JP2004173976A - Ball put-out device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ball put-out device capable of easily controlling the number of game balls to be put out and speedily putting out the game balls. <P>SOLUTION: The ball put-out device 1 has one put-out screw 2, four supply passages 31034, four feeding passages 41-44, and two put-out passages 51 and 52. The ball put-out device 1 is structured to make a game ball 8 move forward on the feeding passages 41-44 by making the thread parts 21 and 22 of the put-out screw 2 abut to the game ball 8 and rotating the put-out screw 2. In the ball put-out device 1, the game balls 8 received in the feeding passages 41-44 from the supply passages 31-34 are put out one by one from different feeding passages 41-44 sequentially to the put-out passages 51 and 52 alternately. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
【Technical field】
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ball dispensing device that sends game balls supplied to a supply passage from a feed passage by rotation of a payout screw and pays out the game balls to the payout passage.
[0002]
[Prior art]
For example, in a pachinko game machine, game balls stored in a storage tank are supplied to a payout screw via a supply passage, and the payout screw rotates the game balls at a predetermined speed for lending or prize balls. A ball dispensing device for dispensing to a dispensing passage which is a passage of the type is known. As such a ball dispensing device, for example, game balls supplied from a pair of left and right supply passages opened on both right and left sides in the cross-sectional direction of the dispensing screw are dispensed to a common dispensing passage by rotation of the dispensing screw. (Patent Document 1).
Further, as such a ball payout device, for example, there is a device that pays out game balls supplied from supply passages formed at a plurality of positions in the axial direction of the payout screw to a common payout passage by rotation of the payout screw ( Patent Document 2).
[0003]
[Patent Document 1]
JP 2001-70571 A (FIG. 4 etc.)
[Patent Document 2]
JP 2001-54659 A (FIG. 7 and the like)
[0004]
[Problem to be solved]
By the way, the game in pachinko gaming machines in recent years has diversified. For example, in an arrangement machine that pays out game balls for prize balls for each game of the game, the payout of the game balls is frequently performed. However, the next game can be played only after the payout of the previous game. Therefore, in the conventional ball payout device described above, the payout speed of the game balls is not sufficient, and there is a possibility that the operating rate of the game may be reduced.
[0005]
The present invention has been made in view of such a conventional problem, and an object of the present invention is to provide a ball payout device which can easily control the number of game balls to be paid out and can pay out game balls at a high speed. It is assumed that.
[0006]
[Means for solving the problem]
According to the present invention, a game ball supplied to the supply passage is received by the supply screw from the supply passage into the feed passage by the rotation of the supply screw having a rotation axis substantially in the horizontal direction, and is advanced on the feed passage to be guided to the payout passage for payment. In the ball dispensing device,
The dispensing screw has a thread portion spirally disposed on the outer periphery thereof, and the thread portion is rotated in contact with the game ball to advance the game ball on the feed passage. Is composed of
The supply passage comprises a pair of right and left two pairs of left and right sides which are opened from both left and right side surfaces of the screw portion in the transverse cross-sectional direction of the dispensing screw through the screw portion and face each other. It has multiple sets in the axial direction of the screw,
The feed passage is formed to extend in the axial direction of the discharge screw, and a plurality of feed passages are formed to connect the supply passages to the discharge passage.
Each of the game balls received from each of the supply passages into each of the feed passages is paid out one by one from the different feed passages to the payout passage one by one by rotation of the payout screw. Ball dispensing device (claim 1).
[0007]
In the ball dispensing device of the present invention, the supply passage is formed not only as a pair of left and right sides on both left and right sides of the thread portion in the cross-sectional direction of the dispensing screw, but also in the axial direction of the dispensing screw. Also, a plurality of sets are formed. Therefore, the supply of the game balls is performed from at least four or more supply passages for one payout screw. Further, each game ball advances on each feed passage corresponding to each supply passage by the rotation of one payout screw, and is paid out to the payout passage.
Therefore, the number of game balls to be paid out per unit time can be increased by the one payout screw.
[0008]
In addition, the timing at which each game ball is received on each feed passage is shifted by the rotation of the one payout screw, and the timing at which each game ball that advances in each feed passage starts to advance is shifted. Then, by controlling the rotation of the one payout screw, each game ball advancing in each feed path is sequentially paid out from the different feed paths one by one to the payout path.
[0009]
Therefore, by controlling the rotation of the one payout screw, the number of game balls to be paid out can be easily controlled.
Therefore, according to the ball payout device of the present invention, it is possible to easily control the number of game balls to be paid out and to pay out the game balls at high speed.
[0010]
Further, for example, if the ball payout device is used in an arrangement machine of a pachinko game machine that pays out game balls for prize balls for each game of the game, a sufficient payout speed of the game balls can be secured.
The forward direction in the feed passage refers to a direction in which the game balls are sent toward the payout passage (the same applies hereinafter).
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a preferred embodiment of the above-described ball dispensing apparatus of the present invention will be described.
The ball payout device can be used for a pachinko game machine. The payout paths include, for example, payout paths for lending a ball, winning a ball, or removing a ball.
In addition, the payout passage for the ball rental refers to a passage for paying out a number of game balls according to the price paid, and the payout passage for the prize ball refers to a number of game balls corresponding to a winning value. A passage for paying out. In addition, the payout passage for removing balls refers to the supply passage and a passage for extracting game balls from a storage tank for supplying the game balls to the supply passage.
[0012]
Further, the thread portion is formed as a first thread portion and a second thread portion at two locations in the axial direction of the dispensing screw, and the supply passages are formed on the right side surface of the first thread portion. , A second supply passage located on the right side of the second thread portion, a third supply passage located on the left side of the first thread portion, and a left side of the second thread portion. The fourth supply passage is formed at four locations as a fourth supply passage located on the surface, and the feed passage includes a first feed passage communicating with the first supply passage, a second feed passage communicating with the second supply passage, and the fourth supply passage. It is preferable that the third feed passage communicating with the third supply passage and the fourth feed passage communicating with the fourth supply passage are formed at four positions (claim 2).
[0013]
In the ball payout device, it is conceivable that the number of game balls that can be paid out per unit time can be increased as the number of the supply passages and the feed passages is increased. However, on the other hand, if the number of game balls to be paid out simultaneously by one payout screw increases too much, the load applied to the payout screw increases. Then, the controllability of the dispensing screw may be deteriorated, or it may be difficult to select a motor to be used for the dispensing screw.
[0014]
Therefore, as described above, when four supply paths and feed paths are provided for one payout screw, the number of game balls that can be paid out per unit time and the controllability of the payout screw are excellent. In addition, a ball dispensing device that balances these can be configured.
[0015]
Further, the first screw portion and the second screw portion have helical directions opposite to each other, and the payout passage is a junction between the first feed passage and the second feed passage. It is preferable that the first discharge passage is formed at two places as a second discharge passage formed at the junction of the third feed passage and the fourth feed passage (claim 3).
[0016]
In this case, the game balls received in the first feed passage or the second feed passage can be paid out in common with the first payout passage, and the third feed passage or the fourth feed passage can be paid out. Can be paid out in common to the second payout passage. Therefore, the number of the payout passages can be reduced, and a compact ball payout device can be formed.
[0017]
Further, since the number of the payout passages is two, it is easy to combine these payout passages into one. Therefore, the game balls that have been paid out from the respective payout paths can easily merge.
Further, by reducing the number of the payout passages, it is possible to reduce the number of payout detection sensors described later.
[0018]
The first payout passage and the second payout passage are each provided with a payout detection sensor for detecting the payout of the game ball, and the payout detection sensor causes the first feed passage or the second feed passage. It is preferable to be configured to be able to alternately detect the payout to the first payout passage and the payout to the second payout passage from the third feed passage or the fourth feed passage (claim 4). .
