TW200934562A - Collection mechanism for bowling game - Google Patents

Abstract

A collection mechanism applied to a bowling game device where a player hits a plurality of pins arranged while erecting on a lane by rolling a ball toward the plurality of pins. The collection mechanism for collecting the pins and balls is equipped with a pin collection mechanism having a rotator for collecting the pins by rotating, and a means for carrying a ball reached to the end side of a lane and a pin expelled to the end side of a lane to the pin collection mechanism. The rotator is provided with a pin transferring portion for transferring a pin, and a ball transferring portion for transferring a ball.

Description

200934562, IX, invention description: [Technical field to which the invention pertains] The present invention relates to a recycling mechanism for a private game, which is used for bowling games or billiards.丄·. Bowling game for the ball of the strong wood (BUib 〇 note)

[Trademarks] D [Prior Art] 0 The ball on the terminal side of the @@达球道 and the ball bottle swept out from the terminal side of the fairway are separately collected (for example, refer to Patent Document U. Patent Document 1. Special Open 1 〇 248 248 995 【 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 248 在 在 在 在 在 在 在 在 在 在 在In many cases, the assembly procedure and the adjustment of the apparatus require a lot of time. In view of the above, an object of the present invention is to reduce the number of parts for recovering the ball and the ball recovery mechanism to form a simple structure. In a first aspect of the present invention, the present invention is applicable to a bowling game device in which a player rolls a ball on a fairway and a plurality of ball bottles are erected for recycling the bottle and The ball receiving mechanism' includes: a ball collecting mechanism having a rotating rotating body for recovering the bottle by the rotation of the rotating body; and a carrying device, which will be 2013-9883 -PF;Chentf 5 200934562 The ball of the final ball (four) and the ball of the ball in the fairway are transported to the ball recycling mechanism. On the rotating body, there is a ball transfer part of the moving (four) bottle and a ball that transfers the ball. In the first aspect of the present invention, a simple structure in which the number of parts of the collecting bottle and the ball collecting mechanism is reduced is obtained. In the second aspect of the present invention, the rotating body is roughly formed into a plate shape. At the same time, the side surface orthogonal to the rotation axis is placed in the rotating body, and the bottle transfer portion is disposed on the outer peripheral side of the ball transfer portion, and the end of the transfer device is set to the side of the ball collecting mechanism. The distance between the portion and the rotating body is smaller than the diameter of the ball, and is larger than the maximum diameter of the bottle, and the end portion of the ball collecting mechanism on the conveying device is set in the wrong direction to be smaller than the ball transfer portion. The upper end is also higher than the upper end of the ball transfer portion. Therefore, in the second aspect of the present invention, the bottle is dropped from the gap between the bottle conveying device and the bottle collecting mechanism and stored in the bottle. Transfer department, the ball will not The gap is dropped and stored in the ball transfer unit. Therefore, even if the bottle is transported to the ball collecting mechanism in a state of being mixed with the ball, both the bottle and the ball can be distinguished and the both can be recovered. In addition, in the third aspect of the present invention, the ball transfer portion is formed by the side surface of the rotating body and the rotating shaft. The recessed portion is formed in the direction of the flat lamp, and the side surface is inclined with respect to the horizontal plane, and the opening of the recessed portion is opened toward the upper side. Thus, in the third aspect of the invention, the bottom and the inner peripheral surface of the recessed portion are 2013-9883. -PF; Chentf 6 200934562 "Knocking ball" can be kept. If the side of the rotating body is vertical, since the ball is only held on the inner peripheral side of the recess, the depth of the recess does not need to be large. Therefore, in the third aspect of the present invention, the thickness of the rotating body can be made thinner than when the side surface of the rotating body is vertical. Further, in the fourth aspect of the present invention, the ball collecting portion for taking out the ball filled in the concave portion is provided on the upper side of the lowermost portion of the rotating body. Further, in the fifth aspect of the present invention, the concave portion is formed by a through hole penetrating the rotating body, and a fixing plate for closing the through hole constituting the concave portion is provided, and a hole portion forming the ball collecting portion is provided on the fixing plate. [Embodiment] This embodiment is a bowling alley apparatus which is applied to Bilibo (registered trademark). And 'Bilib. (registered trademark) is a bowling ball using a ball for billiards

In particular, the game device is a game in which the ball is tilted by the impact of the ball for hitting the ball, and the ball is placed on the terminal side of the fairway. In addition, the bowling game device for the BUIB〇 (registered trademark) is now a structure that is reduced by the normal bowling game device. Therefore, there is a need for a device that is difficult to apply to Bilib〇 (registered trademark). . Here, the bowling device applied to Bilib〇 (registered trademark) will be exemplified below, and an embodiment of the present invention will be described with reference to the drawings. (First Embodiment) 1. Schematic description 2013-9883-PF; Chentf 7 200934562 Fig. 1 shows a bowling game 褒 1 1 in which the recycling mechanism 100, the bottle discharging machine 300, and the ball dragging the mountain The configuration of the sweeping mechanism 400. Fig. 2 is a front view of the recovery mechanism 100 (a view of the arrow A of Fig. 1). Figure 3 is a picture of the front side of the recycling agency, the water and the ancient & Fig. 4a is a front view of the outer cover 130. The first side view of Fig. 4a is shown. Fig. 5 is a view of the bottle P from the shape of the slit from the shape of the slit (Eight) #丁硬# Hard 121. Fig. 6 is a view of the state of Fig. 5 taken from the right side of Fig. 5 in the state of Fig. 5 . ❹

Further, Fig. 7 is a front view of the rotor ill from D, and 111. Figure 8a is a front view of the fixed plate 120, and the nth is a front view of the bottle P. Fig. 9a to Fig. 9c are diagrams showing the operation of the ball B and the bottle P received by the recovery mechanism 1 in this manner. Figs. 10a to 10c are diagrams showing the operation of the ball python and the bottle ρ recovered by the recycling plant 1 * η *1 text mechanism 100. Figure 11 is a picture of the recycling mechanism 100 viewed from the inside of the 丨 && Further, Fig. 12 is a view seen from the B arrow of the i-th image. The figure is a view in which the setting state of the dispenser 250 is viewed from above. The first figure is a view of the distribution mechanism 210 viewed from the arrow 8 of Fig. 1, and the μth view is a top view of the figure. Fig. 15 is a view showing a schematic structure of the bottle transport mechanism. Figure 16 is a left side view of Figure 15. The 17th to 17d chart does not raise the movement of the bottle p. Figure 18 is an enlarged view of the piston P 32Q. Fig. 19a is a cross-sectional view of the bottle guide 351, and Fig. 19b is a cross-sectional view taken along line 19B_19B of the i9a. The second diagram is a diagram showing the operation of the retracting mechanism 360. Fig. 21 is a view showing the operation of the retracting mechanism 36A. Further, Fig. 22 is a view of Fig. 20 viewed from the c arrow. The figure is a diagram showing the state in which the bottle guide 351 loses the bottle p. The first drawing is the release of the 2013-9883-PF; and the clamping of the bottle P by the Chentf 8 200934562. Fig. 24 is a block diagram showing the electrical system of the bowling game device i. Fig. 25 is a view showing a state of the bottle p stored in the bag portion j丨2A. 2. Outline of the bowling game device · The bowling game device 1 'As described above, the ball is rotated from the one end side in the longitudinal direction of the fairway 3 toward the other end side (the terminal side), thereby being disposed on the terminal side of the fairway 3 The device for the game of the bottle P dumped.

Then, at the terminal side of the fairway 3 and its vicinity, as shown in the figure, a recovery mechanism 1 for collecting the bottle P and the ball B is provided, and the bottle P collected by the recovery mechanism 1 is transported to the ball. The bottle handling mechanism 200 of the bottle discharging machine 3, the bottle discharging machine 300 in which the bottle P is placed at a predetermined position on the fairway 3, and the sweeping mechanism 4 of the bottle P and the like. Therefore, in the following description, the bottle conveying mechanism 2 and the bottle placing machine 300 are separated by an individual mechanism, for the purpose of facilitating understanding of the bowling game apparatus 1 of the present embodiment. '

