JP2012045117A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine which allows a player to operate an operation device with operation feeling suitable for him/her.SOLUTION: Three slider-holding cylinders 402 are disposed with elastic members 600 having different spring constants, and when an inner frame 400 is turned, the elastic members 600 for applying urging forces to a starting lever 71 are switched between them. Any strength of the urging force applied to the starting lever 71 is selected. Accordingly, the player is allowed to operate the starting lever 71 with the operation feeling suitable for him/her.

Description

  The present invention relates to a gaming machine represented by a slot machine or the like.

  Conventionally, there is a gaming machine in which a predetermined operation is instructed by a player operating an operation means. For example, Patent Document 1 discloses a gaming machine including a start lever 6 as an example of a gaming machine including an operation unit. According to this gaming machine, when the player operates the start lever 6, the start of the rotation operation of the reels R1 to R3 is instructed.

  In this case, the urging force from the urging means (for example, a coil spring) is applied to the start lever 6, and the start lever 6 is operated against the urging force, so that the player can appropriately operate the urging force. In addition, the operation lever is configured so that the start lever 6 is returned to the initial position after the operation is completed.

JP 2003-180924 A

  However, in the conventional gaming machine described above, when the urging force of the urging means is increased (or decreased), even if the operational feeling is appropriate for a certain player, the excessive feeling (insufficient) There was a problem of giving a feeling. Further, there is a problem that even if the operation feeling is moderate for a short time operation, a feeling of fatigue is given during a long time operation.

  The present invention has been made to solve the above-described problems and the like, and it is an object of the present invention to provide a gaming machine capable of operating an operation means with an operation feeling suitable for a player.

Means for Solving the Problems and Effects of the Invention

  According to the gaming machine of the first aspect, the urging force applied from the urging means can give the player a feeling of operation when operating the operation means, while returning the operation means to the initial position after the operation is completed. Can be made. In this case, in claim 1, a plurality of urging means having different urging forces are provided, and the urging means for applying the urging force to the operation means can be switched from among the plurality of urging means. There is an effect that the magnitude of the urging force applied to the operation means can be arbitrarily selected. Accordingly, there is an effect that the operation means can be operated with an operation feeling suitable for the player.

  According to the gaming machine of the second aspect, in addition to the effect achieved by the gaming machine of the first aspect, the operating member is disposed on the first member and the plurality of urging members are disposed on the second member. Since the second member is moved relative to the first member, any one of the plurality of urging means is arranged at a position where the urging force can be applied to the operation means. An arbitrary biasing force can be selected from a plurality of biasing forces. Therefore, the operation means can be operated with an operation feeling suitable for the player. In this case, since the first member provided with the operating means is fixed to the gaming machine main body, only the urging force can be changed without changing the operating position of the operating means. That is, even if the urging force is changed, the operation means can be operated at the same position, so that the operability can be ensured.

  According to the gaming machine of the third aspect, in addition to the effect achieved by the gaming machine of the second aspect, the second member is formed to be rotatable around the rotation axis, and the plurality of biasing means are arranged around the rotation axis. Therefore, by rotating the second member around the rotation axis, it is possible to sequentially arrange one urging means among the urging means at a position where the urging force can be applied to the operating means. it can. In this case, when the plurality of urging means rotate and move with the rotation of the second member, the movement trajectories of the respective urging means can be overlapped, so that it is necessary to move the plurality of urging means accordingly. Thus, there is an effect that the area to be taken can be reduced and the size can be reduced.

  According to the gaming machine of the fourth aspect, in addition to the effect achieved by the gaming machine according to the second or third aspect, the switching operation unit is fixed to the second member and protrudes to the front side of the gaming machine main body. Therefore, by using such a switching operation unit, there is an effect that the second member can be moved, that is, the urging force can be easily changed. In particular, since the switching operation unit protrudes from the front side of the gaming machine main body, the player can arbitrarily change the biasing force suitable for the player according to the situation while performing the game. There is an effect that can be done.

It is a front view of the slot machine in one Embodiment of this invention. It is a perspective view of the slot machine showing a state where the front door is closed. It is a perspective view of the slot machine showing a state where the front door is opened. It is a front view of a housing | casing. It is an assembly perspective view of a left reel. It is an expanded view of the belt-shaped belt which comprises each reel. The backlight and its periphery are shown. FIG. 1A is a perspective view thereof, and FIG. It is a front view of a selector. It is a block circuit diagram of the slot machine. It is a flowchart which shows a NMI interruption process. It is a flowchart which shows a timer interruption process. It is a flowchart which shows the process at the time of a power failure. It is a flowchart which shows a main process. It is a flowchart which shows a normal process. It is a flowchart which shows a lottery process. It is a flowchart which shows a reel control process. It is a flowchart which shows medal payout processing. It is a flowchart which shows a special game state process. It is a flowchart which shows a bonus symbol determination process. It is explanatory drawing which shows the counter setting at the time of RB game initial setting process. (A) is explanatory drawing which shows the counter setting at the time of BB game initial setting process, (b) is explanatory drawing which shows the counter setting at the time of JAC game initial setting process in BB game. It is a perspective view of a switch apparatus. It is a cross-sectional perspective view of a switch apparatus. It is sectional drawing of a switch apparatus. (A) is a front view of a front outer frame, (b) is sectional drawing of the front outer frame in the XXVb-XXVb line | wire of Fig.25 (a). (A) is a front view of an inner frame, (b) is a rear view of an inner frame. FIG. 27 is a step view of the inner frame taken along line XXVII-XXVII in FIG. It is sectional drawing of a switch apparatus. It is a perspective view of the switch apparatus in 2nd Embodiment. It is a cross-sectional perspective view of a switch apparatus. It is a cross-sectional perspective view of the switch apparatus in 3rd Embodiment. It is a perspective view of the switch apparatus in 4th Embodiment. It is a cross-sectional perspective view of a switch apparatus. It is a partial expanded sectional view of a switch apparatus. It is a partial expanded sectional view of a switch apparatus. It is a section perspective view of the switch device in a 5th embodiment. It is a section perspective view of the switch device in a 6th embodiment. It is a perspective view of the switch apparatus in 7th Embodiment. It is sectional drawing of a switch apparatus. (A) is a rear view of the intermediate outer frame, and (b) is a cross-sectional view of the intermediate outer frame taken along the line XXXb-XXXXb in FIG. 40 (a). (A) is a front view of a rotating plate, (b) is a rear view of a rotating plate. It is sectional drawing of the rotating plate in the XXXII-XXXXII line | wire of FIG.41 (b). (A) is a front view of an inner spring pusher, an intermediate spring pusher, and an outer spring pusher, and (b) is an inner spring pusher and an intermediate spring pusher in the line XXXIII-XXXIII in FIG. 43 (a). It is sectional drawing of an outer spring pushing body. (A) is a rear view of a slider, (b) is sectional drawing of the slider in the XXXIVb-XXXXIVb line | wire of Fig.44 (a). (A) is a front view of a rotating plate, (b) to (d) are front views of each spring pusher. (A) to (c) is a front view of each spring pusher. It is the table | surface which showed the relationship between the phase of a rotating plate, and a spring constant.

  First, a gaming machine according to the present invention, specifically, a slot machine will be described. 1 is a front view of the slot machine 10, FIG. 2 is a perspective view of the slot machine 10 with the front door 12 closed, and FIG. 3 is a perspective view of the slot machine 10 with the front door 12 opened.

  As shown in FIGS. 1 to 4, the slot machine 10 includes a housing 11 that forms an outer shell thereof. As shown in FIGS. 3 and 4, the housing 11 includes a top plate 11 a, a bottom plate 11 b, a back plate 11 c, a left side plate 11 d, and a right side plate 11 e that are formed in a plate shape. 11e is fixed by fixing means such as adhesion, so that it is formed in a box shape with the front surface opened as a whole. In addition, each board 11a-11e may be comprised with a synthetic resin panel or a metal panel other than being comprised with a wooden panel, or it is comprised by forming in the box shape integral with a synthetic resin material or a metal material. May be. The casing 11 configured as described above is attached by, for example, driving nails against a so-called island facility at the time of installation in the game hall.

  A front door 12 as a front open / close door is attached to the front side of the housing 11 so as to be openable and closable. That is, the left side plate 11d of the housing 11 is provided with a pair of upper and lower support shafts 25a and 25b as shown in FIG. Each of the support shafts 25a and 25b includes a tapered shaft portion that protrudes upward. On the other hand, as shown in FIG. 3, the front door 12 is provided with support brackets 26a and 26b having insertion holes into which the shaft portions of the support shafts 25a and 25b are inserted corresponding to the support shafts 25a and 25b. It has been. Then, the support brackets 26a and 26b are disposed above the support shafts 25a and 25b, and the front door 12 is lowered, whereby the shaft portions of the support shafts 25a and 25b are inserted into the insertion holes of the support brackets 26a and 26b. It is assumed that it was done. As a result, the front door 12 is supported so as to be rotatable about an opening / closing axis extending in the vertical direction connecting the both support shafts 25a and 25b to the housing 11, and the front opening side of the housing 11 is opened by the rotation. It can be closed or closed.

  The front door 12 is brought into a locked state that cannot be opened by a locking device provided on the rear surface. Moreover, as shown in FIG. 1, the key cylinder 20 which is an unlocking operation part is provided in the upper right side upper part of the front door 12. As shown in FIG. The key cylinder 20 is integrated with a locking device, and is configured such that the locked state is released by a predetermined key operation on the key cylinder 20. Therefore, an outline of the lock mechanism including the locking device will be described.

  On the right end side of the front door 12, that is, on the opposite side of the opening / closing axis of the front door 12, a locking device is provided on the back surface. As shown in FIGS. 1 and 3, the locking device includes a base frame that extends in the vertical direction and is fixed to the front door 12, and a key cylinder 20 that extends from the top of the base frame to the front of the front door 12. And a long interlocking rod 21 assembled so as to be movable in the vertical direction with respect to the base frame. And only the key cylinder 20 is provided in the state which protruded ahead of the front door 12 among the locking devices. The position where the key cylinder 20 is provided is the thin upper portion of the front door 12, and as a result, a versatile key cylinder 20 having a short overall length can be employed. In the present embodiment, Omlock (registered trademark) having a high function of preventing unauthorized unlocking is used as the key cylinder 20. The interlocking rod 21 is moved downward by operating the key inserted into the key cylinder 20 clockwise. The interlocking saddle 21 is provided with a pair of upper and lower saddle fittings 22 having a bowl shape. When the front door 12 is closed with respect to the casing 11, the saddle fitting 22 is supported on the casing 11 side. Is locked. In addition, the urging member 22 is provided with an urging member such as a coil spring for urging to the side maintaining the locked state. When the key is operated clockwise with respect to the key cylinder 20, the interlocking rod 21 moves downward, and the saddle fitting 22 is moved against the biasing force of the biasing member. The locked state with the support fitting 23 is released, and the locked state of the front door 12 with respect to the housing 11 is released.

  As shown in FIGS. 1 and 2, a game panel 30 for notifying the player of the game state is provided on the upper side of the central portion of the front door 12. In the game panel 30, three vertically long display windows 31L, 31M, and 31R are formed side by side. The display windows 31L, 31M, and 31R are made of a transparent or translucent material, and the inside of the slot machine 10 is visible through the display windows 31L, 31M, and 31R. The display windows 31L, 31M, and 31R may be combined into a single display window.

  As shown in FIG. 3, the inside of the housing 11 is vertically divided into two by a partition plate 40, and a reel unit 41 constituting variable display means is attached to the upper portion of the partition plate 40. The reel unit 41 includes a left reel 42L, a middle reel 42M, and a right reel 42R each formed in a cylindrical shape (annular shape). Each of the reels 42L, 42M, and 42R only needs to be configured as an endless belt, and is not limited to a cylindrical shape (annular shape). Each of the reels 42L, 42M, and 42R is rotatably supported so that the central axis thereof 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, and the reels 42L, 42M, and 42R have a one-to-one correspondence with the display windows 31L, 31M, and 31R. . Therefore, a part of the surface of each reel 42L, 42M, 42R can be visually recognized through the corresponding display windows 31L, 31M, 31R. Further, when the reels 42L, 42M, and 42R rotate forward, the surfaces of the reels 42L, 42M, and 42R are projected as if moving from top to bottom through the display windows 31L, 31M, and 31R.

  As shown in FIG. 5, the reels 42L, 42M, and 42R are connected to stepping motors 61L, 61M, and 61R, and the reels 42L, 42M, and 42R are driven by the stepping motors 61L, 61M, and 61R. Are configured to be able to rotate individually, that is, independently of each other. Since these reels 42L, 42M, and 42R have the same configuration, the left reel 42L is illustrated as a representative of each reel in FIG.

  The left reel 42L includes a cylindrical skeleton member 50 that forms a cylindrical cage, and a belt-like belt wound endlessly on the outer peripheral surface thereof. And it is affixed on the cylindrical skeleton member 50 through a pair of seal parts formed along the 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 at equal intervals on the outer peripheral surface of the belt.

  As shown in FIG. 5, the left reel stepping motor 61 </ b> L is fixed to the side surface of the motor plate 53 arranged in an upright state in the reel unit 41 (FIG. 3) with screws 54. The motor plate 53 is provided with a reel index sensor (rotational position detection sensor) 55 in which a light emitting element 55a and a light receiving element 55b are held at a predetermined interval. On the other hand, the base end portion 56b of the sensor cut bun 56 extending in the radial direction is fixed to the boss reinforcing plate 52 integrated with the left reel 42L with a screw 57. The front end portion 56a of the sensor cut bun 56 is bent at a substantially right angle and is positioned so that it can pass between both elements 55a and 55b of the reel index sensor 55. Each time the left reel 42L makes one rotation, the reel index sensor 55 detects the passage of the tip end portion 56a of the sensor cut bun 56, and outputs a detection signal to the main controller 131 described later each time the detection is made. Therefore, main controller 131 can confirm and correct the angular position of left reel 42L for each rotation based on this detection signal.

  The stepping motor 61L 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 61L, that is, The rotational position of the left reel 42L is controlled.

  On each belt of each of the reels 42L, 42M, and 42R, a plurality of, specifically, 21 symbols are drawn in the long side direction (circumferential direction). Therefore, 24 pulses (= 504 pulses ÷ 21 symbols) are required to switch from one symbol to the next symbol at a predetermined position. 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 display window 31L, or to visually recognize an arbitrary symbol from the exposure window 31L. It is possible to perform control to achieve a proper state.

  Of the symbols attached to the reels 42L, 42M, and 42R, the number of symbols that can be visually recognized through the display windows 31L, 31M, and 31R is mainly determined by the vertical length of the display windows 31L, 31M, and 31R. Is limited to a predetermined number. In this embodiment, three reels are provided. For this reason, 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. 6 shows a symbol array drawn on the belt wound around each of the left reel 42L, the middle reel 42M, and the right reel 42R. As shown in the figure, each of the reels 42L, 42M, and 42R is provided with 21 symbols in a row. Numbers 1 to 21 are assigned to the respective reels 42L, 42M, and 42R, but these are given for convenience of explanation and are not actually attached to the reels 42L, 42M, and 42R. . However, in the following description, the number is used for explanation.

  As the symbols, there are a “7” symbol (for example, the left belt 20th) and a “youth” symbol (for example, the left belt 19th) 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 the second special symbol for shifting to the regular bonus game. Further, there is a “replay” symbol (for example, the eleventh left belt) as a third special symbol for shifting to the replay game. In addition, a “watermelon” symbol (for example, the left belt ninth), a “bell” symbol (for example, the left belt eighth), and a “cherry” symbol (for example, left) as the small character symbols from which the small character is paid out. Belt 4th). In the belts wound around the reels 42L, 42M, and 42R, the number and arrangement order of various symbols are completely different.

  Each reel 42L, 42M, 42R of the reel unit 41 is an example of variable display means for variably displaying the identification information, and constitutes a main display unit. However, the variable display means may have other configurations. For example, other mechanical reel configurations such as a type in which the belt is rotated instead of rotating may be used, and instead of or in addition to the mechanical reel configuration, a liquid crystal display or a dot matrix display It is also possible to provide a display that variably displays the identification information by electrical display such as, and in this case, it is possible to provide a variety of display forms.

  In addition, backlight devices 100L, 100M, and 100R that illuminate the belts of the reels 42L, 42M, and 42R from the inside are disposed inside the reels 42L, 42M, and 42R.

  As shown in FIG. 7A, these backlight devices 100L, 100M, and 100R are attached to the respective reels 42L, 42M, and 42R in a one-to-one correspondence with the left backlight device 100L and the middle backlight. The apparatus 100M includes a right backlight apparatus 100R. As described above, each of the backlight devices 100L, 100M, and 100R includes the game panel 30 on the side surface of each of the motor plates 53L, 53M, and 53R arranged in correspondence with the reels 42L, 42M, and 42R. Is attached to the side. And each backlight apparatus 100L, 100M, 100R is arrange | positioned in the same position seeing to an up-down direction. FIG. 7A is an enlarged perspective view showing the periphery of the reel unit 41 in a state where the reels 42L, 42M, and 42R are removed. Moreover, FIG.7 (b) used by the following description is a front view of the left backlight apparatus 100L. In FIG. 7B, since the backlight devices 100L, 100M, and 100R all have the same structure, the left backlight device 100L is representatively illustrated.

  As shown in FIG. 7B, the left backlight device 100L has a box shape with the front side opened, and the length in the vertical direction and the length in the horizontal direction are substantially the same as those of the display window 31L (FIG. 1). A base 101L is provided. In the base 101L, two partition walls that divide the opening region are formed at equal intervals, so that the first opening region 102L, the second opening region 103L, and the third opening region 104L are formed in an upper stage, a middle stage, and a lower stage, respectively. It has a structure that is lined up. When the front door 12 is closed, the opening regions 102L, 103L, and 104L are arranged behind the positions corresponding to the upper, middle, and lower stages of the display window 31L. Specifically, the first opening area 102L is arranged behind the upper stage of the display window 31L, the second opening area 103L is arranged behind the middle stage of the display window 31L, and the third opening area 104L is arranged in the display window 31L. It is placed behind the lower stage. The opening front of the first opening region 102L is slightly upward, and the opening front of the third opening region 104L is slightly downward. Accordingly, the side surface of the base 101L has an arc shape that bulges toward the game panel 30 side.

  In each of the opening regions 102L, 103L, and 104L, four backlights 105 each made of a light emitting diode are disposed so as to stand forward. Two backlights 105 in each of the opening regions 102L, 103L, and 104L are arranged in two upper and lower rows with a predetermined interval, and the backlights 105 in each row are horizontal with a predetermined interval. Are lined up like That is, the left backlight device 100L includes a first line L1 that is an upper row of the first opening region 102L, a second line L2 that is a lower row, and a third line that is a row above the second opening region 103L. L3 and the fourth line L4, which is the lower row, the fifth line L5, which is the upper row of the third opening region 104L, and the sixth line L6, which is the lower row, total 6 in the vertical direction across the partition wall. There will be a line of backlight 105 in the column. The middle backlight device 100M and the right backlight device 100R also have a total of six lines of the backlight 105. As described above, the backlight devices 100L, 100M, and 100R are viewed in the vertical direction. Since they are arranged at the same position, the lines L1 to L6 of the backlight devices 100L, 100M, and 100R are located on the same line. That is, the line L1 is a line that horizontally connects a total of six backlights 105 arranged in a row above the first opening regions 102L, 102M, and 102R of the backlight devices 100L, 100M, and 100R. Become. The same applies to the other lines L2 to L6. Each backlight 105 is controlled for each of the lines L1 to L6. Accordingly, the backlight 105 is turned on and off for each of the lines L1 to L6.

  When the backlights 105 on the lines L1 to L6 are turned on, different positions of the belts of the reels 42L, 42M, and 42R are illuminated from the rear. As described above, each of the bases 101L, 101M, and 101R is divided into three opening regions 102 to 104 by the partition walls. Therefore, when the backlight 105 on the first line L1 and the second line L2 is turned on, only the inner surface of the belt near the position corresponding to the upper stage of the display windows 31L, 31M, 31R is illuminated, and the display window 31L , 31M, 31R, the inner surface of the belt near the positions corresponding to the middle and lower stages is not illuminated. This is the same when the backlight 105 on the other lines L3 to L6 is turned on. As described above, since the belt is formed of a material that can transmit the irradiated light to some extent, when the belt is illuminated from the rear by the backlight 105, the light transmitted through the belt is displayed on the display window 31L, It is visually recognized by the player through 31M and 31R. Further, when the reels 42L, 42M, and 42R are rotating, the symbols attached to the belt passing in front of the lit backlight 105 are emphasized.

  As shown in FIG. 1, the game panel 30 has a combination line of 3 display windows 31L, 31M and 31R, 3 in parallel in the horizontal direction and 2 in the diagonal direction. Is attached. Of course, the maximum number of combined lines may be 6 or more, or less than 5, and the maximum number of combined lines may be changed according to a predetermined condition. Corresponding to each of these combination lines, effective line display sections 32, 33, and 34 are provided on the left side as viewed from the front of the display windows 31L, 31M, and 31R. 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. When the upper and lower horizontal lines (upper line and lower line) of the combination lines are activated, the second effective line display unit 33 is displayed and notified by lighting or the like. The third effective line display unit 34 is notified by lighting or the like when a pair of diagonal lines (downward right line and upward right line) of the combination lines is activated. A winning is awarded when the symbols are stopped in a predetermined combination on the activated combination line, that is, on the activated line, and a predetermined medal payout process, a transition process to a specific game, and the like are executed.

  Here, the payout number regarding each symbol when winning is explained. Regarding the small role design, when the “Watermelon” design is aligned with the left, middle and right on the active line, 15 medals are paid out. When the “Bell” design is aligned with the left, middle and right on the effective line Pays out 8 medals, and when the “cherry” symbol on the left reel 42L stops on the active line, 2 medals are paid out. That is, the “cherry” symbols of the middle reel 42M and the right reel 42R are irrelevant to the medal payout. In addition, for the “cherry” symbol, the medal payout is performed regardless of the combination with other symbols, and therefore, a plurality of effective lines of the left reel 42L overlap (specifically, the upper or lower row) with “ When the “cherry” symbol is stopped, medals are paid out by multiplying the number of overlapping active lines. As a result, in this embodiment, four medals are paid out.

  As for other symbols, when the “7” symbol or “youth” symbol, which is a combination of the first special symbol (big bonus symbol), is aligned with the left, middle and right on the active line in the same symbol The 15 medals are also paid out when the “BAR” symbol which is a combination of 15 medal payouts and the second special symbol (regular bonus symbol) is aligned with the left, middle and right on the active line. In the present embodiment, for example, a case where the “7” symbol and the “cherry” symbol are established simultaneously may occur, but in this case, 15 medals are paid out. This is because the upper limit number for one medal payout is set to 15.

  Further, when the “replay” symbol, which is the combination of the third special symbol, is aligned with the left, middle, and right on the active line, the medal payout is not performed. In other cases, that is, when the “cherry” symbol of the left reel 42L does not stop on the active line and the same symbols as the left, middle, and right are not aligned on the active line, no medal payout is performed.

  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 simultaneously) is provided on the lower left side of the game panel 30 as shown in FIG. . The start lever 71 constitutes start operation means or start operation means operated to start rotation of the reels 42L, 42M, and 42R, that is, to start variable display. The start lever 71 is a lever that is pushed by the hand when the player starts the game, and automatically returns to the original position after the hand is released. When the start lever 52 is operated while a medal is inserted, the reels 42L, 42M, and 42R start to rotate all at once.

