JP4978063B2 - Ball-flow structure of gaming machines - Google Patents

Description

  The present invention relates to a ball flow structure of a gaming machine that rectifies and flows a large number of stored game balls into a plurality of rows.

In a back side mechanism of a gaming machine such as a pachinko gaming machine, a ball flow-down structure for supplying game balls to a payout device for paying out a predetermined number of game balls is provided. Then, the game balls paid out from the payout device are guided to a ball tray arranged in front of the gaming machine.
The ball flow down structure is configured to receive a game ball from an island facility around the gaming machine and store it, and connect the ball storage unit to the ball storage unit, align the game balls in a predetermined number of rows, and supply the game ball to the payout device. And a spherical flow path portion to be formed.

  An example of such a sphere falling structure is disclosed in Patent Document 1. In the game ball tank (ball flow-down structure) of Patent Document 1, a rectifying rail portion (ball flow path portion) that guides game balls stored in the storage portion to the outside is integrated with a bottom portion of the storage portion that stores the game balls. Is provided.

  However, in the conventional ball flow-down structure, a larger number of game balls are stored in the storage section, and the game balls are rectified in the ball flow path section so as to flow down to the ball payout device in a state where ball clogging hardly occurs. Is not made. In other words, in order to store a large number of game balls in the ball channel portion, it is conceivable to increase the width of the ball channel portion. In this case, if a structure that rectifies the number of flow-down rows and the number of flow-down stages of game balls at the same time is adopted, there is a possibility that ball clogging occurs.

  Further, in the conventional ball flow down structure, when the payout speed per unit time of the ball payout device is functionally increased, there is no contrivance to supply game balls to the ball payout device without causing shortage.

JP 2001-276370 A

  The present invention has been made in view of such conventional problems, and can increase the storage amount of game balls, prevent the occurrence of ball clogging, rectify the game balls, and play the game to the ball payout device. An object of the present invention is to provide a ball flow down structure for a gaming machine that can quickly supply a ball.

The present invention includes a ball storage unit that stores game balls, and a ball channel unit that is connected in the left-right direction of the ball storage unit and rectifies the game balls stored in the ball storage unit to flow downward in the ball flow direction. In the ball flow down structure of the equipped gaming machine,
The ball flow path unit includes a horizontal rectification unit that rectifies the flow of the game ball in the lateral direction with respect to the downward direction of the ball flow, and a vertical rectification unit that rectifies the flow of the game ball in the vertical direction with respect to the downward direction of the ball flow. And
By repeatedly forming a plurality of times alternately with the horizontal rectifying portion and the vertical rectifier portion, it forms a pair of sphere flow path flows down in parallel Butotomoni 1-stack state one column sphere to the horizontal direction ,
A step for allowing the game ball to flow down to a position lower than the radius of the game ball by a diameter equal to or less than the diameter of the sub-flow path, which is the other ball flow path, on the bottom surface of the main flow path, which is one of the pair of ball flow paths. Part is formed,
On the downstream side of the formation position of the stepped portion, the sub-flow path is joined to the main flow path by an inclined sphere flow path that is inclined toward the main flow path,
The main flow path after the merging is configured such that the game balls flow down while maintaining a one-tiered state,
The inclined sphere channel is formed by an inclined flow formed from one side wall to the other side wall of the main channel at a position above the main channel in a state substantially parallel to the one side wall of the sub channel and the side wall. According to a first aspect of the present invention, there is provided a ball flow-down structure for a gaming machine, wherein the game ball is guided and flowed down from both sides by a guide .

The ball flow down structure of the gaming machine of the present invention includes a ball flow path portion formed by alternately repeating the horizontal rectification portion and the vertical rectification portion a plurality of times.
For this reason, in the upstream portion of the ball flow path portion in the downward direction of the ball flow, the number of rows of game balls flowing in the horizontal direction and the number of flow down steps (number of loading steps) of the game balls in the vertical direction can be maximized. Thereby, the storage amount of the game ball by a ball storage part and a ball flow path part can be increased.

  In addition, the ball rectification unit and the vertical rectification unit are not formed at the same time in the ball flow path unit, but are alternately and repeatedly formed multiple times, so that the game ball can be used when performing the horizontal and vertical rectifications. It is possible to prevent the ball clogging.

