JP6884351B2 - Paper leaf collection and transportation system Transport auxiliary relay device - Google Patents

Description

The present invention relates to a paper leaf collection and transport system and a transport auxiliary relay device for transporting paper sheets such as banknotes by an air flow generated in a transport pipe.

In the game hall, a game machine island that houses multiple sets of game ball lending machines that lend game balls (pachinko balls, etc.) to players in response to the insertion of banknotes and game machines such as pachinko machines. Is installed. Inside the game machine island, a transport device for transporting the bills inserted into each game ball lending machine to a safe provided at the end of the game machine island is provided along the longitudinal direction of the game machine island.

In addition to the belt type, there are other transport devices for paper sheets such as banknotes, in which an air flow is generated inside a tubular transport tube by a blower and the paper leaves are transported by the action of the air flow (for example). , Patent Document 1). In addition, there is a transport device that transports paper leaves by sending a transport auxiliary body that moves by receiving an air flow generated in the transport pipe into the transport pipe and pushing the paper leaves from behind by the transport auxiliary body (this transport auxiliary body). For example, see Patent Document 2).

In addition, there is a paper leaf collection and transportation system that uses the above-mentioned transportation aid to collect the banknotes stored in the safes of each game machine island dispersed in the game hall to the collection safe in the store office ( For example, see Patent Document 3).

Patent No. 4130697 Japanese Unexamined Patent Publication No. 2012-82062 Japanese Unexamined Patent Publication No. 2014-188102

In a system that collects banknotes from the safes of each game machine island distributed in the game hall to the safes of the stores, the transportation route becomes considerably long. For example, a transport aid sent from a collective safe installed in the office on the second floor of a store goes down to the game floor on the first floor, and then goes around the safes on each game machine island installed on the first floor in order. After collecting the banknotes, it becomes a long transportation route such as climbing up to the second floor and returning to the safe. Therefore, it takes a long time for one collection operation until the transport auxiliary body sent out from the collection safe goes around this transport path and returns. As a result, if the collection to the collection safe does not proceed and the safe on the game machine island is full of banknotes, the player cannot insert the banknotes into the game ball lending machine, and the game must be interrupted.

For example, assuming that one collection operation takes two minutes and a maximum of six banknotes can be collected in one collection operation, 180 banknotes can be collected in the collection safe in one hour. In a medium-sized game hall with 300 game machines installed, even if the player plays at a pace of inserting one banknote into the game ball lending machine per hour, if the game is full, 300 banknotes per hour Need to be recovered. Therefore, with the collection capacity of 180 sheets per hour, the collection to the collection safe is not in time, and the safe on the game machine island will eventually become full.

Further, in order to solve such a problem, when a relay device for a transport auxiliary body is provided in the middle of a long transport path, it is desirable that the device is small and thin from the viewpoint of installability.
An object of the present invention is to solve the above problems, and an object of the present invention is to provide a transport auxiliary relay device having good installability and a paper leaf collection and transport system including the same.

The gist of the present invention for achieving such an object lies in the inventions of the following items.
[1] Paper leaf collection in which an air flow is generated in the transport pipe and the paper leaves inserted in the transport pipe are pushed and moved from behind by a transport auxiliary body that receives the air flow and moves in the transport pipe. It ’s a transport system,
A transport auxiliary body insertion device provided upstream from the insertion position where paper sheets are inserted into the transport pipe and delivering the transport auxiliary body into the transport pipe.
A holding portion provided in the middle of the transport pipe between the insertion position and the transport assist body insertion device, which receives and temporarily holds the transport assist body arriving from inside the transport pipe on the upstream side, and the holding portion. moving the held conveyance auxiliary member toward the conveying pipe downstream and a moving portion, and conveyance auxiliary body transportable to be out feeding the conveying pipe downstream feed auxiliary body relay device and the moved,
Have,
The moving portion is a rotating body in which the holding portion is provided at a position separated by a predetermined distance in the radial direction from the center of rotation, and when the rotating body rotates, the holding portion faces the upstream side. A paper leaf collection and transportation system characterized in that it is moved to a position facing the downstream side.

It is a figure which shows an example of the in-store layout of the amusement place where the paper leaf collection and transportation system using the transportation auxiliary body relay device which concerns on embodiment of this invention is installed. It is a figure which shows the whole of the paper leaf collection and transportation system. It is explanatory drawing which shows the state which the transport auxiliary body pushes and moves a bill in a transport pipe from the rear end side of the bill. It is a perspective view which shows the transport pipe of a straight part. It is sectional drawing which is perpendicular to the extension direction of the transport pipe of a straight part. It is a figure which shows the plane and the front surface of the transport auxiliary body. It is sectional drawing which shows the transport pipe and the transport auxiliary body in the state which the transport auxiliary body is inserted in the transport pipe. It is a figure which shows the transport pipe around the collective safe and the inside of the collective safe in the paper leaf collection and transport system shown in FIG. It is a perspective view which shows the back of the collective safe. It is a perspective view of the banknote separation / transport auxiliary body circulation device seen from the discharge port side of the separated banknotes. It is a perspective view of the banknote separation / transport auxiliary body circulation device seen from the connection part side of the transport pipe. It is explanatory drawing which shows the outline of the separation operation and the insertion operation by the bill separation / transport auxiliary body circulation device. It is a perspective view which shows the transport auxiliary body relay device. It is a perspective view which shows the transport auxiliary body relay device in the state which a part of the outer cover of a blower part was removed. It is a perspective view which shows the inside of the relay part of the transport auxiliary body relay device. It is a figure which shows the state in which a rotating plate is rotating from a 1st stop position to a 2nd stop position. It is a figure which shows the state which looked at the relay part which removed the front cover from above. It is a figure which shows in chronological order how the holding part in the receiving position holds the transport auxiliary body arriving from the outbound transport pipe. It is a figure which shows the mode that the holding of a transport auxiliary body is automatically released when the holding part rotates to a discharge position. It is a perspective view which shows the inside of a relay part. It is a perspective view which shows the holding part enlarged. It is a figure which shows the rotating plate which provided four holding parts every 90 degrees. It is a perspective view which shows the secondary transport pipe of a relay box and a secondary transport device, and the take-in device connected to the upper end thereof. It is a perspective view which shows the upper part of the auxiliary transport pipe, the take-in device, and the transport pipe 12 before and after the intake device. It is a perspective view which shows the sub-conveyor device and the take-in device (and the transport pipe before and after) connected to the upper end thereof. It is a partial cross-sectional view which shows the sub-conveyor device and the take-in device (and the transport pipe before and after it) connected to the upper end thereof. It is sectional drawing which shows the upper part of the auxiliary transport pipe, and the intake device. It is sectional drawing which shows the banknote taking-in part provided in the lower part of the auxiliary transport pipe. It is a figure which shows the state which the bill taking-in part in the state which removed the lid of the passage part is seen from the side which faces the opening. It is a figure which shows the structure of the transport part which a take-in device has. It is a top view which shows the banknote carrier in the island installed in the game machine island. It is a front view which shows the banknote carrier in the island installed in the game machine island. It is a figure which shows the inside (the state which the door is removed) of a relay box. It is sectional drawing which shows the schematic structure of the temporary storage device which a relay box has. It is a perspective view which shows the structure of a temporary storage device. It is a figure which shows typically the structure and operation of a temporary storage device. It is a figure which shows the state which the bill pushed by a holding plate slides down from a receiving plate, and how the bill pushed by a holding plate separates from the receiving plate which attached the natural rubber sheet. It is a figure which shows the state in which the banknote pressed on the holding plate is separated from the receiving plate to which the natural rubber sheet is attached in the improved type of the structure shown in FIG. 37 (b). It is a figure which shows the state which the connection | connection | connection part and the transport pipe before and after the connection part were disconnected. It is a figure which shows the front surface, the left side surface, the right side surface, the upper surface, and the lower surface in the state where the transport pipe is connected to the connecting portion. It is a figure which shows the front surface, the left side surface, the right side surface, the upper surface, and the lower surface of the connection adapter. It is a figure which shows the state of connecting the downstream end part of a connection adapter to the upstream side connection port of a connection main body part. It is an enlarged view which shows the state in which the rib on the connection adapter side and the rib on the connection main body side overlap and are connected. It is a figure which shows the installation part of the blower device in an enlarged manner. It is a figure which shows a twisted part and a part which comprises this part. It is a figure which shows the operation sequence when the paper leaf collection and transportation system collects the banknote from each relay box. It is a figure which shows the standard at the time of grouping according to the number of stocks. It is a figure which shows the example of the allocation situation of the number of discharged sheets in pattern 1. It is a figure which shows the example of the allocation situation of the number of discharged sheets in pattern 2 (in the case of one G3). It is a figure which shows the example of the allocation situation of the number of discharged sheets in pattern 2 (in the case of two G3s). It is a figure which shows the example of the allocation situation of the number of discharged sheets in pattern 2 (when G3 is 3 or more). It is a figure which shows the example of the allocation situation of the number of discharged sheets in pattern 3. It is a front view which shows the error display which the paper leaf collection and transportation system has. It is a figure which shows the display example of the place where the stagnation abnormality of the transport auxiliary body was detected. It is a figure which shows the relay part of the transfer auxiliary body relay device before improvement, and the relay part of the improved type transfer auxiliary body relay device. It is a figure which shows the inside of the relay part of the improved type transport auxiliary body relay device.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 shows an example of the in-store layout of the amusement park 2 in which the paper leaf collection and transportation system 10 (see FIG. 2) according to the embodiment of the present invention is installed. In the store of the game hall 2, a plurality of game machine islands 3 are arranged across a passage. On each game machine island 3, a pair of a game ball lending machine 4 that lends a game ball (pachinko ball) to a player upon receiving a bill and a game machine 5 such as a pachinko machine is back-to-back. Multiple sets are housed on the front and back sides.

Inside the gaming machine island 3, an island bill transporting device 8 is provided that takes in the bills discharged from the back surface of each gaming ball lending machine 4 and transports them to a safe installed at one end of the gaming machine island 3. At the end of the gaming machine island 3, a relay box 6 having a function of a safe for temporarily storing banknotes transported by the island banknote transfer device 8 is provided.

FIG. 2 shows the collection of banknotes from the relay boxes 6 of the plurality of game machine islands 3 installed in the game hall 2 shown in FIG. 1 up to the collective safe 11 installed in the office of the game hall 2. The paper leaf collection and transportation system 10 to be conveyed is shown.

The paper leaf collection and transportation system 10 is provided with a collection safe 11 installed in the office of the game hall 2 and a relay box 6 of each game machine island 3 installed in the game area after exiting the collection safe 11. A transport pipe 12 is provided so as to return to the collection safe 11 via the above, and a transport auxiliary relay device 17 provided in the middle of the transport pipe 12. The transport pipe 12 from the collecting safe 11 to the transport assist relay device 17 is referred to as an outward transport pipe 12a, and the transport pipe 12 from the transport auxiliary relay device 17 to the transport auxiliary relay device 17 is referred to as a return transport pipe 12b.

FIG. 2 shows a state in which the collective safe 11 is installed on the same floor as the game area where the gaming machine island 3 is installed, but the collective safe 11 may be installed on a floor different from the gaming area. In that case, the length of the transport pipe 12 from the collecting safe 11 to the game floor and the length of the transport pipe 12 from the game floor to returning to the collecting safe 11 are considerably longer than those shown in FIG.

The transport pipe 12 installed on the game floor is piped behind the ceiling of the game floor. In the case of FIG. 2, the outbound transport pipe 12a of the transport pipe 12 bends upward after exiting the collective safe 11 installed on one end side of the amusement park, extends to the height of the attic, and then bends again to the ceiling. It goes into the attic, passes directly above the place where the relay box 6 of each game machine island 3 is installed, and extends to the transport assist relay device 17 installed on the other end side of the game hall. The return transfer pipe 12b extends from the transfer auxiliary relay device 17 and extends along the outward transfer pipe 12a (that is, passes directly above the installation location of the relay box 6 on each gaming machine island 3 and is one end of the game hall. After being extended so as to return to the side), it bends downward and descends to the height of the collective safe 11, and then bends again to become horizontal and extends to the collective safe 11.

The paper leaf collection and transport system 10 generates an air flow in the transport pipe 12, and pushes the bill P from behind by the transport auxiliary body 16 (see FIG. 3) that moves in the transport pipe 12 in response to the air flow. Move and transport to the downstream (transport direction FW). The collective safe 11 and the transport auxiliary relay device 17 each include a blower that generates an air flow. The collecting safe 11 generates an air flow from the start end of the outward transport pipe 12a toward the transport auxiliary relay device 17, and the transport auxiliary relay device 17 sucks the air flow from the end of the outward transport pipe 12a. Further, the transport auxiliary relay device 17 generates an air flow from the start end of the return transport pipe 12b toward the collecting safe 11, and the collecting safe 11 sucks the air flow from the end of the return transport pipe 12b.

An auxiliary blower 18 for strengthening the air flow toward the downstream side (from the transport auxiliary body relay device 17 to the collective safe 11) is provided at the bent portion where the return transport pipe 12b goes downward from the ceiling.

The paper leaf collection and transport system 10 further comprises a sub-conveyor device 13 for transporting banknotes from each relay box 6 to a return transport pipe 12b passing above the relay box 6, and a sub-conveyor device 13 for transporting banknotes from the relay box 6 by the sub-transport device 13. The take-in device 14 is provided so that the paper surface is taken into the return transport pipe 12b in a posture along the extending direction of the return transport pipe 12b.

Since the transport pipe 12 is provided behind the ceiling, the transport pipe 12 does not hinder the activities and traffic of the player even if the transport pipe 12 is laid around in the game hall 2. The transport pipe 12 is not limited to the ceiling, and may be extended along a high position near the ceiling, for example. In this example, the transport pipe 12 is installed at a position higher than the area in the game hall 2 where people are active (playing or passing). Further, since the game ball lending machine 4 in the game machine island 3 is installed at a height suitable for the player playing the game, and the relay box 6 of the game machine island 3 is also installed at the same height, the relay box The bill P is transported from 6 to the return transport pipe 12b above it by the sub-conveyor device 13.

In the present embodiment, the transport auxiliary body 16 that moves by the air flow and pushes the bill P from the rear is sent out from the collecting safe 11 as a base point to the outward transport pipe 12a, and when it reaches the transport auxiliary body relay device 17, the transport auxiliary body 16 is said to be. It is temporarily held by the transport auxiliary relay device 17. The held transport auxiliary body 16 is then sent out from the transport auxiliary body relay device 17 to the return route transport pipe 12b, and moves and gathers while collecting the banknotes P taken into the return route transport pipe 12b by the take-in device 14. Come back to safe 11.

Here, the transport auxiliary body 16 is sent out from the collective safe 11 to the outward transport pipe 12a and the transport auxiliary body 16 is sent out from the transport auxiliary body relay device 17 to the return route transport pipe 12b at the same time. The transport assist body relay device 17 receives and holds the transport assist body 16 arriving from the outbound transport pipe 12a. Then, the held transport assisting body 16 is moved to the start end side of the return path transport pipe 12b, and next time, the held transport auxiliary body 16 is sent out to the return path transport pipe 12b.

By using the transport auxiliary relay device 17, the movement from the collective safe 11 to the transport auxiliary relay device 17 through the outward transport pipe 12a and the collective safe from the transport auxiliary relay device 17 through the return transport pipe 12b. The movement back to 11 will be performed in parallel. When the transport auxiliary body 16 sent out from the base point (collective safe 11) continues to move as it is without using the transport auxiliary body relay device 17, goes around the transport pipe 12, and returns to the base point (collective safe 11). The transport auxiliary body 16 can be sent out in a short cycle (time interval), and the bill collection capacity per unit time can be enhanced.

For example, when the transport auxiliary body relay device 17 is installed at an intermediate point of the entire transport path, the transport assist body 16 that has come out of the base point goes around the transport path as it is and returns to the base point. The time required for one recovery operation by the auxiliary body 16 can be reduced by half, and the recovery capacity per unit time can be doubled.

As shown in FIG. 8, an air flow generator 21 and a bill separation / transport auxiliary body circulation device 22 are provided inside the collection safe 11. The bill separation / transport auxiliary body circulation device 22 has the function of the transport auxiliary body insertion device 23 that sends the transport auxiliary body 16 to the outward transport pipe 12a, and the bill P and the transport auxiliary body 16 that pushes and moves the bill P from behind. It has a function of a separation / recovery device 24 for separating and collecting each of the above, and also has a function of passing the transport assist body 16 collected by the separation / recovery device 24 to the transport assist body insertion device 23 for cyclic use. The banknote P collected by the separation / collection device 24 is stored in the banknote storage unit 25 in the collection safe 11.

The air flow generator 21 generates an air flow by rotating the blades with a motor. The air blowout side of the air flow generator 21 is connected to the air inlet side of the transport auxiliary body insertion device 23, and the start end of the outward transport pipe 12a is connected to the air outlet side of the transport auxiliary body insertion device 23. The end of the return transport pipe 12b is connected to the air inlet side of the separation / recovery device 24, and the air suction side of the air flow generator 21 is connected to the air outlet side of the separation / recovery device 24.

The transport auxiliary body relay device 17 has a function of sucking air in the outward transport pipe 12a from the terminal side of the outward transport pipe 12a and a function of sending an air flow toward the start end of the return transport pipe 12b. That is, the air flow generator 21 of the collective safe 11 sends the air flow to the outbound transport pipe 12a from the start end side thereof, and the transport auxiliary relay device 17 sucks the air flow from the end side of the outbound transport pipe 12a, thereby causing the outbound route. A strong air flow is generated in the transport pipe 12a. Similarly, the transport auxiliary relay device 17 sends an air flow to the return transport pipe 12b from the start end side thereof, and the air flow generator 21 of the collecting safe 11 sucks the air flow from the terminal side of the return transport pipe 12b. A strong air flow is generated in the return transport pipe 12b.