That is, the classification of the mechanism constituting the bowling game device 并不 is not limited to the following description, and for example, the bottle transport mechanism 2 〇〇 and the bottle arranging machine 3 can be classified into one mechanism (ball bottle arranging machine) D Further, the operation of the recovery mechanism 100, the bottle transport mechanism 200, the bottle row name 300, and the sweep mechanism 400 is controlled by the control circuit 500 as shown in Fig. 24, and the control circuit 5 is controlled by the CPU. It is formed by a microcomputer composed of a chip such as R0M and RAM. Then, the (four) circuit 500 controls the recycling mechanism (10) according to the non-volatile recording such as memory, and the like. 3. The recycling mechanism 1 〇〇 2013-9883-PF; the Chentf 9 200934562 recycling mechanism 100, as shown in FIG. As shown, the kiosk simultaneously recovers the pour bottle P and the ball recycling mechanism that reaches the ball B on the end side of the ballway 3. Then, the bottle P recovered by the recovery mechanism 1 搬 is moved '4 to the bottle arranging machine 300 via the bottle conveying mechanism 2 ,, and the ball B & is returned by the returning projector provided on the lower side of the fairway 3. 106 is carried to the one end side of the fairway 3. Then, the recovery mechanism 100 includes a collection unit 110 including a rotator 1U or the like, a belt conveyor 101 disposed between the collection unit 110 and the lane 3, and a bottle for introducing the collected bottle P into the bottle conveying mechanism 2〇〇. The projector 103 and the ball β that has been collected are introduced into the ball projector 1〇5 of the projector 1〇6 (see FIG. 3). Further, the belt conveyor 101 conveys the ball end which reaches the end side of the fairway 3 and the ball end which is swept out to the end side of the fairway 3 to the recovery mechanism 1 by an endless belt which is rotationally driven by the electric motor. Further, the 'balloon projector 103, the ball projector 1〇5, and the return projector 1 0 6 are guides for guiding the bottle ρ or the ball 至 to a predetermined portion by sliding the bottle ρ or the ball β by the height difference. Guide device. Further, the 'ball view projector 103 is a hose, and although it is composed of a flexible tube or a flexible guide groove, the ball projector 1〇5 and the return projector 1〇6 may be flexible tubes or rigid. Body tube or flexible channel or rigid body channel. Therefore, the collision plate 107 is a member for impacting the ball which is rolled over, and the ball is dropped to the impact member of the belt conveyor 101, and the sweeping plate 401 is a member for sweeping the bottle ρ and the ball Β toward the skin ▼ conveyor 101. The sweeping plate is moved from the right side of the first drawing to the left side by the sweeping mechanism 400. 2013-9883-PF; Chentf 10 200934562, 3. 1. Recycling Department #· #* Recycling 邛 110' As shown in Figure 2, it includes a rotating rotator lu, ·. Fixed to the frame of the bowling game A fixing plate 120 (not shown), a cover 13G covering the lower end side of the rotor 111, and a motor 140 (refer to FIG. 9a) for rotating the rotor U1. The rotator 111, as shown in Fig. 9aBI, 'forms the side mountain 8 which is substantially plate-shaped and orthogonal to the rotation axis 111A thereof, and is inclined to the outer peripheral side with respect to the horizontal plane, as shown in Fig. 2, in the circumferential direction A plurality of protrusions 112 projecting radially outward in the radial direction are provided at equal intervals. Then, a spherical portion transfer portion (hereinafter referred to as a pocket portion 112A) in which the bottle p is conveyed by the belt conveyor 101 is formed by forming the concave portion U2A between the protruding portions 112, and is stored in the bottle p In the state of the bag portion 112A, the bottle p is transferred to the irregular slit 121 to be described later by the rotation of the spinner ln. Further, in the rotor 111, on the inner circumference side based on the pocket portion 112A, As shown in Fig. 9a, a through hole 13 is formed which is formed in a direction parallel to the rotating shaft 111A from the side surface 111B of the rotor, and penetrates through the rotor 1U toward the lower side of the through hole 113. The opening portion is closed by the fixing plate 120. On the other hand, the opening that opens toward the upper side of the through hole i3 is opened by being placed on the terminal side of the belt conveyor 1 〇 1, and the lower side of the through hole 3 is a concave portion that is closed. Therefore, the ball B conveyed by the belt conveyor 1〇1 is dropped into the through hole 113 (hereinafter, the through hole 113 is shown as a concave portion 113) and is accommodated in the concave portion 113 (see Fig. 9b). 2013-9883-PF; Chentf 11 200934562 ' Therefore, when the rotor 111 rotates, the ball β accommodated in the recess 11 3 is transferred together with the bottle ρ accommodated in the bag portion U2A. That is, the concave portion 113 has a function as a ball transfer portion for transferring the ball. Between the belt conveyance _ 1 〇 1 and the rotator 111, the guide plate 131 that protrudes from the outer cover 13 〇 toward the belt conveyor 1 〇 1 side is provided as shown in Fig. 9a. The gap with the belt conveyor 1〇1 is set to a size at which the guide plate 131 does not interfere with the belt conveyor 101 when the belt 101 operates. ❹ Therefore, the bottle p and the ball B carried by the belt conveyor 101 slide on the guide plate 131 to reach the bag portion U2A or the recess 113. In the present embodiment, the belt b that reaches the terminal side of the fairway 3 and the bottle p that is swept out to the end side of the fairway 3 are transported to the recovery mechanism 1 by the belt conveyor 101 and the guide plate 131. Handling device. Then, the distance W between the end portion Α1 of the guide portion 131 on the side of the recovery portion 100 and the rotary rotor 111 is smaller than the diameter of the ball B, and is larger than the maximum ❹ diameter of the bottle ρ. Further, the end portion 101A of the guide plate 131 is set at a position higher than the upper end U2B of the pocket portion U2A and lower than the upper end 113A of the recess portion US in the vertical (upper and lower) directions. Further, as shown in Fig. 2, the outer cover 130 covers only the bag portion U2A located at the lowermost end side from the belt conveyor 1〇1, and the bag portion 112A located at the lowermost end side is a bag opened from the upper side. . Then, by the outer cover 130, the bottle ρ which is dropped from the belt conveyor ι 〇 to the bag portion 112A is prevented from falling off from the bag portion U2A, and the plurality of ball bottles P can be prevented from entering the one bag portion 丨丨 2A. . 2013-9883-PF; Chentf 12 200934562 - Moreover, the air mask 130 completely covers only the bag portion. 112A, since the recess 113 is not completely covered by the outer cover 13〇, the ball B carried by the belt conveyor ι〇 It does not enter the bag portion 112A' but slides on the guide plate 131 and is housed in the crotch portion 113. Then, in the present embodiment, as shown in Figs. 2, 乜, and 4b, the outer cover ring i32 covering the outer circumference of the rotor is integrally formed on the outer cover 13A, and the outer cover ring 132 can be prevented from being accommodated in the ball. The bottle p φ of the pocket portion U2A flies radially in accordance with the inertial force (centrifugal force) of the rotation of the rotor U1. Further, in the present embodiment, the guide plate 131 is assembled as another element to the upper end portion i30A of the outer cover 130 (see FIGS. 4a and 4b). However, the present embodiment is not limited thereto, and the guide plate 131 may be The outer cover 130 is integrally formed. Further, the 'fixing plate 120 is disposed on the lower surface side of the rotor lu, and the closed bag portion 112A' is provided on the upper side of the fixed plate 12A. As shown in Fig. 2, the fixed plate 120 is provided to extend in the rotational direction of the rotary unit U1. The long-hole shaped slit 12 is formed as shown in Fig. 8a, and is a shape in which two kinds of long holes having different sizes in the short-side direction are connected in the long-diameter direction. Specifically, in the irregular slit 121, the short side of the first hole I3 1 21A on the retreating side (the right side of FIG. 8a) in the rotation direction; the dimension a is set to be larger than the straight dimension of the small diameter portion p 1 of the bottle p D1 (refer to Fig. 8b) is also larger and smaller than the diameter dimension D2 (see Fig. 8b) of the large portion μ of the bottle p. On the other hand, in the irregular slit 121, the second hole portion 121B in the rotation direction advancing side (the left side of the eighth drawing) has a dimension B in the minor axis direction that is set to be larger than the diameter D2 of the large diameter P2 of the bottle P. size. Therefore, in the first 13 2013-9883-PF;chentf 200934562, the hole portion 1 21A, only the small diameter portion P of the bottle P can pass through the shaped slit 1 21 'the large diameter portion P2 is stuck in the first hole portion i2U In the second hole portion 121B, the entire bottle P can pass through the irregular slit 121. Further, in the fixing plate 12, the portion of the irregular slit 121 is disposed between the standing portion and the rotating member 111. As shown in Fig. 6, a gap 122 is provided, and on the other hand, 'in the fixed plate 120 On the opposite side of the gap 1 22, a funnel-shaped guide member 123' is provided to introduce the bottle p dropped from the irregular slit ι21 into the bottle throwing projector 103. As shown in Fig. 5, the guide member 123' has a receiving surface 123A provided at a portion corresponding to the first hole portion 121A, and is in contact with the front end side of the bottle P passing through the first hole portion 121A (small diameter) The portion P1 side receives the bottle P, and has the inclined guide surface 123B' provided at a portion corresponding to the second hole portion 1 21B toward the rotation direction of the rotor 111 (the right side of FIG. 5). The lower side is lowered and tilted. Then, the discharge port 123C that communicates with the bottle projector 1〇3 is disposed at the lowest position of the inclined inclined guide surface 123B. Further, in the present embodiment, the center line of the discharge port 123C is viewed from the horizontal direction! ^ is shifted in the rotation direction advancing side (the right side of Fig. 5) with respect to the center of curvature 〇1 on the advancing end side in the rotational direction of the second hole portion ΐ2ΐβ. Further, the receiving surface 12 3A is formed on a plane which is expanded in the horizontal direction, and on the side of the boundary portion between the receiving surface 123A and the inclined guiding surface 123B, a resisting body 123D having a direction substantially parallel to the rotating direction of the rotor (1) is provided. The wall. Therefore, the front end side of the bottle p which is dropped from the first hole portion l2U is as shown in the figure 2013-9883-PF; and the picture shown in the figure of Chentf 14 200934562. 6 is engaged with the resisting body I23, that is, the resisting body 2" The obstruction element that moves the tip end side of the bottle p which is dropped by the first hole portion 121A integrally with the rotation of the rotator lu. The arrangement relationship between the first hole portion 121A, the bag portion 112A, and the receiving surface 123A is As shown in Fig. 6, in a state where the front end side of the bottle p is dropped from the first hole portion 121a, the upper outer edge portion 121C of the first hole portion 12ia contacts the bottle P, and the lower outer edge of the first hole portion 121A The portion 121D is in a non-contact state with the bottle p. Therefore, in a state where the tip end side of the bottle P is dropped from the first hole portion 121A, the center axis L2 of the bottle p is gripped on the upper side, and the bottle p is in contact with the first The outer edge portion 121c of the aperture 121A sandwiches the central axis L2 at the lower side, the bottle P contacts the rotator 111, and the contact portion 111C that is in contact with the rotator lu is located at a ratio of the first hole portion 丨2丨The contact portion 121E of the outer edge portion of a and the bottle p is also close to the position on the bottom side of the bottle p. Moreover, the guide member ί in the irregular slit 121 The α side, as shown in the nth figure, is provided with a cover 124 for closing the irregular slit 121, and the cover 124 is driven to be opened and closed by the motor 124B via the link mechanism 124A. The lower portion is further above and below the irregular slit 121, as shown in Fig. 8a, a long hole-shaped recovery hole 125 is provided, and the ball B stored in the concave portion 3 is transferred from the rotor 111. The lower side is taken out, and the ball collecting portion is formed by the collecting hole 25. Then, the "ball projector 1" (see Fig. 1) is assembled in a portion of the fixed plate 2 corresponding to the collecting hole 1 2 5 . Bottle handling mechanism 2013-9883-PF; Chentf 15 200934562 • Ball*·Bottle handling mechanism 200, as shown in Fig. 1, includes a bottle p in a horizontal direction with a bundle of balls The distribution mechanism 210 that distributes the distribution, the conveyance unit 230 that transports the bottle P that is aligned in the distribution mechanism 210 to the dispenser 250, and the guide bottle p are guided to a predetermined position of the bottle placement machine 300 to be described later. Dispenser 250, etc. 4. 1. Dispensing mechanism 210 Dispensing mechanism 210 is the outlet at the bottle projector 1 〇3 In a horizontal direction, the ball is reciprocated, and the ball bottle P is supported on the conveying belt 231 of the conveying unit 230 in a line. Specifically, as shown in Figs. 14a and 14b, the ball bottle is included. The projector fixing portion 201 to which the outlet side of the projector 103 is fixed, the bottle P that discharges the bottle projector 103, and the placement nozzle 202 placed on the conveyance belt 231 can support the projector fixing portion in parallel. 201 and a rail 203 on which the nozzle 202 is placed, a drive belt 204 that connects the projector fixing portion 201 and the nozzle 202, and a motor 205 that rotates the drive belt 204. Further, 'the placement nozzle 202 is provided with a sensor (not shown) for detecting whether or not the bottle bottle P has passed through the nozzle 202. When the sensor detects the passage of the bottle p, the motor 205 rotates the drive belt 204. The projector fixing portion 201 and the placement nozzle 202 are moved in parallel. In the present embodiment, the inlet side (the guide member 123 side) of the bottle projector 103 is fixed to the guide member 123, and the outlet side of the bottle projector 103 is attached to the length of the road 203. The direction moves back and forth. On the other hand, the 10 bottles placed on the conveyance belt 231 are placed in the conveyance direction of the conveyance belt 231 due to the fact that the 2013-9883-PF; Ghentf 16 200934562 .a has its front end on the lower side and the parallel direction. Preferably, the outlet of the mouth 202 is oriented in a direction parallel to the conveying direction of the conveying belt 23ί. Here, in the state of the present embodiment, the nozzle 202 is placed with the outlet direction often facing the conveying belt 23 The direction in which the conveying direction is parallel is moved on the road 203, and the projector