  In the present invention, since the step portion is formed on the bottom surface of the main flow path, the flow speed of the game ball flowing down the main flow path can be increased compared to the game ball flowing down the sub flow path. . In addition, since the sub-flow path is joined to the main flow path at the position where the step portion is formed or at the downstream side thereof, the game balls in the main flow path at the downstream side of the merge section are game balls that merge from the sub-flow path. The downflow speed is also increased by being pushed by.

  Thereby, as a result, the supply speed (supply amount) of the game balls supplied to the ball payout device disposed on the downstream side of the ball flow down structure increases. Therefore, even when the payout speed per unit time of the ball payout device is functionally increased, the game balls to be supplied to the ball payout device can be supplied quickly without being insufficient.

Further, in the present invention, the configuration of the main flow channel, the sub flow channel, and the stepped portion makes it possible to stably join the game balls from the sub flow channel to the main flow channel.
When the first game ball flowing down the main channel flows downward in the step portion (the initial stage of the flow down), the second game ball in the sub-channel is supported by the first game ball in the main channel. The main channel has not yet joined. Next, after the first game ball in the main flow channel has flowed down the stepped portion, the first game ball has increased in speed due to the flow down the stepped portion, and preceded the second game ball in the sub flow channel. Flow down. Then, the second game ball flowing down the sub-flow path gradually stops being supported by the first game ball, and the second game ball flows down the main flow path following the first game ball and the first game ball. An increase in the distance between the three game balls also acts to join the main flow path.

  In other words, in the present invention, the second game ball flowing down the sub-flow path does not merge into the main flow path so as to interrupt between the first game ball and the third game ball, but the flow speed increases. When the support of the first game ball is lost, it joins the main flow path. Thereby, in the present invention, the game balls can be stably merged from the sub-flow path to the main flow path.

  Therefore, according to the present invention, the amount of stored game balls can be increased, the occurrence of clogging can be prevented, the game balls can be rectified, and the game balls can be quickly supplied to the ball dispensing device. A ball falling structure of a gaming machine can be provided.

A preferred embodiment of the present invention described above will be described.
In the present invention, the lateral rectification unit may employ a structure that divides the number of downstream rows described below, or a structure that reduces the number of downstream rows.
In other words, the structure that divides the number of descending rows is that the total number of descending rows of the game balls in the lateral direction does not change, but by providing a descending guide in the direction of the descending ball flow of the ball channel portion, This means a structure that divides the number of rows of game balls flowing in the horizontal direction. Further, the structure for reducing the number of descending rows refers to a structure for reducing the number of descending rows of game balls in the lateral direction by gradually narrowing the interval between the side walls of the ball flow path portion.

Moreover, it is preferable that the said level | step-difference part is located in the side edge part vicinity in the said game machine .
In this case, when the above-described ball-falling structure is employed in the upper frame portion of the frame-shaped back mechanism portion in the gaming machine, the stepped portion and the ball passage portion on the downstream side thereof are located below the central portion of the upper frame portion. Positioning (protruding) can be prevented. Thereby, the opening area | region of the upper part of a back mechanism part can be enlarged as much as possible, and the freedom degree of arrangement | positioning in the upper part of the game components arrange | positioned at a game board can be improved.

Moreover, it is preferable to change the said main flow path so that the inclination | tilt angle of the bottom face may become steep in the downstream of the confluence | merging part where the said sub flow path merges with this main flow path .
In this case, it is possible to intentionally flow the game ball flowing down the main flow path quickly at a portion where the inclination angle of the bottom surface changes, and to delay the flow following of the game ball subsequent thereto. Thereby, a space can be formed in front of the succeeding game ball flowing down the main flow path, and the occurrence of ball clogging in the ball flow path portion can be more effectively prevented.

Hereinafter, an embodiment according to a ball flow down structure of a gaming machine of the present invention will be described with reference to the drawings.
As shown in FIGS. 1 and 11, the ball flow down structure of the gaming machine of this example rectifies the ball storage unit 2 that stores the game ball 8 and the game ball 8 stored in the ball storage unit 2, The sphere tank 1 is provided with a sphere channel portion 3 that flows down in the direction W1. A ball payout device 15 for paying out a predetermined number of game balls 8 to a ball tray (not shown) is disposed on the downstream side of the ball tank 1.

