator are formed. A guided portion that is guided along the guide portion is provided, and the guided portion is guided along the guide portion, so that the operator is displaced from at least the first position to the second position. A game machine D6 characterized by this.

According to the game machine D6, in addition to the effect of the game machine D5, a base member in which an operator is displaceably arranged, a guide portion formed on one of the base member or the operator, and a base member or an operation A guided portion formed on the other side of the child and guided along the guide portion is provided, and the guided portion is guided along the guide portion, so that the operator is displaced from at least the first position to the second position. Therefore, the structure can be simplified. Further, in the operation in the first direction and the operation in the second direction (for example, linear motion and rotation), the guide portion (guide surface) to which the guided portion is guided can be made different. As a result, for example, the shape of the guide portion (guide surface) can be changed to make the displacement mode and operation feeling of the operator different.

The game machine D6 is characterized in that the front surface of the operator is arranged at a position overlapping the rotation axis in the direction view of the rotation axis of rotation in either the operation in the first direction or the operation in the second direction. Game machine D7.

According to the game machine D7, in addition to the effect of the game machine D6, the front surface of the operator is positioned at a position overlapping the rotation axis in the direction view of the rotation axis of rotation in either the operation in the first direction or the operation in the second direction. Since it is arranged, it is possible to make it difficult to form a force component in a direction in which the operator is tilted with respect to the rotation axis when the operator is pushed in. Therefore, the push-operated operator can be smoothly moved directly.

In the game machine D6 or D7, in the directional view orthogonal to the rotation axis of rotation in either the operation in the first direction or the operation in the second direction, the opposite side surfaces of the operator are located at positions overlapping the rotation axis, respectively. A game machine D8 characterized in that it is arranged.

According to the game machine D8, in addition to the effect produced by the game machine D6 or D7, the operation is performed at a position overlapping the rotation axis in a directional view orthogonal to the rotation axis of rotation in either the operation in the first direction or the operation in the second direction. Since the opposing side surfaces of the child are arranged, the opposite side surface of the operator can be used as a handle, and the opposite side surface can be gripped to facilitate rotation of the operator.

<Concept of the invention using the displacement unit 300 (operation unit 320) as an example>
In a gaming machine provided with an operator that is operated and displaced by a player in one direction, a first operation and a second operation different from the first operation are formed on the operator by the operation in one direction. A game machine E1 characterized by being played.

Here, a game machine provided with an operator is known (for example, Japanese Patent Application Laid-Open No. 2017-29609). Examples of the operator include a button that can be pressed and a lever that can be rotated.

However, in the conventional gaming machine illustrated above, the operator has a problem that it is difficult to give interest to the operation of the operator because only one operation is formed by the operation in one direction.

On the other hand, according to the game machine E1, the first operation and the second operation different from the first operation are formed on the operator by the operation in one direction, which gives an interest to the operation of the operator. be able to.

The operations in one direction include, for example, a pushing operation for pressing the operator, a pull-out operation for pulling the operator, a tilting operation for tilting the operator, a slide operation for sliding the operator, and a rotation of the operator. A rotation operation, an operation combining these operations, and the like are exemplified. Further, as the modes of the first operation and the second operation, for example, an operation of displacement along a straight line (linear displacement), an operation of displacement along a curve (curve displacement), an operation of rotating around an axis, and the like. An example is an operation of performing displacement in combination with displacement.

The game machine E2 is characterized in that at least one of the first operation and the second operation is changed during the operation in one direction.

According to the game machine E2, in addition to the effect of the game machine E1, at least one mode of the first operation or the second operation is changed during the operation in one direction, so that the operation of the operator is interesting. Can be given.

As a mode of the game machine E2, for example, as a first mode, an operation of linear displacement (first operation) and an operation of rotation (second operation) by a pushing operation (operation in one direction) are operators. The second mode is that the rotation direction of the operator's rotation operation (second operation) is changed in the opposite direction (for example, from right rotation to left rotation) during the pushing operation. In this mode, a linear displacement operation (first operation) and a rotating operation (second operation) are formed on the operator by the pushing operation (operation in one direction), and the pushing operation is performed. In the middle of the pushing operation, the rotation amount (rotation angle) of the operator per unit pushing amount of the pushing operation is increased or decreased (including the one in which the rotation amount becomes 0). A mode in which a linear displacement operation (first operation) and a rotating operation (second operation) are formed on the operator by (operation in one direction), and the rotation operation is performed during the rotation operation. Examples of modes in which the linear displacement amount of the operator per unit rotation angle is increased or decreased (including those in which the linear displacement amount becomes 0) are exemplified.

In the game machine E1 or E2, the game machine E3 is characterized in that one of the first operation and the second operation is non-formed during the operation in one direction.

According to the game machine E3, in addition to the effect of the game machine E1 or E2, one of the first operation and the second operation is non-formed during the operation in one direction, so that the operation of the operator is interesting. Can be given.

The middle of the operation in one direction may be any timing within the range of the operation. That is, one of the first operation and the second operation is not formed before or after the first operation and the second operation are formed.

Therefore, as an aspect of the game machine E3, for example, in the first half of the pushing operation (operation in one direction), a linear displacement operation (first operation) and a rotating operation (second operation) are performed. In the latter half of the pushing operation, only the linear displacement operation (first operation) is formed on the operator, and the rotating operation (second operation) is not formed. In the first half of the pushing operation (operation in one direction), only the linear displacement operation (first operation) is formed on the operator, and the rotating operation (second operation) is not formed. In the latter half of the above, an embodiment in which a linear displacement motion (first motion) and a rotating motion (second motion) are formed in the operator is exemplified.

In any of the game machines E1 to E3, the operator includes a base member that is displaceably arranged, and the operator is rotatably connected to a base member guided by the base member and the base member. The gaming machine E4 is provided with a member to be operated, which is a part to be operated by the player.

According to the game machine E4, in addition to the effect of the game machine E3, a base member in which the operator is displaced is provided, and the operator is guided to the base member and rotates on the base member. Since the operated member is provided as a part that can be connected and operated by the player, it is possible to improve the operation feeling when operating the operated member.

For example, in a mode in which a linear displacement operation (first operation) and a rotating operation (second operation) are formed on the operator by a pushing operation (operation in one direction), the second operation (rotation) is performed. With the formation, the operator is rotated with respect to the palm of the operator. Therefore, the palm is rubbed by the operator, which causes a decrease in the feeling of operation.

On the other hand, according to the game machine E4, since the member to be operated is rotatably connected to the base member, a linear displacement operation (first operation) and rotation by a pushing operation (operation in one direction) and rotation are performed. While it is possible to form the movement (second movement) to be performed on the base member, it is possible to prevent the member to be operated from being rotated with respect to the palm of the player. Therefore, it is possible to suppress the palm from being rubbed by the operator and improve the operability.

In any of the game machines E1 to E4, a base member in which the operator is displaceably arranged, a guide portion formed on one of the base member or the operator, and the base member or the operator. A game characterized in that a guided portion formed on the other side and guided along the guide portion is provided, and the operator is displaced by guiding the guided portion along the guide portion. Machine E5.

According to the game machine E5, in addition to the effect of any of the game machines E1 to E4, a base member in which the operator is displaceably arranged, and a guide portion formed on one of the base member or the operator. A guided portion formed on the other side of the base member or the operator and guided along the guide portion is provided, and the guided portion is guided along the guide portion to displace the operator. The structure can be simplified while allowing the first operation and the second operation to be formed at the same time.

<Concept of the invention using the displacement unit 300 (operation unit 320) as an example>
In a gaming machine including a base member and a displacement member displaceable on the base member, a guided portion formed on one of the base member or the displacement member and the base member or the displacement member. A guide portion formed on the other side of the guide portion for guiding the guided portion is provided, and the guided portion is characterized in that it is guided to a different region of the guide portion according to a displacement state of the displacement member. Game machine F1.

Here, a base member and a displacement member displaceable on the base member are provided, and a pin projecting from the displacement member slides along a groove formed in the base member. A game machine that defines the displacement mode of the displacement member is known (for example, Japanese Patent Application Laid-Open No. 2012-130539).

However, in the conventional gaming machine illustrated above, since the same region is guided regardless of the displacement state of the displacement member, there is a problem that the load is concentrated in that region and the durability is lowered.

On the other hand, according to the game machine F1, a guided portion formed on one of the base member or the displacement member and a guide portion formed on the other of the base member or the displacement member to guide the guided portion are provided. Since the guide portion is guided to different regions of the guide portion according to the displacement state of the displacement member, it is possible to disperse the region to receive the load and suppress the concentration of the load on a part of the region. As a result, durability can be improved.

Examples of the displacement state of the displacement member include the direction of displacement of the displacement member and the mode of the external force acting on the displacement member.

In the game machine F1, the displacement member is formed so as to be displaceable between the first position and the second position, and in the region of the guide portion to which the guided portion is guided, the displacement member is in the first position. The gaming machine F2 is characterized in that the case where the displacement member is displaced from the second position to the second position and the case where the displacement member is displaced from the second position to the first position are different.

According to the game machine F2, in addition to the effect of the game machine F1, the displacement member is formed so as to be displaceable between the first position and the second position, and the area of the guide part to which the guided part is guided is formed. Since the case where the displacement member is displaced from the first position to the second position and the case where the displacement member is displaced from the second position to the first position are different, the area to be loaded can be dispersed and the area to be loaded can be distributed to a part of the area. It is possible to suppress the concentration of load. As a result, durability can be improved.

In this way, when the displacement member reciprocates between the first position and the second position, the displacement member is displaced alternately between the outward path and the return path, so that the area of the guide portion to which the guided portion is guided is guided. By making the outward path and the return path of the displacement member different, the area receiving the load can be efficiently dispersed. As a result, it is particularly effective in improving durability.

In the game machine F1 or 2, the displacement member is formed so as to be operable by a player in either the first direction and a second direction different from the first direction, and the guided portion is guided. The gaming machine F3 is characterized in that the region of the guide portion differs depending on whether the displacement member is operated in the first direction or the displacement member is operated in the second direction.

According to the game machine F3, in addition to the effect of the game machine F1 or F2, the displacement member is formed so as to be operable by the player in either the first direction and the second direction different from the first direction. Since the region of the guide portion to which the guided portion is guided differs depending on whether the displacement member is operated in the first direction or the displacement member is operated in the second direction, the region that receives the load can be dispersed. , It is possible to prevent the load from being concentrated in a part of the area. As a result, durability can be improved.

In this way, when the displacement member is formed as an operator operated by the player and can be operated in any of the first direction and the second direction different from the first direction, the game state. Since the direction of operation is selected according to the above and the same operation (operation direction) is difficult to repeat, the area of the guide portion to which the guided portion is guided can be divided into the operation in the first direction and the operation in the second direction. By making them different, the area to be loaded can be efficiently distributed. As a result, it is particularly effective in improving durability.

The game machine F2 includes a first member and a second member, and the guide portion is a region in which the guided portion is guided when the displacement member is displaced from the first position to the second position. Is formed in the first member, and a region in which the guided portion is guided is formed in the second member when the displacement member is displaced from the second position to the first position. Amusement machine F4.

In the game machine F3, the first member and the second member are provided, and in the guide portion, the region where the guided portion is guided when the displacement member is operated in the first direction is the first member. The gaming machine F5 is formed in the second member, and a region in which the guided portion is guided is formed in the second member when the displacement member is operated in the second direction.

According to the game machine F4 or F5, in addition to the effect of the game machine F2 or F3, the guide portion is covered when the displacement member is displaced from the first position to the second position or is operated in the first direction. The area where the guide portion is guided is formed in the first member, and the region where the guided portion is guided when the displacement member is displaced from the second position to the first position or is operated in the second direction is the first. Since it is formed into two members, the replacement cost can be reduced.

That is, when the guide portion is formed on the member 1, even if a part of the region of the guide portion is damaged or worn, it is necessary to replace the entire member. On the other hand, according to the game machine F4 or F5, when a part of the area is damaged or worn, only one member (one of the first member or the second member) forming the area is replaced. It is sufficient to do so, and it is not necessary to replace the entire member. Therefore, the replacement cost can be reduced accordingly.

Further, when the guide portion is formed from the first member and the second member in this way and only one region is easily damaged or worn, the one member (first member or second member) forming the region is liable to be damaged or worn. Only the material of one of the members) can be made of a material having higher durability than the other member (the other of the first member or the second member). As a result, it is possible to improve the durability while reducing the material cost.

<Concept of the invention using the displacement unit 300 (guide unit 350) as an example>
In a gaming machine including a first member on which a guided portion is projected and a second member having a groove-shaped guide portion for guiding the guided portion, the second member is a base member and its base. A gaming machine G1 comprising a connecting member connected to the member, wherein the guide portion is formed by the base member and the connecting member.

Here, a base member and a displacement member displaceable on the base member are provided, and a pin projecting from the displacement member slides along a groove formed in the base member. A game machine that defines the displacement mode of the displacement member is known (for example, Japanese Patent Application Laid-Open No. 2012-130539).

However, in the conventional gaming machine illustrated above, when assembling the base member and the displacement member, if other members are present, they can be assembled while avoiding interference with the other members (pins are inserted into the grooves). May be required. In this case, since it is necessary to work while avoiding interference with other members, there is a problem that the shapes of the displacement member, the base member, and the other member are limited, and the degree of freedom in design is reduced.

On the other hand, according to the game machine G1, the second member includes a base member and a connecting member connected to the base member, and a guide portion is formed by the base member and the connecting member. Alternatively, after arranging the first member on one of the connecting members, the base member or the other of the connecting members can be connected to one to assemble the whole. Therefore, it is possible to prevent interference with other members. As a result, the degree of freedom in design can be increased.

In the game machine G1, the guide portion includes a guide surface along a direction for guiding the guided portion and a terminal surface for defining an end in a direction for guiding the guided portion, and the base member and the connecting member. The gaming machine G2 is characterized in that a boundary with the terminal surface is formed at the terminal surface or a connection portion between the terminal surface and the guide surface.

According to the game machine G2, in addition to the effect of the game machine G1, the guide portion includes a guide surface along the direction for guiding the guided portion and a terminal surface for defining the end in the direction for guiding the guided portion. Since the boundary between the base member and the connecting member is formed at the terminal surface or the connecting portion between the terminal surface and the guide surface, the guided portion is a boundary where a step is likely to be formed due to dimensional tolerances and assembly tolerances. Can be avoided from passing. Therefore, it is possible to avoid the occurrence of impact and wear when the guided portion passes through the step. As a result, the guided portion can be smoothly displaced and the durability can be improved.

In the game machine G1 or G2, the guide portion includes a guide surface along a direction for guiding the guided portion and a terminal surface for defining an end in a direction for guiding the guided portion. A gaming machine including a first guide surface and a second guide surface arranged to face each other, the first guide surface is formed of the base member, and the second guide surface is formed of the connecting member. G3.

According to the game machine G3, in addition to the effect of the game machine G1 or G2, the guide portion has a guide surface along the direction for guiding the guided portion and a terminal surface for defining the end in the direction for guiding the guided portion. The guide surface includes a first guide surface and a second guide surface that are arranged to face each other, the first guide surface is formed by a base member, and the second guide surface is formed by a connecting member. The guide surface and the second guide surface can be formed from different members. As a result, the respective materials can be made different according to the characteristics required for the first guide surface and the second guide surface. Further, when changing the shape of the first guide surface or the second guide surface, only one member needs to be changed, and it is not necessary to change the whole.

In the game machine G3, the end surface defines a first end surface that defines one end in the direction of guiding the guided portion and a second end surface that defines the other end in the direction of guiding the guided portion. The gaming machine G4 is provided with an end surface, and the first end surface and the second end surface are formed by either the base member or the connecting member.

According to the game machine G4, in addition to the effect of the game machine G3, the end surface includes the first end surface that defines the end on one side in the direction of guiding the guided portion, and the direction of guiding the guided portion. It has a second end surface that defines the end on the side, and since the first end surface and the second end surface are formed by either the base member or the connecting member, the parts that are easily damaged are integrated into one component. , Parts replacement cost can be reduced. That is, the surface (part) that defines the end in the direction of guiding the guided portion is easily damaged because the guided portion collides, and if the surface (part) that defines the end is damaged, Only one of the base member or the connecting member needs to be replaced, and it is not necessary to replace the whole.

In any of the game machines G1 to G4, the outer surface formed along the first direction of the first member is surrounded by the second member, and the guided portion protrudes from the outer surface of the first member. The gaming machine G5 is provided, wherein the guide portion is formed on an inner surface of the connecting member, and the base member and the connecting member are divided in the first direction.

According to the game machine G5, in addition to the effect of any of the game machines G1 to G4, the outer surface formed along the first direction of the first member is surrounded by the second member, and the guide portion is described. , The guide portion is formed on the inner surface of the connecting member, and the base member and the connecting member are divided in the first direction. Therefore, the base member and the connecting member have a continuous shape (annular shape). ) Can be done. Therefore, it is possible to improve the rigidity of the members (base member and connecting member) that are required to have rigidity because the guide portion for guiding the guided portion is formed. Further, by dividing into a base member and a connecting member, it is possible to easily form a guide portion (die-cutting).

In the game machine G3 or G4, the first member is formed so as to be displaceable from the first position to the second position by the operation of the player, and the first member is displaced from the first position by the operation in the first direction. When displaced to the second position, the guided portion is guided by the first guide surface, and the first member is moved by the operation in the second direction, which is a direction different from the first direction. The gaming machine G6 is characterized in that when the position is displaced from the first position to the second position, the guided portion is guided by the second guide surface.

According to the game machine G6, in addition to the effect of the game machine G3 or G4, the first member is formed so as to be displaceable from the first position to the second position by the operation of the player, and the first member is formed by the operation in the first direction. When one member is displaced from the first position to the second position, the guided portion is guided by the first guide surface, and the first member is moved by an operation in the second direction, which is a direction different from the first direction. When the displacement is performed from the first position to the second position, the guided portion is guided by the second guide surface, so that it depends on the type of operation direction (operation in the first direction or operation in the second direction). A (suitable) guide surface (shape and material) can be used. Thereby, for example, by making the shapes and materials of the first guide surface and the second guide surface different, the operation feeling can be made different. Alternatively, by adopting a material with high wear resistance and impact resistance on the side where wear generation and impact input are large, while adopting a low cost material on the side where wear generation and impact input are small. , Improved durability and reduced product cost can be achieved.

In any of the game machines A1 to A5, B1 to B5, C1 to C11, D1 to D8, E1 to E5, F1 to F5, and G1 to G6, the game machine K1 is a slot machine. .. Among them, the basic configuration of the slot machine is "provided with a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming the identification information, and for operating a starting operation means (for example, an operation lever). Due to this, the dynamic display of the identification information is started, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (stop button) or after a predetermined time has elapsed, and at the time of the stop. A gaming machine provided with a special gaming state generating means for generating a special gaming state advantageous to the player, provided that the definite identification information of the above is the specific identification information. In this case, coins, medals, and the like are typical examples of the game medium.

In any of the gaming machines A1 to A5, B1 to B5, C1 to C11, D1 to D8, E1 to E5, F1 to F5, and G1 to G6, the gaming machine is a pachinko gaming machine. K2. Among them, the basic configuration of the pachinko gaming machine is provided with an operation handle, and the ball is launched into a predetermined game area according to the operation of the operation handle, and the ball is placed in a predetermined position in the game area. As a prerequisite for winning a prize (or passing through the operating port), the identification information dynamically displayed on the display device may be fixedly stopped after a predetermined time. Further, when a special gaming state occurs, a variable winning device (specific winning opening) arranged at a predetermined position in the gaming area is opened in a predetermined manner to enable a ball to be won, and is valuable according to the number of winnings. Some are given value (including not only prize balls but also data written on a magnetic card).

In any of the gaming machines A1 to A5, B1 to B5, C1 to C11, D1 to D8, E1 to E5, F1 to F5, and G1 to G6, the gaming machine is a fusion of a pachinko gaming machine and a slot machine. The gaming machine K3, which is characterized by being. Among them, as a basic configuration of the fused gaming machine, "a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information is provided, and a starting operation means (for example, an operation lever). The variation of the identification information is started due to the operation of, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (for example, the stop button) or after a predetermined time elapses. A special game state generating means for generating a special game state advantageous to the player is provided on the condition that the definite identification information at the time of stopping is the specific identification information, the ball is used as the game medium, and the identification information is described. A game machine that requires a predetermined number of balls to start the dynamic display of the game, and is configured to pay out a large number of balls when a special game state occurs. "

10 slot machine (game machine)
300 Displacement unit (operator)
310 Ring member (base member)
320, 8320, 10320 Operation unit (operator, displacement member, first member)
330,10330 Grip unit (operator, displacement member)
10335 Operator (operator, base member, displacement member)
10336 Connecting member (operator, operated member, displacement member)
340, 8340 Rotating unit (operator, displacement member, first member)
342 Back side member (displacement member, first member)
343 Shaft member (guided part)
344 Guided member (guided part)
350, 8350, 9350, 11350, 12350, 13350, 14350, 15350 Guide unit (base member, second member)
351, 8351, 9351, 11351, 12351, 13351, 14351, 15351 Guide groove (guide unit)
351a 1st guide surface (guide surface, terminal surface, 1st guide surface, 2nd guide surface, 1st terminal surface, 2nd terminal surface)
351b, 14351b, 15351b 2nd guide surface (guide surface, 1st guide surface, 2nd guide surface)
351c, 8351c 3rd guide surface (guide surface, 1st guide surface, 2nd guide surface)
351d 4th guide surface (guide surface, 1st guide surface, 2nd guide surface)
351e, 12351e 1st end (termination surface, 1st end surface, 2nd end surface)
351f, 13351f, 14351f 2nd end (termination surface, 1st end surface, 2nd end surface)
11351g Fifth guide surface (guide surface, end surface, first guide surface, second guide surface, first end surface, second end surface)
11351h 6th guide surface (guide surface, 1st guide surface, 2nd guide surface)
14351i, 15351i 3rd end (termination surface, 1st end surface, 2nd end surface)
9351k Rear recessed portion (guide surface, end surface, first guide surface, second guide surface, first end surface, second end surface)
8351m accommodating part (terminal surface, first terminal surface, second terminal surface)
360, 11360 Front side guide unit (first member, second member, base member, connecting member)
362 Second ring member (first member, second member, base member, connecting member)
370 Rear side guide unit (first member, second member, base member, connecting member)
391,231,3391,4391,5391,6391,7391 Base unit (base member)
392, 2392, 3392, 4392, 5392, 6392, 7392 Base member (base member)
392a, 2392a, 3392a, 4392a, 5392a, 6392a, 7392a Base plate (base member)
5392a2 Sliding groove (opening)
392d1,392d1,3392d1,4392d1 Inner first engaging piece (holding means, protrusion)
392d2 Inner second engaging piece (holding means, protrusion)
3392d3 Inner first locking part (elastic part, engaging part)
3392d4 Inner second locking part (elastic part, engaging part)
392e1,392e1 Outer first engaging piece (holding means, protrusion)
392e2, 2392e2 outer second engaging piece (holding means, protrusion)
3392e3, 4392e3 Outer first locking part (elastic part, engaging part)
3392e4, 4392e4 Outer second locking part (elastic part, engaging part)
392f, 2392f, 3392f, 6392f, 7392f Restriction piece (holding means, elastic part, engaging piece)
393 leaf spring (first member)
393a Protrusion (collision part)
395, 2395, 4395, 5395, 7395 Displacement unit (displacement member, rack, operator)
396, 2396, 4396, 5396 1st displacement member (displacement member, rack, operator, 1st member)
396d1, 2396d1 Inner first recessed part (recessed part)
396d2, 2396d2 Inner second recess (concave)
396e, 2396e Outer recessed part (recessed part)
5396m Hook part (elastic part, engaging part)
397,7397 Second displacement member (displacement member)

The present invention relates to a gaming machine such as a pachinko machine.

There is known a gaming machine in which a displacement member is slidably displaced on a base member (Patent Document 1).

Japanese Unexamined Patent Publication No. 2012-130539

However, the above-exemplified gaming machine has a problem that the product cost increases.

The present invention has been made to solve the above-exemplified problems, and an object of the present invention is to provide a gaming machine capable of reducing product costs.

In order to achieve this object, the gaming machine according to claim 1 has a base member, a displacement member displaceable on the base member, and a holding means for holding the displacement member on the base member. The holding means is provided with an elastic portion formed so as to be elastically deformable, and when the displacement member is attached to the base member, the elastic portion in contact with the displacement member is elastically deformed. Then, when the displacement member is allowed to be mounted on the base member and the displacement member mounted on the base member is brought into contact with the elastic portion, the displacement of the displacement member in the abutting direction is caused. It is regulated by the elastic part.

According to the gaming machine according to claim 1, the product cost can be reduced.

It is a front view of the slot machine in 1st Embodiment. It is a perspective front view of the slot machine with the front door closed. It is a perspective front view of the slot machine with the front door open. It is a perspective rear view of the front door in a state where the reel unit is opened from the front door to the rear side. It is a rear view of the front door. It is a front view of a housing. It is an exploded perspective view of a frame unit. It is a schematic diagram which shows the symbol arrangement. It is a figure which shows the internal structure of a selector. It is a block diagram which shows the electrical structure of a slot machine. It is an exploded perspective front view of a front door. It is an exploded perspective rear view of the front door. (A) is a front view of the displacement unit, (b) is a side view of the displacement unit in the XIIIb direction of FIG. 13 (a), and (c) is a line XIIIc-XIIIc of FIG. 13 (a). It is a cross-sectional model diagram of the displacement unit in. It is an exploded perspective front view of a displacement unit. It is an exploded perspective rear view of the displacement unit. (A) is a front view of the operation unit, (b) is a side view of the operation unit in the XVIb direction view of FIG. 16 (a), and (c) is a rear view of the operation unit. (A) is a perspective front view of the operation unit, and (b) is a perspective rear view of the operation unit. It is an exploded perspective front view of an operation unit. It is an exploded perspective view of the gripping unit. (A) is a front view of the guide unit, (b) is a perspective front view of the guide unit, (c) is a perspective rear view of the guide unit, and (d) is FIG. 20 (a). It is sectional drawing of the guide unit in line XXd-XXd of). (A) is an exploded perspective front view of the guide unit, and (b) is an exploded sectional view of the guide unit. (A) is a perspective front view of the operation unit and the guide unit, (b) is a front view of the operation unit and the guide unit, and (c) is the XXIIc- of FIG. 22 (b). It is sectional drawing of the operation unit and the guide unit in line XXIIc, and (d) is the sectional view of the operation unit and guide unit in line XXIId-XXIId of FIG. 22 (a). (A) is a perspective front view of the operation unit and the guide unit, (b) is a front view of the operation unit and the guide unit, and (c) is the XXIIIc- of FIG. 23 (b). It is sectional drawing of the operation unit and the guide unit in line XXIIIc, and (d) is the sectional view of the operation unit and guide unit in line XXIIId-XXIIId of FIG. 23A. (A) is a perspective front view of the operation unit and the guide unit, (b) is a front view of the operation unit and the guide unit, and (c) is the XXIVc- of FIG. 24 (b). It is sectional drawing of the operation unit and the guide unit in line XXIVc, and (d) is the sectional view of the operation unit and guide unit in line XXIVd-XXIVd of FIG. 24 (a). It is sectional drawing of the operation unit and the guide unit. It is sectional drawing of the operation unit and the guide unit. (A) is a front view of the base unit, (b) is a perspective front view of the base unit, and (c) is a cross-sectional view of the base unit in the XXVIIc-XXVIIc line of FIG. 27 (a). .. It is an exploded perspective front view of a base unit. (A) is a front view of the base unit, and (b) is a cross-sectional view of the base unit in the line XXIXb-XXIXb of FIG. 29 (a). (A) is a front view of the displacement unit, (b) is a rear view of the displacement unit, and (c) is a cross-sectional view of the displacement unit on the XXXc-XXXc line of FIG. 30 (a). It is a front view of a base unit. (A) is a partial cross-sectional schematic diagram of the base unit in the line XXXIIa-XXXIIa of FIG. 31, and (b) is a partial cross-sectional schematic diagram of the base unit in the line XXXIIb-XXXIIb of FIG. 31. (A) is a partial cross-sectional drawing of the base unit in the line XXXIIIa-XXXIIIa of FIG. 27 (a), and (b) is a partial cross-sectional drawing of the base unit in the line XXXIIIb-XXXIIIb of FIG. 27 (a). It is a figure. It is a perspective exploded view of a displacement unit. (A) to (c) are front views of the base unit. It is a front view of a base unit. It is a partially enlarged front view of a base unit. It is a partially enlarged front view of a base unit. (A) to (c) are front views of the base unit in the second embodiment. (A) to (c) are cross-sectional schematic views of the base unit in the XLa-XLa line of FIG. 39 (a). (A) is a front view of the base unit in the third embodiment, (b) is a schematic cross-sectional view of the base unit in the XLIb-XLIb line of FIG. 41 (a), and FIG. 41 (c) is a sectional view of the base unit. It is sectional drawing of the base unit in the XLIc-XLIc line of (a). (A) is a front view of the base unit in the fourth embodiment, and (b) is a schematic cross-sectional view of the base unit in line XLIIb-XLIIb of FIG. 42 (a). (A) is a front view of the base unit in the fifth embodiment, and (b) is a cross-sectional schematic view of the base unit in line XLIIIb-XLIIIb of FIG. 43 (a). (A) is a front view of the displacement unit, (b) is a rear view of the displacement unit, and (c) is a cross-sectional view of the displacement unit of XLIVc-XLIVc of FIG. 44 (a). (A) to (c) are front views of the base unit. (A) to (c) are cross-sectional views of the base unit in the XLVIa-XLVIa line of FIG. 45 (a), and (d) is a cross-sectional view of the base unit in the XLVId-XLVId line of FIG. 46 (a). is there. (E) is a cross-sectional view of the base unit in the XLVIe-XLVIe line of FIG. 46 (a). (A) is a front view of the base unit in the sixth embodiment, (b) is a front view of the base unit, and (c) is a front view of the base unit in the XLVIIc-XLVIIc line of FIG. 47 (b). It is a cross-sectional model diagram. It is sectional drawing of the base unit in 7th Embodiment. (A) is an exploded perspective front view of the operation unit according to the eighth embodiment, and (b) is a cross-sectional view of the operation unit and the guide unit. (A) is a front view of the operation unit and the guide unit, (b) is a side view of the operation unit and the guide unit, and (c) is a cross section of the operation unit and the guide unit. It is a schematic diagram. (A) is a front view of the operation unit and the guide unit, (b) is a side view of the operation unit and the guide unit, and (c) is a cross section of the operation unit and the guide unit. It is a schematic diagram. (A) is a front view of the operation unit and the guide unit, (b) is a side view of the operation unit and the guide unit, and (c) is a cross section of the operation unit and the guide unit. It is a schematic diagram. (A) is a front view of the operation unit and the guide unit, (b) is a side view of the operation unit and the guide unit, and (c) is a cross section of the operation unit and the guide unit. It is a schematic diagram. (A) to (c) are sectional views of the operation unit and the guide unit according to the ninth embodiment. (A) is a side view of the operation unit according to the tenth embodiment, and (b) is a schematic cross-sectional view of the operation unit in the LVb-LVb line of FIG. 55 (a). It is an exploded perspective view of the gripping unit. (A) and (b) are front views of the operation unit and the guide unit, and (c) and (d) are sectional views of the operation unit. (A) and (b) are side views of the operation unit and the guide unit, and (c) and (d) are cross-sectional views of the operation unit. (A) is a front view of the guide unit in the eleventh embodiment, and (b) is a cross-sectional view of the guide unit in the LIXb-LIXb line of FIG. 59 (a). (A) is a cross-sectional view of the guide unit according to the twelfth embodiment, and (b) is an exploded cross-sectional view of the guide unit. (A) is a cross-sectional view of the guide unit according to the thirteenth embodiment, and (b) is an exploded cross-sectional view of the guide unit according to the thirteenth embodiment. (A) is a cross-sectional view of the guide unit according to the 14th embodiment, and (b) is a cross-sectional view of the guide unit according to the 15th embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, with reference to FIGS. 1 to 38, as a first embodiment, an embodiment when the present invention is applied to the slot machine 10 will be described. FIG. 1 is a front view of the slot machine 10 according to the first embodiment. FIG. 2 is a perspective front view of the slot machine 10 with the front door 12 closed, and FIG. 3 is a perspective front view of the slot machine 10 with the front door 12 open. FIG. 4 is a perspective rear view of the front door 12 in a state where the reel unit 41 is opened from the front door 12 to the rear side. FIG. 5 is a rear view of the front door 12, and FIG. 6 is a front view of the housing 11. Note that FIG. 1 shows a state in which the game panel 30 arranged on the front side of the auxiliary display unit 15 is removed. Further, in FIG. 1, each effective line display unit 32, 33, 34 described later is illustrated by a two-dot chain line.

Further, in the following description, with respect to the slot machine 10 in the state shown in FIG. 1, the front side of the paper surface will be referred to as the front (front) side, and the back side of the paper surface will be described as the rear (back) side. Further, with respect to the slot machine 10 in the state shown in FIG. 1, the upper side is the upper (upper) side, the lower side is the lower (lower) side, the right side is the right side (right) side, and the left side is the left side (left). ) Side will be explained respectively. The arrows UD, LR, and FB in the drawing indicate the vertical direction, the horizontal direction, and the front-rear direction of the slot machine 10, respectively.

As shown in FIGS. 1 to 6, the slot machine 10 includes a housing 11 that forms an outer shell thereof. As shown in FIGS. 3 and 6, the housing 11 is composed of a top plate 11a, a bottom plate 11b, a back plate 11c, a left side plate 11d, and a right side plate 11e formed in a wooden plate shape, and each adjacent plate 11a 11e is fixed by a fixing means such as adhesive, so that one surface on the front side (arrow F direction side) is open as a whole to form a box shape. In addition to being made of wooden panels, each of the plates 11a to 11e may be made of a synthetic resin material or a metal material to form an integral box. The housing 11 configured as described above is attached by hitting a nail against the so-called island equipment at the time of installation in the game hall.

Further, on the bottom plate 11b of the housing 11, a metal plate 11b1 made of a plate-like body is arranged on the inner surface of the housing 11 on the open side (arrow F direction side). As a result, when the front door 12, which will be described later, is arranged on the front (open) side of the housing 11, a part of the front door 12 can be mounted on the metal plate 11b1 and arranged at this time. It is possible to prevent the bottom plate 11b of the door from rubbing and becoming brittle. Further, by disposing a part of the front door 12 on the front side of the metal plate 11b1, the front door 12 can be supported by the bottom surface 11b of the housing 11 (that is, the metal plate 11b1 can be used as reinforcement). ). As a result, it is possible to prevent the support shafts 25a and 25b of the housing 11 and the support metal fittings 26a and 26b of the front door 12 from being damaged, which will be described later.

A front door 12 as a front opening / closing door is attached to the front side (arrow F direction side) of the housing 11 so as to be openable / closable. That is, as shown in FIG. 6, the left side plate 11d of the housing 11 is provided with a pair of upper and lower support shafts 25a and 25b. The support shafts 25a and 25b are provided with a tapered shaft portion that protrudes upward. On the other hand, as shown in FIG. 5, the front door 12 is provided with support metal fittings 26a and 26b having shaft support holes into which the shaft portions of the support shafts 25a and 25b are inserted corresponding to the shafts 25a and 25b. Has been done. Then, by arranging the support metal fittings 26a and 26b above the support metal fittings 25a and 25b and lowering the front door 12, the shaft portions of the support metal fittings 25a and 25b are inserted into the insertion holes of the support metal fittings 26a and 26b. It is said that it has been done. As a result, the front door 12 is rotatably supported about the opening / closing axis extending in the vertical direction (arrow UD direction) connecting the support shafts 25a and 25b with respect to the housing 11, and the housing is rotated by the rotation. It is configured so that the front open side of 11 can be opened or closed.

In the following description, as shown in FIG. 2, a state in which the front door 12 is closed with respect to the housing 11 (a state in which the front door 12 is arranged on the open surface of the housing 11) is defined as a closed state. As shown in FIG. 3, a state in which the front door 12 is open to the housing 11 (a state in which the open surface of the housing 11 is open) will be described as an open state. Further, in the following description, unless otherwise specified, the description will be made in a closed state in which the front door 12 is closed with respect to the housing 11.

The front door 12 is locked so that it cannot be opened by the locking device provided on the back surface thereof. Further, as shown in FIG. 1, a key cylinder 20 of an unlocking operation unit is provided at a lower portion (a portion in the arrow D direction) of the front door 12 on the right end side (arrow R direction side). The key cylinder 20 is integrated with the locking device, and is configured so that the locked state is unlocked by a predetermined key operation on the key cylinder 20. Therefore, the lock mechanism including the locking device will be outlined.

A locking device is provided on the right end side of the front door 12, that is, on the opposite side (arrow R direction side) of the opening / closing shaft of the front door 12 on the back surface thereof. As shown in FIGS. 3 and 5, the locking device includes a base frame extending in the vertical direction and fixed to the front door 12, and a key cylinder 20 provided so as to extend from the upper part of the base frame to the front of the front door 12. It is provided with a long interlocking rod 21 that is assembled so as to be movable in the vertical direction with respect to the base frame. Of the locking devices, only the key cylinder 20 is provided so as to project forward of the front door 12. In the present embodiment, the key cylinder 20 is an omlock (trade name) having a high function of preventing unauthorized unlocking.

The interlocking rod 21 is moved downward by operating the key inserted in the key cylinder 20 clockwise. The interlocking rod 21 is provided with a pair of upper and lower hook metal fittings 22 having a hook shape, and when the front door 12 is closed with respect to the housing 11 (closed state), the hook metal fittings 22 are on the housing 11 side. It is locked to the support metal fitting 23 (see FIG. 6) and locked. The hook metal fitting 22 is provided with an urging member such as a coil spring that urges the side that maintains the locked state. When the key is operated clockwise with respect to the key cylinder 20, the interlocking rod 21 moves downward, and the hook fitting 22 is moved against the urging force of the urging member, so that the hook fitting 22 and the hook fitting 22 are moved. The locked state with the support metal fitting 23 is released, and the locked state of the front door 12 with respect to the housing 11 is released.

An auxiliary display unit 15 and a reel unit 41 below the auxiliary display unit 15 are arranged via the game panel 30 on the upper side of the central portion of the front door 12 (closer to the arrow U direction) (see FIG. 1). .. In the following description, the area where the reel unit 41 can be visually recognized from the lower side of the liquid crystal frame member 600 (see FIG. 12) on which the auxiliary display unit 15 is arranged via the game panel 30 is referred to as a “visible area”. Called.

As shown in FIG. 4, the reel unit 41 is attached to the inside of the frame unit 45 formed by combining a plurality of plate members in a frame shape. A speaker 46 that outputs sound is arranged above the frame unit 45. Further, the speaker 46 is arranged so that the sound output surface faces the back side, and the sound output from the speaker 46 is echoed inside the housing 11. As a result, the sound can be transmitted from the entire slot machine 10 to the player, and it is possible to easily give the player a hobby by the sound.

A pair of upper and lower second support shafts 45a and 45b are provided on the left side of the frame unit 45 (on the side in the direction of arrow L) (see FIG. 7). The second support shafts 45a and 45b include a tapered shaft portion that protrudes downward. On the other hand, as shown in FIG. 5, the front door 12 is provided with support metal fittings 26c and 26d having shaft support holes for inserting the shaft portions of the support shafts 45a and 45b corresponding to the shafts 45a and 45b. Has been done. Then, by arranging the support shafts 45a and 45b above the support metal fittings 26c and 26d and lowering the frame unit 45, the shaft portions of the support shafts 45a and 45b are inserted into the insertion holes of the support metal fittings 26c and 26d. It is said that it has been done. As a result, the frame unit 45 is rotatably supported about the (parallel) opening / closing axis along the vertical direction (arrow UD direction) connecting the support shafts 45a and 45b to the front door 12. Therefore, as shown in FIG. 4, the front door 12 is rotated to the front side (arrow F direction side) with respect to the housing 11, and then the frame unit 45 is rotated to the back side (arrow B direction side). The front side of the frame unit 45 (reel unit 41) can be opened.

The reel unit 41 includes a left reel 42L, a middle reel 42M, and a right reel 42R, which are formed in a cylindrical shape (annular shape), respectively. It should be noted that each reel 42L, 42M, 42R may be configured as at least an endless belt, and is not limited to a cylindrical shape (annular ring). Each reel 42L, 42M, 42R is rotatably supported so that its central axis is the rotation axis of the reel. The rotation axes of the reels 42L, 42M, and 42R are arranged on the same axis extending in the substantially horizontal direction. Further, when the reels 42L, 42M, 42R rotate in the forward direction, the surfaces of the reels 42L, 42M, 42R are visually recognized by the player through the game panel 30 as if they are moving from top to bottom.

Each of these reels 42L, 42M, 42R is connected to stepping motors 61L, 61M, 61R, and each reel 42L, 42M, 42R is individually driven by the stepping motors 61L, 61M, 61R, that is, independently of each other. It is configured so that it can be driven to rotate. Since each of these reels 42L, 42M, and 42R has the same configuration, the right reel 42R will be described here with reference to FIG. 7 as an example. FIG. 7 is an exploded perspective view of the frame unit 45.

The right reel 42R includes a cylindrical skeleton member 50 that forms a cage on a cylinder, and a strip-shaped belt that is wound endlessly on the outer peripheral surface thereof. Then, it is attached to the cylindrical skeleton member 50 via a pair of sealing portions formed along both sides of the long side of the belt so as to maintain the wound state. A large number of symbols as identification information are printed on the outer peripheral surface of the belt at equal intervals. A boss portion 51 is formed in the central portion of the cylindrical skeleton member 50, and is attached to the drive shaft of the right reel stepping motor 61R via a disc-shaped boss reinforcing plate 52. Therefore, when the drive shaft of the right reel stepping motor 61R rotates, the cylindrical skeleton member 50 rotates about the drive shaft so that the right reel 42R orbits along the reel surface on the annulus. It has become.

The right reel stepping motor 61R is fixed to the side surface of the motor plate 53 arranged in an upright state in the reel unit 41 (FIG. 4) with screws 54. The motor plate 53 is provided with a reel index sensor (rotational position detection sensor) 55 in which the light emitting element 55a and the light receiving element 55b are held at predetermined intervals. On the other hand, the base end portion 56b of the sensor cut van 56 extending in the radial direction is fixed to the boss reinforcing plate 52 integrated with the right reel 42R with a screw 57. The tip portion 56a of the sensor cut van 56 is bent at a substantially right angle and is aligned so that it can pass between both elements 55a and 55b of the reel index sensor 55. Then, each time the left reel 42R makes one rotation, the reel index sensor 55 detects the passage of the tip portion 56a of the sensor cut van 56, and each time the detection is performed, a detection signal is output to the main control device 131 described later. Therefore, the main control device 131 can confirm and correct the angular position of the left reel 42L for each rotation based on this detection signal.

The stepping motor 61R is set to rotate once by giving, for example, a drive signal of 504 pulses (also referred to as an excitation signal or an excitation pulse; the same applies hereinafter), and the rotation position of the stepping motor 61R, that is, the left side by this excitation pulse. The rotation position of the reel 42L is controlled.

On each belt of each reel 42L, 42M, 42R, a plurality of symbols, specifically 21 symbols, are drawn in the long side direction (circumferential direction) thereof. Therefore, it takes 24 pulses (= 504 pulses ÷ 21 symbols) to switch from one symbol to the next at a predetermined position. Then, based on the number of pulses from the time when the detection signal of the reel index sensor 55 is output, it is possible to recognize which symbol is visible from the visible region, or to make any symbol visible from the visible region. It is possible to perform control such as recognizing whether or not it is, and making an arbitrary symbol visible from a visible region.

Among the symbols attached to the reels 42L, 42M, 42R, the number of symbols that can be visually recognized as a whole from below the liquid crystal frame member 600, which will be described later, via the game panel 30, mainly depends on the length of the visible region in the vertical direction. Limited to a predetermined number to be determined. In this embodiment, there are three reels each. Therefore, when all the reels 42L, 42M, and 42R are stopped, 3 × 3 = 9 symbols are visible to the player.

Here, the symbols attached to the reels 42L, 42M, and 42R will be described. FIG. 8 shows a pattern arrangement drawn on a belt wound around each of the left reel 42L, the middle reel 42M, and the right reel 42R. As shown in the figure, each reel 42L, 42M, 42R is provided with 21 symbols in a row. Numbers 1 to 21 are assigned to each reel 42L, 42M, 42R, but this is for convenience of explanation and is not actually attached to the reels 42L, 42M, 42R. .. However, in the following description, the number will be used for explanation.

As the symbols, there are a "7" symbol (for example, the 20th left belt) and a "youth" symbol (for example, the 19th left belt) as the first special symbol for shifting to the big bonus game. In addition, there is a "BAR" symbol (for example, the 14th left belt) as a second special symbol for shifting to the regular bonus game. In addition, there is a "replay" symbol (for example, the eleventh left belt) as a third special symbol for shifting to a replay game in which the next game can be executed without inserting medals. In addition, the "watermelon" symbol (for example, the 9th left belt), the "bell" symbol (for example, the 8th left belt), and the "cherry" symbol (for example, the left) as the small winning combination symbols for which the small winning combination is paid out. There is a fourth belt). As shown in FIG. 7, the number and arrangement order of various symbols are completely different in the belts wound around the reels 42L, 42M, and 42R.

The reels 42L, 42M, and 42R of the reel unit 41 are examples of display devices that display identification information in a variable manner, and the display devices may have other configurations. For example, it may be another mechanical reel configuration such as a type in which the belt rotates instead of rotating, and instead of or in addition to the mechanical reel configuration, a liquid crystal display, a dot matrix display, etc. It is possible to provide a variable display of the identification information by an electric display such as, and in this case, it is possible to have abundant variations in the display form.