The shackle 201 swings with the swing fulcrum 2〇1 A as the swing center, and moves on the track position <Z03, and the size A of the inlet side of the placement nozzle 202 is larger than the bottle projector! n q h © The size C of the exit side of the Machi 13 is still large. Incidentally, the size of the inlet side of the placement nozzle 202 is artificial (considering) the size C of the outlet side of the bottle projector 103 plus the swing size of the projector fixing portion 201, which is larger than the placement of the mouthpiece 9Π9, c The size of the outlet side of the IT nozzle 2〇2 is still large. Further, in the present embodiment, the discharge direction of the bottle Ρ discharged from the bottle projector 103 is reduced by "the size of the inner wall is reduced smoothly from the inlet side to the outlet side of the mounting nozzle 202." It is swayed smoothly and parallel with the w transporting south of the conveyance belt 231. 4· 2. The transport unit transporting the early element 230 is to be carried in the fish transport direction by transporting the ancient 反 可 231 The rotation of 231 is universal. The 1 〇 ball bottle P, which is arranged in a line in the horizontal direction of the father, is conveyed to the upper side of the main body, and then supplied to the supply device of the dispenser 250. Then, 'the outside of the conveyance belt 231 , as shown in Fig. 15, a plurality of engaging projections 232 protruding outwardly are provided at a plurality of positions, and the engaging projections 232 are used by the dispensing mechanism. 210 is placed on the conveyance belt 231 2013-9883-PF; the bottle p of the Chentf 17 200934562 is conveyed to the upper side in the state of the card compartment (refer to the figure). Moreover, on the upper side of the conveyance unit 230, i. As shown in the figure, a plurality of root guides 233 are provided to prevent the carrying towel (4) bottle p direction If the inclination is too large, the guide pieces are ... looking for 51 pieces 233' on the transport side as shown in Fig. 15, extending from the longitudinal direction of the transport unit 23G to the other end side. The guide piece 234 is provided on the other end side of the longitudinal direction of the sheet 233 (the right end side of Fig. 15), and the bottle p is conveyed to the distribution along the outer peripheral surface of the driven roller 235. Further, the drive roller 236 rotates the conveyance belt 231, and the drive roller 236 rotates from the motor 237 to the driving force via a power transmission device such as a belt or a chain. On the other hand, since the driven roller 235 rotates in accordance with the rotation of the conveying belt 234, the driven roller 235 is rotatably attached to the tension lever 238, and the tension lever 238 is swingably attached to the frame. Then, the carrying roller The tension of the belt 231 is adjusted by the tension lever 238. 5. The bottle discharging machine The bottle discharging machine 300 arranges the plurality of bottles P carried by the bottle conveying mechanism 2 at a predetermined position of the fairway 3. In particular, as shown in Figure 1, it includes a dispenser 250 The bottle lifting device 3〇1, the bottle guiding lifting mechanism 350, etc. 5. The bottle lifting device bottle 301, as shown in Fig. 1, the device for raising the bottle p in the upright state to the fairway 3. In other words, it has a cylindrical root portion 3 0 2 that is filled in the state of the spherical bottle 1 > erect shape 2013-9883-PF; and a Chentf 18 200934562 * state, and a rising mechanism 340 that raises the cylinder portion 3 〇 2 5. 1 · 1. Ascending mechanism The upper lifting mechanism 34 includes a rising plate 341 to which the one-inch cylinder portion 302 arranged in three (pyramid) shape is fixed, and the rising plate 341 is raised and lowered. The chain 342 and the pull-up machine 343 which pulls the chain 342 and the like. Then, the chain 342 has one end side fixed to the rising plate 341, and the other end side is fixed to a fixing member such as the pull-up machine 343, and a motor (not shown) is provided on the upper pulling machine 343. The arm 344 that is rotationally driven and the movable sprocket 345 that is rotatably engaged with the front end side of the arm 344 and meshed with the chain 342 and the like. Further, in order to prevent the chain 342 from coming off the movable sprocket 345, the pair of idler sprocket 346 is given a predetermined tension of the chain 342, thereby rotatably fixing the fixing member such as the pull-up machine 343.

Then, the arm 344 is rotated, and the movable sprocket is moved in the direction of FIG. 1 or its opposite direction, and the rising plate 341 is moved up and down by the rotation of the arm 344 at twice the speed, thereby making the cylinder portion 3〇2 1.5.1 · 2. The cylinder portion 3G2' has a first cylinder 303 with the rising plate 341 2, and an upper end side of the first cylinder 3〇3 and the first cylinder 3〇3 as shown in FIG. ^The second cylinder of the member disposed in the frame or the like, and the piston 2〇l3-9883-PF in the position of the adjacent cylinder 303 in the length direction of the first cylinder 3〇3; Chentf 19 200934562 then 'at The first cylinder 3〇3矽 inner wall, as shown in Fig. 18, is provided with a first protrusion 3〇5 protruding from the inner side, and the upper end side of the first coil spring 3〇6 is engaged with the first protrusion Department 3〇5. On the other hand, the lower end side of the first coil spring 306 is fixed to the rising plate 341. Therefore, the first cylinder 3〇3 is connected to the rising plate 341 in a state where the first coil spring 306 is supported by the rising plate 341. Φ

Further, the 'piston portion 320 includes a pedestal portion 321 that contacts the bottom of the bottle ρ and supports the bottle ρ from the lower side, a push rod 322 that is fixed to the rising plate 341 and is fixed between the push rod 322 and the pedestal portion 321 . The second coil spring 323 and the like which are elastically deformable. Further, the holding member 324 is an element that is detachably attached to the upper end side of the push rod 322 via a connecting member such as a bolt 324β, and the pedestal portion 321 is movably inserted through a through hole 324α provided in the holding member 324. 325 is coupled to the push rod 322. Therefore, when the push rod 322 is raised, the upward displacement (rising force) of the push rod 322 (rising plate 341) is transmitted to the pedestal portion 321 via the second coil spring 323, and when the push 322 is lowered, the bolt 325 is used. The downward displacement (downward force) of the push rod 322 (rising plate 341) is transmitted to the pedestal portion 321. Further, on the lower end side outer wall of the first cylinder 303, as shown in Fig. 17a, a second protrusion 胄3G7 protruding from the outer side is provided, and on the other hand, at the lower end portion of the second known 3'4 The stopper portion 308 mechanically restricts the rise of the first cylinder 303 when the first cylinder 303 is raised by the second projection 307. Then, on the side of the second red 304, a filling port 3〇9 is provided for passing through the dispenser 25. The ball bottle p guided to the cylinder portion 3〇2 is loaded in the second 20 2013-9883-PF; the Chentf 200934562 cylinder 303 (cylinder portion 302), and the ball bottle loaded from the filling port 309 in the cylinder portion 3〇2• The P is housed in the first cylinder in a state where the pedestal portion 321 is upright. Further, at the terminal end side of the fairway 3, a push bottle is provided as shown in Fig. 171's in the portion corresponding to each cylinder portion 3? When the bottle P is pushed up to the fairway 3, the hole portion 3A is closed by the pedestal portion 31 as shown in Fig. 17c. In other words, when the state in which the first cylinder 303 is lowered (the state shown in FIG. 17a) rises to the rising plate 341, the first coil spring 3〇6 and the push rod 322 increase by the same amount, as shown in FIG. 17b. The two protrusions 3〇7 impact the stopper portion 308, the first cylinder 303 and the piston portion 302 are integrally raised, and then, when the second protrusion portion 307 impacts the stopper portion 308, the first coil spring 306 is contracted and deformed, and the first cylinder 303 stops rising. On the other hand, the push rod 322 rises integrally with the rising plate 341. As shown in Fig. 17c, the piston portion 320 rises in conjunction with the rising plate 341, and the pedestal portion 321 is filled in the hole portion 3A. At this time, in a state in which the pedestal portion 321 is filled with the hole portion 3A, the rising plate 341 stops rising and the size of each portion is set. However, after the hole portion 3A is filled in the pedestal portion 321 by the dimensional deviation in the dimensional tolerance, the pedestal portion 321 is raised. Plate 341 is likely to continue to rise. However, in the present embodiment, when the rising plate 34i continues to rise, this portion is absorbed by the second coil spring 323 (refer to Fig. 17 (Fig. 1), and the excessive lift force is prevented from acting on the fairway via the piston portion 320. 3. 5 · 2 · Dispenser dispenser 250 for the 10 bottles of P transported by the transport unit 230 to fall 2013-9883-PF; Chentf 21 200934562 and distributed to the filling port of the bamboo shoots 3〇2 3 〇 9 tons distribution In other words, the dispenser 250, as shown in Fig. 13, is configured to connect ten spherical bottle supply ports 251 arranged in a line and arranged at a position lower than the two bottle supply ports 251. In the present embodiment, the distributor 250 is composed of a flexible tube or a groove-shaped rigid body. Then, 10 bottles P are arranged by the transport unit 230. When the line is conveyed to the supply port 251, the ball bottle p is supplied to the bottle supply port 251 (distributor 250) at the same time. 5. 3. The bottle guide lifting mechanism is guided by the bottle. The mechanism 350, as shown in Figures 19a and 19b, has a bottle p that prevents lifting to the fairway 3 The bottle guide 351 that is dumped on the ball path 3 and the retracting mechanism 360 that retracts the bottle guide 351 from the ball path 3 (refer to Fig. 1). 5. 3. 1. Bottle guide ❿ Bottle guide 351' Fig. 19a shows 'the cup of the ball bottle P from the front end of the bottle p' in the ball guide 351, having the inner wall of the bottle guide 351 being pressed by the bottle P And the missing lever 352 holding the bottle p and the bottle sensor 358 as a detecting means for detecting the presence or absence of the bottle P by the displacement of the front end portion of the bottle p. Then '10 As shown in Fig. 22, the ball guide 351' is attached to the slightly pentagon-shaped lifting plate 353 in a triangular shape. That is, 'on the lifting panel 353', as shown in Fig. 19b, The 356A fixed ring-shaped fixture 356' ball navigation member 351 is slidably inserted from above with respect to the fixture 356 2013-9883-PF; and is stepped by the outer peripheral portion of the fixture 356. The protrusion 351A is engaged with the upper end surface 35 6B of the fixture 356. Then, the upper end side of the bottle guide 351 is often pulled up to the lift by a pair of coil springs 357. 353 side.···_ Therefore, the general lifting plate 353 and the bottle guide 351, as shown in Fig. 21a, are integrally raised and lowered, the bottle p is tilted and the bottle p is not filled in the bottle guide 351, In the case of interference with the bottle guide 351, as shown in the figure