  As shown in FIG. 1 to FIG. 4, the ball flow path portion 3 of this example narrows down the flow guide width X of the game ball 8 in the lateral direction B perpendicular to the ball flow down direction W1 from the upstream side in the ball flow down direction W1. The first horizontal rectification unit 41 that forms the alignment state of the game balls 8 in the horizontal direction B, the ball flow downward direction W1 and the number of flow down stages of the game balls 8 in the vertical direction H orthogonal to the horizontal direction B are reduced in the vertical direction H. The first vertical rectification unit 42 that forms the aligned state of the game balls 8, the second horizontal rectification unit 43 that further narrows down (divides) the flow guide width X of the game ball 8 in the horizontal direction B, and the game balls 8 in the vertical direction H A second vertical rectification unit 44 that further reduces the number of downstream stages is sequentially formed.

And in the 2nd vertical rectification | straightening part 44, two pairs of spherical flow paths 30 (30A, B) which flow down in the horizontal direction B along with one row of spheres are formed along with the horizontal direction. Further, on the downstream side of the second vertical rectification unit 44, a third horizontal rectification unit 45 is formed that restricts (reduces) the number of flow-down rows of the game balls 8 in the horizontal direction B.
In the third horizontal rectification unit 45, the bottom surface 311 of the main flow path 30 </ b> A that is one of the spherical flow paths 30 out of the pair of spherical flow paths 30 is positioned lower than the sub flow path 30 </ b> B that is the other spherical flow path 30. A step 35 is formed to allow the game ball 8 to flow down. Further, in the third horizontal rectification unit 45, the sub-flow channel 30B joins the main flow channel 30A from a position above the main flow channel 30A on the downstream side of the position where the step portion 35 is formed.

Hereinafter, the ball flow down structure of the gaming machine of this example will be described in detail with reference to FIGS.
As shown in FIG. 2, the gaming machine of this example is a pachinko gaming machine 10 that performs a pachinko game. The pachinko gaming machine 10 is configured such that a main body frame 11 with a game board attached thereto can be opened and closed with respect to an outer frame (not shown). Further, on the front side of the main body frame 11, a ball tray (not shown) for storing the game balls 8 paid out from the ball payout device 15 arranged on the back side of the main body frame 11 is provided. In addition, a glass door 12 provided with a glass plate capable of visually recognizing a game area on the game board is disposed so as to be openable and closable above the position of the ball tray on the front side of the main body frame 11.

Further, as shown in FIG. 11, on the back side of the main body frame 11, a frame control unit 16 for controlling the ball payout device 15 and the like in the pachinko gaming machine 10, a power supply unit 17 and the like are arranged. 13 is arranged to be openable and closable.
In this example, the front side means the front side of the pachinko gaming machine 10 facing the player, and the back side means the side opposite to the front side. 1 and 2, the front-rear direction of the pachinko gaming machine 10 is indicated by D, and the front side is indicated by D1.

As shown in FIGS. 1 and 11, the back mechanism plate 13 has a ball tank 1 for storing a game ball 8 in the upper part on the back side of the pachinko gaming machine 10, and the game ball 8 in the ball tank 1 flows downward. A ball lowering passage 14 for causing the ball to flow, and a ball payout device 15 for paying out a predetermined number of game balls 8 from the ball lowering passage 14 to the ball tray are disposed.
The back mechanism plate 13 has a frame shape with an opening region 130, the ball tank 1 is disposed in the upper frame portion 131 of the back mechanism plate 13, and the ball flow down passage 14 is formed of the back mechanism plate. The ball dispensing device 15 is disposed at the corner of the side frame portion 132 and the lower frame portion 133.

As shown in FIGS. 1 and 2, the sphere tank 1 of this example is formed by integrally molding a sphere storage part 2 and a sphere flow path part 3 in the left-right direction W and using a resin.
The ball storage unit 2 of this example is configured to receive and store the game balls 8 from the island facilities around the pachinko gaming machine 10. The ball storage portion 2 is formed by being surrounded by a storage bottom plate portion 21 and a storage side plate portion 22 erected from the outer periphery of the storage bottom plate portion 21.

  As shown in FIG. 1 and FIG. 4, the ball channel portion 3 of the present example includes a rail bottom plate portion 31 and a pair of rail side plate portions 32 erected from both ends in the lateral direction B of the rail bottom plate portion 31. A spherical flow path 30 is formed through which the sphere 8 flows down. Further, as shown in FIG. 4, the rail bottom plate portion 31 is gently inclined downward toward the sphere flow downward direction W1, and the bottom surface 311 of each spherical flow path 30 is gently inclined downward toward the sphere flow downward direction W1. is doing.