[0019]
In this case, the ball payout device, after paying out one game ball from either the first feed path or the second feed path to the first payout path, sets the third feed path or the second feed path. One game ball is paid out from one of the four feed passages to the second payout passage, and then the first payout is made from the first feed passage or the second feed passage that has not been paid out immediately before. A game in which one game ball is paid out to a passage, and one game ball is paid out to the second payout passage from a passage in which the payout is not performed immediately before in the third feed passage or the fourth feed passage. A configuration in which a cycle of paying out balls alternately may be repeated.
[0020]
A payout detection sensor provided in the first payout passage detects one game ball paid out from either the first feed passage or the second feed passage, and detects the game ball discharged from the third feed passage or the fourth feed passage. A passage in which the payout is not performed in the first feed passage or the second feed passage after a lapse of time for one payout detection sensor provided in the second payout passage to detect one game ball paid out from any of the passages. One game ball paid out from is detected.
[0021]
Therefore, the payout detection sensor provided in the first payout passage can detect the next game ball at a predetermined interval after detecting one game ball, and the payout detection sensor can detect one game ball. The time for detecting the payout of the ball can be increased. Therefore, the detection accuracy of the game ball by the payout detection sensor can be improved.
Further, the above operation and effect are the same for the payout detection sensor provided in the second payout passage.
[0022]
In each of the feed passages, the ball center of each game ball arranged on each of the feed passages is located at a height position equal to the axial center of the payout screw or below the axial center of the payout screw. It is preferable to be configured as described above (claim 5).
In this case, it is possible to prevent the pressure due to the weight of the game balls supplied to each supply passage from directly acting on the payout screw from above. Thereby, it is possible to suppress the unreasonable load from being applied to the payout screw by the game balls.
[0023]
Further, the four supply passages and the feed passages are formed in the ball payout device, and the ball centers of the game balls arranged on the respective feed passages are located below the axial center of the payout screw. In this case, the payout screw is formed by an imaginary line connecting the ball centers of the game balls arranged on two feed passages provided on a pair of left and right sides in the cross-sectional direction of the payout screw and the axial center of the payout screw. Preferably, the angle is approximately 90 °.
[0024]
In this case, each time the payout screw rotates by about 90 °, a ball payout device that pays out game balls one by one from each of the feed passages to the payout passage at substantially equal time intervals can be configured. Therefore, it is easy to detect the game ball by the payout detection sensor, and the detection accuracy can be further improved.
Further, the same effect is obtained even when the angle formed by the imaginary line connecting the ball center of each of the game balls arranged on the two feed passages and the shaft center of the payout screw is 85 to 95 °. Is obtained.
[0025]
Further, when the four supply passages and the feed passages are formed in the ball payout device, each supply passage extends from a ball center of a game ball disposed on each feed passage to a release point of the payout passage. Is preferably about ／ of the pitch of the first thread portion and the second thread portion of the dispensing screw.
[0026]
In this case, the one payout screw does not simultaneously advance four or more game balls into the valleys formed between the threads in each of the thread portions. Therefore, the load applied to the payout screw can be reduced, and the game ball can be paid out at high speed.
[0027]
Note that the distance from the center of the game balls arranged on each of the feed passages to the release point of the payout passage from each of the supply passages, that is, the distance that the game balls advance through each of the feed passages should be as short as possible. Accordingly, the ball dispensing device can be formed compact. On the other hand, if the distance by which the game ball advances in each of the feed passages is too short, the game ball may unintentionally flow down to the payout passage due to vibration or the like, which hinders stable payout of the game ball. May cause damage.
From this point of view, as described above, the distance that the game ball advances in each of the feed passages is approximately 3/4 of the pitch in the first thread portion and the second thread portion of the payout screw. Preferably, there is.
[0028]
The pitch is an amount by which the game ball is advanced when the payout screw makes one rotation, and refers to a distance between the threads in each thread portion (the same applies hereinafter). The release point refers to a position where a game ball that has advanced in the feed passage flows down toward the payout passage (the same applies hereinafter).
[0029]
Further, when the four supply passages and the feed passages are formed in the ball dispensing device, the first thread portion and the second thread portion of the dispensing screw are constituted by one thread. Is preferred.
In this case, it becomes easy to configure the ball payout device so as to pay out game balls one by one every time the payout screw rotates by approximately 90 °.
[0030]
The dispensing screw is provided with a rotating plate that rotates together with the dispensing screw, and the ball dispensing device is provided with a rotation detection sensor for detecting a rotation position of the dispensing screw. It is preferable to have a lightweight space that is not involved in the detection of the rotation position by the rotation detection sensor.
[0031]
In this case, the formation of the space can reduce the moment of inertia of the rotating plate.
Further, the space can be formed by a notch or a hole provided in the rotating plate.
[0032]
Further, the first to fourth supply passages form a passage converging portion that converges above the dispensing screw, and the first supply passage and the third supply passage are arranged in a cross-sectional direction of the dispensing screw. The second supply passage and the fourth supply passage are distributed from the passage converging portion to the left and right sides of the second thread portion from the passage converging portion. In the axial direction of the discharge screw, the first supply passage and the third supply passage are distributed from the passage converging portion to the outer shaft end of the first thread portion, and are also distributed. It is preferable that the second supply passage and the fourth supply passage are distributed from the converging portion to an outer shaft end of the second thread portion.
[0033]
In this case, when a game ball is supplied to each of the supply passages, it can be supplied to a portion where the whole converges as the passage converging portion. Therefore, the supply of the game balls to each supply passage is easy.
By distributing the supply passages after the passage converging portion in the transverse section direction and the axial direction of the payout screw, the number of game balls that can be paid out per unit time and the controllability of the payout screw are excellent. In addition, it is possible to form a compact ball dispensing device in which these are balanced and compact.
The outer shaft end refers to an end of the first thread portion or the second thread portion which is located outside the discharge screw in the axial direction (the same applies hereinafter).
[0034]
【Example】
Hereinafter, embodiments of the ball dispensing apparatus of the present invention will be described with reference to the drawings.
As shown in FIGS. 1 to 21, the ball payout apparatus 1 of this embodiment is used for paying out a predetermined number of game balls 8 as lending balls or prize balls in a pachinko gaming machine (not shown).
As shown in FIGS. 1 and 3, the ball payout device 1 of the present embodiment causes each of the game balls 8 supplied to the four supply passages 31 to 34 to rotate by a payout screw 2 having a rotation shaft 20 in a substantially horizontal direction. The four supply passages 31 to 34 receive the four feed passages 41 to 44, respectively, and advance on the respective feed passages 41 to 44 to guide the two payout passages 51 and 52 to pay out.
[0035]
As shown in FIG. 5, the dispensing screw 2 has two thread portions 21 and 22 spirally disposed on the outer periphery thereof. The ball dispensing device 1 advances the game ball 8 on each of the feed passages 41 to 44 by rotating the payout screw 2 by contacting the thread portions 21 and 22 with the game ball 8. It is configured to be.
As shown in FIG. 3, the two supply passages 31, 33 are opposed to each other from the left and right sides of one of the thread portions 21 in the cross-sectional direction B of the discharge screw 2 via the thread portions 21. It is open to. Further, the remaining two supply passages 32 and 34 are opened from both left and right side surfaces in the cross-sectional direction B of the other thread portion 22 at positions facing each other via the thread portion 22.
[0036]
Also, as shown in FIG. 1, the four feed passages 41 to 44 are formed in the axial direction A of the discharge screw 2 and the supply passages 31 to 34 and the discharge passages 51 and 52. Are formed so as to communicate with each other.
Then, as shown in FIG. 8, the ball payout device 1 causes the game balls 8 received from the supply passages 31 to 34 to the feed passages 41 to 44 to rotate sequentially by the rotation of the payout screw 2. It is configured to be paid out one by one from the different feed passages 41 to 44 to the payout passages 51 and 52 alternately.