  On the right side of the start lever 71, button-like stop switches 72, 73, and 74 that are operated to individually stop the rotating reels 42L, 42M, and 42R are provided. The stop switches 72, 73, and 74 are respectively disposed below the display windows 31L, 31M, and 31R corresponding to the reels 42L, 42M, and 42R to be stopped. The stop switches 72, 73, 74 constitute stop operation means that are operated to stop variable display based on the rotation of the reels 42L, 42M, 42R. Each of the stop switches 72, 73, 74 can be stopped when each of the reels 42L, 42M, 42R is rotated at a constant speed. During such a state, the lamps (not shown) are turned on and stopped. It is notified that the operation is possible, and is turned off when the rotation stops.

  On the lower right side of the display windows 31L, 31M, 31R, a medal inserter 180 for inserting medals as an investment value is provided. The medal inserter 180 constitutes an input means for inputting the investment value. Further, if attention is paid to the point that the medal insertion device 180 involves an operation of directly inserting a medal by the player, it can be said that the medal insertion device 180 constitutes a direct input means for directly inputting the investment value.

  The details of the medal inserter 180 in this embodiment will be described later.

  As shown in FIG. 3, the medal inserted from the medal inserter 180 is guided to either the storage passage 81 or the discharge passage 82 by the selector 84 provided on the back surface of the front door 12.

  FIG. 8 is a diagram showing the internal structure of the selector 84. The two-dot chain line in the figure indicates the medal passage route for easy understanding. The selector 84 is formed with a guide passage 85 for guiding medals inserted from the medal inserter 180 to the storage passage 81. The guide passage 85 is formed in a curved line that draws an arc from the upper end to the lower right in the drawing so that medals can pass in one row. More specifically, the selector body constituting the selector 84 is provided with a protrusion 85a protruding toward the front side of the figure, and a guide passage 85 is formed along the protrusion 85a. Thereby, the medal that has reached the guide passage 85 flows in the downstream direction so as to roll on the ridge 85a.

  The medal passage switching member 83 includes a passage switching piece 83a that is provided in the upstream portion of the guide passage 85 and can be moved in and out of the guide passage 85, and a solenoid (not shown) for operating the passage switching piece 83a. is doing. When the solenoid is not excited, the passage switching piece 83a 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 protrusion 85 a and is guided to the discharge passage 82. Further, the passage switching piece 83a is sunk outside the guide passage 85 when the solenoid is excited. Thereby, 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 83a, a first inserted medal detection sensor 86 and a second inserted medal detection sensor 87 for detecting the passage of medals are arranged close to each other so as to be arranged upstream and downstream of the guide passage 85. (At least one time is set to a close state where the same medal is detected at the same time). When the solenoid of the medal path switching member 83 is not energized, the medal falls downward from the middle of the guide path 84, so that the inserted medal detection sensors 86 and 87 do not detect the passage of the medal. On the other hand, when the medal passage switching member 83 is energized with solenoid, the inserted medal detection sensors 86 and 87 sequentially detect the passage of medals.

  Then, the medal guided to the storage passage 81 is guided to the hopper device 91 housed in the housing 11. On the other hand, the medal guided to the discharge passage 82 is guided to the medal tray 18 from the medal discharge port 17 provided in the lower front portion of the front door 12 and returned to the player.

  As shown in FIGS. 3 and 4, the hopper device 91 serving as a payout means for giving a medal to a player includes a storage tank 92 for storing a medal and a payout device 93 for paying out a medal to the player. Yes. The payout device 93 rotates a medal payout rotating plate (not shown) to discharge the medal to the opening 94 provided in the central right part of the discharge passage 82 and to the medal tray 18 through the discharge passage 82. To come out. Further, a reserve tank 95 is provided on the right side of the hopper device 91 in order to avoid storing a predetermined amount or more of medals in the storage tank 92. A guide plate 96 for discharging medals from the storage tank 92 to the reserve tank 95 is provided inside the storage tank 92 of the hopper device 91. Therefore, when medals are stored more than the height at which the guide plate 96 is provided, the medals are stored in the reserve tank 95 via the guide plate 96.

  A button-like return switch 76 (FIG. 1) is provided below the medal inserter 180. The return switch 76 is a switch that is pressed when a medal inserted into the medal inserter 180 is jammed in the selector 84. When this switch is pressed, the selector 84 is mechanically interlocked to operate. The medals packed in 84 are returned from the medal discharge port 17.

  As shown in FIG. 1, a first credit insertion switch 77, a second credit insertion switch 78, and a third credit insertion switch 79 are provided on the lower left side of the display windows 31L, 31M, 31R. The first credit insertion switch 77 is for inserting three credited virtual medals as investment value at a time, and the second credit insertion switch 78 is for inserting two credited virtual medals at a time. The third credit insertion switch 79 is for inserting one virtual medal. Each of the credit insertion switches 77 to 79, together with the medal insertion device 180, constitutes an input means for inputting an investment value. Further, if the medal insertion device 180 is accompanied by an operation of directly inserting a medal by the player, each credit insertion switch 77 to 79 is only accompanied by an operation of inserting a virtual medal based on the storage memory. It can also be said that it constitutes an indirect input means for indirectly inputting the investment value.

  Note that the first credit insertion switch 77 has a built-in lamp as a light emitting member (not shown) in order to notify that the maximum number of medals that can be inserted per game (three) has not been reached. The lamp is turned on when the switch operation of the first credit insertion switch 77 is valid and prompts the operation of the switch 77. However, when there is no credited virtual medal or three medals have already been inserted. It is turned off under the circumstances. Here, instead of the above-described lighting, the player may make it easier to understand the prompt for medal insertion by blinking.

  A button-like changeover switch 80 is provided on the left side of the start lever 71. The change-over switch 80 is configured to be a toggle type that is turned on when pressed once, turned off when pressed again, and turned on / off every time the pressing operation is performed. The changeover switch 80 is operated in order to change the handling format of inserted medals inserted into the medal inserter 180 more than necessary, or acquired medals returned to the player as a result of a predetermined game.

  When the change-over switch 80 is in the ON state, the “credit mode” is set so that surplus inserted medals up to a predetermined maximum value (for example, 50 medals) and winning medals are stored and stored as credit medals. " When the changeover switch 80 is in the OFF state, the “direct mode” is set so that surplus inserted medals and winning medals are paid out as actual medals. If there is a credit medal when the credit mode is switched to the direct mode, the corresponding credit medal is paid out as an actual medal. Thus, 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 changing over the input value and game value handling formats. Further, if paying attention to the function of paying out a 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 game value. In addition to being configured to switch between the “credit mode” and the “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 be made to function as only a settlement switch.

  Below the display windows 31L, 31M, and 31R of the game panel 30, a remaining number display unit 35 that displays the number of medals that are activated and stored in the credit mode, and a special game state such as a big bonus or a regular bonus are displayed. In this case, for example, a game number display unit 36 for displaying the number of remaining games and an acquired number display unit 37 for displaying the number of acquired medals are provided. Although these display parts 35-37 are comprised by the 7 segment display, it is naturally possible to substitute by a liquid crystal display etc. FIG.

  Here, a procedure for betting medals will be described. In both the direct mode and the credit mode, a bet is placed when a medal is inserted from the medal inserter 180 at the start of the game.

  That is, when the first medal is inserted into the medal inserter 180, the first effective line display unit 32 is turned on, and the corresponding center line becomes the effective line, and the second medal is the medal inserter. When it is inserted into 180, the second effective line display section 33 is further lit, and a total of three combination lines including the upper line and the lower line corresponding thereto become effective lines, respectively, and the third medal is a medal. When inserted into the input device 180, the third effective line display unit 34 is further turned on, and all five combination lines including a pair of diagonal lines corresponding thereto become effective lines.

  When four or more medals are inserted into the medal inserter 180, the surplus medals exceeding three are switched to the discharge passage 82 by the selector 84 if the current mode is the direct mode. It is returned from the outlet 17 to the medal tray 18. On the other hand, in the credit mode, it is stored inside the slot machine, and the number of stored sheets is displayed on the remaining number display unit 35. An upper limit number is determined for the number of stored sheets (for example, 50), and when a medal exceeding the number is inserted, it is returned from the medal discharge port 17 to the medal tray 18.

  In addition, when a game is played in the credit mode and the number of stored items is displayed on the remaining number display unit 35, the virtual number is displayed even when any of the first to third credit insertion switches 77 to 79 is pressed. A medal has been inserted and the player bet.

  When the third credit insertion switch 79 is pressed, the numerical value displayed on the remaining number display section 35 is decremented by one as a virtual medal is inserted, and the first effective line display section 32 is displayed. Illuminates and the center line becomes the active line. When the second credit insertion switch 78 is pressed, two numerical values displayed on the remaining number display unit 35 are decremented as two virtual medals are inserted, and the first valid line display unit 32 and The second effective line display section 33 is lit 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 three virtual medals are inserted, and all the effective line display units 32 to 32 are decremented. 34 lights up and a total of five combination lines become effective lines.

  In addition, when the virtual medal to be inserted when any of the first to third credit insertion switches 77 to 79 is pressed is not stored, for example, when the display of the remaining number display unit 35 is 2, the first For example, when the credit insertion switch 77 is pressed, all the values in the remaining number display section 35 are decremented to 0, and a bet is made for the amount of virtual medals that can be inserted.

  On the upper part of the front door 12, there are an upper lamp 13 that lights up or flashes as the game progresses, and a pair of left and right sounds that make various sound effects as the game progresses and inform the player of the game state Speaker 14 and an auxiliary display unit 15 for giving various information to the player. In the present embodiment, the auxiliary display unit 15 is configured by a liquid crystal display for the purpose of diversifying display contents and increasing the display effect. However, other displays such as a dot matrix display may be used. Good. The auxiliary display unit 15 is for executing various display effects as the game progresses, and it can be considered that the game by the reels 42L, 42M, and 42R is caused by the main display unit. This is referred to as an auxiliary display unit 15. A sub-control device 111 for driving the upper lamp 13, the speaker 14, the auxiliary display unit 15, the backlight 105, and the electric motor 223a is provided on the back surface of the auxiliary display unit 15. Note that the positions and number of the upper lamps 13 and the speakers 14 are not particularly limited to those described above.

  A lower plate 16 on which a model name, a character related to a game, and the like are displayed is mounted above the medal tray 18. In addition, an ashtray 19 that can be reversed to the lower side on the front side is provided on the left side of the medal tray 18.

  A power supply box 121 is provided on the left side of the hopper device 91 inside the housing 11. The power supply box 121 includes a power 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 controller 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, and even if a power failure occurs, it retains the state at the time of the power failure and returns to the state at the time of the power failure at the time of recovery from power failure (power recovery). It can be done. Therefore, for example, when the power supply is shut down by a normal procedure, for example, when the game hall is closed, the state before the power shut-off is stored and retained. 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 used by a hole manager or the like to adjust the appearance of medals. That is, the setting state (winning probability setting process) of the slot machine 10 can be changed from “setting 1” to “setting 6” by operating the hole manager or the like by inserting the setting key into the setting key insertion hole 124. It has become.

  As shown in FIG. 4, a main control device 131 is attached to the back plate 11 c of the housing 11 above the reel unit 41. The main control device 131 includes 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 that communicates with various devices, time counting and synchronization. A main board including a clock circuit and the like used in the case of planning is provided, and the main board is accommodated in a board box as an encapsulating means made of a transparent resin material or the like.

  Next, the electrical configuration of the slot machine 10 will be described based on the block diagram of FIG.

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

  On the input side of the main controller 131, a start detection sensor 71a that detects the operation of the start lever 71, stop detection sensors 72a, 73a, and 74a that individually detect the operations of the stop switches 72, 73, and 74, a medal inserter The inserted medal detection sensor 75a for detecting medals inserted from 180, the credit insertion detection sensors 77a, 78a, 79a for individually detecting the operations of the respective credit insertion switches 77, 78, 79, and the switching for detecting the operation of the changeover switch 80. Detection sensor 80 a, reel index sensor 55 that individually detects the rotational position (origin position) of each reel 42, payout detection sensor 91 a that detects medals paid out from the hopper device 91, and reset detection sensor that detects the operation of the reset switch 123 123a, set in the setting key insertion hole 124 Key is connected to various sensors such as setting the key detection sensor 124a for detecting that it has been inserted, the signals from these various sensors are outputted to the CPU151 through the input and output ports 155.

  The inserted medal detection sensor 75a is actually composed of a plurality of sensors. The main control device 131 monitors the order in which the first sensor and the second sensor are turned on / off, the first and second sensors are both off, only the first sensor is on, the first and second sensors are both on, It is determined that the medal has been normally taken in only when the sensor is turned on and both the first and second sensors are turned off and when the time for switching to each on / off switch is within a predetermined time. Otherwise, it is an error. The reason for this is to prevent fraud in which a medal is reciprocated near the inserted medal detection sensor 75a and misidentified as a medal inserted.

  Further, a power failure monitoring circuit 161 b 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. On the power supply board 161, a power supply unit 161 a that supplies driving power to each electronic device of the slot machine 10 including the main control device 131, the power failure monitoring circuit 161 b described above, and the like are mounted.

  The power failure monitoring circuit 161b is for monitoring the power-off state and generating a power failure signal not only at the time of power failure but also at the time of power-off by the power switch 122. For this reason, the power failure monitoring circuit 161b monitors the stabilized drive voltage of 12 VDC in this example output from the power supply unit 161a, and determines that the power supply is shut off when the drive voltage drops below, for example, 10 volts. Power outage signal is output. The power failure signal is supplied to each of the CPU 151 and the input / output port 155, and the CPU 151 recognizes this power failure signal and executes a power failure process described later.

  Even when the output voltage drops below 22 volts, the power supply unit 161a is configured to output a stabilized voltage of 5 volts that is used as a drive voltage in a control system such as the main controller 131. As the time during which the stabilization voltage is output, sufficient time is secured to execute the power failure process by the main controller 131.

  On the output side of the main controller 131, each of the effective line display units 32, 33, 34, the remaining number display unit 35, the game number display unit 36, the acquired number display unit 37, and the reels 42L, 42M, 42R is rotated. Stepping motors 61 (61L, 61M, 61R), a medal path switching solenoid 83 provided in the selector 84, a hopper device 91, a sub-control device 111, an external concentration terminal plate 171 capable of transmitting information to a hall management device (not shown), etc. Are connected via the input / output port 155.

  The sub-control device 111 is a control device for driving the upper lamp 13, the speaker 14, the auxiliary display unit 15, the backlight 105, and the electric motor 223a, and a CPU, ROM, RAM, and the like for driving these are integrated. Provided with a substrate. Then, after receiving a signal from the main control device 131, the sub-control device 111 independently drives and controls the upper lamp 13, the speaker 14, and the auxiliary display unit 15. Therefore, the sub-control device 111 is a sub-base that executes auxiliary control in relation to the main control device 131 that is a main base that manages and manages the game. In other words, the sub-base is provided for voice, lamp, and display related to indirect games, thereby reducing the burden on the main base. In addition, it is good also as a structure which the sub control apparatus 111 controls the various display parts 32-37.

  The CPU 151 described above stores various control programs executed by the CPU 151 and a ROM 152 storing fixed value data, and temporarily stores various data when the control program stored in the ROM 152 is executed. In addition to the RAM 153 for securing the area, although not shown, various processing circuits necessary for the slot machine 10 such as an interrupt circuit, a timer circuit, a data transmission / reception circuit, etc., as well known, and a credit counter for counting the number of credits Various counters such as are built-in. The ROM 152 and the RAM 153 constitute a main memory as storage means, and a program for executing the processes shown in the various flowcharts shown in FIGS. 10 to 19 is stored in the ROM 152 described above as a part of the control program. Yes.

  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 and data can be retained (backed up) even after the power of the slot machine 10 is shut off. In addition to a memory and an area for temporarily storing various data and the like, a backup area is provided.

  In the backup area, when the power is shut down due to the occurrence of a power failure or the like, the values of the stack pointer, each register, I / O, etc. when the power is shut down (including power shut down by operating the power switch 122; the same applies hereinafter) When the power failure is resolved (including power-on by operating the power switch 122. The same applies hereinafter), the slot machine 10 is in the state before power-off based on the backup area information. It is possible to return to the state. Writing to the backup area is executed when the power is shut off by the power failure process (see FIG. 12), and the restoration of each value written in the backup area is executed in the main process (see FIG. 13) when the power is turned on. Note that a power failure signal from the power failure monitoring circuit 161b is input to the NMI terminal (non-maskable interrupt terminal) of the CPU 151 when the power is interrupted due to the occurrence of a power failure or the like. NMI interrupt processing as flag generation processing is immediately executed.

  Subsequently, each control process executed by the CPU 151 in the main control device 131 will be described with reference to the flowcharts of FIGS. The processing of the CPU 151 is roughly divided into a main processing that is started when the power is turned on, a timer interrupt processing that is started periodically (in a cycle of 1.49 msec in the present embodiment), and an NMI terminal (non-maskable terminal). For convenience of explanation, the NMI interrupt process and the timer interrupt process will be described first, and then the main process will be described.

  FIG. 10 is a flowchart illustrating an example of the NMI interrupt process. When the power is shut off due to the occurrence of a power failure or the like, the power failure monitoring circuit 161b of the power supply device 161 generates a power failure signal and outputs it to the main controller 131. In the main controller 131 that has received the power failure signal via the NMI terminal, NMI interrupt processing is executed.

  In the NMI interrupt processing, first, in step S 101, the data of the used register provided in the CPU 151 is saved in the backup area provided in the RAM 153. Subsequently, in step S102, the power failure flag is set in a power failure flag storage area provided in the RAM 153. Thereafter, the data saved in the backup area of the RAM 153 in step S103 is restored to the use register of the CPU 151 again. With this return processing, the NMI interrupt processing ends. If the power failure flag can be set without destroying the data in the register used by the CPU 151, the saving and restoring processing to the backup area can be omitted.

  FIG. 11 is a flowchart of timer interrupt processing periodically executed by the main control device 131, and a timer interrupt is generated by the CPU 151 of the main control device 131 every 1.49 msec, for example.

  First, in the register saving process shown in step S201, the values of all the registers in the CPU 151 used in the normal process described later are saved in the backup area of the RAM 153. In step S202, it is confirmed whether or not a power failure flag is set. If the power failure flag is set, the process proceeds to step S203, and a power failure process is executed.

  Here, the power failure process will be described with reference to FIG. Since the power failure process is performed immediately after the register saving process in the timer interrupt process, other interrupt processes can be executed without interruption. Therefore, for example, during the transmission process of various commands and during the reading process of the switch state (ON or OFF), the interruption process is not executed and this power failure process is not executed. This eliminates the need to create a power failure processing program that takes this into consideration. This simplifies the processing program for power failure processing and reduces the program capacity. This also applies to a processing program for power recovery processing described later.

  In step S301, it is determined whether command transmission has been completed. If the transmission has not ended, the process returns to the original process of FIG. In this way, it is determined whether or not the command transmission is completed at the initial stage of the power failure process, the transmission process is prioritized when the transmission is incomplete, and the power failure process is executed after the unit command transmission process is completed. By doing so, it is no longer necessary to construct a power failure processing program that takes into account that power failure processing is executed during command transmission. As a result, the power failure processing program can be simplified and the ROM 152 can be reduced in capacity.

  If step S301 is YES, that is, if the command transmission is completed, the process proceeds to step S302, and the value of the stack pointer of the CPU 151 is stored in the backup area in the RAM 153. Thereafter, in step S303, a RAM determination value, which will be described later, is cleared as a stop process and the output state of the output port in the input / output port 155 is cleared, and all actuators (not shown) are turned off. In step S304, a RAM determination value is calculated and stored in the backup area. The RAM determination value is specifically a 2's complement of the checksum value at the work area address of the RAM 153. By storing the RAM determination value in the backup area, the checksum of the RAM 153 becomes zero. By setting the checksum of the RAM 153 to 0, subsequent RAM access is prohibited in step S305. After that, an infinite loop is entered in preparation for the case where the power supply is completely shut down and processing cannot be executed.

  The power supply unit 161a of the power supply device 161 holds the output of the stabilization voltage (5 volts) used as the drive voltage for the control system for a time sufficient to execute the above-described NMI interrupt processing and power failure processing. It is comprised so that. In the present embodiment, the drive voltage is continuously output for 30 msec.

  Returning to the description of the timer interrupt process, if the power failure flag is not set in step S202, various processes after step S204 are performed.

  That is, in step S204, a watchdog timer clearing process for initializing the value of the watchdog timer for monitoring the occurrence of malfunction is performed. In step S205, an interrupt end declaration process for giving an interrupt permission to the CPU 151 itself is performed. In step S206, in order to rotate the reels 42L, 42M, and 42R, a stepping motor control process for driving the stepping motors 61L to 61R, which are the respective rotary drive motors, is performed. In step S207, sensor monitoring processing for monitoring the state of various sensors (see FIG. 14) connected to the input / output port 155 is performed. In step S208, timer calculation processing for subtracting the value of each counter or timer is performed. In step S209, counter processing for counting the number of medals bet and the number of payouts is performed.

  In step S210, command output processing for transmitting a command or the like to the sub-control device 111 is performed. In step S211, a segment data setting process for setting segment data displayed on the remaining number display unit 35, the game number display unit 36, and the acquired number display unit 37 is performed. In step S212, segment data set processing in the segment data setting processing is supplied to the display units 35 to 37, and segment data display processing for displaying corresponding numbers, symbols, and the like is performed. In step S213, port output processing for outputting data corresponding to the I / O device from the input / output port 155 is performed. In step S214, the value of each register saved in the backup area in the previous step S201 is restored to the corresponding register in the CPU 151. Thereafter, in step S215, an interrupt permission process for permitting the next timer interrupt is performed, and this series of timer interrupt processes is terminated.

  FIG. 13 is a flowchart showing a main process in main controller 131 executed after power-on. The main processing is executed when power is turned on by recovery from a power failure or by turning on the power switch 122.

  First, in step S401, as initialization processing, the value of the stack pointer is set in the CPU 151, and an interrupt mode that permits interrupt processing is set. Thereafter, various settings for the register group in the CPU 151, the I / O device, and the like are set. And so on.

  When these initialization processes are completed, it is next determined in step S402 whether or not the reset switch 123 has been turned on. If the reset switch 123 has been turned on, the process proceeds to step S403, and all data stored in the RAM 153 is cleared as a RAM clear process.

  After confirming that the reset switch has not been operated in step S402 or performing a RAM clear process in step S403, it is determined in step S404 whether or not a setting key has been inserted into the setting key insertion hole 124. To do. If the setting key has been inserted, the process proceeds to step S405 to perform setting change processing. As the setting change process, first, all data stored in the RAM 153 is cleared. Then, after determining which setting state is selected from the six preset setting states (“Setting 1” to “Setting 6”), internal processing corresponding to the selected setting state is executed. .

  In step S406, it is confirmed whether or not a power failure flag is set. When the power failure flag is not set, that is, when the data in the RAM 153 is cleared in the previous step S403 or step S405, the process proceeds to a normal process in step S407 to be described later, and this process ends.

