KR100526340B1 - Pachinkogi's Bead Control - Google Patents

Abstract

The present invention relates to a bead controller for controlling the flow of pachinko beads, the bead controller of the pachinkogi of the present invention is a bead passage for passing the pachinko beads in a line, and a claw provided on the outer periphery of the bead passage. A control means including a bead wheel which is located at the same time and rotates by the weight of the pachinko beads passing through the bead passage, a valve member which opens and closes the flow path of the bead passage, and a brake member which locks the bead wheel; And a driving means for activating the control means, arranging the bead stop space for one pachinko bead on the downstream side of the bead wheel with the bead wheel and arranging the valve member therein, and the valve member being connected to the bead path. When in the open position to open the flow path, the brake member locks the bead wheel so that the claw of the bead wheel A flow path for closing the other hand, when the valve member is in the closed position for closing the passage of the ball passage, and characterized in that the brake member is in the unlocking position the rotation of the setting wheel so that free beads.

Description

Pachinkogi's Bead Control

The present invention relates to a bead controller for controlling the flow of pachinko beads.

In the pachinkogi, a bead controller for controlling the flow of the pachinko beads is indispensable. For example, as shown in Fig. 6, the prize opening device 19 for detecting the prize sphere or the loan sphere with a bead plate, and the granules for detecting the prize spheres one by one. As shown in Fig. 5, it is a ball-ball automatic supply device 26 for ejecting pachinko beads from a ball dish to a ball-ball launcher.

In this way, as a conventional bead control device, a bead passage for passing the pachinko beads in a line and a claw installed on the outer periphery are placed in the bead passage, and the pachinko beads passing through the bead passage. There is provided a bead wheel to rotate by the weight of, and the flow of the pachinko bead is controlled by stopping the rotation of the bead wheel by the brake means.

The conventional marble ball controller has a problem that an excessive load is applied to the brake means.

The present invention has been made in view of the above, by placing the pachinko beads in a line through the bead passage and the claws installed on the outer periphery of the bead passage, and by the weight of the pachinko beads passing through the bead passage And a control means comprising a rotating bead wheel, a valve member for opening and closing a flow path of the bead passage, and a brake member for locking the bead wheel, and a driving means for operating the control means. When the bead wheel is provided downstream from the bead wheel, a bead stopping space for one pachinko bead is provided between the bead wheel and the valve member is disposed therein, and when the valve member is in an open position to open the flow path of the bead passage, the brake The member locks the bead and the claw of the bead closes the flow path of the bead, while the valve member closes the flow path of the bead. When in the closed position, there is provided a control apparatus of a pachinko ball machine the brake member is in the unlocked (unlock) positioning the rotation of the wheel so that free beads.

In the normal state, as shown in Fig. 4A, the valve member is in the closed position to close the flow path of the bead passage, and at the same time, the brake member is freed to rotate the bead wheel in the unlocked position. In this state, when the pachinko beads flow through the bead channel, the first pachinko beads rotate the bead wheels as shown in Fig. 4 (b), so that they touch the valve member and stop at the bead stop space, and the next pachinko beads touch the claw of the bead wheel. Stops.

Next, when the control means is operated by the drive means, as shown in Fig. 4 (c) the valve member opens the bead passage while the brake member locks the bead wheel. Therefore, the pachinko beads in the bead stopping space flow, but the pachinko beads touching the claw of the bead do not move as they are. Subsequently, when the control means is operated again, the valve member returns to the closed position which closes the flow path of the bead passage, the brake member returns to the unlocked position, and the rotation of the bead wheel is freed. Pachinko beads that were stopped by the flow and stops in the bead stop space between the valve member and the bead wheel as shown in Figure 4 (b). Thereafter, the above operation is repeated to discharge one pachinko beads one by one.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment of this invention is described, referring drawings. 1 is a perspective view of a bead control device, FIG. 2 is a front view of a bead control device, FIG. 3 is a longitudinal sectional view of a bead control device, and FIGS. 5 is a front view of the pachinkogi, and FIG. 6 is a rear view of the pachinkogi.