[0037]
Hereinafter, the payout screw 2, the supply passages 31 to 34, the feed passages 41 to 44, and the payout passages 51 and 52 will be described in detail.
As shown in FIG. 5, the two thread portions 21 and 22 of the dispensing screw 2 are formed as a first thread portion 21 and a second thread portion 22 at two locations in the axial direction A of the dispensing screw 2. I have. Further, the spiral directions of the first thread portion 21 and the second thread portion 22 are opposite to each other.
[0038]
As shown in FIGS. 1, 3, and 8, the four supply passages 31 to 34 are provided with a first supply passage 31 located on the right side surface of the first thread 21 and a second thread 22. The second supply passage 32 is located on the right side of the first thread portion, the third supply passage 33 is located on the left side surface of the first thread portion 21, and the fourth supply passage 34 is located on the left side surface of the second thread portion 22. Is formed.
As shown in FIGS. 1 and 8, the four feed passages 41 to 44 include a first feed passage 41 communicating with the first supply passage 31 and a second feed passage 42 communicating with the second supply passage 32. , A third feed passage 43 communicating with the third supply passage 33 and a fourth feed passage 44 communicating with the fourth supply passage 34.
[0039]
As shown in FIGS. 1 and 8, the two payout passages 51 and 52 include a first payout passage 51 formed at a junction 451 between the first feed passage 41 and the second feed passage 42. The second delivery passage 52 is formed at a junction 452 between the third delivery passage 43 and the fourth delivery passage 44.
[0040]
As shown in FIG. 3, in each of the feed passages 41 to 44, the ball center G <b> 1 of each game ball 8 disposed on each of the feed passages 41 to 44 is positioned below the axial center G <b> 2 of the payout screw 2. It is configured to be located. Therefore, it is possible to prevent the pressure due to the weight of the many game balls 8 supplied to the respective supply passages 31 to 34 from directly acting on the payout screw 2 from above. Thereby, it is possible to suppress the unreasonable load from being applied to the payout screw 2 by the large number of game balls 8.
[0041]
As shown in FIGS. 11 to 19, the ball dispensing device 1 of the present embodiment includes one game ball 8 from each of the four feed passages 41 to 44 each time the dispensing screw 2 rotates approximately 90 ° in one direction. It is paid out one by one. The ball payout device 1 of the present embodiment pays out one game ball 8 from each of the four feed passages 41 to 44 when the payout screw 2 is rotated once.
[0042]
In order to perform such payout control, the ball payout device 1 has the following configuration.
That is, as shown in FIG. 3, two feed passages 41, 43 provided in a pair on the left and right side surfaces of the first thread portion 21 or the second thread portion 22 of the discharge screw 2 in the cross-sectional direction B. A feed path angle θ1 formed by an imaginary line L1 connecting the ball center G1 of each of the game balls 8 arranged on 42 and 44 and the axial center G2 of the payout screw 2 is substantially 90 °.
[0043]
As shown in FIG. 5, the first thread portion 21 and the second thread portion 22 of the dispensing screw 2 are formed by a single thread 231.
Also, as shown in FIG. 1, from the supply paths 31 to 34 to the release point P2 of the payout paths 51 and 52 from the ball center G1 of the game ball 8 immediately after being disposed on the feed paths 41 to 44. Is a distance L, that is, a distance L in which the game ball 8 advances in each of the feed passages 41 to 44 is about 3/4 of the pitch P in the first thread portion 21 and the second thread portion 22 of the payout screw 2. Length.
[0044]
As shown in FIG. 20, the ball dispensing position 234 of the first thread portion 21 and the ball dispensing position 234 of the second thread portion 22 are shifted from each other by approximately 180 °. The ball payout position 234 is defined as a center position between the threads 231 of the threaded portions 21 and 22 (the valley portion 232 formed between the threads 231) due to the rotation of the delivery screw 2. The center position in the axial direction A) is a position in the circumferential direction of each of the thread portions 21 and 22 when the release screw P2 is located closer to the center of the discharge screw 2 in the axial direction A than the release point P2. In addition, the ball payout position 234 of the present example is near the start position of the formation of the screw thread 231 from the end of each of the screw threads 21 and 22 located on the center side in the axial direction A of the payout screw 2.
[0045]
As shown in FIGS. 1 and 3, the ball dispensing device 1 has a frame 11 made of plastic, and the supply passages 31 to 34, the feed passages 41 to 44 and the dispensing passages 51, 52 is formed on the frame portion 11.
In each of the supply passages 31 to 34, a number of game balls 8 are sequentially arranged to flow down from a storage tank (not shown) provided above the ball payout device 1. The payout speed of a large number of game balls 8 is adjusted by the rotation speed of the payout screw 2, and the number of game balls 8 to be paid out is controlled.
[0046]
As shown in FIGS. 5 and 8, the ball payout device 1 has a stepping motor 24 for rotating the payout screw 2. The stepping motor 24 is connected to the rotation shaft 20 of the dispensing screw 2.
The stepping motor 24 rotates 3.75 ° per step, and has the same phase every 8 steps (30 °). Therefore, three times (integer multiple) of the number of steps is 90 °, and the exciting phase when the game ball 8 is paid out is always the same as the payout screw 2 that pays out every time the car rotates by about 90 °. Therefore, the rotation control of the dispensing screw 2 is easy.
[0047]
As shown in FIGS. 5 and 8, the end of the rotating shaft 20 of the dispensing screw 2 opposite to the side to which the stepping motor 24 is connected can be engaged with the dispensing screw 2. A recess 26 is formed. Thus, the payout screw 2 can be manually rotated by engaging a driver or the like with the engagement concave portion 26 at the time of maintenance or the like.
As shown in FIG. 5, a notch 111 for maintenance can be provided in a portion adjacent to an outer peripheral portion of a rotating plate 25 described later in the frame portion 11 of the ball dispensing device 1. The payout screw 2 can also be rotated manually by operating the rotating plate 25 with a finger or the like inserted through the maintenance notch 111.
[0048]
Hereinafter, the supply passages 31 to 34 and the feed passages 41 to 44 will be described in detail.
As shown in FIG. 3, each of the supply passages 31 to 34 is arranged so as to supply the game balls 8 from the outer peripheral side of the payout screw 2. Each of the supply passages 31 to 34 is disposed so as to oppose each of the inner wall portions 35 that partition each of the supply passages 31 to 34 and the dispensing screw 2 and each of the feed passages 41 to 34. And each outer wall surface 36 connected to the outer wall surface 44.
[0049]
As shown in FIG. 3, between the lowermost end 351 of each inner wall 35 in each of the supply passages 31 to 34 and each of the feed passages 41 to 44, the game ball 8 is connected to the thread 21, Each contact opening 37 for making contact with 22 is formed.
Then, as shown in FIG. 4, the position of the lowermost end 351 of each of the inner wall portions 35 is the position of the lowermost end 351 and the position immediately after being arranged on each of the feed passages 41 to 44 from each of the supply passages 31 to 34. The diameter of the virtual inscribed ball 805 located in each of the supply passages 31 to 34 in contact with the game ball 8 and each thread portion 21 or 22 is arranged at a position where the diameter of the virtual inscribed ball 805 is smaller than the diameter of the game ball 8. I have.
[0050]
In addition, the virtual inscribed ball 805 of the present embodiment includes the lowermost end portion 351 of each of the inner wall portions 35 and the game ball 8 immediately after being placed on each of the feed passages 41 to 44 from each of the supply passages 31 to 34. And the outer peripheral end 235 of the thread 231 of each thread 21 or 22.
In FIG. 4, a virtual inscribed ball 806 having the same diameter as the above-mentioned gaming ball 8 is provided at the virtual lowermost end 352 of each inner wall 35 and the feed passages 41 to 34 from the supply passages 31 to 34. Also shown is a case in which the game ball 8 immediately after being placed on 44 and the outer peripheral end 235 of the thread 231 of each thread 21 or 22 are in contact.