Further, an auxiliary blower 18 is provided on the return transfer pipe 12b downstream of the most downstream take-in device 14. The auxiliary blower 18 is a blower that blows air toward the downstream side, and plays a role of enhancing the forward air flow in order to ensure that the transport auxiliary body 16 reaches the collecting safe 11. In the example of FIG. 2, the transport pipe 12 from the installation location of the auxiliary blower 18 to the collection safe 11 is briefly described, but for example, the collection safe 11 may be provided on a floor different from the island bill transfer device 8. In many cases, the transport pipe 12 downstream of the auxiliary blower 18 may have a long distance.

The bill P is collected by the paper leaf collection and transportation system 10 as follows.

The banknotes inserted from each game ball lending machine 4 on the game machine island 3 are transported to the relay box 6 at the end of the game machine island 3 and temporarily stored. When the banknotes P stored in the relay box 6 are collected in the collection safe 11, the banknotes P are discharged from one or more of the relay boxes 6 toward the sub-conveyor device 13. The banknote P discharged from the relay box 6 is conveyed upward by the sub-conveyor device 13, and then sent out into the return path transfer pipe 12b by the take-in device 14.

The import device 14 sends the bill P into the return transport pipe 12b in a posture in which the paper surface follows the extending direction of the return transport pipe 12b. Here, the take-in device 14 sends the bill P into the return path transport pipe 12b so that the paper surface faces up and down in a horizontal posture. The bill P sent out into the return path transport pipe 12b by the take-in device 14 stays at the sending completion position. The return transport pipe 12b of the portion passing through the plurality of intake devices 14 is laid horizontally and in a straight line in a horizontal posture. The horizontal posture is the posture of the return transport pipe 12b in which the paper surface of the bill P in the return transport pipe 12b is horizontal.

When the loading of the bill P into the return transport pipe 12b is completed, the transport auxiliary body 16 is transferred from the transport auxiliary body relay device 17 in order to transport the bill P staying in the return transport pipe 12b to the collecting safe 11 and collect it. It is sent out into the outbound transport pipe 12a. At the same time, the transport auxiliary body 16 is sent out from the collective safe 11 into the outward transport pipe 12a. The transport auxiliary body 16 sent out into the outward transport pipe 12a moves in the outward transport pipe 12a under the action of the air flow, reaches the transport auxiliary body relay device 17, and is received by the transport auxiliary body relay device 17. Is retained. On the other hand, the transport auxiliary body 16 sent out from the transport auxiliary body relay device 17 into the return transport pipe 12b moves in the return transport pipe 12b under the action of the air flow, and moves to the collection safe 11 while collecting the bills P. come back. At that time, as shown in FIG. 3, the transport assisting body 16 pushes and moves the bill P from the rear end side to transport the bill P (the transport direction FW in the drawing).

In this way, the transport assisting body 16 moves under the action of the air flow, and the bill P is pushed and moved from the rear end side by the transport assisting body 16 to transport the bill P, so that the bill P itself obtains propulsive force from the air flow. No need. Therefore, the banknote P can be conveyed by the air flow without taking measures such as bending the banknote P to receive the air flow. Further, since the transport auxiliary body 16 can obtain the propulsive force from the air flow more efficiently than the bill P, the bill P can be efficiently transported.

As shown in FIG. 2, the main transport pipe 12 of the paper leaf collection and transport system 10 is configured by connecting a plurality of transport pipes with a connecting portion 15. The connecting portion 15 plays a role of absorbing the change in the length of the transport pipe 12 so that the entire installation state is not distorted even if the length of the transport pipe 12 changes due to a temperature change or the like. The take-in device 14 also functions to connect the transport pipes 12 before and after the take-in device 14.

Further, the paper leaf collection and transport system 10 includes a control unit 27 (see FIG. 8) whose main parts are a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The control unit 27 includes an air flow generator 21, a bill separation / transfer auxiliary body circulation device 22, an auxiliary transfer device 13, a take-in device 14, a transfer auxiliary body relay device 17, an auxiliary blower 18, an auxiliary transfer device 13, and a relay box 6. Control the operation of each part.

Next, the shapes of the transfer pipe 12 and the transfer auxiliary body 16 will be described in detail.

FIG. 4 is a perspective view of the transport pipe 12 in the straight portion, and FIG. 5 is a cross-sectional shape perpendicular to the extension direction FW (= transport direction FW of the bill P = direction in which the air flow flows) of the transport pipe 12 in the same portion. It is a figure which shows. The transport pipe 12 is made of a resin having a thickness of about 1.5 mm. The transport tube 12 is formed, for example, by extrusion molding.

The shape of the cross section of the straight portion of the transport pipe 12 perpendicular to the extending direction FW has a shape in which the central portion of the long side of the rectangle extends outward in a rectangular shape. Specifically, the transport pipe 12 has a wall portion 31 having a rectangular short side in cross section, a side wall portion 32 having a rectangular long side in cross section, and an extension portion extending outward in a rectangular shape at the central portion of the side wall portion 32. It is equipped with 33. The short side direction is the X direction and the long side direction is the Y direction in a substantially rectangular cross section perpendicular to the extension direction (transport direction FW) of the transfer pipe 12. In each of the X direction and the Y direction, the direction toward the center of the transport pipe 12 is referred to as the inside, and the direction from the center toward the inner wall is referred to as the outside.

The expansion portion 33 is divided into two by a separation wall 34 erected inward of the transport pipe 12. The separation wall 34 is formed by attaching a T-shaped member to the inner wall of the expansion portion 33.

On the side wall portion 32, a plurality of ribs 35 protruding inward of the transport pipe 12 are formed so as to extend along the transport direction. In this example, ribs 35 projecting inward of the transport pipe 12 are formed at the boundary between the side wall portion 32 and the expansion portion 33 along the transport direction FW. The separation wall 34 has the same height as the rib 35, and the top of the separation wall 34 acts as a rib. Hereinafter, the separation wall 34 will also be referred to as a rib 34.

The side wall portion 32 is a pair of inner walls facing the paper surface of the bill P to be transported. The bill P has a rectangular shape, and is transported in the transport pipe 12 in a direction in which the long side is the transport direction FW. In other words, the paper surface P faces the side wall portion 32 of the transport pipe 12, and one short side of the bill P is the front end side in the transport direction FW, and the other short side is the rear end side.

The distance Dy between the pair of wall portions 31 facing each other of the transport pipe 12 is slightly longer than the short side of the bill P. Further, the distance Dx between the pair of side wall portions 32 facing each other (the rib 35, the extension portion 33, and the portion where the separation wall 34 is not formed (referred to as a reference plane portion)) is set to about 21 mm. The expansion portion 33 provided on each side wall portion 32 extends outward by about 6 mm from the side wall portion 32 (reference plane portion). The tops of the ribs 35 and the separation wall 34 have a height of about 2 mm inward from the side wall portion 32 (reference plane portion). The height of the rib 35 may be appropriately set.

The transport pipe 12 can be installed and used by tilting its longitudinal direction at any angle other than vertical and horizontal, and the transport auxiliary body 16 can smoothly move in the transport pipe 12 at any angle. it can. For example, the twisted portion 51 (see FIG. 9), which will be described later, can smoothly transport the bill P and the transport assisting body 16. FIG. 5 shows a transport pipe 12 in a vertical posture installed so that the long side of the rectangular cross section is vertical.

FIG. 6 shows the plane and the front surface of the transport assist body 16. The transport auxiliary body 16 has a columnar shape having a circular cross section having different diameters at each portion. The transport auxiliary body 16 is used by being inserted into the transport pipe 12 so that the central axis of the cylinder is in the Y direction of the transport pipe 12. The transport auxiliary body 16 has a shape symmetrical with respect to the center in the length direction, and in order from one end, the head portion 16a, the neck portion 16b having a diameter slightly smaller than the head portion, and the large diameter larger than the head portion 16a. It is configured to have a constricted portion 16d having the same diameter as the portion 16c and the neck portion 16b and located at the center in the length direction, a large diameter portion 16c, a neck portion 16b, and a head portion 16a. The transport auxiliary body 16 is lightweight and durable, and the inside is formed in a cavity by, for example, plastic. If it is lightweight and durable, it may be formed of expanded polystyrene, extruded polystyrene, or the like.

FIG. 7 shows a cross section of the transport auxiliary body 16 inserted in the transport pipe 12. The figure is a cross section perpendicular to the extension direction FW and passing through the central axis of the transport auxiliary body 16. The diameter of each part of the transport auxiliary body 16 corresponds to the shape of the inner edge of the transport pipe 12. That is, the cross-sectional shape of the transport auxiliary body 16 passing through the central axis corresponds to the shape of the inner edge of the transport pipe 12 in the cross section perpendicular to the extension direction FW, and the inside of the transport pipe 12 is between the inner wall and the inner wall. It has a shape that almost closes with a predetermined clearance.

In this way, the transport auxiliary body 16 has a shape corresponding to the inner edge shape of the transport pipe 12 (almost the same shape with a slight clearance) and closes almost the entire cross section of the transport pipe 12, so that the action of air flow can be exerted. You can receive and move efficiently. Further, the transport assisting body 16 plays a role of preventing the air flow from the upstream side from reaching the downstream side of the transport assisting body 16 and suppressing the turbulence of the air flow on the downstream side.

The bill P tends to stick to the side wall portion 32 when acted on by the air flow in the transport pipe 12. That is, the distance between one paper surface of the banknote P and the side wall portion 32 facing the same and the distance between the other paper surface and the side wall portion 32 facing the other paper surface are rarely equal, and one of the intervals is set. It is narrower than the other. Since the flow velocity of the air flow is faster on the narrow interval side than on the wide interval side, the air pressure on the narrow interval side becomes lower than the air pressure on the wide interval side, and this pressure difference causes the bill P to be adsorbed and pressed against the side wall portion 32 on the narrow interval side. Will be done. In that case, the interval on the narrow interval side becomes even narrower, and a phenomenon occurs in which the bill P sticks to the side wall portion 32 and is adsorbed.

If the bill P is strongly attached to the side wall portion 32, it becomes difficult to push and move the bill P with the transport assisting body 16 to transport the bill P. However, as described above, since the transport auxiliary body 16 acts to block (reduce) the flow of air to the downstream side thereof, the force with which the bill P sticks and is attracted is reduced, and smooth transport is realized.

The two large-diameter portions 16c of the transport auxiliary body 16 engage with each of the two expansion portions 33 separated by the separation wall 34 of the transport pipe 12. In this example, the expansion portion 33 is divided into two by the separation wall 34, and these expansion portions 33 are provided near the center of the transport pipe 12 in the Y direction, so that the transport assist body 16 is maintained in a stable posture. Can be moved. Further, since the posture of the transport assisting body 16 is stable, the large diameter portion 16c of the transport assisting body 16 can appropriately contact the rear end of the bill P to provide a stable transporting force. Further, the bill P is less likely to be caught between the transport pipe 12 and the transport auxiliary body 16.

Further, by providing the transport auxiliary body 16 with the large diameter portion 16c, the area of the portion affected by the air flow is expanded, and the force for moving can be efficiently received. Further, since the large diameter portion 16c is provided to efficiently receive the action of the air flow, the diameter of the head portion 16a can be reduced accordingly. By reducing the diameter of the head, the distance (width (Dx)) between the pair of side wall portions 32 facing each other in the transport pipe 12 can be narrowed, and the bill P can be prevented from falling.

Further, the presence of the plurality of ribs 35 provided on the side wall portion 32 prevents the bill P from sticking to the side wall portion 32 exactly. That is, the contact area between the bill P and the side wall portion 32 is reduced, friction is reduced, and the generation of static electricity and the like can be suppressed. Further, even when the bill P sticks to the side wall portion 32, the bill P is supported by the tip portion of the rib 35, so that a gap is secured between the side wall portion 32 and the bill P around the rib 35. Sticking force is kept small. Further, since the bill P is supported by the separation wall 34, the bill P is prevented from falling into the recess of the expansion portion 33.

Further, the plurality of ribs 35 protruding inward from the side wall portion 32 and the tops of the separation walls 34 have a substantial passage width W of the bill P in the width direction (X direction) of the transport pipe 12, and the distance Dx between the reference plane portions. It serves to make it narrower. As a result, the bill P is less likely to fall toward one side wall portion 32 in the transport pipe 12, and the posture of the bill 6 is held along the Y direction. In particular, by providing a plurality of ribs 35, the above-mentioned fall of the bill P is appropriately prevented, and the sticking of the bill P to the side wall portion 32 is also effectively prevented. It should be noted that the Dx can be increased by the amount of the rib 35 provided, thereby increasing the cross-sectional area of the transport pipe 12 and making the transport auxiliary body 16 more susceptible to the action of the air flow.

In the case of the transport auxiliary body 16 according to the present embodiment, since the diameter of the large diameter portion 16c is the largest, as shown in FIG. 3, the large diameter portion 16c abuts on the rear end of the bill 6 and pushes it. Become.

Next, the internal structure of the safe 11 will be described in more detail.

FIG. 8 shows the collective safe 11 with the front cover removed and the transport pipe 12 in the vicinity thereof, and FIG. 9 shows the back side of the collective safe 11. At the connection position with the safe 11, as shown in FIG. 9, the outward transport pipe 12a and the return transport pipe 12b are in a vertical posture, respectively.

The collection safe 11 has a vertically long rectangular parallelepiped shape, and an air flow generator 21 is arranged in the lower part of the inside thereof, and a bill separation / transport auxiliary body circulation device 22 is attached in the upper part thereof. In addition, inside the collection safe 11, a banknote storage unit 25 for accommodating banknotes P, a banknote transfer unit 26 for transporting banknotes P separated and collected by a separate collection device 24 to the banknote storage unit 25, and a paper leaf collection and transportation system A control unit 27, a power supply unit, and the like that control the operation of the 10 are housed.

The banknote P discharged from the rear end of the separation / collection device 24 follows the route shown by the arrow B in FIG. 8, is delivered to the banknote transport unit 26 provided therefor, and is transported to the banknote storage unit 25 by the banknote transport unit 26. Will be done.

10 and 11 show an overview of the bill separating / transporting auxiliary circulation device 22. FIG. 10 is a perspective view of the bill separation / transport auxiliary body circulation device 22 as viewed from the discharge port side of the separated bills, and FIG. 11 shows the bill separation / transport auxiliary body circulation device 22 connected to the transport pipe 12. It is a perspective view seen from the part side.

The bill separation / transport auxiliary body circulation device 22 is arranged so as to be overlapped with the transport auxiliary body insertion device 23 that sends the transport auxiliary body 16 into the transport pipe 12 (the starting end of the outward transport pipe 12a) and the transport auxiliary body insertion device 23. The end of the return transport pipe 12b is connected, and the bill P arriving from the return transport pipe 12b and the separate recovery device 24 that separates and collects the transport auxiliary body 16 that has pushed and moved the bill P from the rear are integrated. It is composed.

The transport auxiliary body 16 separated from the bill P by the separate / recovery device 24 falls downward from the separate / recovery device 24 through the guide passage 28 (see FIG. 11), and goes to the standby place 29 in the transport auxiliary body insertion device 23. Delivered. As a result, the collected transport assist body 16 is used as the transport assist body 16 that is next sent into the outbound transport pipe 12a, and the transport assist body 16 is repeatedly used.

Specifically, as shown in FIG. 12, the separation / recovery device 24 has a function of passing the banknote P that has been pushed and moved by the transport assisting body 16 to the downstream, and the transport assisting body 16 abuts and stops. It is provided with a holding portion 41 to be fulfilled. The holding portion 41 has a receiving portion 42 having a U-shaped cross section for receiving the transport assisting body 16 at the tip of an arm that rotates about one end in a predetermined angle range. A slit 43 through which the bill P is passed is provided in the center of the receiving portion 42. Further, a discharge port for dropping the transport assist body 16 is provided on the bottom surface of the receiving portion 42.

Normally, the holding portion 41 is positioned so that the tip of the receiving portion 42 faces the end of the transport pipe 12 (return transport pipe 12b) (position shown by a solid line in FIG. 12). When the bill P pushed and moved by the transport assisting body 16 passes through the slit 43 of the receiving portion 42 and is received by the receiving portion 42, the holding portion 41 is driven by the motor to rotate and receive the receiving portion. 42 is moved to a position (the position indicated by the broken line in FIG. 12) off the extension of the transport pipe 12 (return transport pipe 12b). At this position, the opening at the bottom of the receiving portion 42 communicates with the guide passage 28, and the transport assist body 16 falls downward through the guide passage 28.

The bill P that has passed through the slit 43 is transported to a transport belt (not shown) and discharged from the discharge port at the rear end of the separation / recovery device 24. As described above, the discharged banknote P is conveyed to the banknote transfer unit 26 and sent to the banknote storage unit 25.

The transport assisting body 16 that has fallen down the guide passage 28 enters the waiting place 29 provided in the transport assisting body inserting device 23 and is received.

The transport assist body insertion device 23 includes a movable arm 46 having a delivery portion 45 having a U-shaped cross section that rotates around one end and holds the transport assist body 16 at the other end. The delivery unit 45 is provided with a large opening for smoothly flowing the air flow from the air flow generator 21.