  When the power failure flag is set in step S406, the process proceeds to the power recovery process shown in step S408 and thereafter. The fact that the power failure flag is set means that subroutine processing such as RAM clear processing in step S403 and setting change processing in step S405 is not executed at all. Therefore, the data in the RAM 153 is not rewritten at all, and the power recovery process requires confirmation processing such as whether or not the data in the RAM 153 is normal.

  For this purpose, first, in step S408, it is confirmed whether or not the RAM determination value is normal. More specifically, the checksum of the RAM 153 is checked to check whether the value is normal, that is, whether the checksum taking into account the RAM determination value is 0. If the checksum value including the RAM determination value is 0, it is determined that the data in the RAM 153 is normal.

  If the RAM determination value is abnormal in step S408, that is, if the checksum value is not 0, there is a high possibility that the data in the RAM 153 has been destroyed. Therefore, in such a case, an error display process is performed in step S409. As error display processing, interrupt processing is first prohibited and all output ports in the input / output port 155 are cleared to control all actuators connected to the input / output port 155 to an off state. Thereafter, an error display for notifying the occurrence of an error to the hall manager or the like is performed, and this state is maintained until the reset switch 123 is turned on.

  If it is determined in step S408 that the RAM determination value is normal, the process proceeds to step S410, the stack pointer value stored in the backup area is written to the stack pointer of the CPU 151, and the stack state before the power is shut off is written. Return to the state. Next, in step S411, a power recovery command for transmitting the power recovery process is transmitted to the sub-control device 111. Thereafter, in step S412, the game state is stopped and automatic settlement setting storage processing is performed. In step S413, various sensors such as the start detection sensor 71a are initialized. After the above processing is completed, the power failure flag is reset in step S414, and the processing returns to the address before the power is shut off. Specifically, the process returns to the timer interrupt process described above, and the watchdog timer clear process (step S204) is executed.

  Next, normal processing for performing main control related to the game will be described based on the flowchart of FIG.

  First, in step S501, it is determined whether or not a medal is bet. If a medal is bet, it is subsequently determined in step S502 whether the start lever 71 has been operated. If both step S501 and step S502 are YES, the lottery process in step S503, the reel control process in step S504, the medal payout process in step S505, and the special game state process in step S506 are executed in order, and the process returns to step S501. On the other hand, if no medal is bet in step S501 or the start lever 71 is not operated in step S502, the process returns to step S501.

  Next, the lottery process in step S503 will be described based on the flowchart of FIG.

  In step S601, the random number table for determination of success / failure is selected based on the current setting state of the slot machine 10, the number of medals bet, and the small / probable combination probability. Here, the setting state of the slot machine 10 is any one of “setting 1” to “setting 6” set using a setting key (not shown), and the random number having the lowest winning probability of the combination when “setting 1” is set. A table is selected, and when “setting 6” is selected, the random number table having the highest winning probability of the combination is selected. Further, the number of medals bet is any one of 1 to 3, and a random number table is selected such that the winning probability of winning combination increases as the number of bets increases. For example, the winning probability of a winning combination when three bets are higher than the winning probability of winning when a single bet is three times. In addition, there are two types of small role probabilities: a random number table with a high small role winning probability is selected when the current payout rate is lower than the predetermined expected value, and small when the current winning rate is higher than the predetermined expected value. A random number table with a low winning probability is selected.

  In step S602, a random number table selected in this way is used for lottery in light of the random numbers latched by the random number counter when the start lever 71 is operated. In step S603, it is determined whether or not any of the winning combinations has been won. If any of the winning combinations has not been won, the process is terminated. If any of the winning combinations is won, the process proceeds to step S604, where a winning flag corresponding to the winning combination is set and an effective line to be aligned is determined. In step S605, a slip table for reel stop control is determined and stored in the slip table storage area of the RAM 153. Here, when the symbols on the predetermined effective line at the timing when the stop switches 72 to 74 are pressed are different from the symbols to be stopped on the effective line, the slip table is a predetermined symbol to be stopped. It is a table that defines how much the reel slides so as to stop on the active line.

  Next, the reel control processing in step S504 will be described based on the flowchart of FIG.

  In the reel control process, first, a wait process is performed in step S701. This wait process is a process of waiting without starting the reel rotation in the current game until a predetermined time (for example, 4.1 seconds) elapses from the time when the reel rotation is started in the previous game. Therefore, even if the player bets a medal and operates the start lever 71, the reels 42L, 42M, and 42R may not immediately rotate. Following the weight process, the reel rotation process of step S702 is performed to rotate the reels 42L, 42M, and 42R. Thereafter, the process proceeds to step S703, and it is determined whether or not any of the stop switches 72 to 74 is pressed to generate a reel stop command. If no stop command has been issued, the process advances to step S704 to determine whether or not a predetermined maximum rotation time (for example, 40 seconds) of each reel 42L, 42M, 42R has elapsed. If the maximum rotation time has not elapsed, the process returns to step S703. If the maximum rotation time has elapsed, the process proceeds to step S705 to perform a forced stop process for forcibly stopping all the rotating reels.

  On the other hand, if any one of the stop switches 72 to 74 is pressed in step S703 and a stop command is generated, the process proceeds to step S706 to perform reel stop processing. In this reel stop process, the reel corresponding to the pressed stop switch is stopped. If a winning combination is won in the winning lottery and the winning flag is set, the reel is stored in the sliding table storage area of the RAM 153. With reference to the sliding table, control is performed so that the winning combinations are arranged on a predetermined effective line as much as possible. For example, when the “watermelon” symbol is lined up on the lower line and the stop switch is pressed at the timing when the “watermelon” symbol stops on the upper line, the symbol 2 is set so that it stops on the lower line. Slide the reel as much as you can. However, since the range that can be slid is determined in advance (for example, up to four symbols), the “watermelon” symbol may not stop on the lower line depending on the timing of pressing the stop switch. Even in the forced stop process in step S705, if the winning flag is set, the same process is performed.

  Subsequently, in step S707, it is determined whether or not the current stop command is the first stop command, that is, whether or not the stop switch has been pressed when all three reels are rotating. In the case of the first stop command, the process proceeds to step S708, and the slip table changing process is performed. In this slide table change process, for example, it is determined whether or not a combination of combinations occurs when trying to align a combination on the selected active line, and when a combination of combinations does not occur, the process proceeds to the next step as it is. When a combination of combinations occurs, the selected effective line is changed to another effective line, and after changing to a sliding table suitable for the changed effective line, the process proceeds to the next step. Here, “combination of a combination” means that, for example, when a “watermelon” symbol is arranged on the upper line, a “cherry” symbol appears on the lower line when the “cherry” symbol appears on the lower line. Refers to cases. The slip table changing process may be performed other than when avoiding the combination of the combinations.

  On the other hand, if the current stop command is not the first stop command in step S707, the process proceeds to step S709 to determine whether the second stop command is present, that is, one of the three reels is stopped and the two reels are rotating. It is determined whether or not the stop switch has been pressed. If it is the second stop command, the process proceeds to step S710 and a stop eye determination process is performed. In this stop eye determination process, when two reels are stopped, it is determined whether or not the two are aligned with a bonus symbol such as “7” symbol. If they are not aligned, the process proceeds to the next step as it is. When sound effects are generated from the speaker 14, the process proceeds to the next step. In the stop eye determination process, it may be determined whether another condition other than two bonus symbols is satisfied, or an effect using the auxiliary display unit 15 may be performed in addition to the sound effect.

  Then, after the forced stop process in step S705, after the slip table change process in step S708, when the current stop command is not the second stop command in step S709, or the stop eye determination process in step S710 is performed. After that, in step S711, it is determined whether or not all rotations of the left, middle, and right reels 42L, 42M, and 42R have stopped. If step S711 is NO, the process returns to step S703. If YES, the payout determination process is performed in the subsequent step S712, and then the process ends. In the payout determination process, it is determined whether or not the winning combination is arranged on the effective line. When the winning combination is not aligned on the effective line, 0 is set in the payout number storage area of the RAM 153, and the winning combination is aligned on the effective line. When it is, it is determined whether or not the winning combination matches the winning combination, and if not, an error is displayed by the upper lamp 13 or the like and 0 is set in the scheduled payout number storage area. If they match, the number of payouts corresponding to the combinations arranged in the payout amount storage area is set.

  Next, the medal payout process in step S505 will be described based on the flowchart of FIG.

  In the medal payout process, first, it is determined whether or not the payout number counted by the payout number counter in step S801 matches the planned payout number stored in the payout planned number storage area. If the number of payouts does not match the planned payout number, it is determined in step S802 whether or not the game is being performed in the credit mode. If it is in the credit mode, it is determined in step S803 whether or not the count value of the credit counter has reached the upper limit (the number of stored medals is 50). If the upper limit is not reached, the count value of the credit counter and the number of payouts are each incremented by 1 in step S804. Accordingly, the remaining number display unit 35 and the acquired number display unit 37 are each incremented by one.

  On the other hand, when the game is performed in the direct mode, or when the count value of the credit counter reaches the upper limit, the medal payout rotary plate is driven in step S805 and the medal is discharged from the hopper device 91 to the medal discharge port. 17 through the medal tray 18. At this time, in step S806, the number of payouts is incremented by 1 according to the medal detection signal of the payout detection sensor 91a attached to the hopper device 91. As a result, the number of acquired number display section 37 is incremented by one. Then, after the payout number is incremented by 1 in step S804 or step S806, the process returns to step S801 again. When the number of payouts and the planned number of payouts match in step S801, the medal payout rotating plate of the hopper device 91 is stopped in step S807, and this process is terminated. The payout number / acquired number display section 37 is reset when the start lever 71 is operated next time.

  Next, the special game state process of step S506 will be described based on the flowchart of FIG.

  Prior to the description of the special game state process, the bonus game will be described. The regular bonus (hereinafter referred to as “RB”) game is composed of 12 JAC games. The JAC game is a game in which only one bet is allowed, and is a game with a very high probability that the JAC symbols (replay symbols in this case) are aligned on the active line, that is, the probability of establishment of the JAC symbols. When a JAC symbol is established in a JAC game, the maximum number (15 in this case) of medals is paid out. When the JAC symbol is established 8 times, the RB game is ended even before the JAC game reaches 12 times. On the other hand, the big bonus (hereinafter referred to as “BB”) game is composed of 30 small role games and 3 JAC ins. A small role game is a game in which a small role is won with a high probability (“Bell” symbols etc. are on the active line), and JAC in means entering the JAC game 12 times. When JAC symbols are aligned on the active line, JAC in is established. The JAC game is the same as that of the RB game. Also, when the JAC game by the third JAC in is finished, the BB game is finished even before the small role game reaches 30 times, and before the JAC in reaches 3 times after the 30 small role games are finished. Even if there is, the BB game ends.

  In the special game state process, first, in step S901, it is determined whether or not the game state is a bonus game. If it is not during the bonus game, the process proceeds to step S902, and bonus symbol determination processing is performed.

  In this bonus symbol determination process, as shown in FIG. 19, it is first determined in step S1001 whether or not the RB winning flag is set. It is determined whether or not (for example, “BAR” symbols) are aligned, and if the RB symbols are not aligned, this processing is terminated. On the other hand, when the RB symbols are aligned on the active line this time, in step S1003, the RB winning flag is reset and the RB setting flag is set to make an RB game which is one type of bonus game, and the RB game initial setting process shown in FIG. To finish this processing. If the RB winning flag is not set in step S1001, it is determined whether or not the BB winning flag is set in step S1004. If it is not set, the process is terminated. When the BB winning flag is set, the process proceeds to step S1005, where it is determined whether or not the BB symbol (for example, symbol “7”) is aligned on the current effective line. . On the other hand, when the BB symbols are aligned on the active line this time, in step S1006, the BB winning flag is reset and the BB setting flag is set to obtain a BB game which is one type of bonus game, and the BB game shown in FIG. The initial setting process is executed and this process is terminated.

  20 and 21, the remaining small role game counter represents the remaining number of small role games (also referred to as the remaining small role game number), and the remaining JAC in counter represents the remaining number of remaining JAC in (remaining JAC in number). The remaining JAC establishment counter represents the remaining number of times that the JAC symbol can be established (also referred to as the number of remaining JAC formations), and the remaining JAC game counter represents the number of remaining JAC games (also referred to as the number of remaining JAC games). To express. The number of remaining small role games, the number of remaining JAC ins, the number of remaining JACs established, and the number of remaining JAC games are displayed on the game number display unit 36 as appropriate. By the way, if a small role winning flag or replay winning flag is set by winning a small role or replay in the role lottery, those winning flags will not be aligned on the active line in the game. Will be reset, but if the RB winning flag or the BB winning flag is set by winning the RB or BB in the winning lottery, even if the RB symbol or BB symbol cannot be aligned on the active line in the game The winning flag will be carried over to the next time. In the lottery process in the next game that carries over the BB or RB winning flag, a lottery regarding whether or not a small role or replay is won is performed, but a lottery regarding BB or RB is not performed. In addition, when a small combination or replay is won in a state where the BB or RB winning flag is carried over, a slide table is stored so that the small combination or replay is preferentially aligned.

  Returning to FIG. 16, when the gaming state is a bonus game in step S901, it is determined in step S903 whether the bonus game is a JAC game. If it is not a JAC game, it means that the BB game is in the small role game, so the process proceeds to step S904, and it is determined whether or not the JAC symbols are aligned on the active line. When the JAC symbols are aligned on the active line, the JAC game is started in step S905 and the JAC game initial setting process during the BB game shown in FIG. 21B is performed, and this process ends. On the other hand, when the JAC symbols are not aligned on the active line in step S904, the small role game has been consumed, so in step S906 the remaining small role game number is decremented by 1, and in step S907. It is determined whether or not the number of remaining small role games has become zero. When the remaining small role game number is not 0, the present process is terminated. When the remaining small role game number is 0, the process proceeds to step S908, and a special game state end process for appropriately resetting various setting flags, BB setting flags, various counters, etc. To end this process.

  When the game state is a JAC game in step S903, the process proceeds to step S909, where it is determined whether or not the JAC symbols are aligned on the effective line. Decrement by one. After that, or when the JAC symbols are not aligned on the active line in step S909, one JAC game has been consumed, so the number of remaining JAC games is decremented by 1 in step S911. Subsequently, in step S912, it is determined whether or not any of the remaining number of JACs or the number of remaining JAC games has become 0. If neither is 0, that is, the JAC symbol has not yet been established 8 times. If the JAC game has not been digested 12 times, the process is terminated as it is. On the other hand, if any of them is 0, that is, if the JAC symbol is established 8 times or the JAC game is digested 12 times, the JAC in is digested once, so in step S913 the remaining JAC in The number of times is decremented by 1, and in the subsequent step S914, it is determined whether or not the number of remaining JAC in is zero. When it is 0, the special gaming state termination process of step S908 described above is performed, and this process is terminated. Incidentally, if the bonus game is an RB bonus, the initial remaining JAC in number is 1 (see FIG. 20), so it becomes 0 in step S913, and a positive determination is always made in step S914, and the special game in step S908. The RB setting flag is reset in the state end process.

  On the other hand, when the number of remaining JAC ins is not zero in step S914, that is, when the JAC in has not been digested three times in the BB game, after performing the JAC game end processing for resetting the JAC game setting flag in step S915, When the player enters the game, one of the small role games is digested, so the number of remaining small role games is decremented by 1 in step S906, and then whether or not the remaining small role game number has become 0 in step S907. If it is determined that the number of remaining small role games is 0, the special game state ending process in step S908 described above is performed, and this process is ended. On the other hand, when the remaining small-combination game number is not 0, the small-combination game in the BB bonus has not reached 30 times and the JAC in has not reached 3 times.

  With reference to FIG.22 and FIG.23, the whole structure of the switch apparatus 1100 is demonstrated. FIG. 22 is a perspective view of the switch device 1100, and FIG. 23 is a cross-sectional perspective view of the switch device 1100. Note that the switch device 1100 is mounted on the front door 12 by a flange formed on the outer peripheral surface of the front outer frame 200 being fastened and fixed to the back side of the front door 12, but in FIG. 22 and FIG. The illustration of the flange is omitted. The same applies to the following drawings.

  The switch device 1100 is a device that is operated when instructing the rotation start of each of the reels 42L to 42R (see FIG. 1), and includes a front outer frame 200 and a rear outer frame 300 that form a housing, and the outer frames. 200 and 300, an inner frame 400 housed in a rotatable manner, three sliders 500 held by the inner frame 400, and three elastic members 600 that apply different urging forces to the sliders 500, The start lever 71 is provided with a feeling of operation at the time of operation by the biasing force of the elastic member 600, and a sensor 800 that detects the operation of the start lever 71, and exposes the front surface of the front outer frame 200 to adjust the start lever 71 and the adjustment. The lever 405 is attached to the front door 12 in a state where the player can operate (see FIGS. 1 and 2).

  The switch device 1100 can arbitrarily select the magnitude of the urging force applied to the start lever 71 by changing the rotational position of the inner frame 400, and operates the start lever 71 with a feeling of operation suitable for the player. be able to. That is, when the player feels that the operating force is excessive or insufficient, the player can adjust the operating force by rotating the inner frame 400 and changing the magnitude of the biasing force. For example, it is possible to increase the urging force for a short-time operation to enhance the feeling of operation, while reducing the urging force for a long-time operation to reduce fatigue.

  Next, a detailed configuration of the switch device 1100 will be described with reference to FIGS. FIG. 24 is a cross-sectional view of the switch device 1100 and corresponds to a cross-sectional view cut along a plane including the axis O.

  As shown in FIG. 24, the start lever 71 includes a held portion 71 a that is held between the front outer frame 200 and the slider 500. In the held portion 71a, the base end surface (left side surface in FIG. 24) that is in contact with the slider 500 is formed as a flat surface perpendicular to the axis O, and the outer peripheral surface that is in contact with the front outer frame 200 is a spherical surface. Formed. As a result, the slider 500 can be pushed toward the elastic member 600 in accordance with the operation of the start lever 71 while allowing the inner frame 400 to rotate (see FIG. 28).

  The front outer frame 200 is a member that is disposed on the front side of the switch device 1100 and forms a part of the outer frame. Here, the front outer frame 200 will be described with reference to FIG. FIG. 25A is a front view of the front outer frame 200, and FIG. 25B is a cross-sectional view of the front outer frame 200 taken along line XXVb-XXVb in FIG.

  As shown in FIG. 25, the front outer frame 200 is formed in a bottomed cylindrical shape having an axis O, and the front plate 201 that closes the opening on one side (right side of FIG. 25 (b)) of the cylindrical body A lever holding portion 202 for holding the start lever 71 and a guide passage 203 for guiding the adjustment lever 405 (see FIG. 22) are formed.

  The lever holding portion 202 has a holding surface 202 a recessed in a spherical shape, and this holding surface 202 a holds the outer peripheral surface of the held portion 71 a of the start lever 71. The guide passage 203 is a groove-shaped opening formed so as to penetrate the front plate 201 in the thickness direction, and as shown in FIG. Formed in the removed shape.

  The inner peripheral side of the guide passage 203 is formed with a radius R1. Further, on the inner peripheral side of the guide passage 203, three engagement recesses 203 a that are recessed toward the axis O are arranged at intervals of 120 ° in the circumferential direction with the axis O as the center. The adjustment lever 405 is locked to the engagement recess 203a, so that the rotation position of the inner frame 400 is positioned at an appropriate rotation position (see FIGS. 22 and 24).

  Returning to FIG. The rear outer frame 300 is a member that forms the rear surface side of the outer frame, is formed in a bottomed cylindrical shape having an axis O, and has an inner and outer diameter that is the same as that of the front outer frame 200. A sensor 800 is attached to the back plate 301 that closes the opening on the other side (left side in FIG. 24) of the rear outer frame 300. Further, the opening on the other side of the rear outer frame 300 (left side in FIG. 24) is joined to the opening of the front outer frame 200, and the rear outer frame 300 and the front outer frame 200 form an outer frame having a housing space inside. Is done.

  The end surface of the rear outer frame 300 is protruded on the outer peripheral side, while the end surface of the front outer frame 200 is protruded on the inner peripheral side, and both the protrusions are fitted in a seal shape. Thus, the end faces of both outer frames 200 and 300 are joined. In this case, since the convex protruding height of the front outer frame 200 is made lower than the convex protruding height of the rear outer frame 300, a predetermined gap is formed on the inner peripheral side of the joint portion of both the outer frames 200, 300. It is formed over the entire circumference. In the present embodiment, since the guide projection 404 of the inner frame 400 is inserted into the gap, the rotation of the inner frame 400 can be stably guided and positioned in the direction of the axis O.

  The inner frame 400 is a portion that is rotatably accommodated in the outer frame, is formed in a bottomed cylindrical shape having an axis O, and applies a biasing force to the start lever 71 and changes the magnitude of the biasing force. Constitutes part of the mechanism. Here, the inner frame 400 will be described with reference to FIGS. 26 and 27. FIG. 26A is a front view of the inner frame 400, and FIG. 26B is a rear view of the inner frame 400. FIG. 27 is a step view of the inner frame 400 taken along line XXVII-XXVII in FIG.

  As shown in FIGS. 26 and 27, the inner frame 400 includes a front plate 401 that closes an opening on one side (right side of FIG. 27) of the cylindrical body, and a plurality of (this embodiment) recessed in the front plate 401. 3) slider holding cylinders 402, cushioning material holding parts 403 recessed in the front plate 401, guide ridges 404 protruding from the outer peripheral surface of the cylindrical body, and the front plate 401. The adjustment lever 405 is mainly provided.

  The slider holding cylinder 402 is a part for housing the slider 500 and the elastic member 600 (see FIG. 24), is formed in a bottomed cylindrical shape having an axis parallel to the axis O, and has an opening in the front plate 401. It is formed. The slider holding cylinder 402 has a partly larger inner diameter on the opening side, and a step is formed in the opening. As a result, a receiving surface 402 a that is an annular flat surface in front view is formed in the opening of the slider holding cylinder 402. When the receiving surface 402 receives the pressed plate 501 of the slider 500, the displacement of the slider 500 toward the sensor 800 is restricted. Further, the bottom wall of the slider holding cylinder 402 is formed with a circular opening 402b in a front view at the center thereof. The detection pin 502 of the slider 500 is inserted through the opening 402b (see FIG. 24).

  As shown in FIG. 26, each slider holding cylinder 402 is disposed at a position equidistant from the axis O, and is disposed at equal intervals in the circumferential direction (120 ° intervals). The distance from the axis O of each slider holding cylinder 402 matches the distance from the axis center of the lever holding portion 202 and the start lever 71 of the front outer frame 200 to the axis O. Therefore, when the inner frame 400 is rotated around the axis O, the openings of the slider holding cylinders 402 face the held portions 71a of the start lever 71 in order (see FIG. 24).

  In this case, when the slider holding cylinders 402 rotate as the inner frame 400 rotates, the movement trajectories of the slider holding cylinders 402 can be overlapped. Therefore, the area required for moving the slider holding cylinders 402 can be reduced by the overlap of the movement trajectories, so that the switch device 1100 can be reduced in size.

  The buffer material holding part 403 is a part for laying the buffer material 900 (see FIG. 24), and is recessed on the front surface side (left side in FIG. 27) of the front plate 401. The buffer material holding portion 403 is recessed in a circular area centered on the axis O, and the opening of the slider holding cylinder 402 is included in this circular recessed area.