The bead controller 1 is similar to the bead passage 3 provided between the two substrates 2a and 2b facing each other at intervals of one pachinko beads and the bead passages 3 provided between the substrates 2a and 2b. A bead wheel 4 disposed between 2a and 2b, a solenoid 5 serving as a driving means provided on an outer substrate 2a, and a plunger 6 of the solenoid 5 attached thereto. It consists roughly by the control means 7 mentioned later.

The bead passage 3 is an area through which one pachinko beads can pass, and is generally roughly formed by an inlet passage 3a having a downward slope, a vertical bead disconnect passage 3b, and a discharge passage 3c having a downward slope. It is bent in a "ku" shape. In addition, the discharge passage 3c is formed by protruding the inner surfaces of the substrates 2a and 2b into a rail shape and has no bottom, but of course the pachinko beads do not fall.

Next, the bead wheel 4 has a plurality of (four in the embodiment) claws 4a, 4a... On the outer circumference, having a diameter substantially equal to the diameter of the pachinko beads between the claws 4a. It is formed as an arc having a, it is attached between the substrates (2a, 2b) to be rotated by the shaft (8) at the boundary between the bead passage (3) of the bead passage (3) and the discharge passage (3c) do. The bead wheel 4 is in the state where the claw 4a enters and exits the bead disconnect passage 3b and the discharge passage 3c at this attachment position, and receives the weight of the pachinko beads passing through the bead passage 3. It can rotate like aberrations.

Next, the solenoid 5 forms a mounting table 9 on the outer substrate 2a, inserts the mounting plate 10 into the mounting table 9, and inserts and screws the positioning boss 11a. It is attached by the fastening of 11b. The solenoid 5 has a plunger 6 pushed downward by the spring 12, and the plunger 6 is pulled only while electricity flows to the solenoid 5.

Next, the control means 7 is integrally attached to the lower end of the plunger 6 of the solenoid 5, the valve member 7a for opening and closing the flow path of the bead passage 3 and the bead wheel 4 ) Is formed by integrally mounting the brake member 7b that locks)) from the outside of the substrate 2a toward the substrate 2b side. The valve member 7a is disposed in the bead passage 3 through the window hole 13 of the substrate 2a in the form of a plate, and opens the flow path of the discharge passage 3c in a state where the plunger 6 is lowered. On the contrary, the flow path of the discharge passage 3c is opened while the plunger 6 is raised. The valve member 7a is located downstream from the bead wheel 4, and a bead stopping space 14 for one pachinko ball is provided between the bead wheel 4.

Moreover, the brake member 7b is located under the bead wheel 4 covering the lower side of the board | substrate 2a in the form of a square material, and is engaged with the claw 4a in the state which the plunger 6 raised. The bead wheel 4 is locked, and on the contrary, the bead wheel 4 is released from the claw 4a while the plunger 6 is lowered.

In addition, as shown in FIG. 2, a stopper 15 is provided on the substrate 2a so as to face the control means 7, and the bottom surface of the control means 7 contacts the stopper 15 so that the plunger is in contact with the control means 7. (6) the descent stops.

Further, between the substrate 2a and the control means 7, a rotation stop means 16 for regulating the rotational movement about the axis of the plunger 6 is formed. That is, the taper surface 7c is formed on one side of the control means 7, while the substrate 2a is in contact with the tapered surface 17a mating with the taper surface 7c of the control means 7. Protrude the plate (17). The tapered surface 7c of the control means 7 and the tapered surface 17a of the contact plate 17 are matched only at the position where the control means 7 is completely lowered, and the tapered surfaces 7c and 17a are matched with each other. The rotational movement about the axis of the plunger 6 is regulated, and as a result, the positioning of the valve member 7a is corrected so that the size of the ball stop space 14 is always kept constant. On the other hand, in the case where the control means 7 moves up and down to block the pachinko beads as described later, the tapered surface 7c of the control means 7 is moved from the tapered surface 17a of the contact plate 17. The plunger 6 moves about an axis while falling, but in order to perform the beading operation of the pachinko beads, a rotational movement about the axis of the plunger 6, that is, the movement about the vertical axis of the control means 7. The valve member 7a or the brake member 7b has a moderate degree of margin (particularly, the horizontal direction of the valve member 7a), which contributes to the smooth operation of a series of operations. In addition, the adhesion preventing means 70 is provided between the tapered surfaces 7c and 17a to prevent the adhesion between the surfaces. The close contact preventing means 70 shown is a projection provided on the tapered surface 7c, but since the tapered surfaces 7c and 17a are easily dropped by the close contact preventing means 70, the movement of the control means 7 is smooth. Become.