  In addition, as shown in FIGS. 1, 3, and 4, the rail bottom plate portion 31 is provided with standing-down guides 33 and 34 between the pair of rail side plate portions 32. In this example, in order to form the flow-down state of the four rows of the game balls 8 in the lateral direction B, the flow-down guides 33 and 34 include a main flow-down guide 33 formed in the central portion of the horizontal direction B and the main flow-down guide. And a pair of sub-flow guides 34 formed on both sides of 33. The spherical flow path 30 of this example is partitioned into four spherical flow paths 30 by a pair of rail side plate portions 32, a main flow down guide 33 and a pair of sub flow down guides 34.

As shown in FIG. 1, in the ball tank 1 of this example, the ball flow downward direction W1 is formed in the left-right direction W in the pachinko gaming machine 10, and the horizontal direction B is formed in the front-rear direction D in the pachinko gaming machine 10. The vertical direction H is formed in the vertical direction H in the pachinko gaming machine 10.
In addition, the ball tank 1 of this example is configured so that the game ball 8 flows down to the right when viewed from the back side of the pachinko gaming machine 10, and the ball flow downward direction W1 is viewed from the back side of the pachinko gaming machine 10. It is formed to the right.

As shown in FIG. 4, in the ball channel portion 3 of the present example, a diaphragm plate 51 is disposed in a portion that forms a two-stage flow-down state of the game ball 8 in the longitudinal direction H.
Further, in the ball flow path portion 3 of the present example, a flow-down cover 52 is disposed on a ceiling portion that forms a flow-down state of the game ball 8 in the vertical direction H from a two-step flow-down state to a one-step flow-down state. It is.

As shown in FIGS. 3 and 4, the first horizontal rectification unit 41 of the present example forms four rows of flowing-down states of the game balls 8 in the lateral direction B. The first horizontal rectification unit 41 is formed by an inclined step portion 312 that is inclined downward from the storage bottom plate portion 21 of the sphere storage portion 2. The first horizontal rectification unit 41 is formed to have a passage width in which four game balls 8 are arranged in the horizontal direction B, and a main flow guide formed along the ball flow downward direction W1 at the center in the horizontal direction B. 33 is located. The first horizontal rectification unit 41 is divided into two by the main flow guide 33.
As shown in FIG. 3, in the first horizontal rectifying unit 41, the main flow guide 33 forms two rows of ball flow paths 30 having a flow guide width X for two game balls 8 (2 A flow-down state with a width of 2 rows × 2 balls is formed).

As shown in FIGS. 3, 4, and 6, the first vertical rectification unit 42 of this example forms a two-stage flow-down state of the game ball 8 in the vertical direction H. The first vertical rectification unit 42 is formed by a diaphragm plate 51 spanned between the pair of rail side plate units 32 in the spherical flow path unit 3. The 1st vertical rectification part 42 is comprised so that the game ball 8 which flows down in three or more steps from the ball | bowl storage part 2 arrange | positioned in the upstream may flow down in a two-stage stacked state. Also in the first vertical rectification unit 42, the main flow guide 33 is located in the central portion in the horizontal direction B, and the flow state of the game ball 8 in the horizontal direction B is the same as that of the first horizontal rectification unit 41. .
As shown in FIG. 6, in the first vertical rectification unit 42, the main flow guide 33 and the throttle plate 51 form a flow-down state of 2 stages × 2 rows × 2 spheres.

As shown in FIGS. 3, 4, and 7, the second horizontal rectifying unit 43 of the present example has a flow guide for the game ball 8 in the lateral direction B by the sub flow guides 34 formed on both sides of the main flow guide 33. The width X is configured to be narrowed (sorted). That is, in the second horizontal rectification unit 43, the ball flow path 30 having the flow down guide width X for 82 game balls is divided into the ball flow paths 30 in which the game ball 8 has the flow down guide width X for 1 ball. . The second horizontal rectification unit 43 is formed to have a passage width in which four game balls 8 are arranged in the lateral direction B, and is divided into four by the main flow guide 33 and the pair of sub flow guides 34.
Then, as shown in FIG. 7, in the second horizontal rectification unit 43, the ball flow path 30 having the flow guide width X for one game ball 8 by the main flow guide 33 and the pair of sub flow guides 34 is four. A row is formed (a flow-down state of 2 stages × 4 rows × 1 ball width is formed).

