JP2001162033A - Shot recovering mechanism for shooting game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To separate recovered shots one by one and to prevent the shots from becoming unseparable. SOLUTION: This shot recovering mechanism is provided with a box 45a storing many shots 20 shot from a pseudo gun, a rotating rotary disk 48 provided at the lower section of the box 45a, a shot passing hole 48a provided on the rotary disk 48 in a size to pass one shot 20, and a shot separating plate 50 provided above the moving area of the shot passing hole 48a so that one shot 20 enters below it. Many shots 20 stored in the shot storing means 45a are rotated by the rotary disk 48 and guided under the shot separating plate 50, and the shots 20 are separated one by one through the shot passing hole 48a.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bullet collecting mechanism in a shooting game machine.

[0002]

2. Description of the Related Art As a shooting game for collecting bullets actually shot, there is a game in which a muzzle of a pseudo-gun is loaded with bullets, aimed at, and a stationary bullet is searched at an arbitrary position and collected by hand or the like. Are known.

[0003]

By the way, in the above-mentioned game, the game cannot be unmanned due to the necessity of collecting bullets manually.

Therefore, it is conceivable to make it possible to automatically collect bullets. However, in that case, there are the following problems. That is, when bullets are fired from a gun, the bullets are generally fired one by one, but in order to do so, the bullets must be supplied to the gun one by one. However, it is difficult to separate the recovered bullets one by one. For example, as a method of dividing collected bullets into one by one, it is common to divide each bullet by guiding a plurality of bullets to a passage that passes only one and passing through the passage,
There is a problem that a plurality of bullets are entangled with each other at the entrance of the passage, and the entrance of the passage is blocked and clogged, so that supply of the bullet to the gun becomes impossible.

An object of the present invention is to solve such a problem of the prior art, and an object of the present invention is to provide a bullet collecting mechanism in a shooting game machine capable of collecting bullets without clogging.

[0006]

SUMMARY OF THE INVENTION A bullet collecting mechanism in a shooting game machine according to the present invention is a bullet collecting mechanism in a shooting game machine that fires a bullet from a pseudo gun at a target provided in front of the gun. Box that has a through hole of the size of one bullet that functions as an outlet and stores a large number of bullets fired from the box, and that is attached to the box and prevents clogging at the entrance of the through hole Means.

In this configuration, even if the entrance of the through hole is slightly clogged, the clogging prevention means prevents the clogging.

Here, as the means for preventing clogging of bullets, means for vibrating the box, means for agitating bullets in the box, means according to claim 2 and the like correspond.

In the bullet collecting mechanism for a shooting game machine according to the present invention, the bullet ammunition preventing means includes a rotating rotary disc provided at a lower portion inside the box, and one bullet passing through the rotating disc. 1 or 2 provided in a large size
The above-mentioned bullet passage hole, and a bullet separation plate provided in a state where one bullet enters under the movement region of the bullet passage hole and above the through hole, and is provided under the bullet passage hole. A configuration may be adopted in which a large number of stored bullets are rotated by a rotating disk, guided under a bullet separation plate, passed through a bullet passage hole, and given to the through holes one by one.

According to the present invention, when a large number of bullets stored in the box are guided under the bullet separation plate by the rotating disk, and one bullet stays under the bullet separation plate, In addition, when the bullet passage hole provided in the rotating disk passes below the bullet separation plate, the one remaining bullet falls through the bullet passage hole, so that the clogging of the bullet can be reliably prevented. in addition,
Since only one bullet can stay under the bullet separation plate, a plurality of bullets do not block the entrance of the bullet passage hole.

In the bullet collecting mechanism of the shooting game machine of the present invention, the bullet collecting mechanism includes a bullet storing means comprising the above-mentioned bullet clogging preventing means and a box, and is provided upstream of the bullet storing means.
A guide having a gap large enough to allow a large number of bullets to enter each other, receiving a bullet fired from a pseudo-gun, guiding the bullet to the gap, and dropping the bullet, and disposed below the gap, A configuration further comprising: a bullet collecting unit that collects the dropped bullets and blocks the bullets, and simultaneously discharges the bullets blocked from the drop holes provided below the blocking position to the box of the bullet storing unit at a predetermined timing. It can be.

In this configuration, the guide means provided on the upstream side of the bullet storing means having the above-described action discharges bullets from a gap large enough to allow a large number of bullets to enter at the same time. However, since a plurality of bullets are sent at once instead of being sent one by one to the downstream side, no clogging occurs.

In the bullet collecting mechanism of the shooting game machine according to the present invention, the bullet collecting means collects a bullet dropped from a gap between the guide means and dams it, and a drop hole provided on the downstream side of the weir. And a moving means for moving the weir to open and close the drop hole, and when the moving means moves the weir to open the drop hole, the bullet that has been blocked flows from the drop hole, and the moving means closes the weir. When the moving hole is closed by closing the drop hole, the bullet can be blocked.

In this configuration, when the drop hole is closed by the weir, the bullet can be blocked, and when the drop hole is opened by the weir, the blocked bullet can be discharged.

In the bullet collecting mechanism of the shooting game machine of the present invention, gas is supplied into the box,
A through hole is provided on the bottom of the box and below the passage area of the bullet hole of the rotating disk, and passes through the bullet hole and the through hole via a supply pipe arranged between the through hole and the pseudo gun. It is possible to adopt a configuration in which the shot bullet is supplied to the pseudo gun by gas.

In this configuration, the bullets passing through the bullet passage holes are supplied to the pseudo guns one by one by gas through the through holes.

In the bullet collecting mechanism of the shooting game machine according to the present invention, when the bullet is supplied to the pseudo-gun by gas through the supply pipe, the moving means moves the weir to close the drop hole. be able to.

In this configuration, when a bullet is sent to the pseudo-gun by the gas supplied into the box, the gas is used only for feeding the bullet to the pseudo-gun because the weir blocks the drop hole. Can,
Gas leakage can be prevented and gas can be effectively used.

[0019]

Embodiments of the present invention will be specifically described below.

FIG. 1 is a front sectional view showing a shooting game machine to which this embodiment is applied, FIG. 2 is a left side view thereof, and FIG.
FIG. 4 is a front sectional view showing the bullet storage means, and FIG. 4 is a plan view of FIG. 3 as viewed obliquely from above.