The game panel 30 is connected to the symbols of the reels 42L, 42M, and 42R that are visible from the visible region, and is a combination line of three reels in parallel in the horizontal direction and two in the diagonal direction, for a total of five. Is attached. Of course, the maximum number of combination lines may be 6 or more, less than 5, and the maximum number of combination lines may be changed according to a predetermined condition. Each effective line display unit 32, 33, 34 is provided corresponding to each of these combination lines. The first effective line display unit 32 is notified by lighting or the like when the central horizontal line (center line) of the combination lines is activated. The second effective line display unit 33 is notified by lighting or the like when the upper and lower horizontal lines (upper line and lower line) of the combination lines are activated. The third effective line display unit 34 is notified by lighting or the like when a pair of diagonal lines (a downward-sloping line and an upward-sloping line) of the combination lines are enabled. Then, when the symbols stop at the activated combination line, that is, the valid line in a predetermined combination, a prize is won, and a predetermined medal payout process, a transfer process to a specific game, and the like are executed.

In this embodiment, when each effective line display unit 32, 33, 34 is activated, each effective line is supported by an issuing device such as an LED arranged on the motor plate 53 of the reel unit 41. The part to be light is emitted.

Here, the number of payouts for each symbol in the case of winning a prize will be described. Regarding small role symbols, if the "watermelon" symbol is aligned with the left, middle, and right on the effective line, 15 medals will be paid out, and if the "bell" symbol is aligned with the left, middle, and right on the effective line, Eight medals are paid out, and two medals are paid out when the "cherry" symbol on the left reel 42L stops on the effective line. That is, the "cherry" symbols on the middle reel 42M and the right reel 42R are irrelevant to medal payout. In addition, as far as the "cherry" symbol is concerned, medals are paid out regardless of the combination with other symbols, so that the "cherry" symbol is placed at the position where the plurality of effective lines of the left reel 42L overlap (specifically, the upper or lower row). When the "cherry" symbol is stopped, medals are paid out by multiplying the number of overlapping effective lines, and as a result, four medals are paid out in the present embodiment.

Regarding other symbols, if the "7" symbol or the "youth" symbol, which is a combination of the first special symbol (big bonus symbol), is aligned with the left, middle, and right on the effective line with the same symbol, 15 medals are paid out, and 15 medals are also paid out when the "BAR" symbol, which is a combination of the second special symbol (regular bonus symbol), is aligned with the left, middle, and right on the effective line. In the present embodiment, for example, the "7" symbol and the "cherry" symbol may be established at the same time, and in such a case, 15 medals are paid out. This is because the maximum number of medals to be paid out at one time is set to 15.

Furthermore, if the "replay" symbol, which is a combination of the third special symbols, is aligned with the left, middle, and right on the effective line, the medal will not be paid out. In other cases, that is, when the "cherry" symbol on the left reel 42L does not stop on the effective line and the same symbols as left, middle, and right are not aligned on the effective line, it is out of the question. Is not done.

As shown in FIG. 1, a start lever 71 operated to start rotation of the reels 42L, 42M, and 42R all at once (not necessarily at the same time) is provided on the lower left side of the game panel 30. .. The start lever 71 constitutes a starting operation means in which a starting operation is performed so as to start rotating the reels 42L, 42M, 42R, that is, to start the variable display of the symbol. The start lever 71 is a lever that is pushed and operated by the player when the player starts the game, and is automatically returned to the original position after the hand is released by the built-in spring. If the start lever 71 is operated while the medal is being inserted, the reels 42L, 42M, and 42R start rotating all at once.

As shown in FIG. 1, button-shaped stop switches 72, 73, 74 operated to individually stop the rotating reels 42L, 42M, 42R are provided on the right side of the start lever 71. There is. The stop switches 72, 73, and 74 are arranged directly below the reels 42L, 42M, and 42R to be stopped, respectively. The stop switches 72, 73, 74 constitute a stop operation means operated to stop the variation display based on the rotation of the reels 42L, 42M, 42R. Each of the stop switches 72, 73, 74 is in a state where it can be stopped after a predetermined time has elapsed from the start of rotation of the left reel 42L, and during such a state, a lamp (not shown) is lit and displayed to stop. It is notified that the operation is possible, and it is turned off when the rotation stops.

As shown in FIG. 1, a medal insertion slot 75 for inserting a medal as a game medium for playing a game is provided on the lower right side of the visible region. The medal slot 75 constitutes an entrance that can accept game media. Further, paying attention to the fact that the medal insertion slot 75 is accompanied by an operation of directly inserting medals by the player, it can be said that it constitutes a direct input means for directly inputting the game medium.

As shown in FIG. 4, the medals inserted from the medal insertion slot 75 are guided to either the storage passage 81 or the discharge passage 82 by the selector 83 provided on the back surface of the front door 12. The selector 83 is provided with a medal passage switching member 84, which will be described later, so that the passing direction of the medal can be switched between the discharge passage 82 side and the storage passage 81 side according to the state of the medal passage switching member 84. It has become. The medal guided to the storage passage 81 is guided to the hopper device 91 housed inside the housing 11. On the other hand, the medals guided to the discharge passage 82 are guided to the medal tray 18 from the medal discharge port 17 provided in the lower front portion of the front door 12, and are returned to the player.

As shown in FIG. 6, the hopper device 91 as a payout means for awarding medals to the player is arranged below the reel unit 41. Further, as shown in FIG. 3, the hopper device 91 includes a storage tank 92 for storing medals and a payout device 93 for paying out medals to the player. The payout device 93 discharges the medal to the opening 94 provided in the center right portion of the discharge passage 82, and pays out the medal to the medal tray 18 through the discharge passage 82.

As shown in FIG. 6, a spare tank 95 is provided on the right side of the hopper device 91 to prevent medals from being stored in the storage tank 92 from being stored in a predetermined amount or more. Inside the storage tank 92 of the hopper device 91, a guide plate 96 for discharging medals from the storage tank 92 to the spare tank 95 is provided. Therefore, when medals are stored above the height at which the guide plate 96 is provided, the medals are stored in the spare tank 95.

As shown in FIG. 2, a button-shaped return switch 76 is provided below the medal insertion slot 75. The return switch 76 is a switch that is pressed when a medal inserted into the medal insertion slot 75 is jammed in the selector 83, and when the return switch 76 is pressed, the selector 83 is mechanically interlocked and operated. The medals packed in the selector 83 are returned from the medal ejection port 17.

As shown in FIG. 2, a button-shaped first credit insertion switch 77 for inserting three virtual medals credited as a game medium at a time is provided on the lower left side of the display windows 31L, 31M, 31R. There is. Further, on the left side of the first credit insertion switch 77, a second credit insertion switch 78 formed in a button shape smaller than the switch 77 and a third credit insertion switch 79 are provided. The second credit insertion switch 78 is for inserting two credited virtual medals at a time, and the third credit insertion switch 79 is for inserting one virtual medal.

Each of the credit insertion switches 77 to 79 constitutes an input means for inputting a game medium together with the medal insertion slot 75. Further, it should be noted that while the medal insertion slot 75 involves an operation of directly inserting medals by the player, each credit insertion switch 77 to 79 only involves an operation of inserting a virtual medal based on the stored memory. , It can be said that it constitutes an indirect input means for indirectly inputting the investment value.

The first credit insertion switch 77 has a built-in lamp as a light emitting member (not shown) in order to encourage that the maximum number of medals (3 medals) that can be inserted per game has not been reached. The lamp is lit when the switch operation of the first credit insertion switch 77 is valid to prompt the operation of the switch 77, but when there is no credited virtual medal or three medals have already been inserted. It is turned off under the condition that it is. Here, instead of the above lighting, it may be blinked to make it easier for the player to understand the prompt for inserting the medal.

As shown in FIG. 2, a button-shaped changeover switch 80 is provided on the left side of the start lever 71. The changeover switch 80 is configured as a toggle type that turns on when pressed once, turns off when pressed again, and switches on and off each time a subsequent pressing operation is performed. The changeover switch 80 is operated to change the handling format of the inserted medals inserted into the medal insertion slot 75 in excess of the required amount and the acquired medals returned to the player as a result of the predetermined game.

When the changeover switch 80 is on, the "credit mode" is set so that the surplus inserted medals and the medals won at the time of winning are stored and stored as credit medals until the predetermined maximum value (for example, 50 medals) is reached. ". When the changeover switch 80 is in the off state, the "direct mode" is set so that the surplus inserted medals and the winning medals at the time of winning are paid out as actual medals. If there is a credit medal when the mode is switched from the credit mode to the direct mode, the credit medal for that amount is paid out as an actual medal. In this way, the player can execute the game in a format according to his / her preference by switching between the credit mode and the direct mode. The changeover switch 80 constitutes a changeover operation means for switching between the input value and the handling type of the game value. Further, paying attention to the function of paying out the credited virtual medal as an actual medal, it can be said that the changeover switch 80 constitutes a settlement operation means for actually paying out the stored and stored game value. In addition to being configured to switch between "credit mode" and "direct mode" by operating the changeover switch 80, the virtual medal stored and stored is paid out when the changeover switch 80 is operated by always setting the "credit mode". It may function as a payment switch only.

Below the game panel 30, there is a remaining number display unit 35 that displays the number of medals that are activated and stored in the credit mode, and for example, the number of remaining games in a special game state such as a big bonus or a regular bonus. The number of games display unit 36 for displaying the above and the number of acquired medals display unit 37 for displaying the number of acquired medals are provided. These display units 35 to 37 are composed of a 7-segment display, but it is naturally possible to replace them with a liquid crystal display or the like.

Here, the procedure for betting medals will be described. In both the direct mode and the credit mode, when a medal is inserted from the medal insertion slot 75 at the start of the game, a bet is placed.

That is, when the first medal is inserted into the medal insertion slot 75, the first effective line display unit 32 lights up, and the corresponding central line becomes the effective line, and the second medal is the medal insertion slot. When it is inserted into 75, the second effective line display unit 33 lights up, and the corresponding upper line and the lower line, including the lower line, become effective lines, respectively, and the third medal. Is inserted into the medal insertion slot 75, the third effective line display unit 34 is further lit, and all five combination lines including the corresponding pair of diagonal lines become effective lines.

When four or more medals are inserted into the medal slot 75, the surplus medals exceeding three are switched to the discharge passage 82 by the selector 83 if the mode at that time is the direct mode. It is returned from the discharge port 17 to the medal tray 18. On the other hand, in the credit mode, the number of saved cards is displayed inside the slot machine and the remaining number display unit 35 displays the number of saved cards. An upper limit is set for the number of stored medals (for example, 50), and when more medals are inserted, the medals are returned from the medal ejection port 17 to the medal tray 18.

Further, when the game is played in the credit mode and the number of stored sheets is displayed on the remaining number display unit 35, it is virtual even when any of the first to third credit insertion switches 77 to 79 is pressed. It is a bet because the medal has been inserted.

When the third credit insertion switch 79 is pressed, one numerical value displayed on the remaining number display unit 35 is decremented as if one virtual medal has been inserted, and the first effective line display unit 32 displays. It lights up and the center line becomes the effective line. When the second credit insertion switch 78 is pressed, two numerical values displayed on the remaining number display unit 35 are decremented as if two virtual medals have been inserted, and the first effective line display unit 32, Then, the second effective line display unit 33 lights up, and a total of three combination lines become effective lines. When the first credit insertion switch 77 is pressed, three numerical values displayed on the remaining number display unit 35 are decremented as if three virtual medals have been inserted, and all the effective line display units 32 to 34 lights up and a total of 5 combination lines become effective lines.

When any of the first to third credit insertion switches 77 to 79 is pressed and the virtual medals to be inserted are not stored, for example, when the display of the remaining number display unit 35 is 2, the first When the credit insertion switch 77 is pressed, all the numerical values of the remaining number display unit 35 are decremented to 0, and only the virtual medals that can be inserted are bet.

An upper lamp unit 13 is arranged above the front door 12. The upper lamp unit 13 includes an upper lamp 13a formed in a horizontally long shape along the upper side (upper base member 27) of the slot machine 10 inside the upper lamp unit 13. The upper lamp 13a includes a plurality of LEDs (light emitting devices) capable of emitting light, and the LEDs can be turned on or blinked as the game progresses.

In the present embodiment, the auxiliary display unit 15 is composed of a liquid crystal display for the purpose of diversifying the display contents and increasing the weight of the display effect, but another display such as a dot matrix display is used. You may. The auxiliary display unit 15 is for executing various display effects as the game progresses, and the game by each reel 42L, 42M, 42R can be considered to be due to the main display unit. Therefore, in the present embodiment, the auxiliary display unit 15 is used. It is called an auxiliary display unit 15. On the back surface of the auxiliary display unit 15, an upper lamp 13a, a speaker 14, and a display control device 111 for driving the auxiliary display unit 15 are provided. The shapes, positions, numbers, and the like of the lamp 13 and the speaker 14 are not particularly limited to those described above.

As shown in FIG. 2, a lower plate 16 on which a model name, characters related to the game, and the like are displayed is mounted above the medal tray 18.

As shown in FIG. 6, a power supply box 121 is provided on the back side (arrow B direction side) of the hopper device 91 inside the housing 11. The power supply box 121 includes a power supply switch 122, a reset switch 123, a setting key insertion hole 124, and the like. The power switch 122 is a start switch for supplying power to each unit including the main control device 131.

The reset switch 123 is a switch for resetting various states of the slot machine 10. This slot machine 10 has a backup function for various data, maintains the state at the time of power failure even in the unlikely event of a power failure, and returns to the state at the time of power failure when recovering from the power failure (recovery of power). You can do it. Therefore, if the power is shut off in the normal procedure, for example, when the game hall is closed, the state before the shutoff is stored in memory, but if the power switch 122 is turned on while pressing the reset switch 123, the backup data is reset. It has become so. If the reset switch 123 is pressed while the power switch 122 is on, the error state is reset.

The setting key insertion hole 124 is for a hole manager or the like to adjust the output of medals. That is, the hall manager or the like can change the setting state (winning probability setting process) of the slot machine 10 from "setting 1" to "setting 6" by inserting the setting key into the setting key insertion hole 124 and operating the slot machine 10. It has become.

As shown in FIG. 6, the main control device 131 is attached to the back plate 11c of the housing 11 above the reel unit 41. The main control device 131 has a CPU that controls the main control, a ROM that stores a game program, a RAM that temporarily stores necessary data according to the progress of the game, a port for contacting various devices, and time counting and synchronization. It is provided with a main board including a clock circuit or the like used for planning, and the main board is housed in a board box as an encapsulation means made of a transparent resin material or the like. The substrate box includes a box base having a substantially rectangular parallelepiped shape and a box cover that covers an opening of the box base. The box base and the box cover are unopenably connected by a sealing unit as a sealing means, whereby the substrate box is sealed. The box base and the box cover may be connected to each other by using a key member so as not to be opened.

FIG. 9 is a diagram showing the internal structure of the selector 83. The two-dot chain line in the figure shows the passage route of the medal for easy understanding. The selector 83 is formed with a guide passage 85 for guiding the medals inserted from the medal insertion port 75 to the storage passage 81. The guide passage 85 is formed in a curved shape that draws an arc from the upper end to the lower right of the figure so that medals can pass in one row. More specifically, the selector body constituting the selector 83 is provided with a ridge 85a protruding toward the front side in the drawing, and a guide passage 85 is formed along the ridge 85a. As a result, the medals that have reached the guide passage 85 will flow in the downstream direction so as to roll on the ridge 85a.

The medal passage switching member 84 has a passage switching piece 84a provided upstream of the guide passage 85 and capable of appearing and disappearing from the guide passage 85, and a solenoid (not shown) for operating the passage switching piece 84a. doing. When the solenoid is not excited, the passage switching piece 84a protrudes into the guide passage 85, and the flow of medals to the storage passage 81 is obstructed. As a result, the medal falls downward so as to get over the ridge 85a and is guided to the discharge passage 82. Further, when the solenoid is excited, the passage switching piece 84a sinks outside the guide passage 85. As a result, the medal flows along the guide passage 85 and is guided to the storage passage 81.

On the downstream side of the passage switching piece 84a, the first inserted medal detection sensor 86 for detecting the passage of medals and the second inserted medal detection sensor 87 are arranged close to each other so as to line up upstream and downstream of the guide passage 85. (The proximity state is such that the same medal is detected at the same time at least for one period). When the solenoid of the medal passage switching member 84 is not excited, the medal falls downward from the middle of the guide passage 85, so that the passage of the medal is not detected by the inserted medal detection sensors 86 and 87. On the other hand, when the medal passage switching member 84 is solenoid-excited, the passage of medals is sequentially detected by the inserted medal detection sensors 86 and 87.

Next, the electrical configuration of the slot machine 10 will be described with reference to the block diagram of FIG. FIG. 10 is a block diagram showing an electrical configuration of the slot machine 10.

The main control device 131 is equipped with a microcomputer centered on the CPU 151, which is an arithmetic processing means. In addition to the power supply device 161 provided inside the power supply box 121, a clock circuit 154 that outputs a rectangular wave having a predetermined frequency, an input / output port 155, and the like are connected to the CPU 151 via an internal bus. The main control device 131 functions as a main board built in the slot machine 10.

On the input side of the main controller 131, there are a start detection sensor 71a that detects the operation of the start lever 71, a stop detection sensor 72a, 73a, 74a that individually detects the operation of each of the stop switches 72, 73, 74, and a medal insertion slot. The first inserted medal detection sensor 86 that detects the medals inserted from 75, the second inserted medal detection sensor 87 (hereinafter, when these sensors are collectively referred to as the inserted medal detection sensors 86, 87), each credit The credit insertion detection sensors 77a, 78a, 79a that individually detect the operation of the closing switches 77, 78, 79, the switching detection sensor 80a that detects the operation of the changeover switch 80, and the rotation position (origin position) of each reel 42 are individually set. The reel index sensor 55 to detect, the payout detection sensor 91a to detect the medal paid out from the hopper device 91, the reset detection sensor 123a to detect the operation of the reset switch 123, and the setting key insertion hole 124 to detect that the setting key has been inserted. Various sensors such as the setting key detection sensor 124a are connected, and signals from these various sensors are output to the CPU 151 via the input / output port 155.

Further, the detection signals of the input medal detection sensors 86 and 87 are also input to the detection signal latch circuit 88. The detection signal latch circuit 88 inputs a signal detection circuit unit for inputting a detection signal from the first insertion medal detection sensor 86 and a detection signal from the second insertion medal detection sensor 87, and an output signal of the signal detection circuit unit. A latch circuit unit for latching is provided. The signal detection circuit unit has an OR circuit as a main configuration, and by inputting at least one of the detection signals from the first insertion medal detection sensor 86 and the detection signal from the second insertion medal detection sensor 87, A signal corresponding to the logical sum is output to the latch circuit unit, and further, a latch signal is output from the latch circuit unit to the main control device 131. The latch signal output state of the detection signal latch circuit 88 is held until a signal release command is input from the main control device 131. Details will be described later.

Further, a power failure monitoring circuit 161b provided in the power supply device 161 is connected to the input side of the main control device 131 via the input / output port 155. The power supply device 161 is equipped with a power supply unit 161a that supplies drive power to each electronic device of the slot machine 10 including the main control device 131, a power failure monitoring circuit 161b described above, and the like.

The power failure monitoring circuit 161b monitors the power cutoff state and generates a power failure signal not only when the power is cut off but also when the power supply is cut off by the power switch 122. Therefore, the power failure monitoring circuit 161b monitors the stabilized drive voltage of DC 12 volt in this example output from the power supply unit 161a, and determines that the power supply is cut off when this drive voltage drops to less than, for example, 10 volt. It is configured to output a power failure signal. The power failure signal is supplied to each of the CPU 151 and the input / output port 155, and the CPU 151 recognizes the power failure signal to execute the power failure processing described later.

Even if the output voltage drops to less than 10 volts from the power supply unit 161a, a regulated voltage of 5 volts, which is used as a drive voltage in a control system such as the main controller 131, is output. As the time for which the regulated voltage is output, a sufficient time is secured for executing the power failure processing by the main controller 131.

To rotate each effective line display unit 32, 33, 34, remaining number display unit 35, game number display unit 36, acquired number display unit 37, and reels 42L, 42M, 42R on the output side of the main control device 131. External centralized terminal board 171 that can transmit information to each stepping motor 61 (61L, 61M, 61R), a medal passage switching member 84 provided in the selector 83, a hopper device 91, a display control device 111, a hole management device (not shown), and the like. Etc. are connected via the input / output port 155.

The display control device 111 is a control device for driving the upper lamp 13a, the closing abnormality lamp 13b, the speaker 14, and the auxiliary display unit 15 constituting the lamp 13, and includes a CPU, ROM, RAM, and the like for driving these. It has an integrated substrate. Then, after receiving the signal from the main control device 131, the display control device 111 independently drives and controls the lamps 13a and 13b, the speaker 14, and the auxiliary display unit 15. Therefore, the display control device 111 is a sub-board that executes auxiliary control in relation to the main control device 131, which is the main board that centrally manages the game. That is, the burden on the main board is reduced by providing a sub board for voices, lamps, and displays related to indirect games. The display control device 111 may control the various display units 32 to 37.

The CPU 151 described above has a ROM 152 that stores various control programs and fixed value data executed by the CPU 151, and an operation that temporarily stores various data when executing the control program stored in the ROM 152. In addition to the RAM 153 for securing the area, as is well known, various processing circuits required in the slot machine 10 such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit, and a credit counter for counting the number of credits, as is not shown, Various counters such as are built-in. A main memory as a storage means is configured by the ROM 152 and the RAM 153, and a program for executing the processes shown in various flowcharts shown in FIGS. 10 and 10 and later is stored in the ROM 152 described above as a part of the control program.

The RAM 153 has a configuration in which a backup voltage is supplied from the power supply device 161 provided in the power supply box 121 to hold (backup) data even after the power supply of the slot machine 10 is cut off. A backup area is provided in addition to a memory and an area for temporarily storing various data and the like.

In the backup area, when the power is cut off due to a power failure or the like, the stack pointer at the time of power cutoff (including power cutoff by operating the power switch 122; the same applies hereinafter), each register, the value of I / O, etc. It is an area for storing the above, and when the power failure is resolved (including turning on the power by operating the power switch 122. The same applies hereinafter), the state of the slot machine 10 is set to the state before the power is cut off based on the information in the backup area. It is possible to return to the state. Writing to the backup area is executed when the power is cut off by a power failure process (see FIG. 10), and restoration of each value written in the backup area is executed in the main process (see FIG. 10) when the power is turned on. The NMI terminal (non-maskable interrupt terminal) of the CPU 151 is configured to input a power failure signal from the power failure monitoring circuit 161b when the power is cut off due to a power failure or the like. The NMI interrupt process as the flag generation process is immediately executed.

Next, the displacement unit 300 arranged on the front door 12 will be described with reference to FIGS. 11 to 37. First, with reference to FIGS. 11 and 12, the overall configuration of the front door 12 on which the displacement unit 300 is arranged will be described. FIG. 11 is an exploded perspective front view of the front door 12, and FIG. 12 is an exploded perspective rear view of the front door 12.

As shown in FIGS. 11 and 12, the upper portion of the front door 12 is located on the front side (arrow F direction side) of the top plate 11a of the housing 11 described above, and extends in the left-right direction (arrow LR direction). An upper base member 27 to be provided, a pair of left and right left base members 28 extending downward from both ends of the upper base member 27 in the extending direction, and a right base member 29 are provided. The upper base member 27, the left base member 28, and the right base member 29 form a portal shape in a front view.

Further, in the front door 12, a game panel 30 is arranged on the front side of an inner region formed in a gate shape by the above-mentioned upper base member 27, the left base member 28, and the right base member 29. The upper lamp unit 13, the left lamp unit 38, and the right lamp unit 39 are arranged at positions surrounding the periphery of the game panel 30.

The upper lamp unit 13 is arranged on the front side of the upper base member 27, the left lamp unit 38 is arranged on the front side of the left base member 28, and the right lamp unit 39 is arranged on the front side of the right base member 29. Will be done.

Further, the game panel 30 includes a gate-shaped upper base member 27, a left base member 28, a right base member 29, an upper lamp unit 13 arranged on the front side thereof, and a left lamp. It is interposed between the unit 38 and the right lamp unit 39. As a result, the game panel 30 is attached to the front door 12.

The upper lamp unit 13 is provided with an upper lamp 13a, the left lamp unit 38 is provided with a left lamp 38a, and the right lamp unit 39 is provided with a right lamp 39a, respectively, from the lamps 13a, 38a, 39a. The emitted light can cause the surroundings of the slot machine 10 to emit light. The lamps 13a, 38a, and 39a can individually emit different colors.

Further, in the right lamp unit 39, a displacement unit 300 described later is arranged on the front side, and the light emitted from the right lamp 39a passes through the inside of the displacement unit 300 to the front side of the displacement unit 300 (game). It is configured so that it can be emitted from the person side). That is, the displacement unit 300 can be made to emit light by the right lamp 39a.

On the back side (arrow B direction side) of the upper base member 27, the left base member 28, and the right base member 29 formed in a portal shape, the upper side (see FIG. 3) is higher than the above-mentioned reel unit 41 (see FIG. 3). A liquid crystal frame member 600 arranged in the direction of the arrow U) and an auxiliary display unit 15 arranged on the back side of the liquid crystal frame member 600 are provided.

The liquid crystal frame member 600 is a member for making it easy for the player to visually recognize the image displayed on the auxiliary display unit 15, and is formed in a frame shape surrounding the periphery of the image display surface of the auxiliary display unit 15. Further, the liquid crystal frame member 600 is fastened and fixed to the above-mentioned upper base member 27, the left base member 28, and the right base member 29, and the front door is in contact with the back side of the game panel 30. It is arranged in 12. That is, the formation of a gap between the game panel 30 and the liquid crystal frame member 600 is suppressed. As a result, the image displayed on the auxiliary display unit 15 is reflected at the portion where a gap is formed between the game panel 30 and the liquid crystal frame member 600 (the back surface of the game panel 30 and the front surface of the liquid crystal frame member 600). , It is possible to suppress the reflected light (image) from being visually recognized by the player. As a result, it is possible to make it easier for the player to visually recognize the image displayed on the auxiliary display unit 15.

The entire liquid crystal frame member 600 is formed in black. As a result, the light emitted from the outside of the slot machine 10 to the liquid crystal frame member 600 can be easily absorbed by the liquid crystal frame member 600 as compared with the case where the liquid crystal frame member 600 is formed in white. As a result, it is possible to prevent the light emitted from the outside of the slot machine 10 on the liquid crystal frame member 600 from being reflected by the liquid crystal frame member 600 and the reflected light from being incident on the auxiliary display unit 15. Therefore, it is possible to prevent the image displayed on the auxiliary display unit 15 from becoming difficult to be visually recognized by the player.

Further, as described above, the liquid crystal frame member 600 is formed in a front view frame shape that surrounds the periphery of the image display surface of the auxiliary display unit 15, and is arranged above the reel unit 41 (see FIG. 3). The image display surface of the auxiliary display unit 15 visually recognized via the game panel 30 and the reels 42L, 42M, 42R of the reel unit 41 can be divided into two regions, upper and lower.

Next, the overall configuration of the displacement unit 300 will be described with reference to FIGS. 13 to 15. 13 (a) is a front view of the displacement unit 300, FIG. 13 (b) is a side view of the displacement unit 300 in the XIIIb direction of FIG. 13 (a), and FIG. 13 (c) is a side view of the displacement unit 300. It is sectional drawing of the displacement unit 300 in the XIIIc-XIIIc line of (a). FIG. 14 is an exploded perspective front view of the displacement unit 300. FIG. 15 is an exploded perspective rear view of the displacement unit 300.

As shown in FIGS. 13 to 15, the displacement unit 300 is a base unit 390 arranged on the front side (arrow F direction side) of the right lamp unit 39 (see FIG. 11) described above, and the base unit 390 thereof. An intermediate member 380 arranged with a coil spring SP1 sandwiched between them, an operation unit 320 arranged on the front side of the intermediate member 380, and a part of the operation unit 320 (rotating unit 340). A guide unit 350 for guiding the displacement of the operation unit 320, and an annular member 310 for accommodating the operation unit 320, the guide unit 350, the intermediate member 380, the coil spring SP1, and the base unit 390 inside. And mainly prepare.

The annular member 310 includes an annular portion 311 formed in a hollow annular (cylindrical shape) penetrating in the front-rear direction (arrow FB direction), and an annular portion from the inner peripheral surface of the front end portion of the annular portion 311. A regulation wall 312 erected toward the inside of the 311 is provided.

The annular portion 311 is formed in a size capable of accommodating the guide unit 350 and the base unit 390, which will be described later, inside. Further, the annular portion 311 is formed with a plurality of fastening holes for fastening the guide unit 350 and the screw inserted into the base unit 390 from the back side. As a result, the guide unit 350 and the base unit 390 can be fastened and fixed to the annular member 310.

The annular portion 311 is formed so that the inner edge (inner peripheral surface) penetrating in the front-rear direction (in the direction of arrow FB) is inclined upward from the back side toward the front side (FIG. 13 (c)). reference). As a result, the operation unit 320, the guide unit 350, the intermediate member 380, the coil spring SP1, and the base unit 390 arranged inside the annular portion 311 are also arranged so as to be inclined upward toward the front side. However, in the following description, for ease of understanding, the stacking direction of the operation unit 320, the guide unit 350, the intermediate member 380, the coil spring SP1, and the base unit 390 will be described as the front-rear direction.

The regulation wall 312 is formed in a disk shape, has an opening 312a, and has an outer peripheral portion connected to the inner peripheral surface of the annular portion 311. The opening 312a is formed in a circular shape, and the opening width (inner diameter) thereof is set to be smaller than the outer diameter of the guide unit 350 described later. As a result, when the guide unit 350 is arranged on the annular member 310, the guide unit 350 is inserted from the back side of the annular member 310 into the inside of the annular member 310, and the front side of the guide unit 350 is set on the regulation wall 312. Can be brought into contact with the back side of the.

The operation unit 320 includes a gripping unit 330 arranged on the front side and a rotating unit 340 connected to the back side (arrow B direction side) of the gripping unit 330.

The gripping unit 330 is formed long in the front-rear direction (arrow FB direction) in the side view. Further, the gripping unit 330 is a portion to be gripped by the player, and the end portion on the front side (arrow F direction side) is on the front side (front side) of the ring member 310 through the opening 312a of the ring member 310 described above. It is projected toward the player side), and the player can grip (operate) the end portion on the front side.

The mode of operation of the player with respect to the gripping unit 330 is not limited to the mode of gripping the gripping unit 330, for example, the mode of pushing the gripping unit 330 in the direction of arrow B or the direction of arrow F without gripping the gripping unit 330. It may be a mode of pulling out to.

The rotating unit 340 is formed in a substantially columnar shape having (parallel) axes along the front-rear direction (arrow FB direction), and has a rear side (arrow B) of the gripping unit 330 on the end surface on the front side (arrow F direction side). The end (on the directional side) is connected. As a result, the rotating unit 340 can be displaced in conjunction with the gripping unit 330 being gripped (operated) and displaced by the player.

Further, the rotating unit 340 is housed inside the guide unit 350, which will be described later, and its displacement is regulated (guided) by the guide groove 351 formed inside the guide unit 350. Therefore, the displacement of the gripping unit 330 linked to the rotating unit 340 is regulated (guided) by the guide groove 351 formed in the guide unit 350. A detailed description of the guide groove 351 will be described later.

The guide unit 350 is arranged on the front side (arrow F direction side) of the rotating unit 340, and regulates the displacement of the rotating unit 340 to the front side. A rear side guide unit 370, which is arranged on the side in the direction of arrow B) and regulates the displacement of the rotating unit 340 to the rear side, is provided.

The front side guide unit 360 is formed in a substantially cylindrical shape having (parallel) axes along the front-rear direction (arrow FB direction), and its inner diameter is formed larger than the outer diameter of the rotating unit 340. Further, the external dimension of the front side guide unit 360 in the front-rear direction is set to be larger than the external dimension of the rotating unit 340, and the rotating unit 340 can be accommodated inside the front side guide unit 360.

The rear side guide unit 370 includes a first portion 371 formed in a substantially annular shape having (parallel) axes along the front-rear direction (arrow FB direction), and the inner diameter of the first portion 371 is the rotating unit 340. It is formed smaller than the outer diameter of. Therefore, by accommodating the rotary unit 340 inside the front guide unit 360 and then fastening the front guide unit 360 and the rear guide unit 370, the rotary unit 340 is accommodated inside the guide unit 350. A detailed description of the configuration of the rear guide unit 370 and the displacement of the rotating unit 340 will be described later.

The intermediate member 380 is a member that transmits the urging force of the coil spring SP1 to the rotating unit 340, and is arranged at a position adjacent to the back surface side (arrow B direction side) of the rotating unit 340. Further, the intermediate member 380 is formed in a disk shape, and its outer diameter is set to be smaller than the inner diameter of the back side guide unit 370 of the guide unit 350. As a result, the intermediate member 380 can be displaced inside the guide unit 350.

The intermediate member 380 has a first opening 381 that opens in a circular shape at the center position of the disk, and an opening in the front-rear direction (arrow FB direction) at a position that is radially outward from the center of the first opening 381. A second opening 382, a third opening 383 that opens in the front-rear direction at a position different from the second opening 382 in the circumferential direction, and a projecting portion that protrudes radially outward from a part of the outer peripheral portion. 384 and.

The first opening 381 is an opening for aligning (positioning) the intermediate member 380 with respect to the rotating unit 340. The position of the intermediate member 380 with respect to the rotating unit 340 is adjusted by inserting the insertion portion 342a protruding from the back surface side of the rotating unit 340, which will be described later, into the first opening 381.

Further, the intermediate member 380 includes a cylindrical erection portion 385 that is erected from the back surface side (arrow B direction side) along the inner edge of the first opening 381. The upright portion 385 is a portion on which the front side (arrow F direction side) of the coil spring SP1 is fitted, and the outer diameter is set to be smaller than the inner diameter of the coil spring SP1. Therefore, since the coil spring SP1 is fitted on the vertical portion 385, it is possible to prevent the position of the coil spring SP1 with respect to the intermediate member 380 from being displaced due to elastic deformation.

The second opening 382 has an elongated hole-shaped opening curved along an arc centered on the axis of the intermediate member 380 (that is, a ring shape concentric with the axis of the intermediate member 380 is divided in the circumferential direction. It is formed as an opening). The second opening 382 is an opening through which the engaging piece 342b of the rotating unit 340, which will be described later, is inserted, and is formed in a size (region) that does not interfere with the displacement locus of the engaging piece 342b.

The third opening 383 is an opening through which a wiring (not shown) extending from the right lamp unit 39 described above passes through the base unit 390 and extends inside the rotating unit 340 (operation unit 320). Further, the intermediate member 380 includes a wall portion 386 erected from the back surface side (arrow B direction side) along the inner edge of the third opening 383. The wall portion 386 is formed as a continuous wall portion along the inner edge of the third opening 383.

As a result, the wiring extending from the base unit 390 can be connected to the inside of the rotating unit 340 (operation unit 320) via the third opening 383 (through). Further, when the intermediate member 380 is displaced, the wall portion 386 suppresses the wiring connected to the inside of the rotating unit 340 from being sandwiched between the intermediate member 380 and the base unit 390, so that the wiring is broken. Can be suppressed.

The protrusion 384 is a protrusion that is inserted inside the recess 371a of the guide unit 350, which will be described later, and engages with the guide unit 350. The outer shape of the protrusion 384 is the inner surface shape of the recess 371a. Is formed in a shape corresponding to. Therefore, in the state where the projecting portion 384 is inserted inside the recessed portion 371a, even if an external force that rotationally displaces the intermediate member 380 with respect to the guide unit 350 about the axis is input to the intermediate member 380, the projecting portion 384 is projected. Since the portion 384 is in contact with the inner surface of the recessed portion 371a, the rotation of the intermediate member 380 with respect to the guide unit 350 is suppressed (regulated).

The base unit 390 covers the back side (arrow B direction side) of the ring member 310, and the operation unit 320, the guide unit 350, and the intermediate member 380 housed inside the ring member 310 come out to the back side. It is a member that regulates this, and the inner edge shape and the outer edge of the annular member 310 in the rear view are formed to be substantially the same, and are fastened and fixed inside the annular member 310 on the rear surface side.

Further, the base unit 390 is provided with a plurality of fastening holes 392a3 on the back surface side into which the tips of the screws inserted from the back surface side are screwed into the insertion holes of the right base member 29 described above. Therefore, by screwing the screw inserted from the back side of the right base member 29 (see FIG. 11) into the fastening hole 392a3, the displacement unit 300 in which a plurality of components are integrated is arranged in the front door 12. Will be done. Therefore, since the head of the screw that fastens the displacement unit 300 to the front door 12 can be positioned on the back side of the right base member 29, it is possible to prevent the displacement unit 300 from being illegally removed from the player side.

Next, the gripping unit 330 of the operating unit 320 and the rotating unit 340 will be described with reference to FIGS. 16 to 19. 16 (a) is a front view of the operation unit 320, FIG. 16 (b) is a side view of the operation unit 320 in the XVIb direction view of FIG. 16 (a), and FIG. 16 (c) is an operation. It is a rear view of the unit 320. FIG. 17A is a perspective front view of the operation unit 320, and FIG. 17B is a perspective rear view of the operation unit 320. FIG. 18 is an exploded perspective front view of the operation unit 320, and FIG. 19 is an exploded perspective view of the gripping unit 330.

As shown in FIGS. 16 to 19, the gripping unit 330 includes a right side cover member 331 arranged on the right side in the front view, a left side cover member 332 arranged on the left side in the front view, their right side cover member 331, and the right side cover member 331. , A vibrating device 333 disposed between the left side cover members 332, and the like.

The right side cover member 331 is a circular portion 331a formed in a circular plate shape located on the front side (arrow F direction side) of the gripping unit 330 formed long in the front-rear direction (arrow FB direction), and a circular portion thereof. A projecting portion 331b projecting from the outer edge of the portion 331a toward the radial outward side of the circular shape (arrow B direction side) and located on the back surface side (arrow B direction side) of the gripping unit 330, and an inner surface of the circular portion 331a. An annular right first wall portion 331c projecting (standing) from (opposing surface to the left side cover member 332) toward the left side cover member 332 side (arrow L direction side), and front and rear of the projecting portion 331b. The right second wall portion 331d projecting (standing) from the outer edge extending in the direction (arrow FB direction) toward the left side cover member 332 side and the inside (circular center) of the right first wall portion 331c. The third wall portion 331e on the right side, which is located on the side) and is projected (erected) in an annular shape substantially concentric with the first wall portion 331c on the right side from the inner surface of the circular portion 331a, and the rear end portion of the projecting portion 331b. A projecting portion 331f projecting from the back side is provided.

The left side cover member 332 is formed to have substantially the same shape (a shape symmetrical to the right side with the mating surface with the right side cover member 331 as a symmetrical surface) by reversing the right side cover member 331 in the left-right direction (arrow LR direction). Will be done. Therefore, the left side cover member 332 and the circular portion 332a formed in a circular plate shape are located on the front side (arrow F direction side) of the gripping unit 330 formed long in the front-rear direction, similarly to the right side cover member 331. , A projecting portion 332b projecting from the outer edge of the circular portion 332a toward the outward side in the radial direction (arrow B direction side) of the circular shape and located on the back surface side (arrow B direction side) of the gripping unit 330, and a circular portion. The left first wall portion 332c projecting from the inner surface of 332a (the surface facing the right side cover member 331) toward the right side cover member 331 side (arrow R direction side), and the front-rear direction (arrow F) of the projecting portion 332b. Positioned on the inside (center side of the circular shape) of the left side second wall part 332d and the left side first wall part 332c projecting (standing) from the outer edge extending in the −B direction) toward the right side cover member 331 side. From the inner surface of the circular portion 332a, the left third wall portion 332e is projected (erected) in an annular shape substantially concentric with the right first wall portion 331c, and the projecting portion 332b is from the back side end to the back side. It includes a protruding portion 332f that protrudes toward the direction.

Therefore, in the following description, the right side cover member 331 will be described as a representative example, and the description of the left side cover member 332 will be omitted. The differences between the right side cover member 331 and the left side cover member 332 will be described later.

The circular portion 331a is the right side surface when the player grips the gripping unit 330, the central portion of the circular shape is formed in a flat shape, and the annular portion outside (outer edge side) from the central portion covers the left side. It is formed so as to be inclined toward the member 332 side. As a result, the thickness of the gripping unit 330 at the portion gripped by the player can be increased at the central portion, so that the player can easily grip the gripping unit 330. That is, since the outer annular portion of the circular portion 331a is inclined, the thickness of the outer portion of the gripping unit 330 can be reduced. As a result, when the player grips the gripping unit 330, it is possible to prevent the player's hand from being caught by the end of the circular portion 331a, and it is possible to facilitate the player to rotate the gripping unit 330.

The projecting portion 331b is a portion that secures an amount in which the circular portion 331a of the gripping unit 330 is displaced to the back side when the operation unit 320 is displaced to the back side, and the guide unit 350 whose dimensions in the vertical direction will be described later. It is set smaller than the inner diameter of the reduced diameter portion 361b of. As a result, the protruding portion 331b can be inserted into the guide unit 350 by inserting the reduced diameter portion 361b. Further, when the operation unit 320 is displaced to the back side by the length of the protrusion 331b protruding from the reduced diameter portion 361b to the front side (arrow F direction side), the circular portion 331a becomes the guide unit 350. It is possible to suppress contact.

The right side first wall portion 331c and the right side second wall portion 331d of the right side cover member 331 are erected toward the left side cover member 322 side, and the left side first wall portion 332c and the left side first wall portion 332c of the left side cover member 332. The two wall portions 332d are erected toward the right side cover member 321 side, and when the right side cover member 331 and the left side cover member 332 are combined, the erected tip surfaces of the wall portions come into contact with each other. Therefore, a gap (space) is formed between the circular portion 331a and the projecting portion 331b, the circular portion 332a, and the projecting portion 332b, and the vibration device 333 is arranged in the gap.

The right first wall portion 331c includes an engaging portion 331c1 and a positioning projection 331c2. The engaging portion 331c1 is located on the front side (arrow F direction side, opposite side of the projecting portion 331b) of the right first wall portion 331c, and is located on the erection tip side (arrow L direction side) of the right first wall portion 331c. It is projected from the inner peripheral surface of the above to the inside in the radial direction (arrow B direction side, projecting portion 331b side). The positioning projection 331c2 is connected to the inner peripheral surface of the right side first wall portion 331c, and projects toward the left side cover member 332 side from the standing tip of the right side first wall portion 331c.

On the other hand, the left first wall portion 332c includes an engaged portion 332c1 and a positioning projection 332c2. The engaged portion 332c1 is located on the front side (arrow F direction side, opposite side of the protruding portion 332b) of the left side first wall portion 332c, and is located on the erection tip side (arrow R direction side) of the left side first wall portion 332c. ) Inward in the radial direction (arrow B direction side, projecting portion 332b side). The engaged portion 332c1 projects from the inner peripheral surface of the left first wall portion 332c to the right side cover member 331 side from the first portion protruding inward in the radial direction and the protruding tip of the first portion. From the second part and the third part that is folded back toward the front side (arrow F direction side) from the protruding tip of the second part and extends substantially parallel to the first part, the cross section is substantially U-shaped. It is formed. The positioning protrusion 332c2 is connected to the inner peripheral surface of the left side first wall portion 332c, and projects toward the right side cover member 331 side from the standing tip of the left side first wall portion 332c.

The engaging portion 331c1 and the engaged portion 332c1 are arranged at corresponding positions (in the same phase), and the right side cover member 331 and the left side are in a state where the engaging portion 331c1 and the engaged portion 332c1 are engaged. It can be combined with the cover member 332. Specifically, when the right side cover member 331 and the left side cover member 332 are fastened in combination, the engaging portion 331c1 is inserted (arranged) between the first portion and the second portion of the engaged portion 332c1. As a result, the front side (player side) of the mating surface of the right side cover member 331 and the left side cover member 332 can be engaged with each other, and it is possible to prevent the mating surface from being opened.

Further, when the right side cover member 331 and the left side cover member 332 are combined, the positioning protrusion 331c2 of the right side cover member 331 is inscribed in the inner peripheral surface of the left side first wall portion 332c of the left side cover member 332, and the left side cover member 332 The positioning protrusion 332c2 of the above is inscribed in the inner peripheral surface of the right first wall portion 331c of the right side cover member 331. Thereby, the right side cover member 331 and the left side cover member 332 can be positioned in the radial direction.

The positioning protrusions 331c2 and the positioning protrusions 332c2 are formed at different positions (different phases) in the circumferential direction of the first wall portions 331c and 332c, and when the right side cover member 331 and the left side cover member 332 are combined, the positioning protrusions 331c2 And the positioning protrusion 332c2 are suppressed from interfering with each other.

The third wall portion 331e on the right side is a wall portion (projection) for accommodating the vibrating device 333 inside, and is formed in a ring shape along the outer shape of the vibrating device 333. As a result, when electric power is applied to the vibrating device 333 and the vibrating device 333 is vibrated, the vibration is transmitted to the outside of the gripping unit 330 (the gripping unit 330) via the right third wall portion 331e and the circular portion 331a. It can be transmitted to the operating player's hand). As a result, the vibrating device 333 can be vibrated to make the player recognize that it is the timing to operate the displacement unit 300, or to recognize that the gaming state is advantageous to the player.

The protruding portion 331f is a portion to be fastened to the rotating unit 340, and fastening holes (not shown) into which screws inserted from the rotating unit 340 side (rear side) are screwed are formed at a plurality of positions of the protruding tip portion. Will be done. Further, the protruding portion 331f is formed in an outer shape corresponding to the concave shape of the recessed portion 341a1 described later. Therefore, the gripping unit 330 is fastened to the rotating unit 340 in a state where the protruding portion 331f is accommodated in the recessed portion 341a1 of the rotating unit 340.

Further, a through hole 331f1 penetrating in the left-right direction (arrow LR direction) is formed in the protruding portion 331f of the right side cover member 331. On the other hand, a fastening hole 332f1 for screwing a screw is formed in the protruding portion 332f of the left side cover member 332. Further, the through hole 331f1 and the fastening hole 332f1 are formed coaxially in the left-right direction, and the screw through which the through hole 331f1 is inserted is screwed into the fastening hole 332f1 to fasten the right side cover member 331 and the left side cover member 332. Will be done.