[0051]
When determining the position of the lowermost end portion 351 of each of the inner wall portions 35, the game ball 8 can pass through the width D between the inner wall portion 35 and the outer wall surface 36 in each of the supply passages 31 to 34. It is of course necessary to keep the width of
Therefore, the position of the lowermost end portion 351 of each of the inner wall portions 35 is above the position at which the width D of each of the supply passages 31 to 34 can be kept as wide as the game ball 8 can pass, and Most preferably, it is lower than the lower end 352.
[0052]
As shown in FIG. 3, the feed passages 41 to 44 are opposed to the supply passages 31 to 34, and are opposed to each other by receiving the pressure of a large number of the game balls 8 arranged in the supply passages 31 to 34 due to their own weight. It has a surface 46 and a guide surface 47 formed continuously from the outer wall surface 36 in each of the supply passages 31 to 34 and guiding the passage of the game ball 8. The opposing receiving surfaces 46 can receive the pressure due to the own weight of the large number of game balls 8 arranged on the supply passages 31 to 34, so that this pressure is not directly applied to the payout screw 2. be able to.
Further, each of the contact opening holes 37 of the present example is formed between the lowermost end 351 of each of the inner wall portions 35 and the upper end of the opposed receiving surface 46.
[0053]
As shown in FIG. 3, each guide surface 47 is formed so that, in the cross-sectional direction B of the payout screw 2, the axial center G2 of the payout screw 2 and the game balls 8 arranged on the feed passages 41 to 44. It is formed at a position at an angle wider than the virtual orthogonal line L2 orthogonal to the virtual line L1 connecting the sphere center G1 with respect to each of the opposed receiving surfaces 46. That is, the angle θ2 between each opposed receiving surface 46 and each guide surface 47 is larger than the angle θ3 between each opposed receiving surface 46 and the virtual orthogonal line L2. Further, in this example, the angle θ2 between each opposing receiving surface 46 and each guide surface 47 is 90 ° or less.
[0054]
Therefore, when a pressure due to the weight of a large number of game balls 8 arranged in the supply passages 31 to 34 is applied to the game balls 8 arranged in the respective feed passages 41 to 44, the pressure is applied to the respective game balls 8 in the respective feed passages 31 to 34. It is possible to prevent the game balls 8 arranged on the passages 41 to 44 from being pushed out in the directions of the thread portions 21 and 22 of the payout screw 2.
[0055]
As shown in FIG. 7, the first to fourth supply passages 31 to 34 form a passage converging portion 38 converging above the discharging screw 2.
As shown in FIG. 3, in the cross-sectional direction B of the discharging screw 2, the first supply passage 31 is distributed from the passage converging portion 38 to the right side surface of the first thread portion 21. The third supply passage 33 is distributed from the passage converging portion 38 to the left side surface of the first thread portion 21. Further, in the cross-sectional direction B of the discharging screw 2, the second supply passage 32 is distributed to the right side surface of the second thread portion 22 by the passage converging portion 38, and the fourth supply passage 34 is It is distributed from the passage converging portion 38 to the left side surface of the second thread portion 22.
[0056]
As shown in FIG. 1, in the axial direction A of the dispensing screw 2, the first supply passage 31 and the third supply passage 33 are separated from the dispensing screw 2 in the first thread portion 21 by the passage converging portion 38. Are distributed to an outer shaft end 233 which is an end located outside in the axial direction A. In the axial direction A of the discharging screw 2, the second supply passage 32 and the fourth supply passage 34 are distributed from the passage converging portion 38 to the outer shaft end 233 of the second thread portion 22. I have.
[0057]
Then, as shown in FIG. 7, when the game balls 8 are supplied to the supply passages 31 to 34, they can be supplied to the portion where the whole is converged as the passage converging portion 38. Therefore, when supplying the game balls 8 from the storage tank (not shown) provided above the ball dispensing device 1 to each of the supply passages 31 to 34, the game balls 8 can be supplied to the passage converging portion 38. Therefore, the supply of the game balls 8 to the ball payout device 1 is easy.
[0058]
Further, each of the payout passages 51 and 52 of the present example has each of the inclined passage portions 511 and 521 formed to be inclined with respect to the axial direction A of the payout screw 2. Hereinafter, each of the inclined passage portions 511 and 521 will be described in detail.
As shown in FIG. 2, each of the inclined passage portions 511 and 521 is inclined in the axial direction A of the discharging screw 2. The inclined passage portions 511 and 521 are inclined in the same direction in the axial direction A of the discharging screw 2. In this example, the first inclined passage portion 511 and the second inclined passage portion 521 are inclined toward the second feed passage 42 and the fourth feed passage 44.
[0059]
Then, for example, the gaming ball 8 flows down the first payout passage 51 as follows.
That is, as shown in FIG. 2, the game balls 8 which have been paid out to the first payout passage 51 by moving forward in the first feed passage 41, have the side wall portion of the first payout passage 51 on the side of the second feed passage 42. It flows down toward the inner surface 532 at 53. Therefore, after the game ball 8 collides with the inside surface 532 and rebounds, the ball can be quickly and smoothly guided to the downstream side of the first payout passage 51. As a result, the time required for the game balls 8 to pass through the first payout passage 51 can be reduced.
[0060]
On the other hand, as shown in FIG. 2, the game balls 8 that have been paid out to the first payout passage 51 by moving forward in the second feed passage 42 are formed on the side wall of the first payout passage 51 on the first feed passage 41 side. It flows down toward the inner surface 531 of the part 53. At this time, although the game ball 8 swiftly collides with the inner side surface 531, it then rebounds from the inner side surface 531 and flows down toward the inner side surface 532 of the side wall portion 53 on the second feed passage 42 side. This also allows the game ball 8 to be quickly and smoothly guided to the downstream side of the first payout passage 51.
[0061]
The above-described operation and effect are the same when the game balls 8 are paid out from the third feed passage 43 or the fourth feed passage 44 to the second payout passage 52, and each of the inclined passage portions 511, 521 The same can be obtained when inclined toward the first feed passage 41.
Further, since each of the inclined passage portions 511 and 521 in each of the payout passages 51 and 52 is inclined in the same direction in the axial direction A of the payout screw 2, each payout is provided outside the ball payout device 1. It is easy to join the passages 51 and 52, and it becomes easy to pay out the game balls 8 one by one.
[0062]
As shown in FIGS. 2 and 9, each of the dispensing passages 51 and 52 is provided with a junction 451 between the first and second feed passages 41 and 42 or the third and fourth feed passages 43 and the fourth feed passage 43. Openings inclined so as to enlarge the passage cross-sectional area of each of the discharge passages 51 and 52 are provided at both ends in the axial direction A of the discharge screw 2 of each of the openings 54 that open to the junction 452 with the passage 44. Each of the inclined portions 541 is formed. Each of the opening inclined portions 541 is formed so as to chamfer both ends of each of the opening portions 54 in the axial direction A of the discharging screw 2.
[0063]
As shown in FIGS. 2, 6, and 8, the feed passages 41, 52 are located at positions facing the respective opening portions 54 in which the discharge passages 51, 52 are opened with respect to the respective merging portions 451, 452. A payout introduction section 542 is provided to guide the game ball 8 advanced through 42 or 43, 44 to each of the payout paths 51, 52.
As shown in FIG. 2, each payout introduction portion 542 is formed by a slope 543 substantially parallel to each of the opening slopes 541.
[0064]
Then, the game balls 8 that advance in the feed passages 41, 42 or 43, 44 flow down to the payout passages 51, 52 along the opening inclined portions 541 and the payout introduction portions 542, respectively. it can. Therefore, it is easy to guide the game balls 8 from the respective feed passages 41, 42 or 43, 44 to the payout passages 51, 52.
