JP2012157562A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine including a hopper device capable of surely sending out tokens.SOLUTION: A hopper device 1 includes: a token storage part 20; a rotary plate 30 provided with a token holding part for receiving and holding tokens stored in the token storage part 20; and a drive motor 50 for rotating the rotary plate 30. The rotary plate 30 has, as the token holding part, a token hole 31 into which the tokens piled up in a horizontal state can be fitted from above. On a surface of the rotary plate 30, a projection 37 in a circular arcuate shape in a view from the upper surface is formed on a rotating direction rear side along the edge of the token hole 31.

Description

  The present invention relates to a gaming machine having a built-in hopper device for paying out medals using a rotating plate.

In a gaming machine such as a slot machine, a hopper device for paying out medals is provided inside the housing, and the inserted medals are stored in the hopper device, and the stored medals are paid out when winning a prize. ing. As a hopper device, there is known a hopper device in which a rotating plate having a plurality of medal holes into which medals can be inserted is rotated by a drive motor so that medals fitted in the medal holes are sent out one by one.
The performance required for the hopper device of such a gaming machine includes a reduction in the size of the drive motor for rotating the rotating plate, an increase in the capacity of the medal storage unit, and occurrence of a difficult movement state of the medal in the storage unit (so-called bridge) There are various measures such as prevention and reliable medal delivery by a rotating plate. Here, when the number of medals is reduced in the storage unit, there is a problem that medals are difficult to enter in the medal hole and the medals are not paid out smoothly.

  As a method for solving the above-mentioned problem, for example, in Patent Document 1, the hopper device temporarily stops the rotation of the rotating plate while the hopper device is paying out, thereby storing the medals bounced on the rotating plate in the medal storage unit. It is disclosed to do so.

JP 2007-29455 A

  SUMMARY OF THE INVENTION An object of the present invention is to provide a gaming machine equipped with a hopper device capable of reliably delivering medals by paying attention to the shape of the rotating plate in order to meet the demand for reliable medal discharge at the rotating plate.

In order to solve the above problems, the invention described in each claim has the following configuration.
In addition, the code | symbol in parenthesis shows the code | symbol used in embodiment of invention, and does not limit the technical scope of this invention.
The invention described in claim 1 is a reel device (6) having a plurality of rotating reels (6A), a start switch (5C) for rotating the rotating reel (6A), and the rotating reel ( 6A) A stop switch (5D) for individually stopping, a hopper device (1) for storing and paying out medals, and a role lottery for determining whether or not a winning combination is a combination of a plurality of symbols, A control device (7) for controlling the operation of the reel device (1) and the hopper device (1), and a stop pattern of the rotating reel (6A) stopped by the operation of the stop switch (5D) The present invention relates to a gaming machine (slot machine S) that pays out a number of medals according to a prize from the hopper device (1) when a predetermined winning mode is achieved.

The gaming machine according to the present invention is a slot machine (S) or a similar gaming machine.
In the present invention, the hopper device (1) includes a medal storage unit (20) and a rotating plate including a medal holding unit that receives and holds medals stored in the medal storage unit (20) ( 30) and a drive motor (hopper motor 50) for rotating the rotating plate (30), and the rotating plate (30) is used as the medal holding portion to insert the medals that overlap in a horizontal state from above. A top view circle having a possible medal hole (31) and formed on the surface of the rotating plate (32) at the rear in the rotational direction along the edge of the medal hole (31) and inclined downward toward the rear in the rotational direction. An arc-shaped protrusion (convex portion 37) is provided.

The storage section (20) is a tank for storing medals, and has a passage plate (22) protruding in a bowl shape so as not to form a bridge even when a large amount of medals are stored. Also good.
The rotating plate (30) is disposed at the bottom of the medal reservoir (20), and includes a plurality of medal holes (31), and when the rotating plate (30) rotates in a predetermined direction, the medal hole (31 ) Is discharged from the predetermined discharge portion to the outside of the hopper device (1). A plurality of medals can be stacked and stored in the medal hole (31), and as the rotating plate (30) rotates, the medal located at the bottom of the medal hole (31) moves to the vicinity of the discharge part. When it comes, for example, it strikes a stopper (pin) protruding from the support plate (11) that supports the rotating plate (30), changes its direction, and is pushed out to the discharge portion. In addition to the medal hole (31), the “medal holding part” includes a protrusion (34) for pushing out a medal provided on the bottom or side of the rotating plate (30).

The rotating plate (30) is not limited to a disk-shaped one, and may be formed in a conical shape that is inclined downward from the center of rotation toward the circumference.
The drive motor (50) only needs to be able to rotate the rotating plate (30) by driving, and directly rotates the rotating plate (30) by fixing the motor shaft (51) to the rotation center of the rotating plate (30). The gear (motor gear 52) fixed to the motor shaft (51) is meshed with the gear provided on the outer periphery of the rotary plate (30), and the rotary plate (30) is indirectly coupled. It may be rotated.
The protrusion (37) provided on the upper surface of the rotating plate (30) is formed in a circular arc shape when viewed from above, along the edge of the medal hole (31), and extends from the highest portion to the rear side in the rotational direction. Are formed so as to be gradually inclined downward. The protrusion (37) may further be formed so as to be inclined downward from the outer peripheral direction of the rotating plate (30) toward the center.