That is, by screwing the through hole 331f1 and the fastening hole 332f1, the back side of the right side cover member 331 is fastened to the back side (arrow B direction side) of the left side cover member 332. As described above, the right side cover member 331, the left side cover member 332, and the (grip unit 330) are engaged with each other on the front side by the engaging portion 331c1 and the engaged portion 332c1. Therefore, the right side cover member 331 and the left side cover member 332 can be removed by screwing the screw inserted through the through hole 331f1 into the fastening hole 332f1 while the engaging portion 331c1 and the engaged portion 332c1 are engaged. It is considered impossible.

In this case, when the gripping unit 330 is connected to the rotating unit 340, the screws (protruding portions 331f and 332f) for fastening the right side cover member 331 and the left side cover member 332 are housed in the recessed portion 341a1 of the rotating unit 340. Therefore, when the displacement unit 300 is assembled, the gripping unit 330 can be hardly disassembled. As a result, it is possible to prevent the gripping unit 330 from being illegally disassembled by the player.

The rotating unit 340 surrounds the front side member 341 connected to the gripping unit 330, the columnar shaft member 343 projecting radially outward from the back side member 342 thereof, and the shaft member 343. It mainly includes an annular guided member 344, which is arranged in a state (rotatably fitted).

The front side member 341 is located on the gripping unit 330 side (front side) and is formed in a circular shape in the front view toward the back side (arrow B direction side) along the outer edge of the connecting portion 341a. It is provided with a cylindrical erection wall 341b to be erected.

The connecting portion 341a has a recessed portion 341a1 recessed toward the inside (back side) of the vertical wall 341b and an opening 341a2 formed through the inner portion recessed by the recessed portion 341a1. Be prepared.

The recessed portion 341a1 is a portion to which the above-mentioned gripping unit 330 is connected, and a plurality of insertion holes (not shown) are bored in the bottom surface of the recessed portion. The insertion holes of the recessed portions 341a1 are opened at positions facing each of the fastening holes (not shown) formed at a plurality of locations (four locations in the present embodiment) of the protruding portions 331f and 332f of the gripping unit 330. Therefore, the gripping unit 330 and the rotating unit 340 (front side member 341) are fastened by fastening the screw through which the insertion hole of the recessed portion 341a1 is inserted to the fastening holes formed in the protruding portions 331f and 332f. ..

The opening 341a2 is an opening through which the wiring (not shown) connected to the vibrating device 333 of the gripping unit 330 described above is inserted from the rotating unit 340 side to the gripping unit 330 side, and the protrusion 331b and the protrusion of the gripping unit 330. It is communicated with the space between the facing portions of the installation portion 332b. Therefore, the wiring inserted through the opening 341a2 is inserted inside the gripping unit 330 from the space between the projecting portion 331b and the projecting portion 332b facing each other, and is connected to the vibrating device 333.

The erection wall 341b is a portion that regulates the posture of the rotating unit 340 (operation unit 320) with respect to the guide unit 350 described later, and has a cylindrical shape having a predetermined length in the front-rear direction (arrow FB direction). Is formed in. The outer diameter of the erection wall 341b is a virtual circle (virtual line KS1 (see FIG. 21A)) that circumscribes each of the plurality of projecting portions 362a1 in the second annular member 362 of the guide unit 350, which will be described later. The diameter is set to be slightly smaller than the diameter of. As a result, when the rotating unit 340 is housed inside the guide unit 350, the outer peripheral surface of the erection wall 341b becomes the tip (outer peripheral surface) of the plurality of protrusions 362a1 in the second annular member 362 of the guide unit 350. Upon contact, the posture of the operation unit 320 with respect to the guide unit 350 is restricted.

Further, the erection wall 341b includes a regulation piece 341b1 projecting outward in the radial direction from the outer peripheral surface. The regulation piece 341b1 is a portion that defines the rotation range (rotation amount) of the rotation unit 340 with respect to the guide unit 350, and is arranged inside the accommodating recess 362a5 of the second annular member 362 of the guide unit 350, which will be described later. When the rotary unit 340 is rotationally displaced relative to the guide unit 350, the regulation piece 341b1 comes into contact with one inner surface or the other inner surface of the accommodating recess 362a5, so that the guide unit of the rotary unit 340 Rotation in one direction or rotation in the other direction with respect to 350 is restricted. Thereby, the rotation range (rotation amount) of the rotation unit 340 is defined.

The back side member 342 is formed in a disk shape having substantially the same diameter as the outer diameter of the erection wall 341b, and is arranged on the erection wall 341b at a position where the central axis is coaxial with the axis of the erection wall 341b. Will be done. Further, the back surface side member 342 is located at a columnar insertion portion 342a projecting from the center (shaft portion) of the back surface (the surface opposite to the front surface side member 341) and radially outward from the insertion portion 342a. It includes an engaging piece 342b protruding from the back surface, an insertion opening 342c that opens at a position different from that of the engaging piece 342b in the circumferential direction, and an annular standing portion 342d that is erected from the front.

As described above, the insertion portion 342a is a portion to be inserted into the first opening 381 of the intermediate member 380, and its outer diameter is set to a diameter equal to or slightly smaller than the inner diameter of the first opening 381. Therefore, by inserting the insertion portion 342a into the first opening portion 381, it is possible to prevent the position of the intermediate member 380 from shifting in the radial direction (direction perpendicular to the axis) with respect to the rotating unit 340. That is, the rotating unit 340 and the intermediate member 380 are connected so as to be relatively rotatable with their relative positions in the radial direction positioned.

The engaging piece 342b is a portion that engages with the first displacement member 396 of the base unit 390 described later and transmits the displacement of the rotating unit 340 to the displacement unit 395. The length dimension of the engaging piece 342b is such that the inserted tip is the back surface of the intermediate member 380 in the state of being inserted into the second opening 382 of the intermediate member 380 (see FIG. 15) (the assembled state of the displacement unit 300). It is set to a dimension that protrudes from the base unit to the 390 side.

Further, the engaging piece 342b is formed from the first piece 342b1 and the second piece 342b2 in a substantially T-shaped cross section. The first piece 342b1 is formed in a cross-sectional shape extending in the circumferential direction about the center (axis) side of the front side member 341, and is erected from the back surface of the front side member 341 while maintaining the cross-sectional shape. The second piece 342b2 is formed to have a rectangular cross section, and projects from the inner peripheral surface of the first piece 342b1 toward the insertion portion 342a. That is, the second piece 342b2 extends along the longitudinal direction of the first piece 342b1. As a result, the rigidity of the engaging piece 342b can be increased, and it is possible to prevent the engaging piece 342b from being damaged (broken) when the engaging piece 342b is engaged with the first displacement member 396.

As described above, the insertion opening 342c is an opening for inserting the wiring (not shown) inserted into the rotation unit 340 side through the third opening 383 of the intermediate member 380 into the inside of the rotation unit 340. As a result, the wiring inserted from the right lamp unit 39 (see FIG. 11) to the rotating unit 340 via the base unit 390 and the intermediate member 380 is inserted through the opening 341a2 of the front side member 341 of the rotating unit 340. Therefore, it can be connected to the vibrating device 333 of the gripping unit 330.

The standing portion 342d is a cylindrical portion that is erected from a position that is radially inward from the outer edge of the back side member 342 toward the front side member 341 side (front side), and its outer diameter is the back surface. The size is set to be smaller than the outer diameter of the side member 342. Further, the outer diameter of the standing portion 342d is formed to be slightly smaller than the inner diameter of the standing wall 341b of the front side member 341, and when the front side member 341 and the back side member 342 are combined, the standing portion 342d Is arranged (internally fitted) inside the erection wall 341b of the front side member 341. Therefore, when the front side member 341 and the back side member 342 are combined, the standing portion 342d can be inserted into the standing wall 341b to facilitate positioning of the back side member 342 with respect to the front side member 341. Further, by inserting (internally fitting) the erection portion 342d into the erection wall 341b, the connection between the two can be strengthened, the rigidity of the rotating unit 340 can be secured, and the front side member 341 and the back side member 342 can be connected to each other. It is possible to prevent foreign substances such as wires and piano wires from being inserted into the internal space from the mating surface.

The upright portion 342d includes a shaft support hole 342d1 that penetrates in the radial direction (the plate thickness direction (direction orthogonal to the axis of the back surface side member 342)). The shaft support hole 342d1 is a hole through which the shaft member 343, which will be described later, is inserted. Further, the shaft support holes 342d1 are formed at positions where a pair of the shaft support holes 342d1 face each other across the shaft of the back surface side member 342 (positions that are 180 degrees out of phase).

The shaft member 343 has a cylindrical portion, a diameter-expanded portion 343a formed by expanding the diameter of the columnar portion on one end side in the axial direction toward the outside in the radial direction, and a shaft of the columnar portion. A groove portion 343b, which is recessed in a groove shape on the other end side in the direction, is provided. The shaft member 343 is inserted into the guided member 344 and the shaft support hole 342d1, which will be described later, in a posture in which the other end side in the axial direction in which the groove portion 343b is formed is directed toward the center of the back surface side member 342.

The diameter-expanded portion 343a is a regulating portion that regulates the guided member 344 from coming out to one end side in the axial direction, and its outer diameter is set to a diameter larger than the inner diameter of the guided member 344.

The groove portion 343b is formed as a concave groove continuous all around in the circumferential direction, and an E-ring C having an outer diameter larger than the inner diameter of the shaft support hole 342d1 of the back side member 342 is fitted into the concave groove (groove portion 343b). .. As a result, the shaft member 343 cannot be removed from the shaft support hole 342d1.

The guided member 344 is a cylindrical (roller-shaped) member guided by a guide groove 351 (see FIG. 22D) of the guide unit 350 described later, and as described above, the shaft member 343 is on the inner peripheral side. Is inserted into. The inner diameter of the guided member 344 is set to be larger than the outer diameter of the portion (the portion formed in a columnar shape) excluding the enlarged diameter portion 343a of the shaft member 343.

As a result, the guided member 344 is rotatably held (shaft supported) by the shaft member 343. Therefore, when the guided member 344 is guided by the guide groove 351 of the guide unit 350, the guided member 344 is rotated (rolled) with respect to the inner surface of the guide groove 351 to cause the back side member 342 (rotating unit). 340) can be displaced.

Next, the guide unit 350 will be described with reference to FIGS. 20 and 21. 20 (a) is a front view of the guide unit 350, FIG. 20 (b) is a perspective front view of the guide unit 350, and FIG. 20 (c) is a perspective rear view of the guide unit 350. 20 (d) is a cross-sectional view of the guide unit 350 in the line XXd-XXd of FIG. 20 (a). 21 (a) is an exploded perspective front view of the guide unit 350, and FIG. 21 (b) is an exploded sectional view of the guide unit 350. Note that FIG. 21 corresponds to the cross-sectional view of FIG. 20 (d).

As described above, the guide unit 350 is arranged on the front side guide unit 360 arranged on the front side (arrow F direction side) and on the back side (arrow B direction side) of the front side guide unit 360. It is provided with a rear side guide unit 370.

As shown in FIGS. 20 and 21, the front side guide unit 360 is formed by combining two cylindrical members formed in an annular shape in the front view in the axial direction, and is arranged on the front side (arrow F direction side). The first ring member 361 is provided, and the second ring member 362 arranged on the back surface side (arrow B direction side) of the first ring member 361.

The diameter of the first annular member 361 is reduced from the cylindrical tubular portion 361a and the end portion of the tubular portion 361a on the front side (arrow F direction side) (protruding inward in the radial direction in a flange shape). The diameter-reduced portion 361b and the attachment portion 361c formed by partially bulging (overhanging) outward in the radial direction from the end portion on the back surface side (arrow B direction side) of the tubular portion 361a are provided. ..

The outer diameter of the tubular portion 361a is set to be substantially the same as or slightly smaller than the inner diameter of the opening 312a of the annular member 310 (see FIG. 14) described above. As a result, when the guide unit 350 is arranged in the annular member 310, the tubular portion 361a (guide unit 350) is internally fitted in the opening 312a of the annular member 310, and the inner peripheral surface of the opening 312a and the tubular shape are formed. It is possible to suppress the formation of a gap between the portion 361a and the outer peripheral surface. As a result, it is possible to prevent the player from inserting an illegal member (for example, a wire, a piano wire, etc.) into the displacement unit 300 from the front side of the slot machine 10 (see FIG. 1).

The inner diameter of the reduced diameter portion 361b is set to be smaller than the diameter of the circular portions 331a and 332a (see FIG. 17) of the gripping unit 330 described above. Therefore, for example, when the rotating unit 340 is damaged and the rotating unit 340 is displaced more than the specified displacement amount, the circular portions 331a and 332a of the gripping unit 330 are brought into contact with the reduced diameter portion to the inner edge of 361b. This makes it possible to prevent the entire gripping unit 330 (circular portions 331a, 332a) from being pushed inside the guide unit 350.

A screw hole (not shown) into which a screw for fastening the first ring member 361 and the second ring member 362 is screwed is formed in the attachment portion 361c on the back surface side.

The second annular member 362 includes a first cylindrical portion 362a formed in a cylindrical shape, and a cylindrical second cylindrical portion 362b located on the outer peripheral side of the first cylindrical portion 362a and surrounding the first cylindrical portion 362a. A connecting portion for connecting the outer peripheral surface of the first cylindrical portion 362a and the inner peripheral surface of the second cylindrical portion 362b is provided.

The first cylindrical portion 362a is located at a plurality of projecting portions 362a1 protruding from the inner peripheral surface and at the back end side (arrow B direction side) end of the first cylindrical portion 362a, and is located on the inner peripheral surface of the first cylindrical portion 362a. It is provided with a recessed portion 362a2 to be recessed and a storage recess 362a5.

As described above, the protruding portion 362a1 is a portion that comes into contact with the outer peripheral surface of the vertical wall 341b of the rotating unit 340 and regulates the posture (position) of the rotating unit 340 (operating unit 320) with respect to the guide unit 350. A plurality of (11 in this embodiment) are dispersedly arranged in the circumferential direction of the first cylindrical portion 362a at predetermined intervals. The plurality of projecting portions 362a1 are formed so that the virtual circle circumscribes the tip surface (outer peripheral surface) of the plurality of projecting portions 362a1 in the front view (axial view of the second annular member 362). The diameter of the virtual circle (virtual line KS1) is set to a diameter substantially equal to or slightly larger than the outer diameter of the erection wall 341b of the rotating unit 340.

As a result, when the rotary unit 340 (operation unit 320) is displaced, the area where the vertical wall 341b of the rotary unit 340 and the first cylindrical portion 362a of the guide unit 350 come into contact with each other can be reduced. Therefore, the resistance when the rotating unit 340 (operation unit 320) is displaced can be reduced, and the rotating unit 340 can be easily displaced.

The recessed portion 362a2 is a portion in which the guided member 344 of the rotating unit 340 is arranged inside, and corresponds to the guided member 344 arranged in a pair on the rotating unit 340, and the shaft of the first cylindrical portion 362a. A pair is formed at positions opposite to each other (positions that are 180 degrees out of phase). In the assembled state of the displacement unit 300, the recessed portion 362a2 accommodates the guided member 344 of the rotating unit 340, and the guided member 344 is moved (rolled) along the inner wall of the recessed portion 362a2 to operate the displacement unit 300. The operation direction (displacement direction) of the unit 320 is guided.

As described above, the accommodating recess 362a5 is a portion in which the restricting piece 341b1 of the rotating unit 340 is accommodated inside, and when the rotating unit 340 is displaced, the accommodating recess 362a5 is restricted to the inner wall facing the circumferential direction of the accommodating recess 362a5. The pieces 341b1 are brought into contact with each other to regulate the rotation of the rotating unit 340 within a predetermined range. In the present embodiment, the accommodating recess 362a5 is recessed in a range of about 45 degrees at a central angle about the axis of the first cylindrical portion 362a, and the rotatable range (angle) of the rotating unit 340 (operation unit 320) is set. It is set to approximately 45 degrees.

In the second cylindrical portion 362b, the end portion on the front side (arrow F direction side) is connected to the outer peripheral surface of the first cylindrical portion 362a, and the portion connecting the second cylindrical portion 362b and the first cylindrical portion 362a is formed. , A through hole (not shown) for inserting a screw is formed. By screwing the screw inserted through the through hole into the attachment portion 361c of the first annular member 361, the first annular member 361 and the second annular member 362 are fastened and fixed (front side guide unit). 360 is assembled).

The rear side guide unit 370 stands on the front side along the outer edge of the first part 371 formed in an annular shape, the second part 372 protruding from the first part 371 to the front side, and the first part 371. It is formed with a third part 373 to be provided.

The outer diameter of the first portion 371 is set to a diameter larger than the outer diameter of the first cylindrical portion 362a described above, and the inner diameter is set to a diameter smaller than the outer diameter of the erection wall 341b described above. Further, the first portion 371 is formed with a recessed portion 371a that is recessed from a part of the inner edge toward the outer side in the radial direction.

As described above, the recessed portion 371a is a portion in which the protruding portion 384 of the intermediate member 380 is accommodated, and by accommodating the protruding portion 384 in the recessed portion 371a, the intermediate member 380 rotates with respect to the guide unit 350. Is regulated.

The second portion 372 is located along the inner edge of the first portion 371 and projects toward the second annular member 362 side (front side). As shown in FIG. 20D, the second portion 372 is a portion arranged in the recessed portion 362a2 of the second annular member 362 described above, and the protruding tip surface thereof is the inner wall of the recessed portion 362a2. It is in contact with a stepped surface that connects the inner peripheral surface of the recessed portion 362a2 and the inner peripheral surface of the first cylindrical portion 362a).

As a result, as shown in FIG. 20 (d), the guide unit 350 in the assembled state has a connecting surface of the concave bottom surface of the recessed portion 362a2 and the inner peripheral surface of the first cylindrical portion 362a, and the back side guide unit 370. A pair of guide grooves 351 in which a part of the recessed portion 362a2 is surrounded by the first portion 371 and the second portion 372 of the above is formed at positions facing each other with the center of the first cylindrical portion 362a interposed therebetween.

The guide groove 351 is a groove that guides the guided member 344 of the rotating unit 340 described above, and the groove width is set to be larger than the outer diameter of the guided member 344. A detailed description of the guide groove 351 will be described later.

The inner diameter of the third part 373 is set to be substantially the same as or slightly larger than the outer diameter of the first cylindrical part 362a of the second ring member 362, and the back surface of the second ring member 362 (front side guide unit 360). When the back side guide unit 370 is arranged on the side, it is fitted onto the first cylindrical portion 362a. As a result, positioning when disposing the back side guide unit 370 on the front side guide unit 360 can be simplified. Further, the rigidity of the guide unit 350 can be ensured by fitting the third portion 373 to the first cylindrical portion 362a. In particular, the rigidity of the second annular member 362 can be ensured, and the deformation of the guide groove 351 can be suppressed. Therefore, the guidance of the guided member 344 by the guide groove 351 can be stabilized, and the operability of the operation unit 320 can be improved.

Next, with reference to FIGS. 22 to 24, a guide structure when the operation unit 320 is displaced with respect to the guide unit 350 will be described.

22 (a), 23 (a) and 24 (a) are perspective front views of the operation unit 320 and the guide unit 350, and are views of FIGS. 22 (b), 23 (b) and 24 (a). b) is a front view of the operation unit 320 and the guide unit 350, and FIGS. 22 (c), 23 (c) and 24 (c) are FIGS. 22 (b), 23 (b) and It is sectional drawing of the operation unit 320 and the guide unit 350 in the XXIIc-XXIIc line, the XXIIIc-XXIIIc line and the XXIVc-XXIV line of FIG. 24 (b), and is a cross-sectional view of FIGS. 22 (d), 23 (d) and 24. (D) is a cross-sectional view of the operation unit 320 and the guide unit 350 in the XXIId-XXIId line, the XXIIId-XXIIId line and the XXIVd-XXIVd line of FIGS. 22 (a), 23 (a) and 24 (a). Is.

In FIGS. 22 (c), 23 (c), and 24 (c), only the outer line of the operation unit 320 arranged in the guide unit 350 is shown by a two-dot chain line. Further, FIGS. 22 to 24 show the transition states of the operation unit 320 with respect to the guide unit 350 in order. FIG. 22 shows a state in which the operation unit 320 is arranged at the initial position without being operated by the player, and FIG. 24 shows a position where the operation unit 320 is operated by the player and becomes the end of the movable range. The state of being arranged at (hereinafter referred to as "termination position") is illustrated, and in FIG. 23, the state in which the operation unit 320 is arranged at a position between the initial position and the end position (hereinafter referred to as "intermediate position"). Is illustrated.

As shown in FIG. 22, when the operation unit 320 is arranged at the initial position with respect to the guide unit 350, the center lines of the circular portions 331a and 332a of the right side cover member 331 and the left side cover member 332 of the gripping unit 330 are horizontal. It is parallel to the direction (arrow LR direction) (that is, the flat surface at the center of the circular portions 331a and 332a is orthogonal to the arrow LR direction), and the front side of the rotating unit 340 of the operation unit 320 is the first ring. It is arranged at a position where it abuts on the back surface of the reduced diameter portion 361b of the member 361 (see FIG. 23 (c)).

As described above, in the operation unit 320, the guided member 344 of the rotating unit 340 is arranged in the guide groove 351 of the guide unit 350, and the guided member 344 is displaced (guided) along the guide groove 351. This defines the displacement of the operating unit 320 with respect to the guide unit 350.

Here, the guide groove 351 will be described. As shown in FIG. 22D, the guide groove 351 is formed by the second ring member 362 of the front side guide unit 360 and the back side guide unit 370, and the second ring member 362 and the back surface thereof. It extends in the circumferential direction of the side guide unit 370. A part of the guide groove 351 is formed so as to be inclined.

The guide groove 351 is formed by the first guide surface 351a and the second guide surface 351b formed by the second annular member 362 and the back side guide unit 370 as an inner wall for guiding the movement (rolling) of the guided member 344. It includes a third guide surface 351c and a fourth guide surface 351d to be formed. Further, the guide groove 351 has a first end portion 351e formed by the back side guide unit 370 and a second ring member 362 formed as an inner wall for restricting the movement (rolling) of the guided member 344. It includes two ends 351f.

Here, in a gaming machine including a base member and a displacement member that is displaced along a groove formed in the base member, it is necessary to insert a protrusion formed in the displacement member into the groove of the base member. In this case, when the protrusion of the displacement member is inserted into the groove of the base member, if the other member is arranged at a position where it interferes with the displacement member, the displacement member is placed on the base member while avoiding interference with the other member. Since it is necessary to dispose of the members, the shapes of the base member, the displacement member, and other members are limited, and the degree of freedom in design is reduced.

On the other hand, in the present embodiment, since the guide groove 351 is formed of the second ring member 362 and the back side guide unit 370, the guided member 344 arranged inside the guide groove 351. After arranging the (operation unit 320) on the second annular member 362 (front side guide unit 360), the operation unit 320 is assembled to the guide unit 350 by combining the second annular member 362 and the rear side guide unit 370. be able to.

That is, by disposing the guided member 344 in the guide groove 351 on the second ring member 362 side, it is possible to prevent the arrangement of the operation unit 320 in the second ring member 362 from interfering with other members. .. As a result, the degree of freedom in designing the guide unit 350 and the operation unit 320 can be increased.

In particular, when the guide groove 351 is molded into the guide unit 350 formed in an annular shape with a mold, the structure of the mold becomes complicated, and the guide groove 351 is formed on the second annular member 362 and the back surface. The guide unit 350 can be formed in an annular shape by forming the side guide unit 370 with two members, forming a guide groove 351 on the dividing surface thereof, and setting the dividing direction of the two members to the drawing direction of the mold. Further, the structure of each mold can be simplified, and further, the die can be easily removed from the mold after the guide groove 351 is molded.

Although the case where the guide groove 351 is formed on the inner peripheral surface of the guide unit 350 (second annular member 362) is described, the guide groove 351 is formed so as to penetrate the guide unit 350 in the radial direction. It may be a thing.

Further, when the operation unit 320 that is displaced along the guide unit 350 is arranged inside the guide unit 350 formed in an annular shape, the guided member 344 is formed in the guide groove 351 formed in the guide unit 350. Since it is necessary to insert the operation unit 320 inside the guide unit 350 while inserting the above, the assembly work between the operation unit 320 and the guide unit 350 becomes complicated, and the displacement is arranged inside the guide groove 351. After arranging the guide member 344 (operation unit 320) on the second ring member 362 (front side guide unit 360), the second ring member 362 and the back side guide unit 370 are combined to guide the operation unit 320. Since it can be assembled to the 350, the assembly work can be simplified.

The first guide surface 351a and the third guide surface 351c are arranged so as to face each other with a predetermined interval. The facing distance between the first guide surface 351a and the third guide surface 351c is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 is guided to move by either the first guide surface 351a or the third guide surface 351c. In the following description, the region (moving region of the guided member 344) formed between the first guide surface 351a and the third guide surface 351c of the guide groove 351 is referred to as the “first guide region”. It will be explained as.

The first guide region (first guide surface 351a and third guide surface 351c) goes around while advancing from the initial position (away from the first end portion 351e) and approaching the back side (arrow B direction side). It is formed as an inclined guideway extending in the direction. Therefore, by guiding the guided member 344 along the first guide region, the operation unit 320 rotates around the axes of the second ring member 362 and the back side guide unit 370, and the second ring is formed. The member 362 and the back side guide unit 370 are displaced in the axial direction (arrow FB direction).

When the external force to the operation unit 320 is not input (the operation by the player is not performed), the rotation unit 340 is directed toward the front side (arrow F direction side) by the coil spring SP1 described above. Along with being urged, the base unit 390 (coil spring SP2), which will be described later, urges the vehicle in the counterclockwise direction (rotational direction for returning to the initial position). Therefore, when the external force to the operation unit 320 is not input (for example, when the player releases the operation unit 320) while the guided member 344 is in the first guide region, the coil springs SP1 and SP2 The guided member 344 is guided along the first guide surface 351a to the first end portion 351e by the urging force of, and is returned to the initial position. Further, in the initial position, the guided member 344 is maintained at a position where it comes into contact with the first end portion 351e by the urging force of the coil springs SP1 and SP2.

The second guide surface 351b and the fourth guide surface 351d are formed so as to face each other. Further, the fourth guide surface 351d is extended in a direction in which the guide surface is parallel to the horizontal direction. On the other hand, the second guide surface 351b is formed as a guide surface that inclines toward the front side as it approaches the connecting portion with the first guide surface 351a in the circumferential direction of the second ring member 362 and the first portion 371. To.

The second guide surface 351b and the fourth guide surface 351d are on the back side (arrow B direction side, that is, the first end portion 351e) of the first guide region (first guide surface 351a and third guide surface 351c). Is connected to the end (opposite to). As a result, when the guided member 344 is moved toward the back surface side (arrow B direction side) of the first guide region, the guided member 344 moves the second guide surface 351b and the fourth guide surface 351d. Accepted between opposites.

The second guide surface 351b and the fourth guide surface 351d are arranged so as to face each other with a predetermined interval. The minimum facing distance between the second guide surface 351b and the fourth guide surface 351d is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 is guided to move by either the second guide surface 351b or the fourth guide surface 351d. In the following description, the region (moving region of the guided member 344) formed between the second guide surface 351b and the fourth guide surface 351d facing each other in the guide groove 351 is referred to as the “second guide region”. It will be explained as.

The second guide surface 351b is extended in the circumferential direction while approaching the front side (arrow F direction side) as it approaches the connecting portion with the first guide surface 351a (that is, as it separates from the second end portion 351f). The fourth guide surface 351d is formed as an inclined guide surface, and the guide surface extends in the circumferential direction in a posture parallel to the virtual surface perpendicular to the axes of the second annular member 362 and the back side guide unit 370. It is formed as a guide surface to be formed.

Therefore, when the guided member 344 is guided along the second guide surface 351b of the second guide region, the operation unit 320 rotates about the axes of the second ring member 362 and the back side guide unit 370. While doing so, the second ring member 362 and the back side guide unit 370 are displaced in the axial direction (arrow FB direction).

The inclination angle of the second guide surface 351b is set to be smaller than the inclination angle of the first guide surface 351a. Therefore, the amount of axial displacement of the operation unit 320 per unit rotation is such that the guided member 344 is guided along the first guide surface 351a as compared with the case where the guided member 344 is guided along the second guide surface 351b. The amount of displacement is larger when guided.

On the other hand, when the guided member 344 is guided along the fourth guide surface 351d of the second guide region, the operation unit 320 is in the axial direction of the second ring member 362 and the back side guide unit 370 (arrow F). It is not displaced in the −B direction), and only the rotation around the axis of the second ring member 362 and the back side guide unit 370 is performed.

When the guided member 344 is located in the second guide region and no external force is input to the operation unit 320 (for example, when the player releases his / her hand from the operation unit 320), the coil springs SP1 and SP2 The urging force guides the guided member 344 toward the first guide region along the second guide surface 351b, and then returns to the initial position. In this case, since the second guide surface 351b is inclined in the second guide region, it is possible to smoothly return to the initial position.

The first end portion 351e is formed at the start end of the first guide region (the end on the side opposite to the connection side with the second guide region) and forms an initial position. That is, the displacement of the guided member 344 is regulated by the first end portion 351e, so that the operation unit 320 is positioned at the initial position.

The second end portion 351f is formed at the end of the second guide region (the end on the side opposite to the connection side with the first guide region) and forms the end position. That is, the displacement of the guided member 344 is regulated by the second end portion 351f, so that the operation unit 320 is positioned at the terminal position.

As shown in FIG. 23, the operation unit 320 is rotated clockwise in the front view by the player's operation (for example, the circular portions 331a and 332a of the gripping unit 330 gripped by the player are rotated), or The operation unit 320 is operated by the player (for example, the outer peripheral surface of the mating surface (outer peripheral surface) of the right side cover member 331 and the left side cover member 332 of the gripping unit 330 facing the player is pushed by the player). Is pushed toward the front side (arrow B direction side) when viewed from the player, the guided member 344 of the operation unit 320 (rotating unit 340) is guided by the first guide area of the guide groove 351.

In this case, regardless of the operation (rotation or pushing), the guided member 344 is guided by the guide groove 351 (first guide area), so that the operation unit 320 is rotated in the circumferential direction and is rearward. It is displaced (sliding) to the side (arrow B direction side).

That is, when the gripping unit 330 (circular portions 331a, 332a) is rotated clockwise in the front view (when only the rotation operation is performed), it is brought into contact with the first guide surface 351a by the urging force of the coil spring SP1. The (pressed) guided member 344 is guided (rolled) along the first guide surface 351a, and the operation unit 320 is displaced toward the back side (arrow B direction side) while being rotated in the circumferential direction. Slide).

On the other hand, when the gripping unit 330 is pushed toward the back side (the side in the direction of arrow B) (when only the pushing operation is performed), the guided member 344 resists the urging force of the coil spring SP1 and the third guide surface 351c The guided member 344 is guided (rolled) along the third guide surface 351c, so that the operation unit 320 is rotated in the circumferential direction and is on the back side (arrow B). It is displaced (sliding) to the direction side).

As described above, according to the present embodiment, the operation unit 320 is operated even when the player's gripping unit 330 is operated in different directions (in the present embodiment, the circumferential direction during the rotation operation and the arrow B direction during the pushing operation). A similar displacement can be applied to (grip unit 330). As a result, the player can arbitrarily select the direction in which the operation unit 320 is operated. As a result, it is possible to easily enhance the interest of the player.

In addition, when a button or lever is pressed in one direction or tilted in one direction and is displaced in one direction or rotated in one direction, the operation tends to be monotonous. In contrast to the problem that it is difficult to give interest to the operation, in the present embodiment, the operation unit 320 has a rotational displacement or slide in a direction different from the displacement direction due to the operation due to the slide displacement or the rotational displacement due to the pushing operation or the rotational operation. Since the displacement can be formed, it is possible to easily give an interest to the operation of the operation unit 320.

The direction of pushing the operation unit 320 toward the back side and the direction of the rotation axis during the rotation operation of the operation unit 320 are set to be parallel. As a result, the operation unit 320 (grip unit 330) is displaced even when the player's gripping unit 330 is operated in different directions (in the present embodiment, the circumferential direction during the rotation operation and the arrow B direction during the pushing operation). It can be done easily.

When the operation unit 320 (grip unit 330) is further operated from the state shown in FIG. 23, the guided member 344 reaches the connecting portion between the first guide region and the second guide region. From this state, the gripping unit 330 (circular portions 331a, 332a) is rotated clockwise by a rotation operation (or an operation combining rotation and pushing), so that the guided member 344 is guided to the second guide. You will be guided to the area. After that, the guided member 344 is brought into contact with the second end portion 351f, so that the operation unit 320 (grip unit 330) is arranged at the terminal position as shown in FIG. 24.

In this case, in the second guide region, when the operation unit 320 (grip unit 330) is rotationally operated (that is, when only the rotational force around the axis is applied), the second guide surface is driven by the urging force of the coil spring SP1. The guided member 344 abutted (pressed) on the 351b is guided (rolled) along the second guide surface 351b, so that the operation unit 320 is rotated in the circumferential direction and the second guide member 320 is rotated. 2 As the guide surface 351b is tilted, it is also displaced (sliding) toward the back surface side (arrow B direction side).

Further, when the operation unit 320 (grip unit 330) is operated by an operation combining rotation and pushing, the guided member 344 abutting (pressed) on the fourth guide surface 351d by the pushing force of the operation. However, by being guided (rolled) along the fourth guide surface 351d, the operation unit 320 is only rotated in the circumferential direction.

On the other hand, in the second guide region, the operation unit 320 (grip unit 330) is not displaced only by the pushing operation. That is, in the second guide region, the fourth guide surface 351d is formed as a guide surface perpendicular to the axis of the second annular member 362 and the back side guide unit 370 as a guide surface parallel to the virtual surface, so that the gripping unit 330 is on the back surface. Even if the guided member 344 is abutted (pressed) on the fourth guide surface 351d against the urging force of the coil spring SP1 by being pushed to the side (arrow B direction side), the guided member 344 is guided to the fourth guide. A force component that rolls along the surface 351d (that is, a force component in the direction of rotating the operation unit 320 (grip unit 330)) is not generated. Therefore, the guided member 344 stays at the connecting portion (or on the fourth guide surface 351d) between the first guide region and the second guide region, and the operation unit 320 (grip unit 330) is pushed in the pushing direction (arrow B direction). And is not displaced in any direction of rotation.

As described above, according to the present embodiment, by providing the second guide region, the direction in which the player's gripping unit 330 is operated (in the present embodiment, the circumferential direction during the rotation operation and the arrow B direction during the pushing operation). ) Are different, the displacement mode of the operation unit 320 (grip unit 330) can be changed (in the present embodiment, the operation unit 320 is rotated in the rotation operation (or the operation combining rotation and pushing). , The operation unit 320 is stopped only by pushing operation). As a result, the player can arbitrarily select the direction in which the operation unit 320 is operated. As a result, it is possible to easily enhance the interest of the player.

Further, in the present embodiment, the operation unit 320 is pushed toward the back side from the initial position and operated, and after being guided in the first guide area and reaching the second guide area, the operation direction is changed (that is, rotation). By (operating), the operation unit 320 (grip unit 330) can be displaced to the terminal position. Therefore, the player can change the operation direction between the initial position and the end position (on the way). As a result, it is possible to prevent the player from getting tired of operating the operation unit 320.

When the operation unit 320 is pushed (sliding) toward the back side, the guided member 344 is guided while being in contact with the third guide surface 351c and the fourth guide surface 351d of the back side guide unit 370. On the other hand, when the operation unit 320 is rotated clockwise in the front view, the guided member 344 is guided while being in contact with the first guide surface 351a and the second guide surface 351b of the second annular member 362.

That is, the member with which the guided member 344 comes into contact can be changed in the operating direction of the operation unit 320. Thereby, the contact surface with the guided member 344 can be set to a shape and a material suitable for the operation direction of the operation unit 320.

For example, during the pushing operation of the operation unit 320, when the guided member 344 is guided to the fourth guide surface 351d, it comes into contact with the fourth guide surface 351d and its displacement is regulated, so that the impact when the displacement is regulated is regulated. Places a large effect on the rear guide unit 370, and the rear guide unit 370 is set to a material that is resistant to impact. On the other hand, when the operation unit 320 is rotated, the guided member 344 easily slides along the first guide surface 351a and the second guide surface 351b and is easily displaced. Therefore, the second ring member 362 is made of a material resistant to wear. Set. As a result, it is possible to prevent only a part of the guide surface of the guide groove 351 from being concentratedly deformed (deteriorated). As a result, the durability of the guide groove 351 can be improved.

Alternatively, the guide surface of the guide groove 351 may be formed in a stepped shape, and the vibration sliding on the guide surface may be transmitted to the player who operates the operation unit 320. In this case, assuming that the third guide surface 351c and the fourth guide surface 351d and the first guide surface 351a and the second guide surface 351b have different inner surface shapes, vibration when sliding the respective guide surfaces is generated. It may be set so that the frequencies are different when they are displaced at the same speed. As a result, the operation feeling of operating the operation unit 320 can be made different on each guide surface.

Further, the guide surface on which the guided member 344 is guided by the case where the operation unit 320 is pushed (sliding) and the case where the operation unit 320 is rotated is provided with the third guide surface 351c of the rear side guide unit 370 and the guide surface. It can be divided into a fourth guide surface 351d and a first guide surface 351a and a second guide surface 351b of the second ring member 362.

As a result, the guided member 344 can be guided along different guide surfaces according to the displacement mode of the operation unit 320, and the load received by the guide surfaces can be dispersed. That is, when the displacement member displaced along the guide surface formed on the base member is always moved along a part of the guide surface, the load is concentrated on a part of the guide surface and the guide surface becomes In the present embodiment, the guided member 344 can be guided along different guide surfaces according to the displacement mode of the operation unit 320, so that the load is concentrated on a part of the guide surfaces. Can be suppressed. As a result, it is possible to prevent the back side guide unit 370 and the second ring member 362 on which the guide groove 351 is formed from being damaged.

Further, the connecting portion between the second annular member 362 of the guide groove 351 formed of the two members and the back side guide unit 370 is formed at a position different from the guide surface of the guided member 344. To be precise, the connecting portion between the second annular member 362 and the back side guide unit 370 is the connecting portion (connecting portion) of the first end portion 351e and the first guide surface 351a, and the second end portions 351f and the fourth. It is set to the connecting portion (connecting portion) of the guide surface 351d.

Here, when the connecting portion between the second ring member 362 and the back side guide unit 370 is set on the guide surface of the guide groove 351, when the second ring member 362 and the back side guide unit 370 are combined. Due to factors such as the error (assembly tolerance) and the processing accuracy (dimensional tolerance) of the second ring member 362 and the back side guide unit 370, there is a risk that a step may be formed on the guide surface of the guide groove 351. When the guided member 344 guided through the 351 passes through the step, it may be caught in the step and easily worn.

On the other hand, the connecting portion between the second annular member 362 of the guide groove 351 formed of the two members and the back side guide unit 370 is formed at a position different from the guide surface of the guided member 344, so that the guide groove is formed. It is possible to prevent the guided member 344 guided by 351 from becoming worn faster.

The connecting portion between the second ring member 362 and the back side guide unit 370 may be set at a position where it does not abut when the guided member 344 is guided. For example, the second ring member 342 may be connected. Even if the connecting portion between the member 362 and the back side guide unit 370 is formed on the first guide surface 351a or the third guide surface 351c at a position separated from the first end portion 351e by a value smaller than the radius of the guided member 344. It may be formed at the first end portion 351e and the second end portion 351f.

Further, the operation unit 320 can be guided along different guide surfaces during the rotation operation and the push operation, and the guide surfaces are formed of different members. Therefore, when the design of the guide groove 351 is changed, the guide surface can be guided. Design changes can be made easily. For example, when changing the displacement mode of the operation unit 320 at the time of pushing, it is not necessary to change the shape of the second ring member 362, and the third guide surface 351c and the fourth guide surface 351d of the rear side guide unit 370 do not need to be changed. It is only necessary to change the shape of.

The operation direction of the operation unit 320 (grip unit 330) may be appropriately selected by the player, or the operation direction is transmitted to the player according to the effect content of the slot machine 10 (auxiliary display unit 15). (Display on or by voice), and the player may be made to change the operation direction based on the transmission.

Next, with reference to FIGS. 25 and 26, the guide mode (change in the contact surface) of the guided member 344 by the guide groove 351 when the operation unit 320 (grip unit 330) is displaced from the initial position to the terminal position. explain.

25 (a) to 25 (c) and 26 (a) to 26 (c) are cross-sectional schematic views of the operation unit 320 and the guide unit 350, and FIGS. 25 (a) and 25 (a) and 25 (c). (B) and FIG. 25 (c) and FIGS. 26 (a), 26 (b) and 26 (c) are shown in FIGS. 22 (c), 23 (c) and 24 (c), respectively. Correspond.

It should be noted that in FIGS. 25 (a) to 25 (c), the transition states of the guided member 344 when the player rotates the operation unit 320 (grip unit 330) are shown in order from FIG. 26 (a). In FIG. 26C, the player is guided when the operation unit 320 (grip unit 330) is pushed toward the guide unit 450 side (rear side (arrow B direction side)) and then the operation unit 320 is rotated. The transition states of the members 344 are shown in order.

Further, in FIGS. 25 (a) and 26 (a), the operation unit 320 is arranged at the initial position, and in FIGS. 26 (c) and 26 (c), the operation unit 320 is arranged at the terminal position. Each state is illustrated. Further, in FIGS. 25 (b) and 26 (b), the guided member 344 is located at a position (hereinafter referred to as "first position") at the start end (end portion on the first guide region side) of the second guide region. The arranged state is illustrated.

As shown in FIGS. 25 (a) and 25 (b), when the operation unit 320 (grip unit 330) is rotationally operated by the player (when only the rotational force around the axis is applied to the grip unit 330). In the guided member 344, as described above, since the operation unit 320 (rotating unit 340) is urged to the front side (arrow F direction side) by the coil spring SP1, the first guide groove 351 is used. It comes into contact with the guide surface 351a and moves along the first guide surface 351a in the circumferential direction (left-right direction in FIG. 25) to guide the first guide region.

As shown in FIG. 25B, the guided member 344 that has passed through the first guide region and reached the first position of the second guide region has a surface on the front side of the second guide region (that is, the second guide region). It is arranged at a position where it comes into contact with the guide surface 351b).

As shown in FIGS. 25 (b) and 25 (c), the operation unit 320 is in a state where the guided member 344 is located at the first position of the second guide region (in this case, the starting end of the second guide surface 351b). When the (grip unit 330) is further rotated by the player (only the rotational force around the axis is applied to the grip unit 330), the guided member 344 receives the operation unit 320 (rotation unit 340) as described above. ) Is urged to the front side (arrow F direction side) by the coil spring SP1, so that it comes into contact with the second guide surface 351b of the guide groove 351 and goes around the guide groove 351 along the second guide surface 351b. It moves in the direction (left-right direction in FIG. 25) and guides the second guide region to the end position (the position where it abuts on the second end portion 351f).

As described above, the second guide surface 351b of the guide groove 351 extends in the circumferential direction (left-right direction in FIG. 25C) of the second ring member 362 and the first portion 371, and the first guide surface It is formed so as to be inclined toward the front side toward the connecting side with 351a.

Therefore, when the operation unit 320 is displaced by the rotational operation from the initial position to the terminal position (that is, when only the rotational force around the axis is applied to the gripping unit 330), the first guide surface 351a and the second guide With the inclination of the surface 351b, the operation unit 320 is displaced to the back surface side (the arrow B direction side) while being rotated (displaced in the circumferential direction).

In this way, when the operation unit 320 is rotated from the initial position to the terminal position, the guided member 344 is guided to the first guide area and the second guide area, which have different extension directions. The amount of slide displacement toward the rear side with respect to the amount of rotation of the operation unit 320 is changed. That is, while the operation unit 320 is rotationally displaced, the displacement mode toward the rear surface is changed. As a result, the operation of the operation unit 320 can be enjoyed.

As shown in FIGS. 26 (a) and 26 (b), when the operation unit 320 (grip unit 330) is pushed toward the back side (only the axial pushing force is applied to the grip unit 330). Or, when a pushing force in the axial direction is applied to the gripping unit 330 and a rotational force around the axis is also applied), the guided member 344 comes into contact with the third guide portion 351c of the guide groove 351 and takes such a th. 3 The guide groove 351 is moved in the circumferential direction (left-right direction in FIG. 26) along the guide surface 351c to guide the first guide region.

As shown in FIG. 26B, the guided member 344 that has passed through the first guide region and reached the first position of the second guide region has a surface on the back surface side of the second guide region (that is, the fourth guide region). It is arranged at a position where it abuts on the guide surface 351d).

Here, when only the pushing force in the axial direction is applied to the operation unit 320 (grip unit 330) and the rotational force around the axis is not applied, the guided member 344 is subjected to the first guide region (third guide surface). When the first position of the second guide region (in this case, the start end of the fourth guide surface 351d) is reached after passing through 351c), the guided member 344 reaches the fourth guide surface 351d (second guide region). Immediately after being guided, the displacement of the operation unit 320 (grip unit 330) is stopped.

That is, as described above, the fourth guide surface 351d extends in the circumferential direction in a posture perpendicular to the axis of the second annular member 362 and the back side guide unit 370 in a posture parallel to the virtual surface. Since it is formed as a guide surface to be guided, when the guided member 344 reaches the first position of the second guide region (the starting end of the fourth guide surface 351d) only by the pushing operation, the force acting on the guided member 344. Since the direction of the fourth guide surface 351d and the extension direction of the fourth guide surface 351d are substantially orthogonal to each other and no force component is generated in the rotation direction (circumferential direction, left and right direction in FIG. 26B), the operation unit 320 (grip unit) 330) cannot be displaced.