In Figs. 4A to 4C, reference numeral 18 denotes a bead sensor provided at the bottom of the bead stop space 14, and the bead sensor 18 detects the pachinko beads. Of course, the bead sensor 18 is not limited to this place, but may be installed in any place of the bead passage 3, or the bead sensor on the side of the pachinkogi P may be used. In addition, the kind of the bead sensor 18 can use a proximity switch, a micro switch, a reed switch, an optical switch, etc., for example.

Next, operation | movement of the ball | bowl control apparatus 1 of this invention is demonstrated. First, in the normal state, the plunger 6 is lowered when the solenoid 5 is OFF. Therefore, as shown in Fig. 4A, the valve member 7a is in the closed position to close the flow path of the bead passage 3 (discharge passage 3c), and at the same time the brake member 7b is in the unlocked position. In the rotation of the wheel (4) is free. In this state, when the pachinko beads B1, B2, ... are introduced into the bead channel 3 as shown in FIG. 4 (a), the leading pachinko beads B1 are broken through the bead path ( 3b) and placed in the claw 4a, the pachinko beads B1 rotate the bead wheel 4 as shown in Fig. 4 (b), so they enter the bead stop space 14 and touch the valve member 7a. Stop Subsequent pachinko beads B2... Stop in the state of contacting the claw 4a of the bead wheel 4 as shown in FIG. 4 (b).

Next, when electricity flows through the solenoid 5, the control means 7 rises together with the plunger 6, and the valve member 7a opens the bead passage 3 (discharge passage 3c), At the same time, the brake member 7b touches the claw 4a of the bead wheel 4 to lock the rotation of the bead wheel 4. Therefore, as shown in Fig. 4C, the leading pachinko beads B1 in the bead stopping space 14 flow due to the downward inclination of the discharge passage 3c, but not in the claw 4a of the bead wheel 4; Subsequent pachinko beads (B2) lying down do not stop as it moves.

Next, when the solenoid 5 is turned off and the control means 7 moves back to the original position where the stopper 15 touches, the valve member 7a opens the flow path of the bead passage 3 (discharge passage 3c). Since it returns to the closing position to close, the brake member 7b returns to the unlocked position which falls from the claw 4a, and the rotation of the bead wheel 4 becomes free, so the pachinko which had been set to the claw 4a until then The bead wheel 4 is rotated by the weight of the bead B2, and the pachinko bead B2 is bead stop space 14 between the valve member 7a and the bead wheel 4 as in FIG. Enter and stop. Thereafter, whenever the solenoid 5 is operated once, the operations of FIGS. 4 (b) and 4 (c) are repeated to discharge the pachinko beads one by one into the discharge passage 3c.

Since the bead control device 1 of the present invention is configured as described above, when it is installed on the instrument plate 20 as the premium ball discharge device 19 as shown in FIG. Can emit as many as. In this case, of course, the introduction passage 3a is connected to the lead-out cylinder 21 of the mechanical plate 20, and the discharge passage 3c is connected to the premium port discharge cylinder 22. In addition, the solenoid 5 is operated by the number of times of the giveaway release signal or loan signal, and checks the number of release of the giveaway or loan by the bead sensor 18.