According to the present invention, by providing the protrusion (37) on the rear side in the rotational direction of the medal hole (31), the medal accumulated near the upper surface of the rotating plate (30) is agitated by the rotation of the rotating plate (30). , Bridge can be prevented, and as a result, medals can be sent out reliably. Even when the amount of stored medals is small, the medal is guided to the medal hole (31) by the downward inclination of the protrusion (37), and the medal can be reliably delivered.
The protrusion (37) may be provided over the circumferential portion of the surface of the rotating plate (30). Further, a recess (38) may be provided on the surface of the rotating plate (30) in addition to the protrusion (37). Further, at least one of the plurality of medal holes (31) is formed to have a large diameter so that even when the amount of stored medals is small, at least the large-diameter medal hole (31 ′) can pick up medals. Good.

  Since the present invention is configured as described above, it is possible to provide a gaming machine provided with a hopper device that can reliably send out medals even when the amount of medals in the medal storage unit decreases.

FIG. 3 is an external front view of the slot machine according to the embodiment of the present invention. It is the front view which opened the front door of the slot machine. It is a perspective view of a hopper apparatus. It is a disassembled perspective view of a hopper apparatus. It is a top view of the main-body part of a hopper apparatus. It is a first embodiment of the present invention and is a view showing a rotating plate. It is a modification of 1st embodiment, Comprising: It is a figure which shows a rotating plate. It is another modification of 1st embodiment, Comprising: It is a figure which shows a rotating plate. It is another modification of 1st embodiment, Comprising: It is a figure which shows a rotating plate. It is 2nd embodiment of this invention, Comprising: It is a longitudinal cross-sectional view of a hopper apparatus. It is 3rd embodiment of this invention, Comprising: It is a longitudinal cross-sectional view of a hopper apparatus. It is a modification of 3rd embodiment, Comprising: It is the longitudinal cross-sectional view of a hopper apparatus, and the perspective view of a rotating plate. FIG. 6 is a longitudinal sectional view of a hopper device according to a fourth embodiment of the present invention. It is another example of 4th embodiment, Comprising: It is the fragmentary top view of a main-body part, and the longitudinal cross-sectional view of a hopper apparatus. It is a modification of 4th Embodiment, Comprising: It is the longitudinal cross-sectional view and partial top view of a hopper apparatus. FIG. 10 is a longitudinal sectional view of a hopper device according to a fifth embodiment of the present invention.

A preferred embodiment of the present invention will be described with reference to the drawings, taking a slot machine as an example of a medal gaming machine.
(Slot Machine S)
As shown in FIG. 1, the slot machine S has a plate-like front door 3 attached to the front side of a box-shaped housing 2 so as to be freely opened and closed. As shown in FIG. A reel device 6 as a symbol display device having a reel motor 6B (see FIG. 3) and three rotating reels 6A on which a plurality of symbols (not shown) are displayed, and storing and paying out medals. The hopper device 1 for taking out, the control device 7 for controlling the operation of the slot machine S, and the power supply device 8 are housed and fixed.

  The front door 3 is attached through a hinge (not shown) so that the front opening of the housing 2 can be opened and closed. As shown in FIG. 1, the central portion in the height direction is used for the operation of the slot machine S. The operation unit 5 is provided with related operation switches and the like. A front panel 3A having a symbol display window 60 through which the symbol of the rotary reel 6A can be viewed from the front side is provided above the operation unit 5, and a character corresponding to the model of the slot machine S is provided below the operation unit 5. Each of the lower panels 3C is displayed. An upper panel 3B is provided above the front panel 3A, and a medal payout port 3E for discharging medals paid out from the hopper device 1 is provided below the lower panel 3C and below the front door 3. Thus, a lower plate 3D capable of storing medals discharged from the medal payout opening 3E is formed.

Further, the front door 3 is provided with an effect display device 9 for causing various effects accompanying the game. The effect display device 9 includes a lamp 9A disposed around the upper panel 3B, an image display unit 9B provided on the upper panel 3B, and a speaker 9C provided on the back wall of the lower plate 3C. The image display unit 9B displays a character / graphic moving picture or the like using a liquid crystal display device or a dot matrix.
The operation unit 5 includes a medal slot 5A for inserting medals, a bet switch 5B for replacing medals stored as credits with inserted medals, and a lever-shaped start for starting rotation of the rotating reel 6A. A switch 5C, a stop switch 5D composed of three button switches for individually stopping the rotation of the rotary reel 6A, and a settlement switch 5E for paying back the credited medal are provided.

As shown in FIG. 2, a medal selector 4 for detecting a medal inserted from the medal insertion slot 5A is built in the back side of the front door 3, and a medal canceled by the medal selector 4 is displayed. A medal passage 3F for guiding to the lower plate 3D is provided.
The control device 7 includes a control board on which various electronic components such as an IC are mounted, and a board case for housing the control board. As the control board, although not shown in particular, a main board and a sub board are provided.
The main board is provided with various electronic components such as a CPU, a ROM, a RAM, and an I / O, and functions as various control units when the CPU reads a program stored in the ROM. Specifically, the main board constitutes a main control device 7A (see FIG. 2) for controlling the operations of the reel device 6 and the hopper device 1 while performing the lottery. A medal insertion control unit for controlling the game, a role lottery control unit for performing a role lottery for determining whether or not the “comb” consisting of a combination of symbols is won, a reel control unit for controlling the reel device 6, a winning prize It functions as a winning determination control unit for determining presence / absence, a game state control unit for controlling a game state such as a bonus game, and a hopper control unit for controlling the operation of the hopper device 1.