The bottle guide 351 is isolated from the lift plate 353, and the bottle guide 351 and the lift plate 353 are lowered, respectively. Further, the movable plate 354 which is movable in parallel with respect to the lift plate 353 is attached to the lift plate 353. The actuator 355 which displaces the movable plate with respect to the lift plate 353 is attached to the lift plate 353. Each of the clamp bars 352 is coupled to the movable plate 354. Then, when the movable plate 354 is displaced to the left side of the 22g with respect to the lifting plate 353, as shown in Fig. 23b, the clamping lever 352 is separated from the ball p to release the clamping of the bottle P, and on the other hand, When the movable plate is displaced relative to the shoulder plate 353 to the right side of the 22nd figure, as shown in the figure, the ball n is pushed by the square clamping bar 352, so the bottle p is guided by the bottle guide 351# hold. H 2. The retracting mechanism retracting mechanism 360 is a machine for lifting and lowering the 1st ball guide 351; and then 'as shown in the second figure _ on the lower end side solid lifting plate 353 of the lifting guide 361, On the upper side of the lifter LT, A 353, as shown in Fig. 21; slidably contact the outer circumference of the lift guide # 361 to guide the lift guide 2013-9883-PF; the lift guide of the Chentf 23 200934562 The sheath 36 is fixed to the frame 4 by a beam 363, and can be raised and lowered by sliding the lifting guide 361. Further, the upper end side of the pair of lifting guides 361 is supported by the beam 363. When the lifting guide 361 is moved up and down, the size between the lifting guides 361 is constant, and the lifting guide 361 and the end side of the chain 364 are connected to each other. The high plate 353 (see Fig. 21) has the other end side of the chain 364 fixed to the frame 4 side (see Fig. i). Then, the high plate 3 5 3 system 蕻ώ I μ, +, l burdock eclipse is the same as the above-mentioned ascending mechanism 34 的

Method of lifting. 6. The rough motion of the bowling game device (Bilib〇 (registered trademark)) is the ball bottle p and the ball B that are knocked down by the player B, or the ball bottle P and the ball B that are swept out by the sweeping mechanism 400. As shown in the figure 及 and the first 〇 & 〜 l 〇 c, after the conveyance mechanism 1 is conveyed by the belt conveyor 101, the recovery mechanism 100 collects the ball β and the bottle p. Then, the recovered bottle ρ is sorted to the same direction as the falling from the irregular slit 121, and then guided to the transport unit 230 via the bottle projector 103, on the one hand, the recovered ball β rises from the lowermost portion of the rotor ill to After the higher position, it is guided via the ball projector 105 to the return projector 1〇6. Further, the bottle ρ supplied from the transport unit 230 to the dispenser 250 is loaded into the first cylinder 303 and then raised to the fairway 3. At this time, the ball guide 3 is lowered on the fairway 3, and the rising ball bottle is loaded from the lower side to the bottle guide 351 to be placed on the fairway 3. Then, when the pedestal portion 31 closes the hole portion 3 of the ball path 3, the bottle guide 351 retreats from the ball way 3 to the upper side', and the game can be played again. 2013*9883-PF; Chentf 24 200934562 - 7. Characteristics of the bowling game device according to the present embodiment. In the present embodiment, the bag portion 112A that is the bottle transfer portion that transports the bottle P is provided on the rotator. Since the concave portion 113 of the ball transfer portion of the ball B is transferred, the number of components of the recovery mechanism 100 of the bottle P and the ball B can be reduced to form a simple structure. Further, in the present embodiment, the end portion of the guide piece 131 that transports the ball β that has reached the end of the fairway 3 and the bottle p that has been swept out to the end of the fairway 3 to the transport device of the recovery mechanism 100 is configured. The distance between the cymbal and the rotor U1, as shown in Fig. 9a, is smaller than the diameter of the ball B and larger than the maximum direct control of the bottle 15. Further, since the end portion i〇iA of the guide piece 131 is set in the vertical direction at a position higher than the upper end 112B of the pocket portion 112A and lower than the upper end 113A of the concave portion 113, as shown in Fig. 1A As shown in Fig. 1c, the bottle P is dropped from the gap between the guide piece 131 and the recovery mechanism 1〇0 (rotator U1) and stored in the bag portion 112A'. On the other hand, the ball B, as shown in Figs. 9a to 9c As shown, ® does not fall from the gap and is accommodated in the recess 1 1 3 . Therefore, even if the bottle P and the ball B are transported to the recovery mechanism 100 in a mixed state, the bottle P and the ball B can be separated and easily recovered. Further, in the present embodiment, as shown in Fig. 9b, the concave portion 113 is formed by recessing a concave portion in a direction parallel to the rotation axis U1A by the side surface 111B of the square rotor 111, and since the side surface 丨丨1B is opposed Since the opening of the recessed portion 113 is opened upward by tilting horizontally, the ball B is held by the bottom portion 113B of the recessed portion j丨3 and the inner peripheral side surface 113C. On the other hand, if the side surface i丨1B of the rotor 111 is vertical, since 2〇13-9883-PF; Chentf 25 200934562 ball B needs to be held only by the inner peripheral side surface 113C of the concave portion 113, the concave portion 1 i 3 # I The depth dimension of the mine does not need to be enlarged. Therefore, in the present embodiment, the thickness of the rotor 111 can be made thinner than when the side surface n 1B of the rotor 111 is staggered. In the present embodiment, the dimension A in the minor axis direction of the first hole portion 121A on the retreating side in the rotation direction of the irregular slit 121 is larger than the diameter of the small diameter portion P1 of the bottle p, and is larger than the spherical bottle. The diameter of the large diameter portion P2 of the p is small, and the dimension B in the minor axis direction of the second hole portion 121B on the side in the rotation direction of the irregular slit 121 is set to be larger than the diameter of the large diameter portion p2. In the present embodiment, the small-diameter portion P1 side of the bottle p is located on the advancing side of the rotor 111 in the rotation direction, and when the bottle p reaches the profiled slit 121, as shown in FIG. 5, it is small. When the diameter portion P1 reaches the first hole portion 121A and the large diameter portion P2 is engaged with the first hole portion 12U, the small diameter portion P1 is lowered, and the large diameter portion P1 is dropped from the first hole portion 121A. The portion P 2 rises to rotate the bottle p. In other words, in a state where the bottle p is stored in the bag portion 112A, as shown in Fig. 25, the center axis L2 of the bottle P is opposite to the large-diameter portion p2 and the bag.

a _ slave r, the front end of the spare bottle P reaches the profiled slit 121

The small diameter portion P1 is lowered from the first hole 5 and the sixth figure, 2013-9883-PF; Chent 26 26, 2009, 562, part 121A, and the small diameter bottle P is rotated. When the ball first hole portion is raised, the irregular slit ΐ2ι is not moved on the fixing plate 120, and the large diameter 杳p p2 and the first hole portion are not in the point), and the ball bottle P and the rotor m are prevented from being generated. A 'Wu moving force (braking force). On the other hand, since the bottom side of the bottle P is pushed by the rotator 1U, the 2nd speed brake point is centered, and the bottom of the bottle P is advanced in the rotation direction.

Turning, the large control portion P2 is located closer to the forward side in the rotational direction than the braking point. That is, the large-diameter portion P2 is located closer to the forward side in the rotational direction than the small-diameter portion ρι. At this time, the bottle P is located at a position shifted from the braking point toward the bottom side, and receives a force that is advanced in the rotational direction from the rotor m to receive a force in the backward direction in the rotational direction at the braking point (falling preparation state). After moving to the second hole portion 121B, the large diameter portion P2 reaches the second hole portion before the small diameter portion ρι. Therefore, when the large-diameter portion P2 reaches the second hole portion 121B, the large-control portion P2 in the bottle p is lowered, and the small-diameter portion P1 is raised to be rotated and dropped. On the other hand, in a state where the large-diameter portion P2 side of the bottle P is located at the position on the forward side in the rotation direction of the rotary sub-turn, when the bottle p reaches the irregular slit 121, only the small-diameter portion P1 is from the The one hole portion 121A is dropped, and the bottle bottle P is moved to the second hole portion 121B in the above-described drop preparation state. Therefore, when the large diameter portion P2 reaches the second hole portion 121B, as described above, the large diameter portion P2 of the bottle p is lowered and the small diameter portion P1 is raised to drop the bottle p. Thus, in the present embodiment, the movement direction of the bottle p is not reversed, 2〇13-9883-PF; and the Chentf 27 200934562 causes the bottle P to be aligned in the same direction by rotating the bottle P, by acting on the ball The inertial force of the bottle P, the problem of the bottle P passing through the profiled slit 121 does not occur in principle. Therefore, in the present embodiment, the recovery rate of the bottle p can be improved without deteriorating the recovery rate of the bottle p.