In addition, when the bead control device 1 of the present invention is installed on the mechanical plate 20 as the granular ball processing device 23 as shown in FIG. 6, the granular ball can be accurately detected in one unit. In this case, the introduction passage 3a is connected to the granular opening assembly cylinder 24, and the discharge passage 3c is connected to the granular outlet discharge cylinder 25. In addition, the solenoid 5 operates by a signal from which the bead sensor 18 detects the granular ball, and counts the granular ball by the signal of the bead sensor 18.

In addition, the bead control device 1 of the present invention, as shown in Figure 5 as the automatic ball supply device 26 to support the lower edge of the organic plate (not shown, but the bottom of the front plate 27, When installed on the front of the known parts made by installing the launch rail on the front, it is possible to send the pachinko beads to each shot launching device accurately. In this case, the introduction passage 3a is connected to the upper bead plate 28, and the discharge passage 3c is connected to the launch port supply portion. In addition, the solenoid 5 operates by a signal from which the bead sensor 18 detects pachinko beads.

As mentioned above, although one Embodiment of this invention was described, of course, this invention is not limited to said embodiment. For example, the use of the ball control device 1 of the present invention is not limited to the above-mentioned prize ball discharging device 19, the granular ball processing device 23, and the automatic ball throwing device 26. Further, in the above embodiment, the bead passage 3 is bent into a substantially "u" shape, but as shown in FIG. 7, the bead passage 3 is bent into a substantially crank shape, or although not shown, the introduction passage 3a. And bead disconnect passage (3b) may be to continue in a straight line. In addition, when the introduction passage 3a and the bead disconnect passage 3b are bent and the bead wheel 4 is arranged in the vicinity of the bent portion, the ball pressure of the introduction passage 3a is formed at the bent portion. Dispersed can reduce the burden on the wheel 4 or the control means (7). In addition, although the solenoid 5 was used as a driving means in the said embodiment, other than that, a rotary solenoid, an electric motor, a hydraulic type, or a pneumatic cylinder can also be used.

In addition, the control means 7 is not limited to the structure of the said embodiment. For example, the control means 7 of the above embodiment has a structure in which the valve member 7a and the brake member 7b are integrally operated up and down together, for example, FIGS. 8A and 8. As shown in (b), the valve member 7a and the brake member 7b may be separated and connected to each other by the swing link 7d.

That is, the control means 7 of FIG. 8 (a) and FIG. 8 (b) have a sliding rail 29 which the valve member 7a and the brake member 7b protrude from the inner surface of the substrate 2b. The pins 7e and 7f protruding from the valve member 7a and the brake member 7b are provided in the state of being able to slide up and down loosely in the long holes 7g and 7g of the swinging link 7d. It is fitted. In addition, since the swing link 7d has a central portion attached to the inner surface of the substrate 2b as an axis and the movement is limited to the seesaw operation, when the valve member 7a is raised, the brake member 7b is lowered and the valve When the member 7a is lowered, the brake member 7b is raised.

In the normal state, as shown in Fig. 8 (a), the valve member 7a is in the closed position protruding from the bottom of the bead passage 3 (discharge passage 3c) to close the flow passage, and the brake member 7b. ) Is lowered to the unlocked position and the rotation of the bead wheel (4) is free. In this state, when the pachinko beads B1, B2, ... are introduced into the bead passage 3 as shown in the solid line of Fig. 8 (a), the leading pachinko beads B1 are beaded, as shown by the two-dot chain line of Fig. 8 (a). The wheel 4 is rotated to stop in the bead stop space 14, and the subsequent pachinko beads B2 ... touch the claw 4a of the bead wheel 4 to stop.

Next, when the pin 7f of the brake member 7b is pulled up as shown in Fig. 8 (b) by a driving means such as a solenoid, the valve member 7a is moved through the swinging link 7d. It descends and opens the bead channel | path 3 (discharge path 3c), and the top part of the brake member 7b touches the claw 4a, and locks the rotation of the bead wheel 4. As shown in FIG. Therefore, the leading pachinko beads B1 in the bead stopping space 14 flow by the downward inclination of the discharge passage 3c, and the subsequent pachanco beads B2 lying on the claw 4a of the bead wheel 4 Does not move as it is.