The third guide surface 351c and the fourth guide surface 351d have their respective guide surfaces linear in the circumferential direction (left-right direction in FIG. 25B) of the second ring member 362 and the first part 371. It is formed, and the intersection angle between the third guide surface 351c and the fourth guide surface 351d is set to a predetermined angle (preferably about 165 degrees or more and about 135 degrees or less, and in this embodiment, about 150 degrees).

As a result, when the guided member 344 is guided from the third guide surface 351c (first guide region) to the start end of the fourth guide surface 351d (first position of the second guide region), the generation of impact is suppressed. At the same time, it is possible to reliably guide to the first position. That is, if the tolerance angle is too large, the impact when the guided member 344 reaches the second guide region becomes large, while if the tolerance angle is too small, the guided member 344 is displaced in the circumferential direction (rotational direction). The force component for this is insufficient, and the guided member 344 is not smoothly transferred from the first guide region to the second guide region. On the other hand, by setting the tolerance angle, the transition of the guided member 344 from the first guide region to the second guide region is performed while suppressing the impact when the guided member 344 reaches the second guide region. It can be done smoothly.

As a result, when only the pushing force in the axial direction is applied to the operation unit 320 (grip unit 330) and the rotational force around the axis is not applied, the guided member 344 is placed at the same position (first position) each time. It can be easily stopped. As a result, the operation feeling (operation amount) of the player who operates the operation unit 320 can be made the same, so that it is possible to suppress the player from feeling a sense of discomfort in the operation of the operation unit 320.

As shown in FIGS. 26 (b) and 26 (c), the operation unit 320 is in a state where the guided member 344 is located at the first position of the second guide region (in this case, the starting end of the fourth guide surface 351d). When the (grip unit 330) is further operated by the player (the grip unit 330 is subjected to an axial pushing force and an axial rotational force), the guided member 344 is subjected to the fourth guide groove 351. It comes into contact with the guide surface 351d, moves the guide groove 351 (second guide region) in the circumferential direction (left-right direction in FIG. 26) along the fourth guide surface 351d, and ends the second guide region at the terminal position (second end). It is guided to the position where it comes into contact with the portion 351f).

When the player does not operate the operation unit 320 after operating the operation unit 320 to a position where the guided member 344 comes into contact with the second end portion 351f by pushing and sliding the operation unit 320, the operation unit 320 is used. The urging force of the acting coil springs SP1 and SP2 guides the guided member 334 to the starting position along the second guide surface 351b and the first guide surface 351a.

Therefore, when the operation unit 320 is pushed and slid, the guide surfaces (third guide surface 351c and fourth guide surface 351d) to which the guided member 344 is guided by those operations, and the coil spring SP1, By making the guide surface (second guide surface 351b, first guide surface 351a) on which the guided member 344 is guided by the urging force of SP2 different from each other, the load received by the contact of the guided member 344 is efficiently applied. Can be dispersed.

The operation unit 320 (grip unit 330) is rotationally operated (that is, the axis of the grip unit 330) from the state where the guided member 344 is located at the first position of the second guide region (the starting end of the fourth guide surface 351d). (Only the rotational force around it is applied), as described above, the operation unit 320 (rotational unit 340) of the guided member 344 is urged to the front side (arrow F direction side) by the coil spring SP1. Therefore, the guide groove 351 comes into contact with the second guide surface 351b, the guide groove 351 is moved in the circumferential direction along the second guide surface 351b, and the second guide region is set to the terminal position (the second end portion 351f). It is guided to the abutting position) (see FIG. 25 (c)).

Next, the base unit 390 will be described with reference to FIGS. 27 to 30. 27 (a) is a front view of the base unit 390, FIG. 27 (b) is a perspective front view of the base unit 390, and FIG. 27 (c) is a line XXVIIc-XXVIIc of FIG. 27 (a). It is sectional drawing of the base unit 390 in. FIG. 28 is an exploded perspective front view of the base unit 390. 29 (a) is a front view of the base unit 391, and FIG. 29 (b) is a cross-sectional view of the base unit 391 in line XXIXb-XXIXb of FIG. 29 (a). 30 (a) is a front view of the displacement unit 395, FIG. 30 (b) is a rear view of the displacement unit 395, and FIG. 30 (c) is the line XXXc-XXXc of FIG. 30 (a). It is sectional drawing of the displacement unit 395.

In FIGS. 27 (a) to 27 (c), the displacement unit 395 is urged by the coil spring SP2, and the displacement unit 395 is brought into contact with the second displacement member 397 with the regulation piece 392f of the base unit 391. The state of being placed at the position (hereinafter referred to as "initial urging position") is shown.

As shown in FIGS. 27 to 30, the base unit 390 includes a base unit 391, a displacement unit 395 disposed on the base unit 391, and a coil spring SP2 for urging the displacement unit 395 with respect to the base unit 391. And mainly prepare.

The base unit 391 is formed in an outer shape (outer peripheral edge shape) corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300 described above, and is formed on the inner peripheral edge side thereof. It mainly includes a base member 392 that is arranged (internally fitted), and a leaf spring 393 and a detection device 394 that are arranged on the base member 392.

The base member 392 is erected from the base plate 392a and the front side (arrow F direction side) of the base plate 392a, and is formed in a front view arc shape (substantially C-shaped), and a first wall portion 392b thereof. With the second wall portion 392c which is coaxial with the first wall portion 392b and has a larger diameter than the first wall portion 392b and is formed in a front view arc shape (approximately C shape) and is erected from the front side of the base plate 392a. The third wall portion 392h, which is coaxial with the second wall portion 392c and has a diameter larger than that of the second wall portion 392c and is erected from the front side of the base plate 392a, and the base plate. A spring engaging piece 392k projecting from the front side of the 392a, an inner first engaging piece 392d1 and an inner second engaging piece 392d2, and a base plate 392a are formed inside the base plate 392a cut out in a substantially U-shape in the front view. The regulation piece 392f and the like are mainly provided.

The first wall portion 392b is a portion that accommodates (holds) the rear end portion of the coil spring SP1 arranged between the first wall portion 392b and the intermediate member 380 (see FIG. 14), and the inner diameter of the inner peripheral surface thereof is the coil spring. It is set larger than the outer diameter of SP1 and is formed (erected) at a position coaxial with the standing portion 385 (see FIG. 15) of the intermediate member 380. The inner portion of the first wall portion 392b of the base plate 392a (the portion surrounded by the first wall portion 392b) is retracted to the back side (arrow F direction side) of the other portion of the base plate 392a. .. As a result, the depth dimension of the space surrounded by the first wall portion 392b can be secured, so that the coil spring SP1 having a large free length can be adopted, and the durability and the operability can be improved. Even a coil spring SP1 having a long free length can be stably accommodated (held).

The diameter of the second wall portion 392c is set to be larger than the diameter of the first wall portion 392b, and the second wall portion 392c is formed (erected) at a position separated from the first wall portion 392b by a predetermined distance. The second wall portion 392c is a wall portion that guides the displacement of the first displacement member 396 (displacement unit 395), which will be described later, and extends along the displacement locus of the first displacement member 396. That is, the inner diameter of the second wall portion 392c is set to be the same as or slightly larger than the outer diameter of the displacement locus of the first displacement member 396. Although detailed description will be described later, the displacement unit 395 is arranged in a displaceable state between the first wall portion 392b and the second wall portion 392c facing each other.

The second wall portion 392c includes an outer first engaging piece 392e1 and an outer second engaging piece 392e2 projecting radially inward from the inner peripheral surface on the erection tip side. The outer first engaging piece 392e1 and the outer second engaging piece 392e2 are located on the displacement locus of the displacement unit 395 (positions overlapping the displacement locus in the front view), and are located along the circumferential direction of the second wall portion 392c. It is formed at positions separated by a predetermined interval.

The outer first engaging piece 392e1 and the outer second engaging piece 392e2 are protrusions that regulate the displacement unit 395 attached (mounted) to the base unit 391 toward the front side (arrow F direction side). , The facing distance from the base plate 391a is formed at a position that is the same as or slightly larger than the thickness of the displacement unit 395 (first displacement member 396) in the front-rear direction (arrow FB direction). As a result, the displacement unit 395 arranged in front of the base plate 391a can be displaceably arranged between the base plate 391a and the outer first engaging piece 392e1 and the outer second engaging piece 392e2 (FIG. 27). (C).

The outer diameter of the third wall portion 392h is set to substantially the same as the outer diameter of the second cylindrical portion 362b (see FIG. 14) of the second annular member 362, and is coaxial with the second cylindrical portion 362b. Is formed at the position of. As a result, in the assembled state of the displacement unit 300, the front side end portion (standing tip surface) of the third wall portion 392h is brought into contact with the back side end portion of the second cylindrical portion 362b. As a result, unauthorized access to the inside of the displacement unit 300 from the outside can be suppressed.

The spring engaging piece 392k is a portion for engaging one end of the coil spring SP2 for urging the displacement unit 395, which will be described later, and is projected from the front side of the base plate 392a and the protruding tip is opposite to the displacement unit 395. It is formed in an L-shape in a lateral view that is bent toward the side.

The inner first engaging piece 392d1 and the inner second engaging piece 392d2 are members that guide the displacement of the displacement unit 395, which will be described later, and regulate the detachment (removal) of the displacement unit 395. The inner first engaging piece 392d1 and the inner second engaging piece 392d2 are located inward in the radial direction of the displacement locus of the displacement unit 395 in the front view, and stand from the front side (arrow F direction side) of the base plate 392a. It is projected inward in the radial direction from the first part (standing part) to be installed and the protruding tip of the first part, and overlaps the displacement locus on the displacement locus of the displacement unit 395 (in front view, it overlaps with the displacement locus). It is provided with a second portion (protruding portion) located at the position).

The first portion (standing portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 is arranged at a position facing the inner peripheral surface of the displacement unit 395. The portion (standing portion) guides the displacement of the displacement unit 395 in the circumferential direction and regulates the displacement of the displacement unit 395 in the radial direction.

The outer peripheral surface (the surface facing the displacement unit 395) of the first portion (standing portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 is the first in front view. It is formed as a circular circumferential surface concentric with the wall portion 392b. As a result, the displacement of the displacement unit 395 in the circumferential direction can be smoothly guided.

The facing distance between the second portion (protruding portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 and the base plate 391a is the front-rear direction of the displacement unit 395 (first displacement member 396). The thickness is set to be the same as or slightly larger than the thickness (in the direction of arrow FB). As a result, the displacement unit 395 arranged in front of the base plate 391a is placed between the base plate 391a and the second portion (protruding portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2. Can be displaceably arranged (see FIG. 27 (c)).

The regulation piece 392f is a member that regulates the displacement of the displacement unit 395 to one side (defines the initial biasing position), and is between the first wall portion 392b and the second wall portion 392c in the front view. , It is formed at a position where it overlaps with the displacement locus of the displacement unit 395 in the front view.

The regulation piece 392f is an elastic piece in which the base plate 392a is cut out in a substantially U shape in front view so that the base end is connected to the base plate 392a and one end side extending from the base end is a free end. Is formed as. The direction in which one end side of the regulation piece 392f extends from the base end side is opposite to the urging direction of the coil spring SP2 (the direction of the force urging the displacement unit 395 toward the initial urging position). To. The regulation piece 392f includes a convex portion 392f1 projecting from the front surface (the surface on the arrow F direction side) on one end side thereof, and the convex portion 392f1 is brought into contact with the displacement unit 395 (second displacement member 397). Therefore, the displacement of the displacement unit 395 to one side is regulated (the displacement unit 395 is arranged at the initial biasing position).

The base plate 392a includes an upright portion 392j that protrudes from the front side (arrow F direction side) and is located between the outer peripheral surface of the first wall portion 392b and the inner peripheral surface of the second wall portion 392c. The erection portion 392j is a portion that regulates the displacement of the displacement unit 395 to the other side (defines the end of the displacement of the displacement unit 395), and is formed at a position facing the end of the displacement locus of the displacement unit 395. ..

An opening 392g is formed in the base plate 392a on the inner peripheral side of the third wall portion 392h (between the third wall portion 392h and the coil spring SP2 facing each other). The wiring (not shown) extending from the vibrating device 333 (see FIG. 18) can be routed to the back surface side (outside) of the displacement unit 300 through the opening 392 g.

The leaf spring 393 is a plate-shaped spring (leaf spring) that is elastically deformed by contact with the second displacement member 397 when the displacement unit 395 is displaced, and is at a position adjacent to the displacement locus of the displacement unit 395 (the leaf spring 393). It is arranged on the inner peripheral side of the displacement locus). Further, the leaf spring 393 includes a protrusion 393a projecting toward the base plate 392a.

The protrusion 393a is inserted into a recess 392m recessed in the base plate 392a. As a result, when the leaf spring 393 is elastically deformed by the contact with the second displacement member 397, and then the leaf spring 393 is elastically recovered with the passage of the second displacement member 397, the protrusion 393a is formed into the recess 392m. It can be brought into contact (collision) with the inner surface.

The leaf spring 393 is arranged on the base plate 392a in a state of being elastically deformed. That is, in a state where the displacement unit 395 (second displacement member 397) is not in contact with the leaf spring 393, the leaf spring 393 abuts (presses) the protrusion 393a on the inner surface of the recess 392m due to its elastic recovery force. It is said that it is in a state of being made.

Further, the leaf spring 393 is at a position where the leaf spring 393 comes into contact with the displacement unit 395 (first displacement member 396) in a state where the protrusion 393a is not in contact with the inner surface of the recess 392m (pressing is released) and the elasticity is restored. Be placed. As a result, when the protrusion 393a of the leaf spring 393 is damaged, the leaf spring 393 can be brought into contact with the first displacement member 396. Therefore, even if the protrusion 393a of the leaf spring 393 is damaged, the leaf spring 393 is elastically deformed by the contact with the second displacement member 397, and then the leaf spring 393 elastically recovers with the passage of the second displacement member 397. By doing so, the leaf spring 393 can be brought into contact (collision) with the first displacement member 396.

The detection device 394 is a sensor device that detects the position of the displacement unit 395, and includes an irradiation unit that irradiates light and a light receiving unit that is arranged so as to be able to receive the light emitted from the irradiation unit, and faces each other. The position of the displacement unit 395 is detected based on the fact that the detection piece 396f of the displacement unit 395 is arranged between them and the light is blocked.

The displacement unit 395 mainly includes a first displacement member 396 and a second displacement member 397 rotatably supported by the first displacement member 396.

The first displacement member 396 has a main body portion 396a and a main body portion 396a formed in a shape curved in an arc shape in a front view (a shape in which the ring shape is divided at two points (positions where the phases are different by 180 degrees)). The spring engaging portion 396c formed in a substantially C shape on one end side in the longitudinal direction (circumferential direction) of the main body portion 396a, and the arc center (inward in the radial direction) of the main body portion 396a on the other end side in the longitudinal direction (circumferential direction) of the main body portion 396a. ), The engaging portion 396b that is located along the inner edge of the main body portion 396a and is formed as a thinner portion than the other portions, and the outer peripheral edge of the main body portion 396a. An outer recessed portion 396e formed by cutting out a portion, a detection piece 396f projecting radially outward from the outer peripheral edge portion of the main body portion 396a, and a columnar protrusion on the back surface of the main body portion 396a. Mainly includes a shaft portion 396h to be provided.

The outer diameter of the main body portion 396a is set to be smaller than the inner diameter of the second wall portion 392c of the base plate 392a, and the inner diameter (inner diameter of the engaging portion 396d) is outside the first wall portion 392b of the base plate 392a. The diameter is set to be larger than the diameter. Thereby, the first displacement member 396 can be arranged between the first wall portion 392b and the second wall portion 392c of the base plate 392a.

Specifically, the inner diameter of the main body portion 396a (engagement portion 396d) is a virtual circle concentric with the first wall portion 392b, and is the first of the inner first engaging piece 392d1 and the inner second engaging piece 392d2. The diameter is set to be the same as or slightly larger than the diameter of the virtual circle passing through the outer peripheral surface of the portion (standing portion). As a result, the inner peripheral side of the engaging portion 396d slides on the outer peripheral surface of the first portion (standing portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2, thereby causing the first displacement. The displacement of the member 396 in the circumferential direction is guided.

Further, the back surface (the surface on the arrow B side) of the main body portion 396a is the front surface of the first surface 396a1 which is the back surface of the other end side (protruding portion 396b side) in the longitudinal direction (circumferential direction) and the front surface of the first surface 396a1. It is located on the side (arrow F direction side) and is formed from the second surface 396a2 which is the back surface of one end side (spring engaging portion 396c side) in the longitudinal direction (circumferential direction), and these first surface 396a1 and second surface 3996a2. A step in the front-rear direction (arrow FB direction) is connected by a wall surface of 396 g. The first surface 396a1 and the second surface 396a2 are formed parallel to each other.

The wall surface 396 g is formed by being bent like a crank in the rear view, and is a portion that regulates the displacement of the second displacement member 397 by engaging the second displacement member 397 with the crank portion, and is a portion of the first crank surface 396 g1. And a second crank surface 396 g2, and a contact surface 396 g3 connecting them.

The first crank surface 396g1 is located on the radial outer side (outer peripheral side) of the main body portion 396a, and the second crank surface 396g2 is located on the radial inner side (inner peripheral side) of the main body portion 396a. The second crank surface 396g2 is positioned so as to recede from the first crank surface 396g1 toward one end side (spring engaging portion 396c side) of the main body portion 396a in the longitudinal direction (circumferential direction), so that the first crank surface 396g1 and the first crank surface 396g1 are located. A step is formed between the second crank surface and the second crank surface of 396 g2, and the step is connected by the contact surface of 396 g3.

The projecting portion 396b is on the displacement locus of the engaging piece 342b of the operating unit 320, and is on the displacement direction side (traveling direction) of the engaging piece 342b when the operating unit 320 is displaced from the initial position to the terminal position. It is arranged at the position (front side).

Therefore, when the operation unit 320 (grip unit 330) is displaced from the initial position to the terminal position, the projecting portion 396b is pushed by the engaging piece 342b in the displacement direction of the engaging piece 342b. Interlocked, the displacement unit 395 is displaced from the initial bias position. As a result, the coil spring SP2 is elastically stretched, and the urging force of the coil spring SP2 gives a predetermined feeling of operation to the operation of the operation unit 320 (grip unit 330).

On the other hand, when the operation of the operation unit 320 (grip unit 330) is released at the end position (or between the start position and the end position) (for example, when the player releases his / her hand from the grip unit 330). The displacement unit 395 is displaced (returned) toward the initial biasing position by the elastic recovery force of the elastically stretched coil spring SP2. As a result, contrary to the case described above, the engaging piece 342b is pushed by the projecting portion 396b and is interlocked in the displacement direction of the projecting portion 396b, so that the operation unit 320 (grip unit 330) is in the initial position. Displaced (returned) to.

One end of the coil spring SP2 is engaged with the spring engaging piece 392k of the base plate 392a, and the other end is engaged with the spring engaging portion 396c of the displacement unit 395 (first displacement member 396). In the urging position, it is arranged in an elastically stretched state. Therefore, the displacement unit 395 (first displacement member 396) is urged toward the initial urging position by the elastic recovery force of the coil spring SP2.

The thickness of the engaging portion 396d in the front-rear direction (arrow FB direction) is set to be smaller than the thickness of the main body portion 396a in the front-rear direction, and the back surface (the surface on the arrow B direction side) is set to the main body portion 396a. It is formed by connecting with the back of the. That is, the front surface of the engaging portion 396d (the surface on the side in the direction of arrow F) is positioned so as to recede toward the back surface (side in the direction of arrow B) from the front surface of the main body portion 396a.

Here, when the first displacement member 396 (displacement unit 395) is arranged (attached) to the base member 392 (base unit 391), the engaging portion 396d is attached to the base plate 392a and the inner first engaging piece. It is arranged between 392d1 and the inner second engaging piece 392d2 facing the second portion (protruding portion). Therefore, the thickness of the engaging portion 396d is formed to be smaller (thinner) than the thickness of the main body portion 396a, so that the inner first engaging piece 392d1 and the inner second engaging piece 392d2 are projected from the base plate 392a. The installation dimensions (the height of the first portion (erection part)) can be reduced (shortened). As a result, the rigidity of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 is ensured, and the inner first engaging piece 392d1 and the inner second engaging piece 392d2 are elastically deformed or damaged. Can be suppressed. As a result, the first displacement member 396 can be stably displaced.

The engaging portion 396d is partially cut out from the edge portion on the radial inner side (first wall portion 392b side) toward the main body portion 396a side (diameter outer side) to form a substantially rectangular shape in the front view. The inner first recessed portion 396d1 and the inner second recessed portion 396d2 are provided. The inner first recessed portion 396d1 and the inner second recessed portion 396d2 are inner first when the first displacement member 396 (displacement unit 395) is arranged (attached) to the base member 392 (base unit 391). It is a notch for inserting the first engaging piece 392d1 and the second portion (protruding portion) of the inner second engaging piece 392d2 into the front side of the engaging portion 396d, and the inner first concave portion thereof. The circumferential separation dimension of the inner second engaging piece 396d1 and the inner second engaging piece 396d2 is set to be the same as the circumferential separation dimension of the inner first engaging piece 392d1 and the inner second engaging piece 392d2. ..

The outer recessed portion 396e attaches the outer second engaging piece 392e2 to the first displacement member 396 when the first displacement member 396 (displacement unit 395) is arranged (attached) to the base member 392 (base unit 391). It is a notch for inserting into the front side of the main body portion 396a. Therefore, the outer recessed portion 396e is used when the inner first engaging piece 392d1 and the inner second engaging piece 392d2 of the base member 392 are inserted into the inner first recessed portion 396d1 and the inner second recessed portion 396d2, respectively. , The outer second engaging piece 392e2 is formed at a position where it can be received (inserted).

The inner first engaging piece 392d1, the inner second engaging piece 392d2, and the outer second engaging piece 392e2 are inserted into the inner first concave portion 396d1, the inner second concave portion 396d2, and the outer concave portion 396e, respectively. When the first displacement member 396 (displacement unit 395) is arranged at a position where it is possible, the outer first engaging piece 392e1 is adjacent to the other end side of the first displacement member 396 in the longitudinal direction (circumferential direction). It is arranged (that is, at a position that does not overlap the first displacement member 396 in the front view) (see FIG. 31).

Further, the outer recessed portion 396e is formed between the inner first recessed portion 396d1 and the inner second recessed portion 396d2 in the extending direction of the main body portion 396a. As a result, the portion whose rigidity is lowered by being recessed can be dispersed in the extending direction of the main body portion 396a. As a result, it is possible to prevent the main body 396a from being damaged by concentrating the low-rigidity portion on a part of the main body 396a.

The thickness of the detection piece 396f is set to be smaller (thinner) than the thickness of the main body 396a, and the front surface of the detection piece 396f is raised to the front side (arrow F direction side) of the front surface of the first displacement member 396. Will be done. In the second wall portion 392c of the base member 392, a recessed portion 392c1 is formed (recessed) in a region overlapping the displacement locus of the detection piece 396f in the front view, and the detection piece is formed through the recessed portion 392c1. 396f is projected outward in the radial direction of the second wall portion 392c. Thereby, the interference between the second wall portion 392c and the detection piece 396f can be suppressed.

The shaft portion 396h is a columnar shaft that rotatably supports the second displacement member 397, and projects from the second surface 396a2 of the main body portion 396a toward the back surface side.

The protrusion dimension (protrusion height) of the shaft portion 396h from the second surface 396a2 is from the distance T1 in the front-rear direction from the first surface 396a1 to the rear end of the main body portion 396a (see FIG. 30C). Is also set to a small size. As a result, when the first displacement member 396 (displacement unit 395) is displaced with respect to the base member 392, it is possible to prevent the protruding tip of the shaft portion 396h from coming into contact with the base plate 392a of the base member 392. As a result, breakage of the shaft portion 396h can be suppressed. Further, the frictional resistance can be suppressed and the displacement of the first displacement member 396 can be stabilized.

The second displacement member 397 is formed in a plate shape having a substantially triangular shape in the front view, and a shaft support hole 397a is formed through the plate shape in the substantially center in the front-rear direction. In the following description, the three tip portions (corner portions) of the second displacement member 397 in the front view are referred to as a first corner portion 397b, a second corner portion 397c, and a third corner portion 397d.

The shaft support hole 397a is a hole into which the shaft portion 396h of the first displacement member 396 is inserted, and the inner diameter thereof is set to be substantially the same as or slightly larger than the outer diameter of the shaft portion 396h. As a result, the second displacement member 397 can be rotated around the shaft portion 396h.

The thickness dimension T2 (see FIG. 30C) of the second displacement member 397 in the front-rear direction (arrow FB direction) is the distance in the front-rear direction from the first surface 396a1 to the back end of the main body 396a. The dimensions are set to be smaller than T1 (see FIG. 30C) (T2> T1).

As a result, when the second displacement member 397 is arranged on the first displacement member 396, the second displacement member 397 is located between the second surface 396a2 of the first displacement member 396 and the base plate 392a of the base member 392. It is possible to suppress being pinched by. As a result, the second displacement member 397 can be reliably rotated.

The first corner portion 397b is arranged on the radial inward side of the main body portion 396a of the first displacement member 396 (center side of the arc of the main body portion 396a, side of the first wall portion 392b). When the second displacement member 397 is displaced (rotated) with respect to the first displacement member 396, the first corner portion 397b is radially inward (diameterally inward) from the radial inward inner edge of the main body portion 396a in front view. A position (first position (see FIG. 37 (b))) protruding toward the center side of the arc of the main body portion 396a and the first wall portion 392b side) and a position radially outside the first position (second position). (See FIG. 38 (c))) and is displaced. At the first position, a part of the displacement locus of the first corner portion 397b when the first displacement member 396 is displaced is set at a position where it overlaps with the leaf spring 393 of the base unit 391, and at the second position, the second position. 1 The displacement locus of the first corner portion 397b when the displacement member 396 is displaced is set at a position that does not overlap (different) with the leaf spring 393 of the base unit 391.

The second corner portion 397c is arranged on the wall surface 396 g side of the shaft support hole 397a (shaft portion 396h). In front view, the distance T3 (see FIG. 30B) from the center of the shaft support hole 397a (shaft portion 396h) to the tip of the second corner portion 397c is the shaft support hole from the first crank surface 396g1 of the wall surface 396g. The dimension is set to be smaller than the distance T4 (see FIG. 30B) to the center of 397a (shaft portion 396h) (T4> T3), and the shaft support hole 397a (shaft) is set from the second crank surface 396g2 of the wall surface 396g. The dimension is set to be larger than the distance T5 (see FIG. 30B) to the center of the portion 396h) (T3> T5).

As a result, the displacement locus of the second corner portion 397c when the second displacement member 397 is rotated about the shaft support hole 397a (shaft portion 396h) with respect to the first displacement member 396 is set to the contact surface 396g3 of the wall surface 396g. Can be set to the position where it overlaps with. As a result, the side wall of the second corner portion 397c on the first corner portion 397b side can be brought into contact with the contact surface 396g3 to regulate the rotation (displacement) of the second displacement member 397 with respect to the first displacement member 396.

Therefore, the rotation (displacement) of the second displacement member 397 can be regulated by using the wall surface 396 g formed by the step between the first surface 396a1 and the second surface 396a2 of the main body 396a. It is not necessary to form a portion that regulates the displacement of the second displacement member 397. Therefore, it is possible to prevent the displacement unit 395 from becoming large in size and to easily secure the arrangement space of the displacement unit 395.

The third corner portion 397d sandwiches the shaft support hole 397a (shaft portion 396h) and is opposite to the first corner portion 397b (the arc on the radial outer side of the main body portion 396a of the first displacement member 396 (arc of the main body portion 396a). It is arranged on the side opposite to the center of the second wall portion 392c side)).

The distance from the tip of the third corner portion 397d to the center of the shaft support hole 397a (shaft portion 396h) is from the shaft support hole 397a (shaft portion 396h) to the radial outer edge of the main body portion 396a. The size is set to be larger than the distance, and due to the rotation (displacement) of the second displacement member 397 with respect to the first displacement member 396, the position protruding from the radial outer edge of the main body 396a and the position of the main body 396a. It is displaced between the two surfaces 396a2 and the position where they overlap in the front-rear direction (arrow FB direction).

Next, a mounting method for mounting the displacement unit 395 to the base unit 391 will be described with reference to FIGS. 31 to 33. FIG. 31 is a front view of the base unit 390. 32 (a) is a partial cross-sectional drawing of the base unit 390 in the line XXXIIa-XXXIIa of FIG. 31, and FIG. 32 (b) is a partial cross-sectional drawing of the base unit 390 in the line XXXIIb-XXXIIb of FIG. 31. It is a figure. 33 (a) is a partial cross-sectional schematic diagram of the base unit 390 in line XXXIIIa-XXXIIIa of FIG. 27 (a), and FIG. 33 (b) is a schematic diagram of the base unit in line XXXIIIb-XXXIIIb of FIG. 27 (a). It is a partial cross-sectional model drawing of 390.

In addition, in FIG. 31, FIG. 32 (a) and FIG. 32 (b), the position where the displacement unit 395 is pushed toward the back side (the side in the direction of arrow B) with respect to the base unit 391 (hereinafter referred to as “positioning position”). (That is, the state before being placed in the initial urging position) is shown, and in FIGS. 33 (a) and 33 (b), the displacement unit 395 is placed in the initial urging position. Is illustrated.

As shown in FIGS. 31 and 32, in order to attach (arrange) the displacement unit 395 to the base unit 391, first, the inner first recessed portion 396d1 of the first displacement member 396 (displacement unit 395), The inner second recessed portion 396d2 and the outer recessed portion 396e form an inner first engaging piece 392d1, an inner second engaging piece 392d2, and an outer second engaging piece of the base member 392 (base unit 391). The first displacement member 396 (displacement unit 395) is arranged at a position overlapping the 392e2 in the front view, and the first displacement member 396 (displacement unit 395) is directed toward the base plate 392a of the base member 392 (base unit 391). And push it in (in the direction of arrow B).

As shown in FIGS. 32 (a) and 32 (b), the displacement unit 395 places the second displacement member 397 on the front side (in the direction of arrow F) at the protruding tip of the convex portion 392f1 of the regulation piece 392f of the base plate 392a. It is brought into contact from the side), and is pushed toward the base plate 392a while elastically deforming the regulation piece 392f toward the back surface side (arrow B direction side). As a result, the first displacement member 396 (displacement unit 395) is arranged at the positioning position.

Here, in the second displacement member 397, only the shaft portion 396h of the first displacement member 396 is inserted into the shaft support hole 397a (that is, the retaining member is not arranged), and the shaft is formed from the shaft portion 396h. It can be displaced in the direction. Therefore, when the displacement unit 395 is attached (arranged) to the base unit 391, it is necessary to assemble the second displacement member 397 so that the second displacement member 397 does not fall off from the first displacement member 396 (does not fall off from the shaft portion 396h). In this case, if the operator works while holding the second displacement member 397 with his / her fingers, the work efficiency becomes poor.

On the other hand, in the present embodiment, when the displacement unit 395 is arranged at the positioning position, the displacement unit 395 is used as the base unit while the protruding tip of the convex portion 392f1 of the regulation piece 392f is brought into contact with the second displacement member 397. It can be assembled to 391, whereby it is possible to prevent the second displacement member 397 from falling off from the shaft portion 396h of the first displacement member 396. As a result, it is not necessary for the operator to hold the second displacement member 397 with his / her fingers, and the work efficiency can be improved accordingly.

In particular, since the convex portion 392f1 of the regulation piece 392f protrudes toward the displacement unit 395 side, when the displacement unit 395 is assembled to the base unit 391, the convex portion 392f1 of the regulation piece 392f is projected from an early stage. The tip can be brought into contact with the second displacement member 397. Therefore, the workability when assembling the displacement unit 395 to the base unit 391 can be further improved.

After arranging the displacement unit 395 in the positioning position (see FIG. 32), the displacement unit 395 is then placed on the other end side in the circumferential direction of the main body portion 396a (the side on which the projecting portion 396b is formed, FIG. 33 (a). ) And the lower side of FIG. 33B) are displaced in a direction close to the upright portion 392j of the base plate 329a.

In this case, the displacement unit 395 moves while bringing the second displacement member 397 into contact with the convex portion 392f1 of the regulation piece 392f, and when the second displacement member 397 passes through the convex portion 392f1 of the regulation piece 392f, it is shown in FIG. 33. As described above, the elastically deformed regulation piece 392f is restored to the initial shape (returned to the state where it is not elastically deformed), and the displacement unit 395 is arranged at the initial biasing position.

When the displacement unit 395 is arranged at the initial biasing position, the side surface of the convex portion 392f1 of the regulation piece 392f comes into contact with the side surface of the second displacement member 397, so that the displacement unit 395 is positioned (shown in FIG. 32). Displacement to position) is regulated.

At the initial urging position, as described above, the coil spring SP2 is displaced toward the positioning position by its elastic recovery force (the side surface of the second displacement member 397 is a convex portion of the regulation piece 392f). The direction of contact with the side surface of 392f1 (upper side of FIGS. 33 (a) and 33 (b)) is urged.

When the displacement unit 395 is arranged at the initial biasing position, the inner first recessed portion 396d1, the inner second recessed portion 396d2, and the outer recessed portion 396e of the first displacement member 396 (displacement unit 395) are arranged. Is a position (different) that does not overlap with each of the inner first engaging piece 392d1, the inner second engaging piece 392d2, and the outer second engaging piece 392e2 of the base member 392 (base unit 391) in the front view. Position).

As a result, the engaging portion 396d of the displacement unit 395 is arranged between the inner first engaging piece 392d1 and the second portion (protruding portion) of the inner second engaging piece 392d2 and the base plate 392a. Will be done. Further, the main body portion 396a of the displacement unit 395 is arranged between the outer first engaging piece 392e1 and the outer second engaging piece 392e2 and the base plate 392a.

That is, in the front view, the second portion (protruding portion) of the inner first engaging piece 392d1 and the inner second engaging piece 392d2 is inside the engaging portion 396d of the displacement unit 395 (first displacement member 396). In the non-formed region of the first recessed portion 396d1 and the inner second recessed portion 396d2, the outer first engaging piece 392e1 and the outer second engaging piece 392e2 are located in the main body of the displacement unit 395 (first displacement member 396). It is arranged at a position overlapping each other in the non-formed region of the outer recessed portion 396e in the 396a.

As a result, the displacement of the displacement unit 395 (first displacement member 396) with respect to the base unit 391 toward the front side (in the direction of arrow F) is such that the inner first engaging piece 392d1 and the inner second engaging piece 392d2 are displaced by the displacement unit 395 (in the direction of arrow F). The outer first engaging piece 392e1 and the outer second engaging piece 392e2 are engaged with the engaging portion 396d of the first displacement member 396), respectively, with the main body portion 396a of the displacement unit 395 (first displacement member 396). By that, it is regulated. As a result, the displacement unit 395 is held by the base unit 391 in a state where only the displacement in the circumferential direction is allowed.

Here, for example, in a structure in which the inner first concave portion 396d1, the inner second concave portion 396d2, and the outer concave portion 396e are not formed on the first displacement member 396, the displacement unit 395 is engaged with the inner first first engagement. Push the regulation piece 392f into the base unit 390 (base plate 392a) at a position where the piece 392d1, the inner second engaging piece 392d2, the outer first engaging piece 392e1 and the outer second engaging piece 392e2 do not overlap in front view. It needs to be elastically deformed (see FIG. 32). Therefore, the amount of displacement of the displacement unit 395 from the pushed-in position to the initial urging position becomes large, and the workability of the assembling work is lowered. Further, it is necessary to secure a space for pushing the displacement unit 395 into the base unit 390 (base plate 392a) by that amount, and it becomes impossible to erect ribs or form other parts. Space efficiency is reduced.

On the other hand, in the present embodiment, the inner first recessed portion 396d1, the inner second recessed portion 396d2, and the outer recessed portion 396e are formed on the first displacement member 396, and these recessed portions 396d1, 396d2, 396e are formed. The inner first engaging piece 392d1, the inner second engaging piece 392d2, and the outer second engaging piece 392e2 of the base member 392 are inserted into the base member 392. That is, the overlap margin between the displacement unit 395 and the displacement locus of the displacement unit 395 at the position where the displacement unit 395 is pushed into the base unit 390 (base plate 392a) can be increased. As a result, the amount of displacement of the displacement unit 395 from the pushed position (positioning position) to the initial biasing position can be reduced, and the workability of the assembling work can be improved. Further, the space reserved in the base unit 390 (base plate 392a) for pushing the displacement unit 395 can be reduced by that amount, so that the space efficiency can be improved (the space for erecting ribs and forming other parts). Can be secured).

Further, the second surface 396a2 of the main body portion 396a is arranged on the front side of the regulation piece 392f, and the regulation piece 392f is invisible in the front view. As a result, it is possible to make it difficult to access the regulation piece 392f from the front side of the base unit 391, and it is possible to prevent the regulation of the displacement unit 395 by the regulation piece 392f from being illegally released.

The distance from the contact position between the convex portion 392f1 of the regulation piece 392f and the second displacement member 397 in the extending direction of the main body portion 396a to the tip end portion (spring engaging portion 396c side end portion) of the second surface 396a2 is , The first displacement member 396 (displacement unit 395) is set to be larger than the displaceable distance. As a result, even after the first displacement member (displacement unit 395) is displaced, it is possible to make it difficult to access the regulation piece 392f from the front side of the base unit 391.

Further, the convex portion 392f1 of the regulation piece 392f is projected into the space formed by the step between the first surface 396a1 and the second surface 396a2 of the main body portion 396a. As a result, it is possible to prevent the base unit 391 from becoming thicker in the front-rear direction when the displacement unit 395 is arranged on the base member 392.

Next, the displacement of the displacement unit 395 will be described with reference to FIGS. 34 and 35. FIG. 34 is a perspective exploded view of the displacement unit 300, and FIGS. 35 (a) to 35 (c) are front views of the base unit 390.

In FIG. 34, the displacement unit 300 is disassembled between the base unit 390 and the intermediate member 380, and the coil spring SP1 disposed between the base unit 390 and the intermediate member 380 is not shown. Further, in FIGS. 35 (a) to 35 (c), the outer shape of the engaging piece 342b of the back surface member 342 of the operation unit 320 is shown by a chain line.

FIG. 35 (a) shows a state in which the operation unit 320 is arranged at the initial position and the displacement unit 395 is arranged at the initial biasing position. In FIG. 35 (c), the operation unit 320 is arranged at the terminal position. , The state in which the displacement unit 395 is arranged at the position where the displacement unit 395 is maximally displaced from the initial urging position (hereinafter referred to as “termination interlocking position”) is shown, and in FIG. 35 (b), the operation unit 320 is displaced from the initial position. , The state in which the engaging piece 342b of the operation unit 320 is arranged at a position where it abuts on the displacement unit 395 (hereinafter referred to as “contact position”) is shown.

As shown in FIGS. 34 and 35A, the tip of the engaging piece 342b of the back surface member 342 is the side surface (inside) of the projecting portion 396b of the first displacement member 396 in the assembled state of the displacement unit 300. It is arranged at a position facing the first recessed portion (side surface connected to 396d1). In the state where the operation unit 320 is arranged at the initial position, the engaging piece 342b is arranged at a predetermined distance from the side surface of the projecting portion 396b.

As shown in FIG. 35 (b), when the operation unit 320 is displaced with respect to the guide unit 350, the engaging piece 342b is rotated (displaced) in the same direction as the operation unit 320. As a result, the engaging piece 342b is brought into contact with the side surface of the projecting portion 396b.

The position of the operation unit 320 when the projecting portion 396b is brought into contact with the engaging piece 342b is set between the initial position and the first position. As a result, as described above, when the player pushes the operation unit 320 from the initial position, the guided member 344 comes into contact with the fourth guide surface 351d (see FIG. 26B) of the second guide region. Prior, the engaging piece 342b can be brought into contact with the projecting portion 396b. Therefore, before the guided member 344 reaches the first position (the guided member 344 reaches the fourth guide surface 351d), a resistance force (a urging force of the coil spring SP2) opposed to the pushing direction of the gripping unit 330 is applied. be able to. As a result, the impact when the guided member 344 comes into contact with the fourth guide surface 351d can be suppressed, and damage to the guided member 344 and the fourth guide surface 351d can be suppressed.

As shown in FIGS. 35 (b) and 35 (c), after the engaging piece 342b is brought into contact with the projecting portion 396b, the engaging piece 342b is displaced while the operating unit 320 is displaced to the terminal position. It is rotated (displaced) in the same direction as the operation unit 320. That is, since the contact between the engaging piece 342b and the projecting portion 396b is maintained, the urging force (elastic recovery force) of the coil spring SP2 can continue to act as an operation feeling when operating the operation unit 320. it can.

It should be noted that the operation unit 320 stands up from the base plate 392a at a position adjacent to the projecting portion 396b when it is arranged at the terminal position (on the front side in the traveling direction of the projecting portion 396b when traveling toward the terminal position). The erection part 392j to be installed is arranged. As a result, when the coil spring SP2 or the guided member 344 of the displacement unit 395 is damaged, the displacement unit 395 is brought into contact with the standing portion 392j, and the displacement unit 395 is displaced beyond the end interlocking position. It can be suppressed.

A leaf spring 393 disposed on the base unit 391 is arranged on the displacement locus of the second displacement member 397 of the displacement unit 395. Therefore, when the displacement unit 395 is displaced from the initial biasing position to the terminal interlocking position, the second displacement member of the displacement unit 395 is in the middle of the displacement (immediately before reaching the terminal interlocking position in the present embodiment). The 397 comes into contact with the leaf spring 393 to elastically deform the leaf spring 393. The details of the leaf spring 393 will be described later.

As described above, the displacement unit 395 is urged toward the initial urging position side by the urging force (elastic recovery force) of the coil spring SP2. Therefore, when the operation of the operation unit 320 is released (for example, when the player releases the grip unit 330), the displacement unit 395 is displaced toward the initial urging position and is displaced. The engaging piece 342b is pushed back by the protruding portion 396b of the unit 395, and as a result, the operating unit 320 is returned to the initial position.

Next, the leaf spring 393 will be described with reference to FIGS. 36 to 38. 36 is a front view of the base unit 390, and FIGS. 37 and 38 are partially enlarged front views of the base unit 390.

In FIGS. 36 to 38, the first displacement member 396 is shown transparently, and the outer shape of the first displacement member 396 is shown by a two-dot chain line. Further, in FIG. 36, a state in which the displacement unit 395 is arranged at the initial biasing position is shown.

37 (a) to 38 (d) show the transition states when the displacement unit 395 is displaced from the initial biasing position to the terminal interlocking position, and FIGS. 38 (a) to 38 (d) show the transition states. , The transition state when the displacement unit 395 is displaced from the terminal interlocking position to the initial biasing position is shown in order.

As shown in FIG. 36, the leaf spring 393 has a free end on the other end side opposite to the one end side fixed to the base member 392, and the plate surface faces the displacement unit 395 (first displacement member 396). Is arranged with. Therefore, the leaf spring 393 can be elastically deformed in a direction in which the other end side is brought close to or separated from the displacement unit 395. The leaf spring 393 is arranged so that one end side is closer to the coil spring SP2 than the other end side.

The leaf spring 393 is formed by being bent in a substantially triangular shape in front view between one end side and the other end side, and includes a protruding portion that projects the bent tip toward the displacement unit 395 (first displacement member 396). At least a part of the bending tip side of the protruding portion of the leaf spring 393 is arranged at a position overlapping the displacement locus of the second displacement member 397 in the front view, and when the displacement unit 395 is displaced, as will be described later. , The side surface of the protruding portion is brought into contact with (pressing) the second displacement member 397, whereby the leaf spring 393 is elastically deformed.

The leaf spring 393 includes a protrusion 393a projecting from the edge on the other end side toward the back surface side (direction of arrow B). The protrusion 393a is inserted inside the recess 392m of the base plate 392a, and in a state where the leaf spring 393 is arranged at the initial position (a state in which the leaf spring 393 is unloaded), the protrusion 393a hits the inner surface of the recess 392m. Be touched.

As shown in FIGS. 36 and 37 (a), when the displacement unit 395 is arranged at the initial urging position, the urging force of the coil spring SP2 causes the second side wall 397f (first angle) of the second displacement member 397. The side surface connecting the portion 397b and the third corner portion 397d) is in contact with the regulation piece 392f (convex portion 392f1) of the base plate 392a. As a result, the second displacement member 397 is arranged in a posture in which the tip end portion of the first corner portion 397b is projected inward in the radial direction of the first displacement member 396 (main body portion 396a) in the front view.

When the displacement unit 395 is displaced from the initial biasing position toward the terminal interlocking position by the operation of the operation unit 320, as shown in FIGS. 37 (b) and 37 (c), the second displacement member 397 is the second. The portion of one side wall 397e (the side surface connecting the first corner portion 397b and the second corner portion 397c) on the first corner portion 397b side abuts on the leaf spring 393 (side surface of the protruding portion), and the leaf spring The 393 is elastically deformed.

In this case, the second displacement member 397 is elastically deformed because the second corner portion 397c (the first side wall 397e on the second corner portion 397c side) is in contact with the contact surface 396g3 of the first displacement member 396. The second displacement member 397 is restricted from being rotated about the shaft support hole 397a (shaft portion 396h) by receiving the elastic recovery force of the leaf spring 393. That is, the amount of protrusion of the tip of the first corner portion 397b inward in the radial direction of the first displacement member 396 (main body portion 396a) does not change.

Therefore, when the displacement unit 395 is displaced to the terminal interlocking position, the first corner portion 397b elastically deforms the leaf spring 393 to the opposite side to the displacement unit 395 by pressing the side surface of the protruding portion of the leaf spring 393. Then, as shown in FIG. 37 (d), when the first corner portion 397b gets over the protruding portion (protruding tip) of the leaf spring 393, the elastic deformation of the leaf spring 393 is recovered (the leaf spring 393 is in a no-load state). (Returned to the shape in). The amount of elastic deformation of the leaf spring 393 is maximized when the first corner portion 397b of the second displacement member 397 gets over the protruding portion (protruding tip) of the leaf spring 393.