For example, in the invention of Japanese Laid-Open Patent Publication No. H-333044, when the small diameter Deng P1 is located on the forward side in the rotational direction and the bottle p is transported, the bottle p is dropped after the conveyance direction is reversed. On the other hand, in the case where the large-diameter portion P2 is located on the advancing side in the rotational direction and the ball bottle P is transported, the bottle P is dropped in the invention, and the present invention is disclosed in Japanese Laid-Open Patent Publication No. Hei No. 1-1-3044044. The rotation of the rotor m: speed-determined, the period (timing) of the drop of the bottle P from the drop hole depends on the state of the ball p delivered to the drop hole. In the invention of Japanese Laid-Open Patent Publication No. 333044, the small diameter portion P1 is located on the forward side in the rotational direction to transport the bottle. In the case where the diameter portion P2 is located on the advancing side in the rotational direction and the ball is transported, the timing at which the spherical bottle P falls from the falling hole is changed later. In the invention of the Japanese Patent Publication No. H-333044, the bottle bottle p collected by the receiving mechanism 1〇0 is also changed when it is transported to the bottle discharging machine _, so that the bottle discharging machine 3 is easily caused. Awkward mistakes. In the embodiment 1: in the embodiment, in the case where the small bottle is in the direction of rotation before the ball bottle P is carried, the bottle p is in the first: 21: in the state of being ready to fall, and at the same time, moving to the first = so small When the control unit P1 is located on the advancing side in the rotational direction and transports the bottle p 2〇13-9893-pF; in the case of the Chentf 28 200934562 * · •, and the large-diameter portion P 2 is located on the advancing side of the turning direction and transports the bottle p, The timing at which the ball bottle P falls from the second hole portion 12ΐβ is almost the same. Therefore, in the present embodiment, the timing change of the bottle cylinder 〇〇 recovered by the recovery mechanism 1 Ρ when it is transported to the bottle arranging machine 300 is reduced, so that the bottle stop machine 3 Q 0 can be malfunctioned. Further, in the present embodiment, since the gap 122 is provided between the portion where the irregular slit 121 is provided in the fixed plate 120 and the rotator lu, the contact portion of the bottle ρ 〇 and the rotator 111 is subjected to the movement of the bottle p The distance between the force portion and the braking point can be made large. Therefore, the torque required to rotate the bottle P from the small-diameter portion P1 side of the bottle p on the forward side in the rotation direction of the rotor 111 to the drop-prepared state becomes large, and the bottle P is surely in the drop-prepared state. The state moves to the second hole portion 121B. Therefore, in the present embodiment, the recovery rate of the bottle 1> is not deteriorated, and the speed at which the bottle p is recovered can be improved. Further, in the present embodiment, the distal end side of the bottle p 落 that has fallen from the first hole portion 121A is provided with a resisting body 123D that blocks the 7L member from moving along with the rotation of the rotator 111. In the present embodiment, the front end side of the bottle p is dropped from the first hole portion 121A, and the tip end side of the bottle p is prevented from being moved to the falling state. As shown in Fig. 6, the center axis L2 of the bottle p is clamped, and the upper end edge portion 121C' of the first hole portion i2u is brought into contact with the center axis of the bottle bottle P on the upper side. And on the lower side to make the bottle? While contacting the rotor 111, the contact portion with the rotor ηι is located at a ratio of 2013-9883-PF; Chentf 29 200934562 'brake point (contact portion of the outer edge portion of the first hole 121A and the bottle P) Near the bottom side of the bottle P. Therefore, the bottle P which is in the ready-to-fall state is suppressed and cannot fall to the opposite side of the falling direction, that is, it falls to the side opposite to the fixed plate 120, so that the bottle P can be made. The following drop preparation state is moved to the second hole portion 121B. Therefore, the recovery rate of the bottle p does not deteriorate, and the recovery speed of the bottle P can be improved. φ Further, in the present embodiment, since the bottle P is dropped from the dispenser 250 and guided to the filling port 3〇9 disposed at a predetermined position (i.e., a triangle), the ball is compared with the arm that is swung and retracted. The bottle P is supplied to a predetermined position, and the invention disclosed in Japanese Laid-Open Patent Publication No. Hei No. 333044 can reduce the number of components of the bottle placing machine 300 to form a simple structure. Further, in the present embodiment, the transport unit 230 serving as the supply means for supplying the bottle P to the dispenser 25 is capable of simultaneously supplying the bottle p to the plurality of distributors 250, and the plurality of bottles p can be By supplying the configuration in a short time, the processing speed of the bottle discharging machine 300 can be improved. Further, in the present embodiment, since the bottle guide 351 for preventing the bottle P rising to the ball path 3 from falling on the ball path 3 is prevented, the bottle p placed on the ball 3 can be prevented from falling. Further, in the present embodiment, since the loading port 309 for loading the bottle p to the side surface of the cylinder portion 302 (second red 304) is provided, the bottle P can be loaded into the cylinder portion 302 in a short time (first Cylinder 303). That is, in the present embodiment, since the first cylinder 303 is raised, the ball 2013-9883-PF; the Chent 30 200934562 ·, the bottle P is placed on the fairway 3, so as the Japanese nose special opening 2002-1 1 9634 In the case where the filling port is located at the upper portion of the cylinder portion, in order to prevent the ball bottle (the bottle for the next filling) to be loaded in the lower portion from interfering with the red portion when the red portion is six liters 'The lower-loading bottle must stand by in the standby position that is misaligned from the filling port. Therefore, in the invention disclosed in Japanese Laid-Open Patent Publication No. Hei 2 No. Hei. No. Hei. No. 2-9634, when the bottle is filled in the cylinder portion, it is necessary to use the next filling.

The ball is moved from the standby position to the filling port, and even if the cylinder is lowered, the bottle cannot be directly loaded into the cylinder. On the other hand, in the present embodiment, since the loading port 3〇9 is provided on the side surface of the second cylinder 304, it is not necessary to place the loading bottle P at the position shifted from the loading port in the loading operation of the next bottle p. Stand by. Therefore, at the time of the next loading operation, it is not necessary to move the bottle 卩 from the standby position to the loading port 309, and the ball cylinder P for the next loading can be loaded into the cylinder portion 302 while the first cylinder 3〇3 is lowered. One cylinder 3〇3), so the bottle P can be loaded into the red part 3 〇2 in a short time. Further, in the present embodiment, the first cylinder 3〇3 and the piston portion 32〇 are integrally raised by a predetermined amount, and the spherical bottle p is pushed from the hole portion 3A provided in the fairway 3 because only the piston portion 32 is raised. When the ball is moved to the fairway 3, the ball portion p is raised to the vicinity of the fairway 3, and the piston portion 320 raises only the bottle p to the fairway 3. Further, in the present embodiment, the second coil spring 3 2 3 as the elastic deformation portion and the dimensional deviation of the pedestal portion 321 and the assembled dimensional deviation increasing mechanism 340 are provided between the pedestal portion 321 and the push rod 322. Can be second line 2013-9883-PF; Chentf 31 200934562

❹ Ring spring 323 absorbs. Further, in the present embodiment, since the coil spring 357 is provided, the ball guide 351 is connected to the retracting mechanism 360 side, and the elastic portion that can be elastically deformed in the vertical direction is changed to each other. The guide is displaced in the up and down direction. That is, in the state where the bottle ρ is tilted, when the bottle guide 35 135 is lowered, the poured bottle does not interfere with the ball member 351, and the bottle guide 351 cannot be completely lowered, but for the other The lowering action of the bottle guide 351 has an adverse effect. In the present embodiment, as shown in b of Fig. 21, even if the poured bottle P interferes with the bottle guide 351, since it can be absorbed by the coil spring 357, the other bottle guide 351 can be prevented. The falling action has a bad effect. Further, in the present embodiment, the pull-up machine 3A for raising and lowering the rising plate 341 and the retracting mechanism 36G for raising and lowering the lifting plate 353 are constituted by a crank mechanism that rotates by the arm, so that the displacement starts and the displacement ends. The displacement speed becomes smaller. Therefore, at the start of the deformation and at the end of the deformation, since the large If force can be suppressed from acting on the rising plate 341 and the lift plate 353, the rising plate 341 and the lifting plate 353 can be smoothly displaced. (Second Embodiment) In the first embodiment, the outer cover ring 132 is integrated with the outer cover 13A. However, in the present embodiment, the outer cover ring 132 is integrated with the rotary unit lu to form the closed pocket portion 112A. The shape of the outer peripheral side. 32 2013-9883-PF; Chentf 200934562 - In this embodiment, when the rotor 111 is turned green, it is possible to prevent the bottle P stored in the bag portion 2 from being wiped over the cover ring 132 and transferred to the profiled slit. The side of the 121 side can reduce the noise generated when the bottle P is transferred, and at the same time, the abrasion of the bottle P and the outer cover ring 132 can be suppressed. (Third Embodiment) In the present embodiment, the recovery rate of the bottle in the collecting unit 110 can be further improved. Hereinafter, the present embodiment will be described together with the drawings. φ Moreover, Fig. 26 is a front view of the recovery mechanism 100. Figure 27 is a front elevational view of the fixed plate 120. Figure 28 is a front elevational view of the fixed plate 120. Fig. 29a is a view of Fig. 28 viewed from the direction of the arrow D, and Fig. 29b is a view of the right side of Fig. 29a. Figure 30 is a cross-sectional view of the rotator hi. The 31st & figure is a front view of the outer cover 13A. Fig. 31b is a view seen in the E direction of Fig. 31a. Figures 32 to 39 are diagrams of the operation of the recycling mechanism. Figs. 33b, 34b, 35b, 36b, and 39b are views of the arrows 33a, 34a, 35a, 36a, and 39a, respectively, viewed from the direction of the arrow (viewed from the outer side in the radial direction). Fig. 4 is a cross-sectional view taken along line 40-40 of Fig. 26. Fig. 41 is a cross-sectional view taken along line 41-41 of Fig. 26. Fig. 42 is a view for explaining the effect of the concave portion U2F. 1. The structure of the feature of the bowling game device according to the present embodiment is as shown in Fig. 26, and the side of the rotation center 01 of the irregular slit 121 is larger than the bottom 112 of the pocket portion 112A to be enlarged to the center of rotation. On the one side, the dimension A and β in the short-diameter direction of the irregular slit 121 (see FIG. 27) are larger than the above-described embodiment, and as shown in the figure, 2013-9883-PF; Chentf 33 200934562 The portion of the outer sound ring 132 corresponding to the irregular slit 121 is cut and lifted. In the present embodiment, the substantially short-diameter dimension AK of the first hole 胄 mA formed by the rotor (1) and the irregular slit 121 Referring to Fig. 26), about 9.9 times the diameter dimension D2 of the large diameter #p2 of the bottle p (refer to Fig. 8b), the second hole portion 121B composed of the rotator (1) and the irregular slit i2i The substantially short-diameter direction β1 (see Fig. 26) is approximately twice the diameter dimension D2 of the large-diameter portion p2 of the bottle p.

❹ Again, the depth of the pocket portion 112A, that is, from the rotor! As shown in Fig. 28, the size of the outer peripheral surface to the bottom portion 112G of the i-turn is set such that the depth dimension d1 of the advancing side of the rotor 111 in the rotational direction is larger than the depth dimension d2 of the rear end side in the rotational direction. Therefore, in the present embodiment, the side wall 112D of the side wall in the rotation direction of the pocket portion i2A extends in a direction slightly parallel to the radial direction from the center of rotation 〇1, and the side wall on the side in the direction of rotation The 丨丨2E extends in a direction parallel to the direction slightly orthogonal to the bottom 112C. Then, on the side of the fixing plate 120 in the side wall u 2D on the retreating side, on the side of the outer cover ring 132, as shown in Figs. 29a and 29b, a recess 112F is provided. The recess 112F is set to be only the bottle p. The size 0 which can be filled in the front end portion, that is, as shown in Fig. 37a, when the bottle p is stored in the bag portion ii2A and the front end side of the bottle P is in contact with the side wall 1丨2D on the retreating side in the rotation direction, In the state in which the front end side of the bottle p is filled in the concave portion 112F as shown in Fig. 37b, the bottle P is transferred to the irregular slit 121. On the other hand, the bottom of the bottle P is in contact with the side of the retreating side of the rotation direction 2013-9883-PF; the Chentf 34 200934562 wall 112 D 'when the bottle p is stored in the finding piece; when the bag is 112A, as in the 32nd As shown in the figure, the bottom side of the bottle p is not filled in the recess n2F but transferred to the profiled slit 121. Further, in the edge portion of the concave portion 113 for transferring the ball B, a chamfered portion u 3D is provided on the opposite side of the fixing plate 12A as in the case of the 30th ϋ - 冈, and the chamfered portion 113D is used. The depth d3 of the recess m杳d is substantially smaller than the thickness Η of the rotor 111. Further, the substantial depth d3 of the concave portion m d is the size of a portion which is held by the ball r in the inner peripheral side surface 113 C of the concave portion 113.部位 The portion corresponding to the pocket portion 112Α of the mouth plate 120 is closer to the rotation direction than the irregular slit 121. As shown in FIG. 4G, a projection 12GA protruding from the rotor m side is provided, and the projection is provided. In the present embodiment, the ship's head such as a 胄P bolt or the like is formed in a curved shape and attached to the fixed plate 120. Further, on the opposite side of the fixed plate 120 in the rotor 111, as shown in Fig. 41, a stirring portion 111D for mixing the plurality of ball bottles P remaining on the lower end side of the rotor (1) is provided. In the present embodiment, the substantially short-diameter dimension A1 of the first hole portion 121A formed by the rotor ln and the irregular slit 121 is enlarged to approximately the spherical bottle. Diameter size of the large diameter portion P2 of P! When the bottom side of the bottle P is located on the retreating side in the rotation direction and is stored in the bag portion 11 2A, it is transferred to the irregular slit 121, and the large diameter portion p2 of the bottle P is lowered to The bottle p is dropped in a state where the small diameter portion P1 is below the position. In other words, the bottle P that is placed on the retracted side of the rotation side and accommodated in the bag portion 丨丨28 is transferred to the irregular slit 121 2013-9883-PF as shown in Figs. 32 to 33a; Chentf 35 200934562 ' ♦..

