JP7510776B2 - Paper sheet transport device - Google Patents

Description

The present invention relates to a paper sheet transport device for transporting paper sheets such as banknotes.

A paper sheet transport device has been disclosed in Japanese Patent Application Laid-Open No. 2008-213954. In this paper sheet transport device, a transport chain is stretched between a drive sprocket and a driven sprocket. The transport chain is formed into a ring shape by connecting a number of links, which are unit members, in sequence. A friction member is attached to each link. An action portion made of a friction material is provided on the side of the friction member. When the transport chain is driven by the drive sprocket to move in a circle, the banknotes are transported by the action of the friction force generated between the action portions of the links belonging to the individual links that make up the transport chain and the banknotes, which are the paper sheets.

Another paper sheet transport device has been disclosed in JP 2015-087932 A. In this paper sheet transport device, a number of transport pieces, which are unit components, are connected in sequence to form a ring shape. The paper notes are transported by the action of frictional forces generated between the paper note contact parts on each transport piece and the paper notes themselves.

Patent Publication No. 2016-047760 discloses yet another paper sheet transport device. In this paper sheet transport device, a ring-shaped transport chain is formed by connecting multiple chain pieces, which are unit members, in sequence. This transport chain is supported by a pair of pulleys. A rotary actuator is connected to one of the pulleys for running the transport chain in one direction (paragraph [0019]). The specific configuration of the rotary actuator is not clear. When the transport chain moves in a circle, the banknotes are transported by the action of frictional force generated between the action part of the chain piece and the banknotes, which are the paper sheets.

JP 2008-213954 A JP 2015-087932 A JP 2016-047760 A

In a conveying mechanism that uses a conveying chain, the conveying chain is formed by connecting unit members such as conveying pieces. One unit member can freely move toward or away from another adjacent unit member, and can freely rotate and oscillate. Movement toward or away from another unit member means movement toward or away from the other unit member.

When unit members move toward or away from other unit members, or when they rotate or oscillate, as described above, a load may be placed on the circular movement of the conveyor chain, or the conveyor chain may vibrate, causing the balance of the circular movement of the conveyor chain to be lost.

Meanwhile, in the conventional paper transport devices described above, there was only one drive source for driving the transport chain, for example an electric motor, per paper transport device. For this reason, when a load was generated in the circular movement of the transport chain, it was difficult to generate a transport force in any part of the transport chain that could withstand the load. Also, when the balance of the circular movement was lost at various points on the transport chain, it was difficult to optimize the imbalance at all points.

The present invention was made in consideration of the above problems with conventional devices, and aims to improve the conveying force of the conveying chain so that it will not succumb to loads that may occur in any part of the conveying chain, and to efficiently optimize imbalances that may occur in any part of the conveying chain.

The paper sheet transporting device of the present invention is a paper sheet transporting device that transports paper sheets issued from a paper sheet processing means, the device having a transport path along which the paper sheets are transported, a circular transport chain that transports the paper sheets along the transport path, at least two drive sources that drive the transport chain to move in a circular manner, and a power transmission means that transmits the power of the at least two drive sources to the transport chain, the transport chain having a plurality of transport links connected by connecting pins, the transport links having paper sheet abutment portions that transport the paper sheets by frictional force, the transport chain having an outward running portion and a return running portion, the outward running portion and the return running portion each having at least one curved portion, the power transmission means transmits the power of the drive source to the transport chain so that the transport chain moves in one direction, and functions to allow the transport chain itself to move in the one direction, and the directions in which the power transmission means belonging to each of the two drive sources transmit power are the same.

With this paper sheet transport device, the endless circular transport chain is driven by multiple drive sources (e.g. electric motors), providing sufficient transport force compared to a single drive source. In addition, by using multiple drive sources provided at different points on the transport chain, the entire transport chain can be moved in a balanced manner.

The power transmission means also functions to transmit the power of the drive source to the conveyor chain so that the conveyor chain moves in one direction (for example, direction C in FIG. 8), and also to allow the conveyor chain itself to move in the one direction (direction C). This allows the conveyor chain to move stably in a circular motion even when a single conveyor chain is driven by multiple drive sources and there is a slight variation in the driving force of each drive source.