  As shown in FIGS. 3 to 5 and 8, the second vertical rectification unit 44 of this example is configured to restrict the stacked state of the game balls 8 in the vertical direction H. That is, the second vertical rectification unit 44 is configured to cause the game balls 8 flowing down in a two-stage stacked state to flow down in a one-stage stacked state. Further, the second vertical rectifying unit 44 is formed by an inclined restricting part 521 in the falling cover 52 that spans between the upper ends of the pair of rail side plate parts 32 in the spherical flow path part 3. That is, as shown in FIG. 5, the second vertical rectifying unit 44 is formed by narrowing the interval between the inclined throttle unit 521 and the rail bottom plate unit 31 toward the downstream side in the ball flow downward direction W1. It is.

Also in the second vertical rectification unit 44, the main flow guide 33 and the pair of sub flow guides 34 are located on the rail bottom plate portion 31, and the flow state of the game ball 8 in the lateral direction B is the second horizontal rectification unit. 43.
As shown in FIG. 8, in the second vertical rectifying unit 44, the main flow guide 33, the sub flow guide 34, and the inclined throttle unit 521 form a flow state of 1 stage × 4 rows × 1 ball width. Yes.

  As shown in FIG. 3 to FIG. 5 and FIG. 9, the third horizontal rectification unit 45 of this example is an inner side of the four ball flow paths 30 that form the four rows of the flowing-down states of the game balls 8 in the horizontal direction B. A stepped portion that causes the game balls 8 that flow down the main flow path 30A that is the two rows of ball flow paths 30 to flow down to a position lower than the game balls 8 that flow down the sub flow path 30B that is the outer two rows of the ball flow paths 30 35. The step portion 35 is formed so as to be inclined downward toward the ball flow downward direction W1. The step portion 35 of this example is formed at a height substantially equal to the hemisphere of the game ball 8 (more specifically, it is formed at a height greater than or equal to the radius of the game ball 8 and less than the diameter).

As shown in FIGS. 5 and 9, in the stepped portion 35, the game balls 8 flowing down the inner two rows of the ball passages 30 </ b> A become the game balls 8 flowing down the outer two rows of the ball passages 30 </ b> B. On the other hand, the game ball 8 is lowered to a position that is lower by approximately the hemisphere.
3 to 10, the game balls 8 flowing down the main flow path 30A are shown without hatching, and the game balls 8 flowing down the sub flow path 30B are shown hatched.

  As shown in FIGS. 3 and 5, in the third horizontal rectification unit 45, the sub-channel 30 </ b> B has an inclined sphere channel 36 that is inclined toward the main channel 30 </ b> A. The inclined sphere channel 36 is inclined from each sub-channel 30B toward each main channel 30A, and the sub-channel 30B is narrowed inward from both sides in the lateral direction B to communicate with the main channel 30A. ing. Further, the outlet opening 362 of the inclined sphere channel 36 communicates with the main channel 30A on the downstream side in the sphere flow downward direction W1 from the position where the stepped portion 35 is formed.

  Further, as shown in FIG. 9, the outer portion of each inclined sphere channel 36 is formed by a pair of rail side plate portions 32 of the sphere channel portion 3. Further, an inclined flow guide 361 is formed in an inner portion of each inclined sphere channel 36. In each inclined sphere channel 36, the inclined flow guide 361 and the side plate portion 32 are formed substantially in parallel to guide the game ball 8 from both sides so that the game ball 8 flowing down the sub-channel 30B is appropriately used. It is configured to guide in the merging direction.

  As shown in FIG. 5, in the step portion 35 of the third horizontal rectification unit 45, the game ball 8 flowing down the main flow path 30A is moved in the ball flow downward direction W1 before the game ball 8 flowing down the sub flow path 30B. Can flow down. Then, the game ball 8 flowing down the inclined sphere channel 36 formed in communication with the sub-channel 30B joins the main channel 30A at the outlet opening 362 of the inclined sphere channel 36 downstream of the position where the step 35 is formed. To do.

  In the merging portion 39 of the main flow path 30A, the game balls 8 flowing down the main flow path 30A flow down substantially hemispherically below the game balls 8 than the game balls 8 flowing down the sub flow path 30B. In other words, the game ball 8 at the outlet opening 362 of the inclined sphere channel 36 is located at a position shifted upward by approximately a hemisphere in the ball flow downward direction W1 with respect to the game ball 8 at the junction 39 of the main channel 30A. To do.

  Thereby, in the junction 39, the game balls 8 flowing down the inclined sphere flow path 36 merge between the game balls 8 flowing down the main flow path 30A, and the main flow path 30A is upstream of the main flow path 30A. The game ball 8 flowing down from the side and the game ball 8 merged from the inclined sphere channel 36 can be alternately and repeatedly flowed down.