In this case, the protrusion 393a is separated from the inner surface of the recess 392m of the base plate 392a due to the elastic deformation of the leaf spring 393, and when the elastic deformation of the leaf spring 393 is recovered, the protrusion 393a abuts on the inner surface of the recess 392m ( Collision). As a result, when the operation unit 320 (displacement unit 395) is displaced to the terminal position (terminal interlocking position), an impact due to contact (collision) between the protrusion 393a and the recess 392m can be generated. As a result, the vibration can be transmitted to the hand of the player who operates (grips) the operation unit 320 (grip unit 330), and the player can easily recognize that the operation unit 320 has been displaced to the terminal position.

Further, when the operation unit 320 is operated to the terminal position, the vibration can be transmitted to the player's hand, so that the operation feeling can be improved.

Similarly, when the first corner portion 397b of the second displacement member 397 gets over the protruding portion (protruding tip) of the leaf spring 393, the player who operates the operation unit 320 before and after the overcoming operation receives from the leaf spring 393. The reaction force (elastic recovery force) can be reversed. That is, the reaction force from the leaf spring 393 is gradually increased until the first corner portion 397b reaches the protruding tip (top) of the protruding portion of the leaf spring 393, and the maximum reaction force is generated when overcoming the reaction force. On the other hand, the reaction force can be sharply reduced immediately after overcoming it. As a result, when operating the operation unit 320, a click feeling can be formed and the operation feeling can be improved. In particular, when this click feeling is formed, the vibration due to the collision of the protrusion 393a with the recess 392m can be transmitted, so that the operation feeling can be further improved by these combinations.

As shown in FIGS. 38 (a) to 38 (d), when the displacement unit 395 is displaced from the terminal interlocking position to the initial biasing position, the second side wall 397f (first corner portion) of the second displacement member 397 The portion of the side surface connecting the 397b and the third corner portion 397d on the first corner portion 397b side is brought into contact with the side surface of the protruding portion of the leaf spring 393.

In this case, as the displacement unit 395 is displaced toward the initial biasing position, the second displacement member 397 first displaces the second corner portion 397c (the first side wall 397e on the second corner portion 397c side). The displacement member 396 is rotated in the rotation direction (counterclockwise in FIGS. 38 (a) to 38 (c)) separated from the contact surface 396 g3. As a result, the first corner portion 397b of the second displacement member 397 is retracted in the direction away from the leaf spring 393. As a result, the leaf spring 393 is hardly elastically deformed. Therefore, the displacement unit 395 (operation unit 320) can be smoothly returned to the initial biasing position (initial position).

When the displacement unit 395 reaches the initial biasing position, as shown in FIGS. 38 (c) and 38 (d), the first corner portion 397b passes through the protruding portion (bending tip) of the leaf spring 393. After that, the portion of the second side wall 397f (the side surface connecting the first corner portion 397b and the third corner portion 397d) of the second displacement member 397 on the third corner portion 397d side is the regulation piece 392f (convex portion 392f1). ). As a result, the rotation direction of the second displacement member 397 to bring the second corner portion 397c (the first side wall 397e on the second corner portion 397c side) into contact with the contact surface 396g3 of the first displacement member 396 (FIG. 38 (d)). ), The first corner portion 397b is advanced (protruded) in a direction close to the leaf spring 393. That is, the second displacement member 397 can be returned to the initial position. As a result, as described above, it is possible to reliably form the transmission of vibration and the click feeling when the displacement unit 395 is displaced from the initial biasing position toward the terminal interlocking position.

Since the displacement (return) of the displacement unit 395 from the terminal interlocking position to the initial urging position is performed by the elastic recovery force of the coil spring SP2, when the initial urging position is reached, the second displacement member 397 (return) The second side wall 397f) is brought into contact with (collision) with the regulation piece 392f (convex portion 392f1). As described above, in the present embodiment, since the target to be abutted (collised) with the second displacement member 397 (second side wall 397f) is the regulation piece 392f (convex portion 392f1), the regulation piece 392f (convex portion) 392f1) can be elastically deformed to alleviate the impact at the time of contact (collision). As a result, damage (bending or breakage) of the shaft portion 396h that pivotally supports the second displacement member 397 can be suppressed.

Next, the displacement unit 2395 in the second embodiment will be described with reference to FIGS. 39 and 40. In the first embodiment, the case where the displacement unit 395 is rotationally displaced has been described, but in the second embodiment, the case where the displacement unit 2395 is linearly displaced will be described. The same parts as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

39 (a) to 39 (c) are front views of the base unit 2390 in the second embodiment, and FIGS. 40 (a) to 40 (c) are the XLa-XLa lines of FIG. 39 (a). It is sectional drawing of the base unit 2390 in the above.

Note that FIG. 39 (a) shows a state in which the operation unit 320 (see FIG. 16 (a)) is arranged at the initial position and the displacement unit 2395 is arranged at the initial bias position. FIG. 39 (c) shows the state. , The state in which the operation unit 320 is arranged at the terminal position and the displacement unit 2395 is arranged at the terminal interlocking position is illustrated. In FIG. 39 (b), the operation unit 320 is displaced from the initial position and the operation unit 320 is engaged. The state in which the piece 342b is arranged at the contact position where it abuts on the displacement unit 2395 (protruding portion 396b) is shown. Further, in FIGS. 39 and 40, only the outer shape of the engaging piece 342b of the operation unit 320 is shown by a chain line. Further, FIG. 40 (a) is shown in FIG. 39 (a), FIG. 40 (b) is shown in FIG. 39 (b), and FIG. 40 (c) is shown in FIG. 39 (c).

As shown in FIGS. 39 and 40, the base unit 2390 in the second embodiment has a base unit 2391, a displacement unit 2395 disposed on the base unit 2391, and a displacement unit 2395 with respect to the base unit 2391. It mainly includes a coil spring SP2 and a force coil spring SP2.

The base unit 2391 is a base member 2392 arranged inside the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and a leaf spring arranged on the base member 2392. It mainly includes a 393 and a detection device 394 disposed on the base member 2392.

The base member 2392 includes a base plate 2392a, a first wall portion 392b that is erected from the base plate 2392a toward the front side (the side in the direction of arrow F) and is formed in a semicircular arc shape in the front view, and the first wall portion thereof. The second wall portion 2392c erected radially outside the first wall portion 392b with respect to the 392b, the third wall portion 2392h erected from the base plate 2392a toward the front side, and the front side from the base plate 2392a. Mainly, the spring engaging piece 2392k projecting toward the direction, the inner first engaging piece 2392d1, and the regulating piece 2392f formed inside the base plate 2392a cut out in a substantially U-shape in the front view. Prepare for.

The base plate 2392a in the second embodiment is formed in a vertically long rectangular shape when viewed from the front. Further, the annular member 310 on which the base member 2392 is arranged has an inner peripheral edge shape larger than the outer shape (outer peripheral edge shape) of the base plate 2392a.

The second wall portion 2392c is a wall portion that guides the displacement of the displacement unit 2395, which will be described later, is formed at a position adjacent to the displacement unit 2395 in the front view, and is formed in a straight line in the front view along the displacement locus of the displacement unit 2395. It will be extended.

Further, an outer first engaging piece 2392e1 and an outer second engaging piece 2392e2 are projected from the standing tip side (front side) toward the displacement unit 2395 side on the second wall portion 2392c. The outer first engaging piece 2392e1 and the outer second engaging piece 2392e2 are portions for restricting the displacement unit 2395 arranged in the base unit 2391 from falling off toward the front side (arrow F direction), respectively. It is formed at a position separated by a predetermined distance along the extending direction of the second wall portion 2392c (displacement direction of the displacement unit 2395).

The outer first engaging piece 2392e1 and the outer second engaging piece 2392e2 are portions for restricting the displacement unit 2395 arranged in the base unit 2391 from falling off toward the front side (arrow F direction), and are the base unit. The displacement unit 2395 (first displacement member 2396) arranged in 2391 is formed at a position separated from the base plate 2392a by the thickness in the front-rear direction (arrow FB direction). Thereby, the displacement unit 2395 (first displacement member 2396) can be arranged in a state of being sandwiched between the base plate 2392a and the outer first engaging piece 2392e1 and the outer second engaging piece 2392e2 (FIG. 40 (a). )reference).

The third wall portion 2392h is formed along the edge portion of the base plate 2392a, and the front view shape on the upper side (upper side in FIG. 39) is curved into a semicircular shape coaxial with the first wall portion 392b. Further, the second cylindrical portion 362b (not shown) of the second annular member 362 to which the base unit 2390 is fastened is formed so that the outer shape in the rear view is the same as the outer shape of the third wall portion 2392h. As a result, when the base unit 2390 is fastened to the operation unit 320, the back side of the second cylindrical portion 362b and the third wall portion 2392h are brought into contact with each other, and the inside of the second cylindrical portion 362b is brought into contact with the inside of the second cylindrical portion 362b from the outside of the slot machine 10. It is possible to prevent an illegal member from being inserted into the.

The spring engaging piece 2392k is a portion for engaging one end of the coil spring SP2 for urging the displacement unit 2395, is projected from the front side of the base plate 2392a, and is directed toward the side opposite to the displacement direction of the displacement unit 2395. It is formed in an L-shape when viewed from the side with a bent tip.

The inner first engaging piece 2392d1 is a member that prevents the displacement unit 2395 from falling off (removing) toward the front side (arrow F direction), and is located at a position along the displacement locus of the displacement unit 2395 (a position that overlaps in the front view). It is formed. The inner first engaging piece 2392d1 has a first portion (standing portion) erected from the front side (arrow F direction side) of the base plate 2392a and a second wall from the protruding tip of the first portion. A second portion (protruding portion) that is projected toward the portion 2392c and is located on the displacement locus of the displacement unit 2395 (a position that overlaps the displacement locus in the front view) is provided. As a result, the displacement unit 2395 arranged in front of the base plate 2392a can be arranged in a state of being sandwiched between the base plate 2392a and the second portion (protruding portion) of the inner first engaging piece 2392d1 (protruding portion). (See FIG. 40 (a)).

The restricting piece 2392f is a portion that regulates the displacement of the displacement unit 2395 to one side (initial urging position side), and is formed on the back side of the displacement unit 2395 arranged along the second wall portion 2392c. It is formed at a position where it overlaps with the displacement locus of the displacement unit 2395 in front view.

The regulation piece 2392f is formed by cutting out the base plate 2392a in a substantially U shape when viewed from the front, and is formed as an elastic piece having one end connected to the base plate 2392a and the other end having a free end. The other end side of the regulation piece 2392f is provided with a convex portion 392f1 projecting toward the front side (displacement unit 2395 side, arrow F direction side), and the displacement unit 2395 is brought into contact with the convex portion 392f1. Therefore, the displacement of the displacement unit 2395 to one side is regulated.

The displacement unit 2395 mainly includes a first displacement member 2396 that is formed in a straight line (a substantially rectangular shape in the front view) in the front view, and a second displacement member 397 that is pivotally supported by the first displacement member 2396. Prepare for.

The first displacement member 2396 includes a main body portion 2396a extending in a straight line, a spring engaging portion 396c formed on one end side of the main body portion 2396a in the longitudinal direction in a substantially C shape in a front view, and a main body portion 2396a. A protruding portion 396b projecting from the side surface on the other end side in the longitudinal direction toward the first wall portion 392b of the base plate 2392a, and a engaging portion projecting from the side surface of the main body portion 2396a opposite to the second wall portion 2392c. Detection that the joint portion 2396d, the outer recessed portion 2396e formed by cutting out the edge portion of the main body portion 2396a on the second wall portion 2392c side, and the main body portion 2396a projecting from the side surface on the second wall portion 2392c side. It mainly includes a piece 396f and a shaft portion 396h that protrudes from the back surface of the main body portion 2396a and is formed in a columnar shape.

The length of the main body portion 2396a in the longitudinal direction (direction extending in a straight line shape) is set to be shorter than the extension dimension of the second wall portion 2392c. Further, the displacement amount of the displacement unit 2395 is set to a dimension (displacement amount) smaller than the difference between the extension dimension of the second wall portion 2392c and the longitudinal length of the main body portion 2396a. As a result, when the first displacement member 2396 (displacement unit 2395) is displaced along the second wall portion 2392c, the main body portion 2396a can always be arranged at a position adjacent to the second wall portion 2392c.

Further, the main body portion 2396a has a first surface 396a1 forming a back surface on the other end side in the longitudinal direction and a second surface 396a2 located on the front side of the first surface 396a1 and forming a back surface on one end side in the longitudinal direction. , 396 g of a wall surface connecting the first surface 396a1 and the second surface 396a2 in the front-rear direction (arrow FB direction).

In the second embodiment, the spring engaging piece 2392k of the base plate 2392a to which the coil spring SP2 is engaged is formed on an extension of the displacement locus of the displacement unit 2395. The coil spring SP2 is engaged with the spring engaging piece 2392k at a position in a posture along the displacement direction of the displacement unit 2395 (longitudinal direction of the first displacement member 2396), and is arranged in a state of being elastically pulled and deformed. Will be done. Therefore, the coil spring SP2 can apply an urging force (elastic recovery force) in the direction toward the initial urging position to the displacement unit 2395.

The thickness dimension of the engaging portion 2396d in the front-rear direction (arrow FB direction) is set to be smaller than the thickness dimension of the main body portion 2396a, and is formed at a position connected to the back surface of the main body portion 2396a. That is, the front surface of the engaging portion 2396d is located on the back surface side of the front surface of the main body portion 2396a.

Further, the engaging portion 2396d is a second portion (protruding) of the base plate 2392a and the inner first engaging piece 2392d1 in a state where the first displacement member 2396 is arranged on the base member 2392 (base unit 2391). It is a part arranged between facing the part). Therefore, since the thickness dimension of the engaging portion 2396d is set to be smaller (thinner) than the thickness dimension of the main body portion 2396a, the protrusion distance (first portion) of the inner first engaging piece 2392d1 from the base plate 2392a. The height of the (standing part) can be shortened. As a result, the rigidity of the inner first engaging piece 2392d1 can be ensured, and the reaction force applied from the first displacement member 2396 (displacement unit 2395) can prevent the inner first engaging piece 2392d1 from being damaged.

The engaging portion 2396d includes an inner first recessed portion 2396d1 formed by partially cutting out an outer edge along the longitudinal direction of the main body portion 2396a. When the first displacement member 2396 is arranged on the base member 2392 (base unit 2391), the inner first recessed portion 2396d1 engages the second portion (protruding portion) of the inner first engaging piece 2392d1. It is a notch to be inserted into the front side of the 2396d, and the notch is formed with an inner edge shape larger than the front view shape of the bent portion of the inner first engaging piece 2392d1.

When the first displacement member 2396 is arranged on the base member 2392 (base unit 2391), the outer recessed portion 2396e inserts the outer second engaging piece 2392e2 into the front side of the main body portion 2396a of the first displacement member 2396. It is a notch, and at the outer edge along the longitudinal direction of the main body portion 2396a opposite to the inner first concave portion 2396d1, a notch is formed with an inner edge shape larger than the front view shape of the outer second engaging piece 2392e2. ..

The distance between the outer recessed portion 2396e and the inner first recessed portion 2396d1 in the extending direction (longitudinal direction) of the main body portion 2396a is the outer second engaging piece 2392e2 in the displacement direction of the displacement unit 2395. , It is set to be substantially the same as the separation distance of the inner first engaging piece 2392d1.

As a result, as in the case of the first embodiment, the inner first engaging piece 2392d1 of the base member 2392 and the outer second engaging piece 392e2 are placed on the inner first recessed portion 2396d1 of the first displacement member 2396. The first displacement member 2396 (displacement unit 2395) can be arranged in the base member 2392 (base unit 2391) by inserting the first displacement member 2396 (displacement unit 2395) into the outer recessed portion 396e, respectively.

In the base unit 2390, as shown in FIGS. 39 (a) and 40 (a), the tip of the engaging piece 342b of the operation unit 320 (see FIG. 15) projects from the main body 2396a of the first displacement member 2396. When the operation unit 320 is arranged in the initial position in the area surrounded by the portion 396b, the projecting portion 396b and the tip of the engaging piece 342b are arranged at a predetermined interval.

When the operating unit 320 (see FIG. 15) is operated by the player from the initial position and the engaging piece 342b of the operating unit 320 is rotated (displaced), as shown in FIGS. 39 (b) and 40 (b). The engaging piece 342b is brought into contact with the projecting portion 396b of the displacement unit 2395.

In the second embodiment, as in the case of the first embodiment, the position where the engaging piece 342b comes into contact with the projecting portion 396b is such that the operation unit 320 is displaced between the initial position and the first position. It is considered to be a position. As a result, when the player pushes the operation unit 320 from the initial position, the guided member 344 engages before coming into contact with the fourth guide surface 351d (see FIG. 26B) in the second guide region. The piece 342b can be brought into contact with the projecting portion 396b.

Therefore, before the guided member 344 reaches the first position (the guided member 344 reaches the fourth guide surface 351d), a resistance force (a urging force of the coil spring SP2) opposed to the pushing direction of the gripping unit 330 is applied. be able to. As a result, the impact when the guided member 344 comes into contact with the fourth guide surface 351d can be suppressed, and damage to the guided member 344 and the fourth guide surface 351d can be suppressed.

When the operation unit 320 is displaced from the contact position to the end position (that is, the operation unit 320 is further rotationally displaced from the position where the engaging piece 342b abuts on the projecting portion 396b), FIGS. 39 (c) and FIG. As shown in 40 (c), the displacement unit 2395 (first displacement member 2396) is linearly displaced (linearly moved) along its longitudinal direction with the displacement of the engaging piece 342b. As a result, the displacement unit 2395 is placed at the displacement end position.

In this case, as in the case of the first embodiment, after the engaging piece 342b is brought into contact with the projecting portion 396b, the engaging piece 342b stays in the operating unit 320 while the operating unit 320 is displaced to the terminal position. Is displaced in the same direction as. That is, since the contact between the engaging piece 342b and the projecting portion 396b is maintained, the urging force (elastic recovery force) of the coil spring SP2 can continue to act as an operation feeling when operating the operation unit 320. it can.

A leaf spring 393 disposed on the base unit 2391 is arranged on the displacement locus of the second displacement member 397 of the displacement unit 2395. Therefore, when the displacement unit 2395 is displaced from the initial biasing position to the terminal interlocking position, the displacement unit 2395 is in the middle of the displacement (immediately before reaching the terminal interlocking position as in the case of the first embodiment). The second displacement member 397 of the above can be brought into contact with the leaf spring 393 to elastically deform the leaf spring 393. Since the elastic deformation of the leaf spring 393 due to the displacement of the displacement unit 2395 is the same as in the case of the first embodiment, the description thereof will be omitted.

As described above, the displacement unit 2395 is urged toward the initial urging position side by the urging force (elastic recovery force) of the coil spring SP2. Therefore, when the operation of the operation unit 320 is released (for example, when the player releases the grip unit 330), the displacement unit 2395 is displaced toward the initial urging position and is displaced. The engaging piece 342b is pushed back by the protruding portion 396b of the unit 395, and as a result, the operating unit 320 is returned to the initial position.

As described above, in the second embodiment, the engaging piece 342b of the operation unit 320 that is rotationally displaced is brought into contact with the first displacement member 2396 (displacement unit 2395) that is linearly displaced (linearly moved). Since the first displacement member 2396 is displaced (the engaging piece 342b slides on the projecting portion 396b), it is displaced with respect to the circumferential displacement distance of the engaging piece 342b when the operating unit 320 is displaced. The displacement distance of the unit 2395 in the linear direction can be reduced. As a result, the force required to operate the operation unit 320 when the displacement unit 2395 is displaced can be reduced. As a result, the player can easily operate the operation unit 320. Further, since the space required for arranging the displacement unit 2395 can be reduced, the size of the base unit 2390 can be reduced.

The contact surface of the projecting portion 396b to which the engaging piece 342b is in contact is formed as a flat surface having a linear front view, and the displacement direction of the displacement unit 2395 (longitudinal length of the first displacement member 2396) in the front view. It is formed at an angle with respect to the direction). The inclination direction of the contact surface of the projecting portion 396b is set to be inclined in a direction away from the engaging piece 342b toward the projecting tip side (opposite side of the main body portion 396a) of the projecting portion 396b. Further, the side surface of the engaging piece 342b that abuts on the projecting portion 396b is formed by being curved in an arc shape that is convex toward the projecting portion 396b in the front view. As a result, even when the engaging piece 342b is displaced in the rotational direction and the projecting portion 396b is displaced in the linear direction, the engaging piece 432b can be easily slid with respect to the projecting portion 396b. Displacement can be stabilized.

Here, in the second embodiment, in a state where the operation unit 320 (displacement unit 2395) is arranged at the end position (end interlocking position), the engaging piece 342b comes into contact with the projecting portion 396b, and the operation unit 320 (engagement). The direction connecting the center of rotation of the combined piece 342b) and the engaging piece 342b is parallel to the direction of the linear displacement (linear motion) of the displacement unit 2395 in front view, and the engaging piece 342b of the projecting portion 396b The surface to be abutted may be configured to be orthogonal to the direction of the linear displacement (linear motion) of the displacement unit 2395 in the front view. That is, the rotational direction of the engaging piece 342b and the linear displacement direction of the displacement unit 2395 may be orthogonal to each other. According to this, the player can set the second guide surface 351b (see FIG. 22D) of the guide unit 350 in a direction orthogonal to the pushing direction (arrow FB direction) of the operation unit 320. The operation unit 320 can be maintained at the terminal position after the operation unit 320 is rotationally displaced to the terminal position. That is, it is possible to prevent the operation unit 320 from returning to the initial position by the urging force of the coil spring SP1 (see FIG. 14) and the coil spring SP2. As a result, it is possible to improve the interest of the player by giving a variation to the operation method of the operation unit 320.

Next, the base unit 3390 according to the third embodiment will be described with reference to FIG. 41. In the first embodiment, the inner first engaging piece 392d1 and the inner first engaging piece 392d1 of the base member 392 are attached to the inner first recessed portion 396d1, the inner second recessed portion 396d2 and the outer recessed portion 396e of the first displacement member 396. 2 At a position (phase) where the engaging piece 392d2 and the outer second engaging piece 392e2 can be inserted, the displacement unit 395 is elastically deformed to the back side (arrow B direction) with respect to the base member 392 while elastically deforming the regulation piece 392f. The case where the displacement unit 395 is arranged on the base unit 391 by rotating the displacement unit 395 (sliding displacement along the second wall portion 392c) after pushing in has been described, but in the third embodiment, the displacement unit By simply pushing the 3395 toward the back side (in the direction of arrow B) with respect to the base member 3392 (that is, the inner first locking portion 3392d3, the inner second locking portion 3392d4, the outer first locking portion 3392e3, and the outer second displacement). The displacement unit 3395 is arranged in the base unit 3391 (only by elastically deforming the stop 3392e4). The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

41 (a) is a front view of the base unit 3390 according to the third embodiment, and FIG. 41 (b) is a schematic cross-sectional view of the base unit 3390 in the XLIb-XLIb line of FIG. 41 (a). 41 (c) is a cross-sectional schematic diagram of the base unit 3390 in the XLIc-XLIc line of FIG. 41 (a).

As shown in FIG. 41, the base unit 3390 according to the third embodiment includes a base unit 3391, a displacement unit 3395 disposed on the base unit 3391, and a coil for urging the displacement unit 3395 with respect to the base unit 3391. It mainly includes a spring SP2.

The base unit 3391 is formed in an outer shape corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and is arranged inside the annular member 310. It mainly includes a base member 3392, a leaf spring 393 disposed on the base member 3392, and a detection device 394 disposed on the base member 3392.

The base member 3392 includes a base plate 3392a, a first wall portion 392b erected in a semi-circular shape toward the front side (arrow F direction side) of the base plate 3392a, and a center of the first wall portion 392b. A ring shape coaxially with the second wall portion 3392c, the first wall portion 392b, and the second wall portion 392c, which are formed in a semi-arc shape on the same axis and are erected from the base plate 3392a toward the front side. A third wall portion 392h formed in the base plate 3392a and erected toward the front side, a spring engaging piece 392k projecting from the base plate 3392a toward the front side, and an inner first locking portion 3392d3. , The inner second locking portion 3392d4, the convex portion 3392f1, and the regulation piece 392f are mainly provided.

The second wall portion 3392c is set to a diameter larger than the diameter of the first wall portion 392b, and is formed at a position separated from the first wall portion 392b by a predetermined distance. The second wall portion 3392c is a wall portion that guides the displacement of the first displacement member 3396 (displacement unit 3395), which will be described later, and is curved in an arc shape having a diameter along the displacement locus of the first displacement member 3396 (displacement unit 3395). Is formed.

Further, the second wall portion 3392c includes a plurality of cutout portions 3392c2 formed in a slit shape at a predetermined depth (notch size) from the erection tip side thereof toward the base plate 3392a side. In the present embodiment, the cutouts 3392c2 are formed with a pair of notches 3392c2 that are separated by a predetermined distance in the circumferential direction along the second wall portion 3392c at two places (a total of four places) in the circumferential direction.

The pair of notch portions 3392c2 are formed with notches extending from the radially inner side to the radial outer side of the second wall portion 3392c. That is, each notch portion 3392c2 is formed so as to penetrate the second wall portion 3392c in the plate thickness direction (diameter direction).

The notch dimension (depth) of the pair of notch portions 3392c2 toward the base plate 3392a side (arrow B direction side) is set to be smaller than the vertical dimension of the second wall portion 3392c from the base plate 3392a. That is, each cutout portion 3392c2 does not reach the base end of the second wall portion 3392c, and the second wall portion 3392c is in a state in which the base end side thereof is continuous along the circumferential direction (displacement direction of the displacement unit 3395). Is (formed continuously).

The second wall portion 3392c has a first outer portion from the inner peripheral surface of the second wall portion 3392c located between the pair of cutout portions 3392c2 toward the radial inside (displacement unit 3395 side) of the second wall portion 3392c. The stop portion 3392e3 and the outer second locking portion 3392e4 are projected.

The outer first locking portion 3392e3 and the outer second locking portion 3392e4 allow the displacement unit 3395 to be attached to the base member 3392 (base unit 3391), which will be described later, while allowing the displacement unit 3395 to fall off (remove). It is a protrusion that regulates, and is projected to a position that overlaps the displacement locus of the displacement unit 3395 in the front view.

The outer first locking portion 3392e3 and the outer second locking portion 3392e4 are inclined downward to the back side (arrow B direction side) as the front surface (plane on the arrow F direction side) is separated from the second wall portion 3392c. On the other hand, the back surface (the surface on the side in the direction of arrow B) is formed on a plane parallel to the front surface of the base plate 3392a.

The facing distance (dimension in the arrow FB direction) between the back surface of the outer first locking portion 3392e3 and the outer second locking portion 3392e4 and the front surface of the base plate 3392a is the displacement unit 3395 (first displacement member 3396). ) Is set to be substantially the same as or slightly larger than the thickness dimension in the front-rear direction (arrow FB direction). Thereby, the displacement unit 3395 can be displaceably arranged in a state of being sandwiched between the front surface of the base plate 3392a and the back surface of the outer first locking portion 3392e3 and the outer second locking portion 3392e4 (FIG. 41 (c)).

The inner first locking portion 3392d3 and the inner second locking portion 3392d4 are members that regulate the detachment (removal) of the displacement unit 3395 while allowing the displacement unit 3395 to be attached to the base member 3392 (base unit 3391). There is, and it is erected from the front surface of the base plate 3392a toward the same direction as the second wall portion 3392c (direction of arrow F).

At the erection tips of the inner first locking portion 3392d3 and the inner second locking portion 3392d4, a claw portion is projected from the inner peripheral surface toward the second wall portion 3392c side. The claw portion (the portion protruding from the inner peripheral surface at the erection tip toward the second wall portion 3392c side) is projected to a position overlapping the displacement locus of the displacement unit 3395 in the front view.

In the inner first locking portion 3392d3 and the inner second locking portion 3392d4, the front surface (the surface on the arrow F direction side) of the claw portion (protruding portion) is on the second wall portion 3392c side (protruding portion of the claw portion). It is formed so as to be inclined downward toward the back surface side (arrow B direction side) toward the front end side in the direction), while the back surface (plane on the arrow B direction side) is formed on a plane parallel to the front surface of the base plate 3392a.

The facing distance (dimension in the arrow FB direction) between the back surface of the claw portion (protruding portion) of the inner first locking portion 3392d3 and the inner second locking portion 3392d4 and the front surface of the base plate 3392a is the displacement unit 3395. It is set to be substantially the same as or slightly larger than the thickness dimension in the front-rear direction (arrow FB direction) of (engaging portion 396d of the first displacement member 3396). As a result, the displacement unit 3395 (engagement portion 396d of the first displacement member 3396) is placed between the front surface of the base plate 3392a, the outer first locking portion 3392e3, and the back surface of the outer second locking portion 3392e4. It can be displaceably arranged in a sandwiched state (see FIG. 41 (c)).

The base member 3392 (base plate 3392a) is formed of a resin material, and has an outer first locking portion 3392e3, an outer second locking portion 3392e4, an inner first locking portion 3392d3, and an inner second locking portion. 3392d4 is elastically deformable.

The thickness of the inner first locking portion 3392d3 and the standing portion (the portion erected from the base plate 3392a) of the inner second locking portion 3392d4 (dimension in the left-right direction in FIG. 41 (c)) is the base plate 3392a. It is formed to be smaller than the plate thickness (dimension in the front-rear direction (arrow FB direction)). As a result, the inner first locking portion 3392d3 and the inner second locking portion 3392d4 can be easily elastically deformed in the direction in which the claw portion is brought close to or separated from the displacement unit 3395.

The thickness of the second wall portion 3392c of the inner portion of the pair of cutout portions 3392c2 (the portion where the outer first locking portion 3392e3 and the outer second locking portion 3392e4 are formed) (FIG. 41 (FIG. 41). c) The dimension in the left-right direction) may be set to a dimension smaller than the plate thickness (dimension in the front-rear direction (arrow FB direction)) of the base plate 3392a. As a result, the second wall portion 3392c of the inner portion of the pair of cutout portions 3392c2 can be easily elastically deformed in the direction in which the outer first locking portion 3392e3 and the outer second locking portion 3392e4 are brought close to or separated from the displacement unit 3395. ..

The convex portion 3392f1 is formed at a position adjacent to the second displacement member 397 of the displacement unit 3395 arranged at the initial biasing position in front view, and when the displacement unit 3395 is arranged at the initial biasing position, the second By abutting on the displacement member 397, it functions as a portion that defines the arrangement of the second displacement member 397 with respect to the first displacement member 3396. That is, the convex portion 3392f1 is arranged at the same position as the convex portion 392f1 of 392f in the first embodiment, and the action (regulation of arrangement) on the second displacement member 397 at the initial biasing position is the first embodiment described above. Since it is the same as the case of the form (convex portion 392f1), detailed description thereof will be omitted.

The displacement unit 3395 is urged to the initial urging position side by the coil spring SP2, and the second displacement member 397 comes into contact with the convex portion 3392f at the initial urging position, and the displacement unit 3395 is maintained at the initial urging position. (The displacement unit 3395 is suppressed from being displaced beyond the initial biasing position).

The displacement unit 3395 mainly includes a first displacement member 3396 and a second displacement member 397 rotatably supported by the first displacement member 3396.

The first displacement member 3396 has a main body portion 396a and a main body portion 396a formed in a shape curved in an arc shape in a front view (a shape in which the ring shape is divided at two positions (positions in which the phases are 180 degrees out of phase)). The spring engaging portion 396c formed in a substantially C shape on one end side in the longitudinal direction (circumferential direction) of the main body portion 396a, and the arc center (diameter inward) of the main body portion 396a on the other end side in the longitudinal direction (circumferential direction) of the main body portion 396a ), An engaging portion 3396d located along the inner edge of the main body portion 396a and formed as a thinner portion than the other portions, and an outer peripheral edge of the main body portion 396a. An outer recessed portion 396e formed by cutting out a portion, a detection piece 396f projecting radially outward from the outer peripheral edge portion of the main body portion 396a, and a columnar protrusion on the back surface of the main body portion 396a. Mainly includes a shaft portion 396h to be provided.

The thickness of the engaging portion 3396d in the front-rear direction (arrow FB direction) is set to be smaller than the thickness of the main body portion 396a in the front-rear direction, and the back surface (the surface on the arrow B direction side) is set to the main body portion 396a. It is formed by connecting with the back of the. That is, the front surface of the engaging portion 396d (the surface on the side in the direction of arrow F) is positioned so as to recede toward the back surface (side in the direction of arrow B) from the front surface of the main body portion 396a.

When the first displacement member 3396 is arranged on the base member 3392 (base unit 3391), the engaging portion 3392d is formed on the front surface of the base plate 3392a, the inner first locking portion 3392d3, and the inner second locking portion 3392d4. It is arranged between the back surface of the claw portion and the opposite surface. Therefore, since the thickness of the engaging portion 3396d is formed to be smaller (thinner) than the thickness of the main body portion 3396a, the inner first locking portion 3392d3 and the inner second locking portion 3392d4 are separated from the base plate 3392a. The standing height can be lowered.

As a result, the rigidity of the inner first locking portion 3392d3 and the inner second locking portion 3392d4 can be secured. Therefore, it is possible to prevent the displacement unit 3395 from falling off from the base member 3392 toward the front side (arrow F direction side). Further, the inner first locking portion 3392d3 and the inner second locking portion 3392d4 are damaged (broken) due to the load (impact) when the displacement unit 3395 in the radial direction (to the right in FIG. 41C) is received. Can be suppressed. The radial outward displacement of the displacement unit 3395 can be received by the entire second wall portion 3392c, whereas the radial inward displacement of the displacement unit 3395 can be received by the inner first locking portion 3392d3 and the inner side. Since it is necessary to receive only by the second locking portion 3392d4, it is particularly effective to increase the rigidity of the inner first locking portion 3392d3 and the inner second locking portion 3392d4.

The displacement unit 3395 in the third embodiment has recessed portions (inner first recessed portion 396d1, inner second recessed portion d2, outer recessed portion 396e) in the first displacement member 396 as in the first embodiment. ) Is not recessed, but the other configurations are the same as the displacement unit 395.

To attach the displacement unit 3395 to the base unit 3390 (base unit 3391), the displacement unit 3395 is arranged in front of the base unit 3391, and then the displacement unit 3395 is pushed into the back side (base plate 3392a side).

In this case, the back surface (inclined surface) of the radial outer edge of the first displacement member 3396 is the outer first locking portion 3392e3 and the outer second locking portion 3392e4 of the base member 3392. The outer first locking portion 3392e3 and the outer second locking portion 3392e4 are extruded radially outward of the second wall portion 3392c so as to be in contact with the front surface, and the second wall portion 3392c (between the pair of notched portions 3392c2). Part) is elastically deformed outward in the radial direction.

Similarly, the radial inner edge of the first displacement member 3396 (engagement portion 3396d) is the front surface of the inner first locking portion 3392d3 of the base member 3392 and the claw portion of the inner second locking portion 3392d4. The claws of the inner first locking portion 3392d3 and the inner second locking portion 3392d4 are extruded radially inward of the second wall portion 3392c so as to be abutted against the inclined surface). The locking portion 3392d3 and the upright portion of the inner second locking portion 3392d4 are elastically deformed.

After that, the radial outer edge of the first displacement member 3396 is the claws of the outer first locking portion 3392e3 and the outer second locking portion 3392e4, and the inner first locking portion 3392d3 and the inner second locking portion 3392d4. When passing through the portions, the second wall portion 3392c (the portion between the pair of notched portions 3392c2) and the standing portions of the inner first locking portion 3392d3 and the inner second locking portion 3392d4 are elastically recovered. It returns to the initial position (position in the no-load state). This completes the attachment of the displacement unit 3395 to the base unit 3391.

As described above, according to the base unit 3390, when the displacement unit 3395 is arranged in the base unit 3391 as in the first embodiment, it is necessary to align the displacement unit 3395 at a specified position (positioning position). Instead, the displacement unit 3395 can be attached (arranged) to the base unit 3391 only by pushing the displacement unit 3395 from the front side (arrow F direction side) to the back side (arrow B direction side) of the displacement region. Further, as in the case of the first embodiment, it is not necessary to slide the displacement unit 3395 (rotate along the displacement locus) after pushing it toward the back surface side (arrow B direction side). As a result, the operation (assembly work) when arranging the displacement unit 3395 on the base unit 3391 can be simplified.

Further, in the third embodiment, since the displacement unit 3395 can be arranged from the front side in the displacement locus (the region through which the displacement unit 3395 passes from the initial biasing position to the terminal interlocking position), the first embodiment is described above. It is not necessary to secure the arrangement space of the displacement unit 395 outside the displacement region of the displacement unit 395 as in the embodiment (in the first embodiment, a part of the displacement unit 395 protrudes out of the displacement region at the positioning position). Therefore, it is possible to easily secure a space for arranging other parts (for example, coil spring SP2 or detection device 394, or ribs for reinforcement).

As described above, each notch 3392c2 does not reach the base end of the second wall portion 3392c, and the base end side of the second wall portion 3392c is continuous along the circumferential direction (displacement direction of the displacement unit 3395). (Continuously formed).

Therefore, when the displacement unit 3395 (first displacement member 3396) is displaced, the displacement can be received at the proximal end side of the second wall portion 3392c (the region where the notch portion 3392c2 is not formed). Therefore, the portion of the second wall portion 3392c where the outer first locking portion 3392e3 and the outer second locking portion 3392e4 are projected (the portion located between the pair of notched portions 3392c2) is damaged (broken). Can be suppressed.

Further, the displacement unit 3395 (first displacement member 3396) can be guided on the proximal end side of the second wall portion 3392c (the region where the notch 3392c2 is not formed) (the inner peripheral surface on the proximal end side continuous in the circumferential direction). Since it can be slid), it is possible to prevent the outer edge of the first displacement member 3396 from being caught by the inner edge of the notch 3392c2 and being chipped or worn.

Next, the base unit 4390 according to the fourth embodiment will be described with reference to FIG. 42. In the first embodiment, a protrusion formed on the base plate 392a in a recessed portion (inner first recessed portion 396d1, etc.) recessed in the radial inner portion and the radial outer portion of the first displacement member 396. The case where the displacement unit 395 is arranged on the base unit 391 by inserting the installation portion (inner first engaging piece 392d1, etc.) has been described, but in the fourth embodiment, only on one side of the first displacement member 4396. A case where the recessed portion is formed will be described. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

42 (a) is a front view of the base unit 4390 in the fourth embodiment, and FIG. 42 (b) is a schematic cross-sectional view of the base unit 4390 in the XLIIb-XLIIb line of FIG. 42 (a).

As shown in FIG. 42, the base unit 4390 according to the fourth embodiment has a base unit 4391, a displacement unit 4395 disposed on the base unit 4391, and a coil for urging the displacement unit 4395 with respect to the base unit 4391. It mainly includes a spring SP2.

The base unit 4391 is a base member 4392 arranged inside the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and a leaf spring arranged on the base member 4392. It mainly includes a 393 and a detection device 394 disposed on the base member 4392.

The base member 4392 has a base plate 2392a, a first wall portion 392b erected in a semi-circular shape from the base plate 2392a toward the front side (arrow F direction side), and a first wall portion 392b thereof. The second wall portion 2392c erected on the radial outer side of the first wall portion 392b, the third wall portion 2392h erected from the base plate toward the front side, and the protrusion from the base plate 2392a toward the front side. The spring engaging piece 2392k and the inner first engaging piece 4392d1 and the restricting piece 2392f formed on the inner side of the base member 2392 notched in a substantially U shape in the front view (see FIG. 40 (a)). , Is mainly provided.

The inner first engaging piece 4392d1 is a member for preventing the displacement unit 4395, which will be described later, from falling off (removing), and is projected at a position along the displacement locus of the displacement unit 4395. Further, the inner first engaging piece 4392d1 is projected from the base plate 2392a toward the front side, and the protruding tip is bent toward the second wall portion 2392c side.

Further, the inner first engaging piece 4392d1 has a distance between the bent portion and the base plate 2395a facing each other in the front-rear direction (arrow FB direction) of the displacement unit 4395 (engaging portion 4396d of the first displacement member 4396). It is projected longer than the thickness dimension in.

The extension distance T6 of the inner first engaging piece 4392d1 to the second wall portion 2392c side in the bent portion is larger than the distance T7 between the bent portion of the inner first engaging piece 4392d1 and the base plate 2392a facing each other. It is set small (T7> T6).

The second wall portion 4392c is a wall portion that guides the displacement of the displacement unit 4395, which will be described later, is formed at a position adjacent to the displacement unit 4395 in the front view, and extends along the displacement locus of the displacement unit 2395.

Further, the second wall portion 4392c includes a plurality of cutout portions 4392c2 formed by notches from the erection tip side thereof to the base plate 2392a side. In the present embodiment, the notch 4392c2 is formed by forming a pair of notches 4392c2 that are separated by a predetermined distance along the extension direction of the second wall 4392c at two locations (a total of four locations) in the extension direction.

The pair of notch portions 4392c2 are notched in a direction orthogonal to the extending direction of the second wall portion 4392c. Further, in the pair of cutout portions 4392c2, the notch dimension toward the base plate 2392a side (arrow B direction side) is set to be smaller than the vertical dimension of the second wall portion 4392c from the base plate 2392a. That is, the second wall portion 4392c is in a state in which the base end side (base plate 2392a side) is connected.

Further, the outer first locking portion 4392e3 and the outer second locking portion are projected from the side surface of the second wall portion 4392c located between the pair of cutout portions 4392c2 on the displacement unit 4395 side toward the displacement unit 4395 side. The portion 4392e4 is formed.

The outer first locking portion 4392e3 and the outer second locking portion 4392e4 allow the displacement unit 4395 to be attached to the base member 4392 (base unit 4391), which will be described later, while allowing the displacement unit 4395 to fall off (remove). It is a protrusion that regulates, and is projected at a position along the displacement locus of the displacement unit 4395.

Further, the outer first locking portion 4392e3 and the outer second locking portion 4392e4 are inclined toward the back side (arrow B direction side) as the front side (arrow F direction side) is separated from the second wall portion 4392c. Is formed. On the other hand, the outer first locking portion 4392e3 and the outer second locking portion 4392e4 are formed on the back surface side in a plane parallel to the front surface of the base plate 4392a.

Further, the back surfaces of the outer first locking portion 4392e3 and the outer second locking portion 4392e4 are formed at positions separated from the thickness dimension of the displacement unit 4395 (first displacement member 4396) in the front-rear direction. As a result, the displacement unit 4395 arranged in front of the base plate 4392a is arranged in a state of being sandwiched between the base plate 4392a, the outer first locking portion 4392e3, and the outer second locking portion 4392e4. Yes (see FIG. 42 (b)).

Further, the thickness of the second wall portion 4392c of the inner portion of the pair of cutout portions 4392c2 (the portion where the outer first locking portion 4392e3 and the outer second locking portion 4392e4 are formed) is the plate of the base plate 2392a. It is formed smaller than the thickness (thickness of the base plate 2392a in the front-rear direction). As a result, the second wall portion 4392c of the inner portion of the pair of cutout portions 4392c2 can be easily elastically deformed in the radial direction.

The displacement unit 4395 mainly includes a first displacement member 4396 that is formed linearly as a whole when viewed from the front, and a second displacement member 397 that is pivotally supported by the first displacement member 4396.

The first displacement member 4396 has a linear main body portion 2396a and a spring engaging portion 396c formed in a substantially C shape on one end side of the linearly extending main body portion 2396a. A protruding portion 396b projecting toward the center of the first wall portion 392b of the base plate 2392a on the other end side of the extended main body portion 2396a, and a second wall portion 2392c formed along the displacement unit 4395. The engaging portion 4396d projecting from the side surface opposite to the main body portion 2396a, the detection piece 396f projecting from the side surface of the second wall portion 2392c side of the main body portion 2396a, and the detection piece 396f projecting from the back surface of the main body portion 2396a in a columnar shape Mainly includes a shaft portion 396h and a shaft portion 396h.

Since the engaging portion 4396d has a shape in which the inner first concave portion 2396d1 is omitted from the engaging portion 2396d in the second embodiment, detailed description thereof will be omitted.

In the method of attaching the displacement unit 3395 to the base unit 4391 of the base unit 4390 configured as described above, first, the engaging portion 4396d side of the displacement unit 4395 is brought close to the base plate 2392a, and the displacement unit 4395 is attached to the base plate. The engaging portion 4396d is pushed into the inside of the bent portion of the inner first engaging piece 4391d1 in a state of being slanted with respect to the front surface of the 2392a.

As described above, the inner first engaging piece 4391d1 has an extension distance T6 (see FIG. 42B) in the bent portion of the inner first engaging piece 4392d1 toward the second wall portion 2392c. Since the distance T7 (see FIG. 42 (b)) between the bent portion of the first engaging piece 4392d1 and the base plate 4391a is set smaller (shorter), the engaging portion 4396d is arranged diagonally. After pushing the inner first engaging piece 4391d1 inside the bent portion in the state, the displacement unit 4395 can be rotated toward the base plate 4392a about the engaging portion 4396d side.

Next, the displacement unit 4395 in a state of being diagonally arranged with respect to the front surface of the base plate 2392a is rotated around the engaging portion 4396d side as the axis, and the displacement unit 4395 is rotated toward the base plate 4392a side, and the side opposite to the engaging portion 4396d. Is displaced toward the base plate 4392a.

As a result, the edge portion of the first displacement member 4396 opposite to the engaging portion 4396d comes into contact with the outer first locking portion 4392e3 and the outer second locking portion 4392e4, and the outer first locking portion 4392e3. , And the outer second locking portion 4392e4 is pushed out toward the second wall portion 3392c to elastically deform the second wall portion 3392c.

As a result, a space for displacing the side of the displacement unit 4395 opposite to the engaging portion 4396d toward the base plate 4392a can be secured, and the displacement unit 4395 can be attached to the base unit 3391.

Further, as described above, the plate thickness of the main body portion 4396a in the front-rear direction is set smaller than the distance from the outer first locking portion 4392e3 and the outer second locking portion 4392e4 to the front surface of the base plate 2392a.