Furthermore, the conveying chain is formed by connecting multiple conveying pieces. When each conveying piece moves around, it rotates and oscillates relative to other adjacent conveying pieces and moves back and forth. These movements of the conveying pieces can cause the conveying chain to lose balance as it moves around. However, in this embodiment, the power transmission means transmits the power of the drive source to the conveying chain so that the conveying chain moves in one direction (for example, direction C in Figure 8), and allows the conveying chain itself to move in the one direction (direction C). Therefore, even if each of the multiple conveying pieces rotates and oscillates or moves back and forth independently, the conveying chain can be moved around stably without losing balance.

Another aspect of the paper sheet transport device according to the present invention has a guide member arranged opposite the transport chain, and the transport path is formed between the transport chain and the guide member. This structure allows the paper sheets to be transported stably.

In yet another aspect of the paper sheet transport device according to the present invention, the drive source is an electric motor, and the power transmission means has a rotation transmission element that engages with the transport chain to move the transport chain in a circular motion, and a one-way clutch provided between the output shaft of the electric motor and the rotation transmission element, and the one-way clutch can take two states: a locked state in which the power of the output shaft of the electric motor is transmitted to the rotation transmission element, and an unlocked state in which the rotation transmission element rotates freely relative to the output shaft of the electric motor, and the one-way clutch transmits the one-way power of the drive source to the rotation transmission element in the locked state, and allows the transport chain itself to move in the one direction in the unlocked state. With this configuration, the power transmission means of the present invention can be realized simply and reliably.

In yet another aspect of the paper sheet transport device according to the present invention, the drive source is provided at each end of the transport chain, which is the boundary between the outward traveling section and the return traveling section. In this paper sheet transport device, the transport chain has a curved section, so that the paper sheet transport device can be installed even if there is an obstacle such as a pillar at the installation location of the paper sheet transport device.

In yet another aspect of the paper sheet transport device according to the present invention, the paper sheets are banknotes, a banknote storage vault is provided for storing the banknotes, the paper sheet processing means is a gaming medium dispenser that receives the inserted banknotes and dispenses gaming media, and the transport path transports the banknotes from the paper sheet processing means to the banknote storage vault. This paper sheet transport device makes it possible to transport banknotes in an amusement facility equipped with multiple gaming machines.

In the paper sheet transport device according to the present invention, the endless circular transport chain is driven by multiple drive sources (e.g. electric motors), so a sufficient transport force can be obtained compared to when the transport chain is driven by a single drive source.

In addition, by using multiple drive sources installed at different points on the conveyor chain, the conveyor chain can be moved in a more balanced manner throughout the chain compared to when one drive source is installed in one location.

The power transmission means also functions to transmit the power of the drive source to the conveyor chain so that the conveyor chain moves in one direction (for example, direction C in FIG. 8), and also to allow the conveyor chain itself to move in the one direction (direction C). This allows the conveyor chain to move stably in a circular motion even when a single conveyor chain is driven by multiple drive sources and there is a slight variation in the driving force of each drive source.

Furthermore, the conveying chain is formed by connecting multiple conveying pieces. When each conveying piece moves around, it rotates and oscillates relative to other adjacent conveying pieces and moves back and forth. These movements of the conveying pieces can cause the conveying chain to lose balance as it moves around. However, in this embodiment, the power transmission means transmits the power of the drive source to the conveying chain so that the conveying chain moves in one direction (for example, direction C in Figure 8), and allows the conveying chain itself to move in the one direction (direction C). Therefore, even if each of the multiple conveying pieces rotates and oscillates or moves back and forth independently, the conveying chain can be moved around stably without losing balance.