Although not particularly shown, the sub board is also equipped with electronic components such as a CPU, ROM, and RAM, and, like the main board, the CPU reads various programs stored in the ROM and functions as various control units. To do. Specifically, the sub board constitutes a sub control device 7B (see FIG. 2) for inputting a signal from the main board and controlling the operation of the effect display device 9, and although not particularly shown, the effect display device 9 It functions as an effect control unit for controlling an effect using.
(Outline of operation of slot machine S)
The slot machine S having the above-described configuration is capable of placing (betting) a maximum of three medals in one game and storing up to 50 medals inserted from the medal slot 5A as credits. Has been. When a medal is credited, the numerical value is displayed on a predetermined credit display unit, and every time the bet switch 5B is operated, a predetermined number of 1 to 3 is subtracted from the display of the credit display unit. The medal is considered to be bet.

Then, based on the operation of the start switch 5C, a winning lottery is performed and the rotating reel 6A starts rotating. By operating the corresponding stop switch 5D while the rotating reel 6A is rotating, the rotating reel 6A stops rotating. Then, when all the three rotating reels 6A are stopped, if the symbols constituting the winning combination of each rotating reel 6A are displayed in an arrangement corresponding to the winning combination, the number of the number corresponding to the winning combination from the hopper device 1 It is formed so that medals can be paid out or shifted to advantageous games such as bonus games.
(Hopper device 1)
Next, the hopper device 1 will be described based on the drawings, divided into first to fifth embodiments. Here, the outline of the hopper apparatus 1 common to each embodiment will be described first, and then the details of each embodiment will be described. Portions that are not particularly mentioned in the description of each embodiment are the same as the outline of the hopper device 1.

(Common explanation)
As shown in FIG. 2, the hopper device 1 includes a main body 10 including a rotating plate 30 for sending out medals and a hopper motor 50, and a medal storage 20 provided above the main body 10. . Further, a medal discharge port 17 for discharging medals sent out by the rotary plate 30 is formed in the front portion of the hopper device 1. Then, the hopper motor 50 is driven to rotate the rotating plate 30 in the white arrow direction (forward rotation direction) shown in FIG. It is configured to be discharged one by one. Note that the rotation direction of the hopper motor 50 or the rotation plate 30 in which medals are discharged by the rotation of the rotation plate 30 is referred to as a normal rotation direction.

As shown in FIG. 4, the main body 10 is a box having an upper surface inclined. A substantially circular rotating recess 12 is formed in the support plate 11 constituting the upper surface of the main body 10, and a rotating plate 30 having a plurality of medal holes 31 is disposed in the rotating recess 12. A hopper motor 50 (see FIG. 2) for rotating the rotating plate 30 is fixed to the lower surface of the support plate 11, and a motor shaft 51 interlocking with the drive shaft of the hopper motor 50 protrudes from the support plate 11 and rotates. It is located at the center of the recess 12. The rotating plate 30 is fixed to the motor shaft 51 and is rotatable in the horizontal direction inside the rotating recess 12.
As shown in FIGS. 4 and 5, the rotating recess 12 is formed with a notch 15 in which a part of the peripheral wall 14 forming the rotating recess 12 is notched. A concave bottom surface 13 of the rotary concave portion 12 and a medal discharge port 17 in front of the main body portion 10 communicate with each other. A medal discharge mechanism 40 is provided between the notch 15 and the medal discharge port 17.

  The medal discharge mechanism 40 includes a discharge recess 41 that allows the cutout portion 15 and the medal discharge port 17 to communicate with each other, and a fixed pin 42 and a movable pin 43 provided in the discharge recess 41. The fixing pin 42 is a columnar protrusion provided at the end of the notch 15. The movable pin 43 is a columnar protrusion that protrudes from a long hole formed in the discharge recess 41, and is disposed at a position that maintains a gap smaller than the diameter of the medal M between the fixed pin 42. The movable pin 43 is always urged by a spring (not shown) so as to be in the above-described position, and along the elongated hole to a position where the distance from the fixed pin 42 is slightly larger than the diameter of the medal. You can move. That is, the medal is formed so as to pass between the fixed pin 42 and the movable pin 43 in a horizontal state. A payout sensor that detects the passage of a medal by detecting the movement of a detection piece (not shown) fixed below the movable pin 43 inside the main body 10 and in the vicinity of the discharge recess 41. 80 is provided. A payout guide 16 is attached to the discharge recess 41, and a gap between the payout guide 16 and the discharge recess 41 serves as the medal discharge port 17.

As shown in FIGS. 4 and 5, the rotating plate 30 has eight medal holes 31 having an inner diameter slightly larger than the medal diameter, and an inclined portion 35 is formed around the medal hole 31. A ridge 36 is formed between adjacent medal holes 31. The number of medal holes 31 in the rotating plate 30 of the hopper device 1 in the present invention is not limited to eight. The inclined portion 35 is for smoothly guiding medals stored above the rotating plate 30 to the medal hole 31, and the ridge portion 36 is stored above the rotating plate 30 while the rotating plate 30 is rotating. It is for stirring the medals.
Further, on the back surface of the rotating plate 30, a bottom medal transport unit 32 is formed as a medal holding unit that holds the medal M fitted in the medal hole 31 and discharges it to the side of the rotating plate 30. The bottom medal transport section 32 is a bottom-view gear-shaped convex surface formed on the back surface of the rotating plate 30. As shown in FIG. It has a medal insertion groove 33 that is open on the side, and a protrusion 34 that is formed by curving an opening portion of the medal insertion groove 33 in a direction reverse to the plan view. The height (thickness) of the bottom medal transport unit 32 is formed to be slightly larger than the thickness of one medal.