The shooting game machine 1 has a housing 2 roughly divided into an upper part 2a and a lower part 2b, and the upper part 2a is formed in a substantially rectangular cylindrical shape having an opening 2c formed on the front side thereof. In the vicinity of the opening 2c, a pseudo gun 10 which is a main part of the present invention is provided, while a screen member 30 as a target is provided in the inner part. An inclined floor 2d and an inclined ceiling 2e are provided on the front side of the screen member 30. The inclined floor 2d is arranged with the screen member 30 side up, and the inclined ceiling 2e is arranged with the screen member 30 side down. Have been. The inclined floor 2d and the inclined ceiling 2e are provided to prevent the spherical bullet 20 emitted from the pseudo gun 10 from bouncing back to the opening 2c side. Further, a part of the inclined ceiling 2e is open, and a safety sensor 23 described later is disposed in the opening with the detection direction facing the opening 2c.

The floor 2f of the rectangular cylindrical upper part 2a has a higher opening 2c side and a lower screen member 30 side, and the front end of the floor 2f extends to the front of the lower end of the inclined floor 2d. A gap 2g is provided between the tip of the surface 2f and the lower end of the inclined floor 2d. The gap 2g is for guiding the bullet 20 to the bullet storage means 40 provided in the lower portion 2b of the housing 2. Therefore, the bullet 20 rolls on the inclined floor 2f and the inclined floor 2d toward the gap 2g,
It falls into the bullet storage means 40 from the gap 2g.

The bullet storage means 40 receives the bullet 20 dropped from the gap 2g, and rolls the received bullet 20 forward, and a hanging plate 42 connected to the lower end of the inclined plate 41; The second inclined plate 4 is connected to a position slightly above the lower end of the hanging plate 42 and rolls the bullet 20 forward.
3 and a bullet 20 from the second inclined plate 43, FIG.
A bullet collection unit 44 shown in (plan view) and a bullet storage unit 45 shown in FIG. 3 for temporarily storing the bullets 20 collected in the bullet collection unit 44.
And a supply pipe 46 for supplying the bullets 20 from the bullet storage unit 45 to the pseudo gun 10 one by one.

The bullet 20 dropped from the gap 2g is
It is provided to the bullet recovery unit 44 via the first and second inclined plates 43.

As shown in FIGS. 3 and 4, the bullet collecting portion 44 includes an inclined plate 44a connected to the second inclined plate 43, and a guide member 44b for guiding the bullet 20 rolling down the inclined plate 44a.
And a dam portion 44c for temporarily stopping the bullet 20 guided by the guide member 44b, a drop hole 44d for dropping a bullet formed on the inclined plate 44a below the dam portion 44c, and moving up and down the dam portion 44c. And elevating means 44e. Lifting means 44e
Is composed of an electric motor, driving force transmitting means, and the like.

As shown in FIG. 3A, the elevating means 44e
When the weir portion 44c descends due to the
As shown in FIG. 3B, when the weir portion 44c rises, the bullet 20 stopped by the weir portion 44c falls from the drop hole 44d and is given to the bullet storage portion 45.
The upstream side of the bullet recovery unit 44 is provided with the inclined plate 41 and the second
The inclined plate 43 may be omitted, and the bullet 20 may be transported by a belt conveyor so that the bullet collecting unit 44 is located at the drop position.

The bullet storage section 45 has a box 45 having a substantially rectangular parallelepiped shape.
The ceiling of the box 45a is formed by the inclined plate 44a, and the entire box 45a is disposed in an inclined state, and the floor 45b of the box 45a is inclined substantially in parallel with the inclined plate 44a. ing. One end 47a of an air supply pipe 47 is connected to an upper side surface 45c of the inclined box 45a in a communicating state, while a spring is provided below the inclined floor 45b as shown in FIG. 5 (plan view). A rotating disk 48 having a large number of passage holes 48a is provided in an inclined state like the floor 45b.

The bullet 20 dropped from the drop hole 44d and given to the bullet storage section 45 is placed under the inclined box 45a by its own weight and by the blowing force of air from the air supply pipe 47 on the rotating disc 48 side. It is sent to.

The rotating disk 48 is rotatable about a rotating shaft 49a of an electric motor 49 provided below the box 45a, and the bullet passage hole 48a is separated from the rotating shaft 49a by an equal distance. It is arranged at an equal distribution angle and bullet 2
It is formed in a circle slightly larger than 0. A circular through hole 45d slightly larger than the bullet 20 is formed at one location of the floor 45b through which the bullet passing hole 48a passes upward. The supply pipe 4 communicates with the through hole 45d.
6 are connected. The supply pipe 46 has a flexible hose shape, and supplies the bullets 20 to the pseudo gun 10 one by one by the pressure of the air from the air supply pipe 47 (see FIG. 1). The floor 45b of the box 45a and the rotating disk 4
Even if a gap is provided slightly with the lower surface of the nozzle 8 and the weir portion 44c descends to completely close the drop hole 44d, air passing through the gap escapes from the supply pipe 46 and supplies the bullet 20 to the pseudo gun 10 without any trouble. it can. Above the through-hole 45d, a bullet separation plate 50 is provided in the horizontal direction with an interval for receiving one bullet 20. Even when a large number of bullets 20 are present above the bullet passage holes 48a of the rotating disk 48, the bullet separation plate 50 separates such bullets 20 before entering the bullet passage holes 48a, and The bullet 20 is prevented from simultaneously entering the bullet passage hole 48a, and only one bullet 20 is
And a bullet passing hole 48a.

Here, the rotating disk 48 having the bullet passage hole 48a and the bullet separation plate 50 constitute a bullet clogging prevention means. As described above, when a means for vibrating the box or a means for stirring the bullets in the box is used as the means for preventing clogging of the bullet, the rotating disk 48 having the bullet passage hole 48a is used.
And the bullet separation plate 50 are unnecessary.

Next, the structure of the pseudo gun 10 will be described with reference to FIG.

The pseudo-gun 10 includes a grip portion 13, a trigger 11 provided on the front side of the grip portion 13, a barrel 12 provided on the upper portion, and a photo sensor 1 provided on the way of the barrel 12.
7, a flash 18 as a light storing light source disposed closer to the muzzle side than the photo sensor 17, a reaction unit 16 provided below the barrel 12 in front of the trigger 11, and an LED 19 as a light source for a safety sensor. It includes a trigger locking solenoid 22 provided immediately behind the trigger 11 and a microswitch 21 provided behind the solenoid 22.