The movable arm 46 has a standby position (position indicated by a broken line in FIG. 12) in which the delivery unit 45 fits in the standby place 29 and a delivery unit 45 which is an extension of the start end of the transfer pipe 12 (outward transport pipe 12a). It is driven by a motor to rotate at a position (position shown by a solid line in FIG. 12). The movable arm 46 is normally in the standby position, and the delivery unit 45 receives the transport assist body 16 that has fallen from the separation / recovery device 24 through the guide passage 28. When the transport assist body 16 is fed into the transport pipe 12 (outward transport pipe 12a), the movable arm 46 is rotated to move the delivery unit 45 to the feed position. Then, due to the air flow from the air flow generator 21, the transport auxiliary body 16 is separated from the delivery unit 45 and sent into the transport pipe 12 (outward transport pipe 12a).

In this way, the transport auxiliary body 16 that has returned while pushing and moving the bill P from behind is separated from the bill P by the separation / recovery device 24, collected, and delivered to the transport auxiliary body insertion device 23, and then next. It is reused for sending out.

Next, the posture of each part of the transport pipe 12 will be described.

Here, as shown in FIG. 1, four gaming machine islands 3 are arranged side by side with a passageway, and as shown in FIG. 2, in order to collect bills P from the relay box 6 of these gaming machine islands 3. , The case where the transport pipe 12 is piped will be described as an example.

As shown in FIGS. 9 and 2, the outbound transport pipe 12a is in a vertical posture when exiting from the back surface of the safe 11, but after that, it is in a horizontal posture through the twisted portion 51 and then moves vertically upward. Change. When it reaches the ceiling, the course is returned to the horizontal position, and then the posture is changed to the vertical posture through the twisted portion 51, and the ceiling is extended to the transport assist relay device 17 in the vertical posture. The end of the outward transfer pipe 12a is connected to the transfer auxiliary relay device 17 in a vertical position.

The return route transfer pipe 12b is in a vertical position at the starting end portion connected to the transfer auxiliary relay device 17, but is then placed in a horizontal position via a twisted portion 51 before reaching the first take-in device 14. The return path transport pipe 12b is extended straight above the ceiling in a horizontal position, passing through a plurality of intake devices 14 on the way, and above the relay box 6 of each gaming machine island 3. When the return transport pipe 12b reaches the end of the portion passing through the attic, the course is changed vertically downward while maintaining the horizontal posture, and when it descends to the height of the safe 11, the course is returned to the horizontal position, and then the vertical posture is reached through the twisted portion 51. It is connected to the connection port on the back of the safe 11 in a vertical position (see FIG. 9).

When the transport pipe 12 (return transport pipe 12b) of the portion where the bill P is transported is curved to change the course, if the paper surface of the bill P faces the inside and outside of the arc, the bill P can pass through the curved portion without difficulty. can do. Therefore, as shown in FIG. 2, the transport pipe 12 is placed in a horizontal position before and after the position where the course of the transport pipe 12 (return transport pipe 12b) is changed horizontally / vertically.

Even when the banknote P is moving by itself without transporting the bill P, the axis of the transport assisting body 16 is perpendicular to the radial direction of the curved portion, so that even a small radius can be smoothly moved. You can go through the curved part. That is, also for the outbound transport pipe 12a, it is preferable that the transport pipe 12 is in a horizontal posture before and after the position where the course of the transport pipe 12 is changed horizontally / vertically as shown in FIG.

Further, when the transport pipe 12 is extended in a thin wall, it is preferable that the longitudinal direction of the cross section of the transport pipe 12 is the direction along the wall surface (the short side direction of the cross section is the thickness direction of the wall). Therefore, the transport pipe 12 of the portion extending vertically in the wall is set to have the above-mentioned orientation.

Since the twisted portion 51 is provided in the middle of the transport pipe 12, the course of the transport pipe 12 can be freely set in a plane such as the attic while mixing the vertical direction and the horizontal direction as the transport direction of the bill P. ..

Next, the configuration of the transport auxiliary relay device 17 will be described.

As shown in FIG. 13, the transport auxiliary body relay device 17 draws air from the relay portion 61 having a rectangular thin box shape to which the outward transport pipe 12a and the return transport pipe 12b are connected and the end of the outward transport pipe 12a. It is provided with a blower portion 62 that has a function of sucking and a function of blowing air to the start end of the return route transport pipe 12b. FIG. 14 shows a state in which a part of the outer cover of the blower portion 62 is removed. Inside the blower unit 62, a fan 63 driven by a motor and a control device 64 for controlling the operation of the transport auxiliary body relay device 17 are provided. The suction duct 65 connected to the suction port of the fan 63 is connected to the suction duct connection port 71a (see FIGS. 15 and 16) that opens on the back surface of the relay portion 61, and is connected to the air outlet of the fan 63. Is connected to a ventilation duct connection port 71b (see FIGS. 15 and 16) that opens on the back surface of the relay unit 61.

As shown in FIG. 14, on the front side of the relay portion 61 of the transport auxiliary body relay device 17, the inflow side connection port 67 to which the outward transport pipe 12a is connected and the outflow side connection port 68 to which the return transport pipe 12b is connected. Is provided so as to protrude forward. The inner edge of each of the inflow side connection port 67 and the outflow side connection port 68 has a shape corresponding to the outer edge side shape of the transport pipe 12, and the end of the outbound transport pipe 12a is densely inserted into the inflow side connection port 67. Then, the start end of the return transfer pipe 12b is densely inserted into the outflow side connection port 68.

FIG. 15 shows a state in which the cover on the front side of the relay unit 61 is removed. The relay unit 61 has a rectangular base plate 71 that constitutes the back surface of the relay unit 61, and a rotary plate 72 that is rotatably supported by the support shaft 73 on the base plate 71. The rotating plate 72 is provided with a pair of holding portions 74 at target positions about the support shaft 73. The holding unit 74 functions to temporarily hold the transport assisting body 16.

The rotating plate 72 can be stopped at two positions, a first stop position shown in FIG. 15 and a second stop position rotated 180 degrees from the first stop position. FIG. 16 shows a state in which the rotating plate 72 is rotating from the first stop position to the second stop position. A transmission type optical sensor 76 for detecting whether or not the rotating plate 72 is in the first stop position and the second stop position is provided.

When the rotating plate 72 stops at any of the stop positions, one holding portion 74 is located just behind the inflow side connection port 67 and is connected to the inflow side connection port 67 (referred to as a receiving position), and the other The holding portion 74 is located just behind the outflow side connection port 68 and is connected to the outflow side connection port 68 (referred to as a discharge position).

The rotating plate 72 is provided with a ventilation hole 72a at a position corresponding to the center of each holding portion 74. When the rotary plate 72 is stopped at the stop position, the suction duct 65 and the inflow side connection port 67 communicate with each other through the suction duct connection port 71a provided in the base plate 71 and the ventilation hole 72a provided in the rotary plate 72, and The air duct 66 and the outflow side connection port 68 communicate with each other through the air duct connection port 71b provided in the base plate 71 and the ventilation hole 72a provided in the rotating plate 72.

FIG. 17 is a view of the relay unit 61 from which the front cover has been removed as viewed from above. The holding portion 74 is a pair of a receiving portion 81 that abuts on the transport assisting body 16 arriving from the outbound transport pipe 12a to receive the transport assisting body 16 and a pair of the transport assisting body 16 that abuts on the receiving portion 81 from the left and right sides. The holding roller 82 is provided. The transport auxiliary body 16 is sandwiched and held between the pair of holding rollers 82 and the receiving portion 81. The receiving portion 81 is composed of a shock absorbing member that absorbs the shock when the transport assisting body 16 is received.

The pair of holding rollers 82 are arranged at intervals on the left and right so that the transport assisting body 16 can push and pass between them. The holding roller 82 is attached to the inside of the tips of the pair of holding arms 83 whose longitudinal direction is the traveling direction of the transport assisting body 16. The rear end of the holding arm 83 is pivotally supported, and the distance between the pair of holding rollers 82 attached to the tip of the holding arm 83 is slightly narrower than the diameter of the transport assist body 16 and the distance between the pair of holding rollers 82 is transported. It rotates to an open position that is sufficiently wider than the diameter of the auxiliary body 16, and is urged by a spring or the like toward the closed position.

Of the pair of holding arms 83, a release plate 84 parallel to the rotating plate 72 and projecting outward is attached to the outer side surface of the outer holding arm 83. As shown in FIG. 15, the release plate 84 is a rectangular metal plate whose longitudinal direction is the tangential direction of the circle in which the rotary plate 72 rotates, and both ends in the longitudinal direction are bent diagonally in a direction away from the rotary plate 72. There is. When the rotating plate 72 rotates and the holding portion 74 comes to the release position, the base plate 71 comes into contact with the release plate 84 of the holding portion 74 that has come to the release position, and the release plate 84 is attached to the base plate 71. A release roller 85 is attached to push the holding arm 83 to an open position where the tip opens outward. The base plate 71 is provided with a sensor 75 that detects whether or not the holding portions 74 at the first stop position and the second stop position hold the transport assist body 16. The sensor 75 is a transmissive optical sensor.

FIG. 18 shows how the holding portion 74 at the receiving position holds the transport assisting body 16 arriving from the outward transport pipe 12a. As shown in FIG. 6A, the holding portion 74 stands by at a closed position where the distance between the pair of holding rollers 82 is slightly narrower than the diameter of the transport assisting body 16. As shown in FIG. 3B, the transport assisting body 16 arriving from the end of the outward transport pipe 12a passes through a portion of the holding rollers 82 while expanding the distance between the pair of holding rollers 82, and is shown in FIG. ), It comes into contact with the receiving portion 81. At the position of contact with the receiving portion 81, the center of the transport assisting body 16 is slightly closer to the receiving portion 81 than the line C1 connecting the centers of the pair of holding rollers 82, and the center of the transport assisting body 16 is located on the receiving portion 81 side. Held by 82.

FIG. 19 shows a state when the holding portion 74 comes to the discharge position. When the release position is reached, the release plate 84 comes into contact with the release roller 85, so that the outer holding arm 83 to which the release plate 84 is attached rotates in the opening direction, and the distance between the pair of holding rollers 82 is conveyed. The diameter becomes wider than the diameter of the auxiliary body 16, and the holding of the transport auxiliary body 16 by the receiving portion 81 and the holding roller 82 is released.

As shown in FIGS. 20 and 21, various ribs 91 and 92 that regulate the position and posture of the transport assist body 16 are inside the inflow side connection port 67 and the outflow side connection port 68 and inside the holding portion 74. , 93 are provided. The ribs 91 and 92 are provided inside the inflow side connection port 67 and the outflow side connection port 68, and the rib 93 is provided inside the holding portion 74. The side rib 91 that abuts on the outer peripheral surface of the large diameter portion 16c of the transport auxiliary body 16 gradually narrows the passage width of the portion through which the large diameter portion 16c of the transport auxiliary body 16 passes from the entrance side of the connection port to the back. After that, it is set to spread a little suddenly. The side rib 91 prevents the left and right rattling of the transport assist body 16.

The guide ribs 92 provided inside the inflow side connection port 67 and the outflow side connection port 68 at positions corresponding to the upper, middle, and lower constricted portions 16d of the transport auxiliary body 16 are positioned in the axial direction of the transport auxiliary body 16 and. Regulate posture. Similarly, a pair of upper and lower guide ribs 93 provided inside the holding portion 74 and at positions corresponding to the upper and lower constricted portions 16d of the transport assisting body 16 regulate the axial position of the transport assisting body 16.

The upper and lower guide ribs 92 have a taper that widens the distance between the connection ports 67 and 68 toward the holding portion 74. The pair of upper and lower guide ribs 93 following the inner side of the upper and lower guide ribs 92 have a taper (taper opposite to the guide ribs 92) in which the distance between the upper and lower guide ribs 93 widens toward the connection ports 67 and 68.

The transport auxiliary relay device 17 operates as follows.

By driving the fan 63 of the blower portion 62, air is sucked from the end of the outward transport pipe 12a and the air flow is sent to the start end of the return transport pipe 12b. As a result, an air flow from the start end to the end of the outward transport pipe 12a and an air flow from the start end to the end of the return transport pipe 12b are generated and strengthened.

The holding portion 74 at the receiving position receives and holds the transport assisting body 16 arriving from the outward transport pipe 12a. At this time, the position and posture of the transport auxiliary body 16 arriving from the outward transport pipe 12a are restricted by the side ribs 91 and the guide ribs 92 and 93 when passing through the inflow side connection port 67, and the holding portion 74 at the receiving position is restricted. It is held in the correct position and posture.

After that, when the rotating plate 72 rotates 180 degrees, the holding portion 74 at the receiving position moves to the releasing position. When the release position is moved, the release plate 84 comes into contact with the release roller 85, and the holding of the transport assist body 16 is released. When the fan 63 of the blower portion 62 operates in the released state, the transport auxiliary body 16 is sent out to the return path transport pipe 12b through the outflow side connection port 68 in response to the air blown from the blower duct 66. At this time, the position and posture of the transport auxiliary body 16 are regulated by the side ribs 91, the guide ribs 92, and 93, and the transport auxiliary body 16 is delivered into the return transport pipe 12b in the correct posture.

In the present embodiment, the transport auxiliary body 16 is sent from the transport auxiliary body relay device 17 to the return route transport pipe 12b, and the transport auxiliary body 16 is sent out from the transport auxiliary body insertion device 23 of the collective safe 11 to the outward transport pipe 12a. Is controlled so that they are performed at the same time. As a result, the first movement of the transport auxiliary body 16 from the transport auxiliary body insertion device 23 of the collecting safe 11 to the transport auxiliary body relay device 17 through the outward transport pipe 12a and the assembly from the transport auxiliary body relay device 17 through the return route transport pipe 12b. The second movement of the transport assisting body 16 to the separation / recovery device 24 of the safe 11 is performed in parallel.

As a result, the transport assisting body 16 sent from the collecting safe 11 to the outbound transport pipe 12a goes around the entire transport pipe 12 and returns to the collecting safe 11 without providing the transport assisting body relay device 17, and then the next transport assisting body. Compared with the case of sending out 16, the operation of collecting the banknotes P by the transporting auxiliary body 16 can be performed in a shorter cycle, and the collecting capacity of the paper leaf collecting and transporting system 10 per unit time can be enhanced.

It should be noted that the transport auxiliary body 16 is sent from the transport auxiliary body relay device 17 to the return route transport pipe 12b and the transport auxiliary body 16 is sent out from the transport auxiliary body insertion device 23 of the collective safe 11 to the outward transport pipe 12a at the same time. Not limited to that. The first movement in which the transport assist body 16 sent by the transport assist body insertion device 23 moves in the outward transport pipe 12a, and the first movement in which the transport assist body 16 sent out by the transport assist body relay device 17 moves in the return transport pipe 12b. At least a part of the two movements may be performed in parallel. If even a part of the first movement and the second movement are performed in parallel, the delivery cycle can be shortened and the collection capacity can be improved accordingly.

For example, when the second movement of the return route from the transport auxiliary body relay device 17 to the collective safe 11 takes longer than the first movement of the outward route from the collective safe 11 to the transport auxiliary body relay device 17, the travel time is longer. The transport auxiliary body 16 may be delivered to the return route (return transport pipe 12b) first, and then to the outward route (outward transport pipe 12a) having a short travel time. It is desirable to control the delivery at the same time as the second movement on the return route is completed or at the timing when the first movement on the outward route is completed before that.

In the transport auxiliary body relay device 17, as shown in FIG. 13, at the connection point between the inflow side connection port 67 and the end of the outward transport pipe 12a, and at the connection point between the outflow side connection port 68 and the start end of the return route transport pipe 12b. The inflow side connection port 67 and the outflow side connection port 68 are arranged so that the longitudinal direction of the cross section of the outward transport pipe 12a and the longitudinal direction of the cross section of the return transport pipe 12b are parallel (match).

In the installation example of FIG. 2, the transport auxiliary body relay device 17 is an extension in which the outward transport pipe 12a and the return transport pipe 12b of the portion extended along the upper side of the relay box 6 of each gaming machine island 3 are extended as they are. It is arranged on the line. However, for example, when the transport auxiliary relay device 17 must be installed by being bent from the above extension line, it becomes necessary to bend the outward transport pipe 12a and the return transport pipe 12b. At this time, if the longitudinal directions of the cross sections of the outward transport pipe 12a and the return transport pipe 12b are parallel at the connection point to the transport auxiliary body relay device 17, the curved portion of the outward transport pipe 12a and the return transport pipe 12b has the same structure. It is possible to connect curved connecting members.

However, if the longitudinal directions of the cross sections of the outward transport pipe 12a and the return transport pipe 12b are not parallel at the connection points to the transport auxiliary body relay device 17, the curved portions of the outward transport pipe 12a and the return transport pipe 12b have different curvatures. It becomes necessary to use a curved connecting member. Therefore, not only is it time-consuming to design and manufacture the product individually, but it is also difficult to maintain the product because it is an individually manufactured product. Like the transport assist body relay device 17 of the present embodiment, the outward transport pipe 12a and the return transport pipe 12b are both in the vertical posture at the connection point to the transport auxiliary body relay device 17, and the longitudinal directions of the cross sections are parallel. By doing so, the above problem can be solved, and the degree of freedom in the installation location of the transport auxiliary body relay device 17 can be increased.

In the paper leaf collection and transport system 10 shown in FIG. 2, since it is necessary to put the return route transport pipe 12b in the horizontal position at the portion passing over the relay box 6, the outflow side connection port 68 of the transport auxiliary body relay device 17 is required. The return path transport pipe 12b connected to the above is changed from the vertical posture to the horizontal posture by inserting the twisted portion 51 at a position upstream of the first intake device 14.