  As shown in FIGS. 3 and 4, the medal storage part 20 is a box having a storage part 21 that opens upward, and an overflow opening 22 is formed in a side part. The overflow opening 22 is for discharging medals stored in the storage unit 21 to a predetermined amount or more from the storage unit 21 through the overflow guide 23. The overflowed medal is on the side of the hopper device 1 in the housing 2. Is transferred to a sub-tank 90 (see FIG. 2) installed adjacent thereto. An opening 24 (see FIG. 4) whose center coincides with the rotary plate 30 when the medal storage unit 20 is mounted on the main body 10 is formed at the bottom of the medal storage unit 20 and is inserted into the storage unit 21. The medal is stored above the rotating plate 30 through the opening 24. The medals stored in the storage unit 21 are fitted into the medal holes 31 of the rotating plate 30, and a plurality of medals are stacked and stored in the medal hole 31 in the horizontal direction.

Of the medals fitted in the medal hole 31 of the rotating plate 30, the medal at the bottom is held in the medal insertion groove 33 when the medal hole 31 is positioned on the upper side of the rotating plate 30. It fits inside the hole 31. On the other hand, when the medal hole 31 is located on the lower side of the rotating plate 30, it falls out of the medal insertion groove 33 (or, when the rotating plate 30 is rotating, it jumps out of the medal insertion groove 33 by centrifugal force). Thus, the medal hole 31 comes off and comes into contact with the peripheral wall 14 of the rotary recess 12.
When the hopper motor 50 is driven to rotate in the forward direction and the rotating plate 30 is rotated in the forward direction, the medal that protrudes from the medal hole 31 and contacts the peripheral wall 14 below the rotating recess 12 It is pushed by the outer curved portion 34b of the 32 projections 34 and rolls in the rotational direction along the peripheral wall 14. As shown by the solid line in FIG. 5, the medal that has rolled to the vicinity of the discharge recess 41 is in contact with the fixed pin 42 and the movable pin 42 and is prevented from moving in the rotational direction. Since it is further pressed by the outer curved portion 34b of the protrusion 34 as it rotates, the movable pin 43 is pressed to widen the gap between the fixed pin 42 and the movable pin 43, as shown by the two-dot chain line in FIG. . That is, the outer curved portion 34b and the movable pin 43 play a role of changing the course of the medal. When the diameter portion of the medal passes between the fixed pin 42 and the movable pin 43, the movable pin 43 returns to the original position by the biasing force, so that the medal is flipped away in the direction of the medal discharge port 17. Note that the medals stacked above fall into the medal hole 31 from which the medals have been discharged, and move together with the rotating plate 30 while being held in the medal insertion groove 33.

  On the other hand, when the hopper motor 50 is driven to rotate in the reverse direction and the rotating plate 30 is rotated in the direction opposite to the normal direction (reverse direction), it protrudes from the medal hole 31 below the rotating recess 12 and comes into contact with the peripheral wall 14. The medal is pushed by the inner curved portion 34a of the projection 34, rolls in the rotational direction along the peripheral wall 14, and is scooped up by the inner curved portion 34a as the medal hole 31 moves upward in the inclination. Is stored in the medal hole 31. The medal carried to the vicinity of the discharge recess 41 spills from the medal insertion groove 33 along the outer curved portion 34b, but the movement in the rotation direction is not prevented by the fixed pin 42 and the movable pin 43, and the path Is not changed, it continues to move in the rotational direction along the peripheral wall 14 while being located between the outer curved portion 34b and the inner curved portion 34a. As described above, the hopper device 1 does not pay out medals when the hopper motor 50 is operated in reverse.

(First embodiment)
Next, features of the first embodiment will be described. 6 to 9 are diagrams showing the first embodiment. The first embodiment aims to ensure that medals can be sent out even when the amount of stored medals decreases, and the shape of the medal hole 31 of the rotating plate 30 and the incidental shape of the rotating plate 30 The improvement is aimed at.
As shown in FIG. 6, the rotating plate 30 of the hopper device 1 according to the first embodiment is provided with a specially shaped convex portion 37 in the vicinity of the medal hole 31. In the illustrated example, four medal holes 31 are provided, but the number of medal holes 31 is not limited to four. As shown in FIG. 6 (A), the convex portion 37 is formed in a substantially sector shape in plan view. As shown in FIG. 6 (B), the convex portion 37 extends from the outer periphery 37B located on the circumferential side of the rotary plate 30 to the rotary plate 30. It is formed so as to be gradually inclined downward toward the center side. Further, as shown in FIG. 6C, which is a sectional view taken along the line CC of FIG. 6A, the medal hole 31 is in contact with the edge on the rear side in the forward rotation direction (white arrow direction) of the rotating plate 30. The height of the arcuate radiation side 37B when viewed from above is high, and is formed so as to be gradually inclined downward toward the rear side in the rotation direction. By providing such a convex portion 37, at the time of rotation of the rotating plate 30, the radial side 37B agitates the medals near the upper surface of the rotating plate 30, and by the downward inclination from the radial side 37B toward the rear side in the rotation direction, The medal can be smoothly guided to the medal hole 31.

  Further, as an incidental shape around the medal hole 31, a recess 38 as shown in FIG. 7 may be provided. As shown in FIG. 7A, the concave portion 38 is formed in an oval shape in a plan view on the rotational direction side of the medal hole 31, and is a cross-sectional view taken along the line BB in FIG. As shown, it is formed so as to incline downward toward the direction of centrifugal force (black arrow direction). By providing such a recess 38, a medal near the upper surface of the rotating plate 30 can be skimmed and the medal can be smoothly guided to the medal hole 31 by the downward inclination. In addition, since the concave portion 38 that extends in the rotation direction side of the medal hole 31 is provided, the medal that has been scooped into the concave portion 38 but did not fit into the dull hole 31 is the edge of the medal hole 31 opposite to the concave portion 38. This also causes the effect of stirring the medals in the vicinity of the upper surface of the rotating plate 30.