1 is a plan view of a game island including an embodiment of a paper sheet transport device according to the present invention; FIG. 2 is a perspective view showing a portion indicated by an arrow A in FIG. 1 . 2 is a cross-sectional view showing the vertical cross-sectional structure of the paper sheet transport device taken along line BB in FIG. 1. FIG. 4 is an exploded perspective view of the paper sheet transport device of FIG. 3 . FIG. 4 is a perspective view of the paper sheet transport device of FIG. 3 . 1 is a perspective view of a conveying piece which is a unit member of a conveying chain which is a component of a paper sheet conveying device according to the present invention; 1 is a front view of a portion of a conveyor chain that is a component of a paper sheet conveying device according to an embodiment of the present invention; FIG. 2 is a perspective view showing one embodiment of a power transmission means which is a component of the paper sheet transport device according to the present invention. FIG. 13 is a diagram showing how a transport top rotates. FIG. 11 is another diagram showing the manner in which the transport top rotates. 13 is a plan view of a game island including another embodiment of a paper sheet transport device according to the present invention. FIG. 13 is a plan view of a game island including still another embodiment of a paper sheet transport device according to the present invention. FIG. 13 is a cross-sectional view showing the vertical cross-sectional structure of the paper sheet transport device taken along line HH in FIG. 12. 13 is a plan view of a game island including still another embodiment of a paper sheet transport device according to the present invention. FIG.

The paper sheet transport device according to the present invention will be described below based on an embodiment. It is needless to say that the present invention is not limited to this embodiment. Furthermore, in the drawings attached to this specification, the components may be shown at different ratios than in actuality in order to clearly show the characteristic parts.

First Embodiment
(Overall structure)
Fig. 1 is a plan view of an example of a game island using a paper sheet transport device according to the present invention. In Fig. 1, the game island 1A has a plurality of game machines 2 and a plurality of game media lending machines 3 as paper sheet processing means. In Fig. 1, not all of the game machines are labeled with the reference number 2. Also, not all of the game media lending machines are labeled with the reference number 3. However, the game machines 2 and the game media lending machines 3 are installed side by side with no gaps across the entire surface of the game island 1A.

The multiple gaming machines 2 and multiple gaming media lending machines 3 are each installed vertically (through the paper in FIG. 1). The multiple gaming machines 2 and multiple gaming media lending machines 3 are also installed alternately in the horizontal direction (left-right direction in FIG. 1). The gaming machine row 4A on the front side and the gaming machine row 4B on the back side are installed back-to-back with a space between them.

Figure 2 shows a perspective view of the portion indicated by the arrow A in Figure 1 when viewed from diagonally above. As shown in Figure 2, the gaming machine 2 in this embodiment is a pachinko machine. In some cases, the gaming machine 2 may be a pachislot machine or other gaming machine. The gaming medium lending machine 3 has a bill insertion port 7. In addition, a gaming medium dispensing outlet (not shown) is provided at an appropriate position of the gaming medium lending machine 3. When a predetermined amount of bills is inserted into the bill insertion port 7, a predetermined amount of gaming media (pachinko balls in this embodiment) is dispensed from the gaming medium dispensing outlet and supplied to a predetermined location in the gaming machine 2. Reference numeral 6 in Figure 2 indicates a bill storage for collecting bills.

(paper sheet transport device)
In Fig. 1, a paper sheet transport device 8A according to the present invention is provided inside amusement island 1A, specifically between a front row of gaming machines 4A and a rear row of gaming machines 4B. Fig. 3 shows a cross-sectional structure of paper sheet transport device 8A along line B-B in Fig. 1. In Fig. 3, paper sheet transport device 8A has a frame 9 and a guide plate 10A as a guide member and a guide plate 10B as a guide member. Frame 9, guide plate 10A and guide plate 10B are all roughly rectangular plate-like members as shown in Fig. 4.

In FIG. 4, the frame 9 is made of a lightweight, rust-resistant material, such as an aluminum alloy. The guide plates 10A and 10B are made of synthetic resin. It is desirable that the guide plates 10A and 10B are transparent or light-transmitting so that the banknotes being transported inside can be seen.