The barrel 12 includes a first barrel member 12A and a second barrel member 12A.
It is composed of three barrel members 12B and a third barrel member 12C. The first barrel member 12A is formed in a cylindrical shape with a circular section having a length from the muzzle 12a to the proximal end 12b, and the second barrel member 12B is formed with a circular tube having a length from the distal end 12c to the proximal end 12d. It is formed in a shape. The inner diameter of the first barrel member 12A is slightly larger than the outer diameter of the second barrel member 12B, and the second barrel member 12B
Is inserted inside the base end 12b of the first barrel member 12A. Note that the inner diameter of the barrel 12 is slightly larger than the outer diameter (for example, 5.8 mm) of the bullet 20, and the smallest portion is, for example, about 6.0 mm.

The third barrel member 12C has a length from the distal end 12e to the proximal end 12f, and the distal end 12e is connected to the proximal end 12d of the second barrel member 12B.

FIG. 7A is a front view showing the third barrel member 12C, and FIG. 7B is a plan view thereof. Third barrel member 12C
The region D on the distal end 12e side and the region E on the proximal end 12f side have a circular outer cross section, the intermediate region F is formed as a rectangular cross section, the upper part of the circular cross sectional region E is a flat surface 12g, and the flat surface is a flat surface 12g. A slit 12h is formed on the base end side of 12g. On the other hand, the lower portion 12i on the base end 12f side of the region E having a circular cross section functions as an elastic partition portion described later.

Further, an elastic pressing member 14 made of a leaf spring is attached from the intermediate region F to the region E of the third barrel member 12C.

FIG. 8A is a front view showing the elastic pressing member 14, FIG. 8B is a plan view thereof, and FIG. 8C is a right side view thereof.

As shown in FIGS. 6 and 8, the elastic pressing member 14 has a mounting portion 14d having a U-shaped cross section on the muzzle 12a side, and the opposite side of the mounting portion 14d from the muzzle 12a side is horizontal. And a mounting portion 14 for the horizontal portion 14a.
The side opposite to d is a downward inclined portion 14b bent downward,
The opposite side of the downwardly inclined portion 14b from the horizontal portion 14a is an upwardly inclined portion 14c bent upward. This elastic pressing member 14
Is mounted on the third barrel member 12C with screws (not shown) so that the mounting hole 14e of the mounting portion 14d and the mounting hole 12j of the third barrel member 12C shown in FIG. 7 are aligned, and the horizontal portion 14a has a flat surface 12g. , The downwardly inclined portion 14b protrudes downward through the inside of the slit 12h.

The intermediate region F of the third barrel member 12C
Is attached to the upper part of the trigger 11.

FIG. 9A is a front view showing the trigger 11.
(B) is a right side view thereof, and (c) is a plan view thereof. The trigger 11 has a cylindrical mounting portion 11a having a mounting hole 11b having a rectangular cross section therein at an upper portion thereof, and a protrusion 1 at a rear end.
1d.

The third barrel member 12C passes through a mounting hole 11b through an intermediate region F having a circular outer periphery and a cylindrical mounting portion 11a.
7 and the mounting hole 12k formed in the intermediate region F of the third barrel member 12C as shown in FIG. 7, and is mounted on the trigger 11 with screws (not shown). Therefore, the third barrel member 12 </ b> C and the elastic pressing member 14 can slide with the movement of the trigger 11. The tip 12c of the second barrel member 12B described above.
Is inserted inside the base end 12b of the first barrel member 12A, and is set to be longer than the slide length.

The first barrel member 12A and the second barrel member 12B are made of a transparent or translucent resin. When the photo sensor 17 is provided on the base end 12b side of the first barrel member 12A, A flash 18 is arranged closer to the muzzle 12a than the flash 17 is. The photo sensor 17 is
Upon detecting a bullet 20 passing through the barrel 12, the flash 18 emits light based on the detection result and irradiates the bullet 20. Bullet 20
Is a relatively hard material containing a luminous agent, for example, an alkaline earth sulfide, and shines for a certain period of time by light irradiation by the flash 18. Here, the luminous agent has a property that it shines for a while by light irradiation and then darkens to an extinction state or a state close to it. As the flash 18, for example, a xenon lamp is used. In front of the flash 18, below the muzzle, L
The ED 19 is mounted so as to emit light in a direction in which the muzzle 12a faces. The light from the LED 19 is detected by a safety sensor 23 provided inside the housing 2. The safety sensor 23 includes, for example, a muzzle 12a having a screen member 30.
When the muzzle 12a is directed to the side, the light from the LED 19 is detected, and when the muzzle 12a is directed to the outside of the opening 2c of the housing 2, the light is not detected.

The lower end of the solenoid 22 is attached to the protrusion 11d at the rear end of the trigger 11 so that the solenoid 22 moves forward and backward. The details are shown in FIG. When the safety sensor 23 does not detect the light from the LED 19,
The solenoid 22 advances upward as shown by a broken line, and its upper end 22a is locked by a step portion 24a of a lock member 24 provided above the solenoid 22, and the trigger 1
1 cannot be closed. On the other hand, when the safety sensor 23 is LE
When the light from D19 is detected, the solenoid 2
2 retreats downward as shown by the solid line, and its upper end 22a
Is separated from the step portion 24a, and the trigger 11 can be pulled. That is, only when the muzzle is actually pointed at the screen member 30, the safety sensor 23
Since 0 can be fired and the bullet 20 is not fired in other cases, safety can be achieved. Note that reference numeral 15 in FIG. 10 denotes a spring that presses the trigger 11 in the whiteout direction.

Further, the LED 19 emits light by the pulse oscillation shown in FIG. 11 and has two kinds of frequencies f1 and f2, and the safety sensor 23 uses these two kinds of frequencies f1 and f2.
2 is also provided. When the safety sensor 23 does not detect the two types of frequencies f1 and f2, the solenoid 22 advances upward and prevents the trigger 11 from being pulled. As a result, even if light other than the LED 19 enters the safety sensor 23, the safety sensor 23 operates at two different frequencies f1.
And f2 are not detected and the solenoid 22 is in a state in which the trigger 11 cannot be pulled, so that double safety can be secured.

Inside the grip portion 13, an air pipe 13a for projectile firing, an air pipe 13b for driving a reaction unit branched from the middle of the air pipe 13a, and an air pipe 13c for bullet supply are provided. .