  Further, as shown in FIGS. 3 to 5 and 10, an outlet channel portion 46 is formed on the downstream side of the third horizontal rectifying portion 45, and the outlet channel portion 46 has two rows of main channels. 30A. At the downstream end portion of the outlet channel portion 46, ball outlet portions 38 for discharging the game balls 8 from the ball channel portion 3 in a two-row flow-down state are formed. To the above-mentioned ball flow down passage 14. Further, in the ball flow down passage 14, the game balls 8 are caused to flow down in a state where they are arranged in two rows in the lateral direction B (a state where they are arranged in two rows in the front-rear direction D of the pachinko gaming machine 10).

In addition, the game balls 8 flow down from the ball tank 1 to the ball flow-down passage 14 in the flow-down cover 52 disposed in the third horizontal rectification unit 45 and the outlet flow path unit 46 when performing maintenance of the ball dispensing device 15 and the like. A ball stopper 522 for stopping the operation is provided. The ball stopper 522 is retracted from the outlet channel portion 46 in a normal gaming state.
In this way, the game balls 8 flowing down the respective ball flow paths 30 can be stably merged, and the game balls 8 can be stably flowed down in the ball flow path portion 3.

  As shown in FIGS. 2, 3, and 5, in the spherical flow passage portion 3, the rail bottom plate portions 31 of the four rows of spherical flow passages 30 in the second horizontal rectification portion 43 and the second vertical rectification portion 44 ( In the rail bottom plate portion 31 (bottom surface 311) of the main flow path 30A in two rows in the bottom surface 311) and the third horizontal rectification unit 45 and the outlet flow channel portion 46, a through long groove 313 for dropping dust is directed in the ball flow downward direction W1. Formed. Further, the through long groove 313 can also guide the flow down of the game ball 8.

In addition, the through long groove 313 in the second horizontal rectification unit 43 and the second vertical rectification unit 44 extends from the middle of the second horizontal rectification unit 43 to the step portion 35 in the main flow path 30A and the inclined spherical flow in the sub flow path 30B. An inlet opening 363 of the path 36 is formed.
And in the 2nd vertical rectification | straightening part 44, the penetration long groove 313 formed in the rail bottom-plate part 31 of 30 A of main flow paths is continuously formed also in the upstream corner | angular part of the level | step-difference part 35 as shown in FIG. Thereby, it is possible to prevent the game ball 8 flowing down along the through long groove 313 in the main flow path 30A from riding on the bottom surface 311 at the step portion 35, and to smoothly flow down the game ball 8.

  Further, as shown in FIG. 5, in the third horizontal rectification unit 45, the bottom surface 311 of the main flow path 30A has an inclination angle on the downstream side in the spherical flow downward direction W1 from the position where the sub flow path 30B communicates with the main flow path 30A. It has changed to be steep. That is, the bottom surface 311 of the main flow path 30 </ b> A in the third horizontal rectification unit 45 is formed by the first inclined bottom surface 371 and the second inclined bottom surface 372 whose inclination angle is steeper than that of the first inclined bottom surface 371.

  With this configuration, when the game ball 8 flowing down the main flow path 30A is transferred from the first inclined bottom surface 371 to the second inclined bottom surface 372, the game ball 8 intentionally flows down quickly, and the following flow of the game ball 8 following this is delayed. be able to. Thereby, the space S can be formed in front of the succeeding game ball 8 flowing down the main flow path 30A, and the occurrence of clogging in the ball flow path portion 3 can be more effectively prevented.

  As shown in FIG. 11, the ball tank 1 of this example is formed over substantially the entire length of the upper frame portion 131 of the back mechanism plate 13 in the left-right direction W. Is located in the vicinity of the side end of the back mechanism plate 13. Thereby, when the ball tank 1 is disposed on the upper frame portion 131 of the frame-shaped back mechanism plate 13 in the pachinko gaming machine 10, the stepped portion 35 and the inclined sphere flow path 36 are located below the central portion of the upper frame portion 131. Positioning can be prevented. Therefore, the opening area 130 in the upper part of the back mechanism plate 13 can be made as wide as possible, and the degree of freedom of arrangement in the upper part of the gaming parts arranged in the game board can be improved.