Therefore, when the displacement unit 4395 is pushed to the front surface of the base plate 2392a, the contact between the outer first locking portion 3392e3, the outer second locking portion 3392e4, and the first displacement member 4396 is released, and the outer first engaging portion is released. The elastic deformation of the stop portion 3392e3 and the outer second locking portion 3392e4 is returned (released).

According to the base unit 4390 configured as described above, one side (engaging portion 4396d side) of the displacement unit 4395 is engaged with the inside of the bent portion of the inner first engaging piece 4391d1, and the engaging side is engaged. As a fulcrum, the displacement unit 4395 can be arranged on the base unit 4391 by pushing the other side of the displacement unit 4395 toward the base plate 4392a side.

Therefore, when the displacement unit 3395 is arranged on the base unit 4391 as in the third embodiment, the outer first locking portion 3392e3, the outer second locking portion 3392e4, and the inner side formed on both sides of the displacement unit 3395. It is not necessary to elastically displace the first locking portion 3392d3 and the inner second locking portion 3392d4, respectively. That is, it is not necessary to push the locking portions 3392e3, 33992d3 and the like on both sides of the displacement unit 3395 while uniformly elastically deforming them. Therefore, the displacement unit 4395 can be easily arranged on the base unit 4391.

Further, since it is not necessary to elastically deform the inner first engaging piece 4391d, the rigidity of the inner first engaging piece 4391d is relatively high (compared to the inner first locking portion 4391d3 of the third embodiment). It is possible to prevent the inner first engaging piece 4391d from being deformed when the displacement unit 4395 is displaced.

In particular, by adopting a configuration in which the inner first engaging piece 4391d is not elastically deformed, it is possible not only to improve the holding performance (performance to prevent falling off) of the displacement unit 4395, but also to improve an illegal member (for example, a wire or a wire). By using the piano wire), it is possible to easily prevent the displacement unit 4395 from being illegally removed. In this case, the arrangement position of the inner first engaging piece 4391d is closer to the side where the illegal member is inserted than the arrangement position of the outer first locking portion 4392e3 and the outer second locking portion 4392e4. Is preferable.

Next, the base unit 5390 according to the fifth embodiment will be described with reference to FIGS. 43 to 46. In the first embodiment, the case where the displacement unit 395 is displaced by the operation of the operation unit 320 by the player has been described. However, in the base unit 5390 in the fifth embodiment, the displacement unit 5395 is moved by the drive device 5398. It is made displaceable, and the operation unit 320 is displaced by the displacement of the displacement unit 5395. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

First, the configuration of the base unit 5390 according to the fifth embodiment will be described with reference to FIGS. 43 and 44. FIG. 43 (a) is a front view of the base unit 5391 according to the fifth embodiment, and FIG. 43 (b) is a sectional view of the base unit 5391 taken along the line XLIIIb-XLIIIb of FIG. 43 (a). 44 (a) is a front view of the displacement unit 5395, FIG. 44 (b) is a rear view of the displacement unit 5395, and FIG. 44 (c) is the displacement of XLIVc-XLIVc of FIG. 44 (a). It is sectional drawing of the unit 5395.

As shown in FIGS. 43 and 44, the base unit 5390 according to the fifth embodiment has a base unit 5391, a displacement unit 5395 disposed on the base unit 5391, and a displacement unit 5395 with respect to the base unit 5391. It mainly includes a coil spring SP2 (see FIG. 45 (a)) and a drive device 5398 (see FIG. 46 (a)) arranged on the back side of the base unit 5391.

The base unit 5391 is formed in an outer shape corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300 described above, and is arranged inside the annular member 310. The base member 5392 is mainly provided with a leaf spring 393 disposed on the base member 5392, and a detection device 394 disposed on the base member 392.

The base member 5392 is formed on the base plate 5392a and its base plate 5392a in a semicircular shape, and is erected toward the front side (arrow F direction side) of the base plate 5392a and its first wall portion 392b and its first. A third wall portion formed in a semicircular shape coaxially with the center of the one wall portion 392b, formed in a ring shape coaxially with the first wall portion 392b, and erected from the base plate 392a toward the front side. The 392h, the spring engaging piece 392k and the convex portion 3392f1 projecting from the base plate 5392a toward the front side, and the first wall portion 5392b are located on the outer side in the radial direction and are formed through the base plate 5392a in a long hole shape. The sliding groove 5392a2 is mainly provided.

The insertion hole 5392a1 is a hole through which the shaft of the drive device 5398 (see FIG. 46 (a)) arranged on the back surface side of the base unit 5391 is inserted, and is formed at a position corresponding to the drive device 5398. In the drive device 5398, the pinion 5398a is mounted on the shaft through which the insertion hole 5392a1 is inserted, and the pinion 5398a is engaged with the tooth portion 5396k of the displacement unit 5395 described later to drive the drive device 5398 and the displacement unit. The 5395 can be displaced.

The sliding groove 5392a2 is a groove that guides the displacement of the displacement unit 5395, which will be described later, and the roller 5396j of the displacement unit 5395 is inserted into the sliding groove 5392a2. Further, the sliding groove 5392a2 is formed in an arc shape coaxial with the first wall portion 392b.

The displacement unit 5395 mainly includes a first displacement member 5396 which is formed in a substantially semi-circular shape as a whole when viewed from the front, and a second displacement member 397 which is pivotally supported by the first displacement member 5396.

The first displacement member 5396 includes a main body portion 396a formed in an arc shape, a spring engaging portion 396c formed in a substantially C shape in front view on one end side of the main body portion 396a extending in an arc shape, and a circle. A plurality of ridges 5396b projecting toward the center of the arc of the main body 396a on the other end side of the main body 396a extending in an arc shape and a plurality of rows along the outer peripheral edge of the main body 396a are provided. The tooth portion 5396k to be formed, the detection piece 396f projecting radially outward from the outer peripheral edge portion of the main body portion 396a, and the shaft portion 396h projecting in a columnar shape on the back surface of the main body portion 396a. Mainly prepared.

Further, on the first surface 396a1 of the main body portion 396a, a rotating shaft portion 5396i projecting in a columnar shape from two positions different in the circumferential direction toward the back side, and a state in which the rotating shaft portion 5396i can rotate around the rotating shaft portion 5396i. A ring-shaped roller 5396j arranged in the above direction and a hook portion 5396m projecting from two locations in the circumferential direction different from the rotating shaft portion 5396i toward the back surface side in a hook shape are provided.

The rotating shaft portion 5396i is a shaft that holds the roller 5396j, is set to an outer diameter smaller than the inner diameter of the roller 5396j, and is set to have a longer axial length than the roller 5396j. Further, the rotating shaft portion 5396i is formed with a hole for screwing a screw in the center. As a result, the roller 5396j is arranged around the rotating shaft portion 5396i, and then the screw is screwed into the rotating shaft portion 5396i, so that the roller 5396j is arranged on the rotating shaft portion 5396i in a rotatable state.

The roller 5396j is a portion arranged inside the sliding groove 5392a2 of the base plate 5392a as described above, and the outer diameter is set to be smaller than the width dimension of the sliding groove 5392a2. Further, each roller 5396j arranged on the two rotating shaft portions 5396i has a sliding groove at an angle θ1 (see FIG. 44 (b)) that is separated in the circumferential direction about the center of the arc of the main body portion 396a. It is set smaller than the angle θ2 (see FIG. 43A) extending in the circumferential direction about the center of the arc of 5392a2. As a result, the two rollers 5396j can be displaced along the sliding groove 5392a2, the difference between the angle θ1 and the angle θ2, and the displacement unit 5395 can be rotationally displaced.

The projecting portion 5396b is formed on the displacement locus of the engaging piece 342b of the operating unit 320 (see FIG. 15). Further, an engaging hole 5396b1 penetrating in the front-rear direction (arrow FB direction) is formed in the projecting portion 5396b.

The engagement hole 5396b1 is a hole into which the engagement piece 342b of the operation unit 320 is inserted, and when the displacement unit 5395 is arranged at the initial biasing position, the engagement piece of the operation unit 320 arranged at the initial position is inserted. It is formed at a position corresponding to 342b (see FIG. 16B). Therefore, in the fifth embodiment, when the operation unit 320 and the base unit 5390 are assembled, the engagement piece 342b is inserted into the engagement hole 5396b1.

Further, the size of the engaging hole 5396b1 about the center of the main body 396a in the circumferential direction is set to be substantially the same as the size of the engaging piece 342b about the center of the main body 396a in the circumferential direction. As a result, the displacement unit 5395 and the operation unit 320 can always be interlocked with each other.

A plurality of (11 in this embodiment) rows of tooth portions 5396k are arranged along the radial outer edge of the main body portion 396a from the other end of the main body portion 396a extending in an arc shape toward one end side. Will be set up. The tooth portion 5396k is a portion that meshes with the pinion 5398a arranged on the shaft of the drive device 5398 arranged in the base unit 5391. As a result, the displacement unit 5395 is displaced when the pinion 5398a is rotated by driving the drive device 5398.

The two hook portions 5396m are projected from the main body portion 396a with their tips bent in a substantially L shape. Further, the two hook portions 5396m are formed between the two rotating shaft portions 5396i arranged at different positions in the circumferential direction about the center of the arc of the main body portion 396a, and are formed from the center of the arc of the main body portion 396a. It is projected at different positions in the radial direction.

Further, the two hook portions 5396 m are bent in opposite directions in the radial direction from the center of the arc of the main body portion 396a, and the one hook portion 5396 m that bends inward in the radial direction is the above-mentioned slide. The other hook portion 5396m, which is projected from a position along the inner diameter side edge of the moving groove 5392a2 and bends outward in the radial direction, is projected from a position along the outer diameter side edge of the sliding groove 5392a2. (See FIG. 46 (e)).

Further, the hook portion 5396m is a member that engages with the base plate 5392a to prevent the displacement unit 5395 from falling off to the front side, and the bent portion at the tip of the hook portion 5396m is a base around the sliding groove 5392a2. It is set at a position where it overlaps with the plate 5392a in the front-rear direction, and the distance between the bent portions and the first surface 396a1 is set to be larger than the plate thickness of the base plate 5392a.

Further, the hook portion 5396m is formed so that the projecting tip surface is inclined toward the front side toward the bending tip side. As a result, when the displacement unit 5395 is arranged in the base unit 5391, the hook portion 5396 m in which the bent portion at the tip overlaps with the base plate 5392a around the sliding groove 5392a2 in the front-rear direction is formed on the protruding tip surface of the hook portion 5396 m. Can be elastically deformed inside the sliding groove 5392a2 by utilizing the inclination of. Further, by arranging the bent portion of the hook portion 5396 m beyond the back surface of the base plate 5392a, the elastic deformation of the hook portion 5396 m is restored and the bent portion at the tip of the hook portion 5396 m is placed on the base around the sliding groove 5392a2. It can be arranged at a position where it overlaps with the plate 5392a in the front-rear direction. That is, the hook portion 5396m allows the displacement unit 5935 to be arranged in the base unit 5391, and can prevent the displacement unit 5935 from falling off from the base unit 5391.

Further, the two hook portions 5396m are set so that the distance between the outer diameters of the main body portion 396a side (base end side) in the radial direction facing each other is smaller than the outer diameter of the roller 5396j described above. As a result, when the displacement unit 5395 is displaced with respect to the base plate 5392a, it is possible to prevent the hook portion 5396m arranged inside the sliding groove 5392a2 from being rubbed against the inner surface of the sliding groove 5392a2 and damaged.

According to the base unit 5390 configured as described above, the first displacement member 5396 (displacement unit 5395) configured as a rack is arranged in the base unit 5391 only by engaging the hook portion 5396 m with the sliding groove 5392a2. Will be set up. That is, no operation after disposing the displacement unit 5395 on the base unit 5391 (for example, an operation of fastening the screws) is required. Therefore, the work of the operator who assembles the base unit 5390 can be simplified.

Further, the sliding groove 5392a2 can be provided with (combined with) a role as a guide portion for guiding the displacement of the displacement unit 5395 and a role as an engaged portion for engaging the hook portion 5396 m. Therefore, it is not necessary to separately form the guide portion for guiding the displacement unit 5395 and the engaged portion for engaging the hook portion 5396 m on the base plate 5392a, and other members are arranged on the base plate 5392a. It is easy to secure space.

Further, as in the case of the first embodiment, the inner first engaging piece 392d1 and the outer first engaging piece 392e1 are provided on the base plate 392a, and the inner first engaging piece 392d1 and the outer first engaging piece 392e1 are provided. Is engaged with the displacement unit 395 (first displacement member 396), of the outer edges of the first displacement member 396, the inner first engaging piece 392d1 or the outer first engaging piece when the displacement unit 395 is displaced. The tooth portion 5396k cannot be provided in the portion facing (interfering with) the 392e1.

On the other hand, according to the fifth embodiment, since the hook portion 5396m is projected from the back surface side of the first displacement member 5396 and the hook portion 5396m is engaged with the sliding groove 5392a2, the first displacement member 5396 It is possible to easily secure a region where the tooth portion 5396k can be arranged on the outer edge of the.

Next, the displacement of the displacement unit 5395 in the fifth embodiment will be described with reference to FIGS. 45 and 46. 45 (a) to 45 (c) are front views of the base unit 5390, and FIGS. 46 (a) to 46 (c) are the base unit 5390 in the XLVIa-XLVIa line of FIG. 45 (a). It is a cross-sectional view, and FIG. 46 (d) is a cross-sectional view of the base unit 5390 in the XLVId-XLVId line of FIG. 46 (a). FIG. 46 (e) is a cross-sectional view of the base unit 5390 in the XLVIe-XLVIe line of FIG. 46 (a).

In FIGS. 45 (a) to 45 (c) and 46 (a) to 46 (c), the outer shape of the engaging piece 342b (see FIG. 16 (b)) of the operation unit 320 is shown by a chain line. To. Further, in FIGS. 45 (a) and 46 (a), the base unit 5390 in the state of being arranged at the initial biasing position is shown, and in FIGS. 45 (c) and 46 (c), the terminal interlocking position is shown. The base unit 5390 in the state of being arranged in is illustrated, and in FIGS. 45 (b) and 46 (b), the base unit 5390 in the state of being arranged at an intermediate position between the initial biasing position and the terminal interlocking position is shown. Will be done.

As shown in FIGS. 45 and 46, the displacement unit 5395 is driven by the pinion 5398a, which is rotated by the drive of the drive device 5398, via the tooth portion 5396k. In the fifth embodiment, the displacement unit 5395 is displaced from the initial biasing position to the terminal interlocking position side by rotating the pinion 5398a counterclockwise in the front view. On the other hand, when the pinion 5398a is rotated clockwise in the front view, the displacement unit 5395 is displaced from the terminal interlocking position to the initial biasing position side.

In the initial urging position, the roller 5396j arranged on one end side of the main body portion 396a of the two rollers 5396j is arranged at a position adjacent to the end portion on the one end side in the circumferential direction of the sliding groove 5392a2. .. Further, at the interlocking terminal position, the roller 5396j arranged on the other end side of the main body portion 396a of the two rollers 5396j is arranged at a position adjacent to the end portion on the other end side in the circumferential direction of the sliding groove 5392a2. To. As a result, it is possible to prevent the displacement unit 5395 from being displaced beyond the initial biasing position or the terminal interlocking position.

Further, the rotation angle of the displacement unit 5395 from the initial urging position to the end interlocking position is set to be the same as the rotation angle of the operation unit 320 from the initial position to the end position. As described above, since the engagement piece 342b of the operation unit 320 arranged at the initial position is inserted into the engagement hole 5396b1 of the displacement unit 5395 arranged at the initial biasing position, the displacement unit 5395 reaches the end interlocking position. When rotated, the operating unit 320 is rotated to the terminal position.

Next, the base unit 6390 according to the sixth embodiment will be described with reference to FIG. 47. In the first embodiment, the case where the side of the regulation piece 392f connected to the base plate 392a is set in the direction in which the displacement unit 395 is urged by the coil spring SP2 has been described, but in the sixth embodiment, the regulation is performed. The side of the piece 6392f connected to the base plate 6392a is set in the direction opposite to the direction in which the displacement unit 395 is urged by the coil spring SP2. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

47 (a) is a front view of the base unit 6391 according to the sixth embodiment, FIG. 47 (b) is a front view of the base unit 6390, and FIG. 47 (c) is a front view of FIG. 47 (b). It is a sectional drawing of the base unit 6390 in the XLVIIc-XLVIIc line.

As shown in FIG. 47, the base unit 6390 according to the sixth embodiment includes a base unit 6391, a displacement unit 395 disposed on the base unit 6391, and a coil for urging the displacement unit 395 with respect to the base unit 391. It mainly includes a spring SP2.

The base unit 6391 is formed in an outer shape corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and is arranged inside the annular member 310. It mainly includes a base member 392, a leaf spring 393 disposed on the base member 6392, and a detection device 394 disposed on the base member 392.

The base member 6392 is formed on the base plate 6392a and its base plate 6392a in a semicircular shape, and is erected toward the front side (arrow F direction side) of the base plate 392a and its first wall portion 392b and its first. A second wall portion 392c formed in a semicircular shape coaxial with the center of the first wall portion 392b and erected from the base plate 392a toward the front side, a first wall portion 392b, and a second wall portion 392c. A third wall portion 392h formed in a ring shape coaxial with the base plate 392a and erected toward the front side from the base plate 392a, and a spring engaging piece 392k projecting from the base plate 392a toward the front side. It mainly includes an inner first engaging piece 392d1, an inner second engaging piece 392d2, and a regulating piece 6392f formed inside the base plate 392a cut out in a substantially U-shape in the front view.

The restricting piece 6392f is a member that regulates the displacement of the displacement unit 395 to one side, which will be described later, and is formed between the first wall portion 392b and the second wall portion 392c in a front view. Further, the regulation piece 6392f is formed at a position overlapping the displacement locus of the displacement unit 395 arranged between the first wall portion 392b and the second wall portion 392c.

The regulation piece 6392f is formed by cutting out the base plate 6392a in a substantially U shape when viewed from the front, and one end side connected to the base plate 6392a is in the direction in which the displacement unit 395 is urged by the coil spring SP2. Set in the opposite direction. Further, the regulation piece 6392f is provided with a convex portion 392f1 projecting toward the front side (displacement unit 395 side) at the other end, and the convex portion 392f1 is brought into contact with the displacement unit 395 to bring the convex portion 392f1 into contact with the displacement unit 395 on one side of the displacement unit 395. Displacement to can be regulated.

According to the regulation piece 6392f in the sixth embodiment, when the displacement unit 395 is displaced from the terminal interlocking position side to the initial biasing position side, the second displacement member 397 is brought into contact with the convex portion 392f1 of the regulation piece 6392f. Therefore, the displacement unit 395 can be maintained in the initial biasing position.

The regulation piece 6392f is regulated while the displacement unit 395 is displaced to the initial biasing position side because one end side connected to the base plate 6392a is set in the direction opposite to the direction in which the displacement unit 395 is urged by the coil spring SP2. The force when the piece 6392f comes into contact with the piece 6392f can act as a force in the direction of pulling the regulation piece 6392f in the extending direction.

Therefore, like the regulation piece 392f in the first embodiment, when the displacement unit 395 comes into contact with the regulation piece 6392f, the regulation piece 6392f is elastically deformed into a posture of bending with its base side (connecting portion with the base plate 392a) as a fulcrum. Can be suppressed. That is, the burden on the base side of the regulation piece 6392f can be reduced, and the durability can be improved.

Further, in the state where the convex portion 392f1 of the regulation piece 6392f is brought into contact with the second displacement member 397 and the displacement unit 395 is maintained at the initial biasing position, in the case of the first embodiment, the base side (base plate 392a). There is a risk that the regulation piece 392f will have a habit of bending with the fulcrum as the fulcrum. When such a habit is formed, the relative position of the regulation piece 392f (convex portion 392f1) with respect to the second displacement member 397 changes, and the second displacement member 397 cannot be brought into contact with the convex portion 392f1 of the regulation piece 6392f. Alternatively, the contact causes the base of the restricting piece 6392f to bend more. On the other hand, the posture of the regulation piece 392f can be maintained in the initial posture by being pulled and deformed as in the sixth embodiment.

When the displacement unit 395 is arranged on the base unit 6391, the regulation piece 6392f is elastically deformed to the back side in the same manner as the regulation piece 392f in the first embodiment, and the displacement unit 395 is arranged on the base unit 6391. it can. In this case, the position of the convex portion 392f1 with respect to the second displacement member 397 is the same as in the case of the first embodiment. Therefore, also in the sixth embodiment, when the displacement unit 395 is arranged on the base unit 6391, it is convex. By using (contacting) the portion 3921f1, it is possible to prevent the second displacement member 397 from falling off (pulling out from the shaft portion 396h).

Next, the base unit 7390 according to the seventh embodiment will be described with reference to FIG. 48. In the first embodiment, the case where the second side wall 397f of the second displacement member 397 is formed on a flat surface has been described, but in the seventh embodiment, the recess 7397f1 is formed in the second side wall 7397f of the second displacement member 7397. It is recessed. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 48 is a cross-sectional schematic view of the base unit 7390 according to the seventh embodiment. Note that FIG. 48 corresponds to the cross-sectional view of the base unit 390 in FIG. 33 (a).

As shown in FIG. 48, the base unit 7390 according to the seventh embodiment has a base unit 391, a displacement unit 7395 disposed on the base unit 7391, and a coil for urging the displacement unit 395 with respect to the base unit 391. It mainly includes a spring SP2.

The base unit 7391 is formed in an outer shape corresponding to the inner peripheral edge shape on the back surface side (arrow B direction side) of the annular member 310 (see FIG. 15) of the displacement unit 300, and is arranged inside the annular member 310. It mainly includes a base member 7392, a leaf spring 393 disposed on the base member 7392, and a detection device 394 disposed on the base member 392.

The base member 7392 is formed on the base plate 392a and the base plate 392a in a semicircular shape, and is erected toward the front side (arrow F direction side) of the base plate 392a and the first wall portion 392b and the first wall portion 392b thereof. A second wall portion 392c formed in a semicircular shape coaxial with the center of the first wall portion 392b and erected from the base plate 392a toward the front side, a first wall portion 392b, and a second wall portion 392c. A third wall portion 392h formed in a ring shape coaxial with the base plate 392a and erected toward the front side from the base plate 392a, and a spring engaging piece 392k projecting from the base plate 392a toward the front side. It mainly includes an inner first engaging piece 392d1, an inner second engaging piece 392d2, and a regulating piece 7392f formed inside the base plate 392a cut out in a substantially U-shape in the front view.

The restricting piece 7392f is a member that regulates the displacement of the displacement unit 395 to one side, which will be described later, and is formed between the first wall portion 392b and the second wall portion 392c in a front view. Further, the regulation piece 7392f is formed at a position overlapping the displacement locus of the displacement unit 395 arranged between the first wall portion 392b and the second wall portion 392c.

The regulation piece 7392f is formed by cutting out the base plate 392a in a substantially U shape when viewed from the front, and one end thereof is connected to the base plate 392a. Further, the regulation piece 7392f is provided with a convex portion 7392f1 projecting toward the front side (displacement unit 7395 side) at the other end, and the convex portion 7392f1 is brought into contact with the displacement unit 7395 to bring the convex portion 7392f1 into contact with the displacement unit 7395 to one side of the displacement unit 7395. Displacement to can be regulated.

Further, the convex portion 7392f1 includes a second convex portion 7392f2 having a triangular cross section in which the contact surface with the displacement unit 7395 projects toward the contact surface (second side wall 7397f) side of the displacement unit 7395. The second convex portion 7392f2 has a triangular cross section formed along the plane of the base plate 7392a over the entire contact surface of the convex portion 7391f with the displacement unit 7395.

The displacement unit 7395 mainly includes a first displacement member 396 formed in a substantially semicircular shape in the front view, and a second displacement member 7397 axially supported by the first displacement member 396.

The first displacement member 396 includes a main body portion 396a formed in an arc shape, a spring engaging portion 396c formed in a substantially C shape in front view on one end side of the main body portion 396a extending in an arc shape, and a circle. A protruding portion 396b projecting toward the center of the arc of the main body 396a on the other end side of the main body 396a extending in an arc shape, and an engaging portion 396d projecting along the inner edge of the main body 396a. The outer concave portion 396e formed by cutting out the outer peripheral edge portion of the main body portion 396a, and the detection piece 396f projecting radially outward from the outer peripheral side edge portion of the main body portion 396a. It mainly includes a shaft portion 396h projecting in a columnar shape on the back surface of the main body portion 396a.

Similar to the second displacement member 397 in the first embodiment, the second displacement member 7397 is formed in a substantially triangular shape as a whole in the front view. Further, the second displacement member 7397 includes a shaft support hole 397a penetrating in the front-rear direction. In the second displacement member 7397, as in the case of the second displacement member 397 in the first embodiment, the first corner portion 397b, the second corner portion 397c, and the third corner portion 397d are attached to the tip portions of each of the three locations. It will be described with reference to.

The second side wall 7397f of the side wall connecting the first corner portion 397b and the third corner portion 397d is brought into contact with the regulation piece 7392f of the base plate 7392a when the displacement unit 7395 is arranged at the initial biasing position. It is a surface, and includes a recess 7397f1 in which the cross-sectional shape of the side surface thereof is recessed in a triangular shape corresponding to the cross-sectional shape of the second convex portion 7392f2 of the regulation piece 7392f.

As a result, when the displacement unit 7395 is arranged at the initial urging position and the displacement unit 7395 is urged to the regulation piece 7392f side by the coil spring SP2, the second convex portion 7392f2 is inserted inside the concave portion 7397f1. The regulation piece 7392f and the second displacement member 7397 can be engaged with each other. Therefore, in the state where the displacement unit 7395 is arranged at the initial biasing position, the regulation piece 7392f is elastically deformed to the back side (arrow B direction side) by using an illegal member (for example, a wire or a piano wire). , It is possible to prevent the regulation of the displacement unit 7395 by the regulation piece 7392f from being illegally lifted. As a result, it is possible to prevent the displacement unit 7395 from being displaced to the positioning position and illegally removing the displacement unit 7395 from the base plate 392a.

Further, by engaging the regulation piece 7392f and the second displacement member 7397, the displacement unit 7395 is maintained at the initial fulcrum position by the urging force of the coil spring SP2, and the base side (base plate 392a) is maintained. It is possible to prevent the regulation piece 7392f from having a habit of being in a bent posture with the connecting portion) as a fulcrum.

Next, the operation unit 8320 according to the eighth embodiment will be described with reference to FIGS. 49 to 53. In the first embodiment, the case where the guided member 344 is formed in a perfect circular ring shape has been described, but in the operation unit 8320 in the eighth embodiment, the guided member 8345 is formed in an elliptical ring shape. .. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

First, with reference to FIG. 49, the overall configuration of the operation unit 8320 and the guide unit 8350 in the eighth embodiment will be described. FIG. 49 (a) is an exploded perspective front view of the operation unit 8320 according to the eighth embodiment, and FIG. 49 (b) is a cross-sectional view of the operation unit 8320 and the guide unit 8350. The cross-sectional view of FIG. 49 (b) corresponds to the cross-sectional view of the operation unit 320 and the guide unit 350 in FIG. 22 (d).

As shown in FIG. 49, the operation unit 8320 according to the eighth embodiment includes a gripping unit 330 arranged on the front side and a rotating unit 8340 connected to the back side (arrow B direction side) of the gripping unit 330. , Equipped with.

The rotating unit 8340 is arranged on the gripping unit 330 side and is connected to the gripping unit 330 on the front side member 341, the back side member 342 arranged on the back side of the front side member 341, and the back side member thereof. A shaft member 343 projecting radially outward from 342, an annular guided member 344 arranged so as to surround the shaft member 343, and a guided member 8345. Mainly prepared.

In the eighth embodiment, the guided member 344 is arranged on one side of the shaft member 343 projecting from two locations facing outward in the radial direction from the back surface side member 342, and the other side of the shaft member 343. The guided member 8345 is arranged in the.

The guided member 8345 has an elliptical outer shape and a perfect circular inner shape. Further, the guided member 8345 is arranged in a state of being fastened and fixed to the shaft member 343, and is arranged in a state of being non-rotatable about the shaft member 343. Further, the guided member 8345 is arranged inside the guide groove 8351 of the guide groove 351 and the guide groove 8351 formed in the guide unit 8350 described later. A guided member 344 is arranged inside the guide groove 351.

The guide unit 8350 is arranged on the front side of the rotating unit 340 to regulate the displacement of the rotating unit 340 to the front side, and is arranged on the back side of the rotating unit 340 and is arranged on the back side of the rotating unit 340. It is provided with a rear side guide unit 370 that regulates displacement to the rear side.

Further, the guide unit 8350 is recessed by a connecting surface of the recessed bottom surface of the recessed portion 362a2 and the inner peripheral surface of the first cylindrical portion 362a, and the first portion 371 and the second portion 372 of the rear side guide unit 370. A guide groove 351 and a guide groove 8352 that partially surround the setting portion 362a2 are formed. The guide groove 351 and the guide groove 8352 are formed at opposite positions of the guide unit 8350, respectively.

As shown in FIG. 49B, the guide groove 8352 extends in the circumferential direction of the second annular member 362 of the front side guide unit 360 and the first portion 371 of the back side guide unit 370. The portion is formed in a shape that is inclined toward the back surface side.

Further, the guide groove 8352 includes a first guide surface 351a and a second guide surface 351b which are guide surfaces (wall surfaces for restricting the movement of the guided member 8344) of the guided member 8344 on the second ring member 362 side. The third guide surface 8351c and the fourth guide surface 8351d, which are the guide surfaces of the guided member 8344 on the back side guide unit 370 side, the second ring member 362 of the front side guide unit 360, and the back side guide. A first end portion 351e and a second end portion 351f, which are end portions in the circumferential direction of the first portion 371 of the unit 370, are mainly provided.

The first guide surface 351a and the third guide surface 8351c are formed so as to face each other. Further, the distance between the first guide surface 351a and the third guide surface 8351c facing each other is set to be larger than the external dimensions of the guided member 8344 in the lateral direction. As a result, the guided member 8344 can be moved by the first guide surface 351a and the third guide surface 8351c while restricting the moving direction. In the following description, the moving region of the guided member 344 formed between the first guide surface 351a and the third guide surface 8351c facing each other will be referred to as a "first guide region".

Further, the first guide surface 351a and the third guide surface 8351c extend in the circumferential direction of the second ring member 362 and the first portion 371, and are formed as a wall surface inclined in the front-rear direction. Therefore, the guided member 8344 that moves in the first guide region is moved in the front-rear direction of the guide unit 350 while being moved in the circumferential direction of the second ring member 362 and the first portion 371. Therefore, the operation unit 320 is displaced so as to rotate about the center of the erection wall 341b of the rotation unit 340 and move in the axial direction of the erection wall 341b.

When no force is input to the operation unit 320 from the outside of the slot machine 10 (see FIG. 1) (the player does not operate the operation unit 320), the rotation unit 340 is directed toward the front side by the coil spring SP1 described above. By being urged, the guided member 344 is guided along the first guide surface 351a to the first end portion 351e. As a result, in the initial position, the guided member 344 is maintained at a position where it abuts on the first end portion 351e.

The second guide surface 351b and the fourth guide surface 8351d are formed so as to face each other. Further, the second guide surface 351b is extended in a direction in which the guide surface is parallel to the horizontal direction. On the other hand, the fourth guide surface 8351d is formed as a guide surface toward the front side as it approaches the connecting portion with the first guide surface 351a in the circumferential direction of the second ring member 362 and the first portion 371.

The second guide surface 351b and the fourth guide surface 8351d are connected to the end portion of the first guide region (first guide surface 351a and third guide surface 351c) on the back surface side (arrow B direction side). .. As a result, the guided member 8344 that has moved the first guide region to the back side (arrow B direction side) can be received between the second guide surface 351b and the fourth guide surface 8351d.

Further, the second guide surface 351b and the fourth guide surface 8351d are formed so as to face each other. Further, the minimum distance between the second guide surface 351b and the fourth guide surface 8351d is set to be larger than the external dimensions of the guided member 8344 in the lateral direction. As a result, the guided member 8344 can be moved by the second guide surface 351b and the fourth guide surface 8351d while restricting the moving direction. In the following description, the moving region of the guided member 8344 formed between the second guide surface 351b and the fourth guide surface 8351d facing each other will be referred to as a "second guide region".

The second guide surface 351b is extended in a direction in which the guide surface is parallel to the horizontal direction, and the fourth guide surface 8351d is the first guide in the circumferential direction of the second annular member 362 and the first part 371. It is formed as a guide surface toward the front side as it approaches the connecting portion with the surface 351a. Therefore, when the guided member 8344 moves on the second guide surface 351b side (front side) of the second guide region, the guided member 8344 moves in the circumferential direction of the second ring member 362 and the first part 371. The guided member 8344 is moved in the front-rear direction (arrow FB direction) with respect to the guide unit 350 by the amount of inclination of the second guide surface in the front-rear direction.

Further, when the guided member 8344 moves on the fourth guide surface 8351d side (rear side) of the second guide region, the guided member 8344 moves in the circumferential direction of the second ring member 362 and the first part 371. Moved to. In this case, since the guide surface of the fourth guide surface 8351d extends parallel to the horizontal direction, the guided member 8344 is not displaced in the front-rear direction (arrow FB direction) with respect to the guide unit 350. To.

Further, the connecting portion with the third guide surface 8351c and the fourth guide surface 8351d is provided with an accommodating portion 8351 m recessed on the back side guide unit 370 side along the guide surface of the third guide surface 8351c. The accommodating portion 8351m is an area for receiving the guided member 8344 guided in the first guide area and rotating the guided member 8344 in order to allow the guided member 8344 to enter the second guided area. The displacement of the guided member 8344 from the first guide region to the second guide region will be described later.

Next, the operation of the operation unit 8320 in the eighth embodiment will be described with reference to FIGS. 50 to 53. 50 (a), 51 (a), 52 (a) and 53 (a) are front views of the operation unit 8320 and the guide unit 8350, and FIGS. 50 (b) and 51 (b). 52 (b) and FIG. 53 (b) are side views of the operation unit 8320 and the guide unit 8350, which are 50 (c), 51 (c), 52 (c) and 53. (C) is a cross-sectional schematic view of the operation unit 8320 and the guide unit 8350.

In addition, in FIGS. 50 to 53, the transition state of the operation unit 8320 with respect to the guide unit 8350 is shown in order, and in FIGS. 50 (a) to 50 (c), the state in which the operation unit 8320 is arranged at the initial position is shown. 51 (a) to 51 (c) show the state in which the operation unit 8320 is arranged at the first position, and FIGS. 52 (a) to 52 (c) show the operation unit 8320 arranged at the first position. The state in which the operation unit 8320 is rotated with respect to the axial direction of the guide unit 8350 is shown, and FIGS. 53 (a) to 53 (b) show the state in which the operation unit 8320 is arranged at the terminal position. ..

As shown in FIG. 50, when the operation unit 8320 is arranged at the initial position, the circular portions 331a of the left and right cover members 331 and 332 of the gripping unit 330 of the operation unit 8320 and the center lines of the 331b are in the horizontal direction. Is placed parallel to. Further, the guided member 8344 arranged inside the guide groove 8351 is arranged on the first end portion 351e side of the first guide region.

Next, the operation unit 8320 is operated by the player, and the center lines of the circular portions 331a and 332a of the left and right cover members 331 and 332 of the gripping unit 330 are rotated clockwise in the front view, or the operation unit 320. Is operated by the player and the gripping unit 330 is pushed toward the back side (arrow B direction side), the guided member 334 of the rotating unit 340 fastened to the gripping unit 330 moves in the first guide region of the guide groove 351. To do.

As a result, as shown in FIG. 51, the gripping unit 330 is rotated clockwise in the front view. Further, the guided member 8344 disposed inside the guide groove 8351 slides in the first guide region and is arranged in the connecting portion (inside the accommodating portion 8351 m) between the first guide region and the second guide region. Will be done.

Third, when the operating unit 8320 is operated by the player and the gripping unit 330 is displaced in the extending direction of the center lines of the circular portions 331a and 332a of the left and right cover members 331 and 332 of the gripping unit 330, the gripping unit 330 is gripped. The guided member 8344 is rotated inside the guide groove 7244 with the displacement of the unit 330, and is arranged in a direction in which the longitudinal direction of the guided member 8344 is parallel to the extending direction of the second guide region. As a result, the guided member 8344 can be slidable in the second guide region.

Further, in the present embodiment, the displacement direction of the center lines of the circular portions 331a and 332a of the left and right cover members 331 and 332 of the gripping unit 330 of the operation unit 8320 in the extending direction is set upward. As a result, when the player stops the operation of the operation unit 8320 in the middle, the operation unit 8320 is moved to the first position (FIGS. 41 (a) to 41 (c)) by utilizing the load of the gripping unit 330. Can be displaced to position).

Finally, when the operating unit 8320 is further operated by the player and the gripping unit 330 is rotated clockwise in the front view, the guided member 8334 of the rotating unit 8340 to be fastened to the gripping unit 330 is formed in the guide groove 351. The second guide region is moved and arranged at a position where it comes into contact with the second end portion 351f.

In the second guide region, unlike the first guide region, the guide surface on the back side of the guide groove 351 to which the guided member 344 is guided extends in parallel with the horizontal direction, so that the player can hold the grip unit 330. When the guide unit side (back side (arrow B direction side)) is pushed, the guided member 344 does not move in the second guide area, and the guided member 344 stays in the connecting portion with the first guide area. It is considered to be in a state.

According to the operation unit 8320 of the eighth embodiment displaced as described above, the operation when the guided member 8344 moves in the first guide area and the operation when the guided member 8344 moves in the second guide area. An operation is required when the guided member 8344 makes the second guide area movable between the operations. As a result, it is possible to prevent the operation unit 8320 from being inadvertently displaced to the terminal position.

Next, the operation unit 320 and the guide unit 9350 according to the ninth embodiment will be described with reference to FIG. 54. In the first embodiment, the case where the guided member 344 moves between the first guide area and the second guide area has been described, but in the ninth embodiment, the guided member 344 moves between the first guide area and the second guide area. And 3 guide areas. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

54 (a) to 54 (c) are cross-sectional schematic views of the operation unit 320 and the guide unit 9350 according to the ninth embodiment. It should be noted that FIGS. 54 (a) to 54 (c) correspond to the cross sections of the operation unit 320 and the guide unit 9350 in FIG. 22 (d).

As shown in FIG. 54, the guide groove 9351 formed in the guide unit 9350 in the ninth embodiment includes the second annular member 362 of the front side guide unit 360 and the first part 371 of the back side guide unit 370. A portion extending in the circumferential direction, a portion extending in the axial direction (arrow FB direction) of the front side guide unit 360 and the rear side guide unit 370, and a portion extending in the circumferential direction on the front side. It includes a portion formed in a shape inclined toward.

Further, the guide groove 9351 includes a first guide surface 351a and a second guide surface 351b that serve as a guide surface (a wall surface that regulates the movement of the guided member 344) of the guided member 344 on the second ring member 362 side. , The third guide surface 351c and the fourth guide surface 351d which are the guide surfaces of the guided member 344 on the back side guide unit 370 side, the second ring member 362 of the front side guide unit 360, and the back side guide. From the connecting portion of the first end portion 351e and the second end portion 351f, the third guide surface 351c, and the fourth guide surface 351d, which are the peripheral ends of the first portion 371 of the unit 370, to the back side. It mainly includes a back-side recessed portion 9351k that is recessed toward the rear.

The back surface side recessed portion 9351k is formed with a groove width larger than the outer shape of the guided member 344, and extends toward the back surface side. Further, the back-side recessed portion 9351k is capable of moving the guided member 344 in the extending direction thereof, and the moving area thereof will be referred to as a "third guide area". The third guide region is formed so as to be connected to the connecting portion between the first guide region and the second guide region, and can accept the guided member 344 moving in the first guide region or the second guide region. To.

As a result, as shown in FIG. 54B, when the operating unit 320 is operated by the player and the gripping unit 330 is pushed toward the back side (arrow B direction side), the rotating unit 340 is fastened to the gripping unit 330. Guided member 334 moves in the first guide region of the guide groove 351. In this case, the guided member 344 is guided along the third guide surface 351c on the back side, and is inserted inside the recessed portion 9351k on the back side at the connecting portion between the first guide area and the third guide area. To. As a result, the guided member 344 that moves in the first guide region can be moved to the third guide region.

On the other hand, as shown in FIG. 54 (c), the operation unit 320 is operated by the player, and the center lines of the circular portions 331a and 332a of the left and right cover members 331 and 332 of the gripping unit 330 are rotated clockwise in the front view. When rotated, the guided member 334 of the rotating unit 340 fastened to the gripping unit 330 moves in the first guide region of the guide groove 351. In this case, the guided member 344 is guided along the first guide surface 351a on the front side, and is guided between the second guide surface 351b and the fourth guide surface 351d. As a result, the guided member 344 that moves in the first guide region can be moved to the second guide region.

According to the guide unit 9350 configured as described above, the displacement of the operation unit 320 can be changed by the difference in the operation direction of the operation unit 320 (selection of push operation or rotation operation). As a result, a plurality of operation patterns can be formed to make it easier for the player to enjoy the hobby.

A sensor device for detecting the displacement position of the operation unit 320 is provided, and whether the operation unit 320 is displaced to the second guide area (rotation operation is performed) or displaced to the third guide area (push operation is performed). It may be configured to detect at least.

Specifically, a detection unit (detection piece) is formed in the operation unit 320, and a sensor device that detects the detection unit (for example, an irradiation unit that irradiates light and light emitted from the irradiation unit can be received. (A device that detects the displacement position of the operation unit 320 based on the fact that the light receiving unit is provided so as to face each other and the detected portion of the operation unit 320 is arranged between them to block light). There are two locations, one on the displacement locus of the detected part when the operation unit 320 is displaced to the second guide area, and the other on the displacement locus of the detected part when the operation unit 320 is displaced to the third guide area. The configuration in which each is arranged is exemplified.

As a result, even with one operation unit 320, two types of inputs can be formed by the difference in the operation direction of the operation unit 320 (selection of push operation or rotation operation). Therefore, it is not necessary to provide the same number of operators (operation units 320) as the types of inputs (two in this embodiment), and the component cost can be reduced. Further, since a plurality of inputs (two types in the present embodiment) can be formed by one operator (operation unit 320), the operability of the player is improved (that is, it is not necessary to take the hand off the grip unit 330). It can be done) and it can be easily given to the player.

Next, the operation unit 10320 according to the tenth embodiment will be described with reference to FIGS. 55 to 57. In the first embodiment, the case where the gripping unit 330 and the rotating unit 340 are interlocked has been described, but in the tenth embodiment, the interlocking between the gripping unit 10330 and the rotating unit 340 can be released. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

First, the overall configuration of the operation unit 10320 will be described with reference to FIGS. 55 and 56. FIG. 55 (a) is a side view of the operation unit 10320 according to the tenth embodiment, and FIG. 55 (b) is a schematic cross-sectional view of the operation unit 10320 in the LVb-LVb line of FIG. 55 (a). FIG. 56 is an exploded perspective view of the gripping unit 10330.

As shown in FIGS. 55 and 56, the operation unit 10320 according to the tenth embodiment is a rotation connected to the gripping unit 10330 arranged on the front side and the back side (arrow B direction side) of the gripping unit 10330. It includes a unit 340 and.

The gripping unit 10330 is composed of an operator 10335 which is located on the front side and is formed in a circular shape in a side view, and a connecting member 10336 which is connected to the back side of the operator 10335.

The operator 10335 is arranged between the right side cover member 10331 arranged on the right side in the front view, the left side cover member 10332 arranged on the left side in the front view, the right side cover member 10331, and the left side cover member 10332. The vibration device 333 and the vibration device 333 are mainly provided.

The right side cover member 10331 includes a circular portion 331a formed in a circular plate shape and a right first wall portion 331c projecting from the outer edge of the circular portion 331a toward the left side cover member 10332 side (arrow L direction side). , The third wall portion 331e on the right side, which is located inside the first wall portion 331c on the right side and is erected in an annular shape from the circular portion 331a, and the shaft protruding from the circular portion 331a toward the back side in a semicircular columnar shape. The portion 10331g and the engaging portion 10331h projecting from the periphery of the shaft portion 10331g toward the back surface side are mainly provided.

The left side cover member 10332 is formed in substantially the same shape by reversing the right side cover member 10331 in the left-right direction (arrow LR direction), and the left side cover member 10332 is also a circular plate like the right side cover member 10331. More than the circular portion 332a formed in a shape, the left first wall portion 332c projecting from the outer edge of the circular portion 332a toward the right side cover member 10331 side (arrow R direction side), and the left side first wall portion 332c. The left third wall portion 332e located inside and erected in an annular shape from the circular portion 332a, the shaft portion 10332 g protruding from the circular portion 332a toward the back side in a semicircular columnar shape, and the shaft portion 10332 g. It mainly includes an engaging portion 10332h that protrudes from the periphery toward the back surface side.

Therefore, in the following description, the right side cover member 10331 will be described as a representative, and the description of the left side cover member 332 will be omitted. The differences between the right side cover member 331 and the left side cover member 332 will be described later.

The outer shape of the shaft portion 10331 g is made cylindrical by being combined with the shaft portion 10332 g of the left side cover member 10332. Further, the portion formed in a columnar shape by the shaft portions 10331 g and 10332 g is a shaft pivotally supported by the connecting member 10336 described later, and is a bulging portion that bulges outward in the radial direction at the tip on the insertion side (back surface side). It includes 10331 g1 and 10332 g1.

The outer diameters of the bulging portions 10331g1 and 10332g1 are larger than the inner diameters of the recessed portions 10331i and 10332i that are recessed in the connecting member 10336 described later in a semicircular shape. As a result, the connecting member 10336 is arranged from the outside of the shaft portions 10331g and 10332g, and the base end side of the shaft portions 10331g and 10332g is accommodated inside the recessed portions 10331i and 10332i. The operator 10335 can be pivotally supported in a rotatable state.