Due to its mechanism, the transport auxiliary body relay device 17 is installed vertically (the posture shown in FIG. 13) even if it is installed horizontally (the posture shown in FIG. 13), and the whole is 90 degrees around the rotation axis of the rotating plate 72 with respect to the posture shown in FIG. It may be installed in a rotated posture), or may be installed so that the inflow side connection port 67 and the outflow side connection port 68 face upward. However, since the holding by the holding roller 82 is released at the discharge position, the posture in which the outflow side connection port 68 faces downward is such that the transport auxiliary body 16 does not naturally fall into the return transport pipe 12b through the outflow side connection port 68. You need to avoid it.

The configuration of the transport auxiliary relay device 17 is not limited to that illustrated in FIGS. 13 to 21. For example, the transport auxiliary body relay device 17 is provided with a buffer unit capable of holding a plurality of transport auxiliary bodies 16 arriving from the outbound transport pipe 12a, and one transport auxiliary body 16 held in the buffer unit is sent out to the next. It may be configured to be used for.

Further, in the transport assist body relay device 17 shown in FIG. 13 and the like, the transport assist body 16 received from the inflow side connection port 67 is moved to the outflow side connection port 68 side by rotating the rotating plate 72 by 180 degrees. However, the method of movement may be arbitrary. For example, as shown in FIG. 22, four holding portions 74 are provided on the rotating plate 72 every 90 degrees, and the stop position of the rotating plate 72 is set every 90 degrees. Then, the inflow side connection port 67 is provided at a position facing one holding portion 74a, and the outflow side connection port 68 is provided at a position facing the holding portion 74b at a position where the rotating plate 72 is rotated 90 degrees from the position, and the rotation plate 72 is rotated. The transport auxiliary body 16 may be moved from the receiving position to the discharging position by rotating the plate 72 by 90 degrees. In addition, the transport auxiliary body 16 may be slidably moved from the receiving position to the discharging position.

In the transport auxiliary body relay device 17 shown in FIG. 13 and the like, since the transport auxiliary body 16 is moved from the receiving position to the discharge position by using the rotating plate 72, the relay portion 61 of the transport auxiliary body relay device 17 becomes thin and transports. The installation of the auxiliary body relay device 17 is less likely to interfere with the decorations of the game hall 2 and the game machine island 3.

Further, as shown in FIGS. 17 and 18, the transport auxiliary body relay device 17 catches the transport auxiliary body 16 with the holding roller 82 urged by the spring, holds the rotary plate 72 during rotation, and holds the rotary plate 72 during rotation. When the holding portion 74 comes to the release position by rotation, the release plate 84 comes into contact with the release roller 85 to release the holding by the holding roller 82 urged by the spring. Therefore, it is not necessary to use an electromagnetic relay or the like, and the transport assisting body 16 can be received, held, and released with a simple configuration.

Further, as shown in FIGS. 20 and 21, side ribs 91 and guide ribs 92 and 93 are provided inside the inflow side connection port 67 and the outflow side connection port 68, so that the posture of the transport assist body 16 is restricted. Stable and secure the catch of the transport auxiliary body 16 and correct the posture of the transport auxiliary body 16 to be sent from the inflow side connection port 67 to the return transport pipe 12b, and send the transport auxiliary body 16 to the return transport pipe 12b without tilting. Can be done.

Next, a portion of the bill P transported from the sub-conveying device 13 and sent out into the transport pipe 12 by the fetching device 14 will be described.

As shown in FIG. 23, the sub-conveying device 13 fulfills a function of transporting banknotes P from the relay box 6 toward the return path transport pipe 12b extending horizontally above the relay box 6. When the bill P is taken into the return transport pipe 12b from the sub-conveyor 13, the traveling direction of the bill P changes from vertical to horizontal. As described above, when changing the traveling direction, it is necessary that the paper surface of the bill P faces the inside and outside of the arc. Therefore, as shown in FIGS. 23 and 24, the posture of the return path transport pipe 12b extending horizontally above the relay box 6 is such that the paper surface of the bill P (P3 in FIG. 24) to be transported is in the vertical direction. Be in a horizontal position. Then, at least the terminal portion (the portion immediately before reaching the fetching device 14) of the transport pipe (referred to as the sub transport pipe 101) extending in the vertical direction of the sub transport device 13 is the bill P to be transported (P1 in FIG. 24). ) Is arranged so as to face the extension direction Fw of the return transfer pipe 12b at the location where the take-in device 14 is located.

FIG. 24 shows the periphery of the take-in device 14 inserted in the return transfer pipe 12b of the portion passing above the relay box 6. Inside, the import device 14 changes the course of the bill P as shown in P1, P2, and P3 of FIG. 24 and sends it out into the return transport pipe 12b. The take-in device 14 can smoothly send the banknote P conveyed by the sub-conveyor device 13 into the transfer pipe 12 by changing the course of the banknote P without twisting.

In addition, in order to put the return route transport pipe 12b vertically connected to the outflow side connection port 68 of the transport auxiliary body relay device 17 in the horizontal posture before reaching the first capture device 14, the paper leaf collection and transport system In No. 10, the twisted portion 51 is inserted into the return path transport pipe 12b immediately after exiting the outflow side connection port 68 of the transport auxiliary body relay device 17 (see FIG. 2).

Next, the sub-conveyor device 13 will be described.

FIG. 25 is a perspective view showing the sub-conveyor device 13 and the take-in device 14 (and the transport pipes 12 before and after the sub-conveyor device 14) connected to the upper end thereof. FIG. 26 is a cross-sectional view of the sub-conveyor device 13 and the take-in device 14 (and the transport pipes 12 before and after the sub-conveyor device 14) connected to the upper end thereof. FIG. 27 is an enlarged cross-sectional view showing the upper portion of the sub-transport pipe 101 of the sub-conveyor device 13 and the take-in device 14. FIG. 28 is an enlarged cross-sectional view showing the lower part of the sub-conveyor pipe 101 of the sub-conveyor device 13.

The sub-transport device 13 conveys the banknote P by using a transfer auxiliary body 16 different from the transfer auxiliary body 16 that moves the transfer pipe 12. However, the shape is the same as that of the transport auxiliary body 16 that moves the transport pipe 12. In the sub-conveyor device 13, one transport auxiliary body 16 reciprocates through the sub-conveyor pipe 101 extending in the vertical direction. The cross-sectional shape of the auxiliary transfer pipe 101 is the same as that of the straight portion of the transfer pipe 12, and the description thereof will be omitted.

As shown in FIGS. 25 and 26, the sub-conveyor device 13 includes a sub-transport pipe 101 extending in the vertical direction, a transport auxiliary body 16 that reciprocates in the sub-convey pipe 101 up and down, and a sub-convey pipe. A bill taking-in portion 103 attached to the lower end of the 101, and an ascending flow generating portion 102 that sends an air flow from the lower side to the upper side of the bill taking-in portion 103 to the sub-conveying pipe 101 via the bill taking-in portion 103. There is.

The auxiliary transfer pipe 101 is provided with a twisted portion 51 slightly in front of the upper end thereof. The twisting portion 51 twists the sub-conveying pipe 101 by 90 degrees. As described above, the portion of the auxiliary transport pipe 101 above the twisted portion 51 is oriented so that the paper surface of the bill P passing through the portion faces the extending direction of the return transport pipe 12b at the installation location of the take-in device 14. (See FIG. 24). On the other hand, in the portion below the twisted portion 51, the longitudinal direction of the cross section of the sub-conveying pipe 101 coincides with the extending direction of the return transport pipe 12b at the installation location of the take-in device 14.

As shown in FIG. 28, the bill taking-in portion 103 has a passage portion 104 having a cross-sectional shape similar to that of the sub-conveying pipe 101 and having a length of about 15 cm communicating with the lower end of the sub-conveying pipe 101, and the passage. An opening 104b provided on one side wall of the portion 104 for taking in the bill P, a transport roller 105a and a transport belt 105b for sending the bill P diagonally upward from the opening 104b into the aisle portion 104 are provided. There is.

The lower end of the passage portion 104 is narrowed in width to receive and hold the transport assisting body 16. Further, at the lower end of the passage portion 104, an inflow port 104c for the air flow from the ascending flow generating portion 102 is provided. An air duct 102b extending from a fan 102a (see FIG. 25) of the ascending current generating portion 102 is connected to the inflow port 104c.

FIG. 29 shows a state in which the bill taking-in portion 103 with the lid (the wall portion on the side facing the opening 104b) of the passage portion 104 removed is viewed from the side facing the opening 104b. The transport roller 105a and the transport belt 105b bridged to the transport roller 105a are provided on the left and right sides of the passage portion 104 in the width direction, respectively. Since the banknotes P are sent into the aisle portion 104 by the left and right transport belts 105b, the banknotes P are not tilted diagonally when the banknotes P are sent upward, and the banknotes P can be sent straight into the aisle part 104.

As shown in FIG. 27, the upper end of the sub-transport pipe 101 is provided with a narrowed opening 101a, and the transport auxiliary body 16 comes into contact with the narrowed portion of the upper end of the sub-convey pipe 101 and stops. The bill P pushed up by the transport assisting body 16 passes through the opening 101a and advances into the capture device 14.

The sub-conveyor device 13 operates as follows.

The ascending current generating portion 102 is constantly stopped, and the transport assisting body 16 is held at the lower end of the passage portion 104 of the bill taking-in portion 103 (see FIG. 26). When the bill P is sent out into the sub-conveying pipe 101 by the bill receiving unit 103, the transport roller 105a or the like of the bill receiving unit 103 is driven by a motor, and the bill P received from the outside (relay box 6) is passed through the passage portion 104. It is sent out toward the opening 104b of. When the bill P is completely sent out into the passage portion 104, the ascending flow generating portion 102 is operated to generate an upward air flow. By the action of this air flow, the transport auxiliary body 16 rises in the auxiliary transport pipe 101 while pushing the bill P from the rear end.

The banknote P transported to the upper end of the sub-conveying pipe 101 by the transporting auxiliary body 16 raised by the air flow advances directly into the fetching device 14 through the opening 101a and is fetched into the fetching device 14 (see FIG. 27). The transport auxiliary body 16 comes into contact with the narrow portion at the upper end of the sub transport pipe 101 and stops. After that, when the ascending current generating portion 102 is stopped, the transport assisting body 16 naturally falls, returns to the original position, and is held at the lower end of the passage portion 104 of the bill taking-in portion 103. As a result, a series of operations for transporting the bill P to the upper fetching device 14 is completed.

The sub-transport device 13 has a transport capacity for transporting a plurality of (for example, 3 to 5) bills P upward at a time. The bill taking-in unit 103 performs the operation of sending the bills P one by one into the passage portion 104 a plurality of times to form a state in which the plurality of bills P stay in the passage portion 104. When the ascending current generating unit 102 is operated in this state, the transport assisting body 16 transports the plurality of bills P to the upper end capturing device 14 at a time.

Next, the capture device 14 will be described.

As shown in FIG. 27, the take-in device 14 has a cross-sectional shape equivalent to that of the transport pipe 12, and has a passage portion 121 to which the transport pipe 12 (return transport pipe 12b) is connected to the front and rear. The passage portion 121 has an inner shape similar to that of the straight portion of the transport pipe 12, and the transport auxiliary body 16 can smoothly pass through the passage portion 121. The passage portion 121 is in a horizontal position. An opening 121b for taking the bill P into the passage portion 121 is formed on the lower wall surface of the passage portion 121. The import device 14 includes a transport unit 122 for sending bills P from the opening 121b into the passage unit 121.

The transport unit 122 conveys the bill guide path 123 leading to the opening 121b, the transport belt 124 that transports the bill P conveyed by the sub-convey device 13 toward the opening 121b of the passage portion 121 through the bill guide path 123, and the transport belt 124. In order to prevent the leakage of airflow from the feeding roller 125a and the feeding belt 125b, which have the function of completely sending the bill P sent into the passage portion 121 by the belt 124 to the end thereof into the passage portion 121, and the bill guide path 123. It includes a shutter 126 provided in the middle of the bill guide path 123 to open and close the bill guide path 123, a transport belt 124, a feeding roller 125a, a motor for driving the feeding belt 125b, and the like. The shutter 126 is urged to a closed position by a spring or the like.

When the deformed banknote P or the weak banknote P is discharged from the relay box 6 to the sub-conveyor device 13, the banknote P transported to the import device 14 by the sub-conveyor device 13 and the transfer belt 124 of the import device 14 In some cases, the contact with the banknote P becomes insufficient, and the banknote P is conveyed by the conveying belt 124 and cannot be taken into the passage portion 121 well. Therefore, the take-in device 14 presses the bill P, which has not been successfully conveyed by the transfer belt 124, toward the transfer belt 124, and sandwiches the bill P with the transfer belt 124 to assist the transfer. It also has rollers 128.

As shown in FIG. 30, the holding roller 128 is attached to the lower end of the movable arm 129 axially supported by the support point 129a at the upper end portion, and swings the movable arm 129 by turning on / off the solenoid 130. When the solenoid 130 is turned on, the holding roller 128 at the lower end advances into the bill guide path 123 to reach the holding position (see FIG. 30B) for holding the bill P between the bill guide path 123 and the transport belt 124, and the solenoid 130 is turned off. Then, the pinching roller 128 is urged by a spring or the like to return to the retracted position (see FIG. 30A) retracted to the side of the bill guide path 123.

The transport belt 124 is provided at two locations on the left and right in the width direction of the bill P, and the holding roller 128 is located between the left and right transport belts 124. Further, a bill detection sensor 131 for detecting the bill P is provided near the center of the range in which the transport belt 124 is bridged in the transport direction. Here, the bill detection sensor 131 is an optical sensor. Since the bill detection sensor 131 and the movable arm 129 are extremely close to each other, the movable arm 129 is provided with light so that the movable arm 129 does not interfere with the installation of the optical sensor or the movable arm 129 does not block the light of the optical sensor. There is an opening to avoid the sensor and its light.

When the bill detection sensor 131 detects the bill P, the solenoid 130 is turned on to displace the pinching roller 128 to the pinching position, and the bill P is sandwiched between the pinching roller 128 and the transport belt 124 for transport. When the bill detection sensor 131 does not detect the bill P, the solenoid 130 is turned off and the holding roller 128 is returned to the retracted position.

The take-in device 14 has a main body side provided with the holding roller 128 and a door side provided with the transport belt 124 facing the holding roller 128 in order to deal with the case where the bill P is clogged inside. It has a structure that can be separated at the banknote guide path 123. The main body side is integrated with the passage portion 121 and is fixedly installed. If the bill P is clogged, remove the door side to deal with it. Since a movable mechanism including a holding roller 128 or the like, which is a relatively heavy object, is provided on the fixed main body side, the door side can be easily removed. Further, since the movable mechanism, which is a heavy object, is also an element that generates vibration, if it is provided on the door side, problems such as loosening of the attachment on the door side are likely to occur. Therefore, movable mechanisms such as the holding roller 128 and the movable arm 129 are provided on the main body side.

As described above, the taking-in device 14 is provided with the holding roller 128, so that even a deformed bill P or a weak bill P can be stably taken into the passage portion 121.

When a plurality of banknotes P are transported from the sub-transport device 13 at one time, the import device 14 can make the plurality of banknotes P stand by in the banknote guide path 123 at one time. When the take-in device 14 receives a command from the control unit 27 to send the bill P to the transport pipe 12, the bill P waiting in the bill guide path 123 is transferred to the transport belt 124, the holding roller 128, the feeding roller 125a, and the feeding belt. 125b and the like are driven and conveyed, and are sent out into the passage portion 121.

Next, the collection of banknotes P and the relay box 6 in the gaming machine island 3 will be described.

The island banknote transfer device 8 that takes in the banknotes P discharged from the back surface of each game ball lending machine 4 in the game machine island 3 and transports them to one end of the game machine island 3 also moves the transport auxiliary body 16 by the air flow. The bill P is pushed and moved by the transport assisting body 16 from the rear to be transported.

FIG. 31 is a plan view showing the island bill transporting device 8 installed in the gaming machine island 3, and FIG. 32 is a front view showing the island bill transporting device 8 installed in the gaming machine island 3. FIG. 33 is a diagram showing the inside of the relay box 6.

Inside the gaming machine island 3, a transport pipe 140 having the same cross-sectional shape as the transport pipe 12 is installed. The transport pipe 140 is in a vertical posture, and the bill P transported through the transport pipe 140 is transported in an upright posture. On the game machine island 3, the game ball rental machine 4 is formed in a box shape with a narrow front width in order to increase the number of installed machines. Therefore, the bill slot provided in the game ball lending machine 4 is also usually vertically long. The bill P is inserted into the bill insertion slot in a standing posture, and the bill P is ejected from the back surface of the game ball lending machine 4 in a standing posture. Therefore, the transport pipe 140 of the island bill transport device 8 is configured to receive the bill P from the game ball lending machine 4 in the upright posture and to convey the bill P in the upright posture.

The transport pipe 140 extends from the relay box 6 toward the other end of the gaming machine island 3, and is piped so as to make a U-turn at the other end and return to the relay box 6. In the middle of the portion of the transport pipe 140 that makes a U-turn and then returns to the relay box 6 (referred to as a return route), it was discharged from the back surface of the game ball lending machine 4 to a position corresponding to each game ball lending machine 4. A bill taking device 142 for taking the bill P into the transport pipe 140 is installed. The bill taking device 142 includes bills P from the gaming ball lending machine 4 arranged on the front surface side of the gaming machine island 3 and bills P from the gaming ball lending machine 4 arranged on the back surface side of the gaming machine island 3. Is provided on both sides of the side wall of the transport pipe 140 in order to take in. The bill P taken into the transport pipe 140 from the bill take-in device 142 stays at a predetermined take-in completion position with its paper surface in a posture along the extending direction of the transport pipe 140.