[0065]
The direction in which the thrust of the game ball 8 acts on the opening inclined portion 541 and the payout introduction portion 542 is changed from the direction in which the thrust of the game ball 8 acts in the axial direction A of the payout screw 2. It can be converted into a direction flowing down obliquely downward along the inclined surface 543 of the portion 542.
As a result, the time required for the game balls 8 to pass through the payout passages 51 and 52 can be further reduced.
[0066]
As shown in FIG. 2, each of the inclined passage portions 511 and 521 is a circle in which each of the inner side surfaces 531 and 532 of the side wall portions 53 on both sides in the axial direction A of the discharge screw 2 is convex toward the outside. It is formed in an arc shape. Therefore, the game balls 8 paid out from the feed passages 41, 42 or 43, 44 to the payout passages 51, 52 are placed on the inner side surfaces 531, 532 of the inner wall portions 53 of the payout passages 51, 52. Bounce at the time of collision can be further reduced. Thus, the gaming balls 8 can smoothly flow down to the payout passages 51 and 52.
[0067]
As shown in FIGS. 2, 6, and 9, a first payout detection sensor 61 and a second payout detection sensor that detect the payout of the game ball 8 are provided in the first payout passage 51 and the second payout passage 52, respectively. 62 are provided. Hereinafter, each of the payout detection sensors 61 and 62 will be described in detail.
Each of the payout detection sensors 61 and 62 in the present example is a photo sensor. In this photosensor, a light-emitting diode as a light-emitting portion 64 is provided on one side through the payout passages 51 and 52, and a photodiode or phototransistor as a light-receiving portion 65 is provided on the other side. It is configured.
[0068]
As shown in FIG. 2, when the game balls 8 flow down to the payout passages 51 and 52, the game balls 8 block the sensing points P1 of the payout detection sensors 61 and 62, so that the payout of the game balls 8 is performed. Can be detected. Note that the sensing point P1 refers to a position at which light emitted from the light emitting section 64 passes toward the light receiving section 65.
[0069]
As shown in FIG. 2, the payout detection sensors 61 and 62 are provided in the inclined passage portions 511 and 521 of the payout passages 51 and 52, respectively. Each of the payout detection sensors 61 and 62 has a base 63 and a light-emitting unit 64 and a light-receiving unit 65 erected from the base 63. Further, in this example, the first payout detection sensor 61 and the second payout detection sensor 62 are integrally formed.
Then, the integrated payout detection sensors 61 and 62 use the base 63 as an outer surface of the side wall 53 of each of the inclined passages 511 and 521 on the side of the first feed passage 41 and the third feed passage 43. 533.
[0070]
As shown in FIG. 2, the first payout detection sensor 61 determines that the sensing point P1 is at a point where the game ball 8 flows down from the first feed passage 41 or the second feed passage 42 to the first payout passage 51. They are arranged so as to be at substantially the same distance from a certain release point P2. Similarly, the second payout detection sensor 62 has its sensing point P1 at each release point at which the game ball 8 flows down from the third feed path 43 or the fourth feed path 44 to the second payout path 52. They are arranged so as to be at substantially the same distance from P2.
In this example, the end of each of the opening inclined portions 541 on the side of each of the feed passages 41 to 44 corresponds to each of the release points P2.
[0071]
Further, as shown in FIG. 2, each sensing point P1 in the present example is set at the center of the game ball 8 when the game ball 8 flows down along each of the opening inclined portions 541 of the payout passages 51 and 52. It is within the range W of the length of the radius of the game ball 8 from the intersection X of the locus L3 drawn by G1 downward.
[0072]
As shown in FIG. 2, as described above, by forming the respective inclined passage portions 511 and 521 in the respective payout passages 51 and 52, the respective payout detection sensors 61 and 62 allow the respective base portions 63 to be The inclined passage portions 511 and 521 can be disposed on the ball dispensing device 1 by contacting the outer side surfaces 533 of the side wall portions 53 on the first and third feed passages 41 and 43 side.
[0073]
Thereby, each sensing point P1 in each of the payout detection sensors 61 and 62 can be brought closer to each release point P2. Therefore, the payout detection sensors 61 and 62 can quickly detect the game balls 8 to be paid out to the payout passages 51 and 52 from the feed passages 41 and 42 or 43 and 44.
Therefore, when performing the rotation control of the payout screw 2, the payout of the game balls 8 can be quickly fed back, and the controllability of the rotation control can be improved.
[0074]
Further, as described above, each sensing point P1 in each of the payout detection sensors 61 and 62 is located at substantially the same distance from each release point P2. Therefore, the payout can be equally detected for the game balls 8 moving forward in the respective feed paths 41 to 44.
[0075]
As shown in FIGS. 1, 5, and 8, the ball payout device 1 includes a rotation detection sensor 71 that detects the rotational position of the payout screw 2 and a rotating plate 25 that rotates together with the payout screw 2. . Hereinafter, the rotation detecting sensor 71 and the rotating plate 25 will be described in detail.
In this example, as shown in FIG. 1, the rotation detection sensor 71 is provided on the electrical board 7 provided on the outer peripheral side of the stepping motor 24, and the rotation position of the payout screw 2 is determined by the rotation of the rotation plate 25. Can be detected.
[0076]
Further, the rotation detection sensor 71 of the present example is a photo sensor. The photosensor has a structure in which a light emitting diode as a light emitting unit 64 is provided on one side of the rotating plate 25 and a photodiode or phototransistor as a light receiving unit 65 is provided on the other side. I have.
Further, an output circuit to the stepping motor 24, and input circuits from the payout detection sensors 61 and 62 and the rotation detection sensor 71 are formed on the electric board 7. The electrical board 7 is connected to a control unit of a pachinko game machine described later.
[0077]
As shown in FIG. 20, the rotary plate 25 of the present example is projected outward from the central shaft portion 251 connected to the rotary shaft 20 of the dispensing screw 2 in order to block the sensing point P1 of the rotation detection sensor 71. It has four projections 252. Further, in the portion of the rotating plate 25 where the protruding portion 252 is not formed, a lightweight space portion 255 that is not involved in the detection of the rotation position of the rotation detection sensor 71 is formed.
Note that the sensing point P1 refers to a position at which light emitted from the light emitting section 64 passes toward the light receiving section 65.
[0078]
Then, the rotation detecting sensor 71 is configured to perform the dispensing operation by blocking the light from the light emitting unit 64 to the light receiving unit 65 of the rotation detecting sensor 71 by the protruding portion 252 of the rotating plate 25 that rotates with the rotation of the dispensing screw 2. It can be detected that the screw 2 is located at any of the first to fourth payout rotation positions 201 to 204 described later.
[0079]
As shown in FIG. 20, the rotary plate 25 has the space portion 255, and the four protrusions 252 are formed only partially on the outer peripheral side of the center shaft portion 251. Therefore, the moment of inertia of the rotating plate 25 can be reduced. Therefore, the torque required for the stepping motor 24 can be reduced, and selection of the stepping motor 24 can be facilitated.
[0080]
On the other hand, as shown in FIG. 21, the rotating plate 25 may have four notches 254 provided on the outer peripheral portion of the disc-shaped body 253. In this case, a plurality of holes 255 serving as the space portions 255 are formed between the central shaft portion 251 of the disc-shaped body 253 and the cutout portions 254 to reduce the weight of the rotating plate 25. Can be planned.
[0081]
In this case, the light emitted from the light emitting portion 64 of the rotation detection sensor 71 passes through the cutout portion 254 of the rotating plate 25 and reaches the light receiving portion 65, so that the payout screw 2 Can be detected at any one of first to fourth payout rotation positions 201 to 204 described later.
Also in this case, similarly to the above, the moment of inertia of the rotating plate 25 can be reduced, and the torque required for the stepping motor 24 can be reduced.