The engaging portion 10331h formed on the right side cover member 10331 projects below the shaft portion 10331g (in the direction of arrow D). On the other hand, the engaging portion 10332h formed on the left side cover member 10332 is projected above the shaft portion 10332g (in the direction of arrow U).

The connecting member 10336 mainly includes a right side connecting member 10336a arranged on the right side in the front view and a left side connecting member 10336b arranged on the left side in the front view. The right side connecting member 10336a is located on the back side of the above-mentioned right side cover member 10331, and the left side connecting member 10336b is located on the back side of the above-mentioned left side cover member 10332.

The right side connecting member 10336a has a protrusion 331b extending toward the back side (arrow B direction side) and a left side connecting member 10336b from an edge extending in the front-rear direction (arrow FB direction) of the protrusion 331b. The right second wall portion 331d projecting toward the side, the projecting portion 331f projecting from the back side end portion of the projecting portion 331b toward the back side, and the left side connection from the front side end portion of the projecting portion 331b. It includes a third wall portion 10331j on the right side that protrudes toward the member 10336b side.

The left side connecting member 10336b is formed to have substantially the same shape as the right side connecting member 10336a inverted in the left-right direction, and has a protrusion 332b extending toward the back side (arrow B direction side). The left second wall portion 332d projecting from the edge extending in the front-rear direction (arrow FB direction) of the setting portion 332b toward the right side connecting member 10336a, and the rear side end portion to the rear side of the projecting portion 332b. It includes a projecting portion 331f projecting toward the right side, and a left third wall portion 10332j projecting from the front side end portion of the projecting portion 331b toward the right side connecting member 10336a side. Therefore, in the following description, the right side connecting member 10336a will be described as a representative, and the description of the left side connecting member 10336b will be omitted.

The right third wall portion 10331j is formed at a position facing the back side of the right cover member 10331, and includes a recessed portion 10331i recessed in a semicircular shape at a position corresponding to the shaft portion 10331 g of the right cover member 10331. .. Further, an engaged portion 10331k is provided above the recessed portion 10331i.

The engaged portion 10331k is a protrusion that engages the right side cover member 10331 of the gripping unit 10330 and the engaging portion 10332h of the left side cover member 10332 when the left side cover member 10332 is rotated, and is a protrusion of the engaging portion 10332h. It is formed at a position that overlaps the displacement locus. When the operation unit 10320 is arranged at the initial position, the engaged portion 10331k and the engaging portion 10332h are arranged at adjacent positions (see FIG. 16B).

Further, as described above, since the operator 10335 is pivotally supported with respect to the connecting member 10336 in a rotatable state, when the operator 10335 is gripped by the player and is rotated clockwise in the front view. Is engaged with the engaged portion 10331k and the engaging portion 10332h (engaged portion 10332k and the engaging portion 10331h), and the connecting member 10336 is rotationally displaced as the operator 10335 rotates.

On the other hand, when the connecting member 10336 is rotated clockwise in the front view, the engagement between the engaged portion 10331k and the engaging portion 10332h (engaged portion 10332k and the engaging portion 10331h) is released, and the connecting member is released. Only 10336 is rotationally displaced.

Next, with reference to FIG. 57, the displacement of the operation unit 10320 when the player rotationally displaces the operation unit 10320 will be described. 57 (a) and 57 (b) are front views of the operation unit 10320 and the guide unit 350, and FIGS. 57 (c) and 57 (d) are cross-sectional views of the operation unit 10320. Note that FIGS. 57 (c) and 57 (d) correspond to the cross sections of the operation unit 10320 and the guide unit 350 in FIG. 55 (b). Further, in FIGS. 57 (a) and 57 (c), the operation unit 10320 at the initial position is shown, and in FIGS. 57 (b) and 57 (d), the operation unit 10320 at the first position is shown.

As shown in FIG. 57, when the operator 10335 of the operation unit 10320 is rotationally displaced, the engaged portion 10331k and the engaging portion 10332h (engaged portion 10332k and the engaging portion 10331h) are engaged with each other. The connecting member 10336 is rotationally displaced as the operator 10335 rotates. As a result, the rotating unit 340 to be fastened to the connecting member 10336 is rotationally displaced, and the guided member 344 of the rotating unit 340 is displaced along the guide groove 351 of the guide unit 350.

Next, with reference to FIG. 58, the displacement of the operation unit 10320 when the player pushes (slides) the operation unit 10320 toward the back side will be described. 58 (a) and 58 (b) are side views of the operation unit 10320 and the guide unit 350, and FIGS. 58 (c) and 58 (d) are cross-sectional views of the operation unit 10320. Note that FIGS. 58 (c) and 58 (d) correspond to the cross sections of the operation unit 10320 and the guide unit 350 in FIG. 55 (b). Further, in FIGS. 58 (a) and 58 (c), the operation unit 10320 at the initial position is shown, and in FIGS. 58 (b) and 58 (d), the operation unit 10320 at the position is shown.

As shown in FIG. 58, when the operator 10335 of the operation unit 10320 is pushed (sliding) toward the back side, the connecting member 10336 is pushed toward the back side in conjunction with the pushing operation. When the connecting member 10336 is pushed toward the back surface side, the rotating unit 340 to be fastened to the connecting member 10336 is pushed toward the back surface side. As a result, the guided member 344 of the rotating unit 340 is guided by the guide groove 351 of the guide unit 350, and the rotating unit 340 is rotated. Therefore, the connecting member 10336 to which the rotating unit 340 is fastened is also rotated as the rotating unit 340 rotates.

On the other hand, since the connecting member 10336 and the operator 10335 are not fastened, only the connecting member 10336 is rotated clockwise with respect to the operator 10335 in the front view. Therefore, in the tenth embodiment, when the player pushes the operation unit 10320, the operator 10335 is not rotated. Therefore, the operator 10335 opposes the hand or finger that the player presses the operator 10335. Is not rotated. Therefore, it is possible to make it easier for the player to operate the operation unit 10320.

Next, a case where the player rotates and displaces the operation unit 10320 counterclockwise will be described. When the operation unit 10320 is rotationally displaced counterclockwise, the engagement between the engaged portion 10331k and the engaging portion 10332h (engaged portion 10332k and the engaging portion 10331h) is released, and only the operator 10335 is released. It is rotated counterclockwise when viewed from the front.

Thereby, for example, when the player mistakenly rotates the operation unit 10320 counterclockwise in the front view, the player can be notified that the operation direction is wrong. Further, when the player who has finished the game stands up by grasping the operation unit 10320 as an aid when standing up, the front-view counterclockwise force input to the operator 10335 causes the operator 10335 to idle counterclockwise in the front view. Therefore, it is possible to prevent the force from being transmitted to the rotating unit 340. As a result, when the player grips the operator 10335 for a purpose other than operating the operation unit 10320, it is possible to prevent the operation unit 10320 from being damaged.

The counterclockwise idle rotation of the operator 10335 can be rotated to a position where the engaged portion 10331k and the engaging portion 10331h (engaged portion 10332k and the engaging portion 10332h) come into contact with each other (this implementation). In the form, the operator 10335 can be rotated approximately 160 degrees counterclockwise in the front view).

Further, the return of the operator 10335 rotated counterclockwise in the front view to the initial position is performed by a spring member (shown) interposed between the shaft portions 10331 g and 10332 g of the operator 10335 and the connecting member 10336. It is done by the urging force of (Z). As a result, it is possible to return the operator 10335 rotated counterclockwise in the front view to the initial position and maintain the operator 10335 in the initial position.

Next, the guide unit 11350 according to the eleventh embodiment will be described with reference to FIG. 59. In the first embodiment, the case where the guided member 344 is guided in the same region of the guide groove 351 by the displacement from the initial position to the terminal position of the operation unit 320 and the displacement from the terminal position to the initial position will be described. However, in the guide unit 11350 according to the eleventh embodiment, the guided member 344 covers different regions of the guide groove 11351 depending on the displacement of the operation unit 320 from the initial position to the terminal position and the displacement from the terminal position to the initial position. You will be guided. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

59 (a) is a front view of the guide unit 11350 according to the eleventh embodiment, and FIG. 59 (b) is a cross-sectional view of the guide unit 11350 in the LIXb-LIXb line of FIG. 59 (a).

As shown in FIG. 59, the guide unit 11350 according to the eleventh embodiment includes a front side guide unit 11360 arranged on the front side and a back side guide unit 11370 arranged on the back side of the front side guide unit 11360. And.

The front side guide unit 360 is formed by combining two members formed in an annular shape, and is a first annular member 361 arranged on the front side (arrow F direction side) and the first annular member 361 thereof. A second annular member 11362, which is arranged on the back surface side (the side in the direction of arrow B), is provided.

The second annular member 11362 includes a first cylindrical portion 11362a formed in a cylindrical shape, and a cylindrical second cylindrical portion 362b protruding from the outer peripheral surface of the first cylindrical portion 11362a and surrounding the first cylindrical portion 11362a. To be equipped.

The first cylindrical portion 11362a is located at a plurality of protruding portions 362a1 projecting from the inner peripheral surface and at the back end side (arrow B direction side) end of the first cylindrical portion 11362a, and is located on the inner peripheral surface side of the first cylindrical portion 11362a. The recessed portion 11362a2 is recessed toward the radial outer side of the first cylindrical portion 11362a, and is recessed from the inner peripheral surface side of the first cylindrical portion 11362a toward the radial outer side of the first cylindrical portion 11362a. It is provided with a storage recess 362a5.

The recessed portion 11362a2 is a portion in which the guided member 344 of the rotating unit 340 is arranged inside, and is formed over the entire circumference of the inner peripheral surface of the first cylindrical portion of 11362a. Further, the recessed portion 11362a2 is formed with points A (see FIG. 59 (b)) having a maximum distance recessed from the rear end side end portion to the front side at regular intervals in the circumferential direction. In the present embodiment, the intervals of the points A are formed at intervals of approximately 45 degrees in the circumferential direction.

Further, the recessed portion 11362a2 is formed so that one side connected to the point A is formed in a straight line toward the back surface side (the side in the direction of arrow B) and the other side is inclined in a straight line connected to the back surface side end portion on the one side. ..

The rear side guide unit 11370 stands on the front side along the outer edge of the first part 371 formed in an annular shape, the second part 11372 protruding from the first part 371 to the front side, and the outer edge of the first part 371. It is formed with a third part 373 to be provided.

The second portion 11372 projects toward the second annular member 362 side (front side) along the inner edge side of the first portion 371. The protruding tip surface of the second portion 11372 is predeterminedly spaced in the front-rear direction (arrow FB direction) from the end portion of the recessed portion 11362a2 of the second annular member 11362 described above (more than the diameter of the guided member 344). It is set at a position that separates it (a large distance).

As a result, the guide unit 11350 is formed with a guide groove 11351 that is recessed outward in the radial direction on a part of the inner peripheral surface. The guide groove 11351 is a groove for guiding the rotating unit 340 (see FIG. 16B), and the groove width is set to be larger than the outer shape of the guided member 344.

Further, a plurality of guide grooves 11351 are continuously formed in a predetermined shape in the circumferential direction, and are formed around the inner peripheral surface of the guide unit 11350.

The guide groove 11351 is a first guide surface 351a and a second guide surface that serve as a guide surface (a wall surface that regulates the movement of the guided member 344) of the guided member 344 on the second ring member 11362 side (front side). The 351b, the third guide surface 351c which is the guide surface of the guided member 344 on the back side guide unit 370 side (rear side), the fourth guide surface 351d, and the guide surface from the fourth guide surface 11351d to the front side. The fifth guide surface 11351 g and the sixth guide surface 11351h of the guide surface facing the front side from the second guide surface are mainly provided.

The fifth guide surface 11351 g and the sixth guide surface 11351 h are formed so as to face each other. Further, the distance between the fifth guide surface 11351 g and the sixth guide surface 11351 h facing each other is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 can be moved by the fifth guide surface 11351 g and the sixth guide surface 11351 h while restricting the moving direction. In the following description, the moving region of the guided member 344 formed between the fifth guide surface 11351 g and the sixth guide surface 11351 h facing each other will be referred to as a "third guide region".

Further, one end of the 5th guide surface 11351g is connected to the 4th guide surface 351d at the end opposite to the connection side with the 3rd guide surface 351c, and the end portion opposite to the connection side with the 4th guide surface 351d. The other end side is connected to the third guide surface 351c. That is, the fifth guide surface 11351 g connects the third guide surface 351c and the fourth guide surface 351d formed at positions adjacent to each other in the circumferential direction in the front-rear direction.

One end of the sixth guide surface 11351h is connected to the second guide surface 351b at the end opposite to the connection side with the first guide surface 351a, and the first end portion opposite to the connection side with the second guide surface 351b. The other end side is connected to the guide surface 351a. That is, the sixth guide surface 11351h connects the first guide surface 351a and the second guide surface 351b formed at positions adjacent to each other in the circumferential direction in the front-rear direction.

Therefore, one end of the third guide region formed between the fifth guide surface 11351 g and the sixth guide surface 11351 h is connected to the second guide region at the end opposite to the first guide region. , The other end side is connected to the first guide area at the end opposite to the connection side with the second guide area. As a result, a plurality of the first guide region to the third guide region can be continuously formed in the circumferential direction.

According to the guide groove 11351 formed as described above, the operation unit 320 (see FIG. 16A) receives no force from the outside of the slot machine 10 (see FIG. 1) into the operation unit 320 (by the player). In the case of non-operation), the rotating unit 340 is urged toward the front side (arrow F direction side) by the coil spring SP1 (see FIG. 14), so that the guided member 344 is the first guide surface. The guide is guided along the 351a (first guide region) or the third guide region to the connecting portion (point A side) between the first guide region and the third guide region. As a result, when the operation unit 320 is not operated, the operation unit 320 is stopped (maintained) at a position pushed out to the front side.

The sixth guide surface 11351h is provided with an inclined surface 11351h1 at a connecting portion with the first guide region (first guide surface 351a). The inclined surface 11351h1 is a surface that guides the guided member 344, which guides the third guide region from the back side to the front side, to the first guide region by using the urging force of the coil spring SP1 toward the front side. , The operation unit 320 is formed so as to be inclined in a direction opposite to the inclination direction of the first guide surface 351a with respect to the pushing (sliding) direction. Further, the guided member 344, which is guided by the inclined surface 11351h1 and is arranged in the first guide region, is arranged at a position where the center thereof overlaps with the third guide surface 351c in the pushing (sliding) direction of the operation unit 320. As a result, when the operation unit 320 after the guided member 344 is guided from the third guide area to the first guide area along the inclined surface 11351h1 is pushed toward the back side, the guided member 344 is pushed into the second guide member 344. 3 It is possible to guide along the guide surface 351c.

Next, the operation unit 320 is operated by the player to rotate the grip unit 330 clockwise in the front view, or the operation unit 320 is operated by the player and the grip unit 330 is on the back side (arrow B direction side). When pushed into, the guided member 334 of the rotating unit 340 fastened to the gripping unit 330 moves in the first guide region of the guide groove 11351.

Therefore, when the gripping unit 330 is rotated clockwise in the front view, the guided member 344 of the rotating unit 340 fastened to the gripping unit 330 is moved in the first guide region of the guide groove 11351. In this case, the rotating unit 340 (operation unit 320) is inserted inside the guide unit 11350 as the guided member 344 is moved to the back side (arrow B direction side) with respect to the guide unit 11350. It is displaced in the direction (back side).

After the guided member 344 moves in the first guide region, when the gripping unit 330 is continuously rotated clockwise in the front view, the guided member 334 of the rotating unit 340 to be fastened to the gripping unit 330 is moved to the guide groove 11351. The second guide region of the above is moved and comes into contact with the fifth guide surface 11351 g. As a result, the clockwise rotation of the operation unit 320 in the front view is restricted.

When the player does not operate the operation unit 320 from the position where the clockwise rotation of the operation unit 320 is restricted (the position where the guided member 344 comes into contact with the fifth guide surface 11351 g), the operation unit 320 is not operated. The rotating unit 340 is pushed out to the front side by the urging force of the coil spring SP1, and the guided member 344 moves in the third guide region. Therefore, the operation unit 320 can be pushed out to the front side at a position where the clockwise rotation of the operation unit 320 is restricted, and the operation unit 320 can be arranged at the initial position. That is, each time the operation unit 320 is rotated clockwise in the front view, the initial position of the operation unit 320 is changed to a position rotated clockwise by a certain amount.

In this case, since the third guide region is formed so that the distance for moving the guided member 344 is shorter than the region where the first guide region and the second guide region are combined, the operation unit 320 is continuously played a plurality of times. When a person operates the operation unit 320, the time required for the operation unit 320 to return to the initial position can be shortened so that the operation unit 320 can be continuously rotated clockwise in the front view a plurality of times. As a result, it is possible to suppress a decrease in the interest of the player.

On the other hand, the player rotates the operation unit 320 on the opposite side (counterclockwise in the front view) from the position where the clockwise rotation of the operation unit 320 is restricted (the position where the guided member 344 comes into contact with the fifth guide surface 11351 g). When the operation of the operation unit 320 is not operated after rotating to, the rotation unit 340 is pushed out to the front side by the urging force of the coil spring SP1, and the guided member 344 is pushed to the second guide surface 351b and the second guide surface 351b. It is moved to the front side along the first guide surface 351a. Therefore, the operation unit 320 that is moved to the initial position is arranged at the same rotation position (phase) in the front view of the operation unit 320 before the operation.

Therefore, in the eleventh embodiment, the operation unit 320 is frontally operated depending on whether or not the player operates the operation unit 320 counterclockwise in the front view at a position where the rotation operation of the operation unit 320 in the clockwise direction in the front view is restricted. The rotation position when pushed out toward the side can be changed. As a result, since the operation of the operation unit 320 can be given a variation, it is possible to easily give the player an interest.

Further, when the operation unit 320 at the initial position is pushed toward the back side (arrow B direction side) by the player and the guided member 344 moves in the first guide area, the guided member 344 moves to the second guide area. The movement of the guided member 344 is restricted at the connecting portion between the first guide region and the second guide region in contact with the fourth guide surface 351d.

After the guided member 344 comes into contact with the fourth guide surface 351d in the second guide region and its movement is restricted, when the player does not operate the operation unit 320, the rotation unit 340 is a coil spring. The guided member 344 is pushed to the front side by the urging force of SP1 and is moved to the front side along the first guide surface 351a. Therefore, the operation unit 320 that is moved to the initial position is arranged at the same rotation position (phase) in the front view of the operation unit 320 before the operation.

On the other hand, when the operation unit 320 is rotated clockwise in the front view after the guided member 344 comes into contact with the fourth guide surface 351d in the second guide region and its movement is restricted, the operation is performed from the initial position. Similar to the case where the unit 320 is rotated, the guided member 334 moves in the second guide region of the guide groove 11351 and comes into contact with the fifth guide surface 11351 g, so that the operation unit 320 rotates clockwise in the front view. Be regulated.

Therefore, in the eleventh embodiment, the operation of the operation unit 320 in which the rotation position (phase) of the operation unit 320 arranged at the initial position changes in the front view and the rotation position of the operation unit 320 arranged in the initial position in the front view The operation of the operation unit 320 having the same (phase) can be performed. Therefore, since variations can be provided in the operation method of the operation unit 320, the interest of the player can be enhanced.

In the eleventh embodiment, in order to detect the position of the operation unit 320 in the front-rear direction, a columnar detection piece (not shown) is projected from the back side of the rotation unit 340 at the rotation center of the operation unit 320. A sensor device (not shown) for detecting the detection piece at a position where the operation unit 320 is moved to the rear side is arranged in the base unit 391 (see FIG. 14). Thereby, the movement of the operation unit 320 to the rear side can be detected regardless of the phase in which the operation unit 320 is arranged in the front view.

Further, the rotating unit 340 is provided with a plurality of protrusions (not shown) projecting toward the front side on the same circumference centered on the rotating shaft of the operating unit 320. Further, the plurality of protrusions are distributed and arranged over a half circumference around the rotation axis of the operation unit 320. Further, the plurality of protrusions are formed at a distance from the adjacent protrusions by the amount that the initial position of the operation unit 320 is rotated in the front view by one rotation operation of the operation unit 320.

On the other hand, in the reduced diameter portion 361b of the front side guide unit 360 of the guide unit 11350, a plurality of detection sensors for detecting the protrusions are arranged at positions facing the plurality of protrusions of the operation unit 320 arranged at the initial position. Will be done. As a result, the detection positions and the number of detections of the plurality of protrusions can be detected by the plurality of detection sensors, and the phase of the operation unit 320 at the initial position can be detected.

Further, in order to prevent the wiring connected to the operation unit 320 from being entangled due to the rotational displacement of the operation unit 320, the wiring is connected to the operation unit 320 after passing through the rotation center position of the rotation unit 340. A rotary connector or a slip ring is provided in a part of the wiring.

Next, the guide groove 12351 of the guide unit 12350 in the twelfth embodiment will be described with reference to FIG. 60. In the first embodiment, the case where the first end portion 351e and the second end portion 351f of the guide groove 351 are formed as separate members (front side guide unit 360 and back side guide unit 370) has been described. In the twelfth embodiment, the first end portion 12351e and the second end portion 351f of the guide groove 12351 are formed in the same member (rear side guide unit 370). The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 60 (a) is a cross-sectional view of the guide unit 12350 according to the twelfth embodiment, and FIG. 60 (b) is an exploded cross-sectional view of the guide unit 12350.

As shown in FIG. 60, the guide groove 12351 of the guide unit 12350 in the twelfth embodiment has the second ring member 362 of the front side guide unit 360 and the back surface thereof, similarly to the guide groove 351 of the first embodiment. The side guide unit 370 extends in the circumferential direction of the first portion 371, and a part of the side guide unit 370 is formed in a shape inclined toward the back surface side.

Further, the guide groove 12351 is a first guide surface 351a and a second guide surface 351a serving as a guide surface (a wall surface for restricting the movement of the guided member 344) of the guided member 344 on the second annular member 362 side (front side). The guide surface 351b, the third guide surface 351c which is the guide surface of the guided member 344 on the back side guide unit 370 side (rear side), the fourth guide surface 351d, and the second ring of the front side guide unit 360. Mainly includes a member 362, a first end portion 12351e which is an end portion in the circumferential direction of the first portion 371 of the rear side guide unit 370, and a second end portion 351f.

The first end portion 12351e in the twelfth embodiment is formed on the front side guide unit 360. Similarly, the second end portion 351f is also formed on the front side guide unit 360. These both end portions (first end portion 12351e and second end portion 351f) are portions that define the operation end point of the operation unit 320, and are easily damaged because the guided member 344 collides with them. Therefore, both ends (first end 12351e and second end 351f) are formed on the same member (front side guide unit 360), so that both ends (first end 12351e and second end) are used. When the portion 351f) is damaged, only one member (front side guide unit 360) needs to be replaced, and it is not necessary to replace two members of the front side guide unit 360 and the back side guide unit 370. As a result, both ends of the guide groove 12351 can be replaced.

In particular, the front side guide unit 360 has a higher rigidity than the back side guide unit 370 because it is formed in a cylindrical shape continuous in the circumferential direction and a plurality of protrusions 362a1 are extended at predetermined intervals. Therefore, it is easy to suppress damage when the guided member 344 collides with both end portions (first end portion 12351e and second end portion 351f). Therefore, the exchange cycle can be lengthened.

Next, the guide groove 13351 of the guide unit 13350 in the thirteenth embodiment will be described with reference to FIG. 61. In the first embodiment, the case where the first end portion 351e and the second end portion 351f of the guide groove 351 are formed as separate members (front side guide unit 360 and back side guide unit 370) has been described. In the thirteenth embodiment, the first end portion 351e and the second end portion 13351f of the guide groove 13351 are formed in the same member (rear side guide unit 370). The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 61 (a) is a cross-sectional view of the guide unit 13350 according to the thirteenth embodiment, and FIG. 61 (b) is an exploded cross-sectional view of the guide unit 13350 according to the thirteenth embodiment.

As shown in FIG. 61, the guide groove 13351 of the guide unit 13350 in the thirteenth embodiment has the second annular member 362 of the front side guide unit 360 and the back surface thereof, similarly to the guide groove 351 of the first embodiment. The side guide unit 370 extends in the circumferential direction of the first portion 371, and a part of the side guide unit 370 is formed in a shape inclined toward the back surface side.

Further, the guide groove 13351 is a first guide surface 351a and a second guide surface 351a serving as a guide surface (a wall surface for restricting the movement of the guided member 344) of the guided member 344 on the second annular member 362 side (front side). The guide surface 351b, the third guide surface 351c which is the guide surface of the guided member 344 on the back side guide unit 370 side (rear side), the fourth guide surface 351d, and the second ring of the front side guide unit 360. It mainly includes a member 362, a first end portion 351e which is an end portion in the circumferential direction of the first portion 371 of the rear side guide unit 370, and a second end portion 13351f.

The second end portion 13351f in the thirteenth embodiment is formed on the back side guide unit 370. Similarly, the first end portion 351e is also formed on the back side guide unit 370. These both end portions (first end portion 12351e and second end portion 351f) are portions that define the operation end point of the operation unit 320, and are easily damaged because the guided member 344 collides with them. Therefore, both ends (first end 12351e and second end 351f) are formed on the same member (rear side guide unit 370), so that both ends (first end 12351e and second end) are used. When the portion 351f) is damaged, only one member (rear side guide unit 370) needs to be replaced, and it is not necessary to replace two members of the front side guide unit 360 and the back side guide unit 370.

In particular, since the back side guide unit 370 is a member forming the back side of the guide unit 13350, it is easy to replace only the back side guide unit 370. For example, in a configuration in which both ends (first end 12351e and second end 351f) are formed on the front guide unit 360, the back guide unit 370 is removed and the front guide unit 360 is a first ring member. It is also necessary to disassemble the 361 and the second ring member 362, and to remove the operation unit 320 at the time of this disassembly.

On the other hand, if both ends (first end 12351e and second end 351f) are formed on the back guide unit 370, only the back guide unit 370 may be removed, and the front guide unit 360 may be removed. It is not necessary to disassemble the first ring member 361 and the second ring member 362, and it is not necessary to remove the operation unit 320. Therefore, the replacement man-hours can be reduced and the replacement cost can be reduced.

Next, the guide unit 14350 according to the 14th embodiment will be described with reference to FIG. 62 (a). In the first embodiment, the case where the displacement directions of the first guide region and the second guide region of the guide groove 351 in the circumferential direction are set to be the same has been described, but the guide groove 14351 in the 14th embodiment is the first. The displacement directions of the first guide region and the second guide region in the circumferential direction are set to be opposite to each other. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 62A is a cross-sectional view of the guide unit 14350 according to the 14th embodiment. The cross section of FIG. 62 (a) corresponds to the cross section of FIG. 23 (d).

As shown in FIG. 62 (a), the guide groove 14351 of the guide unit 14350 in the 14th embodiment is the second annular member 362 of the front side guide unit 360 and the first part 371 of the back side guide unit 370. It extends in the circumferential direction, and a part of it is formed in a shape that inclines toward the back side.

Further, the guide groove 14351 is a first guide surface 351a and a second guide surface that serve as a guide surface (a wall surface that regulates the movement of the guided member 344) of the guided member 344 when the operation unit 320 is rotated. 14351b, the third guide surface 351c which becomes the guide surface (the wall surface which regulates the movement of the guided member 344) of the guided member 344 when the operation unit 320 is pushed in, and the fourth guide surface 14351d and the circumference. It includes three first end portions 351e, a second end portion 14351f, and a third end portion 14351i formed at the end portions in the direction.

The second guide surface 14351b and the fourth guide surface 14351d are formed so as to face each other. Further, the second guide surface 14351b and the fourth guide surface 14351d are the ends of the first guide region (first end portion 351e) formed between the first guide surface 351a and the third guide surface 351c facing each other. It is connected to the end on the opposite side of the first guide region and extends in the horizontal direction (direction orthogonal to the rotation axis of the operation unit 320) from the end of the first guide region. That is, the second guide region formed between the second guide surface 14351b and the fourth guide surface 14351d facing each other is formed with the second end portion 14351f as the start end and the third end portion 14351i as the end end.

The minimum distance between the second guide surface 14351b and the fourth guide surface 14351d is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 can be moved on the second guide surface 14351b and the fourth guide surface 14351d while restricting the moving direction.

In the fourteenth embodiment, the moving direction of the guided member 344 in the circumferential direction when moving the first guide area toward the second plan area and the second guide area toward the end (third end portion 14351i). The moving direction of the guided member 344 in the circumferential direction is set to be opposite to that of the guided member 344.

Therefore, in order to displace the operation unit 320 from the initial position to the end position, the player needs to switch the rotation direction of the operation unit 320 to the opposite direction (for example, from right rotation to left rotation) on the way. As a result, it is possible to make the player perform complicated operations of the operation unit, and it is possible to suppress the deterioration of the player's interest.

Further, since the second guide region (fourth guide surface 14351d) extends in the horizontal direction (direction orthogonal to the rotation axis of the operation unit 320), the guided member 344 is operated by pushing the operation unit 320. Cannot be moved along the second guide region to the third end 14351i.

Further, the moving direction of the guided member 344 from the start end to the end in the second guide region is set to be the same as the moving direction of the guided member 344 by the urging force of the coil spring SP2 (see FIG. 27A). Since the second guide surface 14351b, which is pushed out to the front side by the urging force of the coil spring SP1 (see FIG. 14) and comes into contact with the guided member 344, extends in the horizontal direction, it is guided to the end of the second guide region. The guided member 344 can be maintained in contact with the third end portion 14351i.

As a result, when returning the operation unit 320 in a state where the guided member 344 is guided to a position where the guided member 344 comes into contact with the third end portion 14351i to the initial position, the player operates the operation of rotating the operation unit 320 clockwise in the front direction. Can be made to. Therefore, the operation of the operation unit 320 can be complicated, and it is possible to prevent the operation of the operation unit 320 from becoming monotonous and deteriorating the interest of the player.

Further, since the rotation direction when the operation unit 320 arranged at the terminal position is returned and the rotation direction when the operation unit 320 arranged at the initial position is displaced can be the same direction, the player can use the same direction. It is possible to prevent the operation unit 320 from making a mistake in the rotation direction.

In this way, the operation of displacementing the operation unit 320 from the initial position (the position where the guided member 344 is arranged at the first end portion 351e) to the terminal position (the position where the guided member 344 reaches the third end portion 14351i). As a result, the player can be required to perform a two-step operation (an operation of switching the rotation direction in the middle). Therefore, it is possible to prevent the operation feeling from becoming monotonous. Further, it is possible to prevent the operation unit 320 from being displaced to the terminal position (the position where the guided member 344 reaches the third end portion 14351i) only by the pushing operation. That is, the operation unit 320 can be prevented from being displaced to the terminal position by a careless operation of the player.

Next, the guide unit 15350 according to the fifteenth embodiment will be described with reference to FIG. 62 (b). In the first embodiment, the case where the displacement directions of the first guide region and the second guide region of the guide groove 351 in the circumferential direction are set to be the same has been described, but the guide groove 15351 in the fifteenth embodiment is the first. The displacement directions of the first guide region and the second guide region in the circumferential direction are set to be opposite to each other. The same parts as those in the above embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 62B is a cross-sectional view of the guide unit 15350 according to the fifteenth embodiment. The cross section of FIG. 62 (b) corresponds to the cross section of FIG. 23 (d).

As shown in FIG. 62B, the guide groove 15351 of the guide unit 15350 in the fifteenth embodiment is formed by the second annular member 362 of the front side guide unit 360 and the first part 371 of the back side guide unit 370. It extends in the circumferential direction and is formed in a shape that inclines toward the back side as a whole.

The guide groove 15351 includes a first guide surface 351a and a second guide surface 15351b that serve as a guide surface (a wall surface that regulates the movement of the guided member 344) of the guided member 344 when the operation unit 320 is rotated. The third guide surface 351c and the fourth guide surface 15351d, which are the guide surfaces of the guided member 344 (the wall surface that regulates the movement of the guided member 344) when the operation unit 320 is pushed in, are in the circumferential direction. It includes three first end portions 351e, a second end portion 15351f, and a third end portion 15351i formed on the end portions.

The second guide surface 15351b and the fourth guide surface 15351d are formed so as to face each other. Further, the second guide surface 15351b and the fourth guide surface 15351d are the ends of the first guide region (first end portion 351e) formed between the first guide surface 351a and the third guide surface 351c facing each other. It is connected to the end on the opposite side to the first guide region) and extends in the circumferential direction while inclining from the end of the first guide region to the side opposite to the first guide region. That is, the second guide region formed between the second guide surface 15351b and the fourth guide surface 15351d facing each other is formed with the second end portion 15351f as the start and the third end portion 15351i as the end.

The minimum distance between the second guide surface 15351b and the fourth guide surface 15351d is set to be larger than the diameter of the guided member 344. As a result, the guided member 344 can be moved on the second guide surface 15351b and the fourth guide surface 15351d while restricting the moving direction.

When the player pushes (slides) the operation unit 320 toward the back side, the third guide surface 351c in the first guide area and the fourth guide surface 15351d in the second guide area are used. , The guided member 344 can be moved. Therefore, when the player pushes the operation unit 320 toward the back side and displaces it, the operation unit 320 can be displaced from the initial position to the end position without having to change the displacement direction of the operation unit 320.

In the fifteenth embodiment, the moving direction of the guided member 344 in the circumferential direction when moving the first guide area toward the second plan area and the second guide area toward the end (third end portion 14351i). The moving direction of the guided member 344 in the circumferential direction is set to be opposite to that of the guided member 344.

Therefore, in order to displace the operation unit 320 from the initial position to the end position, the player needs to switch the rotation direction of the operation unit 320 to the opposite direction (for example, from right rotation to left rotation) on the way. As a result, it is possible to make the player perform complicated operations of the operation unit, and it is possible to suppress the deterioration of the player's interest.

Further, in the fifteenth embodiment, since the second guide region (fourth guide surface 14351d) is inclined and extended, the guided member 344 can be pushed along the second guide region even by the pushing operation of the operation unit 320. It can be moved to the third end 14351i.

In this way, the operation of displacementing the operation unit 320 from the initial position (the position where the guided member 344 is arranged at the first end portion 351e) to the terminal position (the position where the guided member 344 reaches the third end portion 14351i). As for the rotation operation, the player can be required to perform a two-step operation (an operation of switching the rotation direction in the middle). Therefore, it is possible to prevent the operation feeling from becoming monotonous. On the other hand, in the case of the pushing operation, the operation unit 320 is moved from the initial position (the position where the guided member 344 is arranged at the first end 351e) to the end position (the position where the guided member 344 reaches the third end 14351i). ) Can be displaced by one-way operation.

That is, in either the rotation operation or the pushing operation, the operation unit 320 is moved from the initial position (the position where the guided member 344 is arranged at the first end portion 351e) to the end position (the guided member 344 is the third). Since it can be displaced to the end (position reaching the end 14351i), the player can arbitrarily select the type of operation. As a result, it is possible to give a variation to the operation feeling.

Although the present invention has been described above based on the above-described embodiment, the present invention is not limited to the above-described embodiment, and it is easy to make various modifications and improvements within a range that does not deviate from the gist of the present invention. It can be inferred.

In each of the above embodiments, a game machine may be configured by replacing or combining a part or all of one embodiment with a part or all of another one or a plurality of other embodiments.

In the first embodiment, the case where the back side guide unit 370 is formed of one member in which the first part 371 and the second part 372 are connected has been described, but the present invention is not necessarily limited to this. For example, the back side guide unit 370 may form the first part 371 and the second part 372 from different members, and assemble the first part 371 and the second part 372.

In this case, by forming the first part 371 and the second part 372 separately, the shapes of the first part 371 and the second part 372 can be easily complicated. As a result, the degree of freedom in designing the back side guide unit 370 can be improved, and the variation in the moving direction of the guided member 344 displaced along the back side guide unit 370 can be increased.

In the first embodiment, the second guide surface 351b of the guide groove 351 is inclined so as to approach the front side (arrow F direction side) and extend in the circumferential direction as it approaches the connecting portion with the first guide surface 351a. When the operation unit 320, which is formed as a guide surface and is guided to a position where the guided member 344 comes into contact with the second end portion 351f, is not operated, the urging force on the front side of the coil spring SP1 causes the first operation unit 320. 2 The case where the guided member 344 is guided to the first guide region along the guide surface 351b has been described, but the present invention is not necessarily limited to this.

For example, the extension direction of the second guide surface 351b in the circumferential direction of the second annular member 362 may be extended in parallel with the horizontal direction, or the second guide surface in the circumferential direction of the second annular member 362 may be extended. The extension direction of the 351b may be extended in a direction close to the front side while being away from the first guide surface 351a.

In this case, it is possible to prevent the guided member 344 from moving to the first guide region side due to the urging force on the front side of the coil spring SP1. That is, the guided member 344 can be maintained at a position where it abuts on the second end portion 351f. Therefore, when returning the operation unit 320 in the state where the guided member 344 is guided to the position where the guided member 344 comes into contact with the second end portion 351f to the initial position, the player is required to rotate the operation unit 320 counterclockwise in the front direction. Can be made to. Therefore, the operation of the operation unit 320 can be complicated, and it is possible to prevent the operation of the operation unit 320 from becoming monotonous and deteriorating the interest of the player.

When the guided member 344 of the rotating unit 340 is guided toward the first guide region side by the urging force of the coil spring SP2 of the base unit 391, the second guide in the circumferential direction of the second annular member 362 By increasing the inclination angle of the surface 351b toward the front side, the guided member 344 can be maintained at a position where it abuts on the second end portion 351f.

Further, when the extension direction of the second guide surface 351b in the circumferential direction of the second ring member 362 is extended in parallel with the horizontal direction, when the operation unit 320 is rotated from the initial position to the end position, By guiding the guided member 344 to the first guide area and the second guide area, which have different extension directions, the slide displacement to the rear side with respect to the rotation amount of the operation unit 320 is not generated during the rotation of the operation unit 320. It is considered to be displacement. That is, the slide displacement to the rear side is not formed while the operation unit 320 is rotationally displaced. As a result, the operation of the operation unit 320 can be enjoyed.

In the fifth embodiment, the case where the displacement unit 5395 is suppressed from being displaced to the front side of the base plate 5392a by the two hook portions 5396m has been described, but the present invention is not necessarily limited to this. For example, one end side (rear side) of the roller 5396j formed in an annular shape in the axial direction is expanded in diameter beyond the width of the sliding groove 5392a2, and the displacement unit 5395 is displaced to the front side of the base plate 5392a by the roller 5396j. You may suppress doing. In this case, after the displacement unit 5395 is arranged in front of the base plate 5392a, the roller 5396j is attached and the displacement unit 5395 is arranged on the base unit 5391.

In the fifth embodiment, the size of the engagement hole 5396b1 about the center of the main body 396a in the circumferential direction is substantially the same as the size of the engagement piece 342b about the center of the main body 396a in the circumferential direction. The case where the displacement unit 5395 and the displacement unit 320 are set and the displacements of the displacement unit 5395 and the operation unit 320 are always linked has been described, but the present invention is not necessarily limited to this.

For example, the size of the engaging hole 5396b1 about the center of the main body 396a in the circumferential direction may be set larger than the size of the engaging piece 342b about the center of the main body 396a in the circumferential direction. In this case, the gap between the engaging hole 5396b1 and the engaging piece 342b in the circumferential direction about the center of the main body 396a is provided with a difference between the timing at which the displacement unit 5395 is operated and the timing at which the operation unit 320 is operated. Can be done.

In the fifth embodiment, the roller 5396j arranged on the rotating shaft portion 5396i of the first displacement member 5396 and the sliding groove 5392a2 of the base member 5392 are used to determine the displacement direction of the first displacement member 5396 (displacement unit 5395). The case of regulation has been explained, but it is not necessarily limited to this.

For example, assuming that the rotating shaft portion 5396i of the first displacement member 5396 is not formed (the roller 5396j is not mounted), the displacement directions of the first displacement member 5396 (displacement unit 5395) are set at two hook portions 5396m and the base member 5392. It may be regulated by the sliding groove 5392a2. In this case, since the two hook portions 5396m are formed so as to be elastically deformable, the tooth portion 5396k of the first displacement member 5396 and the pinion 5398a are in a poorly engaged state, and the resistance between the tooth portion 5396k and the pinion 5398a is large. When this is done, the tooth portion 5396m can be elastically deformed to stabilize the tooth engagement between the tooth portion 5396k and the pinion 5398a.

In this case, it is preferable that the distance between the two hook portions 5396m in the radial direction of the main body portion 396a on the outer side in the opposite direction is set to be substantially the same as the width direction of the sliding groove 5392a2. As a result, when the hook portion 5396m is elastically deformed in the direction in which the hook portion 5396m is disengaged from the sliding groove 5392a2, it is possible to prevent the tip of the hook portion 5396m and the base plate 5392a from being overlapped in the front-rear direction. .. As a result, it is possible to prevent the hook portion 5396 m from being disengaged from the sliding groove 5392a2.

Further, the two hook portions 5396m are in a state in which the hook portions 5396m are elastically deformed by setting the distance between the outer sides of the main body portion 396a in the radial direction facing each other to be larger than the width direction of the sliding groove 5392a2. May be engaged with the sliding groove 5392a2. In this case, since the force required for elastic deformation of the hook portion 5396m in the direction of disengaging the sliding groove 5392a2 can be increased, the engagement between the hook portion 5396m and the sliding groove 5392a2 is released. Can be suppressed.

In the seventh embodiment, the case where the second convex portion 7392f2 is formed on the regulation piece 7392f and the concave portion 7397f1 is formed on the second displacement member 7397 has been described, but the present invention is not necessarily limited to this. For example, a concave portion may be formed in the regulation piece 7392f and a convex portion may be formed in the second displacement member 7397. When the displacement unit 7395 is arranged at the initial biasing position, the regulation piece 7392f and the second displacement member may be formed. Anything that engages with 7397 will do.

In the tenth embodiment, the case where the operator 10335 is formed so as to be able to rotate counterclockwise in the front view with respect to the connecting member 10336 has been described, but the present invention is not necessarily limited to this. For example, when the bulging portion 10331g1, 10332g1 of the operator 10335 is deformed and the operating operator 10335 is rotated counterclockwise in the front view, the bulging portion 10331g1, 10332g2 is attached to the protruding portions 331b and 332b of the connecting member 10336. It may be abutted to regulate the counterclockwise rotation of the operator 10335 in the front view.

In this case, since it is not necessary for the operation unit 10320 to have a means (for example, a spring member) for returning the operator 10335 to the initial position, the number of parts of the operation unit 10320 can be reduced. Moreover, the assembly of the operation unit 10320 can be simplified.

In the tenth embodiment, the case where the operator 10335 rotated counterclockwise in the front view is returned to the initial position by the urging force of the spring member has been described, but the present invention is not necessarily limited to this, and for example, the operation. The center of gravity of the child 10335 is set to the lower position of the operator 10335 arranged at the initial position, and the operator 10335 rotated counterclockwise in the front view is returned to the initial position by its own weight. It may be.

In the eleventh embodiment, the case where the guide groove 11351 is formed from the first guide region, the second guide region, and the third guide region has been described, but the present invention is not necessarily limited to this, and for example, the second guide region is not limited to this. The guide groove 111351 may be formed only by the first guide region and the third guide region.

In this case, when the player pushes the operation unit 320 toward the back side, the guided member 344 that moves in the first guide area is moved along the third guide surface 351c, and the third guide is moved from the first guide area. Moved to the area. Therefore, when the player does not operate the operation unit 320 after pushing the operation unit 320, the rotating unit 340 is pushed out to the front side by the urging force of the coil spring SP1 and the guided member 344 is guided to the third guide. Move the area towards the front.

Since the third guide area is formed so that the distance for moving the guided member 344 is shorter than that in the first guide area, the initial position of the operation unit 320 when the player operates the operation unit 320 a plurality of times in succession. The time required for returning to is shortened, and the operation unit 320 can be easily operated a plurality of times in succession. As a result, it is possible to suppress a decrease in the interest of the player.

In the eleventh embodiment described above, in order to detect the position of the operation unit 320 in the front-rear direction, a case where a columnar detection piece is projected from the back side of the rotation unit at the center of rotation of the operation unit 320 has been described, but it is not always the case. It is not limited to this. For example, an annular protrusion about the center of rotation of the operation unit 320 may be projected from the back surface side of the rotation unit 340, and the sensor device may be arranged at a position where the protrusion can be detected.

In the first, third to fifth, and seventh embodiments, the case where the displacement units 395, 3395, 5395, and 7395 are rotationally displaced when viewed from the front has been described. However, the displacement units 395, 3395, 5395, and 7395 have been described in the above-mentioned first embodiment. The displacement units 2395 and 4395 in the 2nd and 4th embodiments may be linearly displaced. On the contrary, in the second and fourth embodiments, the case where the displacement units 2395 and 4395 are linearly displaced has been described, but the displacement units 395, 3395, 5395 and 7395 in the first, third to fifth and seventh embodiments have been described. It may be rotationally displaced.

The displacement units 395, 2395, 3395, 4395, 5395, and 7395 in the first to seventh embodiments may be combined, respectively.

In the above embodiment, an example in which the present invention is embodied with respect to the slot machine 10 is shown, but the present invention may be applied to a gaming machine in which a slot machine and a pachinko machine are fused. That is, among the slot machines, instead of the medal insertion and medal payout functions, a gaming machine having ball throwing and ball payout functions such as a pachinko machine may be used. If such a game machine is used instead of a slot machine, only the ball can be treated as a game value in the game hall. Therefore, a medal that is a game value in the current game hall where pachinko machines and slot machines are mixed. It is possible to solve problems such as the burden on the equipment and restrictions on the location of the gaming machine due to the separate handling of the ball and the ball.

It is also possible to apply the present invention to pachinko machines. In the case of a pachinko machine, the game machine main body is attached to the outer frame, and a door member is provided on the front side of the game machine main body. The game machine main body is equipped with a game board in which a game area as a game ball flight area is formed and an operation port and a liquid crystal display device are installed. The display device is visible. Then, as the game ball launched by the game ball launcher wins a prize in the operating port, an internal lottery is performed and a variable display of the pattern is performed on the liquid crystal display device. Even when the configuration of the display control device and the sub control device of the above embodiment is applied to such a pachinko machine, it is clear that the same functions and effects as those of the above embodiment are exhibited.