Inside the relay box 6, an air flow generator 144 similar to the air flow generator 21 provided in the safe 11 and a bill separation having the same configuration as the bill separation / transport auxiliary circulation device 22 provided in the safe 11 are separated. A transport auxiliary circulation device 145 is provided. The bill separation / transfer auxiliary body circulation device 145 has a transfer auxiliary body insertion device 146 similar to the transfer auxiliary body insertion device 23 and a separation / collection device 147 similar to the separation / collection device 24 (FIGS. 32 and 33). reference).

Further, the relay box 6 includes a banknote transport unit 148 (see FIG. 33) that transports the banknotes P discharged from the separation / collection device 147, and a temporary storage device 150 that temporarily stores the banknotes P. The temporary storage device 150 temporarily stores a plurality of banknotes P received from the banknote transport unit 148, and pays out the stored banknotes P based on an instruction from the control unit 27, and performs the above-mentioned sub-conveyance. It has a function of sending out to the bill taking-in unit 103 of the device 13.

When the bill P discharged from the back surface of the game ball lending machine 4 in the game machine island 3 is transported to the relay box 6 and collected, the transfer auxiliary body insertion device 146 in the relay box 6 is inserted into the starting end of the transport pipe 140. The transport auxiliary body 16 is sent out. The transport auxiliary body 16 sent out into the transport pipe 140 moves toward the downstream in the transport pipe 140 in response to the air flow generated by the air flow generator 144, and is in the middle of the return route after making a U-turn. The bill taking device 142 collects the bill P taken into the return path from the game ball lending machine 4 and returns it to the separation collecting device 147 in the relay box 6. The separation / recovery device 147 separates the bill P and the transport assisting body 16 that have been transported by the transporting auxiliary body 16, and delivers the transporting auxiliary body 16 to the transporting auxiliary body inserting device 146. On the other hand, the separated bill P is transported to the temporary storage device 150 in the relay box 6 by the bill transport unit 148. FIG. 33 shows a path M in which the banknote transport unit 148 transports the banknote P. At this time, the bill P is conveyed in an upright posture.

FIG. 34 is a cross-sectional view showing a schematic configuration of the temporary storage device 150, and FIG. 35 is a perspective view showing the internal structure of the temporary storage device 150. The temporary storage device 150 receives and stores the banknotes P that have been transported in an upright position by the banknote transport unit 148.

The temporary storage device 150 includes a posture changing unit 151 that changes the direction of the bill P received from the bill transporting unit 148 from a posture in which the paper surface is vertical (standing posture) to a posture in which the paper surface is horizontal (laying down posture), and the paper surface. The elevator section 152 that transports the leveled banknotes P to the lower storage section 154 and the banknotes P that are stored in the storage section 154 are fed out one by one in a laid-down position, and the banknote taking-in section of the sub-conveyor device 13 It has a feeding transport unit 153 for transporting toward 103. The thick line 156 shown in FIG. 34 indicates the transport path of the bill P by the payout transport unit 153.

FIG. 36 schematically shows the configuration and operation of the temporary storage device 150. As shown in FIG. 36, the posture changing unit 151 has a pair of U-shaped grooves having a cross section facing each other along both long sides of a U-shaped base plate having one short side and a pair of long sides. It has a shape in which L-shaped protrusions are provided along both long sides so as to be formed. The posture changing unit 151 can store a plurality of banknotes P between the pair of grooves. The posture changing unit 151 supports and stores only the edge portion of the bill P by the pair of opposing U-shaped grooves.

As shown in FIG. 36A, the posture changing unit 151 is in a vertically standing posture (a posture in which the stored banknote P is in a standing posture) during standby. In this state, the banknotes transported in an upright position from the banknote transfer unit 148 are received and stored between a pair of opposite U-shaped grooves. The posture changing unit 151 has a vertical posture shown in FIG. 36 (a) and a horizontal posture (a posture in which the stored banknote P is laid down) that is rotated 90 degrees around the lower end from the vertical posture and falls horizontally. (See (b)) and is displaceable. The posture changing unit 151 is displaced into a vertical posture and a horizontal posture by a motor (not shown).

The elevator unit 152 conveys the banknote P, which has been placed in the horizontal position by the posture changing unit 151, in the horizontal position in the direction facing the paper surface (here, downward). The elevator unit 152 has a receiving plate 152a that supports the laterally-positioned bill P from below, and a holding plate 152b for sandwiching the bill P placed on the receiving plate 152a from above the receiving plate 152a. .. The receiving plate 152a is composed of two plates that support only both ends of the bill P in the width direction, and the holding plate 152b is a plate-like member whose width is narrower than the distance between the two plates of the receiving plate 152a. It is possible to pass between the two plates of the plate 152a.

During standby, the receiving plate 152a stops at a position where it just abuts on the lower surface of the posture changing unit 151 in the horizontal posture (the lower surface of the pair of U-shaped grooves of the posture changing unit 151 rotated in the horizontal posture). The pressing plate 152b is stopped at a position directly above the receiving plate 152a (between the two plates) and higher than the posture changing unit 151 in the vertical posture.

When the bill P stored in the posture changing unit 151 is conveyed downward by the elevator unit 152 and stored in the storage unit 154, the temporary storage device 150 operates as follows.

First, as shown in FIG. 36A, the posture changing unit 151 stands by in a vertical posture, and in this state, the bill P carried in an upright posture from the bill transporting unit 148 is received and stored. Next, as shown in FIG. 3B, the posture changing unit 151 tilts to the horizontal posture. The holding plate 152b is sized and positioned so as to pass between a pair of opposite U-shaped grooves (referred to as penetrating portions) of the posture changing portion 151 in the lateral posture.

After the posture changing unit 151 is in the horizontal position, the holding plate 152b of the elevator unit 152 starts descending (FIG. 36 (c)). When the pressing plate 152b reaches the penetrating portion of the posture changing unit 151, the receiving plate 152a also starts descending at the same speed as the pressing plate 152b, and thereafter, the receiving plate 152a and the pressing plate 152b are integrally lowered. .. As a result, the bill P held by the posture changing unit 151 descends while being sandwiched between the receiving plate 152a and the holding plate 152b of the elevator unit 152.

Since the posture changing unit 151 holds only the edge portion of the bill P, the bill P easily separates from the posture changing unit 151 as the elevator unit 152 descends. Then, the bill P is conveyed downward by the elevator section 152 in a state of being sandwiched between the receiving plate 152a and the holding plate 152b of the elevator section 152 (FIG. 36 (d)).

The attitude conversion unit 151 returns to the vertical attitude when the elevator unit 152 descends to some extent below the attitude conversion unit 151 (FIG. 36 (e)).

When the elevator unit 152 descends to a predetermined position, the receiving plate 152a stops descending, and the holding plate 152b continues descending (FIG. 36 (e)). The space between the stopped receiving plate 152a and the surface of the feeding transporting portion 153 where the transport belt 153b exists is the storage portion 154 (see FIGS. 34 and 35).

When the pressing plate 152b continues to descend while the receiving plate 152a has stopped descending, the pressing plate 152b passes between the two plates constituting the receiving plate 152a and descends from the receiving plate 152a. At this time, the banknote P whose both ends are supported by the two plates constituting the receiving plate 152a is pressed by the holding plate 152b and gradually curved, and eventually both ends are separated from the receiving plate 152a and fall downward to be stored. It is housed in the unit 154 (FIGS. 36 (e) and 36 (f)). In addition, in order to separate both ends of the bill P from the receiving plate 152a and drop them downward, the receiving plate 152a may be raised while lowering the holding plate 152b.

After that, the elevator section 152 (the receiving plate 152a and the pressing plate 152b) begins to rise (FIG. 36 (g)). Then, when the receiving plate 152a rises to the height of the lower end (height in standby mode) of the posture changing unit 151 (FIG. 36 (h)), the receiving plate 152a stops at that position, and the holding plate 152b continues to rise to change the posture. It moves to a position higher than the unit 151 (a position during standby) and stops (FIG. 36 (i)).

By repeating the above operation, the temporary storage device 150 can convert the bill P received from the bill transport unit 148 from the vertical posture to the horizontal posture and store a large number in the storage unit 154. The storage unit 154 of this example can store about 500 banknotes P. When the transport belt 153b is driven while the bill P is present in the storage portion 154, the lowest bill P among the bills P stored in the storage portion 154 is unwound, and the path shown by the thick line 156 in FIG. 34 is used. It is conveyed toward the bill taking-in portion 103 of the sub-conveying device 13.

When paying out the bill P, it is desirable to press the bill P downward with the holding plate 152b as shown in FIG. 36 (f). Therefore, when the position of FIG. 36 (f) is set to the normal position and the bills P are accumulated in the posture changing unit 151, the elevator unit 152 is moved to the elevator unit 152 as shown in FIGS. 36 (g) to (i) and (a) to (f). The bill P may be controlled to be conveyed to the storage unit 154.

In the temporary storage device 150, by rotating the posture changing unit 151 into the vertical posture and the horizontal posture, the posture of the bill P is changed from a vertical paper surface (standing posture) to a horizontal paper surface (laying posture). Since the conversion is performed, the posture of the bill P can be converted in a smaller space as compared with the case where the posture of the bill P is changed from the vertical state to the horizontal state by transporting the bill P while twisting. it can.

Further, as soon as the posture conversion unit 151 is in the horizontal posture, the holding plate 152b starts to descend, and as soon as the entire elevator unit 152 descends from the posture conversion unit 151, the posture conversion unit 151 returns to the vertical posture. However, the period during which the banknote P cannot be received from the banknote carrier 148 is only a short period of time, and the collection of the banknote P in the game machine island 3 is not hindered. In the present embodiment, the posture changing unit 151 returns to the vertical posture, which is a condition for the island bill transporting device 8 to send the next transport assisting body 16.

Further, since the posture changing unit 151 can store a plurality of banknotes P, the time during which the elevator unit 152 is lowered becomes longer for some reason, and the banknote transporting unit 148 transports the plurality of banknotes P during that time. Even if they come, they can be accepted and stored.

As shown in FIG. 36 (e), when the holding plate 152b is lowered from the receiving plate 152a to separate the bill P from the receiving plate 152a and moved to the storage portion 154, the bill P is disturbed and stored. As a result, when the transport belt 153b of the pay-out transport unit 153 feeds out the bill P from the storage portion 154, the bill P may be clogged. For example, as shown in FIG. 37 (a), when the pressing plate 152b starts to be lowered below the receiving plate 152a, only one end of the bill P slips off the receiving plate 152a, and the bill P Storage may be disturbed. Therefore, as shown in FIG. 37 (b), an elevator to which a sheet 155 made of a material having a frictional force against the bill P (for example, natural rubber) is attached to the upper surface of the two plates constituting the receiving plate 152a. When the holding plate 152b descends with respect to the receiving plate 152a and pushes the bill P from above to below in order to store the bill P resting on the receiving plate 152a of the portion 152 in the storage portion 154, the natural rubber The sheet 155 rubs against both ends of the bill P to prevent it from slipping off. As a result, as shown in FIG. 37 (b), the central portion of the banknote P pressed by the action of the pressing plate 152b first descends, and finally both ends are separated from the receiving plate 152a and fall into the storage portion 154. Will be. As a result, as shown in FIG. 37 (a), one end portion does not fall first and the posture is not disturbed, and the bill P can be moved and stored in the storage portion 154 in a stable posture. Subsequent transport by the feed transport unit 153 can also be smoothly performed.

FIG. 38 shows a case where the structure of FIG. 37 (b) is further improved. A sheet 155 made of a material having elasticity and frictional force against the bill P (for example, natural rubber) is attached to the upper surface of the two plates constituting the receiving plate 152a and the lower surface of the pressing plate 152b. Further, the inner (banknote passing side) ends of the two plates constituting the receiving plate 152a are bent downward to form an inverted L shape, and an elastic and frictional material (sheet 155) is placed on the bill passing side. It is designed to protrude. The strength of the receiving plate 152a is increased by bending it into an inverted L shape.

Further, when the material having frictional force (sheet 155) is elastic such as natural rubber, when the pressing plate 152b descends from the receiving plate 152a and pushes the bill P downward, the sheet 155 is placed on the bill passing side. Since the protruding portion is slightly curved downward, the bill P falls more smoothly while receiving friction from the sheet 155. Further, the presence of the elastic sheet 155 provided on the upper surface of the receiving plate 152a and the lower surface of the pressing plate 152b prevents the bill P from being damaged or damaged. Also in the improved type shown in FIG. 38, one end of the bill P does not fall first and the posture is disturbed, and the bill P can be moved and stored in the storage portion 154 in a stable posture. Subsequent transport by the feed transport unit 153 can also be smoothly performed.

In the island banknote transport device 8, as shown in FIG. 31, the transport pipe 140 piped along the longitudinal direction of the island is extended straight as it is and connected to the relay box 6, so that the relay box 6 is connected to the relay box 6. The space to be secured at the island edge for installing the relay box 6 can be reduced as compared with the case where the relay box 6 is bent 90 degrees via a curved pipe immediately before the connection.

However, as shown in FIG. 2, in the configuration in which the return transport pipe 12b passes above the plurality of relay boxes 6, as shown in FIG. 24, the direction of the bill P when reaching the import device 14 is set to the bill P. It is necessary that the paper surface of the return path transport pipe 12b faces the extension direction Fw of the return path transfer pipe 12b. Therefore, it is necessary to change the longitudinal direction of the bill P flowing into the relay box 6 from the transport pipe 140 of the island bill transport device 8 by 90 degrees. Since it is difficult to perform such a direction change in the relay box 6 in terms of space, as shown in FIG. 23, a twisted portion 51 is provided in the middle of the sub-conveying pipe 101 of the sub-conveying device 13.

Since the transport pipe 140 in the gaming machine island 3 is directly connected to the relay box 6, a transport error is less likely to occur and the quality of transport can be improved as compared with the case where the transport pipe 140 is bent 90 degrees in front of the relay box 6. Further, as shown in FIGS. 1 and 23, since the door of the relay box 6 faces the front (the direction in which the island edge faces), the work of opening the door and maintaining and inspecting the inside of the relay box 6 becomes easy.

In the present embodiment, the relay box 6 is not provided with a bill determination device for inspecting the authenticity of the bill P or detecting the denomination. Therefore, as shown in FIG. 34, the transport path of the pay-out transport unit 153 that transports the bill P from the storage portion 154 of the temporary storage device 150 to the bill take-in portion 103 of the sub-conveyor device 13 can be shortened.

Since the paper leaf collection and transport system 10 is provided with the relay box 6 on the gaming machine island 3 as described above, the island bill transporting device 8 and the paper leaf collection and transporting device 8 for collecting and transporting the bill P in the gaming machine island 3 and the paper leaf collection and transporting system 10 While configuring the transport system 10 as a separate device, the bills P collected in the gaming machine island 3 can be automatically transported to the collective safe 11 in the office. That is, since the relay box 6 converts the posture of the bill P from the standing posture to the lying posture, the bill P received from the island bill transporting device 8 that conveys the bill P in the standing posture is laid down. It can be smoothly sent to the sub-transport device 13 that conveys P. Further, since the temporary storage device 150 has a function of temporarily storing and storing the bill P, the bill P is sent out to the sub-transport device 13 at the timing when the bill P is transported by the island bill transport device 8. It is possible to absorb the deviation from the desired timing.

In addition, if there is a risk that the transport route from the relay box 6 to the office safe 11 is abnormal due to a malfunction of the office safe 11 or a disaster such as an earthquake, the use of the safe 11 is stopped and relayed. By switching the box 6 to the independent operation mode, it can also be used as a conventional safe for the island alone.

Next, the connecting portion 15 inserted in the middle of the transport pipe 12 will be described. As shown in FIG. 2, the main transport pipe 12 of the paper leaf collection and transport system 10 is configured by connecting a plurality of transport pipes with a connecting portion 15. Unlike the island banknote transport device 8, the transport pipe 12 of the paper leaf collection and transport system 10 is extended over a very long distance, so that the expansion and contraction of the transport pipe 12 due to a temperature change cannot be ignored in construction. When the transport pipe 12 contracts, a large gap is generated at the connection point, and when it expands, the transport pipes 12 may collide with each other at the connection point and a large stress may be applied to refract. Such gaps and refractions hinder the smooth movement of the bill P and the transport auxiliary body 16 and cause clogging.

Therefore, even if the length of the transport pipe 12 changes due to a temperature change or the like, the change in the length of the transport pipe 12 is combined with the connecting portion 15 so that the entire installation state is not distorted or a large gap is not generated. Absorb with.

FIG. 39 is a diagram showing the connection between the connecting portion 15 and the transport pipes 12 before and after the connecting portion 15 by breaking the connection. The connecting portion 15 includes a connecting main body portion 160 and a connecting adapter 170. In the figure, the transport direction of the bill P (the direction in which the air flow flows) is indicated by the arrow Fw. Further, the connecting main body 160 shows a state in which one side wall is removed.

FIG. 40 is a view showing the front surface, the left side surface, the right side surface, the upper surface, and the lower surface in a state where the transfer pipe 12 is connected to the connecting portion 15, and FIG. 41 is a view showing the front surface, the left side surface, the right side surface, and the upper surface of the connection adapter 170. , It is a figure which shows the lower surface.