When the small-diameter portion P1 of the bottle P reaches the first hole portion 121A as shown in Fig. 33b, the front end side of the bottle P falls from the irregular slit 121 to the side of the guide member 123 and falls. At this time, the gap size A1 is enlarged to about the size D2 of the large diameter portion P2 of the bottle-p. 9 times 'when the leading end side of the bottle p starts to fall from the irregular slit 121 to the side of the guiding member 123 In the case of the 34th and the mth diagrams, the bottle P has the large diameter portion p2 as the upper side and the small diameter portion P1 as the lower side due to the gravity acting on itself, and the vertical direction is reversed. Then, when the rotor 1U is rotated in this state, the frictional force generated in the outer edge portion of the first hole portion 121A and its contact portion 121E with respect to the bottle p (refer to FIG. 34b) and the rotation of the rotor 111 As shown in Figs. 35a and 35b, the large-diameter portion P2 side of the bottle P is located closer to the forward side in the rotational direction than the small-diameter portion P1 side, and the moment acts on the bottle p. Therefore, in the large-diameter portion P2 of the bottle P, the bottle p is transferred to the second hole portion © 121B in a state where the rotator 1U is engaged with the outer edge portion of the first hole portion 121A, and the large-diameter portion P2 When the second hole portion i21B is reached, as shown in FIGS. 36a and 36b, the entire bottle p is dropped from the profiled slit 121 to the guide member 123, and the large diameter portion P2 is located below the small diameter portion pi. It slides up into the bottle projector 103. Therefore, even if the bottom side of the bottle P is located on the retreating side in the rotation direction and is stored in the bag portion 112A, the large-diameter portion p 2 of the bottle P can be positioned in the smaller-diameter portion p even if it is transferred to the irregular slit 121. 1 The bottle P is dropped in the lower state. Further, the distal end side of the bottle P is located on the retreating side in the rotational direction and is stored in 2013-9883-PF; in the state of the chest pocket portion 112A, as shown in Figs. 37a and 37b, in the bottle. When the front end side of P is filled in the recessed portion .112F, the bottle p is transferred to the irregular slit 121. In the case of the 'the front end side of the bottle P, the concave portion 112F provided on the side of the outer cover ring 132 in the side wall 112D on the retreating side of the rotation direction is filled with A. As shown in Fig. 38, the front end side of the bottle P is self-shaped. The offset portion of the slit 121 is slidingly deformed. Therefore, the small diameter portion P1 side of the bottle P does not fall from the irregular slit 121 to the side of the guide member 123. When the entire bottle P moves with the rotation of the rotator hi, when the large diameter portion P2 reaches the second In the hole portion 121B, as shown in FIGS. 39a and 39b, the entire bottle P is dropped from the irregular slit 121 to the position where the large diameter portion P2 of the guide member 123' is located below the small diameter portion P1, and The bottle projector 103 slides down. When the bottom of the bottle P is located on the retracted side in the rotation direction and is stored in the bag portion 112A, when the bottle P is transferred to the irregular slit 121, the large diameter portion P2 of the bottle P is as described above. The small-diameter portion Pi becomes the lower side and the upper and lower jaws are reversed. However, since the rotator 111 is frequently rotated, as shown in FIG. 34b, the front end side of the bottle bottle P is dropped to the first hole portion 121A, and the ball is The bottle p jumps and is most likely to vibrate in the direction of the arrow. Then, when the bottle P is bouncing and vibrating, the outer cover ring 132 collides with the large diameter portion P2 of the bottle p, and the bottle p cannot be surely dropped to the guiding member 123. On the other hand, in the present embodiment, since the notch corresponding to the irregular slit 121 is cut out in the portion of the outer cover ring j32, the outer cover ring ι32 does not collide with the large-diameter portion P2 of the ball tiling p, and can surely make The bottle p is dropped into the guiding member 123. 2013-9883-PF; Chentf 37 200934562 ' In addition, in this embodiment, since the outer cover ring 132 can be prevented from colliding with the large diameter portion P2 of the bottle P, the portion of the outer cover ring 132 corresponding to the irregular slit 121 is not The portion of the outer cover ring 1 32 corresponding to the irregular slit 1 21 can be formed as a shape which is separated from the rotary sub-turn 1 and is expanded radially outward. In the present embodiment, the side wall 112D on the retreating side in the rotation direction is fixed to the side of the plate 120, and the recessed portion 0 112F' in which the tip end portion of the bottle p is filled is stabilized. It can be accommodated in the bag part 112A. That is, as shown in Fig. 8b, since the diameter of the bottom of the bottle p from the large diameter portion p2 is gradually reduced, as shown in Fig. 42, when the force F acts on the bottom side from the large diameter portion P2, the front end of the bottle P The department is floated from the state shown by the solid line to the state shown by the broken line. Therefore, when the other bottle P hits the bottom side of the large-diameter portion P2 of the bottle P accommodated in the bag portion 11 2A, the front end side of the bottle p to be stored floats from the fixed plate 1 2 0 . In the case where the bottle is stored in the bag portion 112A so that the distal end side of the bottle p is located at the position on the retreating side in the rotation direction (see FIGS. 37a and b), the bottle is supported on the front end side of the bottle P. P, when the front end side of the bottle p is lifted from the fixing plate 120, the recovery rate of the bottle p which is stored in the bottle portion U2A from the bag portion U2A is lowered. On the other hand, in the present embodiment, the recessed portion 112F in which the tip end portion of the bottle p is inserted is provided on the side of the fixing plate 120 on the side wall 112 of the reversing side in the rotation direction, even if the position of the other bottle p is larger than that of the large diameter. The portion p2 is also close to the bottom side, and it is also possible to suppress the front end side of the bottle P from floating up from the fixing plate 12. Therefore, 2013-9883-PF; Chentf 38 200934562 ’ can suppress the bottle P that is stored from falling from the bag portion 11 2A, and can avoid the reduction of the recovery rate of the bottle P. Further, the bottle P is stored in the bag portion 1 i 2A, and in the state in which the bottom side of the bottle P is located on the retreating side of the rotation height, the state of the bottle P is stabilized, and the position of the other bottle P is more than that. The large diameter portion P2 is also close to the bottom side. The bottle P also hardly falls from the bag portion Π 2A. In the case where the depth dimension of the concave portion 113 is sufficiently large, the bottle p is filled in the concave portion 113 and transferred. Here, in the present embodiment, the chamfered portion 113D is provided on the opposite side of the fixing plate 120 in the edge portion of the concavity and concave portion 113, whereby the substantial depth d3 of the concave portion 113 is smaller than the thickness Η of the rotor 111. The ball bottle P is prevented from being filled in the concave portion 113 and transferred. Further, if the thickness Η of the rotor 111 becomes small, it is not necessary to provide the chamfered portion 113D'. When the thickness η of the rotor 111 becomes small, since the bottle ρ is not easily fallen from the pocket portion 112, the bottle can not be transferred to the profiled narrow portion. Seam 121, the recovery rate of the ball bottle is reduced. In this regard, although the rotor 111 having the thickness Η of the outer peripheral side (the pocket portion 11 2 Α side) of the rotor 111 and the thickness Η on the concave portion 113 side can be solved, in the solution, the 'rotator 1 丨The shape of 1 becomes complicated, which causes the manufacturing price of the rotor 111 to rise. However, in the present embodiment, a simple method of providing the chamfered portion n 3d on the opposite side of the fixed plate 120 from the edge of the recessed portion 3 prevents the manufacturing price of the rotor 111 from increasing while When the bottle ρ is filled in the recess 113 and transferred, the bottle P can be prevented from falling from the bag portion u 2A. The bottle ρ that is stored in the bag portion i丨2A in an incomplete state is transferred to 2013-9883-PF; Chentf 39 200934562 • · 'The profile is narrow 121' because the bottle P is not as described by the profile When the slit 121 is dropped, the bottle P cannot be recovered normally, resulting in a decrease in the recovery rate of the bottle. In the present embodiment, the portion of the fixing plate 120 corresponding to the bag portion Qin 11 2A is provided with the protruding portion 120A, which is located closer to the % reverse direction than the irregular slit 121. Therefore, it is incomplete. The bottle p stored in the bag portion 112A in the state can be actively dropped from the bag portion 112A before being transferred to the irregular slit 112, and the recovery rate of the bottle P can be improved. In other words, the bottle is stored in the bag portion 112A, and the bottle is in contact with the fixed plate 120 at two positions of the small diameter portion Ρ1 and the large diameter portion Ρ2. On the other hand, in the incomplete state, the ball bottle 收纳 accommodated in the bag portion 112 is in a state in which only one of the small diameter portion pi and the large diameter portion ρ2 of the bottle ρ comes into contact with the fixed plate 120. Therefore, in the bottle bottle 收纳 which is accommodated in the bag portion 112 不 in the incomplete state, for example, the front end side of the bottle Ρ is likely to protrude from the rotator 111 on the opposite side (hereinafter referred to as the front side) of the fixed plate 12 〇. Therefore, even if it is transferred to the & shaped slit 121, as described above, there is a high possibility that it does not fall from the irregular slit 121. On the other hand, in the present embodiment, since the protruding portion 120A is provided, the front side of the bottle bottle is pushed by the protruding portion 120Α before the ball bottle reaches the irregular slit 121. Therefore, the bottle P accommodated in the bag portion u 2Α in the incomplete state can be prevented from being sent to the irregular slit 121 in advance, so that the recovery rate of the bottle ρ can be improved. Further, the bottle ρ accommodated in the bag portion 11 2A in the full state is also pressed against the front side by the protruding portion 120 A, and is housed in the bag portion 2013-9883-PF in the full state; Chentf 40 200934562 112A Since the bottle p is in contact with the fixing plate 120 at two portions of the small diameter portion p 1 and the large diameter portion p2, it does not fall from the bag portion η 2A. When the plurality of ball bottles remaining on the lower end side of the rotor 111 are aligned neatly, the recovery rate of the bottle P is lowered because the retained bottle is difficult to enter the bag portion 丨丨2Α·.