Furthermore, as the convex portion 37, a plurality of small protrusions may be provided along the circumferential portion of the rotating plate 30 as shown in FIG. 6 and 7 may also be provided with a convex portion 37 as shown in FIG. If it forms in this way, the stirring effect of a medal will improve further.
As described above, according to the first embodiment, the medals above the rotating plate 30 are agitated by the convex portion 37 or the concave portion 38, and the rotating plate 30 can easily pick up the medal through the medal hole 31 as a whole. . Therefore, not only can the medal be guided to the medal hole 31 even if the number of stored medals decreases, but even if the capacity of the medal storage unit 20 is increased, the stored medals are consolidated in a continuous state. As a result, it is possible to suppress the occurrence of so-called bridges, and as a result, there is also an accompanying effect of reducing the burden on the hopper motor 50.

(Modification)
In the embodiment described above, all the medal holes 31 are easy to pick up medals, but at least the specific medal hole 31 may be formed so as to easily pick up medals. For example, as shown in FIG. 9, a large diameter medal hole 31 ′ having a diameter larger than that of other medal holes 31 can be provided. Of course, the diameter of all the medal holes 31 may be increased, but in that case, the diameter of the rotating plate 30 also needs to be increased. Accordingly, at least one large-diameter medal hole 31 ′ is provided in order to keep the size of the rotating plate 30 unchanged (in other words, without changing the performance of the hopper motor 50). If formed in this way, at least the large diameter medal hole 31 ′ can easily enter medals. For example, when the number of stored medals decreases, at least the large diameter medal can be acquired even if the other medal holes 31 cannot pick up the medal. You can pick up medals at hole 31 '.

(Second embodiment)
FIG. 10 is a diagram showing a second embodiment. Similar to the first embodiment, the second embodiment aims to ensure that medals can be sent out even when the amount of stored medals decreases, and the overall shape of the rotating plate 30 The improvement is aimed at.
As shown in FIG. 10, the main body 10 of the hopper device 1 according to the second embodiment has a rotating recess 12 of the support plate 11 formed in a conical shape. The rotary plate 30 is also formed in a conical shape that matches the concave bottom surface 13 of the rotary concave portion 12. That is, the entire shape of the rotating plate 30 is an umbrella shape. The medal hole 31 is inclined in the outer peripheral direction of the rotating plate 30. Even if formed in this way, the transfer of medals fitted in the medal hole 31 by the rotation of the rotating plate 30 is performed in the same manner as described in the common explanation part. Although not particularly illustrated, in the present embodiment, the discharge recess 41 (see FIG. 4) is inclined so as to be continuous with the concave bottom surface 13, so that the medal fitted in the medal hole 31 can be removed without any problem. Can be discharged.

According to the second embodiment, since the rotating plate 30 is inclined downward from the center toward the periphery, the load of medals is dispersed, and the rotational force can be maintained even if the hopper motor 50 is downsized. This can save power. Also, since the opening of the medal hole 31 is inclined in accordance with the inclination of the rotating plate 30, it is easy to pick up the medal, and even if the driving speed of the hopper motor 50 is slightly increased, the medal is not missed and the payout speed is increased. Improvements can be made.
Also in this embodiment, by providing the rotating plate 30 with the convex portions 37 and the concave portions 38 as described in the first embodiment, the medal agitation effect can be enhanced, and the bridge prevention effect is enhanced. be able to.

(Third embodiment)
11 and 12 are diagrams showing a third embodiment. The third embodiment aims to make the internal medal difficult to become a bridge even if the capacity of the medal storage unit 20 is increased, and the improvement is focused on the internal shape of the medal storage unit 20 It is.
As shown in FIG. 11, the medal storage unit 20 of the hopper device 1 according to the third embodiment is provided with a plurality of passage plates 22 protruding alternately on the inner wall of the medal storage unit 20. In the illustrated example, two passage plates 22 are provided, but two or more passage plates may be provided. The passage plate 22 is inclined downward toward the center side of the medal storage portion 20, and the end portions of the passage plate 22 overlap each other in the vertical direction. When the medal storage portion 20 is viewed from above, the passage plate 22 covers the rotating plate 30. It is like that. Further, as shown in FIG. 11A, the passage plate 22 is provided so as to protrude from the inclined direction side or the opposite side to the inclined direction with respect to the inclined surface of the support plate 11 of the main body 10. The passage plate 22 located on the upper side of the inclination is disposed on the lower side. As shown in FIG. 11B, the passage plate 22 may be provided so as to protrude from the side (lateral side) orthogonal to the inclined direction with respect to the inclined surface of the support plate 11.

  Further, in the present embodiment, a vibration mechanism 100 is provided at a predetermined location of the hopper device 1 so that the medals in the storage unit 21 are not hardened. In the example of FIG. 11A, the vibration mechanism 100 is provided in the hopper motor 50. The vibration mechanism 100 is not shown in detail, but the one-way clutch provided on the motor shaft 51 does not vibrate when the motor shaft 51 rotates in the forward direction, and vibrates when rotated in the reverse direction. It is formed so as to occur. When normal medals are paid out, no vibration is generated, and vibration can be generated by driving the hopper motor 50 in reverse at a predetermined time for a predetermined time.