[0082]
As shown in FIGS. 11 to 19, the ball payout device 1 pays out one game ball 8 each time the payout screw 2 is rotated by approximately 90 ° as described above. Then, the dispensing screw 2 dispenses the first dispensing rotation position 201 (see FIGS. 11A, 12, and 13) from which the first dispensing passage 41 dispenses the first dispensing passage 51 to the first dispensing passage 51, and the second dispensing screw 44 disposes the second dispensing screw 44 from the fourth feed passage 44. The second payout rotation position 202 (see FIGS. 11B, 14 and 15) for paying out to the payout passage 52, and the third payout rotational position 203 for paying out from the second feed passage 42 to the first payout passage 51 (FIG. 11). (C), see FIGS. 16 and 17) and four rotations at a fourth payout rotation position 204 (see FIGS. 11 (d), 18 and 19) for paying out the third feed passage 43 to the second payout passage 52. The position can be controlled for rotation.
[0083]
Hereinafter, a cycle of paying out game balls 8 by the ball payout device 1 will be described.
FIG. 11 is a schematic diagram when the payout screw 2 is viewed from a side surface on the stepping motor 24 side. As shown in the figure, the payout screw 2 of the present example rotates counterclockwise when viewed from the stepping motor 24 side.
In FIGS. 11 to 19, the game balls 8 moving forward in the respective feed passages 41 to 44 are indicated by game balls 801 to 804, respectively.
[0084]
As shown in FIGS. 11A and 12, when the payout screw 2 is located at the first payout rotation position 201, game balls 801 are paid out from the first feed passage 41 to the first payout passage 51.
Further, at this time, as shown in FIG. 13, the game balls 804 and 802 are advanced on the fourth feed path 44 and the second feed path 42, respectively, and the third feed path 33 is moved to the third feed path. The game ball 803 is welcomed to 43.
[0085]
That is, as shown in FIG. 3, when each of the game balls 801, 804, 802 moves forward through the first feed passage 41, the fourth feed passage 44, and the second feed passage 42 by the rotation of the payout screw 2, The game balls 803 are not arranged in the third feed passage 43, and the game balls 803 in the third supply passage 33 are in a standby state in contact with the outer peripheral end 235 of the first thread portion 21. .
[0086]
Then, as shown in FIG. 8, when the game ball 801 is paid out from the first feed passage 41 as described above, the valley portion 232 between the threads 231 of the first thread portion 21 becomes the third supply It faces the passage 33. Then, the game balls 803 in the standby state are received from the third supply passage 33 into the trough 232 and the third feed passage 43.
[0087]
Next, as shown in FIGS. 11B and 15, when the dispensing screw 2 is rotated by approximately 90 ° from the first dispensing rotation position 201 and positioned at the second dispensing rotation position 202, the fourth feed passage 44 is rotated. The game balls 804 are paid out to the second payout passage 52.
At this time, as shown in FIGS. 14 and 15, similarly to the above, the game balls 802 and 803 advance on the second feed passage 42 and the third feed passage 43, respectively, The game ball 801 is received in the portion 232 and the first feed passage 41 from the first supply passage 31.
[0088]
Next, as shown in FIGS. 11C and 16, when the dispensing screw 2 is further rotated by approximately 90 ° from the second dispensing rotation position 202 and is located at the third dispensing rotation position 203, the second feed passage is rotated. The game ball 802 is paid out to the first payout passage 51 from 42.
At this time, as shown in FIGS. 16 and 17, similarly to the above, the game balls 803 and 801 are moving forward on the third feed passage 43 and the first feed passage 41, respectively. The game ball 804 is received in the portion 232 and the fourth feed passage 44 from the fourth supply passage 34.
[0089]
Next, as shown in FIG. 11D and FIG. 19, when the dispensing screw 2 is further rotated by approximately 90 ° from the third dispensing rotation position 203 and is located at the fourth dispensing rotation position 204, the third feed passage is rotated. The game ball 803 is paid out to the second payout passage 52 from 43.
At this time, as shown in FIGS. 18 and 19, similarly to the above, the game balls 801 and 804 advance on the first feed passage 41 and the fourth feed passage 44, respectively, and The game ball 802 is received in the portion 232 and the second feed passage 42 from the second supply passage 32.
[0090]
Then, as shown in FIG. 3, each of the game balls 8 flowing down the supply passages 31, 33 or 32, 34 is rotated by the rotation of the payout screw 2 through the abutment hole 37 to form the screw ball. The thread portions 21 and 22 are arranged in the valley portions 232 between the threads 231 of the thread portions 21 and 22 from the state in which they contact the outer peripheral end 235 of the thread portions 21 and 22. At this time, the game balls 8 are received on the feed passages 41, 43 or 42, 44 via the contact opening holes 37.
[0091]
In this state, as shown in FIG. 12 to FIG. 19, by further rotating the payout screw 2, each game ball 8 is hooked by the thread 231 in each of the thread portions 21 and 22, and each feed ball is fed. It advances on the passages 41, 42 or 43, 44 toward the respective payout passages 51, 52.
Then, each game ball 8 is dispensed to each of the payout passages 51, 52 by moving forward on the feed passages 41, 42 or 43, 44 by a distance L of approximately 3/4 of one pitch P of the payout screw 2. It is.
[0092]
In this manner, the cycle of paying out the game balls 8 in the predetermined order (the order of the first supply passage 31, the fourth supply passage 34, the second supply passage 32, and the third supply passage 33) can be performed. Then, every time the dispensing screw 2 rotates approximately 90 ° in one direction, the dispensing screw 2 is moved from the first to fourth feed passages 41 to 44 to the first dispensing passage 51 or the second dispensing passage 52 at substantially equal time intervals. The game balls 8 can be alternately paid out one by one.
[0093]
FIG. 10 shows the trajectories of the game balls 8 passing through the supply passages 31 to 34 and the feed passages 41 to 44 and the payout passages 51 and 52 described above. As shown in the figure, each game ball 8 is inserted into the ball payout device 1 from each supply port 311, 321, 331, 341 of each supply path 31-34, and each payout port 512, of each payout path 51, 52. From 522, the ball is paid out of the ball discharging device 1.
[0094]
Further, as described above, the ball payout device 1 detects the payout of the game ball 8 to the first payout passage 51 by the first payout detection sensor 61 and to the second payout passage 52 by the second payout detection sensor 62. And the detection of the payout of the game ball 8 can be performed alternately.
Therefore, after the first payout detection sensor 61 detects the payout of the game balls 8 to the first payout passage 51, the second payout detection sensor 62 detects the payout of the game balls 8 to the second payout passage 52. After a certain time, the payout of the game balls 8 to the first payout passage 51 can be detected again. Similarly, after the second payout detection sensor 62 detects the payout of the game balls 8 to the second payout passage 52, the first payout detection sensor 61 controls the payout of the game balls 8 to the first payout passage 51. After the detection time, the payout of the game balls 8 to the second payout passage 52 can be detected again.
[0095]
Therefore, each of the payout detection sensors 61 and 62 can detect the next game ball 8 at a predetermined interval after detecting one game ball 8, and each payout detection sensor 61 and 62 has one The time required to detect the payout of the game ball 8 can be increased. Therefore, the detection accuracy of the game balls 8 by the payout detection sensors 61 and 62 can be improved.
[0096]
In the ball payout device 1, the control of paying out the gaming balls 8 is performed by a control unit (not shown) provided in the pachinko gaming machine. Hereinafter, the payout control of the game balls 8 by the control unit will be described.
Upon receiving a payout command of a predetermined number of game balls 8 in a game in the pachinko gaming machine, the control unit operates the ball payout apparatus 1 with the predetermined number as a target payout number. That is, the control unit operates the stepping motor 24 to rotate the payout screw 2 and pay out the game balls 8 to the payout passages 51 and 52 alternately. The game balls 8 paid out to the payout passages 51 and 52 join at a ball receiving portion (not shown) provided below the ball payout device 1.