As shown in FIG. 6, the base end (not shown) of the air pipe 13c is connected to the supply pipe 46 so as to communicate with the air pipe 13c, as shown in FIGS. 6, 10, and FIG. Are connected to each other in a state where the tip side is orthogonal to a slightly forward position in the inner part of the barrel 12, and supplies the bullet 20 sent by the supply pipe 46 to the inside of the barrel 12. The proximal side (not shown) of the air pipe 13a for bullet firing is connected to an air supply pipe (78c shown in FIG. 12) different from the supply pipe 46, and is shown in FIGS. 6 and 18 (a). As described above, the distal end side is connected to the inner part of the barrel 12 so as to supply air for firing the bullet 20 disposed in the barrel 12 into the barrel 12. On the other hand, the air sent from the reaction unit driving air line 13b branched from the middle of the air line 13a is supplied to the reaction unit 16 at the tip end.

FIG. 12 is a block diagram showing an air supply system in the shooting game machine according to the present embodiment.

The air from the compressor 71 is supplied to the pipe 7
The pipe 78b (47) is sent to the air filter 72 at 8a and then divided into two. The pipe 78b (47) holds the regulator 73, the solenoid valve 74, the bullet storage section 45, the supply pipe 46, and the pseudo gun 10. Air is supplied to the barrel 12 from the bullet supply air pipe 13c via the section 13.

On the other hand, air is supplied to the barrel 12 from a bullet firing air pipe 13a through a regulator 76, a solenoid valve 77, and a gripper 13 of the pseudo gun 10 by a pipe (another air supply pipe) 78c. Drive air piping 13
Air is supplied to the reaction unit 16 from b. Most of the air supply system includes a lower part 2 as shown in FIG.
b.

Next, a description will be given of a method of supplying the air supplied to the bullet firing air pipe 13a.

As shown in FIG. 6, the trigger 11 has a protruding portion 11d which protrudes rearward at a rear portion of a lower portion thereof, and a switch piece 21a of the microswitch 21 disposed behind the trigger 11 has a protruding portion. The angle is changed by the portion 11d.

When the switch piece 17a operating as described above reaches a predetermined angle, the micro switch 21 is operated, and
The solenoid valve 77 provided on the pipe 78c connected to the air pipe 13a is switched from the closed state to the open state. As a result, air at a predetermined pressure is supplied to the air pipe 13a for firing and the air pipe 13b for driving the reaction unit.

FIG. 13 is a front sectional view showing the recoil unit 16.

The reaction unit 16 is shown in FIGS.
As shown in FIG. 3, a unit base 16h, a connecting portion 16g fixed to the unit base 16h and connected to an end of the pipe 13b, and a tube 16a connected to the connecting portion 16g in parallel with the barrel 12; A cylindrical support member 16b and 16c fixed to the distal end side and a proximal end side of the tube 16a; a closed cylindrical weight 16d slidably supported by the cylindrical support members 16b and 16c; A cylindrical intermediate member 16e fixed to the inside of the cylindrical support member 16c and reciprocating outside the cylindrical support member 16c with the sliding of the weight 16d, and both ends are attached to the cylindrical intermediate member 16e and the cylindrical support member 16b. And weight 16
and a coil spring 16f for applying a pressing force in the direction of the arrow to d.

The reaction unit 16 configured as described above
The weight 16d moves forward as indicated by the broken line by the supply of air from the pipe 13b, and then the air stored inside the reaction unit 16 is released by switching the solenoid valve 77, and the weight 16d is pressed by the coil spring 16f. The weight 16d moves in the direction of the arrow and collides with the unit base 16h. Due to this collision, a reaction is felt in the hand of the game player holding the holding portion 13 of the pseudo gun 10.

Further, as shown in FIG. 10 in a state where the trigger 11 is not pulled, the elastic partitioning portion 12i of the elastic pressing member 14 and the third partitioning member 12C of the third barrel member 12C which move in conjunction with the trigger 11. The rear end (12f) is the same as or slightly retracted from the edge of the leading end opening of the air pipe 13c.
“b” is located slightly behind the rear end of the bullet partition 15, and presses the upper part of the bullet 20 supplied into the barrel 12 from the air pipe 13 c downward.

Next, a screen member which is a target of the pseudo gun will be described.

FIG. 14A is an exploded front view showing a screen member, and FIG. 14B is an exploded perspective view showing a part thereof.

The screen member 30 is made of the topsheet 3
1, an intermediate sheet 32, and a back sheet 33. The topsheet 31 has a sticky gel-like surface layer 31a made of, for example, an organogel (oil-based gel). When the bullet 20 fired from the pseudo gun 10 hits the surface layer 31a, the bullet 20 It attaches for a short time and then falls.

As shown in FIG. 15 (a), the intermediate sheet 32 has a large number of longitudinally long blind electrodes 32b formed on one side of the insulating sheet 32a in the horizontal direction, and spacers sandwiching each electrode 32b. 32c is formed in a line shape. As shown in FIG. 15 (b), the back sheet 33 has a large number of laterally long screen-shaped electrodes 33b formed on one side of an insulating sheet 33a in a vertical direction, and spacers 33c sandwiching each electrode 33b. It is formed in a line shape.

As shown in FIG. 14 (b), the intermediate sheet 32 and the back sheet 33 are
b and the two electrodes 32b,
33b is separated by spacers 32c and 33c. On the opposite side of the bonded intermediate sheet 32 from the electrode 32b, the topsheet 31 is bonded with the gel-like surface layer 31a side as the outside, thereby forming the screen member 30.

FIG. 16 shows a bullet 2
FIG. 4 is an explanatory diagram of a mechanism that can detect a position where 0 has hit. In FIG. 16, the insulating sheet 32a is omitted.

In FIG. 16, the position where the bullet 20 hits is indicated by A. The coordinate position of this position A is, for example, the electrode 32
b is applied to one of the electrodes 33b and the electrode 33b.
Hits the screen member 30, at least the top sheet 31, the intermediate sheet 32, and the electrode 32b indicated by B at the position A is bent, and a part of the bent electrode 32b is denoted by a certain electrode C. The electrode 33b is electrically contacted with the electrode 33b. Electricity flows through only one of the electrodes 33b in contact with the electrode 33b, and is measured by detecting that a current flows through the electrode 32b indicated by B and the electrode 33b indicated by C. . The measured value is provided to a control system described later. In addition, position A
And when the bullet 20 hits both of the adjacent coordinate positions on the upper, lower, left and right sides, the current may flow to only one side due to the presence of the spacer. The higher one is the coordinate position where the bullet 20 has hit. Further, it is preferable to use a flexible material that is easily bent for each member on the front side of the spacer 32c from the viewpoint of detecting the coordinate position.
Further, it is preferable to use a soft material which is easily bent for the spacers 32c and 33c for the same reason.