The downstream end 172 of the connection adapter 170 is inserted into the upstream connection port 161 of the connection main body 160, and the upstream transfer pipe 12 is connected to the upstream connection port 171 of the connection adapter 170. A transport pipe 12 on the downstream side is connected to the connection port 162 on the downstream side of the connection main body 160.

The inner shape of the upstream connection port 171 of the connection adapter 170 has a shape corresponding to the outer shape of the transport pipe 12. Further, the inner shape of the downstream connection port 162 of the connecting main body 160 has a shape corresponding to the outer shape of the transport pipe 12. The transport pipe 12 is inserted into the upstream connection port 171 of the connection adapter 170 and the downstream connection port 162 of the connection main body 160, respectively, with a thin packing (not shown) made of an elastic material such as rubber covering the outer circumference. It is connected tightly.

The downstream end 172 of the connection adapter 170 has substantially the same inner and outer shapes as the transport pipe 12, and the inner shape of the upstream connection port 161 of the connection main body 160 is the downstream end of the connection adapter 170. It has a shape corresponding to the outer shape of the portion 172. The downstream end 172 of the connection adapter 170 is also inserted inside the upstream connection port 161 of the connection main body 160 with the same packing as above, and is airtightly connected.

The downstream side transport pipe 12 is connected and fixed with the upstream end abutted against the abutting portion 162b provided inside the downstream side connecting port 162 of the connecting main body portion 160. For example, it is glued. The upstream side transfer pipe 12 is inserted and connected until it hits the back of the upstream side connection port 171 of the connection adapter 170. Inside the downstream end 172 of the connection adapter 170, ribs 173 and 174 similar to the ribs 34 and 35 formed inside the transfer pipe 12 are formed, and the ribs 173 and 174 are the connection adapter 170. It extends further downstream from the downstream end 172 and protrudes.

Ribs 163 and 164 are also provided inside the connecting main body 160 like the ribs 34 and 35 of the transport pipe 12, and when the connecting adapter 170 is connected to the connecting main body 160, the ribs 173 and 174 of the connecting adapter 170 are provided. And the ribs 163 and 164 of the connecting main body 160 are continuous.

FIG. 42 shows how the downstream end portion 172 of the connection adapter 170 is connected to the upstream side connection port 161 of the connection main body portion 160. When the downstream end 172 of the connection adapter 170 is inserted into the upstream connection port 161 of the connection main body 160, the ribs 173 and 174 of the connection adapter 170 and the rib 163 of the connection main body 160 are shown in FIG. 164 overlaps and continues. FIG. 3C shows a state in which the connection adapter 170 is inserted into the downstream connection port 162 of the connection main body 160 to the deepest point where it abuts.

At the time of construction, as shown in FIG. 3B, the connection is made in a state about 10 mm in front of the innermost part. As a result, when the length changes due to the contraction and expansion of the transport pipe 12, the change in the length can be absorbed by the connecting portion between the connecting main body portion 160 and the connecting adapter 170. The position 20 mm before the innermost part is the shallowest connected state, and the connecting portion 15 can absorb the change in length due to contraction and expansion by ± 10 mm with respect to the time of construction. The ribs 163 and 164 on the connecting main body 160 side and the ribs 173 and 174 on the connecting adapter 170 side exceed a predetermined length (for example, 5 mm) even when the connecting adapter 170 is connected to the connecting main body 160 at the shallowest distance. Wrap.

FIG. 43 is an enlarged view showing the connection state between the ribs 173 and 174 on the connection adapter 170 side and the ribs 163 and 164 on the connection main body 160 side. The central rib 163 on the connecting main body 160 side is divided into two parallel ribs 163a and 163b, and the central rib 173 on the connecting adapter 170 side is inserted between them. The distance between the two ribs 163a and 164b constituting the rib 163 coincides with the thickness of the rib 173, and the rib 173 is inserted between the two ribs 163a and 163b without a gap. In this way, by inserting the rib 173 on the connection adapter 170 side between the two ribs 163a and 163b on the connection main body 160 side, the downstream side of the connection adapter 170 is inserted into the upstream connection port 161 of the connection main body 160. Even if the connection depth when the end portion 172 is connected changes significantly due to contraction and expansion, the rib 163 on the connection body 160 side and the rib 173 on the connection adapter 170 side can be connected without shifting their positional relationship. Can be done.

The rib 164 of the connecting main body and the rib 174 on the connecting adapter 170 side overlap each other so that one side surface of the rib 164 is in contact with each other. Here, the rib 164 comes into contact with the inside in a positional relationship with the rib 174 on the outside. By allowing the outer rib 174 to slightly press the inner rib 164 inward, they are in close contact and smoothly connected.

As described above, in the connecting portion 15 of the present embodiment, the rib 173 is fitted between the two ribs 163a and 163b, instead of simply facing the rib on the connecting main body 160 side and the rib on the connecting adapter 170 side. The structure is such that they are combined, and the length of the ribs to be fitted is also set to a length that can absorb fluctuations due to contraction and expansion. As a result, even if there is a temperature change in the installation environment, the contraction and expansion of the transport path due to the temperature change can be absorbed by the connecting portion 15, and a gap may be created at the connection point of the transport pipe or the pipe may be bent due to stress. It is possible to prevent inconveniences such as Further, since the ribs are fitted and connected, the ribs are not displaced or stepped at the connection point, and the transport assisting body 16 and the bill P can be smoothly passed.

As shown in FIG. 42, the connecting main body 160 of the connecting portion 15 is provided with a sensor 166 (optical sensor) for detecting the passage or catching of the bill P or the transport assisting body 16. The clogging of the bill P and the catching of the transport assisting body 16 are liable to occur at the connecting portion.

(About auxiliary blower)
In the return route transport pipe 12b in which the transport auxiliary body 16 moves while transporting the bill P, the load is larger than that in the outward transport pipe 12a in which the bill P is not pushed, and the moving speed of the transport auxiliary body 16 tends to decrease. Therefore, an auxiliary blower is provided to strengthen the air flow.

In particular, as the size of the game hall 2 becomes larger, the transport pipe 12 of the paper leaf collection and transport system 10 needs to go around a large number of game machine islands 3, and further, it is laid across a plurality of floors. Therefore, the portion where the transport pipe 12 is curved increases. In the curved portion, the resistance becomes large, the progress of the transport assisting body 16 becomes poor, and the flow of the air flow is likely to be obstructed. In addition, the curved portion is connected to the straight portion before and after the curved portion. Air leaks can occur at the connection points.

Therefore, an auxiliary blower for increasing the air volume is installed at a position where the transport pipe 12 is curved. For example, just upstream of the curve (immediately before reaching the curve), an auxiliary blower is provided to increase the air flow toward the downstream. Alternatively, an auxiliary blower heading downstream may be provided immediately downstream of the curve.

Further, an auxiliary blower may be provided downstream of the most downstream intake device 14. That is, the transport auxiliary body 16 collects the bill P around the installation location of the relay box 6 of each game machine island 3 in the game hall, and then moves to the collection safe 11 while transporting the bill P. When the collective safe 11 is installed on a floor different from that of the pachinko / pachislot machine island 3, the transport pipe 12 from the last take-in device 14 to the collective safe 11 may be a long distance.

In such a case, it is difficult to obtain an air volume sufficient to ensure that the transport auxiliary body 16 reaches the collective safe 11 only by blowing air from the transport auxiliary body relay device 17. Therefore, an auxiliary blower is provided downstream of the most downstream intake device 14 to increase the air volume. In addition, auxiliary blowers are provided at appropriate positions in the middle of the transport path, if necessary.

Even if the air volume is increased by the auxiliary blower, distortion may occur at the connection points at both ends of the curved portion as described above, and the posture may be changed at the connecting points of the transport pipes where the transport auxiliary body 16 curves. Since it is broken, it may get caught. Therefore, a release wind blower that generates an air flow (release wind) from the downstream to the upstream is provided downstream of the portion where the transport assist body 16 is easily caught, and the transport assist body 16 reaches the location where the release wind blower is installed. When the air is not reached, the release air blower is operated to send the release air for a predetermined time (for example, 10 seconds) to release the catch of the transport auxiliary body 16. An obstacle in which the transport assisting body 16 does not reach a predetermined location is regarded as a transport assisting body transport error.

For example, a release wind blower that generates an air flow (release wind) from the downstream to the upstream is provided immediately upstream of the curve or in the middle of the curve, and when the transport auxiliary body 16 does not reach the downstream side of the curve, the release is performed. The wind blower is operated to send the release wind to release the catch of the transport auxiliary body 16.

While the release wind is sent, the air flow in the normal direction is stopped. When the feeding of the release wind is completed, the air flow in the normal direction is generated again, and the transport auxiliary body 16 is moved to transport the bill P. As a result, the catch of the transport assisting body 16 can be released, and the bill P can be stably transported by the transport assisting body 16.

The place where the release wind blower is provided is not limited to the upstream or the middle of the curve, and the catch of the transfer auxiliary body 16 may be released. Therefore, the air outlet of the release wind blower is located near the transfer auxiliary body 16. All you need is. That is, a release wind blower is provided at an appropriate position on the transport path, particularly downstream of a place where the transport assist body 16 is easily caught, or when there are several places where the transport assist body 16 is easily caught, the most downstream of them. A release wind blower may be provided immediately downstream of the location. Further, the wind direction of the release wind is not limited to the direction in which the wind flows from the downstream to the upstream, and if the wind direction in the transport pipe is changed, the catching is released, so the wind direction is not limited to one direction.

FIG. 44 shows an example in which the release wind blower 19 is added to the system shown in FIG. The release wind blower 19 blows air from a position downstream of the most downstream intake device 14 (a position before reaching the curved portion) toward the upstream (send the release air). The auxiliary blower 18 blows air from a position downstream of the most downstream intake device 14 (a position immediately after passing through the curved portion) toward the downstream to enhance the forward air flow.

(Auxiliary blower activation setting)
The auxiliary blower is operated for a predetermined time based on the time when a sensor (see FIG. 44) provided slightly downstream of the installation location detects the passage of the transport auxiliary body 16. Normally, the bill P is pushed and moved by the transport auxiliary body 16, but the bill P may self-propell even if it is not pushed by the transport auxiliary body 16 due to the action of the air flow. When the above sensor detects the self-propelled banknote P, it erroneously detects that the transport assisting body 16 has passed even though the transport assisting body 16 has not arrived. At this time, the transport auxiliary body 16 is still upstream of the bill P in the transport direction.

When the auxiliary blower is turned on, an air flow retention phenomenon occurs around the air outlet of the auxiliary blower, and a headwind toward the upstream may occur on the downstream side of the auxiliary blower. Therefore, when the auxiliary blower is operated at the timing when the self-propelled banknote P is detected by the above sensor, the movement of the transport auxiliary body 16 upstream from the sensor is hindered by the retention phenomenon of the air flow and the generation of the headwind. Transport auxiliary body Transport error may occur.

Therefore, the following measures were introduced.
1. 1. After the transport auxiliary body 16 is sent out, the scheduled passage time required for the transport auxiliary body 16 to pass through the location of the sensor, which is the reference for the operation timing of the auxiliary blower, is set, and after the transport auxiliary body 16 is sent out. Until the scheduled passage time elapses, control is performed so that the auxiliary blower is not turned on even if the sensor detects the passage of an object. That is, if the sensor is turned on before the scheduled passage time has elapsed, the auxiliary blower is turned on after the scheduled passage time has elapsed. When the sensor is turned on after the scheduled passage time has elapsed, the auxiliary blower is immediately turned on.

2. A test run in which the transport auxiliary body 16 is moved by itself without transporting the bill P is performed three times in a row, and the time from when the transport auxiliary body 16 is sent out until the sensor detects the transport auxiliary body 16 is automatically measured. If the time difference between the three times is within 2 seconds, the latest measurement time is set as the scheduled passage time.

3. 3. The scheduled passage time can be changed by operating the control device (DIP-SW, push button, etc.).

By the above measures, the auxiliary blower is not turned on by the sensor detecting the self-propelled bill P before the transport auxiliary body 16 reaches the installation location of the auxiliary blower, and the transport auxiliary body based on the factor is prevented. Transport errors are prevented.

(Automatic setting of auxiliary body orbit reference time)
In the paper leaf collection and transportation system 10, the auxiliary body orbiting reference time until the transportation auxiliary body 16 sent out from the collecting safe 11 goes around the conveying pipe 12 and returns to the collecting safe 11 is set, and the auxiliary body orbiting reference time is set. Based on the time, the presence or absence of the transport auxiliary transport error is determined. The auxiliary body orbit reference time may be set by the worker manually measuring the time when the transfer auxiliary body 16 actually goes around the transfer pipe 12 using a stopwatch or the like, but it is automatically set. If it can be measured and set, it will save time and convenience.

Therefore, the paper leaf collection and transport system 10 automatically performs a test lap running in which the transport auxiliary body 16 laps the transport pipe 12 by itself without transporting the bill P, and automatically performs the lap time a plurality of times. It has a function to automatically set the auxiliary body orbit reference time after measuring and considering the equipment configuration. The auxiliary body orbit reference time can be manually changed. By providing an automatic setting function for the auxiliary body orbit reference time, the time and effort for initial setting can be reduced, and human error at the time of input setting can be avoided.

(About the control of the auxiliary blower)
If the configuration of the transport route is complicated (many curves, etc.) or there is a very long distance to the safe 11, it becomes necessary to install a plurality of auxiliary blowers 18 at appropriate positions on the transport route. A plurality of control methods for controlling one or a plurality of auxiliary blowers 18 are shown below. In either control method, each auxiliary blower 18 is controlled so as to be activated at the timing when the transport auxiliary body 16 has passed.

<Independent control>
In the independent control, as explained in the section of "Auxiliary blower activation setting", when the sensor detects the passage of the transport auxiliary body 16 provided slightly downstream of the auxiliary blower 18, the operation is determined by the passage time. , The auxiliary blower 18 is activated and operated for a predetermined time. Even if a plurality of auxiliary blowers 18 are installed, each auxiliary blower 18 determines the operation individually. In the case of independent control, if there is a place where the air volume is insufficient in the middle of the transport path, it can be dealt with by simply adding an auxiliary blower 18 for independent control near the upstream of that place, so measures to increase the air volume can be taken as necessary. It can be done easily.

<Management control>
In the management control, the control unit (control unit 27 of the collective safe 11) that controls the overall operation of the paper leaf collection and transport system 10 collectively manages the operation timing of the auxiliary blower 18. In the management control, the timing (elapsed time after delivery) at which the transfer assist body 16 passes through each point of the transfer path is investigated and grasped in advance. The passing point is, for example, a place where a sensor 166 (see FIG. 42) provided in the connecting portion 15 is installed, and the passing is detected by this sensor to check the passing timing at each point.

From the passing timing of each point examined in this way, the activation timing at which each auxiliary blower 18 should be operated is set in advance. The control unit 27 measures the elapsed time from the time when the transport auxiliary body 16 is sent out to the transport pipe 12, and transmits an operation instruction to each auxiliary blower when the start timing of the auxiliary blower is reached. Upon receiving this operation instruction, the auxiliary blower 18 operates the fan for a predetermined time to stop it.

As a result, when a plurality of auxiliary blowers 18 are installed, the auxiliary blowers 18 operate one after another for a predetermined time and then stop in order from the one installed upstream.

In the management control, it is not necessary to provide a determination unit for determining the activation timing on the auxiliary blower 18 side, and the configuration is simplified. Further, even if a defect or abnormality occurs in the sensor that detects the passage of the transport auxiliary body while the system is moving, each auxiliary blower 18 can be operated at a predetermined timing, and more reliable paper leaf collection can be performed. The transport system 10 can be provided.

As another method of control, the activation timing of each auxiliary blower 18 examined as described above is set in each auxiliary blower 18, and the control unit 27 sends out the transport auxiliary body 16 to that effect. Is notified to each auxiliary blower 18, the elapsed time from each auxiliary blower 18 receiving the notification is timed, and the fan is autonomously started when the start timing set in the own device is reached. You may. In this configuration, each auxiliary blower 18 needs a circuit that measures the elapsed time and determines whether or not the start timing has arrived, but even if a defect or abnormality occurs in the passage sensor, each auxiliary blower 18 is predetermined. It can be operated at the timing.

Next, the structure of the twisted portion 51 will be described.

As shown in FIG. 45, the twisted portion 51 connects a plurality of short sub-twisted pipes 51a twisted little by little to realize twisting at a desired angle. In this example, 10 sub-twisted pipes 51a are connected to form a 90-degree twist, and a connecting portion 51b with the transport pipe 12 is connected to the downstream end thereof. There is no twist in the connection portion 51b.

Next, the operation sequence when the paper leaf collection / transport system 10 collects the bill P from the relay box 6 of each gaming machine island 3 will be described.

FIG. 46 is a diagram showing the above sequence. The control unit 27 of the collective safe 11 inquires at the relay box 6 of each game machine island 3 and confirms the number of bills P stored in the bill storage unit 25 of each relay box 6 (P1, P2).

Next, based on the number of banknotes P stored in the banknote storage section 25 of each relay box 6, it is determined how many banknotes P are to be collected from the banknote storage section 25 of which relay box 6 (P3). , A bill ejection instruction specifying the number of ejected sheets is transmitted to one or a plurality of relay boxes 6 determined as collection destinations (P4).

The relay box 6 that has received the bill discharge instruction discharges the instructed number of bills P from the bill storage unit 25, and the auxiliary transport device 13 installed in the relay box 6 ejects the designated number of bills P from the return transport pipe 12b. The bill P is conveyed to 14 (P5). When the take-in device 14 takes in the banknote P inside, a signal indicating that the banknote P has been discharged into the return transport pipe 12b is transmitted from the take-in device 14 to the control unit 27 of the collection safe 11. (P6).