[0097]
When the game balls 8 are paid out to the payout passages 51 and 52, the payout detection sensors 61 and 62 detect the payout of the game balls 8 respectively. Then, the control unit moves the payout screw 2 to the payout rotation positions 201 to 204 until the sum of the number of game balls 8 paid out to the payout detection sensors 61 and 62 reaches the target payout number. Rotate.
When the dispensing screw 2 rotates, the rotating plate 25 rotates accordingly, and the rotation detecting sensor 71 detects that the dispensing screw 2 has rotated to each of the dispensing rotation positions 201 to 204. I do.
[0098]
Then, thereafter, when the sum of the number of game balls 8 paid out to each of the payout detection sensors 61 and 62 reaches the target payout number, the control unit stops the rotation of the payout screw 2.
In this way, the ball payout device 1 can control the payout of the gaming balls 8.
[0099]
Next, the overall operation and effect of the ball dispensing apparatus 1 will be described.
In the ball dispensing device 1 of the present embodiment, as described above, the supply passages 31 to 34 are paired with the one dispensing screw 2 on both left and right sides in the cross-sectional direction B and in the axial direction. A is formed at two places. Therefore, the supply of the game balls 8 is performed from the four supply passages 31 to 34 for one payout screw 2. Further, each game ball 8 is sent over the four feed passages 41 to 44 by the rotation of one payout screw 2 and is paid out to the first payout passage 51 or the second payout passage 52 alternately.
Therefore, the number of game balls 8 to be paid out per unit time can be increased by the single payout screw 2.
[0100]
The timing at which each game ball 8 is received on each of the feed passages 41 to 44 by the rotation of the one payout screw 2 is shifted by an amount of time during which the payout screw 2 rotates by approximately 90 °. Accordingly, the timing at which each game ball 8 starts to advance with respect to each of the feed passages 41 to 44 is also shifted by the time during which the payout screw 2 rotates by approximately 90 °.
Each time the dispensing screw 2 rotates approximately 90 ° in one direction, the first and second feed passages 41, 44, the second and third feed passages 42, 43 are separated at substantially equal time intervals. By repeating the payout cycle, the game balls 8 can be paid out one by one.
[0101]
Therefore, by controlling the rotation of the one payout screw 2, the number of game balls 8 to be paid out can be easily controlled.
Therefore, according to the ball payout device 1 of the present embodiment, the number of game balls 8 to be paid out can be easily controlled and the game balls 8 can be paid out at high speed.
Further, according to the pachinko game machine using the ball payout device 1, a sufficient payout speed of the game balls 8 can be ensured even in an arrangement machine that pays out the game balls 8 for prize balls for each game of the game. Can be.
[0102]
Further, as described above, in the ball dispensing device 1 of the present example, the supply passages 31, 33 or 32, 34 are disposed on the outer peripheral side of the first thread portion 21 or the second thread portion 22 of the dispensing screw 2. That is, the game balls 8 are provided so as to be supplied from both left and right side surfaces of the first thread portion 21 or the second thread portion 22 in the cross-sectional direction B.
[0103]
The supply passages 31 to 34 have the inner wall portions 35 and the outer wall surfaces 36, and the game balls 8 flowing down in the supply passages 31 to 34 have the inner wall portions 35 and the respective It passes between the outer wall surfaces 36. At this time, each game ball 8 is prevented from being in contact with each of the thread portions 21 and 22 of the payout screw 2 by each of the inner wall portions 35, and can smoothly flow down.
[0104]
Further, as described above, in this example, the position of the lowermost end 351 of each inner wall 35 in each of the supply passages 31 to 34 is determined by the position of the lowermost end 351 and each of the supply passages 31 to 34 and each of the feed passages. The virtual inscribed sphere 805 located in each of the supply passages 31 to 34 that comes into contact with the game ball 8 immediately after being placed on the sphere 41 to 44 and the outer peripheral end 235 of the thread 231 of each thread 21 or 22. It is arranged at a position where the diameter is smaller than the diameter of the game ball 8.
[0105]
Therefore, when the game balls 8 are received from the first supply passage 31 to the first feed passage 41, two game balls 8 enter the valley portion 232 of the first thread portion 21 between the threads 231 at the same time. Nothing. Similarly, when the game balls 8 are received from the third supply passage 33 to the third feed passage 43, two game balls 8 do not enter the valley portion 232 of the first thread portion 21 at the same time. .
[0106]
The same applies to the case where the game balls 8 are received in the second supply passage 32 and the fourth supply passage 34.
In this example, the game ball 8 in each of the supply passages 31 to 34 comes into contact with each of the thread portions 21 and 22 of the payout screw 2 depending on the formation position of the lowermost end portion 351 of each of the inner wall portions 35. I can't. For this reason, it is possible to prevent an unnecessary load from being applied to the payout screw 2 by the game balls 8 in each of the supply passages 31 to 34.
Therefore, according to the ball payout device 1, it is possible to prevent an excessive load from being applied to the payout screw 2, and to smoothly pay out the game balls 8 by the payout screw 2.
[0107]
In addition, due to the configuration of the ball payout device 1 that pays out the game balls 8 one by one each time the payout screw 2 rotates by 90 ° and performs one cycle, the payout screw 2 has the screw in each of the thread portions 21 and 22. There is no case where four or more game balls 8 are simultaneously moved into the valley 232 formed between the mountains 231 and are advanced. More specifically, after paying out one game ball 8 from any of the feed passages 41 to 44 to any of the payout passages 51 and 52, the payout is performed until the payout screw 2 rotates approximately 90 °. The game balls 8 are not arranged again in the feed passages 41 to 44. Therefore, actually, the payout screw 2 only needs to have a torque enough to advance the three game balls 8.
Therefore, according to the ball payout device 1, the load applied to the payout screw 2 can be reduced and the game balls 8 can be paid out at high speed.
[0108]
Further, as described above, the payout passages 51 and 52 of the present example have the inclined passage portions 511 and 521, respectively. It flows down while colliding with the passages 511 and 521. At this time, the game balls 8 flow down while rebounding to the inclined passage portions 511 and 521, but the number of rebounds can be reduced as compared with the payout passage formed in the vertical direction as in the related art. Therefore, the game balls 8 rebounding from the inclined passage portions 511, 521 can be smoothly guided to the downstream side of the payout passages 51, 52.
[0109]
Therefore, the time required for the game balls 8 to pass through the payout passages 51 and 52 can be reduced, and the payout speed of the game balls 8 in the ball payout device 1 can be improved.
Further, since the inclined passage portions 511 and 521 have the opening inclined portions 541, the payout introduction portions 542, and the arc-shaped inner side surfaces 531 and 532, the game in the ball dispensing device 1 is performed. The payout speed of the ball 8 can be further improved.
[Brief description of the drawings]
FIG. 1 is a diagram showing a cross section in the axial direction of a dispensing screw of a ball dispensing device in an embodiment, and is a cross-sectional explanatory view particularly explaining a supply passage, a feed passage, and a discharge passage.
FIG. 2 is a diagram showing a cross section in the axial direction of a dispensing screw of a ball dispensing device in the embodiment, and is a cross-sectional explanatory view particularly illustrating a periphery of a dispensing passage.
FIG. 3 is a view showing a cross section in a transverse section direction of a dispensing screw of a ball dispensing device in the embodiment when viewed from a side surface on a stepping motor side, and is a cross-sectional explanatory view particularly explaining a supply passage and a feed passage.
FIG. 4 is a view showing a cross section of the dispensing screw of the ball dispensing device in the transverse section direction in the embodiment, and is a cross-sectional explanatory view particularly explaining a position of a lowermost end portion on an inner wall portion of the supply passage.
FIG. 5 is a diagram showing a cross section in the axial direction of a dispensing screw of a ball dispensing device in the embodiment, and is a cross-sectional explanatory view particularly explaining a dispensing screw.