The surface layer 31a of the topsheet 31 has, for example, a white color or a pale color close to white, and a projected image is projected from a projector 35 provided on the floor 2f of the upper portion 2a as shown in FIG. It is a screen. Examples of the projected image include not only an image for selecting the game content, but also a selected shooting landscape image or target mark. As shown in FIG. 2, when a predetermined coin is inserted into a coin insertion unit 6 provided on the front side of the lower part 2b, the image for selecting the game content is projected from the projector 35 to the screen member 30, and the scenery image or the like is displayed. Shooting images such as target marks include push buttons 5a, 5b provided on an operation unit 5 also provided below the opening 2c.
It is projected by pressing and selecting 5c. Note that the shooting images are classified into an elementary course, an intermediate course, an advanced course, and the like according to the level of the game player, and each course can be selected from a plurality of types by operating the operation unit 5. ing.

For example, as an elementary course, there is a still image in which one or two or more target marks to be hit are simultaneously displayed. The intermediate course includes a dynamic image in which the target of the doll moves forward, backward, left, and right. Advanced courses include those in which the target moves faster and further changes the viewpoint of the displayed image.

FIG. 17 is a block diagram showing a control system.

The control system 80 includes a game control unit 81
, A target display control unit 82, a sound effect control unit 83, a coordinate position detection unit 84, and a game performance determination unit 85.

The game control section 81 has a CPU, a ROM, a RAM, etc., and controls the entire game machine.
, And performs time management and the like. The target display control unit 82 projects the projection image selected by the operation unit 5 from the projector 35 and controls the display contents of the projector 35 in accordance with an instruction from the game control unit 81. The sound effect control unit 83 includes a game control unit 81
According to the instruction from, the predetermined sound as the game progresses,
As shown in FIG. 1, the signals are output from a front speaker 9A and a rear speaker 9B provided in the upper portion 2a of the housing 2. The loudspeaker 9A outputs a simulated sound accompanying the firing of the simulated gun 10, and the loudspeaker 9B outputs a simulated effect corresponding to the object (image) displayed on the screen when the bullet 20 hits the object. Output sound. The two output timings are shifted by about 0.1 second. The coordinate position detection unit 84 has a function of detecting the coordinate positions of the electrodes 32b and 33b that are in contact with each other when the bullet 20 hits the screen member 30. The game score judging section 85 includes the screen member 30
The position of the target (or target mark) in the above projected image is compared with the coordinate position detected by the coordinate position detection unit 84, and it is determined whether or not the two match, and how many bullets are fired at the target A game score is obtained by adding a predetermined score to the target hit or not, or to the target hit by the bullet. After the game result is given to the game control section 81, the game result is displayed on the screen member 30 from the projector 35. Note that the position of the target mark on the screen member 30 and the coordinate position corresponding to the target mark detected by the coordinate position detection unit 84 are adjusted so as to coincide with both positions.

Next, the operation of the shooting game machine according to the present embodiment configured as described above will be described.

At the start of the game, the compressor 71
Is set to a predetermined value. Accordingly, the pseudo-gun 10 can be supplied with the bullet 20. In addition, each electric operating part is also in a predetermined standby state.

In this state, when a predetermined coin is inserted into the coin insertion unit 6, the control system 80 starts controlling the start of the game. Accordingly, the target display control unit 82
The projector 35 projects an image for selection on the screen member 30, and the game player operates the operation unit 5 while viewing the image to select a course, and selects a game image included in the selected course.

Thereafter, a substantial game starts, and the selected game image is projected from the projector 35 onto the screen member 30. The bullet 20 is fired from the pseudo gun 10 toward a target provided in the game image on the screen member 30. At this time, the pseudo gun 10 has the following operation.

First, the light emitted from the LED 19 of the simulated gun 10 is detected by the safety sensor 23, and the two types of frequencies f1 and f2, which are the light emission states, are detected by the safety sensor 2.
3, the upper end 22 of the solenoid 22
a remains in the step portion 24a of the lock member 24, the state in which the trigger 11 cannot be pulled is maintained, and safety is ensured. On the other hand, the safety sensor 23 detects the light emitted from the LED 19 of the pseudo gun 10 and
When two types of frequencies f1 and f2 are detected, the solenoid 2
The upper end 22a of the lock member 24 is disengaged from the step portion 24a of the lock member 24, and the trigger 11 can be pulled. In addition,
Although the advance / retreat direction of the solenoid 22 is set to the vertical direction, the advance / retreat direction of the solenoid 22 is set to the direction along the barrel, so that the trigger is locked when the solenoid 22 advances and the trigger can be triggered when the solenoid 22 retreats. It may be. In this case, it is preferable that the distance between the advance and retreat of the solenoid 22 be longer than the stroke of the trigger.

Next, there is an effect that the bullets 20 can be reliably fired one by one. FIG. 18 is a diagram for explaining this.

FIG. 18A shows a state in which the trigger has not been triggered as described above, FIG. 18B shows a state in which the trigger has been slightly pulled, FIG. 18C shows a state in which the trigger has been further pulled, and FIG. It is in the state where it was pulled out.

In the state of FIG. 18A where the trigger is not pulled, the rear end of the elastic partitioning member 15 opens the air pipe 13c fully as described above, while the rear end of the elastic pressing member 14 Is pressed downward.

When the trigger 11 is pulled, the state shown in FIG.
And (c), the elastic pressing member 14
The bullet partition portion 15 has a bullet 20 supplied into the barrel 12 and a bullet 20 to be supplied next against the force of pressing the bullet downward.
And between. Then, as shown in FIG. 18 (d), when the trigger 11 is pulled, the bullet partition 15 is
The bullet 20 supplied into the barrel and the bullet 20 supplied next are completely separated, while the elastic pressing member 14 releases the pressed state of the bullet 20 supplied into the barrel 12. At substantially the same time, when the trigger 11 is pulled, the solenoid valve 77 switches and the bullet 20 is fired by the air sent through the bullet firing air pipe 13a. Therefore, it becomes possible to fire the bullets 20 one by one from the pseudo gun 10 in this manner. After the trigger 11 is completely pulled out, the trigger 11 returns to the original position by the coil spring 15 which presses and urges the trigger 11 in a direction opposite to the pulling direction. The electromagnetic valve 77 switches to the original state after a certain period of time. The muzzle 12
When a is tilted downward, the safety sensor 23 does not catch the light from the LED 19, so that the solenoid 22 is locked and the trigger 11 does not operate, whereby the bullet 20 is pressed by the elastic pressing member 14. Therefore, bullet 2 from muzzle 12a
0 is prevented from spilling.