  Further, in the ball tank 1 of the present example, not only a large number of game balls 8 can be stored in the ball storage unit 2, but also a large number of game balls 8 can be stored in the ball channel unit 3. That is, as described above, in the spherical flow path portion 3 of this example, the first horizontal rectification unit 41, the first vertical rectification unit 42, the second horizontal rectification unit 43, the second vertical rectification unit 44, and the third horizontal rectification unit. 45 are alternately formed.

Therefore, in the upstream portion of the ball flow path portion 3 in the ball flow downward direction W1, the number of rows of the game balls 8 in the horizontal direction B (four rows in this example) and the number of steps of the game balls 8 in the vertical direction H (number of loading steps) ) (Two stages in this example) can be made as large as possible. Thereby, the storage amount of the game ball 8 in the whole ball tank 1 can be increased.
Further, in the spherical flow path section 3, the horizontal rectification sections 41, 43, 45 and the vertical rectification sections 42, 44 are alternately formed without being formed at the same time. When repeatedly squeezing, it is possible to effectively prevent clogging of the game ball 8 from occurring.

  Further, in this example, the stepped portion 35 is formed on the bottom surface 311 of the main flow path 30A, so that the flow velocity of the game ball 8 flowing down the main flow path 30A is lower than the game ball 8 flowing down the sub flow path 30B. Can be raised. Further, the sub-flow channel 30B is merged with the main flow channel 30A on the downstream side of the formation position of the stepped portion 35, so that the game balls 8 in the main flow channel 30A on the downstream side of the merge portion 39 are The downflow speed is also increased by being pushed by the game ball 8 that joins the game.

  As a result, the supply speed (supply amount) of the game ball 8 supplied to the ball payout device 15 disposed downstream of the ball tank 1 and the ball flow down passage 14 is increased. Therefore, even when the payout speed per unit time of the ball payout device 15 is functionally increased, the game balls 8 supplied to the ball payout device 15 can be supplied quickly without being insufficient.

Moreover, according to the ball tank 1 of the present example, it will be described with reference to FIG. 12 that the gaming ball 8 can be stably merged from the sub-flow path 30B to the main flow path 30A with the above configuration.
As shown in FIG. 12 (a), when the first game ball 8A flowing down the main flow path 30A flows down in the step portion 35 (initial stage of flow down), the second game ball 8B in the sub flow path 30B. Is supported by the first game ball 8A in the main flow path 30A, and has not yet joined the main flow path 30A.

Next, as shown in FIG. 12B, after the first game ball 8A in the main flow path 30A has flowed down the step portion 35, the first game ball 8A has flowed down through the step portion 35. It increases, and flows down ahead of the 2nd game ball 8B in the subchannel 30B.
Then, as shown in FIG. 12 (c), the second game ball 8B flowing down the sub-flow channel 30B gradually loses its support by the first game ball 8A, and the first game ball 8A and the first game ball 8A The gap between the game ball 8A and the third game ball 8C flowing down the main flow path 30A following the game ball 8A also acts to join the main flow path 30A.

  That is, in the ball tank 1 of the present example, the second game ball 8B flowing down the sub-flow path 30B joins the main flow path 30A so as to interrupt between the first game ball 8A and the third game ball 8C. Instead, the first game ball 8A whose flow-down speed has increased is no longer supported, and merges into the main flow path 30A. Thereby, in the ball tank 1 of the present example, the game balls can be stably merged from the sub-flow path 30B to the main flow path 30A.

  Therefore, according to the ball flow down structure of the pachinko gaming machine 10 of the present example, it is possible to rectify the game ball 8 while increasing the storage amount of the game ball 8 and preventing the occurrence of the clogging of the ball. The game ball 8 can be quickly supplied to the device 15.

In addition, the ball flow down structure of this example can also be adopted as a ball flow down structure in a ball tray of a slot machine using the game ball 8 as a game medium.
Further, the stepped portion 35 can be formed long in the ball flow downward direction W1, and the sub-channel 30B can be joined to the main channel 30A in the middle of the stepped portion 35 (position where the stepped portion 35 is formed).