  Here, the “predetermined time” is when the game is not being executed, for example, when the operation signal of the start switch 5C is not received for a certain period of time, or when the settlement switch 5E is operated and the credit is settled. be able to. In addition, for example, when the slot machine S is turned on, or when an error (particularly, a hopper empty error) is reset (that is, when a medal is supplied to the medal storage unit 21), the hopper motor 50 is driven in reverse. It may be. Further, the “predetermined time” is a predetermined time, and a different time may be set in accordance with the timing for driving the hopper motor 50 in the reverse direction. These controls are performed by the hopper controller of the main controller 7A.

  According to the present embodiment, since the passage plate 22 is present, the passage plate 22 supports a part of the weight of the medal, so that the burden on the rotary plate 30 can be reduced. That is, since medals are not stored immediately below the base of the inner wall of the medal storage unit 20, even if the stored medals are almost full as shown by a thin line in FIG. A space is formed on the upper inclined side of the upper surface, so that a large load is not applied to the rotating plate 30. Also, the passage plate 22 makes the internal space of the storage portion 21 zigzag, and a passage is formed inside the storage portion 21 due to the inclination of the passage plate 22, so that the medal gradually moves downward. The bridge is also unlikely to occur. Furthermore, the bridge prevention effect is further enhanced by operating the vibration mechanism 100. On the other hand, when there are few medals in the storage part 21 of the medal storage part 20, as shown in FIG. 11 (A), the medals inserted from above pass through the passage plate 22 and slide down on the upper surface of the rotating plate 30. That is, since the medals do not drop vigorously on the upper surface of the rotating plate 30, the medals near the medal hole 31 are not repelled and the insertion into the medal hole 31 is not hindered.

From the above, even if the capacity of the medal storage unit 20 is increased to some extent, a bridge is not easily generated and the rotating plate 30 is not burdened, so the hopper motor 50 can be reduced in size, resulting in power saving. And lead to cost reduction.
(Modification)
Here, in the above-described embodiment, the plurality of passage plates 22 are provided. However, as a method of reducing the burden on the rotating plate 30, as shown in FIG. It is also possible to provide a semi-cylindrical flange 23 (see FIG. 12 (B)) extending in the direction. As shown in FIG. 12A, the flange portion 23 is provided on the support plate 11 along the upper edge of the rotation plate 30 so as to cover the upper half of the rotation plate 30 from above. Even when such a collar 23 is provided, medals do not collect at the base of the collar 23, so that the load applied to the rotating plate 30 can be reduced.

Further, the vibration mechanism 100 is not limited to the above. For example, an eccentric motor can be used for the hopper motor 50 so that it always vibrates even when a medal is paid out. Further, an eccentric motor can be provided separately from the hopper motor 50, and this can be attached to, for example, the outer wall of the medal storage unit 20 and driven at a predetermined time so as to vibrate the internal medal.
Even when the vibration mechanism 100 is not provided, there is an effect that the rotation plate 30 is not burdened by the passage plate 22 and the flange 23. If the load is not applied to the rotating plate 30, it is possible to reduce the size of the motor and increase the capacity of the medal storage unit 20. Furthermore, if the shape of the rotating plate 30 is formed as in the first embodiment, the medal guidance to the medal hole 31 is surely performed even when the number of medals in the storage portion 21 is reduced, which is effective.

Incidentally, if the vibration mechanism 100 is provided, the bridge prevention effect can be expected even if the passage plate 22 and the flange 23 are not provided. However, when the capacity of the medal storage unit 20 with respect to the rotating plate 30 is increased, it is more preferable to provide the passage plate 22 and the collar unit 23 because the burden on the rotating plate 30 is reduced.
(Fourth embodiment)
13 to 15 are diagrams showing a fourth embodiment. The fourth embodiment aims to reduce the size of the hopper motor 50 or increase the capacity of the medal storage unit 20 with the same type motor, and focuses on the rotation method of the rotating plate 30 and improves the method.

Here, in the first to third embodiments described above, the rotating plate 30 is connected to the motor shaft 51 of the hopper motor 50, and the rotating plate 30 is directly rotated by the motor shaft 51. . On the other hand, the hopper device 1 according to the fourth embodiment has a gear 39A formed on the outer peripheral portion of the rotating plate 30 and a motor gear 52 on the motor shaft 51 of the hopper motor 50 as shown in FIG. The motor gear 52 and the gear 39A are engaged with each other, and the rotating plate 30 is rotated by the rotation of the motor gear 52.
As shown in FIG. 13, the rotating plate 30 according to the present embodiment is provided with a disc 39 having a gear 39A formed around the lower portion of the rotating plate 30, and the disc 39 and the rotating plate 30 are fixed by a shaft 39B. It is. The disc 39 is disposed below the support plate 11, and the hopper motor 50 is disposed on the inner surface of the outer wall of the main body 10 so that the motor gear 52 is engaged with the gear 39A. When the hopper motor 50 is driven, the motor gear 52 rotates, and the rotation of the motor gear 52 is transmitted to the gear 39A and the disk 39 rotates, whereby the rotating plate 30 rotates in the direction opposite to the rotating direction of the motor gear 52. It is supposed to be.