  The guide ridge 404 is a portion that serves as a guide during positioning and rotation of the inner frame 400, and is formed as a ridge having a rectangular cross section from the outer peripheral surface of the cylindrical body and continuously formed over the entire circumference. The The guide ridges 404 are inserted into the gaps formed at the joints between the outer frames 200 and 300 (see FIG. 24), so that the position of the inner frame 400 in the direction of the axis O is set to the outer frames 200 and 300. As a result, the rotational movement of the inner frame 400 can be guided stably.

  The adjustment lever 405 is a part that is operated by the player to rotate the inner frame 400, and is formed as a rod-like body having an oval cross section that is erected along the axis O from the front plate 401. The adjustment lever 405 is inserted into the guide passage 203 of the front outer frame 200 (see FIG. 22), and a part of the tip protrudes to be operable. By moving the adjustment lever 405 along the guide passage 203, the inner frame 400 can be smoothly rotated about the axis O as the center of rotation.

  In this case, the position of the adjustment lever 405 is such that when the adjustment lever 405 is locked in each engagement recess 203a of the guide passage 203 (see FIG. 22), the opening of each slider holding cylinder 402 is the position of the start lever 71. It is set at a position where it can face the held portion 71a. Therefore, the player can securely place the inner frame 400 at an appropriate rotational position (that is, a position where the urging force can be applied to the start lever 71) by engaging the adjustment lever 405 with the engagement recess 203a. it can. Further, based on whether the adjustment lever 405 is engaged with the engagement recess 203a, it can be easily determined whether the inner frame 400 is disposed at an appropriate rotational position.

  In the adjustment lever 405, a distance from the outer peripheral surface on the axis O side to the axis O is set to a distance L1, and this distance L1 is a radius R1 on the inner periphery side of the guide passage 203 (see FIG. 25A). ) (L1 <R1). Therefore, the adjustment lever 405 inserted into the guide passage 203 is brought into contact with the inner peripheral side wall of the guide passage 203 while being elastically deformed. It is guided along the side wall while pressing the inner peripheral side wall. Therefore, when the adjustment lever 405 is guided to the recessed position of the engagement recess 203a, the adjustment lever 405 enters and engages with the engagement recess 203a by the elastic recovery force. Thereby, the inner frame 400 can be easily disposed at an appropriate rotational position.

  Returning to FIG. Since the inner frame 400 includes the front plate 201 having a circular front view on the side facing the front plate 201 of the front outer frame 200, the inner side of the inner frame 400 can be shielded. As a result, even when the guide passage 203 is opened in the front outer frame 200, the inner side of the inner frame 400 (that is, the inner space between the inner frame 400 and the rear outer frame 300) through the guide passage 203. It is possible to prevent foreign matter from being inserted into the body. In the inner frame 400, the slider 500 is disposed in each of the slider holding cylinders 402, and the guide protrusions 404 protruding from the outer peripheral surface of the cylindrical body of the inner frame 400 have both outer frames 200, 300. Therefore, even with these configurations, the insertion of foreign matter into the inner side of the inner frame 400 can be suppressed.

  The slider 500 is a member that is slid in accordance with the operation of the start lever 71, and is formed in a bottomed cylindrical shape that is inserted into the slider holding cylinder 402. The slider 500 includes a pressed plate 501 that closes an opening on one side of the cylindrical body (the right side in FIG. 24), and a rod-shaped detection pin 502 that is erected along the axis from the back side of the pressed plate 501. Prepare.

  The cylindrical body of the slider 500 is formed to have an outer diameter that is slightly smaller than the inner diameter of the slider holding cylinder 402, and is slidable in the direction of the axis O within the slider holding cylinder 402. The pressed plate 501 is a portion with which the base end surface of the start lever 71 is abutted, and is formed in a circular shape in front view having the same diameter as the base end surface of the start lever 71.

  The pressed plate 501 is formed to project outward from the outer peripheral surface of the cylindrical body of the slider 500. Therefore, when the slider 500 slides in the slider holding cylinder 402 toward the sensor 800, the pressed plate 501 is received by the receiving surface 402a, and the sliding movement is restricted.

  The detection pin 502 is a part for causing the sensor 800 to detect the displacement of the slider 500, and the standing tip side protrudes from the opening 402 b of the slider holding cylinder 402 toward the sensor 800. When the start lever 71 is operated and the detection pin 502 is pushed out in accordance with the displacement of the slider 500, the operation of the start lever 71 is detected because the leading end of the detection pin 502 enters the detection region of the sensor 800.

  A slit is extended from the tip surface toward the pressed plate 501 at the standing tip of the detection pin 502, and a pair of return portions project radially outward from the outer peripheral surface sandwiching the slit. Is formed. Thereby, the slider 500 can be easily attached to the slider holding cylinder 402 and the slider 500 can be prevented from coming out of the slider holding cylinder 402.

  The elastic member 600 is a member for giving a feeling of operation to the start lever 71 and generating an urging force for returning to the initial position. The elastic member 600 is formed in a cylindrical shape from a rubber-like elastic material, It is interposed between the opening side end surface of the slider 500.

  The total axial dimension of the elastic member 600 and the slider 500 in the no-load state (the horizontal dimension in FIG. 24) is based on the distance from the bottom surface of the slider holding cylinder 402 to the surface of the front plate 401 (the right side surface in FIG. 24). Has also been enlarged. Therefore, in the state shown in FIG. 24 in which the start lever 71 is not operated, the elastic member 600 is elastically compressed and deformed, and the pressed plate 501 of the slider 500 moves the base end surface of the start lever 71 by the elastic recovery force. Pressing.

  Here, the elastic member 600 has different characteristics (spring constant) for each of the three slider holding cylinders 402. Therefore, the operating force of the start lever 71 can be changed according to the rotational position of the inner frame 400. That is, when the slider 500 of the slider holding cylinder 402 provided with the elastic member 600 having the smallest spring constant is displaced by operating the start lever 71, the operating force is minimized while the elastic force having the largest spring constant is obtained. When the slider 500 of the slider holding cylinder 402 provided with the member 600 is displaced by operating the start lever 71, the operating force is maximized.

  The buffer material 900 is formed in a sheet shape from a rubber-like elastic material, and is laid on the buffer material holding portion 403 of the inner frame 400. The cushioning material 900 is formed in a circular shape when viewed from the front, and is laid on the entire surface of the cushioning material holding portion 403 excluding a region corresponding to the opening of the slider holding cylinder 402. Thereby, even when the start lever 71 is operated in a state where the rotation position of the inner frame 400 is not appropriate (that is, in a state where the adjustment lever 405 is not engaged with the engagement recess 203a), the base end surface of the start lever 71 and The cushioning material 900 is interposed between the front plate 401 of the inner frame 400 and damage to the inner frame 400, the start lever 71, and the like can be suppressed.

  In addition, the thickness dimension (FIG. 24 left-right direction dimension) of the shock absorbing material 900 is a dimension equivalent to or slightly smaller than the recessed depth (FIG. 24 left-right direction dimension) of the shock absorbing material holding | maintenance part 403. Thereby, interference between the base end surface of the start lever 71 and the buffer material 900 can be suppressed, and the inner frame 400 can be smoothly rotated.

  Here, in the switch device 1100, the adjustment lever 405 is erected from the front surface of the front plate 401 of the inner frame 400, while the guide path is formed in the front plate 201 of the front outer frame 200 facing the front plate 401 of the inner frame 400. Since the opening 203 is formed, the structure can be simplified and the product cost can be reduced. That is, since the front outer frame 200 serves as both a member for holding the start lever 71 and a member for forming the guide passage 203, it is not necessary to separately provide a member for forming the guide passage 203. And can. Further, if the inner frame 400 is sandwiched between the rear outer frame 300 and the front outer frame 200, a structure in which the inner frame 400 can rotate and the adjustment lever 405 can be guided by the guide passage 203 can be obtained. The assembly process can be simplified. In this manner, by forming the guide passage 203 on the front side (front plate 201) of the front outer frame 200, the start lever 71 and the adjustment lever 405 can be arranged side by side. Can be improved.

  Next, the operation of the switch device 1100 will be described with reference to FIG. FIG. 28 is a cross-sectional view of the switch device 1100 and corresponds to a cross-sectional view cut along a plane including the axis O. When the start lever 71 is operated by the player, the held portion 71a is guided along the spherical shape while being held by the holding surface 202a of the front outer frame 200, and is swung in the operation direction by the player.

  By this swinging, the pressed plate 501 of the slider 500 is pressed by the base end surface of the start lever 71, and the slider 500 is slid and moved toward the sensor 800 in the slider holding cylinder 402. At this time, the elastic member 600 is compressed and deformed between the slider 500 and the bottom wall of the slider holding cylinder 402, whereby a biasing force in the direction opposite to the operation direction is applied to the start lever 71, and the player is operated. A feeling is given.

  When the start lever 71 is further operated, as shown in FIG. 28, the pressed plate 501 of the slider 500 is brought into contact with the receiving surface 402a of the slider holding cylinder 402, and the sliding movement of the slider 500 is restricted. At this time, when the detection pin 502 enters the detection region of the sensor 800, the sensor 800 reacts, and thereby it is detected that the start lever 71 has been operated to a predetermined position.

  On the other hand, when the operation of the start lever 71 is released, the elastic member 600 that has been compressed and deformed between the slider 500 and the bottom wall of the slider holding cylinder 402 is elastically recovered, and the slider 500 is started by the elastic recovery force. It is slid toward the lever 71 side. As a result, the start lever 71 is returned to the initial position (see FIG. 24).

  The inner frame 400 is provided with three slider holding cylinders 402 for holding the slider 500, and elastic members 600 having different characteristics are disposed on the inner frame 400, respectively. Therefore, by rotating the inner frame 400 to a predetermined position, the elastic member 600 that applies a biasing force to the start lever 71 can be switched from among the elastic members 600 having different characteristics. Thereby, the player can arbitrarily select the magnitude of the urging force, and as a result, the start lever 71 can be operated with an operation feeling suitable for the player.

  Since the adjustment lever 405 (see FIG. 22) is provided in the inner frame 400, the movement of the inner frame 400, that is, the change of the urging force can be easily performed by using the adjustment lever 405. . In particular, since the adjustment lever 405 protrudes from the front side of the front outer frame 200, the player can change the urging force while playing the game.

  In this case, since the front outer frame 200 on which the start lever 71 is disposed is fixed to the front door 12 (see FIG. 1), the operating force is changed without changing the operating position of the start lever 71. be able to. That is, even if the inner frame 400 is rotated and the magnitude of the urging force is changed, the operation of the start lever 71 can always be performed at the same position, so that the operability can be ensured.

  Next, a switch device 2100 according to the second embodiment will be described with reference to FIGS. 29 and 30. FIG. 29 is a perspective view of the switch device 2100 according to the second embodiment, and FIG. 30 is a cross-sectional perspective view of the switch device 2100. 29 and 30 correspond to FIGS. 22 and 23, respectively. Further, the switch device 2100 is attached to the front door 12 by a flange formed on the outer peripheral surface of the front outer frame 2200 being fastened and fixed to the rear side of the front door 12, but in FIG. 29 and FIG. The illustration of the flange is omitted.

  In the first embodiment, the case where the player operates the adjustment lever 405 has been described. However, the switch device 2100 according to the second embodiment prohibits the player from operating the adjustment lever 2405. In addition, the same code | symbol is attached | subjected to the part same as above-described 1st Embodiment, and the description is abbreviate | omitted.

  As shown in FIGS. 29 and 30, the front outer frame 2200 in the second embodiment is omitted from the front outer frame 200 in the first embodiment. Therefore, no opening is formed in the front plate 2201 of the front outer frame 2200 except for an opening for inserting the start lever 71, and the inner frame 2400 can be shielded by the front plate 2201.

  The rear outer frame 2300 in the second embodiment includes a guide passage 2203. The guide passage 2203 is a groove-like opening formed through the cylindrical body of the rear outer frame 2300 in the plate thickness direction, and has the same length (center angle) as the guide passage 203 of the first embodiment. It extends in the circumferential direction.

  Three engagement recesses 2203a that are recessed in the direction of the axis O are formed on one inner wall (on the front outer frame 2200 side) of the guide passage 2203 at intervals of 120 ° in the circumferential direction centering on the axis O (that is, , At a position corresponding to the engaging recess 203a in the first embodiment. The adjustment lever 2405 is locked to the engagement recess 2203a, so that the rotation position of the inner frame 2400 is positioned at an appropriate rotation position.

  In the inner frame 2400 in the second embodiment, the rising direction of the adjustment lever 2405 is opposite to the inner frame 400 in the first embodiment. That is, the adjustment lever 2405 is disposed on the end surface of the cylindrical body of the inner frame 2400 opposite to the front outer frame 2200 (that is, the end surface on the opening side of the inner frame 2400). The adjustment lever 205 is formed in an L shape as viewed from the side, extending from the end surface on the opening side of the inner frame 2400 along the axis O, bent outward in the radial direction, and inserted into the guide passage 2203. Is done.

  Here, the adjustment lever 405 has a distance from the end surface on the opening side of the inner frame 2400 to the side surface of the portion bent in an L shape so that the engaging recess 2203a of the guide passage 2203 from the end surface on the opening side of the inner frame 2400. It is shorter than the distance to the inner wall on the recessed side. Therefore, the adjustment lever 2405 inserted into the guide passage 2203 is brought into contact with the inner wall of the guide passage 2203 in an elastically deformed state, and presses the inner wall of the guide passage 2203 when guided and moved by the guide passage 2203. However, it is guided along the inner wall. Therefore, when the adjusting lever 2405 is guided to the recessed position of the engaging recess 2203a, it is self-entered into the engaging recess 2203a by the elastic recovery force. Thereby, the inner frame 2400 can be easily disposed at an appropriate rotational position.

  As described above, in the switch device 2100, when the front outer frame 2200 is attached to the front door 12, the adjustment lever 2405 is disposed on the rear outer frame 2300. It can be arranged inside the body 11. Therefore, careless operation by the player can be avoided and damage to the adjustment lever 2405 can be suppressed. Further, in this case, since it is not necessary to form an opening (guide passage 2203) through which the adjustment lever 2405 is inserted in the front outer frame 2200, it is difficult to perform an illegal act such as inserting a foreign object through the opening. be able to. Even in a narrow space in the housing 11 of the slot machine 10, the biasing force can be easily changed / selected by operating the adjustment lever 2405.

  Next, with reference to FIG. 31, a switch device 3100 according to the third embodiment will be described. FIG. 31 is a cross-sectional perspective view of the switch device 3100 according to the third embodiment. FIG. 31 corresponds to FIG. Further, the switch device 3100 is attached to the front door 12 by a flange formed on the outer peripheral surface of the front outer frame 3200 being fastened and fixed to the back side of the front door 12, but in FIG. The illustration is omitted.

  In the first embodiment, the case where the inner frame 400 is rotated by moving the adjustment lever 405 along the guide path 203 has been described. However, the switch device 3100 in the third embodiment is adjusted by the player. By rotating the rotor 3405, the inner frame 3400 is rotated. In addition, the same code | symbol is attached | subjected to the part same as each above-mentioned embodiment, and the description is abbreviate | omitted.

  As shown in FIG. 31, in the front outer frame 3200 in the third embodiment, the opening of the guide passage 203 is omitted from the front outer frame 200 in the first embodiment, while the adjustment rotor 3405 is pivoted. A shaft support hole 3201a is provided. Therefore, the front plate 3201 of the front outer frame 3200 is not formed with an opening except for the opening for inserting the start lever 71 and the adjustment rotor 3405, and the inner frame 3400 can be shielded by the front plate 3201. Has been.

  The inner frame 3400 in the third embodiment includes a ring gear 3406 that protrudes from the peripheral edge of the front plate 401 toward the front outer frame 3200 and is formed in a cylindrical shape concentric with the axis O. The ring gear 3406 has teeth engraved on the inner peripheral surface thereof, and meshes with the gear 3405b of the adjusting rotor 3405 via the teeth.

  The adjustment rotor 3405 is a part operated by the player to rotate and move the inner frame 3400. A shaft portion rotatably supported by the front plate 3201 of the front outer frame 3200 and one end of the shaft portion. An operation portion 3405a fixed to the end portion (right side in FIG. 31) and exposed to the front side of the front plate 3201, and a gear 3405b fixed to the end portion of the shaft portion opposite to the operation portion 3405a. Prepare.

  The gear 3405b has teeth engraved on its outer peripheral surface, and meshes with the ring gear 3406 of the inner frame 3400 via these teeth. Therefore, when the operation unit 3405a is rotated by the player and the adjusting rotor 3405 is rotated, the rotation is transmitted from the gear 3405b to the ring gear 3406 of the inner frame 3400, and the ring gear 3406 is rotated, whereby the inner frame 3400 is rotated about the axis O as the center of rotation.

  According to the switch device 3100 in the third embodiment, the inner frame 3400 can be rotated in a range of 360 degrees or more by the rotating operation of the adjusting rotor 3405. Therefore, the selection operation when selecting the urging force is performed. Increase efficiency.

  For example, in the first embodiment, the maximum biasing force is selected by positioning the adjustment lever 405 at one end of the guide passage 203 and the minimum biasing force by positioning the adjustment lever 405 at the other end of the guide passage 203. Is selected, and an intermediate biasing force is selected by being positioned in the middle of the guide passage 203, the adjustment lever 405 is used to select the minimum biasing force from the state where the maximum biasing force is selected. When moving the guide passage 203 from one end to the other end, it is necessary to pass the intermediate position, which is inefficient.

  On the other hand, in the third embodiment, the inner frame 3400 can be rotated in a range of 360 degrees or more. Therefore, in order to select the minimum urging force from the state where the maximum urging force is selected, the adjustment rotation is performed. By rotating the child 3405, it is possible to directly shift from the state in which the maximum urging force is selected to the state in which the minimum urging force is selected without passing through the intermediate position, and the selection operation can be made efficient.

  Next, a fourth embodiment will be described with reference to FIGS. 32 to 35. FIG. 32 is a perspective view of a switch device 4100 according to the fourth embodiment, and FIG. 33 is a cross-sectional perspective view of the switch device 4100. 34 and 35 are partially enlarged cross-sectional views of the switch device 4100. FIG.

  32 to 35 correspond to cross-sectional views cut along a plane including the axis O. FIG. 34 shows a state where the compression amount of the elastic member 4600 is maximum (that is, a state where the inner frame 4400 is displaced to the start lever 71 side to the maximum), and FIG. 35 shows a state where the compression amount of the elastic member 4600 is minimum ( That is, the state in which the inner frame 4400 is displaced to the sensor 800 side to the maximum) is shown. Further, the switch device 4100 is attached to the front door 12 by a flange formed on the outer peripheral surface of the front outer frame 4200 being fastened and fixed to the rear side of the front door 12, but in FIG. The illustration is omitted.

  In the first embodiment, a plurality of elastic members 600 having different characteristics (spring constants) are provided, and the magnitude of the urging force applied to the start lever 71 is selected by selecting one of the plurality of elastic members 600. Although the case of changing is described, the switch device 4100 in the fourth embodiment changes the magnitude of the urging force applied to the start lever 71 by increasing or decreasing the elastic deformation amount of the elastic member 4600. In addition, the same code | symbol is attached | subjected to the part same as each above-mentioned embodiment, and the description is abbreviate | omitted.

  The switch device 4100 according to the fourth embodiment is formed by a front outer frame 4200, a first intermediate outer frame 4250, a second intermediate outer frame 4350, a rear outer frame 4300, and the outer frames 4200 that constitute the casing. An inner frame 4400 housed in a casing, a slider 4500 held by the inner frame 4400, an elastic member 4600 that applies a biasing force to the slider 4500, and a biasing force of the elastic member 4600 give an operational feeling. A start lever 71, a sensor 800 for detecting the operation of the start lever 71, and an adjustment rotor 4405 operated by a player to rotate and move the inner frame 4400, and the front surface of the front outer frame 4200 is exposed. The start lever 71 and the adjusting rotor 4405 are mounted on the front door 12 in a state where the player can operate.

  This switch device 4100 allows the magnitude of the urging force applied to the start lever 71 to be continuously adjusted by increasing or decreasing the amount of elastic deformation of the elastic member 4600 by the rotation of the inner frame 4400, and is suitable for the player. The start lever 71 can be operated with a feeling. That is, when the player feels that the operating force is excessive or insufficient, the player can adjust the operating force by rotating the inner frame 4400 and changing the magnitude of the biasing force. For example, it is possible to increase the urging force for a short-time operation to enhance the feeling of operation, while reducing the urging force for a long-time operation to reduce fatigue.

  As shown in FIGS. 33 to 35, the front outer frame 4200 is a member that forms the front side of the housing, and is formed in a bottomed cylindrical shape having an axis O. The front plate 4201 that closes the opening on one side of the cylindrical body (the right side in FIGS. 33 and 34) has a lever holding portion 202 that holds the start lever 71 and a shaft support hole 4201a that supports the adjusting rotor 4405. Each is formed. In the fourth embodiment, the lever holding portion 202 is disposed concentrically with the axis O.

  The first intermediate outer frame 4250 is a member constituting the middle of the housing, and is formed in a bottomed cylindrical shape having an axis O. That is, the first intermediate outer frame 4250 includes a back plate 4251 that closes the opening on the other side (left side in FIGS. 33 and 34) that is located on the outer peripheral side and forms the outer wall, and the back plate 4251 includes: A cylindrical first inner wall portion 4252 having an axis O and open at both ends is disposed. The first inner wall portion 4252 has a first restricting portion 4252a formed to project from the inner peripheral surface in a flange shape, and the first restricting portion 4252a to the other end side (left side in FIG. 33) opening of the first inner wall portion 4252. A female screw portion 4252b formed by screwing a female screw on the inner peripheral surface.

  The first restricting portion 4252a is a part for receiving the pressed plate 4501 of the slider 4500. When the pressed plate 4501 is brought into contact with the first restricting portion 4252a, the displacement of the slider 4500 toward the sensor 800 side is reduced. Be regulated. The female screw portion 4252b is a portion into which the male screw portion 4403 of the inner frame 4400 is screwed. That is, when the inner frame 4400 is rotated with respect to the first intermediate outer frame 4250, the male screw portion 4403 is screwed with respect to the female screw portion 4252b, and the inner frame 4400 is moved in the direction of the axis O by the screwing. Moved to.

  The second intermediate outer frame 4350 is a member that forms the middle of the housing together with the first intermediate outer frame 4250 and is formed in a cylindrical shape having an axis O. An intermediate plate 4351 for closing the inner space of the cylindrical body is formed in the middle of the cylindrical body in the axial direction. The intermediate plate 4351 has a cylindrical second inner wall portion having an axis O and open at both ends. 4352 is disposed. The second inner wall portion 4352 is a portion in which the inner frame 4400 is fitted to the inner peripheral surface side so as to be movable in the axial direction, and the inner diameter of the portion on the first intermediate outer frame 4250 side is the portion of the portion on the rear outer frame 4300 side. By making it larger than the inner diameter, a second regulating surface 4252a as a step is formed between these two portions.

  An outer peripheral gear 4402 of the inner frame 4400 is disposed in a portion where the inner diameter of the second inner wall portion 4352 is increased (that is, a portion from the second restriction surface 4252a to the first intermediate outer frame 4250). Therefore, when the inner frame 4400 moves in the direction of the axis O, the outer peripheral gear 4402 is brought into contact with the second restriction surface 4252a, so that the displacement of the inner frame 4400 toward the sensor 800 is restricted. Further, when the outer peripheral gear 4402 is brought into contact with the end surface of the first inner wall portion 4252 of the first intermediate outer frame 4250, the movement of the inner frame 4400 toward the start lever 71 is restricted.