Linear grooves 11, 11 are formed on both the left and right sides of the upper edge of the frame 9. Linear grooves 12, 12 are formed on both the left and right sides of the lower edge of the frame 9. Multiple (three in this embodiment) engaging protrusions 15 are provided on the upper edge of the guide plate 10A. Multiple (three in this embodiment) engaging protrusions 16 are also provided on the lower edge of the guide plate 10A. Multiple (three in this embodiment) engaging protrusions 17 are provided on the upper edge of the guide plate 10B. Multiple (three in this embodiment) engaging protrusions 18 are also provided on the lower edge of the guide plate 10B.

As shown in FIG. 3, the upper engagement protrusion 15 of guide plate 10A is inserted and fitted into the upper groove 11 of frame 9, the lower engagement protrusion 16 of guide plate 10A is inserted and fitted into the lower groove 12 of frame 9, the upper engagement protrusion 17 of guide plate 10B is inserted and fitted into the upper groove 11 of frame 9, and further the lower engagement protrusion 18 of guide plate 10B is inserted and fitted into the lower groove 12 of frame 9, thereby forming a transport unit 19 having an overall rectangular cylindrical shape as shown in FIG. 5. By connecting multiple transport units 19 consecutively in the longitudinal direction, the long paper sheet transport device 8A shown in FIG. 1 is formed.

In FIG. 3, the frame 9 has a partition plate 22 between the upper groove 11 and the lower groove 12. A space K1 for the chain is formed between the partition plate 22 and the left guide plate 10A, and a space K2 for the chain is formed between the partition plate 22 and the right guide plate 10B. The inner surfaces of the guide plates 10A and 10B are provided with ridges 23 that extend linearly in the longitudinal direction (the direction penetrating the paper surface in FIG. 3). These ridges 23 act to guide the paper sheets, i.e., banknotes, that are being transported.

The forward running portion of the conveyor chain 24 is provided in the chain space K1. The return running portion of the conveyor chain 24 is provided in the chain space K2. As shown in FIG. 1, the conveyor chain 24 is supported at one end by the first sprocket 25a and at the other end by the second sprocket 25b. The conveyor chain 24 is stretched in a long, endless loop between the first sprocket 25a and the second sprocket 25b. The conveyor chain 24 moves in a circle between the first sprocket 25a and the second sprocket 25b.

As described above, in this embodiment, the transport unit 19 (see FIG. 5) with guide plates 10A and 10B on both sides is used as a casing. Both the forward and return running portions of the transport chain 24 are enclosed by the single casing. The inner surfaces of both sides of the casing serve as guide surfaces for guiding the transported banknotes.

(Bend)
In Fig. 1, the conveyor chain 24 has a plurality of bends 28, 28 (two in this embodiment) in the middle of the circular movement path. In this embodiment, these bends 28 are formed by a combination of rotation transmission elements such as a driven pulley, a driven sprocket, etc., and curved guide plates 10A, 10B. These bends 28 are provided according to the convenience of the location where the game island 1A is installed. For example, the bends 28 are provided to avoid obstacles such as walls and pillars when the installation location has such obstacles. In addition, the bends 28 are provided when it is desired to install a large number of game machines 2 when the installation location is not elongated such as a circle or a square when viewed in a plan view.

In this embodiment, the conveyor chain 24 is bent at an angle of approximately 90 degrees at the bend 28, but the bend angle can be any angle other than 90 degrees. The bend 28 can also be curved with a curvature. In this embodiment, the bend 28 is formed by combining a rotary transmission element such as a pulley with a curved guide plate, but the bend 28 can have any other configuration.

In FIG. 3, a bill transport path R1 for transporting bills 29 as paper sheets is formed between the forward running portion of the transport chain 24 and the left guide plate 10A. Also, a bill transport path R2 for transporting bills 29 is formed between the return running portion of the transport chain 24 and the right guide plate 10B.

(Conveyor chain)
The conveyor chain 24 is formed by sequentially connecting a plurality of conveyor pieces 30 as unit members shown in Fig. 6 by connecting pins 31 as shown in Fig. 7. In Fig. 6, the conveyor piece 30 has a connecting portion 32 and arms 33a, 33b. A banknote abutting portion 36 is provided on the side portion of the connecting portion 32. The banknote abutting portion 36 is made of a material capable of generating sufficient frictional force with the banknote, for example a material with a large coefficient of friction. The connecting portion 32 is also provided with a connecting hole 37 for passing the connecting pin 31 through.