When the control unit 27 of the collection safe 11 confirms that the bill P instructed by the bill discharge instruction has been taken into the transport pipe 12 (return transport pipe 12b) by the take-in device 14, the own device and the transport auxiliary relay The device 17 is instructed to start the blowing / sucking operation and to send out the transport assisting body 16 (P7).

The control unit 27 of the collecting safe 11 moves the air flow generator 21 to blow air to the start end of the outward transport pipe 12a, suck the air flow from the end of the return transport pipe 12b, and insert the transport auxiliary body. The transport auxiliary body 16 is delivered to the outward transport pipe 12a by the device 23 (P8, P9). At the same time, the transport auxiliary body relay device 17 operates the fan 63 of the blower portion 62 to suck the air flow from the end of the outward transport pipe 12a and from the start end side of the return transport pipe 12b into the return transport pipe 12b. In addition to blowing air to the return path transport pipe 12b, the transport auxiliary body 16 is sent out (P10, P11). That is, the transport auxiliary body 16 is sent out from the collective safe 11 to the outward transport pipe 12a and the transport auxiliary body 16 is sent out from the transport auxiliary body relay device 17 to the return route transport pipe 12b at the same time.

A sensor provided in the middle of the outward transport pipe 12a and the return transport pipe 12b detects the passage of the transport auxiliary body 16 (P12, P13). When the transport assist body 16 sent out from the collection safe 11 on P8 reaches the inflow side connection port 67 of the own device, the transport assist body relay device 17 receives and holds the transport assist body 16 by the holding unit 74 (P14). Then, the control unit 27 of the collective safe 11 is notified that the transport assist body 16 has been received and held (P15).

When the transport auxiliary body 16 sent from the transport auxiliary body relay device 17 to the return route transport pipe 12b on P11 reaches its own device, the collecting safe 11 separates the bill P and the transport auxiliary body 16 by the separation / collection device 24. The bill P is collected in the bill storage unit 25, and the transport assist body 16 is moved to the transport assist body insertion device 23 for the next delivery (P16).

Then, the control unit 27 of the collective safe 11 instructs its own device and the transport auxiliary relay device 17 to stop the blowing / sucking operation (P17). In response to this instruction, the fan 63 of the blower portion 62 of the air flow generator 21 of the collective safe 11 and the transport auxiliary relay device 17 is stopped (P18 to P20).

Further, the transport auxiliary body relay device 17 that receives this instruction rotates the rotating plate 72 by 180 degrees (P21). When this rotation is completed, the lock (holding) of the transport assisting body 16 by the holding roller 82 of the holding portion 74 that has moved to the outflow side connection port 68 is automatically released (P22).

The above operation is repeated for each collection operation of the bill P.

Next, the operation in which the control unit 27 of the collection safe 11 determines how many banknotes P are to be collected from which relay box 6 in P3 of the above-mentioned collection operation will be described.

The paper leaf collection and transportation system 10 can collect up to six banknotes P for each operation of collecting the banknotes P by the transport auxiliary body 16. Further, it is assumed that the number of banknotes P that the sub-transport device 13 conveys to the import device 14 at one time is restricted to 3 or less.

The control unit 27 of the collection safe 11 keeps the total number of banknotes P to be collected in the collection operation within the maximum number of banknotes P that can be collected in one collection operation (6 in this example) for each collection operation of the banknotes P. In this way, the number of banknotes P to be collected from each of the one or two or more relay boxes 6 to be collected is determined. Here, the number of bills P to be ejected from one relay box 6 is further limited to a predetermined upper limit or less. The maximum number of sheets is set to 3, and the maximum number of sheets is changed according to the number of stock sheets.

That is, the control unit 27 of the collection safe 11 does not exceed the set upper limit number (for example, 3) for each collection operation, and the total number of bills P to be collected. Allocate the number of ejected sheets to one or more relay boxes 6 so as not to exceed the maximum number of six sheets that can be collected.

In the control unit 27 that controls the entire operation of the paper leaf collection and transport system 10, the number of banknotes P (stock number) stored in the control unit 27 is set so that the temporary storage device 150 of each relay box 6 is not full during business hours. The number of discharges at the collection destination and each collection destination is determined so that the larger the number of relay boxes 6 is, the more priority is given to the discharge.

The control unit 27 classifies the number of stocks of banknotes P in each relay box 6 into a plurality of levels, and manages the relay boxes 6 by grouping them according to the level. Since each relay box 6 can store about 500 bills P, it is divided into 7 levels (G1 to G7) and managed as shown in FIG. 47. FIG. 47 shows the relationship between the groups (G1 to G7), the number of stocks, and the priority of collection.

In this example, G1 is a group with 1 stock, G2 is a group with 2 stocks, G3 is a group with 3-9 stocks, G4 is a group with 10-49 stocks, and G5 is a group with 10-49 stocks. The G6 is a group with 50 to 149 stocks, the G6 is a group with 150 to 254 stocks, and the G7 is a group with 255 or more stocks.

G7 has the highest priority for collection, G6, G5, G4, G3, and G2 have the lowest priority, and G1 has the lowest priority for collection.

G1 and G2 are provided so that the number of sheets less than the maximum number (3 sheets) that can be instructed to be discharged to one relay box 6 is grouped according to the number of stocks. If G1 and G2 are not provided and G3 is set as the group with the smallest number of stocks, even if the relay box 6 belonging to G3 is instructed to discharge three pieces, the actual number of stocks is two or one. In that case, only the number of stocks will be discharged. In order to prevent such a situation, G1 and G2 are provided so that the same number of bills P as the number of bills to be ejected instructed by the control unit 27 are ejected from the relay box 6.

For example, when there are four relay boxes 6 of G1 (the number of stocks is one) and one relay box 6 of G2 (the number of stocks is two), the banknotes P are in the four relay boxes 6 belonging to G1. It is possible to control such that instructing the one relay box 6 belonging to G2 to eject two bills P one by one, and instructing one relay box 6 belonging to G2 to eject two bills P.

Further, even when the number of stocks is large, since a plurality of groups (G4 to G7) are set according to the number of stocks, the discharge from the relay box 6 having a large number of stocks can be preferentially performed. Specifically, since G4 to G7 are provided, it is possible to finely control the discharge as compared with the case where all 10 or more sheets are classified into one group.

The control unit 27 determines the number of banknotes P and the collection destination so that the relay box 6 having a larger number of stocks is preferentially collected.

Further, the control unit 27 classifies the relay boxes 6 into a plurality of groups based on the number of stocks, and limits the number of discharges allocated to one relay box 6 within a predetermined upper limit in order from the group with the largest number of stocks. Then, the number of sheets to be discharged and the collection destination are determined by allocating the number of sheets to be discharged to the relay boxes 6 belonging to the same group as evenly as possible.

For example, if there are six or more relay boxes 6 belonging to the G7, the number of ejected sheets is assigned to each of the six relay boxes 6 among them. If there is only one relay box 6 belonging to the G7 and there are two relay boxes 6 belonging to the G6, three relay boxes 6 belonging to the G7 are assigned to the one relay box 6 belonging to the G7, and one of the relay boxes 6 belonging to the G6 is assigned. Two cards will be assigned to the table, and one card will be assigned to the other one.

Further, the upper limit number of sheets set in the group in which the number of stocks is less than the predetermined number (the upper limit number of the number of ejected sheets allocated to one relay box 6) is made smaller than the upper limit number of sheets set in the group in which the number of stocks is the predetermined number or more. In this example, the maximum number of sheets is 3 for G4 and above, and 2 for G3 and below.

If the total number of sheets does not reach 6 as a result of allocating the number of ejected sheets with the maximum number of sheets limited to 2, the maximum number of sheets may be changed to 3. In addition, even if the work of allocating the number of discharged sheets in order from the group with the largest number of stocks is performed and the total number of discharged sheets does not reach the maximum number of sheets (6 sheets) that can be collected in one collection operation even after going around all the groups. , The remaining number of sheets to be ejected may be allocated in order from the relay box 6 belonging to the group having the largest number of stocks. For example, if there are only G3 or less, even if the maximum number of sheets is set to 2 and the number of ejected sheets is assigned to these, if the total number of sheets does not reach 6, the maximum number of sheets for G3 is changed to 3 and the maximum number of sheets is changed from G3. It performs operations such as allocating the remaining number of sheets.

Specific examples of the method of determining the collection destination and the number of sheets to be discharged will be described below.

Depending on what kind of groups (G1 to G7) exist in the entire system, control is performed by dividing into the following three patterns.

<Pattern 1>
When there is a relay box 6 corresponding to G4 or higher In this case, the relay box 6 having a higher priority is preferentially discharged.

The specific procedure is as follows: ・ Allocate the number of discharged sheets in order from the group with the highest priority.

-The upper limit of the number of ejected sheets to be assigned to one relay box 6 is 3, and the number of ejected sheets is made as even as possible, and allotted to the same group until the total number of ejected sheets becomes 6.

-If the total number of ejected sheets does not reach 6 even if all the relay boxes 6 belonging to the group are assigned the number of ejected sheets, the number of ejected sheets is assigned to the group having the next highest priority.

In the example shown in FIG. 48 (a), since there are seven relay boxes 6 belonging to G7, one is evenly assigned to each of the six relay boxes (IDs 1 to 6). In the example shown in FIG. 3B, since there are five relay boxes 6 belonging to G7 (IDs 1 to 5), two relay boxes 6 are assigned to the relay box 6 of ID1 as the number of ejected sheets, and the other relay boxes 6 (IDs 2 to 5) are assigned. ) Are assigned one as the number of ejected sheets. For example, the first sheet is sequentially assigned to each relay box 6 belonging to G7, and if the number of sheets is less than six even after one round, the second sheet is sequentially assigned to the relay box 6 belonging to G7 as the second round. Just do.

In the example shown in FIG. 6C, since there are three relay boxes 6 belonging to the G7 (IDs 1 to 3), two are assigned as the number of discharges to each. In the example shown in FIG. 3D, as the first-stage allocation work, since there is only one relay box 6 belonging to the G7 (ID1), the maximum number of relay boxes 6 is allocated to the relay box 6. Then, as the second-stage allocation work, the remaining number of sheets is allocated to the group having the next highest priority. In this example, since there is only one relay box 6 (ID2) belonging to the G6 having the next highest priority, the relay box 6 (ID2) is assigned the upper limit of three as the number of ejected sheets.

<Pattern 2>
When all the relay boxes 6 are G3 or less and there is a relay box 6 belonging to G3 [a] When the number of G3s is only one In this case, the number of discharges indicated to the relay box 6 of G3 is two ( (Maximum number of sheets), and by allocating the remaining 4 sheets to G2 or less, the number of relay boxes 6 of G2 or less is reduced.

The specific procedure is as follows: -Assigning 2 sheets (upper limit number) to one relay box 6 belonging to G3, and allocating the remaining 4 sheets to the relay box 6 belonging to G2 or less.

-If there is a relay box 6 belonging to G2, 2 sheets (upper limit number) are assigned to each relay box 6 belonging to G2 as the number of discharged sheets.

-If the total number of sheets does not reach 6, the rest is allocated to each relay box 6 belonging to G1 one by one.

・ If the total number of cards does not reach 6, increase the number of relay boxes that belong to G3 to 3 (raise the maximum number from 2 to 3).

-If the total number of sheets still does not reach 6, the allocation process is terminated.

In the example shown in FIG. 49A, as the first-stage allocation work, two relay boxes 6 (ID1) belonging to G3 are allocated as the number of ejected sheets (upper limit number of sheets). As the second stage allocation work, since there are two relay boxes 6 (ID2, 3) belonging to G2, two are allocated as the number of ejected sheets to each. Now that the total number of sheets reaches 6, the allocation process ends.

In FIG. 3B, as the first-stage allocation work, two relay boxes 6 (ID1) belonging to G3 are allocated as the number of ejected sheets (upper limit number of sheets). Next, as the second-stage allocation work, since there is only one relay box 6 belonging to G2 (ID2), two (upper limit) are allocated as the number of ejected sheets. Since the total number of sheets is still four at this stage, one is further allocated to each of the relay boxes 6 (ID3, 4) belonging to G1 as the number of ejected sheets as the third stage allocation work. Since the total number of sheets reaches 6, the allocation process is completed.

In the case of FIG. 3C, as the first-stage allocation work, two relay boxes 6 (ID1) belonging to G3 are assigned as the number of ejected sheets (upper limit number), and as the second-stage allocation work, G2. Since there is only one relay box 6 (ID2) belonging to, two (upper limit) are assigned as the number of ejected sheets. Further, as the third stage allocation work, one is allocated as the number of ejected sheets to the relay box 6 (ID3) belonging to G1. Since the total number of sheets is 5 at this stage, as a residual process, the number of sheets discharged from the relay box 6 of ID1 belonging to G3 is increased by +1 to 3 sheets. Now that the total number of sheets reaches 6, the allocation process ends. That is, since the total number of sheets does not reach 6 even after going around each group, the upper limit number of G3 is increased to 3, and the remaining number of sheets is allocated again in order from the group with the largest number of stocks.

[B] When the number of G3s is two In this case, the number of ejected sheets instructed to the relay box 6 of each G3 is set to two (upper limit number), and the remaining two sheets are allocated to G2 or less to relay G2 or less. Reduce box 6.

The specific procedure is as follows: -Assign 2 sheets (upper limit number) to each of the 2 relay boxes 6 belonging to G3, and assign the remaining 2 sheets to the relay box 6 belonging to G2 or less.

-If there is a relay box 6 belonging to G2, 2 sheets (upper limit number) are assigned to the relay box 6 belonging to G2 as the number of discharged sheets.

-If the total number of sheets does not reach 6, the rest is allocated to each relay box 6 belonging to G1 one by one.

・ If the total number of cards does not reach 6, increase the number of relay boxes that belong to G3 to 3 (raise the maximum number from 2 to 3).

In the example shown in FIG. 50A, as the first-stage allocation work, two relay boxes 6 (IDs 1 and 2) belonging to G3 are allocated as the number of ejected sheets (upper limit number of sheets). As the second stage allocation work, there are two relay boxes 6 belonging to G2 (IDs 3 and 4), and two relay boxes (upper limit number) are allocated to one of them as the number of ejected sheets. Now that the total number of sheets reaches 6, the allocation process ends.

In FIG. 3B, as the first-stage allocation work, two relay boxes 6 (ID1) belonging to G3 are allocated as the number of ejected sheets (upper limit number of sheets). Next, as the second-stage allocation work, the work of allocating to the relay box 6 belonging to G2 is performed. However, in this example, since there is no relay box 6 belonging to G2, the assignment is not performed. Next, as the third-stage allocation work, allocation to the relay box 6 belonging to G1 is performed. Since there are four relay boxes 6 belonging to G1 (IDs 3 to 7), one is assigned as the number of ejected sheets to two of them (IDs 3 and 4). Since the total number of sheets reaches 6, the allocation process is completed.

In the figure (c), as the first-stage allocation work, two relay boxes 6 (ID1) belonging to G3 are allocated as the number of ejected sheets (upper limit number of sheets). Next, as the second-stage allocation work, the work of allocating to the relay box 6 belonging to G2 is performed. However, in this example, since there is no relay box 6 belonging to G2, the assignment is not performed. As the third-stage allocation work, the relay box 6 belonging to G1 is assigned. Since there is only one relay box 6 belonging to G1 (ID3), one is assigned to the relay box 6 (ID3) as the number of ejected sheets. Since the total number of sheets is 5 at this stage, as a residual process, the number of sheets discharged from the relay box 6 of ID1 belonging to G3 is increased by +1 to 3 sheets. Now that the total number of sheets reaches 6, the allocation process ends. In the residual processing, the maximum number of G3 sheets has been raised from two to three.

[C] When the number of G3s is 3 or more The number of discharges is assigned only to the relay box 6 of G3, and the discharge from the relay box 6 of G3 is prioritized.

The specific procedure is as follows: -Assign the number of ejected sheets one by one to the relay box 6 belonging to G3.

-If the total number of ejected sheets does not reach 6 in the above, allocate one by one again in descending order of the number of stocks.

In the example shown in FIG. 51 (a), since there are seven relay boxes 6 (IDs 1 to 7) belonging to G3, one is assigned to each of the six relay boxes 6 as the number of ejected boxes. In the example shown in FIG. 3B, since there are four relay boxes 6 (IDs 1 to 4) belonging to G3, one is assigned to each of them. Since the total number of sheets is 4 and does not reach 6, the relay boxes 6 belonging to G3 are assigned one by one until the total number of sheets reaches 6. In this example, the second piece is assigned to the relay box 6 of ID1 and ID2.

In the allocation in the above pattern 2, the maximum number of sheets that can be assigned to one relay box 6 belonging to G3 is set to 2, which is less than the maximum number of sheets that can be assigned to the relay box 6 belonging to the group of G4 or higher. It is done. As a result, the banknotes P are collected by dispersing them in more relay boxes 6.

<Pattern 3> When all the relay boxes 6 are G2 or less In this case, one (upper limit) is assigned to each relay box 6 in descending order of the number of stocks.

In the example shown in FIG. 52 (a), since there are two relay boxes 6 belonging to G2 (ID1 and 2) and five relay boxes 6 belonging to G1 (ID3 to 7), they belong to G2 having a large number of stocks. The relay boxes 6 (IDs 1 and 2) are preferentially assigned one by one, and then four of the relay boxes 6 belonging to G1 (IDs 3 to 6) are assigned one by one.