The bullet 20 contains a luminous agent,
The light from the flash 18 illuminates the bullet, so that the shining bullet 20 is fired from the pseudo gun 10. Therefore, when the bullet 20 passes through the dimly lit area of the housing 2, the bullet is visually recognized by the game player in a state where the trajectory of the bullet 20 is known. Thereafter, the light emitting state gradually decreases, and after that, the light storing state of the bullet 20 is eliminated and the bullet 20 becomes dark. Further, air passing through the reaction unit driving air piping 13b branched from the bullet firing air piping 13a is sent to the reaction unit 16 and the weight 1 of the reaction unit 16 is reduced.
The reaction due to the collision of 6d is transmitted to the game player.

When the bullet 20 from the simulated gun 10 is fired toward the screen member 30, the coordinate position detecting unit 84 detects the coordinate position, and the game score judging unit 85 determines the projected image on the screen member 30. The position of the target (or the target mark) is compared with the coordinate position detected by the coordinate position detection unit 84, and it is determined whether or not the two match, and how many bullets hit the target is determined. Alternatively, a predetermined score is obtained for the target hit by the bullet. This is performed each time the bullet 20 is fired toward the screen member 30, and the game score determination unit 85 obtains the game score by summing up the points.

The bullet 20 hitting the screen member 30 is
It adheres to the gel-like surface layer 31a of the topsheet 31 constituting the screen member 30. At this time, the portion of the top sheet 31 hit by the bullet 20 is deformed and the electrode 32b and the electrode 33 are deformed.
b contacts. Thus, the coordinate position is detected by the coordinate position detection unit 84. In addition, the gel-like surface layer 31
The bullets 20 attached to the surface layer 31 return to the original flat state from the state in which the topsheet 31 is bent, and the gel surface layer 31
The contact area between a and the bullet 20 decreases, and eventually, the bullet 20 falls from the gel-like surface layer 31a. At the time of this drop, the bullet 20 is in the original non-light storage state. For example, the time during which the bullet 20 accumulates and shines is about 1 second, and the time until the bullet 20 is fired from the pseudo gun 10 and reaches the screen member 30 is the time from the pseudo gun 10 to the screen member 30. The distance is about 0.1 second when the distance is 5 m, and the time required for the bullet 20 to fall after adhering to the screen member 30 is about 3 to 10 seconds.

The dropped bullets 20 are collected by the bullet collecting section 44 of the bullet storing means 40 and are temporarily stored in the bullet storing section 45.
Then, when the next coin is inserted into the coin insertion unit 6,
The game control unit 81 activates the lifting / lowering means 44e to raise the dam 44c, and moves the stored bullets 20 into the falling holes 44d.
And drop it into the box 45a. This drop timing may be any time, before or after the game, or during the game. The electric motor 49 has started to operate with the rise of the weir portion 44c, and the rotating disk 48 is rotated by the electric motor 49,
The bullets 20 inserted between the rotating disk 48 and the bullet separation plate 50 enter the supply pipe 46 one by one from the through holes 45d of the rotating disk 48. Therefore, the bullets 20 are supplied one by one from the bullet storage section 45 to the pseudo gun 10 via the supply pipe 46 by the air from the air supply pipe 47, and are fired from the pseudo gun 10. In addition,
When supplying the bullet 20 to the gun 10 via the supply pipe 46,
The weir portion 44c is lowered by the lifting / lowering means 44e, and
4d is closed so that air does not leak from the drop hole 44d.

In the bullet collecting mechanism provided in the shooting game machine 1 of the present embodiment configured as described above, a large number of bullets 20 stored in the box 45a are moved below the bullet separation plate 50 by the rotating disk 48. When one bullet 20 stays under the bullet separation plate 50 and passes through a bullet passage hole 48a provided in the rotary disk 48 below the bullet separation plate 50, the bullet stays. Since one of the bullets 20 falls through the bullet passage hole 48a, the bullets 20 can be reliably separated. Also, since only one bullet 20 can stay under the bullet separation plate 50, a plurality of bullets 20 do not block the entrance of the bullet passage hole 48a.

Further, the bullet storing means 40 having the above-mentioned function is provided.
The floor surface 2f and the inclined floor 2d as guide means provided on the upstream side discharge the bullets 20 from a gap 2g large enough to allow a large number of bullets 20 to enter each other. Since a plurality of bullets 20 are sent at once instead of sending the bullets 20 one by one to the downstream side, no jamming occurs. When the drop hole 44d is closed by the dam portion 44c, the bullet 20 can be blocked. When the drop hole 44d is opened by the dam portion 44c, the blocked bullet 20 can be discharged. In addition, the bullet passage hole 48a
Can be supplied one by one to the pseudo-gun 10 by air through the through-hole 45d. Further, the bullet 20 is simulated by the pseudo gun 1 with air supplied into the box 45a.
When the air is sent to 0, since the drop hole 44d is closed by the weir portion 44c, the air can be used only for feeding the pseudo gun 10 to the air, preventing air leakage and enabling effective use of the air.

In the above embodiment, the gun 1
Although one “0” is provided, the present invention is not limited to this, and a configuration may be used in which two or more “0” s are provided so that a plurality of game players can play simultaneously. In this case, two or more sets of the screen member 30 and the projector 35 may be provided, or the projector 35 may display two or more images on one screen member 30.

In the above-described embodiment, the air piping 13a for firing and the air piping 13 for driving the reaction unit are used.
b, the solenoid valve is arranged at a position before the branch,
The switching of the solenoid valves supplies and stops air at the same pressure to both pipes 13a and 13b, but the present invention is not limited to this. For example, both pipes 13a,
At the position after the branch of 13b, a separate electromagnetic valve is provided for each of the pipes 13a and 13b, so that the switching operation of each electromagnetic valve is made independent and the air supply / stop timing is made different. Good. In addition, both pipes 13a, 13
b may be completely separated and the pressure of the air may be changed.

In the above-described embodiment, the weir 4
4c is lifted and lowered to close or open the drop hole 44d, but the weir 44c is slid horizontally to drop the drop hole 44d.
d may be closed or opened.