Further, in addition to the pachinko machine, it may be implemented as various game machines such as a pachinko machine, a sparrow ball, a slot machine, a so-called pachinko machine and a slot machine.

As a specific example of a gaming machine in which a pachinko machine and a slot machine are fused, a display device for displaying a variable display of a sequence of symbols consisting of a plurality of symbols and then confirming the symbol is provided, and a handle for launching a ball is not provided. Things can be mentioned. In this case, after a predetermined amount of balls are thrown in based on a predetermined operation (button operation), the symbol variation is started due to, for example, the operation of the operation lever, and for example, due to the operation of the stop button or a predetermined amount. As time elapses, the fluctuation of the symbol is stopped, and a special game is generated that gives the player a predetermined game value on the condition that the confirmed symbol at the time of the stop is a so-called jackpot symbol, and the player is given a predetermined game value. Is for paying out a large amount of balls to the lower saucer.

The concepts of various inventions included in the above-described embodiments in addition to the gaming machine of the present invention are shown below.

<Concept of the invention using the base unit 390 as an example>
In a gaming machine including a base member, a displacement member displaceably arranged on the base member, and a holding means for holding the displaced member on the base member, the holding means is formed so as to be elastically deformable. When the displacement member is attached to the base member, the elastic portion in contact with the displacement member is elastically deformed, and the displacement member is allowed to be attached to the base member. The gaming machine A1 is characterized in that when the displacement member mounted on the base member is brought into contact with the elastic portion, the displacement of the displacement member in the abutting direction is regulated by the elastic portion.

Here, there is known a gaming machine in which a displacement member is slidably displaced on a base member (for example, Japanese Patent Application Laid-Open No. 2012-130539). In such a technique, a groove is opened in the base member, and a protrusion of the displacement member is inserted into the groove. Therefore, the end point of the slide displacement of the displacement member is defined by abutting the protrusion at the end of the groove. A collar larger than the groove width is fastened and fixed to the tip of the protrusion. As a result, the displacement member is held by the base member and is prevented from falling off.

Further, there is also known a gaming machine that defines the end point of slide displacement by locating a wall portion erected from a base member on the displacement locus of the displacement member and bringing the displacement member into contact with the wall portion. For example, Japanese Patent Application Laid-Open No. 2017-29609). A lid member is arranged on the base member, and a displacement member is housed between the base member and the lid member. As a result, the displacement member is held by the base member and is prevented from falling off.

However, in the conventional gaming machine illustrated above, not only separate parts such as a collar and a lid member are required, but also these separate parts need to be fastened and fixed to the base member with screws, which increases man-hours. Therefore, there is a problem that the product cost increases.

On the other hand, according to the game machine A1, the elastic portion is elastically deformed so that the displacement member is attached to the base member, and after the attachment, the displacement of the displacement member is regulated by the elastic portion whose elasticity is restored. .. That is, the displacement member is held by the base member. Therefore, not only the separate parts are unnecessary, but also the process of attaching the separate parts can be eliminated, so that the product cost can be reduced accordingly.

In the game machine A1, the displacement member is displaced between the first position and the second position, and the displacement member is at least a displacement locus when the displacement member is displaced between the first position and the second position. The gaming machine A2 is characterized in that it is mounted on the base member by being displaced in a direction orthogonal to the displacement locus at a position overlapping a part and then being displaced in accordance with the displacement regulation.

According to the game machine A2, in addition to the effect of the game machine A1, the displacement member is orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus when the displacement member is displaced between the first position and the second position. After being displaced in the direction of displacement, the displacement member is mounted on the base member by being displaced according to the displacement regulation. Therefore, when the displacement member is mounted on the base member, the displacement member can be overlapped with the displacement locus of the displacement member. it can. Therefore, the space on the base member required for mounting the displacement member can be reduced by the amount of the overlapping allowance.

In the game machine A2, a protrusion that is projected from one of the base member or the displacement member and a recess that is formed so that the protrusion can pass through and is recessed in the other of the base member or the displacement member. The gaming machine A3 is characterized in that, when the protrusion passes through the recess, the displacement member is displaced in a direction orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus.

According to the game machine A3, in addition to the effect of the game machine A2, the displacement member is displaced in the direction orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus by passing the protrusion through the recess. Therefore, it is possible to increase the overlap margin between the displacement locus of the displacement member and the displacement member when the displacement member is mounted on the base member. Therefore, the space on the base member required for mounting the displacement member can be made smaller.

In the game machine A2 or A3, the game machine A4 is characterized in that the elastic portion is engaged with the base member or the displacement member in a state where the displacement member is arranged at the first position.

According to the game machine A4, in addition to the effect of the game machine A2 or A3, the elastic part is engaged with the base member or the displacement member in the state where the displacement member is arranged at the first position, so that the elastic part is the base. It is possible to suppress elastic deformation in the contact direction each time the member or the displacement member is contacted. Therefore, it is possible to prevent the elastic portion from becoming deformed.

The gaming machine A4 is characterized by comprising an urging means for applying an urging force in a direction of holding the displacement member to the first position to the displacement member.

According to the game machine A5, in addition to the effect of the game machine A4, an urging means for applying a urging force in the direction of holding the displacement member to the first position is provided to the displacement member, so that the elastic portion is a base member or It is possible to maintain a state in which the displacement member is in contact with the displacement member (a state in which elastic deformation of the elastic portion is restricted). Therefore, it is possible to prevent the elastic portion from being illegally elastically deformed and the displacement member from being removed.

<Concept of the invention using the base unit 390 as an example>
In a gaming machine including a base member, a displacement member displaceable on the base member, and a holding means for holding the displaced member on the base member, the holding means is the base member or the above. The gaming machine B1 is characterized in that one of the displacement members is provided with an elastic portion that is elastically deformably arranged, and the displacement member is held by the elastic portion on the base member.

Here, there is known a gaming machine in which a displacement member is slidably displaced on a base member (for example, Japanese Patent Application Laid-Open No. 2012-130539). In such a technique, a groove is opened in the base member, and a protrusion of the displacement member is inserted into the groove. Therefore, the end point of the slide displacement of the displacement member is defined by abutting the protrusion at the end of the groove. A collar larger than the groove width is fastened and fixed to the tip of the protrusion. As a result, the displacement member is held by the base member and is prevented from falling off.

Further, there is also known a gaming machine that defines the end point of slide displacement by locating a wall portion erected from a base member on the displacement locus of the displacement member and bringing the displacement member into contact with the wall portion. For example, Japanese Patent Application Laid-Open No. 2017-29609). A lid member is arranged on the base member, and a displacement member is housed between the base member and the lid member. As a result, the displacement member is held by the base member and is prevented from falling off.

However, in the conventional gaming machine illustrated above, there is a problem that assembly is complicated because it is necessary to fasten and fix another part such as a collar and a lid member to the base member with screws.

On the other hand, according to the game machine B1, the holding means is provided with an elastic portion that is elastically deformably arranged on one of the base member and the displacement member, and the displacement member is held by the elastic portion on the base member. , It is not necessary to fasten and fix other parts such as collars and lid members with screws. Therefore, it can be easily assembled.

In the game machine B1, the displacement member is displaced in one direction and is held by the elastic portion on the base member.

According to the game machine B2, in addition to the effect of the game machine B1, the displacement member is displaced in one direction and is held by the elastic portion on the base member, so that it is not necessary to perform a complicated operation. That is, the displacement member can be held by the base member by a simple operation such as pushing in one direction. Therefore, it can be easily assembled.

In the game machine B2, the holding means includes an engaging portion that is arranged on one of the base member or the displacement member and is formed so as to be engageable with the base member or the other of the displacement members. A gaming machine characterized in that the base member or the other of the displacement members is displaced in one direction while being engaged with the engaging portion, so that the base member is held by the elastic portion. B3.

According to the game machine B3, the holding means includes an engaging portion disposed on one of the base member or the displacement member and formed to be engageable with the other of the base member or the displacement member, and the displacement member is the base member or the displacement member. The other side of the displacement member is displaced in one direction while being engaged with the engaging portion, so that the displacement member is held by the elastic portion on the base member. Therefore, since the portion engaged with the engaging portion can be used as a fulcrum to be displaced in one direction, the assembly can be facilitated in addition to the effect of the game machine B2.

Further, as a portion for holding the displacement member on the base member, an engaging portion can be used in addition to the elastic portion, so that the holding strength can be improved. Therefore, it is possible to prevent the displacement member from falling off from the base member.

In any of the game machines B1 to B3, the holding means includes an opening opened in the base member or the other of the displacement members and extended along the displacement direction of the displacement member, and the opening includes the opening. A game machine B4 characterized in that an elastic portion is inserted.

According to the game machine B4, in addition to the effect of any of the game machines B1 to B3, the holding means has an opening opened in the other of the base member or the displacement member and extended along the displacement direction of the displacement member. Since the elastic portion is inserted through the opening, space efficiency can be improved. That is, the opening and the elastic portion can have both a function of guiding the displacement of the displacement member with respect to the base member and a function of causing the base member to hold the displacement member. Therefore, space efficiency can be improved as compared with the case where both functions are provided separately.

In the game machine B4, the displacement member is formed as a rack in which teeth are engraved along the outer edge of the game machine B5.

According to the game machine B5, in addition to the effect of the game machine B4, the displacement member is formed as a rack in which teeth are carved along the outer edge thereof, so that the tooth carving range can be easily secured. That is, as described above, the function of guiding the displacement and the function of holding the displacement can be provided to the opening and the elastic portion, and it is not necessary to provide both of these functions on the outer edge of the displacement member. Therefore, it is possible to secure a tooth engraving range on the outer edge of the displacement member.

<Concept of the invention using the base unit 390 as an example>
In a game machine including an operator that is formed to be displaceable by the operation of a player, a first member that comes into contact with the operator in a predetermined displacement region is provided, and the operator is operated by contact with the first member. A game machine C1 characterized in that the feeling is changed.

Here, a game machine provided with an operator is known (for example, Japanese Patent Application Laid-Open No. 2017-29609). Examples of the operator include a button that can be pressed and a lever that can be rotated.

However, the gaming machine illustrated above has a problem that it is difficult to grasp the operation position of the operator.

On the other hand, according to the game machine C1, a first member that comes into contact with the operator in a predetermined displacement region is provided, and the operation feeling of the operator is changed by the contact with the first member. It is possible to easily grasp the operation position of the operator based on the change in the operation feeling.

In the game machine C1, the first member is characterized in that the reaction force acting on the operator increases as the operator approaches a predetermined position.

According to the game machine C2, in addition to the effect of the game machine C1, the first member increases the reaction force acting on the operator as the operator approaches the predetermined position, so that the operator approaches the predetermined position. Can be easily recognized by the player.

The game machine C2 includes a base member in which the operator is displaceably arranged, and the first member collides with the operator or the base member when the operator exceeds the predetermined position. A game machine C3 characterized by.

According to the game machine C3, in addition to the effect of the game machine C2, a base member in which the operator is displaced is provided, and the first member is the operator or the base member when the operator exceeds a predetermined position. Since it collides with the operator, vibration can be transmitted to the operator by the collision. This makes it easier for the player to recognize that the operator has been displaced to a predetermined position.

In the game machine C3, the first member of the game machine C4 collides with the base member when the operator exceeds the predetermined position.

According to the game machine C4, in addition to the effect of the game machine C3, the first member collides with the base member when the operator exceeds a predetermined position, so that damage to the operator can be suppressed. Since the operator is arranged on the base member, the vibration due to the collision of the first member can be transmitted to the operator via the base member.

In any of the game machines C2 to C4, the first member is formed as an elastic body that is elastically deformed by contact with the operator, and when the operator exceeds the predetermined position, the first member with the operator The gaming machine C5, characterized in that the contact is released and the elastic recovery causes the collision with the base member or the operator.

According to the game machine C5, in addition to the effect of any of the game machines C2 to C4, the first member is formed as an elastic body that is elastically deformed by contact with the operator, and the operator exceeds a predetermined position. Then, the contact with the operator is released, and the elastic recovery causes the collision with the base member or the operator, so that the structure can be simplified. That is, by elastic deformation of the first member and its elastic recovery, it is possible to form a reaction force acting on the actuator and a displacement of the first member due to a collision with the actuator or the base member, and the reaction force is formed. It is not necessary to separately provide an actuator for colliding with each other.

In the game machine C5, when the operator is displaced beyond a predetermined position, the first member is released from contact with the operator and collides with the operator or the base member due to its elastic recovery. A game machine C6 characterized by this.

According to the game machine C6, in addition to the effect of the game machine C5, when the operator is displaced beyond a predetermined position, the first member is released from contact with the operator, and the elastic recovery of the first member causes the operator. Alternatively, since it collides with the base member, that is, it has a mechanical structure that utilizes the elastic deformation of the first member and its elastic recovery, the reliability is improved as compared with the case of electrically controlling by using an actuator, for example. Can be improved.

In the game machine C5 or C6, the first member includes a collision portion that collides with either the base member or the operator, and when the collision portion is damaged, the other portion of the first member is said. A gaming machine C7 characterized in that it collides with a base member or the operator.

According to the game machine C7, in addition to the effect of the game machine C5 or C6, the first member includes a collision portion that collides with either the base member or the operator, and when the collision portion is damaged, the first member Since the other part of the member collides with the base member or the operator, the transmission of vibration to the operator can be reliably formed. That is, even if the collision portion is damaged, the player can be made to recognize that the operator has been displaced to a predetermined position.

In any of the game machines C5 to C7, the operator is a displaceable displacement between the first position capable of contacting the first member and the second position not contacting the first member. When a member is provided and the operator is displaced in the first direction, the displacement member is arranged at the first position and the operator is displaced in a second direction opposite to the first direction. In this case, the game machine C8 is characterized in that the displacement member is arranged at the second position.

According to the game machine C8, in addition to the effect of any of the game machines C5 to C7, the operator has a first position capable of contacting the first member and a second position in which the operator is not in contact with the first member. A second position is provided with a displacement member displaceable from a position, and when the operator is displaced in the first direction, the displacement member is placed in the first position and the operator is in the direction opposite to the first direction. When the displacement member is displaced in the direction, the displacement member is arranged at the second position. Therefore, when the operator is displaced in the first direction, the operation feeling is changed, and when the operator is displaced in the second direction, the operation feeling is changed. The operation feeling can be unchanged. Therefore, it is possible to prevent the operation feeling from being changed when the operator is displaced in any direction, and it is possible to prevent the player's interest from being lowered.

In the game machine C8, the displacement member is displaced from the first position to the second position by being brought into contact with the first member when the operator is displaced in the second direction. Characteristic gaming machine C9.

According to the game machine C9, in addition to the effect of the game machine C8, the displacement member is moved from the first position to the second position by being brought into contact with the first member when the operator is displaced in the second direction. Since it is displaced, it is not necessary to separately provide a configuration for displacementing the displacement member, and such a configuration can also be used for the first member. Therefore, the number of parts can be reduced accordingly.

In the game machine C9, the base member includes an engaging piece that displaces the displacement member from the second position to the first position when the operator is arranged at the end in the second direction. Game machine C10.

According to the game machine C10, in addition to the effect of the game machine C9, the base member engages to displace the displacement member from the second position to the first position when the operator is placed at the end in the second direction. Since the piece is provided, the displacement member can be brought into contact with the first member when the operator is displaced in the first direction.

In the game machine C10, the engaging piece is formed so as to be elastically deformable.

According to the game machine C11, in addition to the effect of the game machine C10, the engaging piece is formed so as to be elastically deformable, so that the displacement member engages when the operator is arranged at the end in the second direction. Even if it collides with a piece, the impact caused by the collision can be absorbed by the elastic deformation of the engaging piece. Therefore, damage to the displacement member can be suppressed.

<Concept of the invention using the displacement unit 300 (operation unit 320) as an example>
In a gaming machine provided with an operator that is displaceably formed from the first position to the second position by the operation of the player, the operation in the first direction or the second direction, which is a direction different from the first direction. The gaming machine D1 is characterized in that the operator is displaced from the first position to the second position in any direction of the operation.

Here, a game machine provided with an operator is known (for example, Japanese Patent Application Laid-Open No. 2017-29609). Examples of the operator include a button that can be pressed and a lever that can be rotated.

However, the conventional gaming machine illustrated above has a problem that the operation feeling is monotonous.

On the other hand, according to the game machine D1, the operator moves from the first position to the first position in either the operation in the first direction or the operation in the second direction, which is a direction different from the first direction. Since it is displaced to two positions, the player can arbitrarily select the type of operation. As a result, it is possible to give a variation to the operation feeling.

In the game machine D1, the operator is formed so as to be displaceable from the second position to the third position, and the operator is displaced from the second position to the third position by the operation in the second direction. The gaming machine D2 is characterized in that in the operation in the first direction, the displacement of the operator from the second position to the third position is restricted.

According to the game machine D2, in addition to the effect of the game machine D1, the operator is displaced from the second position to the third position by the operation in the second direction, and the second operation of the operator is caused by the operation in the first direction. Since the displacement from the position to the third position is regulated, the operation of displacing the operator from the first position to the third position can be complicated (a mixture of one-step operation and two-step operation can be formed). That is, in the operation in the first direction, the displacement of the actuator from the first position to the third position cannot be completed (after that, it is necessary to further perform the operation in the second direction in the second position), while the first If the operation is in two directions, the displacement of the operator from the first position to the third position can be completed in one operation.

In the game machine D1, the operator is formed so as to be displaceable from the second position to the third position, and is operated in the third direction, which is a direction different from both the first direction and the second direction. The operator is displaced from the second position to the third position, and in the operations in the first direction and the second direction, the displacement of the operator from the second position to the third position is restricted. A game machine D3 characterized by this.

According to the game machine D3, in addition to the effect of the game machine D1, the operator moves from the second position to the third position by operating in the third direction, which is a direction different from both the first direction and the second direction. In the operation of being displaced and described in the first and second directions, the displacement of the operator from the second position to the third position is restricted, so that the operation is to displace the operator from the first position to the third position. , Two-step operation can be required. Therefore, it is possible to prevent the operation feeling from becoming monotonous. Further, it is possible to prevent the operator from being inadvertently displaced (operated) from the second position to the third position.

That is, after the operator is displaced from the first position to the second position by the operation in the first direction or the operation in the second direction, the third direction is different from the first or second direction. The operator cannot be displaced to the third position unless the operation is performed in the direction.

In any of the game machines D1 to D3, one of the operation in the first direction and the operation in the second direction is an operation for rotating the operator, and the operation in the first direction or the operation in the second direction. The other is the gaming machine D4, which is an operation of directly moving the operator.

According to the game machine D4, in addition to the effect of any of the game machines D1 to D3, one of the operation in the first direction and the operation in the second direction is an operation for rotating the operator, and the operation in the first direction. Alternatively, since the other operation in the second direction is an operation in which the operator is directly moved, the difference in the operation direction can be noticeable. Therefore, it is possible to clarify the change in the operation feeling due to the operation in different directions.

In the game machine D4, the direction of the rotation axis of rotation in one of the operations in the first direction or the operation in the second direction, and the direction of linear motion in the other of the operations in the first direction or the operation in the second direction. A game machine D5 characterized in that

According to the game machine D5, in addition to the effect of the game machine D4, the direction of the rotation axis of rotation in either the operation in the first direction or the operation in the second direction, and the operation in the first direction or the operation in the second direction. Since the direction of linear motion on the other side is parallel, the operator can be easily displaced from the first position to the second position in either the operation in the first direction or the operation in the second direction.

In the game machine D5, the base member in which the operator is displaceably arranged, a guide portion formed on one of the base member or the operator, and the other of the base member or the operator are formed. A guided portion that is guided along the guide portion is provided, and the guided portion is guided along the guide portion, so that the operator is displaced from at least the first position to the second position. A game machine D6 characterized by this.

According to the game machine D6, in addition to the effect of the game machine D5, a base member in which an operator is displaceably arranged, a guide portion formed on one of the base member or the operator, and a base member or an operation A guided portion formed on the other side of the child and guided along the guide portion is provided, and the guided portion is guided along the guide portion, so that the operator is displaced from at least the first position to the second position. Therefore, the structure can be simplified. Further, in the operation in the first direction and the operation in the second direction (for example, linear motion and rotation), the guide portion (guide surface) to which the guided portion is guided can be made different. As a result, for example, the shape of the guide portion (guide surface) can be changed to make the displacement mode and operation feeling of the operator different.

The game machine D6 is characterized in that the front surface of the operator is arranged at a position overlapping the rotation axis in the direction view of the rotation axis of rotation in either the operation in the first direction or the operation in the second direction. Game machine D7.

According to the game machine D7, in addition to the effect of the game machine D6, the front surface of the operator is positioned at a position overlapping the rotation axis in the direction view of the rotation axis of rotation in either the operation in the first direction or the operation in the second direction. Since it is arranged, it is possible to make it difficult to form a force component in a direction in which the operator is tilted with respect to the rotation axis when the operator is pushed in. Therefore, the push-operated operator can be smoothly moved directly.

In the game machine D6 or D7, in the directional view orthogonal to the rotation axis of rotation in either the operation in the first direction or the operation in the second direction, the opposite side surfaces of the operator are located at positions overlapping the rotation axis, respectively. A game machine D8 characterized in that it is arranged.

According to the game machine D8, in addition to the effect produced by the game machine D6 or D7, the operation is performed at a position overlapping the rotation axis in a directional view orthogonal to the rotation axis of rotation in either the operation in the first direction or the operation in the second direction. Since the opposing side surfaces of the child are arranged, the opposite side surface of the operator can be used as a handle, and the opposite side surface can be gripped to facilitate rotation of the operator.

<Concept of the invention using the displacement unit 300 (operation unit 320) as an example>
In a gaming machine provided with an operator that is operated and displaced by a player in one direction, a first operation and a second operation different from the first operation are formed on the operator by the operation in one direction. A game machine E1 characterized by being played.

Here, a game machine provided with an operator is known (for example, Japanese Patent Application Laid-Open No. 2017-29609). Examples of the operator include a button that can be pressed and a lever that can be rotated.

However, in the conventional gaming machine illustrated above, the operator has a problem that it is difficult to give interest to the operation of the operator because only one operation is formed by the operation in one direction.

On the other hand, according to the game machine E1, the first operation and the second operation different from the first operation are formed on the operator by the operation in one direction, which gives an interest to the operation of the operator. be able to.

The operations in one direction include, for example, a pushing operation for pressing the operator, a pull-out operation for pulling the operator, a tilting operation for tilting the operator, a slide operation for sliding the operator, and a rotation of the operator. A rotation operation, an operation combining these operations, and the like are exemplified. Further, as the modes of the first operation and the second operation, for example, an operation of displacement along a straight line (linear displacement), an operation of displacement along a curve (curve displacement), an operation of rotating around an axis, and the like. An example is an operation of performing displacement in combination with displacement.

The game machine E2 is characterized in that at least one of the first operation and the second operation is changed during the operation in one direction.

According to the game machine E2, in addition to the effect of the game machine E1, at least one mode of the first operation or the second operation is changed during the operation in one direction, so that the operation of the operator is interesting. Can be given.

As a mode of the game machine E2, for example, as a first mode, an operation of linear displacement (first operation) and an operation of rotation (second operation) by a pushing operation (operation in one direction) are operators. The second mode is that the rotation direction of the operator's rotation operation (second operation) is changed in the opposite direction (for example, from right rotation to left rotation) during the pushing operation. In this mode, a linear displacement operation (first operation) and a rotating operation (second operation) are formed on the operator by the pushing operation (operation in one direction), and the pushing operation is performed. In the middle of the pushing operation, the rotation amount (rotation angle) of the operator per unit pushing amount of the pushing operation is increased or decreased (including the one in which the rotation amount becomes 0). A mode in which a linear displacement operation (first operation) and a rotating operation (second operation) are formed on the operator by (operation in one direction), and the rotation operation is performed during the rotation operation. Examples of modes in which the linear displacement amount of the operator per unit rotation angle is increased or decreased (including those in which the linear displacement amount becomes 0) are exemplified.

In the game machine E1 or E2, the game machine E3 is characterized in that one of the first operation and the second operation is non-formed during the operation in one direction.

According to the game machine E3, in addition to the effect of the game machine E1 or E2, one of the first operation and the second operation is non-formed during the operation in one direction, so that the operation of the operator is interesting. Can be given.

The middle of the operation in one direction may be any timing within the range of the operation. That is, one of the first operation and the second operation is not formed before or after the first operation and the second operation are formed.

Therefore, as an aspect of the game machine E3, for example, in the first half of the pushing operation (operation in one direction), a linear displacement operation (first operation) and a rotating operation (second operation) are performed. In the latter half of the pushing operation, only the linear displacement operation (first operation) is formed on the operator, and the rotating operation (second operation) is not formed. In the first half of the pushing operation (operation in one direction), only the linear displacement operation (first operation) is formed on the operator, and the rotating operation (second operation) is not formed. In the latter half of the above, an embodiment in which a linear displacement motion (first motion) and a rotating motion (second motion) are formed in the operator is exemplified.

In any of the game machines E1 to E3, the operator includes a base member that is displaceably arranged, and the operator is rotatably connected to a base member guided by the base member and the base member. The gaming machine E4 is provided with a member to be operated, which is a part to be operated by the player.

According to the game machine E4, in addition to the effect of the game machine E3, a base member in which the operator is displaced is provided, and the operator is guided to the base member and rotates on the base member. Since the operated member is provided as a part that can be connected and operated by the player, it is possible to improve the operation feeling when operating the operated member.

For example, in a mode in which a linear displacement operation (first operation) and a rotating operation (second operation) are formed on the operator by a pushing operation (operation in one direction), the second operation (rotation) is performed. With the formation, the operator is rotated with respect to the palm of the operator. Therefore, the palm is rubbed by the operator, which causes a decrease in the feeling of operation.

On the other hand, according to the game machine E4, since the member to be operated is rotatably connected to the base member, a linear displacement operation (first operation) and rotation by a pushing operation (operation in one direction) and rotation are performed. While it is possible to form the movement (second movement) to be performed on the base member, it is possible to prevent the member to be operated from being rotated with respect to the palm of the player. Therefore, it is possible to suppress the palm from being rubbed by the operator and improve the operability.

In any of the game machines E1 to E4, a base member in which the operator is displaceably arranged, a guide portion formed on one of the base member or the operator, and the base member or the operator. A game characterized in that a guided portion formed on the other side and guided along the guide portion is provided, and the operator is displaced by guiding the guided portion along the guide portion. Machine E5.

According to the game machine E5, in addition to the effect of any of the game machines E1 to E4, a base member in which the operator is displaceably arranged, and a guide portion formed on one of the base member or the operator. A guided portion formed on the other side of the base member or the operator and guided along the guide portion is provided, and the guided portion is guided along the guide portion to displace the operator. The structure can be simplified while allowing the first operation and the second operation to be formed at the same time.

<Concept of the invention using the displacement unit 300 (operation unit 320) as an example>
In a gaming machine including a base member and a displacement member displaceable on the base member, a guided portion formed on one of the base member or the displacement member and the base member or the displacement member. A guide portion formed on the other side of the guide portion for guiding the guided portion is provided, and the guided portion is characterized in that it is guided to a different region of the guide portion according to a displacement state of the displacement member. Game machine F1.

Here, a base member and a displacement member displaceable on the base member are provided, and a pin projecting from the displacement member slides along a groove formed in the base member. A game machine that defines the displacement mode of the displacement member is known (for example, Japanese Patent Application Laid-Open No. 2012-130539).

However, in the conventional gaming machine illustrated above, since the same region is guided regardless of the displacement state of the displacement member, there is a problem that the load is concentrated in that region and the durability is lowered.

On the other hand, according to the game machine F1, a guided portion formed on one of the base member or the displacement member and a guide portion formed on the other of the base member or the displacement member to guide the guided portion are provided. Since the guide portion is guided to different regions of the guide portion according to the displacement state of the displacement member, it is possible to disperse the region to receive the load and suppress the concentration of the load on a part of the region. As a result, durability can be improved.

Examples of the displacement state of the displacement member include the direction of displacement of the displacement member and the mode of the external force acting on the displacement member.

In the game machine F1, the displacement member is formed so as to be displaceable between the first position and the second position, and in the region of the guide portion to which the guided portion is guided, the displacement member is in the first position. The gaming machine F2 is characterized in that the case where the displacement member is displaced from the second position to the second position and the case where the displacement member is displaced from the second position to the first position are different.

According to the game machine F2, in addition to the effect of the game machine F1, the displacement member is formed so as to be displaceable between the first position and the second position, and the area of the guide part to which the guided part is guided is formed. Since the case where the displacement member is displaced from the first position to the second position and the case where the displacement member is displaced from the second position to the first position are different, the area to be loaded can be dispersed and the area to be loaded can be distributed to a part of the area. It is possible to suppress the concentration of load. As a result, durability can be improved.

In this way, when the displacement member reciprocates between the first position and the second position, the displacement member is displaced alternately between the outward path and the return path, so that the area of the guide portion to which the guided portion is guided is guided. By making the outward path and the return path of the displacement member different, the area receiving the load can be efficiently dispersed. As a result, it is particularly effective in improving durability.

In the game machine F1 or 2, the displacement member is formed so as to be operable by a player in either the first direction and a second direction different from the first direction, and the guided portion is guided. The gaming machine F3 is characterized in that the region of the guide portion differs depending on whether the displacement member is operated in the first direction or the displacement member is operated in the second direction.

According to the game machine F3, in addition to the effect of the game machine F1 or F2, the displacement member is formed so as to be operable by the player in either the first direction and the second direction different from the first direction. Since the region of the guide portion to which the guided portion is guided differs depending on whether the displacement member is operated in the first direction or the displacement member is operated in the second direction, the region that receives the load can be dispersed. , It is possible to prevent the load from being concentrated in a part of the area. As a result, durability can be improved.

In this way, when the displacement member is formed as an operator operated by the player and can be operated in any of the first direction and the second direction different from the first direction, the game state. Since the direction of operation is selected according to the above and the same operation (operation direction) is difficult to repeat, the area of the guide portion to which the guided portion is guided can be divided into the operation in the first direction and the operation in the second direction. By making them different, the area to be loaded can be efficiently distributed. As a result, it is particularly effective in improving durability.

The game machine F2 includes a first member and a second member, and the guide portion is a region in which the guided portion is guided when the displacement member is displaced from the first position to the second position. Is formed in the first member, and a region in which the guided portion is guided is formed in the second member when the displacement member is displaced from the second position to the first position. Amusement machine F4.

In the game machine F3, the first member and the second member are provided, and in the guide portion, the region where the guided portion is guided when the displacement member is operated in the first direction is the first member. The gaming machine F5 is formed in the second member, and a region in which the guided portion is guided is formed in the second member when the displacement member is operated in the second direction.

According to the game machine F4 or F5, in addition to the effect of the game machine F2 or F3, the guide portion is covered when the displacement member is displaced from the first position to the second position or is operated in the first direction. The area where the guide portion is guided is formed in the first member, and the region where the guided portion is guided when the displacement member is displaced from the second position to the first position or is operated in the second direction is the first. Since it is formed into two members, the replacement cost can be reduced.

That is, when the guide portion is formed on the member 1, even if a part of the region of the guide portion is damaged or worn, it is necessary to replace the entire member. On the other hand, according to the game machine F4 or F5, when a part of the area is damaged or worn, only one member (one of the first member or the second member) forming the area is replaced. It is sufficient to do so, and it is not necessary to replace the entire member. Therefore, the replacement cost can be reduced accordingly.

Further, when the guide portion is formed from the first member and the second member in this way and only one region is easily damaged or worn, the one member (first member or second member) forming the region is liable to be damaged or worn. Only the material of one of the members) can be made of a material having higher durability than the other member (the other of the first member or the second member). As a result, it is possible to improve the durability while reducing the material cost.

<Concept of the invention using the displacement unit 300 (guide unit 350) as an example>
In a gaming machine including a first member on which a guided portion is projected and a second member having a groove-shaped guide portion for guiding the guided portion, the second member is a base member and its base. A gaming machine G1 comprising a connecting member connected to the member, wherein the guide portion is formed by the base member and the connecting member.

Here, a base member and a displacement member displaceable on the base member are provided, and a pin projecting from the displacement member slides along a groove formed in the base member. A game machine that defines the displacement mode of the displacement member is known (for example, Japanese Patent Application Laid-Open No. 2012-130539).

However, in the conventional gaming machine illustrated above, when assembling the base member and the displacement member, if other members are present, they can be assembled while avoiding interference with the other members (pins are inserted into the grooves). May be required. In this case, since it is necessary to work while avoiding interference with other members, there is a problem that the shapes of the displacement member, the base member, and the other member are limited, and the degree of freedom in design is reduced.

On the other hand, according to the game machine G1, the second member includes a base member and a connecting member connected to the base member, and a guide portion is formed by the base member and the connecting member. Alternatively, after arranging the first member on one of the connecting members, the base member or the other of the connecting members can be connected to one to assemble the whole. Therefore, it is possible to prevent interference with other members. As a result, the degree of freedom in design can be increased.

In the game machine G1, the guide portion includes a guide surface along a direction for guiding the guided portion and a terminal surface for defining an end in a direction for guiding the guided portion, and the base member and the connecting member. The gaming machine G2 is characterized in that a boundary with the terminal surface is formed at the terminal surface or a connection portion between the terminal surface and the guide surface.

According to the game machine G2, in addition to the effect of the game machine G1, the guide portion includes a guide surface along the direction for guiding the guided portion and a terminal surface for defining the end in the direction for guiding the guided portion. Since the boundary between the base member and the connecting member is formed at the terminal surface or the connecting portion between the terminal surface and the guide surface, the guided portion is a boundary where a step is likely to be formed due to dimensional tolerances and assembly tolerances. Can be avoided from passing. Therefore, it is possible to avoid the occurrence of impact and wear when the guided portion passes through the step. As a result, the guided portion can be smoothly displaced and the durability can be improved.

In the game machine G1 or G2, the guide portion includes a guide surface along a direction for guiding the guided portion and a terminal surface for defining an end in a direction for guiding the guided portion. A gaming machine including a first guide surface and a second guide surface arranged to face each other, the first guide surface is formed of the base member, and the second guide surface is formed of the connecting member. G3.

According to the game machine G3, in addition to the effect of the game machine G1 or G2, the guide portion has a guide surface along the direction for guiding the guided portion and a terminal surface for defining the end in the direction for guiding the guided portion. The guide surface includes a first guide surface and a second guide surface that are arranged to face each other, the first guide surface is formed by a base member, and the second guide surface is formed by a connecting member. The guide surface and the second guide surface can be formed from different members. As a result, the respective materials can be made different according to the characteristics required for the first guide surface and the second guide surface. Further, when changing the shape of the first guide surface or the second guide surface, only one member needs to be changed, and it is not necessary to change the whole.

In the game machine G3, the end surface defines a first end surface that defines one end in the direction of guiding the guided portion and a second end surface that defines the other end in the direction of guiding the guided portion. The gaming machine G4 is provided with an end surface, and the first end surface and the second end surface are formed by either the base member or the connecting member.

According to the game machine G4, in addition to the effect of the game machine G3, the end surface includes the first end surface that defines the end on one side in the direction of guiding the guided portion, and the direction of guiding the guided portion. It has a second end surface that defines the end on the side, and since the first end surface and the second end surface are formed by either the base member or the connecting member, the parts that are easily damaged are integrated into one component. , Parts replacement cost can be reduced. That is, the surface (part) that defines the end in the direction of guiding the guided portion is easily damaged because the guided portion collides, and if the surface (part) that defines the end is damaged, Only one of the base member or the connecting member needs to be replaced, and it is not necessary to replace the whole.

In any of the game machines G1 to G4, the outer surface formed along the first direction of the first member is surrounded by the second member, and the guided portion protrudes from the outer surface of the first member. The gaming machine G5 is provided, wherein the guide portion is formed on an inner surface of the connecting member, and the base member and the connecting member are divided in the first direction.

According to the game machine G5, in addition to the effect of any of the game machines G1 to G4, the outer surface formed along the first direction of the first member is surrounded by the second member, and the guide portion is described. , The guide portion is formed on the inner surface of the connecting member, and the base member and the connecting member are divided in the first direction. Therefore, the base member and the connecting member have a continuous shape (annular shape). ) Can be done. Therefore, it is possible to improve the rigidity of the members (base member and connecting member) that are required to have rigidity because the guide portion for guiding the guided portion is formed. Further, by dividing into a base member and a connecting member, it is possible to easily form a guide portion (die-cutting).

In the game machine G3 or G4, the first member is formed so as to be displaceable from the first position to the second position by the operation of the player, and the first member is displaced from the first position by the operation in the first direction. When displaced to the second position, the guided portion is guided by the first guide surface, and the first member is moved by the operation in the second direction, which is a direction different from the first direction. The gaming machine G6 is characterized in that when the position is displaced from the first position to the second position, the guided portion is guided by the second guide surface.

According to the game machine G6, in addition to the effect of the game machine G3 or G4, the first member is formed so as to be displaceable from the first position to the second position by the operation of the player, and the first member is formed by the operation in the first direction. When one member is displaced from the first position to the second position, the guided portion is guided by the first guide surface, and the first member is moved by an operation in the second direction, which is a direction different from the first direction. When the displacement is performed from the first position to the second position, the guided portion is guided by the second guide surface, so that it depends on the type of operation direction (operation in the first direction or operation in the second direction). A (suitable) guide surface (shape and material) can be used. Thereby, for example, by making the shapes and materials of the first guide surface and the second guide surface different, the operation feeling can be made different. Alternatively, by adopting a material with high wear resistance and impact resistance on the side where wear generation and impact input are large, while adopting a low cost material on the side where wear generation and impact input are small. , Improved durability and reduced product cost can be achieved.

In any of the game machines A1 to A5, B1 to B5, C1 to C11, D1 to D8, E1 to E5, F1 to F5, and G1 to G6, the game machine K1 is a slot machine. .. Among them, the basic configuration of the slot machine is "provided with a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming the identification information, and for operating a starting operation means (for example, an operation lever). Due to this, the dynamic display of the identification information is started, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (stop button) or after a predetermined time has elapsed, and at the time of the stop. A gaming machine provided with a special gaming state generating means for generating a special gaming state advantageous to the player, provided that the definite identification information of the above is the specific identification information. In this case, coins, medals, and the like are typical examples of the game medium.

In any of the gaming machines A1 to A5, B1 to B5, C1 to C11, D1 to D8, E1 to E5, F1 to F5, and G1 to G6, the gaming machine is a pachinko gaming machine. K2. Among them, the basic configuration of the pachinko gaming machine is provided with an operation handle, and the ball is launched into a predetermined game area according to the operation of the operation handle, and the ball is placed in a predetermined position in the game area. As a prerequisite for winning a prize (or passing through the operating port), the identification information dynamically displayed on the display device may be fixedly stopped after a predetermined time. Further, when a special gaming state occurs, a variable winning device (specific winning opening) arranged at a predetermined position in the gaming area is opened in a predetermined manner to enable a ball to be won, and is valuable according to the number of winnings. Some are given value (including not only prize balls but also data written on a magnetic card).

In any of the gaming machines A1 to A5, B1 to B5, C1 to C11, D1 to D8, E1 to E5, F1 to F5, and G1 to G6, the gaming machine is a fusion of a pachinko gaming machine and a slot machine. The gaming machine K3, which is characterized by being. Among them, as a basic configuration of the fused gaming machine, "a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information is provided, and a starting operation means (for example, an operation lever). The variation of the identification information is started due to the operation of, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (for example, the stop button) or after a predetermined time elapses. A special game state generating means for generating a special game state advantageous to the player is provided on the condition that the definite identification information at the time of stopping is the specific identification information, the ball is used as the game medium, and the identification information is described. A game machine that requires a predetermined number of balls to start the dynamic display of the game, and is configured to pay out a large number of balls when a special game state occurs. "
<Others>
There is known a gaming machine in which a displacement member is slidably displaced on a base member (Japanese Unexamined Patent Publication No. 2012-130539).
However, the above-exemplified gaming machine has a problem that the product cost increases.
The present technical idea is made to solve the above-exemplified problems, and aims to provide a game machine capable of reducing the product cost.
<Means>
In order to achieve this object, the gaming machine of the technical idea 1 includes a base member, a displacement member displaceably arranged on the base member, and a holding means for holding the displaced member on the base member. The holding means is provided with an elastic portion formed so as to be elastically deformable, and when the displacement member is attached to the base member, the elastic portion in contact with the displacement member is elastically deformed. Then, when the displacement member is allowed to be mounted on the base member and the displacement member mounted on the base member is brought into contact with the elastic portion, the displacement of the displacement member in the abutting direction is caused. It is regulated by the elastic part.
In the game machine described in Technical Thought 1, the displacement member is displaced between the first position and the second position, and the displacement member is the first position and the second position. It is mounted on the base member by being displaced in a direction orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus when being displaced from the position and then being displaced according to the displacement regulation. Will be done.
The gaming machine of the technical idea 3 is the gaming machine described in the technical idea 2, in which a protrusion projecting from one of the base member or the displacement member and the protrusion are formed so as to be passable, and the base member is formed. Alternatively, the displacement member is provided with a recess recessed in the other side of the displacement member, and the protrusion is passed through the recess so that the displacement member is orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus. Displaced in the direction.
<Effect>
According to the gaming machine described in Technical Thought 1, the product cost can be reduced.
According to the game machine described in the technical idea 2, in addition to the effect of the game machine described in the technical idea 1, the space on the base member required for mounting the displacement member can be reduced.
According to the game machine described in the technical idea 3, in addition to the effect of the game machine described in the technical idea 2, the space on the base member required for mounting the displacement member can be made smaller.

10 slot machine (game machine)
300 Displacement unit (operator)
310 Ring member (base member)
320, 8320, 10320 Operation unit (operator, displacement member, first member)
330,10330 Grip unit (operator, displacement member)
10335 Operator (operator, base member, displacement member)
10336 Connecting member (operator, operated member, displacement member)
340, 8340 Rotating unit (operator, displacement member, first member)
342 Back side member (displacement member, first member)
343 Shaft member (guided part)
344 Guided member (guided part)
350, 8350, 9350, 11350, 12350, 13350, 14350, 15350 Guide unit (base member, second member)
351, 8351, 9351, 11351, 12351, 13351, 14351, 15351 Guide groove (guide unit)
351a 1st guide surface (guide surface, terminal surface, 1st guide surface, 2nd guide surface, 1st terminal surface, 2nd terminal surface)
351b, 14351b, 15351b 2nd guide surface (guide surface, 1st guide surface, 2nd guide surface)
351c, 8351c 3rd guide surface (guide surface, 1st guide surface, 2nd guide surface)
351d 4th guide surface (guide surface, 1st guide surface, 2nd guide surface)
351e, 12351e 1st end (termination surface, 1st end surface, 2nd end surface)
351f, 13351f, 14351f 2nd end (termination surface, 1st end surface, 2nd end surface)
11351g Fifth guide surface (guide surface, end surface, first guide surface, second guide surface, first end surface, second end surface)
11351h 6th guide surface (guide surface, 1st guide surface, 2nd guide surface)
14351i, 15351i 3rd end (termination surface, 1st end surface, 2nd end surface)
9351k Rear recessed portion (guide surface, end surface, first guide surface, second guide surface, first end surface, second end surface)
8351m accommodating part (terminal surface, first terminal surface, second terminal surface)
360, 11360 Front side guide unit (first member, second member, base member, connecting member)
362 Second ring member (first member, second member, base member, connecting member)
370 Rear side guide unit (first member, second member, base member, connecting member)
391,231,3391,4391,5391,6391,7391 Base unit (base member)
392, 2392, 3392, 4392, 5392, 6392, 7392 Base member (base member)
392a, 2392a, 3392a, 4392a, 5392a, 6392a, 7392a Base plate (base member)
5392a2 Sliding groove (opening)
392d1,392d1,3392d1,4392d1 Inner first engaging piece (holding means, protrusion)
392d2 Inner second engaging piece (holding means, protrusion)
3392d3 Inner first locking part (elastic part, engaging part)
3392d4 Inner second locking part (elastic part, engaging part)
392e1,392e1 Outer first engaging piece (holding means, protrusion)
392e2, 2392e2 outer second engaging piece (holding means, protrusion)
3392e3, 4392e3 Outer first locking part (elastic part, engaging part)
3392e4, 4392e4 Outer second locking part (elastic part, engaging part)
392f, 2392f, 3392f, 6392f, 7392f Restriction piece (holding means, elastic part, engaging piece)
393 leaf spring (first member)
393a Protrusion (collision part)
395, 2395, 4395, 5395, 7395 Displacement unit (displacement member, rack, operator)
396, 2396, 4396, 5396 1st displacement member (displacement member, rack, operator, 1st member)
396d1, 2396d1 Inner first recessed part (recessed part)
396d2, 2396d2 Inner second recess (concave)
396e, 2396e Outer recessed part (recessed part)
5396m Hook part (elastic part, engaging part)
397,7397 Second displacement member (displacement member)

Claims (3)

In a gaming machine provided with a base member, a displacement member displaceable on the base member, and a holding means for holding the displacement member on the base member.
The holding means includes an elastic portion formed so as to be elastically deformable.
When the displacement member is mounted on the base member, the elastic portion in contact with the displacement member is elastically deformed, and the displacement member is allowed to be mounted on the base member and mounted on the base member. A gaming machine characterized in that when the displacement member is brought into contact with the elastic portion, the displacement of the displacement member in the abutting direction is regulated by the elastic portion. The displacement member is displaced between the first position and the second position.
The displacement member is displaced in a direction orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus when displaced between the first position and the second position, and then conforms to the displacement regulation. The gaming machine according to claim 1, wherein the game machine is mounted on the base member by being displaced. A protrusion that is projected from one of the base member or the displacement member and a recess that is formed so that the protrusion can pass through and is recessed in the other of the base member or the displacement member.
The game according to claim 2, wherein when the protrusion passes through the recess, the displacement member is displaced in a direction orthogonal to the displacement locus at a position overlapping at least a part of the displacement locus. Machine.

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