A space S1 is formed between the arm 33a and arm 33b that branch off from the connecting portion 32. The connecting pin 31 is present inside this space S1. In FIG. 7, a hole 38 for fitting a sprocket is formed between the rear end of the connecting portion 32 of one transport top 30 and the front end of the connecting portion 32 of the other transport top 30 adjacent to the rear of the connecting portion 32.

In FIG. 6, a roller 39a is provided on one arm 33a of the transport top 30. Flanges 40 are provided on both ends of the roller 39a. A roller 39b is provided on the other arm 33b of the transport top 30. Flanges 40 are provided on both ends of the roller 39b. In FIG. 3, two guide rails 43a, 43b are provided slightly above the vertical center of the frame 9. These guide rails 43a, 43b extend linearly as shown in FIG. 4. In addition, two guide rails 43c, 43d are provided slightly below the vertical center of the frame 9. These guide rails 43c, 43d also extend linearly as shown in FIG. 4.

In FIG. 3, the flanges 40 of the rollers 39a and 39b of the conveying link 30 of the conveying chain 24 installed inside the chain spaces K1 and K2 are loosely fitted into the guide rails 43a, 43b, 43c, and 43b of the frame 9. As a result, the conveying link 30 moves while being guided by the guide rails 43a, 43b, 43c, and 43b in FIG. 4.

(Drive source and power transmission means)
In Fig. 1, a first electric motor 44a is provided as a drive source at the left end of the endless looped conveyor chain 24. On the other hand, a second electric motor 44b is provided as a drive source at the right end of the conveyor chain 24. These electric motors 44a, 44b are drive sources for moving the conveyor chain 24 in a circular motion as shown in Fig. 8. Specifically, a pulley 50 is attached to the output shafts 45a, 45b of the electric motors 44a, 44b, a pulley 52 is attached to the shafts of the first sprocket 25a and the second sprocket 25b that mesh with the conveyor chain 24, and a belt 46 is stretched between the pulley 50 and the pulley 52. In this embodiment, the first sprocket 25a and the second sprocket 25b act as rotation transmission elements.

The rotation of the output shafts 45a, 45b of the motors 44a, 44b is transmitted to the first sprocket 25a and the second sprocket 25b by the belt 46. The teeth of the first sprocket 25a and the second sprocket 25b are adapted to fit into the sprocket fitting holes 38 of the conveying links 30 of the conveying chain 24. Therefore, when the sprockets 25a, 25b are driven by the motors 44a, 44b to rotate, the conveying chain 24 moves in a circle as shown by the arrow C.

In this embodiment, a one-way clutch 47 is provided between the belt 46 and the sprockets 25a and 25b. The one-way clutch 47 is locked when the belt 46 moves in the direction of the arrow D, and transmits the movement to the sprockets 25a and 25b. This causes the sprockets 25a and 25b to rotate in the direction of the arrow C, and the conveyor chain 24 moves in the direction of the arrow C.

When the belt 46 tries to move in the direction opposite to the arrow D, the one-way clutch 47 is unlocked and the belt 46 spins freely around the sprockets 25a and 25b. In other words, the one-way clutch 47 functions to transmit the power of the motors 44a and 44b to the conveyor chain 24 so that the conveyor chain 24 moves in one direction indicated by the arrow C, while allowing the conveyor chain 24 itself to move in the same direction C.

From another perspective, the following explanation can be given. Under normal conditions, the conveyor chain 24 is driven by the motors 44a and 44b to move in a circle at a speed v. If, under these conditions, the speed of the conveyor chain 24 becomes faster than v for some reason, the speed of the sprockets 25a and 25b and their shafts 51 also increases in accordance with the conveyor chain 24. However, at this time, the pulleys 52 and 50 do not increase in speed due to the action of the one-way clutch 47.