  The second intermediate outer frame 4350 is cut into a part of the cylindrical body and the second inner wall part 4352 in order to prevent the gear 4405b of the adjusting rotor 4405 from interfering with the cylindrical body and the second inner wall part 4352. A notch is formed, and a gear 4405b is disposed at a portion where the notch is formed.

  The rear outer frame 4300 is a member that forms the rear surface side of the housing, and is formed in a bottomed cylindrical shape having an axis O. That is, the rear outer frame 4300 includes a back plate 4301 that closes the opening on the other side (left side in FIG. 33) of the cylindrical body, and the sensor 800 is attached to the back plate 4301. The rear outer frame 4300 is joined to the front outer frame 4200 with the first and second intermediate outer frames 4250 and 4350 interposed therebetween, thereby forming a housing (outer frame) having an accommodation space inside. The

  The inner frame 4400 is a part that is accommodated in the first intermediate outer frame 4250 and the second intermediate outer frame 4350 so as to be rotatable and movable in the axial direction, and is formed in a bottomed cylindrical shape having an axis O. That is, the inner frame 4400 includes a bottom wall 4401 that closes the opening on the other end side (left side in FIG. 33). The bottom wall 4401 has a circular opening 4401a in the center when viewed from the front, and the detection pin 4502 of the slider 4500 is inserted therethrough.

  In addition, the inner frame 4400 is formed by screwing an outer peripheral gear 4402 projecting from the outer peripheral surface, and a screw on the outer peripheral surface from the outer peripheral gear 4402 to one end side (right side in FIG. 33) of the inner frame 4400. And a male screw portion 4403.

  The outer peripheral gear 4402 is a part to which the rotation from the adjusting rotor 4405 is transmitted. The outer peripheral gear 4402 is continuously formed in the circumferential direction, and teeth that are meshed with the gear 4405b of the adjusting rotor 4405 are engraved on the outer peripheral surface. Is done. When adjustment rotor 4405 is rotated, the rotation is transmitted to outer peripheral gear 4402 via gear 4405b, and inner frame 4400 is rotated.

  As described above, the male screw portion 4403 is screwed into the female screw portion 4252b of the first intermediate outer frame 4250, and when the inner frame 4400 is rotated, the male screw portion 4403 is engaged with the female screw portion 4252b. The inner frame 4400 is moved in the direction of the axis O by being screwed. Note that the amount of elastic deformation (compression amount) of the elastic member 4600 is increased or decreased by moving the inner frame 4400 in the direction of the axis O, and as a result, the operating force of the start lever 71 is increased or decreased.

  The slider 4500 is a member that is slid in accordance with the operation of the start lever 71, and is formed in a cylindrical shape that is inserted into the inner frame 4400. The slider 4500 includes a pressed plate 4501 formed on one side of the columnar body (the right side in FIG. 33) and a rod-shaped detection pin 4502 erected along the axis O from the other side of the columnar body. .

  The columnar body of the slider 4500 is formed to have an outer diameter slightly smaller than the inner diameter of the inner frame 4400, and is slidable in the direction of the axis O within the inner frame 4400. The pressed plate 4501 is a portion with which the base end surface of the start lever 71 is in contact, and is formed in a circular shape in front view having the same diameter as the base end surface of the start lever 71.

  Further, the pressed plate 501 is formed to project outward from the outer peripheral surface of the cylindrical body of the slider 4500. Therefore, when the slider 4500 slides in the inner frame 4400 toward the sensor 800, the pressed plate 4501 is received by the first restricting portion 4252a of the first intermediate outer frame 4250, and the sliding movement is restricted. The

  The detection pin 4502 is a part for causing the sensor 800 to detect the displacement of the slider 4500, and the front end side of the detection pin 4502 projects from the opening 4401 a of the inner frame 4400 toward the sensor 800. When the start lever 71 is operated and the detection pin 4502 is pushed out in accordance with the displacement of the slider 4500, the rising end of the detection pin 4502 enters the detection area of the sensor 800, whereby the operation of the start lever 71 is detected.

  The elastic member 4600 is a member for giving a feeling of operation to the start lever 71 and generating an urging force for returning to the initial position. The elastic member 4600 is formed in a cylindrical shape from a rubber-like elastic material, and has a bottom wall 4401 of the inner frame 4400. And the end face of the cylindrical body of the slider 4500. The elastic member 4600 is compressed and deformed between the bottom wall 4401 and the slider 4500. The amount of compressive deformation is increased or decreased by moving the inner frame 4400 in the direction of the axis O, and the operational feeling of the start lever 71 is changed depending on the degree of increase or decrease.

  Note that the elastic member 4600 has the inner frame 4400 moved most to the sensor 800 side (that is, when the outer peripheral gear 4402 is in contact with the second restricting surface 4352a as shown in FIG. 35). In addition, it has an axial dimension (dimension in the left-right direction in FIG. 34) sufficient to be compressed and deformed between the bottom wall 4401 and the slider 4500. Therefore, when the start lever 71 is not operated, the elastic member 4600 is always elastically compressed and deformed, and the pressed plate 4501 of the slider 4500 moves the base end surface of the start lever 71 by the elastic recovery force. Pressing.

  As described above, in the present embodiment, even when the elastic deformation amount of the elastic member 4600 is minimized, the elastic member 4600 is elastically deformed (compressed). A preload can be applied between the female screw portion 4252 b of the outer frame 4250 and the male screw portion 4403 of the inner frame 4400. Thereby, it is possible to suppress the occurrence of a gap between the external thread and the internal thread in the external thread part 4403 and the internal thread part 4252b, and to suppress the rattling of the inner frame 4400. The operational feeling can be improved.

  Further, by applying a preload between the external thread portion 4403 and the internal thread portion 4252b as described above, the rotational position of the inner frame 4400 is utilized by utilizing the frictional force that acts between the external thread and the internal thread. Can be held. This eliminates the need for a mechanism for holding the rotational position of the inner frame 4400, thereby reducing the product cost. Further, it is possible to prevent the rotational position of the inner frame 4400 from being shifted in accordance with the operation of the start lever 71, and as a result, it is possible to easily keep the operation force constant.

  The adjusting rotor 4405 is a part operated by the player to rotate the inner frame 4400, and is rotatably supported by the front plate 4201 of the front outer frame 4200 and the rear plate 4251 of the first intermediate outer frame 4250. A shaft portion fixed to one end side (right side in FIG. 33) of the shaft portion and exposed to the front side of the front plate 4201, and a shaft portion on the opposite side of the operation portion 4405a. A gear 4405b fixed to the end.

  The gear 4405b has teeth engraved on the outer peripheral surface thereof, and meshes with the outer peripheral gear 4402 of the inner frame 4400 via the teeth. Therefore, when the operation unit 4405a is rotated by the player and the adjusting rotor 4405 is rotated, the rotation is transmitted from the gear 4405b to the outer peripheral gear 4402 of the inner frame 4400, and the outer peripheral gear 4401 is rotated. The inner frame 4400 is rotated about the axis O as the center of rotation. Thereby, the operation | movement which rotates the inner frame 4400 and moves to the axial center O direction can be performed easily.

  The outer peripheral gear 4401 and the gear 4405b are formed as spur gears in which tooth traces are engraved in parallel with the axis O. Therefore, even when the inner frame 4400 moves in the direction of the axis O due to the screwing of the external thread 4403 to the internal thread 4252b, the meshing state between the outer peripheral gear 4401 and the gear 4405b is maintained and adjusted rotation The rotation from the child 4405 can be transmitted to the inner frame 4400.

  Next, the operation of the switch device 4100 will be described. When the start lever 71 is operated by the player, the held portion 71a is guided along the spherical shape while being held by the holding surface 202a of the front outer frame 200, and is swung in the operation direction by the player.

  By this swinging, the pressed plate 4501 of the slider 4500 is pressed by the base end surface of the start lever 71, and the slider 4500 is slid and moved toward the sensor 800 in the inner frame 4400. At this time, the elastic member 4600 is compressed and deformed between the slider 4500 and the inner frame 4400 bottom wall 4401, so that the urging force in the direction opposite to the operation direction is applied to the start lever 71, and the player feels the operation feeling. Is granted.

  When the start lever 71 is further operated, the pressed plate 4501 of the slider 4500 comes into contact with the first restricting portion 4252a of the first intermediate outer frame 4250, and the sliding movement of the slider 4500 is restricted. At this time, when the detection pin 4502 enters the detection area of the sensor 800, the sensor 800 reacts, thereby detecting that the start lever 71 has been operated to a predetermined position.

  On the other hand, when the operation of the start lever 71 is released, the elastic member 4600 that has been compressed and deformed between the slider 4500 and the bottom wall 4401 of the inner frame 4400 elastically recovers, and the slider 4500 starts by the elastic recovery force. It is slid toward the lever 71 side. As a result, the start lever 71 is returned to the initial position.

  In this case, the elastic member 4600 is elastically deformed by rotating the operation portion 4405a of the adjusting rotor 4405 in one direction and moving the inner frame 4400 to the start lever 71 side (right side in FIG. 34) as shown in FIG. While the amount (compression amount) can be increased, the operation portion 4405a of the adjusting rotor 4405 is rotated in the other direction, and the inner frame 4400 is moved to the sensor 800 side (left side in FIG. 35) as shown in FIG. Thus, the elastic deformation amount (compression amount) of the elastic member 4600 can be reduced.

  Here, the force required to move the slider 4500 toward the bottom wall 4401 of the inner frame 4400 and elastically deform (compress) the elastic member 4600 is proportional to the amount of elastic deformation of the elastic member 4600. In the state shown in FIG. 34 in which the amount of elastic deformation is larger than the reference value, a force larger than the reference is required to further elastically deform the elastic member 4600, while the amount of elastic deformation is smaller than the reference value shown in FIG. In the state, the force required to elastically deform the elastic member 4600 is smaller than the reference.

  As described above, according to the switch device 4100 in the present embodiment, the elastic deformation amount of the elastic member 4600 can be adjusted by operating the adjustment rotor 4405, and when the start lever 71 is operated. The magnitude of the biasing force applied in the direction opposite to the operation direction can be changed. Thereby, the player can arbitrarily change the force required to operate the start lever 71, and as a result, the start lever 71 can be operated with an operation feeling suitable for the player.

  Thus, in the present embodiment, the rotational motion of the inner frame 4400 can be converted into a linear motion, so that the structure for adjusting the elastic deformation amount of the elastic member 4600 can be reduced in size. Further, since the elastic deformation amount of the elastic member 4600 can be continuously adjusted, an operation feeling suitable for the player can be obtained with certainty. Further, even if the inner frame 4400 is rotated once, the amount of screwing is a distance corresponding to one pitch of the screw in the male screw portion 4403 and the female screw portion 4252b, so that the elastic deformation amount (compression amount) of the elastic member 4600 is finely adjusted. Can be easily performed.

  Further, in the present embodiment, the magnitude of the biasing force applied to the start lever 71 can be adjusted only by one elastic member 4600, and characteristics (spring constants) for applying different biasing forces. Since there is no need to provide a plurality of elastic members having different values, the product cost can be reduced accordingly.

  Since the adjusting rotor 4405 protrudes to the front side of the front outer frame 4200, the player can adjust the urging force while playing the game. In this case, since the front outer frame 4200 on which the start lever 71 is disposed is fixed to the front door 12 (see FIG. 1), the operation force is changed without changing the operation position of the start lever 71. be able to. That is, even if the inner frame 4400 is moved and the magnitude of the urging force is changed, the start lever 71 can always be operated at the same position, so that the operability can be ensured.

  Next, with reference to FIG. 36, a switch device 5100 in the fifth embodiment will be described. FIG. 36 is a cross-sectional perspective view of a switch device 5100 according to the fifth embodiment. FIG. 36 corresponds to FIG. In addition, the switch device 5100 is mounted on the front door 12 by a flange formed on the outer peripheral surface of the front outer frame 5200 being fastened and fixed to the rear side of the front door 12, but in FIG. The illustration is omitted.

  In the fourth embodiment, the case where the player operates the adjustment rotor 4405 has been described. However, the switch device 5100 according to the fifth embodiment prohibits the player from operating the adjustment rotor 5405. In addition, the same code | symbol is attached | subjected to the part same as each above-mentioned embodiment, and the description is abbreviate | omitted.

  As shown in FIG. 36, the adjusting rotor 5405 according to the fifth embodiment is omitted from the adjusting rotor 4405 according to the fourth embodiment in that the operating portion 4450a and the shaft portion to which the operating portion 4405a is fixed are omitted. Has been. That is, the adjustment rotor 5405 includes a gear 4405b and a shaft portion on the side to which the gear 4405b is fixed and is supported on the back plate 4251 of the first intermediate outer frame 4250. Therefore, the front plate 5201 is not formed with a shaft support hole for supporting the shaft portion of the adjusting rotor 4405 in the front outer frame 5200, and an opening is formed except for an opening through which the start lever 71 is inserted. Therefore, the inside of the housing can be shielded by the front plate 5201.

  Thus, in the switch device 5100, when the front outer frame 5200 is attached to the front door 12, the adjustment rotor 5405 has only the gear 4405b and a part of the shaft portion. It can be arranged inside the housing 11 of the slot machine 10. Therefore, careless operation by the player can be avoided, and damage to the adjusting rotor 5405 and the inner frame 4400 can be suppressed. Further, in this case, it is not necessary to form an opening (shaft support hole) through which the shaft portion of the adjusting rotor 5405 is inserted in the front plate 5201 of the front outer frame 5200, and accordingly, foreign matter is inserted through the opening. It is possible to make it difficult to perform illegal acts such as.

  Since the gear 4405b of the adjusting rotor 5405 is exposed from the outer peripheral surface of the second intermediate outer frame 4350, the gear 4405b of the adjusting rotor 5405 is operated, so Even in a narrow space, the urging force can be easily changed and selected.

  Next, a switch device 6100 according to the sixth embodiment will be described with reference to FIG. FIG. 37 is a cross-sectional perspective view of the switch device 6100 according to the sixth embodiment. FIG. 37 corresponds to FIG. Further, the switch device 6100 is attached to the front door 12 by a flange formed on the outer peripheral surface of the front outer frame 4200 being fastened and fixed to the back side of the front door 12, but in FIG. The illustration is omitted.

  In the fourth embodiment, the case where the inner frame 4400 is moved in the direction of the axis O by rotating the inner frame 4400 in accordance with the rotation operation of the adjusting rotor 4405 has been described. The switch device 6100 in the form is moved in the direction of the axis O without the inner frame 6400 rotating. In addition, the same code | symbol is attached | subjected to the part same as each above-mentioned embodiment, and the description is abbreviate | omitted.

  As shown in FIG. 37, the first intermediate outer frame 6250 in the sixth embodiment is a female thread portion to the inner peripheral surface of the first inner wall portion 6252 with respect to the first intermediate outer frame 4250 in the fourth embodiment. The formation of 4252b is omitted, and the inner frame 6400 in the sixth embodiment is omitted in the formation of the male thread portion 4403 on the outer peripheral surface of the inner frame 4400 in the fourth embodiment. Therefore, the inner frame 6400 is held so as to be slidable in the direction of the axis O by the inner peripheral surfaces of the first inner wall portion 6252 and the second inner wall portion 4352 of the first intermediate outer frame 6250 and the second intermediate outer frame 4350. .

  In addition, the inner frame 6400 in the sixth embodiment includes a protruding portion 6403 that protrudes radially outward from the outer peripheral surface of the cylindrical body. The projecting portion 6403 includes a nut portion 6403a formed so as to penetrate in the direction of the axis O and having a female screw threaded on the inner peripheral surface thereof.

  The adjusting rotor 6405 is a part operated by the player to slide the inner frame 6400, and is pivotally supported on the front plate 4201 of the front outer frame 4200 and the rear plate 4251 of the first intermediate outer frame 6250. Shaft part, an operation part 6405a fixed to one end side (right side in FIG. 37) of the shaft part and exposed to the front side of the front plate 4201, and a shaft part opposite to the operation part 6405a A bolt portion 6405b formed by screwing a screw on the outer peripheral surface of the screw.

  The bolt part 6405b is screwed into a nut part 6403a formed on the projecting part 6403 of the inner frame 6400. Therefore, when the operation portion 6405a is rotated by the player and the adjusting rotor 6405 is rotated, the rotation is transmitted from the bolt portion 6405b to the nut portion 6403a of the protruding portion 6403, and the nut portion 6403a is in the direction of the axis O. It is screwed to. That is, the rotational motion of the adjusting rotor 6405 is converted into a linear motion by the bolt portion 6405b and the nut portion 6403a, and as a result, the inner frame 6400 is slid and moved in the direction of the axis O.

  The second intermediate outer frame 4350 has a slit-like notch formed in a part of the second inner wall portion 4352 in order to avoid interference with the protruding portion 6403 protruding from the inner frame 6400. A projecting portion 6403 is disposed in the notch. In the notch, a second restriction surface 6352a is formed on the wall portion on the sensor 800 side, and the projecting portion 6403 is brought into contact with the second restriction surface 6352a, so that the inner frame 6400 moves toward the sensor 800 side. The slide movement is restricted. The sliding movement of the inner frame 6400 toward the start lever 71 is restricted by the end face of the opening side of the inner frame 6400 coming into contact with the first restricting portion 4242a.

  As described above, in the present embodiment, the inner frame 6400 can be slid in the direction of the axis O by rotating the adjustment operation element 6405. Thus, as in the case of the fourth embodiment, the slider The elastic deformation amount (compression amount) of the elastic member 4600 can be adjusted by changing the distance between 4500 and the bottom wall 4401 of the inner frame 6400. Thereby, when the start lever 71 is operated, the magnitude of the urging force applied in the direction opposite to the operation direction can be changed, so that the player can arbitrarily change the force required to operate the start lever 71, As a result, the start lever 71 can be operated with an operation feeling suitable for the player.

  Further, in the present embodiment, the rotational motion of the adjusting rotor 6405 can be converted into the linear motion of the inner frame 6400, so that the structure for adjusting the elastic deformation amount of the elastic member 4600 can be reduced in size. Further, since the elastic deformation amount of the elastic member 4600 can be continuously adjusted, an operation feeling suitable for the player can be obtained with certainty. Furthermore, even if the adjusting rotor 6405 is rotated once, the amount by which the inner frame 6400 is screwed is a distance corresponding to one pitch of the screws in the bolt portion 6405b and the nut portion 6403a, so the elastic deformation amount (compression amount) of the elastic member 4600 ) Can be easily adjusted.

  Further, in the present embodiment, the magnitude of the biasing force applied to the start lever 71 can be adjusted only by one elastic member 4600, and characteristics (spring constants) for applying different biasing forces. Since there is no need to provide a plurality of elastic members having different values, the product cost can be reduced accordingly.

  Further, in the present embodiment, conversion of the rotational motion into linear motion is performed by the bolt portion 6405b and the nut portion 6403a, and the inner frame 6400 is not rotated, so that the elastic member 4600 is rotated with the rotation of the inner frame 6400. It can suppress twisting. Therefore, the urging force can be stably applied to the start lever 71, and the durability of the elastic member 4600 can be improved.

  The elastic member 4600 has the bottom wall 4401 and the slider even when the inner frame 6400 is moved most toward the sensor 800 (that is, when the projecting portion 6403 is in contact with the second restriction surface 6352a). It has an axial dimension (dimension in the left-right direction in FIG. 37) that can only be compressed and deformed with 4500. Therefore, when the start lever 71 is not operated, the elastic member 4600 is always elastically compressed and deformed, and the pressed plate 4501 of the slider 4500 moves the base end surface of the start lever 71 by the elastic recovery force. Pressing.

  As described above, in the present embodiment, even when the elastic deformation amount of the elastic member 4600 is minimized, the elastic member 4600 is elastically deformed (compressed). A preload can be applied between the internal thread 6403a of the 6403 and the external thread 6405b of the adjusting rotor 6405. Thereby, it is possible to suppress the occurrence of a gap between the external thread and the internal thread in the external thread part 6405b and the internal thread part 6403a, and to suppress the rattling of the inner frame 6400. The operational feeling can be improved.

  Further, in this way, by applying a preload between the external thread portion 6405b and the internal thread portion 6403a, the rotational position of the inner frame 6400 is utilized by using the frictional force that operates between the external thread and the internal thread. Can be held. This eliminates the need for a mechanism for holding the rotational position of the inner frame 6400, thereby reducing the product cost. Further, it is possible to prevent the rotational position of the inner frame 6400 from being shifted with the operation of the start lever 71, and as a result, it is possible to easily keep the operation force constant.

  Next, a seventh embodiment will be described with reference to FIGS. 38 to 47. FIG. 38 is a perspective view of the switch device 7100 according to the seventh embodiment, and FIG. 39 is a cross-sectional view of the switch device 7100. The switch device 7100 is attached to the front door 12 by a flange formed on the outer peripheral surface of the front outer frame 7200 being fastened and fixed to the rear side of the front door 12, but in FIGS. The illustration of the flange is omitted.

  In the first embodiment, a plurality of elastic members 600 having different characteristics (spring constants) are provided, and the magnitude of the urging force applied to the start lever 71 is selected by selecting one of the plurality of elastic members 600. Although the case where it changes is demonstrated, the switch apparatus 7100 in 7th Embodiment is provided with the elastic members 7601-7603 from which a characteristic differs, By selecting the combination of these several elastic members 7601-7603, the start lever 71 is provided. Change the magnitude of the force applied. In addition, the same code | symbol is attached | subjected to the part same as each above-mentioned embodiment, and the description is abbreviate | omitted.

  The switch device 7100 according to the seventh embodiment includes a front outer frame 7200, an intermediate outer frame 7250, and a rear outer frame 7300 that constitute the housing, and a rotatable and axial center within the housing formed by the outer frames 7200 and the like. A rotating plate 7500 that is housed so as to be slidable in the O direction, and an inner spring pusher 7510, an intermediate spring pusher 7520, and an outer spring pusher 7530 that are partially or entirely slid according to the rotational position of the rotary plate 7500. A slider 7550 that is slid in association with a part or all of the spring pushers 7510 to 7530, a return spring member 7610 that applies a biasing force to the slider 7550, and each spring. An inner spring member 7601, a middle spring member 7602, and an outer spring that apply different urging forces to the push bodies 7510 to 7530. It comprises a timber 7603, a start lever 71 is given the operation feeling during operation by their urging force of each spring member 7601-7603, and a sensor 800 for detecting an operation of the start lever 71.

  The front outer frame 7200 is a member that forms the front side of the housing, and is formed in a bottomed cylindrical shape having an axis O. That is, the front outer frame 7200 includes a front plate 7201 that closes an opening on one side (right side in FIG. 39) of the cylindrical body. The front plate 7201 includes a lever holding portion 202 that holds the start lever 71, and an adjusting rotor. A pivoted support portion 7203 on which 7405 is rotatably supported is formed.

  The intermediate outer frame 7250 is a member constituting the middle of the housing, and is formed in a bottomed cylindrical shape having an axis O. Here, the detailed configuration of the intermediate outer frame 7250 will be described with reference to FIG. 40A is a rear view of the intermediate outer frame 7250, and FIG. 40B is a cross-sectional view of the intermediate outer frame 7250 taken along the line XXXb-XXXb of FIG. 40A.