In the above-described embodiment, the bullet 2
Although a spherical shape is used as 0, the present invention is not limited to this, and an oval shape or the like can be used as long as it can collect bullets and supply bullets to the gun without any trouble.

Further, in the above-described embodiment, the supply of bullets and the operation of the firing and reaction units are performed by using air. However, the present invention is not limited to this, and the present invention is not limited to this. it can.

In the above-described embodiment, the rotating disk 48 having the bullet passage hole 48a and the bullet separation plate 50
Although the means for preventing clogging is configured, the present invention is not limited to this, and a method of vibrating the box or a method of stirring the bullets in the box may be used. As the former method,
A configuration in which a box is placed on a vibrating plate material, or a configuration in which a box is gripped by a gripping member having a function of vibrating to apply vibration is applicable. On the other hand, the latter method corresponds to a configuration in which a rotating wing or the like is installed inside a box.

Further, in the above-described embodiment, the rear end of the third barrel member 12C constituting the barrel is used as a bullet partition. However, the third barrel member 12C is not slightly shortened. A configuration may be adopted in which a bullet partition plate separate from the three barrel member 12C is attached. In the case of such a configuration, a separate bullet partition plate may be connected to the trigger, and may be slid along with the triggering operation. In addition, the elastic pressing member 14 may be connected to a separate elastic partition plate or a trigger. In addition, a solenoid or the like that moves in and out of the bullet partition position without being connected to the trigger 11 is provided, and when the position where the trigger 11 is pulled reaches a predetermined position, a signal is generated by a separately provided position sensor to activate the solenoid or the like. It is also possible to adopt a configuration in which it is advanced to perform bullet partitioning.

In the above-described embodiment, the screen member 30 has a configuration in which three sheets 31, 32, and 33 are bonded. However, the present invention is not limited to this, and the front-side sheet 31 is omitted. A configuration in which the two sheets 32 and 33 on the rear side are bonded together and a gel-like surface layer 31a is formed on the front side of the sheet 32 may be adopted.

In the above embodiment, the electrodes 32b and 33b formed on the two sheets 32 and 33, respectively, are used.
Spacers for separating the two sheets 32, 33
However, the present invention is not limited to this, and may be formed only on one of the two sheets 32 and 33. In the above-described embodiment, the spacers are formed in a line shape on each of the two sheets 32 and 33. However, the present invention is not limited to this, and as shown in FIG.
Spacers 32c, 33c may be formed intermittently on each of the sheets 32, 33, and the two sheets 32, 33 may be bonded together with the other spacer 33c inserted between the spacers 32c, as shown in FIG. So, both sheets 3
Intermittent spacers 32c may be formed on the sheet 32 in the illustrated example. However, both sheets 32, 3
In the case where a spacer is formed on one of the sheets 3, both sheets 32,
In the case where the spacers are formed on both of the members 33, when the bullet 20 is fired from the pseudo gun, the coordinates at which the bullet hits can be specified, and at other times, the thickness and the like are set so that the electrodes 32b and 33b can be separated from each other. Is adjusted.

[0093]

As described in detail above, claim 1 of the present invention
Is a bullet collection mechanism in a shooting game machine that shoots bullets from a pseudo-gun at a target provided in front of the bullet, and stores a large number of bullets fired from the pseudo-gun and functions as an outlet 1 Since there is provided a box having a through hole of the size of an individual, and a clogging prevention means attached to the box and preventing clogging at the entrance of the through hole, bullets are likely to be clogged at the entrance of the through hole. Even so, the clogging prevention means can prevent clogging.

According to the second aspect of the present invention, the means for preventing clogging of a bullet includes a rotating rotary disc provided at a lower portion inside the box, and a size capable of passing one bullet through the rotating disc. One or two or more bullet passage holes provided in the
A bullet separation plate provided above the moving area of the bullet passage hole and above the through-hole so that one bullet is inserted under the bullet passage hole, and rotates a large number of bullets stored in the bullet storage means; A large number of bullets stored in the box are rotated by the rotating disk to guide them under the bullet separation plate and pass through the bullet passage holes to give bullets one by one to the through hole. When one bullet stays under the bullet separation plate and the bullet passage hole provided in the rotating disk passes below the bullet separation plate, the one Since the bullet falls through the bullet passage hole, it is possible to reliably prevent clogging of the bullet. In addition, since only one bullet can stay under the bullet separation plate, it is possible to prevent a plurality of bullets from clogging the entrance of the bullet passage hole.

Further, according to the third aspect of the present invention, there is provided a bullet storage means comprising the above-mentioned bullet clogging prevention means and a box,
A guide provided upstream of the bullet storage means and having a size large enough to allow a large number of bullets to enter at the same time, receiving a bullet fired from a pseudo-gun and guiding it to the gap for dropping; Is disposed below, and collects and blocks the bullets dropped from the gap, and simultaneously blocks the bullets blocked from the drop hole provided below the blocking position at a predetermined timing with the box of the bullet storage means. Since the configuration further includes a bullet collecting means for discharging the bullets, the guide means provided on the upstream side of the bullet storing means having the above-described action discharges bullets from a gap large enough to allow a large number of bullets to enter simultaneously, Also in the bullet collecting means, a plurality of bullets are sent at once instead of sending them one by one to the downstream side, so that clogging can be prevented.

Further, according to the invention of claim 4, the bullet collecting means comprises a weir for collecting and blocking a bullet dropped from the gap of the guide means, and a drop hole provided on the downstream side of the weir. And a moving means for moving the weir to open and close the drop hole, and when the moving means moves the weir to open the drop hole, the bullet that has been blocked flows from the drop hole, and the moving means closes the weir. When the drop hole is closed by moving, the bullets are blocked. Therefore, when the drop holes are closed by the weir, the bullets can be blocked. When the drop holes are opened by the weir, the blocked bullets can be discharged.

According to the fifth aspect of the present invention, gas is supplied to the inside of the box, and a through hole is provided on the bottom surface of the box below the passage area of the bullet hole of the rotating disk. , Via a supply pipe arranged between the through hole and the pseudo gun,
Since the configuration is such that the bullets that have passed through the bullet passage holes and the through holes are supplied to the pseudo-gun by gas, the bullets that have passed through the bullet passage holes can be supplied one by one to the pseudo-gun by gas through the through holes.