FIG. 6 is a view showing a cross section of the payout screw of the ball payout device in the embodiment in a cross-sectional direction as viewed from a side surface opposite to the stepping motor side, and particularly a cross-sectional explanation for explaining the vicinity of a payout passage; FIG.
FIG. 7 is a top view showing the ball payout device in the embodiment.
FIG. 8 is an explanatory cross-sectional view showing a ball payout device as viewed from above in the embodiment, particularly showing a cross section near a payout screw;
FIG. 9 is a cross-sectional explanatory view showing the ball dispensing device as viewed from above, particularly showing a cross section near a feed passage in the embodiment.
FIG. 10 is an explanatory diagram showing trajectories of game balls passing through a supply passage, a feed passage, and a payout passage in the embodiment.
FIG. 11 is a view schematically showing a state in which a game ball is paid out by rotation of a payout screw in the embodiment, wherein the payout screw is (a) a first payout rotational position, (b) a second payout rotational position, Explanatory drawing which shows the state which is in c) 3rd payout rotation position and (d) 4th payout rotation position.
FIG. 12 is a diagram showing a cross section in the axial direction of a payout screw of a ball payout device and a right side surface of the payout screw in the embodiment, and is a cross-sectional explanatory view showing a state where the payout screw is at a first payout rotation position.
FIG. 13 is a diagram showing a cross section in the axial direction of the dispensing screw of the ball dispensing device and a left side surface of the dispensing screw in the embodiment, and is an explanatory sectional view showing a state in which the dispensing screw is at a first dispensing rotation position.
FIG. 14 is a diagram showing a cross section in the axial direction of the payout screw of the ball payout device and a right side surface of the payout screw in the embodiment, and a sectional explanatory view showing a state where the payout screw is at a second payout rotation position.
FIG. 15 is a diagram showing a cross section in the axial direction of the dispensing screw of the ball dispensing device and a left side surface of the dispensing screw in the embodiment, and is an explanatory sectional view showing a state in which the dispensing screw is at a second dispensing rotation position.
FIG. 16 is a diagram showing a cross section in the axial direction of the dispensing screw of the ball dispensing device and a right side surface of the dispensing screw in the embodiment, and is an explanatory sectional view showing a state in which the dispensing screw is at a third dispensing rotation position.
FIG. 17 is a diagram showing a cross section in the axial direction of the dispensing screw of the ball dispensing device and a left side surface of the dispensing screw in the embodiment, and is an explanatory sectional view showing a state where the dispensing screw is at a third dispensing rotation position.
FIG. 18 is a diagram showing a cross section in the axial direction of the dispensing screw of the ball dispensing device and a right side surface of the dispensing screw in the embodiment, and is an explanatory sectional view showing a state where the dispensing screw is at a fourth dispensing rotation position.
FIG. 19 is a diagram showing a cross section in the axial direction of the dispensing screw of the ball dispensing device and a left side surface of the dispensing screw in the embodiment, and a sectional explanatory view showing a state where the dispensing screw is at a fourth dispensing rotation position.
FIG. 20 is a perspective view showing a payout screw and a rotary plate in the embodiment.
FIG. 21 is a perspective view showing a payout screw and another rotating plate in the embodiment.
[Explanation of symbols]
1. . . Ball dispenser,
2. . . Dispensing screw,
201. . . First payout rotation position,
202. . . Second payout rotation position,
203. . . Third payout rotation position,
204. . . 4th payout rotation position,
21. . . 1st thread part,
22. . . 2nd thread part,
231. . . Thread,
232. . . Tanibe,
24. . . Stepper motor,
25. . . Rotating plate,
251. . . Central shaft,
252. . . Overhang,
31. . . The first supply passage,
32. . . The second supply passage,
33. . . Third supply passage,
34. . . Fourth supply passage,
41. . . 1st feed passage,
42. . . The second feed passage,
43. . . Third feed path,
44. . . 4th feed passage,
51. . . First payout passage,
52. . . Second payout passage,
61. . . First payout detection sensor,
62. . . Second payout detection sensor,
7. . . Electrical board,
71. . . Rotation detection sensor,
8,801-804,. . . Play ball,
A. . . Axial direction of the dispensing screw,
B. . . Cross-sectional direction of the dispensing screw,
G1. . . The center of the game ball,
G2. . . Dispense screw shaft center,
P1. . . Sensing point P1,
P2. . . Release point P2

Claims (7)

A ball dispensing device that receives game balls supplied to the supply passage from the supply passage into the feed passage by rotating a dispensing screw having a rotation axis in a substantially horizontal direction, advances the supply passage on the feed passage, and guides the game balls to the payout passage to pay out. At
The dispensing screw has a thread portion spirally disposed on the outer periphery thereof, and the thread portion is rotated in contact with the game ball to advance the game ball on the feed passage. Is composed of
The supply passage comprises a pair of right and left two pairs of left and right sides which are opened from both left and right side surfaces of the screw portion in the transverse cross-sectional direction of the dispensing screw through the screw portion and face each other. It has multiple sets in the axial direction of the screw,
The feed passage is formed to extend in the axial direction of the discharge screw, and a plurality of feed passages are formed to connect the supply passages to the discharge passage.
Each of the game balls received from each of the supply passages into each of the feed passages is paid out one by one from the different feed passages to the payout passage one by one by rotation of the payout screw. Ball dispensing device. In claim 1, the thread portion is formed as a first thread portion and a second thread portion at two locations in the axial direction of the discharge screw,
Each of the supply passages includes a first supply passage located on a right side surface of the first thread portion, a second supply passage located on a right side surface of the second thread portion, and a left side surface of the first thread portion. A fourth supply passage located on the left side of the second thread portion and a third supply passage located at four locations;
The feed path includes a first feed path communicating with the first supply path, a second feed path communicating with the second supply path, a third feed path communicating with the third supply path, and a fourth feed path. A ball dispensing device characterized in that four fourth feed passages are formed at four locations to communicate with each other. In claim 2, the first screw portion and the second screw portion have helical directions opposite to each other,
The dispensing passage includes a first dispensing passage formed at a junction of the first and second feed passages, and a second discharge passage formed at a junction of the third and fourth feed passages. A ball dispensing device, wherein two dispensing passages are formed in two places. 4. The payout detection sensor according to claim 3, wherein the first payout passage and the second payout passage are each provided with a payout detection sensor for detecting payout of the game ball.
The dispensing detection sensor is configured to perform dispensing from the first or second feed passage to the first dispensing passage and dispensing from the third or fourth feed passage to the second dispensing passage. A ball dispensing device configured to be able to detect alternately. 5. The payout path according to claim 1, wherein the center of a ball of each game ball disposed on each of the feed paths has a height equal to the axial center of the payout screw or the payout. 6. A ball dispensing device configured to be located below a shaft center of a screw. 6. The rotation detecting device according to claim 1, wherein the payout screw is provided with a rotating plate that rotates together with the payout screw, and the ball payout device is provided with a rotation detection device that detects a rotational position of the payout screw. Sensor is provided,
A ball dispensing device, wherein the rotating plate has a light-weight space that is not involved in detecting the rotation position by the rotation detection sensor. In any one of claims 2 to 6, the first to fourth supply passages form a passage converging portion that converges above the discharge screw,
In the cross-sectional direction of the discharging screw, the first supply passage and the third supply passage are distributed to the left and right sides of the first thread portion from the passage converging portion, and the second supply passage and the third supply passage are separated from each other. The fourth supply passage is distributed to the left and right sides of the second thread portion from the passage converging portion,
In the axial direction of the discharging screw, the first supply passage and the third supply passage are distributed to the outer shaft end of the first thread portion from the passage converging portion, and the second supply passage and the third supply passage are arranged. The fourth supply passage is distributed from the converging portion to an outer shaft end of the second thread portion.

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