  As shown in FIG. 40, the intermediate outer frame 7250 includes a cylindrical body that is located on the outer peripheral side and forms an outer wall, and a back plate 7251 that closes the opening on the other side (left side of FIG. 40 (b)) of the cylindrical body. Prepare. In the cylindrical body, the inner diameter of the portion on the side opposite to the back plate 7251 is made larger than the inner diameter of the portion on the back plate 7251 side, and a step is formed between these two portions. . The restricting surface 7252 is a part that receives the end surface of the rotating plate 7500, and the end surface of the rotating plate 7500 is brought into contact with the restricting surface 7252, so that the displacement of the rotating plate 7500 toward the sensor 800 is restricted.

  The rear plate 7251 is provided with an inner locking port 7251a, an intermediate locking port 7251b, an outer locking port 7251c having a rectangular shape when viewed from the front, and an opening 7251d having a circular shape when viewed from the front. The inner locking port 7251 is an opening through which the locking leg portion 7511 of the inner spring pusher 7510 is inserted, and a pair of the inner locking ports 7251 are formed at positions that are equidistant from the axis O while sandwiching the axis O. The middle locking port 7251b is an opening through which the locking leg 7521 of the middle spring pusher 7520 is inserted, and a pair sandwiches the axis O at a position shifted by 90 degrees from the inner locking port 7251a. It is formed at a position that is equidistant from the axis O.

  The outer locking port 7251c is an opening through which the locking leg 7531 of the outer spring pushing body 7530 is inserted, and a pair of the shaft center O is sandwiched between the pair of shafts O at the same phase as the middle locking port 7251b. It is formed in the position which becomes equidistance from. Note that the locking leg portions 7511 to 7531 inserted through the locking ports 7251a to 7251c are locked to the back side (left side of FIG. 40B) of the back plate 7251 (see FIG. 39). The opening 7251d is an opening through which the detection pin 7551 of the slider 7550 is inserted, and is formed in the center of the back plate 7251.

  Returning to FIG. The rear outer frame 7300 is a member that forms the rear surface side of the housing, and is formed in a bottomed cylindrical shape having an axis O. That is, the rear outer frame 7300 includes a back plate 7301 that closes the opening on the other side (left side in FIG. 39) of the cylindrical body, and the sensor 800 is attached to the back plate 7301. The rear outer frame 7300 is joined to the front outer frame 7200 with the intermediate outer frame 7250 interposed therebetween, so that a housing (outer frame) having an accommodation space inside is formed.

  The adjusting rotor 7405 is a disk-like member that is operated to rotate and move the rotating plate 7500, and is fastened to the pivoted support portion 7203 of the front outer frame 7200 with a screw, and is disposed in a rotatable shaft supported state. Is done. The adjusting rotor 7405 has teeth formed on the outer peripheral surface thereof, and meshes with the gear cylinder portion 7503 of the rotating plate 7500 via the teeth. Therefore, when the adjusting rotor 7405 is rotated, the rotation is transmitted to the gear cylinder portion 7503, and the rotating plate 7500 is rotated around the axis O. Thereby, the operation | movement which rotates the rotating plate 7500 and arrange | positions to a predetermined | prescribed phase (refer FIG.45 and FIG.46) can be performed easily.

  The adjusting rotor 7405 is disposed inside the casing 11 of the slot machine 10 when the front outer frame 7200 is attached to the front door 12. Therefore, careless operation by the player can be avoided and damage to the adjusting rotor 7405 and the rotating plate 7500 can be suppressed. Further, in this case, the opening that exposes a part of the adjusting rotor 7405 so as to be operable is not positioned on the player side, and the opening is shielded by the front door 12, and accordingly, foreign matter is inserted through the opening. It is possible to make it difficult to perform fraudulent acts such as Further, by operating the adjusting rotor 7405, it is possible to easily change and select the urging force even in a narrow space in the casing 11 of the slot machine 10.

  However, for example, by attaching the intermediate outer frame 7250 to the front door 12, the adjusting rotor 7405 may be disposed outside the casing 11 of the slot machine 10 and exposed to the front side of the front door 12. Thereby, the player can easily move the rotating plate 7500, that is, change the urging force. Further, the operating force can be changed without changing the operating position of the start lever 71. That is, even if the rotating plate 7500 is rotated and the magnitude of the urging force is changed, the operation of the start lever 71 can always be performed at the same position, so that the operability can be ensured.

  The rotary plate 7500 is a member that slides in the direction of the axis O in accordance with the operation of the start lever 71 and slides part or all of the spring pushers 7510 to 7530 toward the sensor 800 side. It is inserted in the inner periphery side of 7200 in the state which can rotate and slide. Here, the detailed configuration of the rotating plate 7500 will be described with reference to FIGS. 41 and 42.

  41A is a front view of the rotating plate 7500, and FIG. 41B is a rear view of the rotating plate 7500. FIG. 42 is a cross-sectional view of the rotary plate 7500 taken along the line XXXII-XXXII in FIG. The rotating plate 7500 includes a cylindrical body 7501 formed in a cylindrical shape having an axis O, a pressed plate 7502 that closes one side (right side in FIG. 42) of the cylindrical body 7501, and the pressed plate 7502. A gear cylinder portion 7503 that is erected from the front side and formed concentrically and cylindrically with the cylindrical body 7501, and first to fourth protrusions that protrude from the back side of the pressed plate 7502 and that are formed in a circular column with a circular cross section. Pins 7504a to 7504d.

  The cylindrical body 7501 is held on the inner periphery of the front outer frame 7200 and the intermediate outer frame 7250 so as to be rotatable and slidable in the direction of the axis O, and the end surface on the other side (left side in FIG. 42) has an intermediate outer frame. By abutting against the restriction surface 7252 of 7250, the sliding movement toward the sensor 800 side is restricted.

  The pressed plate 7502 is a portion with which the base end surface of the start lever 71 comes into contact. When the start lever 71 is operated, the pressed plate 7502 is pressed by the base end surface of the start lever 71, thereby rotating the rotating plate 7500. Is slid toward the sensor 800 side.

  The gear cylinder portion 7503 is a portion to which the rotation from the adjusting rotor 7405 is transmitted, and teeth that mesh with the adjusting rotor 7405 are engraved on the outer peripheral surface. Further, the gear cylinder portion 7503 is fitted on the lever holding portion 202 of the front outer frame 7200, and also serves as a guide when the rotating plate 7500 is rotated and slid.

  The first to fourth projecting pins 7504a to 7504d are portions for pressing one of the spring pushing bodies 7510 to 7530 to the sensor 800 side when the rotating plate 7500 is slid toward the sensor 800 side. is there. Specifically, the first projecting pin 7504a is a part for pressing the outer spring pusher 7530, and the position corresponding to the outer spring pusher 7530 (that is, the separation distance from the axis O is each projecting pin 7504a). ˜7504d).

  The third projecting pin 7504c is a part for pressing the inner spring pusher 7510, and a position corresponding to the inner spring pusher 7510 (that is, the distance from the axis O is within the projecting pins 7504a to 7504d). (Smallest position). The second projecting pin 7504b and the fourth projecting pin 7504d are portions for pressing the middle spring pusher 7520, and the position corresponding to the inner spring pusher 7510 (that is, the separation distance from the axis O is the first projecting). It is disposed at a position intermediate between the pin 7504a and the third protruding pin 7504c.

  The first projecting pin 7504a and the third projecting pin 7504c are arranged at a position on an imaginary line passing through the axis O, and the second and fourth projecting pins 7504b and 7504d are slightly out of phase from the imaginary line ( In the present embodiment, the protrusion pins 7504a to 7504d are arranged at positions shifted by a distance equal to or less than twice the diameter. Further, each of the spring pushing bodies 7510 to 7530 is provided with relief holes 7511 to 7513 capable of receiving the first to fourth projecting pins 7504a to 7504d (see FIG. 43), and the relief holes 7511 to 7513 are provided in the relief holes 7511 to 7513. When the projecting pins 7504a to 7504d are received, no pressing force is applied to the spring pushing bodies 7510 to 7530 from the received projecting pins 7504a to 7504d.

  In this case, the second and fourth projecting pins 7504b and 7504d are arranged on one side and the other side with the axis O sandwiched therebetween, so that they are end surfaces of the intermediate spring pusher 7520 and sandwich the axis O therebetween. Two opposing positions can be pressed (see FIG. 45 (c), FIG. 46 (a) and FIG. 46 (c)). As a result, the inclination of the middle spring pusher 7520 can be suppressed, and the middle spring pusher 7520 can be smoothly slid in the direction of the axis O.

  Further, when the second and fourth projecting pins 7504b and 7504d are inserted into the escape holes 7522, the middle spring pusher 7520 is inclined by fitting the fourth projecting pins 7504b and 7504d with the escape holes 7522. Is suppressed. Therefore, when the spring pushers 7510 and 7530 located on the inner peripheral side or the outer peripheral side of the intermediate spring pusher 7520 are slid and moved (FIGS. 45B, 45D and 46B). )), The middle spring pusher 7520 serves as a guide, and the inclination of each of the spring pushers 7510 and 7530 can be suppressed and smoothly slid in the direction of the axis O.

  Returning to FIG. Between the rotary plate 7500 and the slider 7550, an inner spring pusher 7510, a middle spring pusher 7520, and an outer spring pusher 7530 are disposed. When the rotating plate 7500 is slid and moved toward the sensor 800, the movement is transmitted to the slider 7550 via the spring pushers 7510 to 7530, and the slider 7550 is slid toward the sensor 800 side. When the slider 7550 is slid and moved toward the start lever 71, the movement is transmitted to the rotating plate 7500 via the spring pushing bodies 7510 to 7530, and the rotating plate 7500 is directed toward the start lever 71. And slide.

  Here, with reference to FIG. 43, the detailed structure of each spring pushing body 7510-7530 is demonstrated. 43 (a) is a front view of the inner spring pushing body 7510, the middle spring pushing body 7520, and the outer spring pushing body 7530, and FIG. 43 (b) is an inner spring taken along the line XXXIII-XXXIII in FIG. 43 (a). It is sectional drawing of the pushing body 7510, the middle spring pushing body 7520, and the outer spring pushing body 7530. FIG. In FIG. 43, the arrangement of the spring pushers 7510 to 7530 in a state of being housed in the switch device 7100 is illustrated.

  As shown in FIG. 43, each spring pusher 7510-7530 is formed in a cylindrical shape having an axis O, and is recessed from the back side (left side of FIG. 43 (b)) toward the front side. Is formed over the entire circumference. That is, each of the spring pushing bodies 7510 to 7530 is formed in a cylindrical shape obtained by rotating a U-shape with the back side opened around the axis O as shown in FIG.

  The inner spring pusher 7510, the middle spring pusher 7520, and the outer spring pusher 7530 are configured separately from each other, and each has a different diameter dimension. It is inserted and arranged in a nested manner in this order. That is, an intermediate spring pusher 7520 is inserted and arranged on the inner peripheral side of the outer spring pusher 7530, and an inner spring pusher 7510 is inserted and arranged on the inner peripheral side of the intermediate pusher spring 7520.

  Thus, each spring pushing body 7510-7530 is formed in the cylindrical shape from which a diameter differs, respectively, and the space in the switch apparatus 7100 is used efficiently by inserting in order to the inner peripheral side in a nested form. Therefore, the size can be reduced. As a result, even if the arrangement space in the switch device 7100 is limited, the number of arrangements of the spring pushing bodies 7510 to 7530 (that is, the respective spring members 7601 to 7603) can be ensured. By increasing the number of types of urging force combinations that can be made, it is possible to easily obtain a feeling of operation suitable for the player.

  Each spring pushing body 7510-7530 is formed with a pair of locking leg portions 7511-7531, respectively. These locking leg portions 7511 to 7513 are flange portions that are formed so as to protrude from the extending tips while being inserted into the respective locking ports 7251a to 7251c (see FIG. 40) opened in the back plate 7251 of the intermediate outer frame 7250. The back plate 7251 of the intermediate outer frame 7250 is locked (see FIG. 39). Accordingly, each of the spring pushing bodies 7510 to 7530 is allowed to slide toward the sensor 800 side, and the sliding movement toward the start lever 71 side is restricted at a predetermined position.

  A plurality of escape holes 7512 to 7532 penetratingly formed in the direction of the axis O are distributed in the circumferential direction in each of the spring pushing bodies 7510 to 7530. Each of the escape holes 7512 to 7532 is a hole for allowing the projecting pins 7504a to 7504c of the rotating plate 7500 to escape, and is formed as a circular hole having an inner diameter larger than the outer diameter of each of the projecting pins 7504a to 7504c. .

  For example, when the rotary plate 7500 is slid toward the sensor 800 side, if the first protruding pin 7504a presses the non-formation surface of the escape hole 7532 of the outer spring pusher 7530, the outer spring pusher 7530 becomes the sensor. When the first projecting pin 7504a is inserted into the escape hole 7532 while being slid and moved toward the 800 side, the pressing force of the first projecting pin 7504a is not transmitted to the outer spring pusher 7530, and the outer spring is pushed. The body 7530 is not slid toward the sensor 800 side.

  Returning to FIG. The slider 7550 is a member that is slid toward the sensor 800 by being pressed by any or all of the spring pushers 7510 to 7530 when the start lever 71 is operated. Here, the slider 7550 will be described with reference to FIG.

  44A is a rear view of the slider 7550, and FIG. 44B is a cross-sectional view of the slider 7550 taken along the line XXXIVb-XXXIVb in FIG. 44A. The slider 7550 is formed in a disc shape having an axis O and has an outer diameter equivalent to that of the outer spring pusher 7530 (see FIG. 39). Further, the slider 7550 is provided with an inner insertion port 7550a, a middle insertion port 7550b, and an outer insertion port 7550c having a rectangular shape in front view, and a cylindrical detection pin 7551 having a circular cross section along the axis O. Projected from the side.

  The inner insertion port 755oa is an opening through which the locking leg 7511 of the inner spring pusher 7510 is inserted, and a pair is formed at a position equidistant from the axis O while sandwiching the axis O. The intermediate insertion port 7550b is an opening through which the locking leg 7521 of the intermediate spring pusher 7520 is inserted, and a pair of shaft centers with the axis O sandwiched at a position shifted by 90 degrees from the inner insertion port 7550a. It is formed at a position that is equidistant from O. The outer insertion port 7550c is an opening through which the locking leg 7531 of the outer spring pusher 7530 is inserted, and a pair of shaft insertion points O and the like from the axis O at the same phase as the middle insertion port 7550b. It is formed at a position to be a distance. That is, these insertion holes 7550a to 7550c are formed at positions corresponding to the respective locking openings 7251a to 7251c of the intermediate outer frame 7250.

  The detection pin 7551 is a part for causing the sensor 800 to detect the displacement of the slider 7550, and the leading end side protrudes from the opening 7251 of the intermediate outer frame 7250 toward the sensor 800. When the start lever 71 is operated and at least one of the spring pushing bodies 7510 to 7530 is slid toward the sensor 800, the slider 7550 is displaced toward the sensor 800 along with the sliding movement. The detection pin 7551 is similarly displaced. In this case, when the standing tip of the detection pin 7551 enters the detection area of the sensor 800, the operation of the start lever 71 is detected by the sensor 800.

  As described above, when at least one of the spring pushing bodies 7510 to 7530 is displaced, the slider 7550 is displaced, and the start lever 71 is operated based on the position of the detected pin 7551 of the slider 7550. Since it can be detected, it is not necessary to arrange the detected pins 7551 and the sensors 800 by the number of the spring pushing bodies 7510 to 7530, and the number of arrangement can be made 1, and as a result, the product cost can be reduced. be able to.

  Further, since the opening 7251a in the inner peripheral side of the inner spring pushing body 7510 and the back plate of the intermediate outer frame 7250 can be shielded by the slider 7550, it is difficult to perform an illegal act on the sensor 800 from the start lever 71 side. can do.

  Returning to FIG. An inner spring member 7601, an intermediate spring member 7602, and an outer spring member 7603 are disposed in recesses provided in the inner spring pusher 7510, the middle spring pusher 7520, and the outer spring pusher 7530, respectively. Further, a return spring member 7610 is disposed between the opposing surfaces of the slider 7550 and the back plate 7251 of the intermediate outer frame 7250. Each of the spring members 7601-7603 and the return spring member 7610 is a member for generating an urging force for giving an operational feeling to the start lever 71 and returning it to the initial position, and is made of a rubber-like elastic material. Note that the spring members 7601 to 7603 are not disposed at the positions where the escape holes 7512 to 7532 are formed, and the projecting pins 7504a to 7504c can be inserted into the escape holes 7512 to 7532.

  The axial dimension (the lateral dimension in FIG. 39) of each spring member 7601-7603 is made larger than the recessed depth of the recess in each spring pusher 7510-7530. Further, the axial dimension (the lateral dimension in FIG. 39) of the return spring member 7610 is the slider 7550 and the back plate 7251 of the intermediate outer frame 7250 in a state where each of the spring pushers 7510 to 7530 is not elastically deformed in the axial direction. It is made larger than the distance between opposing surfaces formed between. Therefore, in the state shown in FIG. 39 in which the start lever 71 is not operated, the spring members 7601 to 7603 and the return spring member 7610 are elastically compressed and deformed in the axial direction, and the slider 7550 and The rotating plate 7500 presses the base end surface of the start lever 71 via the spring pushing bodies 7510 to 7530.

  Here, each spring pushing body 7510 to 7530 and slider 7550 has a locking leg portion 7511 to 7531 of each spring pushing body 7510 to 7530, and each locking opening 7550 a to 7550 c of each slider 7550 and each locking of the intermediate outer frame 7250. By being inserted into the ports 7251a to 7251c and being locked to the back side of the back plate 7251, the intermediate outer frame 7250 is supported so as not to rotate around the axis O and to move in the direction of the axis O. . As a result, when the rotating plate 7500 is rotated, the phase relationship between the rotating plate 7500 and each of the spring pushing bodies 7510 to 7530 can be changed, and the sliding movement of the rotating plate 7500 toward the sensor 800 is performed. The slider 7550 can be simply configured to slide toward the sensor 800 side.

  Each spring member 7601-7603 is set to a different characteristic (spring constant). Specifically, in this embodiment, when the value of the spring constant of the inner spring member 7601 is 1, the value of the spring constant of the middle spring member 7602 is 2, and the value of the spring constant of the outer wing member 7603 is set. Is set to a ratio of 2.5 (see FIG. 47). Therefore, by combining these spring members 7601 to 7603, the magnitude of the urging force that urges the start lever 71 can be changed to six levels. Here, a method for changing the biasing force will be described with reference to FIGS. 45 to 47.

  FIG. 45A is a front view of the rotating plate 7500, and the arrangement positions of the first to fourth projecting pins 7500a to 7500d projecting to the back side of the pressed plate 7502 are illustrated using “x”. In addition, the outer shape of each of the spring pressing bodies 7510 to 7530 disposed on the back side of the pressed plate 7502 is illustrated using broken lines. In FIG. 45A, an imaginary line that connects the centers of the first and third projecting pins 7504a and 7504c and passes through the axis O is illustrated using a broken line. Further, in FIG. 45A, one end side (first protruding pin 7500a side) of the imaginary line is a reference position A of the rotating plate 7500, and the reference position A is indicated by a symbol “A”.

  45 (b) to 45 (d) and FIGS. 46 (a) to 46 (c) are front views of the respective spring pushing bodies 7510 to 7530, in which the rotating plate 7500 is positioned in each of the first to sixth phases. The arrangement | positioning position of the 1st-4th protrusion pins 7500a-7500d with respect to each spring pushing body 7510-7530 at the time of rotating to a phase position is shown in figure. In FIGS. 45B to 45D and 46A to 46C, the reference numerals “7512 to 7532” of the escape holes 7512 to 7532 are omitted to simplify the drawing. Is done.

  FIG. 47 is a table showing the relationship between the phase of the rotating plate 7500 and the spring constant. In FIG. 47, it is assumed that the spring constant of the inner spring member 7601 is k = 1, the spring constant of the middle spring member 7602 is k = 2, and the spring constant of the outer spring member 7603 is k = 2.5. The description is omitted. Here, since each spring member 7601-7603 is a parallel connection in which the displacement amount when the rotating plate 7500 slides is the same displacement amount, the total spring constant when the rotating plate 7500 slides is the respective spring constant. This is the total value of the spring constants of the members 7601 to 7603 that are displaced as the rotary plate 7500 slides. In FIG. 47, the total spring constant is described in association with each phase in the bottom column.

  As shown in FIG. 45A, the first to fourth projecting pins 7500a to 7500d project from the rotary plate 7500 toward the back side (that is, the respective spring pushing bodies 7510 to 7530). 7500a is at a position corresponding to the outer spring pressing body 7530, the second and fourth spring pressing bodies 7500b and 7500d are at a position corresponding to the middle spring pressing body 7520, and the third spring pressing body 7500c is at the inner spring pressing body 7510. Each is arranged.

  As described above, each of the spring pushing bodies 7510 to 7530 is only one in which the non-formed surface is pressed when the non-formed surface of the escape holes 7512 to 7532 is pressed by any of the projecting pins 7500a to 7500d. Is slid toward the sensor 800 (that is, the corresponding ones of the spring members 7601 to 7603 are elastically deformed), and the biasing force can be applied to the start lever 71, while the projecting pins 7500a to 7500d are Those which are inserted into the escape holes 7512 to 7532 and the non-formed surface is not pressed are not slid toward the sensor 800 side (that is, the corresponding ones of the spring members 7601 to 7603 are not elastically deformed), and start. No biasing force is applied to the lever 71. Therefore, the magnitude of the urging force applied to the start lever 71 is changed depending on the combination of these spring pushing bodies 7510 to 7530 that are slid.

  As shown in FIG. 45B, when the rotating plate 7500 is rotated and positioned in the first phase, the first, second and fourth projecting pins 7500a, 7500b, 7500d are inserted into the escape holes 7522, 7532. Only the third projecting pin 7500c is arranged on the non-formation surface of the escape hole 7512. Therefore, when the rotating plate 7500 is slid toward the sensor 800, only the inner spring pusher 7510 is pressed by the third projecting pin 7500c and slid toward the sensor 800 (that is, the inner spring member). Only 7601 is elastically deformed). Therefore, the total spring constant in the first phase is “1”, which is the same as the spring constant of the inner spring member 7601, as shown in FIG. 47 (see FIG. 47).

  In addition, a protrusion is provided on the outer peripheral surface of the cylindrical body 7501 of the rotating plate 7500, and the inside of the cylindrical body of each outer frame 7200, 7250 into which the cylindrical body 7501 of the rotating plate 7500 is inserted. On the peripheral surface, recesses are provided at a plurality of locations (60 ° intervals) in the circumferential direction, and the protrusions of the rotating plate 7500 can be engaged. Each of these recesses is extended along the direction of the axis O, so that the rotating plate 7500 can be slid in the direction of the axis O while the protrusion is engaged. Are set at positions corresponding to the first to sixth phases. Therefore, when rotating the rotating plate 7500, the rotating plate 7500 can be easily arranged in the first to sixth phases by rotating the rotating plate 7500 to a position where the protrusion and the recess are engaged.