On the other hand, if the speed of the conveyor chain 24 becomes slower than v for some reason, the sprockets 25a, 25b, their shafts 51, pulley 52, and pulley 50 will follow suit and try to slow down. This is the same whether or not there is a one-way clutch 47. In this case, an excessive load is placed on the motors 44a, 44b. When an excessive load is placed on the motors 44a, 44b in this way, the clutches in the motors 44a, 44b are activated and the rotation of the output shafts 45a, 45b becomes intermittent. A sensor is attached to the shaft 51 of the sprockets 25a, 25b in advance, and the intermittent rotation of the output shafts 45a, 45b of the motors 44a, 44b is detected by the sensor. In this case, it is assumed that an abnormality has occurred in the motors 45a, 45b, and appropriate measures are taken.

In this embodiment, the pulley 50, the belt 46, the pulley 52, the one-way clutch 47, and the sprockets 25a and 25b constitute a power transmission means 54 for transmitting the power of the motors 44a and 44b to the conveyor chain 24. The main function of the power transmission means 54 is to transmit the power of the motors 44a and 44b to the conveyor chain 24 so that the conveyor chain 24 moves in one direction indicated by the arrow C, and to allow the conveyor chain 24 itself to move in the same one direction C. As long as this function is achieved, the specific configuration of the power transmission means is not limited to the configuration adopted in this embodiment. A structure in which the tension of the conveyor chain is kept constant using a well-known ratchet or biasing means may also be used.

(Operation of the paper sheet transport device)
Since the paper sheet transport device 8A shown in Fig. 1 is configured as described above, when the output shafts 45a, 45b (see Fig. 8) of the motors 44a and 44b at both ends of the transport chain 24 rotate in the same direction at the same speed, the transport chain 24 moves in a constant direction. In this state, a bill is inserted into the bill insertion slot 7 (see Fig. 2) of one of the game media lending machines 3. The inserted bill undergoes a predetermined authenticity inspection process. Bills that are determined to be authentic by this authenticity inspection process are sent to the bill transport path R1 or R2 (see Fig. 3) in Fig. 3.

The bills 29 that are sent out come into contact with the surface of the bill contact portion 36 of the transport piece 30 in a landscape upright state, and are transported in the circular direction of the transport chain 24 by the action of friction. The bills 29 transported in this way move in the circular direction of the transport chain 24 in FIG. 1, and are then stored in the bill storage vault 6 located at the left end of the play island 1A.

In order to meet the needs of users and the like, in this embodiment, the length of the conveyor chain 24 is increased. Moreover, the conveyor chain 24 has two bent portions 28, 28. As a result, the load on the entire conveyor chain 24 is large. If there were only one motor as the driving source for driving the conveyor chain 24 as in the past, a large-capacity motor would not be used to obtain sufficient conveying force. However, even if one large-capacity motor is used, there would be a difference in conveying force between the portion close to the motor and the portion far from the motor, and there is a risk that stable conveying of banknotes cannot be achieved.

In contrast, in this embodiment, the conveyor chain 24 is driven by two motors 44a, 44b installed at different locations, so that even if the conveyor chain 24 is long or if the conveyor chain 24 has a bent portion 28, the conveyor chain 24 can be stably conveyed with sufficient conveying force throughout the entire conveyor chain 24.

In addition, in this embodiment, as shown in FIG. 8, a one-way clutch 47 is provided between the output shafts 45a, 45b of the motors 44a, 44b and the sprockets 25a, 25b. This allows the sprockets 25a, 25b some freedom in their own movement to rotate in the direction of arrow C. Therefore, even when two motors 44a, 44b are provided for one conveyor chain 24, it is possible to prevent abnormal loads from being applied to the sprockets 25a, 25b, and to rotate the sprockets 25a, 25b stably.