According to the invention of claim 6, when the bullet is supplied to the pseudo-gun by gas through the supply pipe, the moving means moves the weir to close the drop hole. Therefore, when sending ammunition to the pseudo-gun with the gas supplied in the box, since the weir blocks the drop hole, it can be used only for sending the gas to the pseudo-gun, preventing gas leakage and preventing gas leakage. Can be used effectively.

[Brief description of the drawings]

FIG. 1 is a front sectional view showing a shooting game machine to which the present embodiment is applied.

FIG. 2 is a left side view showing a shooting game machine to which the embodiment is applied.

FIG. 3 is a front sectional view showing a bullet storing means provided in a shooting game machine to which the embodiment is applied.

FIG. 4 is a plan view of the bullet storage means of FIG. 3 as viewed obliquely from above.

FIG. 5 is a plan sectional view showing the inside of a box of bullet storage means provided in a shooting game machine to which the present embodiment is applied.

FIG. 6 is a front sectional view showing a structure of a pseudo gun provided in a shooting game machine to which the present embodiment is applied.

FIG. 7A is a front view showing a third barrel member constituting a pseudo gun provided in a shooting game machine to which the present embodiment is applied,
(B) is a plan view thereof.

FIG. 8A is a front view showing an elastic pressing member constituting a pseudo gun provided in a shooting game machine to which the present embodiment is applied,
(B) is a plan view thereof, and (c) is a right side view thereof.

FIG. 9A is a front view showing a trigger constituting a pseudo-gun provided in a shooting game machine to which the present embodiment is applied, and FIG.
Is a right side view thereof, and (c) is a plan view thereof.

FIG. 10 is a front sectional view showing the vicinity of a solenoid constituting a pseudo gun provided in a shooting game machine to which the present embodiment is applied.

FIG. 11 is a diagram showing pulses for causing LEDs included in a pseudo gun provided in a shooting game machine to which the present embodiment is applied to emit light.

FIG. 12 is a block diagram showing an air supply system provided in a shooting game machine to which the present embodiment is applied.

FIG. 13 is a front sectional view showing a recoil unit constituting a pseudo gun provided in a shooting game machine to which the present embodiment is applied.

14A is an exploded front view showing a configuration of a screen member provided as a target provided in a shooting game machine to which the present embodiment is applied, and FIG. 14B is a perspective view showing a partially bonded state. .

FIG. 15A is a front view of one of two sheets having electrodes among screen members provided in a shooting game machine to which the present embodiment is applied, viewed from the electrode side, and FIG.
Is a front view of the other viewed from the electrode side.

FIG. 16 is an explanatory view of a mechanism provided in a shooting game machine to which the present embodiment is applied and capable of detecting a position at which a bullet hits a screen member.

FIG. 17 is a block diagram showing a control system provided in a shooting game machine to which the present embodiment is applied.

FIGS. 18 (a) to (d) are explanatory views (front sectional views) of an operation in which a pseudo gun provided in a shooting game machine to which the present embodiment is applied can surely fire bullets one by one;
It is.

FIG. 19A is a front view of one of two screens having electrodes among other screen members provided in a shooting game machine to which the present embodiment is applied, viewed from the electrode side, and FIG. It is the front view seen from the side.

FIG. 20A is a front view of one of two screens having electrodes among other screen members provided in a shooting game machine to which the present embodiment is applied, viewed from the electrode side, and FIG. It is the front view seen from the electrode side.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Shooting game machine 2 Case 10 Pseudo-gun 12i Bullet partition 13a Bullet firing air piping 13b Reaction unit drive air piping 13c Bullet supply air piping 14 Elastic pressing member 20 Bullet 30 Screen member (target) 46 Supply piping

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Eita Kada 7-3-3 Minatojima Nakamachi, Chuo-ku, Kobe Inside (72) Inventor Satoshi Uchiyama 7-3-2 Minatojimanakamachi, Chuo-ku, Kobe Konami Co., Ltd. F-term (reference) 2C014 PP02

Claims (6)

[Claims] 1. A bullet collecting mechanism in a shooting game machine for firing a bullet from a pseudo-gun at a target provided in front thereof, wherein the bullet 1 stores a large number of bullets fired from the pseudo-gun and functions as an outlet. A box having a through hole having a size corresponding to the number of pieces, and a bullet collecting mechanism for a shooting game machine, comprising: a box attached to the box, for preventing a bullet from being clogged at an entrance of the through hole. . 2. The means for preventing ammunition from being clogged includes: a rotating rotating disk provided at a lower portion inside the box; and one or two or more rotating disks provided with a size capable of passing one bullet on the rotating disk. A bullet-passing hole, and a bullet separation plate provided above the through-hole in a moving area of the bullet-passing hole and in a state where one bullet enters under the bullet-passing hole; 2. The structure according to claim 1, wherein the bullets are rotated by a rotating disk, guided under a bullet separation plate, and passed through a bullet passage hole to give bullets one by one to a through hole. Bullet collection mechanism in shooting game machine. 3. A bullet storage means comprising said bullet clogging prevention means and a box, provided upstream of said bullet storage means and having a gap large enough for a large number of bullets to enter each other. Guide means for receiving a bullet fired from a gun and guiding it into the gap to drop it, and disposed below the gap to collect and drop the bullet dropped from the gap and to lower the damming position. 3. A bullet collecting mechanism in a shooting game machine according to claim 2, further comprising: a bullet collecting means for simultaneously discharging a bullet blocked from a drop hole provided to a box of said bullet storing means at a predetermined timing. . 4. The bullet collecting means, comprising: a weir for collecting and blocking a bullet dropped from a gap of the guide means, a drop hole provided on a downstream side of the weir, and a drop hole provided by moving the weir. When the moving means moves the weir to open the drop hole, the arrested bullet flows in from the drop hole, and when the moving means moves the weir to close the drop hole, the bullet The bullet collecting mechanism in the shooting game machine according to claim 3, wherein the bullet is stopped. 5. A gas is supplied to the inside of the box, and a through hole is provided on the bottom surface of the box below the passage area of the bullet passage hole of the rotating disk, and between the through hole and the pseudo gun. 5. A bullet collecting mechanism in a shooting game machine according to claim 4, wherein a bullet passing through the bullet passage hole and the through hole is supplied to the pseudo-gun by gas through the supply pipe provided. . 6. The method according to claim 4, wherein when the bullet is supplied to the pseudo-gun by gas through the supply pipe, the moving means moves the weir to close the drop hole. Bullet collection mechanism in shooting game machine.