  As shown in FIG. 45 (c), when the rotary plate 7500 is rotated by 60 ° clockwise from the first phase and positioned in the second phase, the first and third projecting pins 7500a and 7500c are The second and fourth projecting pins 7500b and 7500d are arranged on the non-formation surface of the escape hole 7512. The second and fourth projecting pins 7500b and 7500d are arranged at positions corresponding to the escape holes 7512 and 7532. Therefore, when the rotating plate 7500 is slid and moved toward the sensor 800, only the middle spring pusher 7520 is pressed by the second and fourth projecting pins 7500b and 7500d and slid toward the sensor 800 ( That is, only the middle spring member 7602 is elastically deformed). Therefore, the total spring constant in the second phase is “2”, which is the same as the spring constant of the middle spring member 7602, as shown in FIG.

  As shown in FIG. 45 (d), when the rotary plate 7500 is rotated 60 degrees clockwise from the second phase and positioned in the third phase, the second to fourth projecting pins 7500b to 7500d are The first protrusion pin 7500a is disposed on the surface where the escape hole 7532 is not formed, and the first protrusion pin 7500a is disposed at a position corresponding to the escape holes 7512 and 7522 (that is, a position where the escape hole 7532 is inserted when sliding). Therefore, when the rotating plate 7500 is slid toward the sensor 800, only the outer spring pusher 7530 is pressed by the first projecting pin 7500a and slid toward the sensor 800 (that is, the outer spring member). Only 7603 is elastically deformed). Therefore, the total spring constant in the third phase is “2.5”, which is the same as the spring constant of the outer spring member 7603, as shown in FIG. 47 (see FIG. 47).

  As shown in FIG. 46A, when the rotary plate 7500 is rotated 60 ° clockwise from the third phase and positioned in the fourth phase, only the first projecting pin 7500a enters the escape hole 7532. The second to fourth projecting pins 7500b to 7500d are disposed on the non-formation surfaces of the escape holes 7512 and 7522. Therefore, when the rotating plate 7500 is slid toward the sensor 800 side, the inner spring pushing body 7510 and the middle spring pushing body 7520 are pressed by the second to fourth projecting pins 7500b to 7500d and moved toward the sensor 800 side. The sliding movement is performed (that is, the inner spring member 7601 and the middle spring member 7602 are elastically deformed). Therefore, the total spring constant in the fourth phase is the sum of the spring constant (k = 1) of the inner spring member 7601 and the spring constant (k = 2) of the middle spring member 7602 as shown in FIG. 3 ".

  As shown in FIG. 46B, when the rotary plate 7500 is rotated by 60 ° clockwise from the fourth phase and positioned in the fifth phase, the second and fourth projecting pins 7500b and 7500d are moved. The first and third projecting pins 7500a and 7500c are arranged on the surface where the escape holes 7512 and 7532 are not formed. The first and third projecting pins 7500a and 7500c are arranged at positions corresponding to the escape holes 7532 (that is, positions inserted when sliding). Therefore, when the rotating plate 7500 is slid and moved toward the sensor 800 side, the inner spring pusher 7510 and the outer spring pusher 7530 are pressed by the first and third projecting pins 7500a and 7500c and moved toward the sensor 800. The sliding movement is performed (that is, the inner spring member 7601 and the outer spring member 7603 are elastically deformed). Therefore, the total spring constant in the fifth phase is the sum of the spring constant (k = 1) of the inner spring member 7601 and the spring constant (k = 2.5) of the outer spring member 7603, as shown in FIG. , “3.5”.

  As shown in FIG. 46 (c), when the rotary plate 7500 is rotated clockwise by 60 ° from the fifth phase and positioned in the sixth phase, only the third projecting pin 7500c enters the escape hole 7532. The first, second, and fourth projecting pins 7500a, 7500b, and 7500d are disposed on the non-formation surfaces of the escape holes 7522 and 7532, respectively. Therefore, when the rotary plate 7500 is slid toward the sensor 800 side, the middle spring pusher 7520 and the outer spring pusher 7530 are pressed by the first, second, and fourth projecting pins 7500a, 7500b, 7500d, and the sensor It is slid toward 800 side (that is, the middle spring member 7602 and the outer spring member 7603 are elastically deformed). Therefore, the total spring constant in the sixth phase is the sum of the spring constant (k = 2) of the middle spring member 7602 and the spring constant (k = 2.5) of the outer spring member 7603, as shown in FIG. , “4.5”.

  Thus, by positioning the rotary plate 7500 in the first to sixth phases, the spring members 7601 to 7603 can be combined and the magnitude of the urging force urging the start lever 71 can be selected from six types. it can. In this case, the magnitude of the total spring constant in each phase increases or decreases in order according to the phase. That is, by rotating the rotating plate 7500 clockwise in front view (moving the phase from the first phase to the sixth phase), the magnitude of the urging force can be increased in order, while the rotating plate 7500 is moved to the front. By rotating it counterclockwise, the magnitude of the urging force can be reduced in order. Thereby, the operativity at the time of changing the magnitude | size of urging | biasing force can be aimed at.

  In this case, as described above, the second and fourth projecting pins 7504b and 7504d are disposed on one side and the other side with the axis O interposed therebetween, so that the second and fourth projecting pins 7504b and 7504d When the intermediate spring pusher 7520 is pressed (that is, in the case of the second, fourth, and sixth phases), the inclination of the middle spring pusher 7520 is suppressed and the slide is smoothly slid in the direction of the axis O. Can do.

  On the other hand, when the second and fourth projecting pins 7504b and 7504d are inserted into the escape holes 7522 (that is, in the case of the first, third, and fifth phases), the fourth projecting pins 7504b and 7504d are allowed to escape. By fitting the holes 7522 on both sides of the axis O, the inclination of the middle spring pusher 7520 is suppressed. Therefore, when the inner spring pusher 7510 or (and) the outer spring pusher 7530 is slid, the middle spring pusher 7520 serves as a guide, and the inner spring pusher 7510 or (and) the outer spring pusher. The inclination of 7530 can be suppressed, and as a result, it can be smoothly slid in the direction of the axis O.

  In particular, in the case of the first, third and fifth phases, the first or third projecting pins 7504a and 7504c press only one portion of the inner spring pressing body 7510 or the outer spring pressing body 7530, and thus are easily inclined. However, since these first and third projecting pins 7504a and 7504c are close to the second and fourth projecting pins 7504b and 7504d (distances equal to or less than twice the diameters of the projecting pins 7504a to 7504d), The guide effect by the spring pushing body 7520 can be easily obtained, and smooth sliding movement can be ensured.

  Note that in a state where the rotating plate 7500 is not positioned in each of the first to sixth phases, any of the projecting pins 7500a to 7500d is inserted into a position corresponding to the escape holes 7512 to 7532 (that is, inserted when sliding). It is not arranged at the position), but is arranged on the non-formation surface of the escape holes 7512 to 7532. Therefore, in this state, when the rotating plate 7500 is slid and moved toward the sensor 800, the spring pushers 7510 to 7530 are pressed by the projecting pins 7500a to 7500d, and are slid toward the sensor 800. (That is, all of the inner spring member 7601, the middle spring member 7602, and the outer spring member 7603 are elastically deformed). Therefore, the total spring constant in this state is the spring constant of the inner spring member 7601 (k = 1), the spring constant of the middle spring member 7602 (k = 2), and the spring constant of the outer spring member 7603 (k = 2). .5) and becomes “5.5”.

  As described above, in the seventh embodiment, a plurality of spring members 7601 to 7603 are adjusted by rotating the rotating plate 7500 and adjusting the positional relationship between the escape holes 7512 to 7513 and the projecting pins 7500a to 7500d. Thus, the magnitude of the urging force urged by the start lever 71 can be switched. Thereby, the magnitude of the urging force can be arbitrarily selected, and as a result, the start lever 71 can be operated with an operation feeling suitable for the player.

  As described above, the present invention has been described based on the embodiments, but the present invention is not limited to the above embodiments, and various modifications can be easily made without departing from the spirit of the present invention. It can be guessed.

  The numerical values given in the above embodiment are merely examples, and other numerical values can naturally be adopted.

  In the first to third embodiments, a sensor for detecting the rotational position (phase) of the inner frame 400 is provided, and whether or not the inner frame 400 is in an appropriate rotational position (that is, the pressed plate 501 of the slider 500). May be detected to notify whether or not it is at a position facing the base end face of the start lever 71). Thereby, the slider 500 can be surely displaced by the operation of the start lever 71, and the inner frame 400 and the like can be prevented from being damaged by the operation when the inner frame 400 is in an inappropriate position.

  In the first to third embodiments, the cushioning material holder 403 is recessed in the front plate 401 in the inner frame 400, and the cushioning material 900 is laid in the cushioning material holder 403 so that the inner frame 400 rotates. Even when the position is inappropriate, the case where the base end surface of the start lever 71 is prevented from directly pressing the front plate 401 of the inner frame 400 to prevent the damage has been described. However, the present invention is not necessarily limited to this. Alternatively, the installation of the buffer material holding part 403 may be omitted. In this case, it is possible to secure the recessed depth of the buffer material holding portion 403 so that the base end surface does not directly press the front plate 401 of the inner frame 400 when the start lever 71 is operated to the maximum. preferable.

  In the fourth and fifth embodiments, the case where the inner frame 4400 is rotated by providing the outer gear 4402 on the inner frame 4400 and rotating the gear 4405b meshed with the outer gear 4402 has been described. For example, a lever is fixed to the inner frame 4400 (for example, equivalent to the structure in which the adjustment lever 405 described in the first or second embodiment is fixed to the inner frame 400). The inner frame 4400 may be rotated by operation.

  In each of the above embodiments, the elastic member 600, the spring members 7601-7603, and the return spring 7604 are compressed and deformed in accordance with the operation of the start lever 71, and a biasing force is applied to the start lever 71 by the elastic recovery force. Although described above, the present invention is not necessarily limited to this, and it is naturally possible to configure the elastic member 600 and the like to be deformed in tension as the start lever 71 is operated.

  In each of the above embodiments, the case where the elastic member 600, each of the spring members 7601 to 7603, and the return spring 7604 are formed of a rubber-like elastic body has been described. Of course, it is possible to construct the material from other elastic materials such as urethane and metal materials. Moreover, although the case where the elastic member 600 grade | etc., Was formed in the cylindrical shape was demonstrated, the shape is arbitrary and may be another shape. Therefore, you may comprise the elastic member 600 grade | etc., As a coil spring or a leaf | plate spring from a metal material.

  In the seventh embodiment, the case where each of the spring members 7601 to 7603 is configured to have different characteristics (spring constants) has been described. However, the present invention is not necessarily limited to this, and some or all of these are configured. Of course, it is possible to have the same characteristic (spring constant). Accordingly, it is not necessary to prepare a plurality of types of elastic members, and the same types can be used, so that the part cost can be reduced accordingly. The same applies to the plurality of elastic members 600 in the first to third embodiments.

  In each of the above embodiments, the embodiment in which the present invention is applied to the start lever 71 has been described as an example. However, the present invention is not necessarily limited thereto. The invention may be applied to other operation means. Examples of other operation means include a credit insertion switch, a stop switch, a ball lending switch and a return switch, or a switch for switching an image displayed on the liquid crystal display device. Note that the operation means is not limited to one that can be operated by the player. Therefore, the other operation means may be an operation means disposed in the gaming machine such as a setting change switch or a power switch.

  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 of a type in which a slot machine and a pachinko machine are integrated. That is, in the slot machine, instead of the medal insertion and medal payout functions, a gaming machine having a ball insertion and ball payout function such as a pachinko machine may be used. If such a gaming machine is used in place of a slot machine, only a ball can be handled as a gaming value in the gaming hall. Therefore, a medal as a gaming value in a current gaming hall in which pachinko machines and slot machines are mixed. The problem of the burden on the equipment and the restriction of the location of the gaming machine due to the separate handling of the ball and the ball can be solved.

  It is also possible to apply the present invention to a pachinko machine. In the case of a pachinko machine, the gaming machine main body is mounted on the outer frame, and a door member is provided on the front side of the gaming machine main body. The gaming machine main body is provided with a gaming board in which a gaming area as a gaming ball flying area is formed and an operating port and a liquid crystal display device are installed, and the gaming area and liquid crystal are provided by a visual window provided on the door member. The display device is visible. Then, as the game ball launched by the game ball launching device wins the operating opening, 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-described embodiment is applied to such a pachinko machine, it is apparent that the same effect as that of the above-described embodiment can be obtained.

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

  As a specific example of a gaming machine in which a pachinko machine and a slot machine are integrated, a display device that displays a fixed display of symbols after variably displaying a symbol string composed of a plurality of symbols is provided, and a handle for ball launching is not provided. Things. In this case, after throwing a predetermined amount of spheres based on a predetermined operation (button operation), for example, the change of the symbol is started due to the operation of the operation lever, for example, due to the operation of the stop button, or With the passage of time, the variation of the symbol is stopped, and a special game that gives a predetermined game value to the player is generated on the condition that the determined symbol at the time of stoppage is a so-called jackpot symbol. In this case, a large amount of balls are paid out to the lower tray.

  Hereinafter, in addition to the gaming machine of the present invention, the concept of various inventions included in the above embodiment will be described.

  An operation means configured to be operable, a biasing means for applying a biasing force in a direction opposite to the operation direction to the operation means, a detection means for detecting that the operation means has been operated to a predetermined position, A plurality of urging means having different urging forces, and the urging means for applying the urging force to the operation means can be switched from among the plurality of urging means. A gaming machine A1 that is characterized by being played.

  According to the gaming machine A1, the urging force applied from the urging means can give the player a feeling of operation when operating the operating means, while the operating means can be returned to the initial position after the operation is completed. . In this case, the gaming machine A1 includes a plurality of urging means having different urging forces, and the urging means for applying the urging force to the operation means can be switched from among the plurality of urging means. There is an effect that the magnitude of the urging force applied to the operation means can be arbitrarily selected. Accordingly, there is an effect that the operation means can be operated with an operation feeling suitable for the player.

  In the gaming machine A1, the operating means is disposed, a first member fixed to the gaming machine main body, a movable member formed with respect to the first member, and the plurality of biasing means are disposed. And the second member is moved relative to the first member, so that any one of the plurality of urging means applies a urging force to the operating means. A gaming machine A2 which is arranged at a position where it can be given.

  According to the gaming machine A2, in addition to the effects produced by the gaming machine A1, the operating member is disposed on the first member, the plurality of urging members are disposed on the second member, and the second member is the first member. Since any one of the plurality of urging means is disposed at a position where the urging force can be applied to the operation means, any one of the plurality of urging forces can be selected. Can be selected. Therefore, the operation means can be operated with an operation feeling suitable for the player. In this case, since the first member provided with the operating means is fixed to the gaming machine main body, only the urging force can be changed without changing the operating position of the operating means. That is, even if the urging force is changed, the operation means can be operated at the same position, so that the operability can be ensured.

  In the gaming machine A2, the second member is formed to be rotatable around a rotation axis, the plurality of biasing means are distributed around the rotation axis, and the second member is rotated around the rotation axis. Thus, the gaming machine A3 is characterized in that one urging means of the plurality of urging means is sequentially arranged at a position where the urging force can be applied to the previous operating means.

  According to the gaming machine A3, in addition to the effects produced by the gaming machine A2, the second member is formed to be rotatable around the rotation axis, and the plurality of biasing means are distributed around the rotation axis. By rotating the two members around the rotation axis, one urging means among the urging means can be arranged at a position where an urging force can be applied to the operating means in order. In this case, when the plurality of urging means rotate and move with the rotation of the second member, the movement trajectories of the respective urging means can be overlapped, so that it is necessary to move the plurality of urging means accordingly. Thus, there is an effect that the area to be taken can be reduced and the size can be reduced.

  In the gaming machine A2 or A3, the gaming machine A4 is provided with a switching operation unit that is fixed to the second member and protrudes to the front side of the gaming machine main body.

  According to the gaming machine A4, in addition to the effect produced by the gaming machine A2 or A3, the gaming machine A4 includes the switching operation unit that is fixed to the second member and protrudes to the front side of the gaming machine main body. Thus, there is an effect that the movement of the second member, that is, the urging force can be easily changed. In particular, since the switching operation unit protrudes from the front side of the gaming machine main body, the player can arbitrarily change the biasing force suitable for the player according to the situation while performing the game. There is an effect that can be done.

  In the gaming machine A2 or A3, the gaming machine A5 is provided with a switching operation unit that is fixed to the second member and disposed inside the gaming machine main body.

  According to the gaming machine A5, in addition to the effects produced by the gaming machine A2 or A3, the gaming machine A5 includes the switching operation unit that is fixed to the second member and disposed inside the gaming machine main body. Thus, even in a narrow space inside the gaming machine main body, there is an effect that the second member can be easily moved, that is, the biasing force can be easily changed. In addition, by arranging the switching operation unit inside the gaming machine main body in this way, it is unnecessary to form an opening for exposing the switching operation unit on the front side of the gaming machine main body. This has the effect of making it difficult to carry out cheating.

  The gaming machine A4 or A5 includes a guide passage that guides the movement of the switching operation unit, and the second member moves relative to the first member by guiding the movement of the switching operation unit through the guide passage. A gaming machine A6 characterized by being played.

  According to the gaming machine A6, in addition to the effects produced by the gaming machine A4 or A5, the movement of the switching operation unit is guided by the guide passage, whereby the second member is moved relative to the first member. By using the portion, there is an effect that the second member can be smoothly moved in an appropriate direction with respect to the first member.

  In the gaming machine A6, the switching operation portion is elastically deformed by being brought into contact with the side wall of the guide passage, and the side wall of the guide passage is pressed by the elastic recovery force accompanying the elastic deformation. The guide passage is provided with a plurality of recesses that are recessed in a side wall against which the switching operation unit abuts and that can be engaged with the switching operation unit, and the switching operation unit is engaged with the recesses. Thus, the gaming machine A7, wherein any one of the plurality of biasing means is disposed at a position where a biasing force can be applied to the operation means.

  According to the gaming machine A7, in addition to the effects produced by the gaming machine A6, the guide passage includes a plurality of recesses to which the switching operation unit can be engaged. Any one of the urging means can be arranged at a position where the urging force can be applied to the operation means. Therefore, by engaging the switching operation portion with the recess, the urging means can be reliably arranged at a position where the urging force can be applied to the operation means, and whether the switching operation portion is engaged with the recess. Based on this, there is an effect that it is possible to reliably determine whether or not the biasing means is disposed at a position where the biasing force can be applied to the operation means.

  Further, the switching operation portion is elastically deformed by being brought into contact with the side wall of the guide passage, and is guided along the side wall of the guide passage while pressing the side wall of the guide passage by the elastic recovery force accompanying the elastic deformation. Since the concave portion of the passage is recessed in the side wall against which the switching operation portion is brought into contact, when the switching operation portion is moved along the side wall of the guide passage, the switching operation portion itself moves into the concave portion by its elastic recovery force. Engage. Accordingly, there is an effect that the operation of arranging the urging unit at a position where the urging force can be applied to the operation unit can be reliably and easily performed.

  In the gaming machine A6 or A7, the second member is formed to be rotatable around a rotation axis, the plurality of urging means are distributed around the rotation axis, and the switching operation unit is The guide passage is formed in a portion of the first member that faces the end surface in the rotation axis direction of the second member, and the second member rotates around the rotation axis. Thus, the gaming machine A8 is characterized in that one of the plurality of urging means is sequentially arranged at a position where the urging force can be applied to the previous operating means.

  According to the gaming machine A8, in addition to the effects produced by the gaming machine A6 or A7, the switching operation portion is fixed to the end surface in the rotation axis direction of the second member, and the guide passage is the first member and the rotation shaft of the second member. By forming it in the portion facing the direction end surface, the guide passage is opened in the portion of the first member, and the switching operation portion is moved from the end surface of the second member only toward the opening. Can be obtained by the guide passage. Therefore, it is possible to simplify the structure for moving the second member relative to the first member, reduce the manufacturing cost, and reduce the size. Moreover, the member for forming a guide passage is provided separately by the 1st member having the structure which combines both the member for arrange | positioning an operation means, and the member for forming a guide passage. Therefore, the product cost can be reduced accordingly. Further, by forming the guide passage in the first member, the operation means and the switching operation portion can be provided side by side, so that the operability of the player can be improved.

  In the gaming machine A8, the second member includes a cover plate that covers the region that forms the end face in the axial direction and that corresponds to the movement locus of the urging means.

  According to the gaming machine A9, in addition to the effects produced by the gaming machine A8, the second member includes the covering plate that is formed in the area corresponding to the movement locus of the biasing means and that forms the axial end surface. There is an effect that the inner side of the two members can be shielded by the covering plate. As a result, even when the guide passage is opened in the first member, it is possible to prevent foreign matter from being inserted into the second member through the guide passage.

  In the gaming machine A3, the second member is formed to be rotatable in a range of 360 degrees or more around the rotation axis.

  According to the gaming machine A10, since the second member is formed to be rotatable in a range of 360 degrees or more around the rotation axis, the selection operation when selecting the urging means for applying the urging force to the operation means is made efficient. There is an effect that can be done. That is, since the plurality of urging means are distributed around the rotation axis (arranged along the circumferential direction), the first urging means, the second urging means, and so on along the circumferential direction. When the n-th biasing means is arranged and the rotation range of the second member is less than 360 degrees, for example, the second member is rotated to the end point in one direction, In order to select the nth urging member adjacent to the first urging means from the state where the urging member is selected, the second member must be returned by about one rotation toward the other direction end point. However, in the case of the gaming machine A10, the n-th urging means can be selected by further rotating the second member in one direction, so that the operation amount necessary for the selection operation can be reduced. The efficiency can be improved.

  An operation means configured to be operable, a biasing means for applying a biasing force in a direction opposite to the operation direction to the operation means, a detection means for detecting that the operation means has been operated to a predetermined position, The biasing means is elastically deformed in accordance with the operation of the operation means and gives an urging force in a direction opposite to the operation direction to the operation means by an elastic restoring force at the time of the elastic deformation. A gaming machine B1 comprising: an elastic member configured to adjust the amount of elastic deformation of the elastic member when the operating means is not operated.

  According to the gaming machine B1, the urging force applied from the urging means can give the player a feeling of operation when operating the operation means, while the operation means can be returned to the initial position after the operation is completed. . In this case, in the gaming machine B1, the amount of elastic deformation of the elastic member when the operation means is not operated can be adjusted, so that the magnitude of the urging force applied to the operation means can be arbitrarily adjusted. There is an effect. In other words, the force required to elastically deform the elastic member is proportional to the amount of elastic deformation of the elastic member, so that a large force is required to elastically deform the elastic member when the amount of elastic deformation is larger than the reference value. On the other hand, the force required to elastically deform the elastic member in a state where the elastic deformation amount is smaller than the reference value becomes small. Therefore, by changing the elastic deformation amount of the elastic member from the reference value, the magnitude of the urging force applied in the direction opposite to the operation direction when the operation means is operated can be changed. Thereby, since the force required for operation of the operation means can be changed, there is an effect that the operation means can be operated with an operation feeling suitable for the player. In addition, the magnitude of the urging force applied to the operating means can be adjusted by one elastic member, and it is not necessary to provide a plurality of elastic members in order to apply different urging forces. The product cost can be reduced.

  In the gaming machine B1, the operation means is disposed and a case member formed with a male screw or a female screw is formed and fixed to the main body of the gaming machine, and the biasing means is provided on the male screw or the female screw of the case member. A threaded member or a male thread is formed, and a threaded member connected to the operating means via the elastic member is provided, and the threaded member is screwed into the case member, so that the screw The gaming machine B2 is characterized in that the distance between the combined member and the operating means is changed, and the elastic deformation amount of the elastic member is adjusted when the operating means is not operated.