Next, when the driving means is turned off and the brake member 7b is lowered, the valve member 7a is raised to return to the closed position for closing the flow path of the bead passage 3 (the discharge passage 3c), and the brake Since the member 7b returns to the unlocked position falling from the claw 4a and the rotation of the bead wheel 4 is free, the ball wheel is caused by the weight of the pachinko beads B2 placed on the claw 4a. (4) rotates, and the pachinko marble B2 enters into the bead stop space 14 between the valve member 7a and the bead wheel 4 and stops similarly to the pachinko marble B1 of FIG. Thereafter, each time the driving means is operated once, the operations of FIGS. 8 (a) and 8 (b) are repeated to discharge the pachinko beads one by one into the discharge passage 3c.

Moreover, the pin 7f of the brake member 7b is attached so that it can slide with respect to the elongate hole 70b of the brake member 7b, and in the normal state by the spring 71b of the brake member 7b. As shown in Fig. 8A, the pin 7f is pushed to the lower end of the long hole 70b so that the pin 7f and the brake member 7b operate integrally. However, if the pushing pressure acts on the pin 7f even when the top part of the brake member 7b touches the bead wheel 4, the pin 7f is opposed to the pushing of the spring 71b as shown in Fig. 8B. ) Rises along the long hole 70b. Then, when the pin 7f is turned down, the brake member 7b is lowered after the pin 7f touches the lower end of the long hole 70b. This structure is most suitable for adjusting the operation timings of the valve member 7a and the brake member 7b, and, for example, the wheel 4 with the brake member 7b before the valve member 7a opens the flow path. ) Or the operation such as locking the bead wheel 4 with the brake member 7b until the valve member 7a closes the flow path.

By the way, as a means for operating the valve member 7a and the brake member 7b of the control means 7 separately, in addition to the above, the racks 7a and the brake member 7b are respectively provided on opposite surfaces of the valve member 7a and the brake member 7b. rack) A gear may be formed and one pinion gear may be provided in the middle of both rack gears so that the valve member 7a and the brake member 7b may be interlocked by the pinion gear. Of course, also in this case, since the valve member 7a and the brake member 7b are engaged with one pinion gear, the moving direction is reversed.

Since the bead controller of the present invention controls the flow of the pachinko beads by the cooperative action of the bead wheel and the valve member, the brake means for controlling the bead wheel as compared to the conventional apparatus for controlling the flow of the pachinko beads with only the bead wheels. The load on the load can be greatly reduced.

1 is a perspective view of a bead controller.

2 is a front view of the beads control device.

Figure 3 is a longitudinal sectional view of the bead controller.

4 (a) to 4 (c) are cross sectional front views of the principal parts illustrating the operation;

5 is a front view of the pachinkogi.

6 is a rear view of the pachinkogi.

Fig. 7 is a sectional front view of the main portion of a bead controller, showing another embodiment;

8 (a) and 8 (b) are cross-sectional front views of principal parts showing other aspects of the control means.

* Explanation of symbols for main parts of the drawings

P: pachinkogi B1, B2: pachinko beads

1: Bead control device

3: bead passage (3a: introduction passage, 3b: bead disconnect passage, 3c: discharge passage)

4: Bead Wheel 4a: Claw

5: solenoid (driving means) 7: control means

7a: valve member

7b: brake member

Claims (1)

A bead channel through which pachinko beads are lined up, A claw placed on the outer periphery of the bead channel and rotating by the weight of the pachinko beads passing through the bead channel, Control means comprising a valve member for opening and closing a flow path of the bead passage and a brake member for locking the bead wheel; Has driving means for operating the control means, A bead stopping space for one pachinko beads is provided between the bead wheel and the bead wheel downstream, and the valve member is disposed therein, When the valve member is in the open position to open the flow path of the bead passage, the brake member locks the bead wheel so that the claw of the bead wheel closes the flow path of the bead passage, while the valve member opens the flow path of the bead passage. Pachinkogi bead control device, characterized in that the brake member is set to be free to rotate the bead wheel in the unlocked position when in the closed position to close.