In this way, by rotating the rotating plate 30 by applying a rotational force from the outer periphery, the rotating plate 30 can be rotated with a torque smaller than that directly rotated by the motor shaft 51, and the hopper motor 50 can be reduced in size. . Thereby, power saving and cost reduction can be achieved. In addition, when a motor having the same performance is used, the rotating plate 30 can be rotated with a strong torque, so that the capacity of the medal storage unit 20 can be increased.
As shown in FIG. 14, a disc 39 having a diameter larger than that of the rotating plate 30 is formed in close contact with the lower surface of the bottom medal conveying portion 32 of the rotating plate 30, and the disc 39 is formed on the support plate 11. You may make it accommodate in the rotation recessed part 12. FIG. In this case, as shown in FIGS. 14A and 14B, a part of the gear 39A is formed so as to be exposed from the notch 18 provided at the corner of the rotary recess 12, and the notch 18 A motor gear 52 that meshes with the gear 39A is disposed. The rotating plate 30 is supported by a rotating shaft 11A provided on the concave bottom surface 13 of the rotating recess 12, and rotates integrally with the disk 39 inside the rotating recess 12. As shown in FIG. 14B, if the discharge recess 41 for guiding the medal to the medal discharge port 17 is flush with the upper surface of the disk 39, there is no problem in discharging the medal.

(Modification)
In the above-described embodiment, the rotating plate 30 is rotated by the single hopper motor 50, but a plurality of smaller hopper motors 50 are provided and rotated by the plurality of hopper motors 50, compared to the case of rotating alone. The plate 30 is formed so as to rotate, and a medal amount detection sensor capable of detecting the amount of medals stored in the medal storage unit 20 is provided. Based on the detection of the medal amount detection sensor, the hopper motor 50 is driven. You can also change the number.
For example, as shown in FIG. 15A, a hopper motor 50a having a motor gear 52a meshing with the gear 39A and a hopper motor 50b having a motor gear 52b meshing with the gear 39A are provided, and only the hopper motor 50a is driven. The rotating plate 30 can be rotated, and when both the hopper motor 50a and the hopper motor 50b are driven, the rotating plate 30 can be rotated with a stronger torque.

  Here, when only the hopper motor 50a is driven, if the motor gear 52b of the other hopper motor 50b remains engaged with the gear 39A, the motor shaft 51 of the hopper motor 50b rotates, which is not preferable. As shown in (B), it is preferable to form the hopper motor 50b so that the motor gear 52b can move in a direction away from the gear 39A. For example, the moving plate 53 on which the hopper motor 50b is mounted is rotatably supported by the rotating shaft 53A, and the moving plate 53 is rotated by a moving device (for example, a solenoid) (not shown), so that the position of the motor gear 52b is It can be movable between a position engaging with the gear 39A and a position distant from the gear 39A. Alternatively, although not particularly illustrated, a connecting gear is provided between the motor gear 52b and the gear 39A, and when the hopper motor 50b is not driven, the connecting gear is moved away from the gear 39A, and the rotation of the rotating plate 30 is caused by the motor gear 52b. You may not be transmitted to.

  The medal storage unit 20 is provided with the passage plate 22 as described in the third embodiment, and the passage plate 22 is provided with a contact sensor 85 as a medal amount detection sensor. The contact sensor 85 includes a first detection unit 85A at the lower end of the back surface of the passage plate 22 positioned on the upper side, a second detection unit 85B at the lower end of the back surface of the passage plate 22 positioned on the lower side, and a third detection unit on the rotary plate 30. 85C is arranged. Then, when the stored medal in the storage unit 21 reaches the height of the lower end of the back surface of the passage plate 22 positioned on the lower side, the second detection unit 85B and the third detection unit 85C are energized and, for example, the signal 1 is output. When the stored medal reaches the height of the lower end of the back surface of the passage plate 22 positioned on the upper side, the first detection unit 85A and the third detection unit 85C are energized, and for example, the signal 2 is output. This signal output is monitored by the hopper control unit, and the signal 1 is output when the signal is not output (when the stored medal has not reached the height of the lower end of the back surface of the passing plate 22 positioned below). In the meantime, when the medal is paid out, only the hopper motor 50a is driven, and when the signal 2 is output, the two hopper motors 50a and 50b are driven.

By forming as described above, when a predetermined amount or more of medals are stored in the storage unit 21 of the medal storage unit 20, the rotating plate 30 is rotated using a plurality of hopper motors 50, and the medals are less than a predetermined amount. Then, the rotating plate 30 can be rotated using a single hopper motor 50, and power can be saved efficiently. In particular, since the capacity of the medal storage unit 20 can be increased by providing the passage plate 22, it is assumed that the burden on the rotating plate 30 is greatly changed when the amount of medals is large and small. In such a case, it is meaningful to change the number of motors to be driven according to the amount of medals.
Two or more hopper motors 50 may be provided. In addition, even when the passage plate 22 is not provided in the medal storage unit 20, a medal amount detection sensor capable of detecting the medal amount stored in the storage unit 21 is provided at any location, and the hopper is driven based on this detection. The number of motors 50 may be determined. The medal amount detection sensor is not limited to the contact sensor, and may be a weight sensor or an optical sensor.

(Fifth embodiment)
FIG. 16 is a diagram showing a fifth embodiment. The fifth embodiment aims to prevent the rotating plate 30 and the hopper motor 50 from being burdened even if the capacity of the medal storage unit 20 is increased. The fifth embodiment is focused on the overall structure of the hopper device 1 and its improvement. Is intended.
In the hopper device 1 according to the fifth embodiment, as shown in FIG. 16, a support plate 11 is rotatably attached via a hinge 19 provided on the upper portion of the main body 10. A rotating plate 30 is disposed on the medals, and a medal storage unit 20 is fixed. An elastic member 200 is attached to the lower end portion of the support plate 11 that is installed at an angle to bias the support plate 11 upward in the normal state. Further, in the present embodiment, the notch 15 formed in the peripheral wall 14 (see FIG. 4) of the rotating recess 12 of the support plate 11 is located on the upper surface of the main body 10, and the medal outlet 17 is provided at the upper end portion of the main body 10, and a hinge 19 is located on the side of the anti-medal discharge port 17 of the discharge recess 41 that allows the medal discharge port 17 and the cutout portion 15 to communicate with each other. That is, even if the inclination angle of the support plate 11 changes, the medals sent out by the rotating plate 30 are discharged from the medal discharge port 17 through the discharge recess 41. The payout guide 16 fixed to the support plate 11 is adjusted so that the medals discharged from the rotating plate 30 are directed to the medal discharge port 17 even if the inclination angle of the support plate 11 changes.