Furthermore, in this embodiment, the banknotes 29 are transported by the transport chain 24 as shown in FIG. 3. The transport chain 24 is structured to connect a plurality of transport pieces 30 with a connecting pin 31 as shown in FIG. 7. In this case, the connecting pin 31 is inserted into the hole 37 in FIG. 6, and a gap exists between the inner peripheral surface of the hole 37 and the outer peripheral surface of the connecting pin 31. Therefore, in FIG. 9, one transport piece 30a may rotate and oscillate in a vertical plane parallel to the circumferential movement direction F of the transport chain 24 relative to another adjacent transport piece 30b as shown by the arrow E in FIG. 9, or may rotate and oscillate in a vertical plane perpendicular to the circumferential movement direction F of the transport chain 24 (the direction penetrating the paper in FIG. 10) as shown by the arrow G in FIG. 10. In addition, the transport piece 30 may move forward and backward (i.e., move closer to or farther away from) the other adjacent transport piece 30.

When such rotational oscillation or back-and-forth movement of the conveying piece 30 occurs in the chain space K1 or the chain space K2 shown in FIG. 3, a large load may be placed on the conveying chain 24, or the conveying chain 24 may become unbalanced. In this embodiment, two (i.e., multiple) motors 44a, 44b are provided at different points on one conveying chain 24, so that a sufficient conveying force can be applied across the entire conveying chain 24 to withstand a large load applied to the conveying chain 24.

In addition, in this embodiment, as shown in FIG. 8, by using a power transmission means 54 including a one-way clutch 47, the power of the motors 44a, 44b is transmitted in one direction (direction D) and not in the opposite direction. In other words, the sprockets 25a, 25b are given the freedom to rotate in the circular movement direction C, which allows the transport balance of the transport chain 24 to be optimized.

In addition, when a load is applied to the chain transport, the intervals between the transport links increase from the load point to the drive motor (i.e., the intervals between the transport links increase), and the intervals between the transport links decrease from the drive motor to the load point (i.e., the intervals between the transport links decrease). Specifically, the chain is pulled and pushed (i.e., bent) before and after the pulley (or sprocket) of the drive section, and in addition, the chain becomes dislodged due to the increase in driving force caused by the continuous drive of the chain and the increase in bending caused by the transport links. In contrast, by using a power transmission means 54 including a one-way clutch 47 as in this embodiment, such dislodgment of the chain can be prevented.

(Modification)
In the above embodiment, the two curved portions 28 in Fig. 1 are formed by combining a driven rotation transmission element such as a driven pulley and the curved guide plates 10A, 10B. However, instead of this, one or both of the two curved portions 28 may be configured by a rotation drive structure. Such a rotation drive structure may be, for example, a structure including an electric motor 44a and a power transmission means 54 shown in Fig. 8.

Second Embodiment
Figure 11 shows the planar structure of another embodiment of the paper sheet transport device according to the present invention. In Figure 11, the same components as those shown in Figure 1 are given the same reference numerals, and the description of those components will be omitted. The game island 1B shown in Figure 11 has a paper sheet transport device 8B. The overall planar shape of the paper sheet transport device 8B is different from that of the paper sheet transport device 8A in Figure 1, but the cross-sectional structure of the paper sheet transport device 8B taken along line B-B in Figure 11 is the same as the cross-sectional structure of the paper sheet transport device 8A shown in Figure 3.

In this embodiment, a first detour section 57a is formed by four bends 28a, 28b, 28c, and 28d of the conveyor chain 24 to the left of the center in FIG. 11. A second detour section 57b is formed by four bends 28e, 28f, 28g, and 28h of the conveyor chain 24 to the right of the center. These detours 57a and 57b are provided to install the conveyor chain 24 while avoiding obstacles 58 and 58 that exist at the installation location of the play island 1B. The obstacles 58 are, for example, pillars that exist at the installation location. According to this embodiment, the play island 1B can be installed without any problems even in a location where there are obstacles such as pillars.

In this embodiment, when the output shafts 45a, 45b (see FIG. 8) of the motors 44a and 44b at both ends of the conveyor chain 24 rotate in the same direction at the same speed, the conveyor chain 24 moves in a constant direction. In this state, a bill is inserted into the bill insertion slot 7 (see FIG. 2) of one of the game media lending machines 3. The inserted bill undergoes a predetermined authenticity inspection process. Bills that are determined to be genuine by this authenticity inspection process are sent to the bill conveying path R1 or R2 (see FIG. 3) in FIG. 3.