The perspective view which shows the ball tank in the Example in the state seen from the back surface side of the pachinko game machine. Explanatory drawing which shows the pachinko game machine provided with the ball tank in the Example in the state seen from the upper direction of the pachinko game machine. Plan explanatory drawing which shows the ball | bowl flow path part in a ball | bowl tank in an Example in the state seen from the upper direction of the pachinko game machine. Cross-sectional explanatory drawing which shows the ball | bowl channel part in the Example in the state seen from the back surface side of the pachinko game machine. Cross-sectional explanatory drawing which shows the downstream part of the ball | bowl flow path part in the Example seen from the back surface side of the pachinko game machine. It is a figure which shows the 1st vertical rectification | straightening part in a spherical flow path part in an Example, and is AA arrow directional cross-sectional explanatory drawing in FIG. It is a figure which shows the 2nd horizontal rectification | straightening part in a spherical flow path part in an Example, and is B line arrow directional cross-sectional explanatory drawing in FIG. The figure which shows the 2nd vertical rectification | straightening part in a spherical flow path part in an Example, and is C-line arrow directional cross-sectional explanatory drawing in FIG. The figure which shows the 3rd horizontal rectification part in a spherical flow path part in an Example, and is D line arrow directional cross-sectional explanatory drawing in FIG. It is a figure which shows the exit flow path part in a spherical flow path part in an Example, and is E line arrow directional cross-sectional explanatory drawing in FIG. Explanatory drawing which shows the back mechanism board which arrange | positioned the ball tank in an Example in the state seen from the back surface side of the pachinko game machine. In an Example, it is a figure which shows the flow-down state of the game ball in the periphery of a level | step-difference part, (a) The state immediately after the 1st game ball flowed down the level | step-difference part, (b) After the 1st game ball flowed down the level | step-difference part FIG. 4 is a cross-sectional explanatory view showing a state in the middle of the second game ball joining the main flow path, (c) a state in which the second game ball joins the main flow path, as viewed from the back side of the pachinko gaming machine.

Explanation of symbols

1 Ball tank (ball flow structure)
DESCRIPTION OF SYMBOLS 10 Pachinko machine 13 Back mechanism board 130 Opening area 131 Upper frame part 132 Side frame part 2 Ball storage part 3 Ball flow path part 30 Ball flow path 30A Main flow path 30B Sub flow path 35 Step part 36 Inclined spherical flow path 39 Confluence part 41 1st horizontal rectification part 42 1st vertical rectification part 43 2nd horizontal rectification part 44 2nd vertical rectification part 45 3rd horizontal rectification part 46 Outlet flow path part 8 Game ball X Flowing down guide width W1 Ball flow down direction B Horizontal direction H Longitudinal direction

Claims (2)

A gaming machine comprising: a ball storage unit that stores game balls; and a ball channel unit that is connected in the left-right direction of the ball storage unit and rectifies the game balls stored in the ball storage unit to flow downward in the ball flow direction In the ball flow structure of
The ball flow path unit includes a horizontal rectification unit that rectifies the flow of the game ball in the lateral direction with respect to the downward direction of the ball flow, and a vertical rectification unit that rectifies the flow of the game ball in the vertical direction with respect to the downward direction of the ball flow. And
By repeatedly forming a plurality of times alternately with the horizontal rectifying portion and the vertical rectifier portion, it forms a pair of sphere flow path flows down in parallel Butotomoni 1-stack state one column sphere to the horizontal direction ,
A step for allowing the game ball to flow down to a position lower than the radius of the game ball by a diameter equal to or less than the diameter of the sub-flow path, which is the other ball flow path, on the bottom surface of the main flow path, which is one of the pair of ball flow paths. Part is formed,
On the downstream side of the formation position of the stepped portion, the sub-flow path is joined to the main flow path by an inclined sphere flow path that is inclined toward the main flow path,
The main flow path after the merging is configured such that the game balls flow down while maintaining a one-tiered state,
The inclined sphere channel is formed by an inclined flow formed from one side wall to the other side wall of the main channel at a position above the main channel in a state substantially parallel to the one side wall of the sub channel and the side wall. A structure for flowing down a ball of a gaming machine, wherein the game ball is configured to guide and flow down from both sides by a guide . In Claim 1, the said spherical flow path part is the 1st horizontal rectification part which forms the flow guide width of the width | variety for two spheres arranged in two rows in the said horizontal direction from the upstream of a spherical flow down direction, in the said vertical direction A first vertical rectification unit capable of forming the number of flowing-down stages of the game balls in a two-stacked state, a second horizontal rectifying part that partitions the flow guide width of the above-mentioned two spheres for each sphere, and one stacking of the number of the above-mentioned flowing-down stages A game machine comprising: a second vertical rectification unit that narrows down to a state; and a third horizontal rectification unit that narrows down the flow guide width to a width corresponding to one sphere by the stepped portion and the inclined sphere channel. Sphere flow down structure.

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