  The elastic member 200 is a compression coil spring having a lower end fixed to the bottom of the main body 10 and an upper end fixed to the anti-hinge side (inclined lower side) of the support plate 11, and is compressed when subjected to a certain amount of load. Then, the height of the lower end portion of the support plate 11 whose upper end portion is fixed to the hinge 19 is changed (lowered), and the inclination angle of the support plate 11 is changed (inclination angle is increased). In other words, when there are few medals stored in the medal storage unit 20, the elastic member 200 is supported by the support plate 11 and the support plate 11 by the repulsive force as shown in FIG. Is held in a posture close to a horizontal state, and when a predetermined amount of medals are stored in the medal storage unit 20, the elastic member 200 is compressed, as shown in FIG. The inclination angle of the rotating plate 30 is increased. When the inclination angle of the rotating plate 30 is increased, the load applied to the rotating plate 30 is reduced, so that the burden on the hopper motor 50 is also reduced.

  Since the hopper device 1 according to the present embodiment is formed as described above, even if a medal amount detection sensor and a drive source for rotating the support plate 11 are not provided, the number of stored medals exceeds a certain amount. The inclination angles of the support plate 11 and the rotary plate 30 are automatically increased, and when the stored medal is less than a predetermined amount, the inclination angles of the support plate 11 and the rotary plate 30 are automatically reduced. For this reason, when the number of stored medals is small, the medals can be accumulated on the entire upper surface of the rotating plate 30, and the medals can be efficiently picked up by the medal holes 31. Here, it is more preferable that the rotating plate 30 is provided with the convex portion 37 and the concave portion 38 as described in the first embodiment. On the other hand, when there are a large number of stored medals, the inclination of the rotating plate 30 is increased and the load received from the upper side is reduced, so that the rotating plate 30 and the hopper motor 50 are not burdened. As a result, the hopper motor 50 can be downsized. Can do.

  Since the support plate 11 and the medal storage unit 20 are integrally tilted, it is necessary to devise the shape of the medal storage unit 20 so that the medal does not spill from the upper edge of the medal storage unit 20 when the support plate 11 is tilted to the maximum. is there. However, if the medal reservoir 20 is fixed to the main body 10 and only the support plate 11 is changed, the gap generated between the rotating plate 30 and the medal reservoir 20 must be filled using, for example, a bellows structure. In addition, there is a need to take measures to prevent the medal from being caught in the gap, so that it is preferable to move the support plate 11 integrally as described above. In addition, it is conceivable that the amount of medals is detected by a sensor, and the hopper device 1 or the support plate 11 (rotary plate 30) is inclined using a drive source such as a damper. It is optimal to form as in the embodiment.

(Summary)
The hopper device 1 according to the present invention is not limited to the first to fifth embodiments described above, and includes a configuration in which any of the first to fifth embodiments and modifications thereof is combined. May be. Furthermore, it may have a configuration in which any of the individual configuration requirements described in each embodiment and its modifications is combined.

S slot machine (game machine)
1 Hopper device 2 Housing 3 Front door 5 Operation unit
5A medal slot 5B bet switch
5C Start switch 5D Stop switch
5E payment switch 6 reel device 6A rotating reel 7 control device 7A main control device 8 power supply device 9 effect display device
10 Body 11 Support plate
12 Rotating recess 13 Concave bottom
14 Perimeter wall 17 Medal outlet
18 Notch 19 Hinge
20 Medal storage part 21 Storage part
22 Pass plate 23
30 Rotating plate 31 Medal hole (medal holding part)
32 Bottom medal transport section (medal holding section) 33 Medal insertion slot
37 Convex part (protrusion) 38 Concave part
39 Disc 39A Gear
40 Medal ejection mechanism 41 Ejection recess
42 Fixed pin 43 Movable pin
50 Hopper motor (drive motor) 51 Motor shaft
52 Motor gear
60 Symbol display window 61 Numerical display
80 Dispensing sensor 90 Sub tank
100 Vibration mechanism 200 Elastic member

Claims (1)

A reel device comprising a plurality of rotating reels;
A start switch for rotating the rotating reel;
A stop switch for individually stopping the rotating reels in rotation;
A hopper device for storing and paying out medals;
A role lottery for determining whether or not the winning combination is a combination of a plurality of symbols, and a control device for controlling the operation of the reel device and the hopper device,
In the gaming machine that pays out the number of medals according to the winning from the hopper device when the stop symbol of the rotating reel that has stopped rotating based on the operation of the stop switch has become a predetermined winning mode.
The hopper device includes a medal storage unit, a rotating plate including a medal holding unit that receives and holds the medal stored in the medal storing unit, and a drive motor for rotating the rotating plate,
The rotating plate has, as the medal holding portion, a medal hole into which a horizontally overlapping medal can be inserted from above, and on the surface of the rotating plate, on the rear side in the rotation direction along the edge of the medal hole. A gaming machine characterized in that it is provided with a projection having a circular arc shape when viewed from above and inclined downward toward the rear side in the rotational direction.

Images