In the present embodiment, the stirring portion 111D is provided on the front side of the rotor, and the plurality of ball bottles P staying on the lower end side of the rotor U1 are stirred by the stirring portion 111D. Therefore, since the plurality of ball bottles ρ which are retained on the lower end side of the rotor 111 can be prevented from being aligned neatly, the recovery rate of the bottle p can be prevented from being lowered. (Fourth embodiment) The present embodiment relates to a mounting structure of a bracket for attaching various members to the bowling game device 1. Hereinafter, the present embodiment will be described by taking a case where the bracket _ is attached to the side surface of the fairway 3 in the bowling game device i. Further, Fig. 43 is a side view showing the appearance of the bowling game device i. Fig. 44 is a cross-sectional view of the side frame 610 ("the line cross-sectional view" of Fig. 43. Fig. 45a is a front view of (4)_, and Fig. 45a is a side view of the bracket_" Fig. 45c is a bracket 60. Fig. 46 is an explanatory view of the mounting of the bracket_. Fig. 47 is a bracket 6〇. A cross-sectional view of a state of being mounted on the side frame 6〇 is a sectional view along the line 47-47 of Fig. 43. In the bowling game device 1, as shown in Fig. 43, the length (four) of the fairway 3 is provided on the side surface of the fairway 3, and the side frame 61 is in the side frame 6. The second frame extension side frame τ fork As shown in the figure of the assembled portion 44 of the crucible 600, there are provided a pair of opposing groove portions 2013-9883-PF which are spaced apart from each other at a predetermined interval; Chent f 41

Size W2 setting therefore bracket 600 200934562 " 611, 61 2. In addition, in the present embodiment, the pair of groove portions 611 and 612 also extend in the same direction as the side frame 610, and the groove portions 6U and 612 and the side frame are made of a metal material such as a metal frame. It is integrally formed by processing or drawing. Further, as shown in Fig. 45a, the bracket 600 includes a mounting portion 601 for mounting various members, and a fitting plate 6 on which the document mounting portion 601 is provided while being fitted and fitted with a pair of groove portions 611 and 612. 〇 2 and so on. Then, the size (hereinafter referred to as the same size) 2 that is fitted between the groove portions 611 and 612 of the fitting plate 602 is set to be larger than the dimension W1 between the pair of groove portions 6A and 6丨2 (see 44 mesh) A slightly smaller size, @时如帛45. As shown in the figure, a chamfer 6 〇 3 having a diagonal size W3 and a height dimension W2 which are substantially the same size is provided on the diagonal portion of the fitting plate 602. Therefore, when the bracket 600 is attached to the side frame 61, as shown in Fig. 46, the bracket 600 is rotated from the tilted state (the state shown by the broken line) to the state shown by the solid line, so that the chamfer 603 is opposed to the groove portion 611. 612 is slightly parallel, whereby the fitting plate 602 can be filled into the groove portions 611, 612. In the present embodiment, since the height of the fitting plate 6〇2 is slightly smaller than the dimension W1 between the pair of groove portions 611 and 612, it can be moved along the longitudinal direction of the groove portions 611 and 61 2 . 6 1 0, the limit plate 6 3 in the longitudinal direction of movement, as shown in Fig. 43, the two sides of the clamp are mounted, and the support bracket 6 is attached to the side frame. In the present embodiment, the side frame 610 is Between brackets 600. Fill-to-groove portion 611, 612 2013-9883-PF; Chentf 42 200934562 ' • Moreover, since the restricting plate 630 is also a positioning member that serves as the bracket θοο, after the restricting plate 630 is filled into the groove portions 6n, 612, the bracket 6 is Preferably, the groove portions 611 and 612 are filled. However, since the restriction plate 63 of the present embodiment is formed of an elastically deformable member such as a resin, the bracket 6 is attached to the side frame 610. The restricting plate 63〇 can still be filled between the pair of groove portions 6ι, Μ?. (Fifth Embodiment) As shown in Fig. 48, the discharge port 123C of the guide member 123 is disposed at the center in the width direction (horizontal direction), and the opening of the discharge port 123C is viewed from the rear side. The direction is substantially the same as the direction of the straight line (up and down direction). In other words, in the above embodiment, as shown in Fig. 12, it is discharged from the rear side. The direction of the opening of the 123C and the direction of the straight line (up and down direction) are not uniform. However, in the present embodiment, the direction of the opening of the discharge port is substantially the same as the vertical direction (up and down direction). Therefore, in the present embodiment, since the bottle projector 103 is prevented from being unnecessarily deformed, the bottle P can be smoothly dropped by the dispensing mechanism 21 and the door is opened by the outlet port 123C. The direction of the mouth portion coincides with the vertical direction (up and down direction). When the guiding member 123 is formed with the mold member, since the mold forming the guiding member 123 can be divided up and down, the plate structure can be simplified, and the guiding member can be lifted. 123 productivity. (Sixth embodiment) In the present embodiment, as shown in Fig. 4, less m 6 _ 7 is not present, and 43 2 〇 13-9883 PF is applied to the projector fixing portion 2 〇 1; Chent 200934562: a projector is provided The vibration-damping plate 2 01B strongly attenuates the _vibration of the bottle projector 1 〇 3, and at the same time, the upper oscillating plate 202 设有 is provided on the upper side of the outlet side of the mounting nozzle 202 for suppressing the jump of the bottle Ρ . As described above, in the present embodiment, the ball damper plate 103 can prevent the bottle projector 103 from generating more than necessary vibrations, thereby suppressing the stop of the bottle Ρ in the bottle projector 103. The occurrence of an appropriate situation. Further, since the upper jumper plate 202 is provided on the upper portion of the outlet side of the mounting nozzle 202, unnecessary vibration such as a beating of the bottle can be prevented when the bottle is dropped to the transport unit 230. Further, in the present embodiment, the projector damper plate 2〇1 is formed by contacting the metal plate with the lower surface side of the bottle projector 103, and the upper yoke plate 202 is made of an elastic member such as rubber. The plate member to be formed is formed in the upper portion on the outlet side of the placement nozzle 202, but the structure of the vibration-damping plate 2〇ι, 2〇2Α is not limited thereto. (Seventh embodiment) In the present embodiment, as shown in Figs. 50a and 50b, the ball damper member 239 for preventing the bottle P from jumping off the conveyance belt 231 is provided on the conveyance unit 230. Further, the vibration-damping member 239 of the present embodiment is formed of an elastic member such as a rope-like rubber that extends in a direction orthogonal to the conveyance direction of the bottle P. Incidentally, Fig. 50a is a view of the transport unit 23〇 viewed from the upper side, and Fig. 50b is a cross-sectional view taken along line 50B_5〇B of Fig. 50a. Fig. 51 is a view of the transport belt viewed from the direction of the arrow F of Fig. 50a. 23ι's picture. As a result, in the present embodiment, as shown in Fig. 51, even if the bottle p is moved from the 2013-9883-PF; Chent 44 44:34562: nozzle 202, the bottle p can be prevented from being transported. The unit 230 is bouncing to carry the bottle P stably. (Eighth Embodiment) In the present embodiment, when the friend belt of the belt conveyor 101 is not rotated, and the speed is reciprocated in the conveyance direction, the speed is shifted toward the conveyance direction and the speed is shifted toward the conveyance direction. The speed is still big. That is, Fig. 52 is a top view of the belt conveyor 1〇1 of the present embodiment. Fig. 53 is a side view of the belt conveyor 1 〇1 of the embodiment, and Fig. 54 is a schematic view of the operation of the reciprocating mechanism. . The belt conveyor 101, as shown in Figs. 52 and 53, includes an endless belt 101A, a tension roller 101B that imparts a predetermined tension to the belt 101A, and a driving roller 101C that imparts a driving force to the belt i〇iA. And a drive mechanism 1〇11) that swings the drive roller 101C. Further, in the present embodiment, the belt 101A is fixed to the driving roller 101C by a fixing member such as a bolt L1 (see Fig. 53). Ο Then the 'tension roller 101B' can be displaced to the frame 101E' tensioner i〇if via the tensioner 1〇if, and the force that separates the tension roller 1〇1β from the drive roller 101C via the tension The device 101F acts on the tension roller 101B. Further, the driving roller 1 lc is rotatably assembled in a state of being non-displaceable with respect to the frame 101E. Further, as shown in Fig. 53, the drive mechanism 101D includes an electric motor 101H that generates a rotational force, and a crank portion i〇u that is rotated (revolved) by the rotation center of the electric motor 101H while being rotated by the electric motor 1〇1H. The rotary motion of the crank portion 101J is converted into an oscillating motion and transmitted to the drive roller 2013-9883^PF; the slide bar ιοικ of the Chent 45 45, 2009, 562, 101C, and the like. Then, in the rotation range indicated by "downstream" in Fig. 54, the drive roller 101C moves to the conveyance direction advancing side, and in the rotation fe range indicated by "upstream", the drive roller 101C is moved to the conveyance direction to retreat. side. Further, in the present embodiment, the electric motor 1〇1H is rotated to the left (counterclockwise direction) as indicated by the arrow of the 帛54 s. At this time, since the crank portion 101J rotates at an equal angular velocity, the speed at which the retracting side belt 101A is displaced in the conveyance direction 比 is larger than the displacement speed when the belt 101A is displaced in the conveyance direction, and the belt 1〇1A is prevented from being tilted while being conveyed. Ball bottle P. In other words, when the conveyance direction dimension of the belt is 2/3 or less of the dimension in the width direction (the axial direction of the drive roller 101C or the like), the belt conveyor cannot be successfully used because the belt is inclined. On the other hand, in the present embodiment, since the belt 1〇u is reciprocated in the conveyance direction without rotating, the inclination of the belt 1〇1A does not occur in principle, but only the belt 101A does not reciprocate. Carry the bottle p.