  According to the gaming machine B2, in addition to the effects produced by the gaming machine B1, a screw or a female screw is formed on the case member, and a female screw or a male screw that can be screwed to the case member is formed on the screw member. By rotating the screwing member screwed to the member, the screwing member can be screwed. Therefore, the operation means is operated by changing the interval between the screwing member and the operation means. It is possible to adjust the amount of elastic deformation of the elastic member in the absence of the elastic member. Thereby, since the magnitude | size of the urging | biasing force provided to an operation means can be adjusted arbitrarily, an operation means can be operated with the operation feeling suitable for the player. As described above, in the gaming machine B2, by rotating the screwing member, the rotational motion is converted into a linear motion, so that the structure for adjusting the elastic deformation amount of the elastic member can be reduced in size. is there. Further, since the elastic deformation amount of the elastic member can be continuously adjusted, there is an effect that it is possible to reliably obtain an operational feeling suitable for the player. Furthermore, even if the screwing member is rotated once, since the amount of screwing is only one pitch of the male screw and the female screw, there is an effect that the amount of elastic deformation of the elastic member can be easily finely adjusted. In addition, since the case member in which the operating means is disposed is fixed to the gaming machine main body, only the urging force can be changed without changing the operating position of the operating means. That is, even if the urging force is changed, the operation means can be operated at the same position, so that the operability can be ensured.

  In the gaming machine B2, a first restricting means for restricting the screwing of the screwing member at a position where the distance between the screwing member and the operating means is maximized, and between the screwing member and the operating means. A second restricting means for restricting the screwing of the screwing member at a position where the distance is minimum, and the elastic member is elastic within a range from the maximum to the minimum between the screwing member and the operating means. A gaming machine B3 that is deformed, and a preload is applied between the male screw and the female screw of the case member and the screwing member by an elastic recovery force of the elastic member.

  According to the gaming machine B3, in addition to the effect produced by the gaming machine B2, the elastic member is elastically deformed within a range where the space between the screwing member and the operating means is the smallest, so that the elasticity of the elastic member A preload can be applied between the male screw and the female screw of the case member and the screwing member by the restoring force. As a result, it is possible to suppress the occurrence of a gap between the male screw and the female screw and to suppress the rattling of the screwing member, so that the operational feeling of the operating means can be improved accordingly. There is. In addition, in this way, by applying a preload between the male screw and the female screw, it is possible to easily maintain the rotational position of the screwing means by using the frictional force acting between the male screw and the female screw. Can do. This eliminates the need for a mechanism for holding the rotational position of the screwing means, thereby reducing the product cost.

  In the gaming machine B2 or B3, the biasing means includes a rotation operation unit that is connected to the screwing member and protrudes to the front side of the gaming machine main body to rotate the screwing member. Machine B4.

  According to the gaming machine B4, in addition to the effects produced by the gaming machine B2 or B3, the urging means is provided with a rotating operation unit that is connected to the screwing member and protrudes to the front side of the gaming machine body. By using the portion, there is an effect that the screwing member can be easily rotated, that is, the urging force can be easily changed. In particular, since the rotation operation unit protrudes from the front side of the gaming machine main body, the player can arbitrarily change the biasing force suitable for the player according to the situation while performing the game. There is an effect that can be done.

  In the gaming machine B2 or B3, the biasing means includes a rotation operation unit that is connected to the screwing member and is disposed inside the gaming machine main body and rotates the screwing member. Machine B5.

  According to the gaming machine B5, in addition to the effects produced by the gaming machine B2 or B3, the urging means is provided with a rotating operation unit that is connected to the screwing member and disposed inside the gaming machine body. By using the portion, there is an effect that the screwing member can be moved, that is, the urging force can be easily changed even in a narrow space inside the gaming machine main body. In addition, by arranging the rotation operation part inside the gaming machine main body in this way, it is unnecessary to form an opening for exposing the rotation operation part on the front side of the gaming machine main body. This has the effect of making it difficult to carry out cheating.

  In the gaming machine B4 or B5, the screwing member includes a first gear formed concentrically with the male screw and the female screw, and the rotation operation unit meshes with the first gear of the screwing member. A game comprising two gears, wherein the screwing member is rotated by rotating the screwing member via the first gear as the second gear of the rotation operation unit rotates. Machine B6.

  According to the gaming machine B6, in addition to the effects produced by the gaming machine B4 or B5, the screwing member includes the first gear formed concentrically with the male screw and the female screw, and the first gear of the screwing member has teeth. Since the rotation operation unit includes the second gear to be engaged, the rotation is transmitted to the screwing member via the first gear by rotating the second gear by operating the rotation operation unit. Thereby, since the screwing member can be rotated, there is an effect that the operation of screwing the screwing member can be easily performed.

  The gaming machine B1 includes a case member disposed with the operation means and fixed to the gaming machine body, and the biasing means is formed to be slidable with respect to the case member and via the elastic member. A slide member connected to the operating means, a nut member disposed on the slide member and having an internal thread formed on the inner peripheral surface, and a male screw to be engaged with the female thread of the nut member. A bolt member rotatably supported by the case member, and the nut member is screwed with the rotation of the bolt member, and the slide member slides with respect to the case member, thereby operating with the slide member. The gaming machine B7 is characterized in that an elastic deformation amount of the elastic member is adjusted in a state in which an interval between the means and the operating means is not operated.

  According to the gaming machine B7, in addition to the effects produced by the gaming machine B1, the slide member is formed to be slidable with respect to the case member, and the screw of the bolt member is screwed onto the female screw of the nut member disposed on the slide member. Since the bolt member is rotated, the nut member is screwed along the bolt member, and the slide member can be slid along with the screwing. Therefore, it is possible to adjust the elastic deformation amount of the elastic member in a state where the operation means is not operated by changing the interval between the slide member and the operation means. Thereby, since the magnitude | size of the urging | biasing force provided to an operation means can be adjusted arbitrarily, an operation means can be operated with the operation feeling suitable for the player. Thus, in the gaming machine B7, since the rotational motion is converted into the linear motion, there is an effect that the structure for adjusting the elastic deformation amount of the elastic member can be reduced in size. Further, since the elastic deformation amount of the elastic member can be continuously adjusted, there is an effect that it is possible to reliably obtain an operational feeling suitable for the player. Furthermore, even if the bolt member is rotated once, the amount that the bolt member is screwed (that is, the amount that the slide member slides) is only one pitch of the male screw and the female screw, so that the elastic deformation amount of the elastic member can be finely adjusted. There is an effect that it can be easily performed. Further, the conversion of the rotational motion into the linear motion is performed by the bolt member and the nut member, and the slide member is not rotated, so that the elastic member can be prevented from being twisted. In addition, since the case member in which the operating means is disposed is fixed to the gaming machine main body, only the urging force can be changed without changing the operating position of the operating means. That is, even if the urging force is changed, the operation means can be operated at the same position, so that the operability can be ensured.

  In the gaming machine B7, a third regulating means for regulating the screwing of the nut member at a position where the distance between the slide member and the operating means is maximized, and the distance between the slide member and the operating means is minimized. A fourth restricting means for restricting the screwing of the nut member at a position where the elastic member is elastically deformed within a range from the maximum to the minimum between the slide member and the operating means. A gaming machine B8, wherein a preload is applied between a male screw and a female screw of the bolt member and the nut member by an elastic recovery force of the member.

  According to the gaming machine B8, in addition to the effect produced by the gaming machine B7, the elastic member is elastically deformed within a range where the distance between the slide member and the operating means is from the maximum to the minimum, so that the elastic recovery of the elastic member A preload can be applied between the external thread of the bolt member and the internal thread of the nut member by force. As a result, it is possible to suppress the occurrence of a gap between the male screw and the female screw, and to suppress the rattling of the slide member. Therefore, the effect that the operational feeling of the operating means can be improved accordingly. is there.

  In the gaming machine B7 or B8, the urging means includes a rotation operation unit that is coupled to the bolt member and protrudes to the front side of the gaming machine main body to rotate the bolt member. .

  According to the gaming machine B9, in addition to the effects produced by the gaming machine B7 or B8, the urging means is provided with a rotating operation unit that is connected to the bolt member and protrudes to the front side of the gaming machine body. By using this, there is an effect that the bolt member can be easily rotated, that is, the urging force can be easily changed. In particular, since the rotation operation unit protrudes from the front side of the gaming machine main body, the player can arbitrarily change the biasing force suitable for the player according to the situation while performing the game. There is an effect that can be done.

  In the gaming machine B7 or B8, the biasing means includes a rotation operation unit that is connected to the bolt member and is disposed inside the gaming machine main body and rotates the screwing member. B10.

  According to the gaming machine B10, in addition to the effects produced by the gaming machine B7 or B8, the urging means is provided with a rotating operation unit that is connected to the bolt member and disposed inside the gaming machine main body. By using, there is an effect that the bolt member can be easily rotated, that is, the urging force can be changed even in a narrow space inside the gaming machine main body. In addition, by arranging the rotation operation part inside the gaming machine main body in this way, it is unnecessary to form an opening for exposing the rotation operation part on the front side of the gaming machine main body. This has the effect of making it difficult to carry out cheating.

  An operation means configured to be operable, a biasing means for applying a biasing force in a direction opposite to the operation direction to the operation means, a detection means for detecting that the operation means has been operated to a predetermined position, A gaming machine comprising: a plurality of urging means, wherein a combination of urging means for applying an urging force to the operating means is selectable from the plurality of urging means. Game machine C1.

  According to the gaming machine C1, the urging force applied from the urging means can give the player a feeling of operation when operating the operation means, while the operation means can be returned to the initial position after the operation is completed. . In this case, the gaming machine C1 includes a plurality of urging means, and a combination of urging means for applying an urging force to the operating means is selectable from the plurality of urging means. There is an effect that the magnitude of the urging force applied to the operation means can be arbitrarily changed according to the combination of the urging means. Accordingly, there is an effect that the operation means can be operated with an operation feeling suitable for the player. The selection of the combination of the urging means means that one or more urging means are selected from the plurality of urging means.

  The gaming machine C1 includes a transmission unit that is disposed between the plurality of biasing units and the operation unit and transmits a biasing force from the biasing unit to the operation unit. A combination of urging means for applying a urging force to the operation means is changed according to a relative movement position of the transmission means with respect to the plurality of urging means. A gaming machine C2.

  According to the gaming machine C2, in addition to the effects achieved by the gaming machine C1, the gaming machine C2 includes a transmission unit that is disposed between the plurality of biasing units and the operation unit and transmits the biasing force from the biasing unit to the operation unit. When the means is operated, the urging force of the urging means is applied to the operation means via the transmission means, so that the player can be given an operational feeling. In this case, the transmission means is formed to be movable, and the combination of the urging means for applying the urging force to the operation means is changed according to the movement position of the transmission means. There is an effect that the magnitude of the urging force applied to the operation means can be easily changed.

  In the gaming machine C2, the plurality of urging means include a cylindrical member that is formed in a cylindrical shape and has at least one protrusion or recess protruding or recessed on an end surface facing the transmission means, and the cylinder Each of the cylindrical members of the plurality of urging means has a different diametrical dimension and a smaller diametrical dimension has a larger diametrical dimension. A plurality of recesses that receive the protrusions or a plurality of protrusions that are received in the recesses face each end face of the plurality of cylindrical members. Each of which is recessed or protruded on the surface, and is formed to be relatively rotatable and concentric with the cylindrical member and to be close to the end surface of the cylindrical member as the operating means is operated. The transmission with the operation When the step is brought close to the end surface of the cylindrical member, the urging force is not transmitted to the transmitting means from the cylindrical member in which the protruding portion is received in the recessed portion, while the protruding portion is received in the recessed portion. From the non-cylindrical member, the projection is brought into contact with the end face or the opposing surface, the cylindrical member is displaced together with the transmitting means, and the corresponding elastic member is elastically deformed, whereby the transmitting means is changed. The urging force is transmitted to the operating means via the transmission means, and the number of protrusions received in the recess is changed according to the relative rotational position of the transmitting means with respect to the plurality of cylindrical members, and is applied to the operating means. A gaming machine C3 in which the magnitude of the power is changed.

  According to the gaming machine C3, in addition to the effects produced by the gaming machine C2, a protrusion or a recess is formed on each end surface of the plurality of cylindrical members, and a recess or a protrusion is formed on the opposing surface of the transmission means. When the transmission means is brought closer to the end surface of the cylindrical member as a result of the above operation, the urging force is not transmitted to the transmission means from the cylindrical member in which the protrusion is received in the recess, whereas the protrusion is received in the recess. From the non-cylindrical member, the projecting portion comes into contact with the end surface or the opposite surface, the cylindrical member is displaced together with the transmission means, and the corresponding elastic member is elastically deformed, so that the urging force is applied to the operation means via the transmission means. Therefore, the magnitude of the urging force applied to the operating means according to the number of cylindrical members (that is, the number of elastic members to be elastically deformed) that are received in the recesses and displaced together with the transmitting means is determined. The result can be changed arbitrarily There is an effect that it is possible to operate the operation means in the operation feeling suitable for a player.

  Further, in this case, the transmission means is formed to be rotatable, and the number of protrusions received in the concave portion is changed according to the rotation position of the transmission means. There is an effect that the magnitude of the applied urging force can be easily changed.

  Furthermore, since the plurality of cylindrical members are formed in cylindrical shapes having different diameters, and are inserted in order in a nested manner toward the inner peripheral side, it is possible to reduce the size of the entire biasing means. is there. Thereby, even when the arrangement space of the urging means is limited, the number of arrangement of the cylindrical members can be secured, so the number of types of combinations of urging forces that can be selected can be increased, and the player can There is an effect that a suitable operation feeling can be easily obtained.

  In the gaming machine C3, at least one of the plurality of cylindrical members is disposed between an end surface of the plurality of cylindrical members opposite to the end surface facing the transmission unit and the detection unit. A gaming machine C4 comprising a displacement member that is displaced by displacement of the cylindrical member, and the displacement of the displacement member is detected by the detection means.

  According to the gaming machine C4, in addition to the effects produced by the gaming machine C3, the gaming machine C4 is disposed between the plurality of cylindrical members and the detecting means, and is displaced by any one of the plurality of cylindrical members. Since the displacement member to be displaced is provided, there is an effect that the required number of detection means can be reduced and the product cost can be reduced. In other words, since the cylindrical member that is displaced when the operating unit is operated changes in accordance with the rotational position of the transmission unit, in the configuration in which the detecting unit detects the displacement of the cylindrical member, the number of cylindrical members is detected. Means are needed. On the other hand, in the gaming machine C4, when at least one of the plurality of cylindrical members is displaced, the displacement member is displaced, and by detecting the displacement of the displacement member, Since the operation can be detected, the required number of detection means can be set to 1.

  Further, in this way, by disposing the displacement member on the end surface side opposite to the end surface facing the transmission means of the cylindrical member, the detection means can be disposed at a position separated from the operation member. Therefore, there is an effect that it is possible to make it difficult to perform an illegal act against the detection means.

  The gaming machine C4 includes a case member in which the plurality of cylindrical members and the detection unit are accommodated and fixed to the gaming machine main body, and the displacement member is disposed between the plurality of cylindrical members and the detection unit. A gaming machine C5, which is covered in an internal space of the case member.

  According to the gaming machine C5, in addition to the effects produced by the gaming machine C4, the displacement member is covered in the internal space of the case member between the plurality of cylindrical members and the detection means, and thus the detection means is shielded. There is an effect that can be. As a result, even when an opening or a gap is formed on the operating means side with respect to the displacement member, it is possible to prevent foreign objects from being inserted into the detecting means side and make it difficult to perform illegal acts on the detecting means. There is an effect that can be done.

  In any one of the gaming machines C3 to C5, the plurality of cylindrical members and the detection means are housed and a case member that is fixed to the gaming machine main body is provided, and the plurality of cylindrical members cannot rotate with respect to the case member The gaming machine C6 is supported by the case member so as to be movable in the axial direction, and is supported by the case member so as to be rotatable and movable in the axial direction.

  According to the gaming machine C6, in addition to the effects produced by any of the gaming machines C3 to C5, the plurality of cylindrical members are supported by the case member so as not to be rotatable and movable in the axial direction, and the transmission means is supported by the case member. Since it is supported so as to be rotatable and movable in the axial direction, it is possible to simplify the structure that enables the relative rotational movement of the transmission means with respect to the plurality of cylindrical members while allowing the relative rotational movement. is there.

  In any one of the gaming machines C3 to C6, the transmission means corresponding to a protrusion projecting from each end surface of the plurality of cylindrical members or an end surface of one of the plurality of cylindrical members. The gaming machine C7 is characterized in that at least one or more projecting portions projecting from the opposing surface are disposed on one side and the other side across the axis.

  According to the gaming machine C7, in addition to the effects produced by any of the gaming machines C3 to C6, a protrusion projecting from each end face of the plurality of cylindrical members or one cylindrical member of the plurality of cylindrical members At least one or more protrusions provided on the opposite surface of the transmission means corresponding to the end face are disposed on one side and the other side across the axis, so that the protrusions of the cylindrical member When the cylindrical member is abutted against the end surface or the opposing surface of the transmission means and the cylindrical member is displaced together with the transmission means, there is an effect that the transmission means and the cylindrical member can be smoothly displaced.

  In any one of the gaming machines C3 to C7, the game machine includes a case member fixed to the gaming machine main body and a rotation operation unit rotatably supported by the case member, and the transmission means is concentric with the transmission means. The rotation operation unit includes a fourth gear meshing with the third gear of the transmission means, and the rotation operation unit is rotated and operated via the fourth gear. The game machine C8 is characterized in that the rotation is transmitted to the third gear and the transmission means is rotated.

  According to the gaming machine C8, in addition to the effects produced by any of the gaming machines C3 to C7, the transmission means includes the third gear, and the rotation operation unit includes the fourth gear meshing with the third gear. By rotating the rotation operation unit, the rotation can be transmitted to the third gear via the fourth gear, and the transmission means can be rotated. Therefore, there is an effect that the rotational movement of the transmission means can be easily performed by using the rotation operation unit.

  In any one of the gaming machines C3 to C8, the plurality of elastic members have the same spring characteristics, respectively.

  According to the gaming machine C9, since each of the plurality of elastic members has the same spring characteristics, there is no need to prepare a plurality of types of elastic members, and the part cost can be reduced correspondingly. .

  In any one of the gaming machines C3 to C8, the gaming machine C10 is characterized in that at least some of the plurality of elastic members have spring characteristics different from those of the other elastic members.

  According to the gaming machine C10, since at least some of the plurality of elastic members have different spring characteristics from the other elastic members, the plurality of elastic members are combined to give to the operation member. There is an effect that the urging force to be adjusted can be finely adjusted.

  One of the gaming machines A1 to A10, B1 to B10, or C1 to C10, wherein the gaming machine is a slot machine. Above all, the basic configuration of the slot machine is “equipped with variable display means for confirming and displaying the identification information after dynamically displaying an identification information string composed of a plurality of identification information, and for operating the starting operation means (for example, an operation lever). As a result, 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. The game machine is provided with special game state generating means for generating a special game state advantageous to the player on the condition that the confirmed identification information is specific identification information. In this case, examples of the game media include coins and medals.

  One of the gaming machines A1 to A10, B1 to B10, or C1 to C10, wherein the gaming machine is a pachinko gaming machine. Above all, the basic configuration of a pachinko gaming machine is provided with an operation handle, and a ball is launched into a predetermined game area according to the operation of the operation handle, and the ball is placed in an operation port disposed at a predetermined position in the game area. As a necessary condition for winning a prize (or passing through the operating port), the identification information dynamically displayed on the display device is confirmed and stopped after a predetermined time. In addition, when a special gaming state occurs, a variable winning device (specific winning opening) disposed at a predetermined position in the gaming area is opened in a predetermined manner so that a ball can be won, and a value corresponding to the number of winnings is obtained. Examples include those to which values (including data written on magnetic cards as well as premium balls) are given.

  One of the gaming machines A1 to A10, B1 to B10, or C1 to C10, the gaming machine is a combination of a pachinko gaming machine and a slot machine. Among them, the basic configuration of the merged gaming machine includes “a variable display means for confirming and displaying the identification information after dynamically displaying an identification information string composed of a plurality of identification information, and a starting operation means (for example, an operation lever). Due to the operation of the identification information, the change of the identification information is started, and the dynamic display of the identification information is stopped due to the operation of the operation means for stop (for example, the stop button) or when a predetermined time elapses. Special game state generating means for generating a special game state advantageous to the player on the condition that the fixed identification information at the time of stoppage is specific identification information, and using a ball as a game medium, and the identification information The game machine is configured such that a predetermined number of balls are required at the start of the dynamic display, and a large number of balls are paid out when the special gaming state occurs.

10 Slot machines (gaming machines)
11 Housing (part of the gaming machine body)
12 Front door (part of the gaming machine itself)
71 Start lever (operating means)
200, 2200, 3200 Front outer frame (first member)
203, 2203 Guide passage 203a, 2203a Engaging recess (recess)
400 Inner frame (second member)
6400 Inner frame (sliding member)
6403 Projection (nut member)
401 Front plate (covering plate)
405, 2405 Adjustment lever (switching operation unit)
4405 5405 Adjusting rotor (rotation operation unit)
4405b Gear (second gear)
6405 Adjusting rotor (bolt member, rotation operation unit)
7405 Adjusting rotor (4th gear)
4250 First intermediate outer frame (part of case member)
4350 Second intermediate outer frame (part of case member)
4252a 1st regulation part (1st regulation means or 3rd regulation means)
4352a Second restriction surface (second restriction means or fourth restriction means)
4400 Inner frame (screwing member)
4402 Peripheral gear (first gear)
7500 Rotating plate (Transmission means)
7503 Gear cylinder (third gear)
7504a First protrusion pin (protrusion)
7504b Second protrusion pin (protrusion)
7504c Third protrusion pin (protrusion)
7504d 4th projecting pin (projecting part)
7510 Inner spring pusher (tubular member)
7520 Medium spring pusher (tubular member)
7250 Intermediate outer frame (case member)
7530 Outer spring pusher (tubular member)
7512-7532 Relief hole (concave)
7550 Slider (displacement member)
600 Elastic member 7601 Inner spring member (elastic member)
7602 Medium spring member (elastic member)
7603 Outer spring member (elastic member)
7610 Return spring (elastic member)
800 sensor (detection means)
O axis (rotating shaft)

Claims (4)

An operation means configured to be operable, a biasing means for applying a biasing force in a direction opposite to the operation direction to the operation means, a detection means for detecting that the operation means has been operated to a predetermined position, In a gaming machine equipped with
A plurality of the urging means having different urging forces are provided, and the urging means for applying the urging force to the operation means can be switched from among the plurality of urging means. Gaming machine. A first member provided with the operating means and fixed to the gaming machine body;
A second member formed so as to be movable with respect to the first member and provided with the plurality of biasing means,
When the second member is moved with respect to the first member, any one of the plurality of urging means is arranged at a position where the urging force can be applied to the operation means. The gaming machine according to claim 1. The second member is formed to be rotatable around a rotation axis,
The plurality of biasing means are distributed around the rotating shaft,
When the second member is rotated about the rotation axis, one of the plurality of urging means is sequentially arranged at a position where the urging force can be applied to the previous operating means. The gaming machine according to claim 2.   4. The gaming machine according to claim 2, further comprising a switching operation unit that is fixed to the second member and protrudes to a front side of the gaming machine main body.

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