In the example shown in FIG. 3B, since there are two relay boxes 6 belonging to G2 (ID1 and 2) and three relay boxes 6 belonging to G1 (ID3 to 5), they belong to G2 having a large number of stocks. The relay boxes 6 (IDs 1 and 2) are preferentially assigned one by one, and then the three relay boxes 6 (IDs 3 to 5) belonging to G1 are assigned one by one. Since the total number of sheets at this stage is 5, which does not reach 6, the number of sheets discharged from the relay box 6 of ID1 belonging to G2 is increased by +1 as a residual process to make 2 sheets. Now that the total number of sheets reaches 6, the allocation process ends. This corresponds to raising the upper limit number of sheets for G2 from one to two and reallocating.

The above allocation method is an example, and is not limited to this.

In addition, regardless of the number of stocks, the administrator or the like can arbitrarily set and change the priority order for the relay box 6. For example, when the administrator switches the collection mode of the paper leaf collection and transportation system 10 to the special collection mode after the end of business hours, the control unit 27 displays the bill P as the relay box 6 having the higher priority set above. Determine the collection destination and the number of discharges to be instructed to each collection destination so that the collection is prioritized.

For example, during business hours, banknotes P continue to be inserted into the game ball lending machine 4 of the game machine island 3 where many popular models are installed, so the banknotes P are stocked in the relay box 6 of the game machine island 3. It is easy to do so, and the control during business that controls to preferentially collect the banknotes P from the relay box 6 having a large number of stocks may not eliminate the deviation of the stock amount of the banknotes P between the gaming machine islands 3. In addition, after the business is closed, it is often desired to quickly replace or maintain the gaming machine 5 for a specific gaming machine island 3. In order to meet such a demand, the banknote P can be collected according to an arbitrarily set priority by switching to the special collection mode after the business is closed.

Next, the error display provided in the paper leaf collection and transportation system 10 will be described.

FIG. 53 shows the front surface of the error display 180 included in the paper leaf collection and transportation system 10. The error display 180 has a function of displaying an error occurrence location in an easy-to-understand manner. The error display 180 displays the layout of the paper leaf collection and transportation system 10 installed in the amusement park 2. The display is customized according to each playground 2.

The error display 180 has a vertical portion transport path display unit 181 and a horizontal portion transport path display unit 182 as layout display units. The vertical section transport path display unit 181 simulates a transport path from the ceiling on the first floor to the collective safe 11 in the office on the fourth floor. The horizontal portion transport path display unit 182 displays the status of the transport path behind the ceiling on the first floor and the relay box 6 on the first floor.

Further, the error display 180 includes a message display unit 183, an up / down button 184, and an alarm button 185. When an error occurs, the message display unit 183 displays the content of the error. The up / down button 184 is used to select which error to display when a plurality of errors have occurred. The alarm button 185 lights up when an error occurs. When an error occurs, the income of the amusement park staff will be notified to that effect. When the alarm button 185 is pressed in the lit state, the error output to the intercom is stopped.

A symbol corresponding to the game machine island 3 and the transport pipe 12 is displayed on the vertical portion transport path display unit 181 and the horizontal portion transport path display unit 182 according to the layout of the game hall 2, and further, the relay box is superimposed on the symbol. Icons corresponding to the passage sensors installed in various places in the middle of 6 and the transfer pipe 12 are displayed. When the gaming machine island 3 is installed on a plurality of floors, it is possible to switch which floor state is displayed on the horizontal portion transport path display unit 182. When an error occurs, the status of the floor where the error occurred may be automatically displayed.

When an error occurs, the location where the error occurred flashes red. When an abnormality occurs in the auxiliary blower 18 and the transport auxiliary body relay device 17, only that part blinks in red. When the bill P or the transport auxiliary body 16 is clogged, as shown in FIG. 54, the section from the passage sensor that has detected the bill P or the transport auxiliary body 16 to the passage sensor of the unexamined land one downstream thereof. The part corresponding to the transport pipe flashes red.

In this way, the error display 180 displays the content of the error and the location where the error occurs in an easy-to-understand manner, so that the error can be dealt with quickly. A plurality of error display machines 180 may be provided at various locations in the amusement park 2.

As described above, the paper leaf collection and transportation system 10 according to the present embodiment collects banknotes P collected from each of the plurality of gaming machine islands 3 arranged in the gaming field 2 from each gaming machine island 3. Since the bills can be collected and transported to the office safe 11, the banknotes P can be safely and effortlessly collected from each gaming machine island 3 to the office safe 11.

Next, an improved version of the transport auxiliary relay device 19 will be described.

55 and 56 show the relay unit 61B of the improved transport auxiliary body relay device 19B. In the improved transport auxiliary body relay device 19B, when the transport auxiliary body 16 sent out from the collective safe 11 does not normally reach the transport auxiliary body relay device 19B, the second transport auxiliary body 16 is transferred from the collective safe 11. The following two points have been improved in order to deal with the problems that occur when the transport auxiliary body relay device 19B is sent out.

(Improvement 1)
With the first transport assisting body 16 received by the holding portion 74, a part of the second transport assisting body 16 is prevented from entering the holding portion 74.

FIG. 55 (a) shows the relay unit 61 of the transport auxiliary body relay device 19 before the improvement in the state where the two transport auxiliary bodies 16 arrive in succession, and FIG. 55 (b) shows the improved transport in the same state. The relay unit 61 of the auxiliary body relay device 19B is shown. In the transport auxiliary body relay device 19 before the improvement, since the position where the holding portion 74 holds the first transport auxiliary body 16 is a deep position of the holding portion 74, when the second transport auxiliary body 16 arrives in succession. , A part thereof enters the holding portion 74, and the second transport assisting body 16 stops at a position straddling both the inflow side connection port 67 (fixed side) and the holding portion 74 (rotating side). Therefore, if the rotary plate 72 is to be rotated in this state, the second transport auxiliary body 16 is caught between the inflow side connection port 67 and the holding portion 74, and the rotation of the rotary plate 72 is hindered. ..

Therefore, in the improved transport assist body relay device 19B shown in FIG. 55 (b), the position where the holding portion 74 assists the first transport assist body 16 is made shallow, and the second transport assist body 16 is set to 1. The second transport assisting body 16 is prevented from entering the holding portion 74 when it comes into contact with the first transport assisting body 16. As a result, the second transport auxiliary body 16 does not stop at a position straddling both the inflow side connection port 67 (fixed side) and the holding portion 74 (rotating side), and does not hinder the rotation of the rotating plate 72. ..

In the improved transport assist body relay device 19B, in order to make the position where the holding portion 74 holds the transport assist body 16 shallow, the receiving portion 81 is lengthened toward the downstream side, and the pair of holding arms 83 is the base plate 71. The rear end on the side is pivotally supported, and the tip on the inflow side connection port 67 side is provided with a holding roller 82 to open and close. Further, the positions of the release plate 84 and the release roller 85 have been changed. Further, as the position for holding the transport assisting body 16 becomes shallower, the position of the transmissive optical sensor 75 for detecting the transport assisting body 16 held by the holding portion 74 is changed.

(Improvement 2)
While the rotating plate 72 is rotating, the inflow side connection port 67 is closed so that the transport auxiliary body 16 does not pass through the inflow side connection port 67.

In the transport auxiliary body relay device 19 before the improvement, while the rotating plate 72 is rotating, the transport auxiliary body 16 arriving from the upstream flows in even though the holding portion 74 is not located behind the inflow side connection port 67. Since it was in a state where it could pass through the side connection port 67 and enter the relay unit 61, when the second transport auxiliary body 16 arrives in this state, the second transport auxiliary body 16 is brought into the holding portion 74. It may jump into the suction duct 65 or fall into the relay unit 61 to hinder the rotation of the rotating plate 72 without being received by the user.

Therefore, in the improved transport assist body relay device 19B, as shown in FIG. 56, the guard plate 87 prevents the transport assist body 16 arriving from the upstream while the rotating plate 72 is rotating from passing through the inflow side connection port 67. Was provided.

The guard plate 87 shown in FIG. 56 is concentric with the rotating plate 72, and the portion covering the holding portion 74 is removed from the annular plate obtained by hollowing out a disk having a radius just covering the holding portion 74 with concentric small circles. It is a metal plate having a shape corresponding to the remaining portion, and is attached to the rotating plate 72 so as to be flush with the upper end of the holding portion 74 (the opening at the end on the inflow side connection port 67 side). Rotate with. The guard plate 87 faces the outlet of the inflow side connection port 67 and closes the inflow side connection port 67 during rotation when the holding portion 74 is not located at a position facing the inflow side connection port 67.

Here, for convenience of manufacturing and mounting, the guard plate 87 is divided into two parts with the holding portion 74 as a boundary. A collar portion 88 that forms the same plane as the guard plate 87 and extends outward is provided on the peripheral edge of the opening on the inflow side connection port 67 side of the holding portion 74. When the holding portion 74 is slightly displaced from the position facing the front surface of the inflow side connection port 67, such as immediately after the start of rotation or immediately before the end of rotation, the collar portion 88 becomes the outer periphery of the opening on the inflow side connection port 67 side of the holding portion 74. It serves to close a small gap generated between the inflow side connection port 67 and the inflow side connection port 67.

Although the embodiment of the present invention has been described above with reference to the drawings, the specific configuration is not limited to that shown in the embodiment, and there are changes and additions within a range that does not deviate from the gist of the present invention. Is also included in the present invention.

In the embodiment, a transport method using an air flow and a transport auxiliary body 16 is also adopted for the island bill transport device 8 in the gaming machine island 3, but the island bill transport device 8 transports the bill P with a belt or the like. Other methods may be used.

In the embodiment, the transport pipe 12 is installed behind the ceiling, but it may be configured to be piped near the ceiling or under the floor. In the case of under the floor, the sub-conveyor device 13 may transport the banknotes discharged from the back surface of the relay box 6 downward.

In the embodiment, the transport pipe 12 is piped in the vertical direction and in the horizontal plane, but the transport pipe 12 may be installed at an inclination. For example, in the case of an inclined ceiling, the transport pipe 12 may be inclined along the ceiling.

The game machine island 3 is not limited to the configuration for accommodating the pachinko machine and the game ball lending machine exemplified in the embodiment, and may be a game machine island for accommodating the medal lending machine, the slot machine, and the like.

The shape of the transport assist body 16 is not limited to that shown in the embodiment. For example, it may be a pillar shape such as a rectangular cross section or a polygon. Further, although the transport auxiliary body 16 has a shape symmetrical with respect to the central portion in the Y direction, the shape may be asymmetrical in the Y direction.

In the embodiment, the banknote P has been described as an example of paper leaves, but other types of paper leaves such as tickets and cards may be used. Moreover, the shape of paper leaves is not limited to a rectangle. Further, the installation location of the paper leaf collection and transportation system 10 is not limited to the amusement park, and other facilities may be used.

In the embodiment, the cross section of the transport pipe 12 is substantially rectangular, but other shapes such as a circular shape and an elliptical shape may be used. However, it is preferable that the transport auxiliary body has a shape corresponding to its inner edge shape and covers almost the entire cross section. Further, it is preferable to provide a plurality of ribs to narrow the effective passage width of the paper leaves.

2 ... Game hall 3 ... Game machine island 4 ... Game ball rental machine 5 ... Game machine 6 ... Relay box 8 ... Island bill transport device 10 ... Paper leaf collection and transport system 11 ... Collective safe 12 ... Transport pipe 12a ... Outbound transport pipe 12b ... Return route transport pipe 13 ... Secondary transport device 14 ... Capture device 15 ... Connecting part 16 ... Transport auxiliary body 16a ... Head 16b ... Neck 16c ... Large diameter part 16d ... Constricted part 17 ... Transport auxiliary body relay device 18 ... Auxiliary Blower 19 ... Release wind blower 21 ... Air flow generator 22 ... Bill separation / transport auxiliary body circulation device 23 ... Transport auxiliary body insertion device 24 ... Separation / collection device 25 ... Bill storage unit 26 ... Bill transport unit 27 ... Control unit 28 ... Guide passage 29 ... Waiting place 32 ... Side wall 33 ... Expansion 34 ... Rib 34a ... Slope 36 ... Guide rail 37 ... Connecting wall 41 ... Holding 42 ... Receiving 43 ... Slit 45 ... Sending 46 ... Movable arm 51 ... Twisted part 51a ... Sub-twisted pipe 51b ... Connection part 61 ... Relay part 62 ... Blower part 63 ... Fan 65 ... Suction duct 66 ... Blower duct 67 ... Inflow side connection port 68 ... Outflow side connection port 71 ... Base plate 71a ... Suction duct Connection port 71b ... Blower duct connection port 72 ... Rotating plate 72a ... Ventilation hole 73 ... Support shaft 74 ... Holding part 75 ... Sensor 76 ... Transmitting optical sensor 81 ... Receiving part 82 ... Holding roller 83 ... Holding arm 84 ... Release plate 85 ... Release roller 87 ... Guard plate 88 ... Collar 91 ... Side rib 92 ... Guide rib 93 ... Guide rib 101 ... Secondary transport pipe 101a ... Opening 102 ... Upflow generator 102a ... Fan 102b ... Blower duct 103 ... Bill intake section 104 ... Passage part 104b ... Opening 104c ... Inflow port 105a ... Conveying roller 105b ... Conveying belt 121 ... Passage part 122 ... Conveying part 123 ... Bill guide path 124 ... Conveying belt 125a ... Feeding roller 125b ... Feeding belt 126 ... Shutter 128 ... Holding roller 129 ... Movable arm 129a ... Support point 130 ... Solvent 131 ... Bill detection sensor 140 ... Transport pipe 142 ... Bill capture device 144 ... Air flow generator 145 ... Bill separation / transport auxiliary body circulation device 146 ... Transport auxiliary body insertion device 147 ... Separation and collection device 148 ... Bill transport unit 150 ... Temporary storage device 151 ... Attitude conversion unit 152 ... Elevator unit 152a ... Receiving plate 152b ... Holding plate 153 ... Feeding transport unit 153b ... Transport bell To 154 ... Storage part 155 ... Natural rubber sheet 156 ... Thick line indicating the transport route 160 ... Connection body part 161 ... Upstream side connection port 162 ... Downstream side connection port 162b ... Butt part 163 ... Rib (center)
163a, 163b ... Two parallel ribs 164 ... Ribs (both sides)
166 ... Sensor 170 ... Connection adapter 171 ... Upstream connection port 172 ... Downstream end 173 ... Rib (center)
174 ... Ribs (both sides)
180 ... Error display 181 ... Vertical section Transport path display unit 182 ... Horizontal section Transport path display section 183 ... Message display section 184 ... Up / down button 185 ... Alarm button Dx ... Distance between reference planes of the transport tube Dy ... Y of the transport tube Inner dimensions in the direction Ds ... Shift amount FW ... Extension direction of the transport pipe M ... Path of the bill transport section P, P1, P2, P3 ... Bill W ... Passage width X ... Passage width direction of the transport pipe Y ... Height of the transport pipe Direction

Claims (4)

A paper leaf collection and transport system that generates an air flow in the transport pipe and pushes and moves the paper sheets inserted in the transport pipe from behind with a transport auxiliary body that receives the air flow and moves in the transport pipe. There,
A transport auxiliary body insertion device provided upstream from the insertion position where paper sheets are inserted into the transport pipe and delivering the transport auxiliary body into the transport pipe.
A holding portion provided in the middle of the transport pipe between the insertion position and the transport assist body insertion device, which receives and temporarily holds the transport assist body arriving from inside the transport pipe on the upstream side, and the holding portion. moving the held conveyance auxiliary member toward the conveying pipe downstream and a moving portion, and conveyance auxiliary body transportable to be out feeding the conveying pipe downstream feed auxiliary body relay device and the moved,
Have,
The moving portion is a rotating body in which the holding portion is provided at a position separated by a predetermined distance in the radial direction from the center of rotation, and when the rotating body rotates, the holding portion faces the upstream side. A paper leaf collection and transportation system characterized in that it is moved to a position facing the downstream side. When the holding portion is not in a position facing the upstream side, the receiving port of the transport assisting body from the upstream side is closed, and when the holding portion is not in a position facing the downstream side, the transport assisting portion to the downstream side is closed. Has a closure that closes the body's outlet
The paper leaf collection and transportation system according to claim 1. Used in a paper leaf transport system that generates an air flow in the transport pipe and pushes and moves the paper sheets inserted in the transport pipe from behind with a transport auxiliary body that receives the air flow and moves in the transport pipe. It is a transport auxiliary relay device to be used.
In the middle of the transport pipe between the insertion position where paper sheets are inserted into the transport pipe and the transport assist body insertion device provided upstream from the insertion position and sending the transport assist body into the transport pipe. A holding portion that receives and temporarily holds the transport assisting body that has arrived from the upstream side transporting pipe, and a moving portion that moves the transporting auxiliary body held by the holding portion toward the downstream side transporting pipe. It has a function to send the moved transport auxiliary body into the transport pipe on the downstream side.
The moving portion is a rotating body in which the holding portion is provided at a position separated by a predetermined distance in the radial direction from the center of rotation, and when the rotating body rotates, the holding portion faces the upstream side. A transport auxiliary relay device characterized in that it is moved to a position facing the downstream side. When the holding portion is not in a position facing the upstream side, the receiving port of the transport assisting body from the upstream side is closed, and when the holding portion is not in a position facing the downstream side, the transport assisting portion to the downstream side is closed. Has a closure that closes the body's outlet
The transport auxiliary relay device according to claim 3.

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