In other words, in the present embodiment, when the belt 101A is displaced toward the conveyance direction advancing side, the displacement speed of the belt 101A is relatively small, and the bottle p and the belt 101A are integrally advanced. On the other hand, when the conveyance direction is displaced toward the reverse side, the belt 101A is displaced by a large acceleration, and the inertial force acting on the bottle p exceeds the frictional force generated at the contact portion between the belt and the bottle P, and the bottle is borrowed. It stops at this point by its inertial mass, and only the belt 101A retreats. That is, in the present embodiment, when the belt 101A advances toward the conveyance direction 2013-9883-PF; Chent 46 46 200934562 ·. Displacement % ‘the bottle P follows the skin! The displacement is caused by the displacement of 1〇1Α, and when the belt 101A is displaced toward the reverse side in the conveying direction, since the belt IMA is displaced on the reverse side only, the belt p can be carried while preventing the belt 1 〇 1A from being inclined. When the tilt prevention function is provided on the belt 101A, the skin bottle p can be transported by simply rotating the skin strip 101A without reciprocating motion. However, as in the present embodiment, the diameter of the tension roller 丨01B is changed. In hours, it is difficult to provide a tilt prevention function on the skin 101A. Therefore, this embodiment is particularly applicable to a belt conveyor having a small diameter of the tension roller 101B and the driving roller 101C. Further, in the present embodiment, the belt 101A is a linear object that is connected to the center line of the center of the tension roller 101B and the center of the driving roller 101C, and the dynamic balance of the belt 101A during reciprocation can be achieved. Therefore, the load of the electric motor ι〇1Η driving the driving roller 101C can be suppressed from increasing above the demand. Further, in the present embodiment, the belt 101A is fixed to the drive roller 101C. However, the present invention is not limited to the embodiment, and may be fixed to at least one of the tension roller 101B and the drive roller i〇ic, or by The frictional force generated by the contact faces of the belt i〇1A and the driving roller 101C is large enough to remove the fixing member. (Other embodiment) In the above embodiment, the present invention is applied to Binbo (registered trademark), but the present invention is not limited thereto and can be applied to a general bowling game device. Further, in the above-described embodiment, the concave portion 113 2013-9883-PF and the Chentf 47 200934562 of the rotor 111 are formed by through holes, but the present invention is not limited thereto, and the concave portion 113 may be formed by a hole that is not penetrated. Further, in the above embodiment, the rotor ηι and the fixed plate 12〇 are inclined with respect to the vertical square fe. However, the present invention is not limited to this. The rotor ui and the fixed plate 120 are parallel to the vertical direction. Further, in the above-described embodiment, the spherical bottles P collected by using the irregular slits 121 are arranged in the same direction, but the present invention is not limited thereto. Further, the distribution mechanism 210, the transport unit 230, the bottle placement machine 300, and the bottle guide elevating mechanism 350 are not limited to the mechanisms described in the above embodiments. Further, the present invention is not limited to the above-described embodiments as long as it is in accordance with the invention described in the scope of the patent application. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows the arrangement of the recovery mechanism 1〇〇, the ball © bottle placement machine 300, and the sweeping mechanism 4 of the bottle P in the bowling game device i. Fig. 2 is a front elevational view of the recovery mechanism 100 (a cross-sectional view of the arrow of Fig. i). Fig. 3 is a view of the front side of the recovery mechanism 100 as viewed from the horizontal direction. Fig. 4a is a front view of the outer cover 130, and Fig. 4b is a right side view of the second drawing. Fig. 5 is a view of the state in which the bottle P is dropped from the irregular slit 121 from the inside side. Fig. 6 is a view of the state shown in Fig. 5 as viewed from the right side of Fig. 5. 2013-9883~PF; Chentf 48 200934562 Figure I is a front view of the rotator 111. «* Figure 8a is a front view of the fixed plate 12〇, and Figure 8b is a front view of the bottle P. ♦ · Figures 9a to 9c show the movement of the ball b and the bottle p recovered by the recovery unit 1〇〇. Figures 10a to 10C show the operation of the ball B and the bottle P recovered by the recovery mechanism 1A.

Fig. 11 is a view of the recovery mechanism 1A viewed from the inside side. Fig. 12 is a view as seen from the B arrow of Fig. 1. Fig. 13 is a view in which the setting state of the dispenser 250 is viewed from above. Fig. 14a is a top view of the distribution mechanism 21 from the arrow of the i-th diagram, and Fig. 14b is the i-th diagram. Fig. 16 is a view showing a schematic configuration of the bottle transport mechanism 200. Fig. 16 is a left side view of Fig. 15. The figure ~l7d shows the rising motion of the bottle p. Fig. 18 is an enlarged view of the piston portion 320. Figure 19a is a cross-sectional view of the bottle guide 351, and a cross-sectional view taken along line 19B-19B of the first drawing. Fig. 20 is a view showing the operation of the retracting mechanism 36A. Fig. 21 is a view showing the operation of the retracting mechanism 360. Fig. 22 is a view of Fig. 20 viewed from the C arrow. The figure is a diagram in which the ball guide 351 holds the ball view p 23b as a state in which the grip i of the bottle p is released.

Fig. 24 is a block diagram showing the electrical system of the bowling game device 1 2013-9883-PF; Chentf 49 200934562 Fig. 25 is a view showing a state of the bottle p accommodated in the bag portion i12A. Figure 26 is a front elevational view of the recycling mechanism. Figure 27 is a front elevational view of the fixed plate 120. Figure 28 is a front elevational view of the fixed plate 123⁄4. *· Figure 2 9a is a view of Figure 28 from the direction of the arrow D, and Figure 29b is a view of the right side of Figure 29a. Figure 30 is a cross-sectional view of the rotator hi. Fig. 31a is a front view of the outer cover 130, and Fig. 31b is a view taken from the direction of the E arrow in Fig. 31a. Fig. 32 is an explanatory diagram of the operation of the recovery mechanism 1〇〇. Figures 33a and 33b are explanatory diagrams of the operation of the recovery mechanism 1〇〇. Figures 34a and 34b are diagrams showing the operation of the recovery mechanism 1〇〇. Figures 35a and 35b are explanatory diagrams of the operation of the recovery mechanism. Figures 36a and 36b are diagrams showing the operation of the recovery mechanism. Fig. 37a is an explanatory diagram of the operation of the recovery mechanism 100, and Fig. m is an enlarged circle of the portion 37B of Fig. 37a. Fig. 38 is an explanatory diagram of the operation of the recovery mechanism 100. Figs. 39a and 39b are diagrams showing the operation of the recovery mechanism 1A. Fig. 40 is a cross-sectional view taken along line 4〇_4 of Fig. 26. Figure 41 is a cross-sectional view taken along line 4 and line 41 of Figure 26. Fig. 42 is a view for explaining the effect of the concave portion 112F. 43rd 44th view). The picture shows the outer view of the bowling game device 1. The figure is a cross-sectional view of the side frame 610 (Fig. 43 along the line 44-44 line 2013-9883-PF; Chent 50 50 200934562 picture 45a is a front view of the bracket 600, the 45b picture is the bracket 6 〇〇 The side view, the first figure is the inside view of the bracket coffee / the 46th. The figure is the installation illustration of the bracket 600. The 47th is a cross-sectional view of the state in which the bracket 600 is attached to the side frame 610, which is along the line in FIG. Fig. 48 is a view showing a feature of a fifth embodiment of the present invention. Fig. 49 is a view showing a feature of a sixth embodiment of the present invention. 〇5〇a and 5〇b are drawings showing [Embodiment of the seventh embodiment of the present invention] Fig. 51 is a view showing the effects of the seventh embodiment of the present invention. Fig. 52 is a view showing the eighth embodiment of the present invention. Fig. 53 is a side view of Fig. 52. (Partial sectional view) Fig. 54 is the action description circle of the drive mechanism 101D. Main component symbol description] ❹ 3 ~ fairway; 4 ~ frame; 100 ~ recycling mechanism; 103 ~ ball air projector; 11 0 ~ recycling department 111A~rotating shaft; 11 2 A~ball pocket; 121B~second hole; 123~ guiding member; 1 Bowling game device; 3A~hole; 20~ball handling mechanism; 101~belt conveyor; 105~ball projector; 111~rotor; 112~protrusion; 121A~first hole; 122~ clearance; 2013 -9883-PF;Chentf 51 200934562

123A--bearing surface; 123B--inclined guiding surface; 123C~ discharge port; 123D-^resisting body; 124~ cover; 124A--linkage mechanism; 124B-^motor; 125 2. recovery hole; 130~ cover 131~ guide piece; 132~ outer cover ring; 140~ motor; 200~ ball handling mechanism; 201~ projector fixing part; 202~ mounting nozzle; 203~ track; 204~ drive belt; 205~ motor; ~ distribution mechanism; 230~ handling unit; 231~ handling belt; 232~ engaging projection; 233~ guiding piece; 234~ guiding part; 235~ driven roller; 236~ driving roller; 237~ motor; 238~ tension lever; 250~ dispenser; 251~ ball bottle supply port; 300~ ball bottle arrangement machine; 301~ bottle lifting device; 302~ cylinder part; 303~ first cylinder; 304~ second cylinder; First protrusion; 306~ first coil spring; 307~ second protrusion; 308~ stop; 309~ filling port; 320~ piston part; 321~ pedestal part; 322~ pusher; 323~ second coil Spring; 324~ holding member, 324A ^〜through hole; 325~ bolt; 340~ riser; 2013-9883-PF; Chentf 52 200934562 341~ riser; 342~ »· chain; 343~ pull-up machine; 344~ arm; 345~ movable sprocket; 346~ idler sprocket; 350~ ball bottle guiding and lowering mechanism; 351~ ball bottle guide; 351A--protrusion; 352~ clamping bar; 353~ lifting plate; 354~ movable plate; 355~ 356~ fixing fixture; 3 5 6 A~bolt; 357~ coil spring; 3 5 8~ball bottle sensor; 360~ retracting mechanism; 361~ lifting guide; 362~ guiding sheath; 363~ beam ; 364~ chain; 4 0 0~ sweeping mechanism; 500~ control circuit.

Q 2013-9883-PF; Chentf

Claims (1)

200934562 X. Patent application scope: 1. A bowling game recycling mechanism, which is suitable for a bowling game device in which a player rolls a ball to a plurality of ball bottles erected on a fairway and dumps a plurality of erected bottles. A recycling/retracting mechanism for recycling a bottle and a ball, comprising: a bottle recycling mechanism having a rotating rotating body, which recovers the bottle by rotation of the rotating body; and a φ conveying device that will reach the terminal end side of the fairway The spherical bottle and the spherical bottle swept out at the terminal side of the above-described fairway are transported to the above-described spherical bottle collecting mechanism, and the spherical body transferring portion for transferring the spherical bottle and the ball transferring portion for transferring the ball are provided on the rotating body. 2. The bowling game recycling mechanism according to claim 1, wherein the rotating body is substantially formed into a plate shape, and a side surface orthogonal to the rotating axis thereof is intersected with respect to a horizontal plane, and the bottle conveying portion is provided in the above In the rotating body, on the outer peripheral side of the ball transfer unit, the transfer device is set such that the end of the ball collecting mechanism side and the rotating body are smaller than the diameter of the ball, and are smaller than the diameter of the ball. The maximum diameter is also large, and the end portion on the side of the bottle collecting mechanism in the conveying device is set to be higher than the upper end of the bottle conveying portion in the vertical direction and lower than the upper end of the ball transfer portion. Location. 3. The bowling game collecting mechanism according to claim 2, wherein the ball transfer portion is constituted by a concave portion in a direction parallel to the rotating shaft from a side of the rotating body, and the side surface is opposite The opening is inclined in the horizontal plane, and the opening of the concave portion is opened toward the upper side. 2013-9883-PF; Chentf 54 200934562 4. The bowling game collecting mechanism according to the third aspect of the invention, wherein the ball-receiving portion that is filled in the concave portion is set in the ratio The lowermost portion of the above-mentioned rotating body is also on the upper side. 5. The bowling game bait receiving mechanism according to the fourth aspect of the patent application, wherein the recess is formed by a through hole penetrating the rotating body, and a fixing plate for closing a through hole constituting the recess is provided, and The solid plate s has a hole portion for forming the ball collecting portion. ❹ 2013-9883-PF; Chentf 55