The bills 29 that are sent out come into contact with the surface of the bill contact portion 36 of the transport piece 30 in a landscape upright state, and are transported in the circular direction of the transport chain 24 by the action of friction. The bills 29 transported in this way move in the circular direction of the transport chain 24 in FIG. 11, and are then stored in the bill storage vault 6 located at the left end of the play island 1B.

In this embodiment, many bends 28a to 28h are provided in the middle of the conveyor chain 24, so the load on the conveyor chain 24 as it moves around is very large. In such a case, if the conveyor chain is driven by only one motor as in the past, the capacity of that motor will be large. However, a motor with a large capacity is expensive. In addition, when the conveyor chain is driven by one motor, there is a risk that the movement of the conveyor chain will vary between parts of the conveyor chain close to the motor and parts far from the motor. In contrast, if the conveyor chain 24 is driven by motors 44a and 44b provided at different points on the conveyor chain 24 as in this embodiment, the conveyor chain 24 can be moved around stably.

Third Embodiment
Fig. 12 shows yet another embodiment of the paper sheet transport device according to the present invention. In Fig. 12, the same components as those shown in Fig. 1 are given the same reference numerals, and the description of those components will be omitted. In Fig. 12, a paper sheet transport device 8C according to the present invention is provided inside a game island 1C, specifically between a front game machine row 4C and a rear game machine row 4D.

Figure 13 shows the cross-sectional structure of the paper sheet transport device 8C along line H-H in Figure 12. In Figure 13, the paper sheet transport device 8C has a casing 59 that houses the transport pieces 30 that make up the transport chain 24, and guide rails 60, 60 extending from the upper and lower walls of the casing 59. The right side wall 59a of the casing 59 functions as a guide member for guiding the banknotes 29. The inside of the casing 59 forms a banknote transport path R3 for transporting the banknotes 29. The casing 59 has an overall rectangular cylindrical shape, similar to the transport unit 19 shown in Figure 5. By connecting multiple casings 59 in succession in the longitudinal direction, the long paper sheet transport device 8C shown in Figure 12 is formed. The guide rails 60, 60 in Figure 13 extend linearly in the longitudinal direction (the direction penetrating the paper surface in Figure 13).

Multiple (four in this embodiment) ridges 63 are provided on the inner peripheral surface of one side of the casing 59. These ridges 63 extend linearly in the longitudinal direction (the direction penetrating the paper surface in FIG. 13). These ridges 63 act to guide the banknotes 29, which are the paper sheets being transported.

The forward running portion of the conveyor chain 24 is provided inside one casing 59 (upper part of the figure) in FIG. 12, and the return running portion of the conveyor chain 24 is provided inside the other casing 59 (lower part of the figure). The conveyor chain 24 is supported at one end by a first sprocket 25a as a power transmission means, and at the other end by a second sprocket 25b as a power transmission means. The conveyor chain 24 is stretched in a long, endless loop between the first sprocket 25a and the second sprocket 25b. The conveyor chain 24 moves in a circle between the first sprocket 25a and the second sprocket 25b.

The first sprocket 25a and the second sprocket 25b are arranged at a distance J from each other in a horizontal plane. A rotary transmission element 64a, such as a pulley or sprocket, is provided at a short distance from the first sprocket 25a. A rotary transmission element 64b, such as a pulley or sprocket, is provided at a short distance from the second sprocket 25b. The conveyor chain 24 is supported by these rotary transmission elements 64a, 64b, so that the forward running portion and the return running portion move in circles parallel to each other. The rotary transmission elements 64a, 64b form the curved portion of the conveyor chain 24.

In this embodiment, a gap J is provided between the forward running portion and the return running portion of the transport chain 24, so the width L of the paper sheet transport device 8C is increased by that amount. In other words, the paper sheet transport device 8C of this embodiment is suitable when it is desired to make the width of the paper sheet transport device wider in relation to the installation location.

The conveying chain 24 is formed by connecting a number of conveying links 30 as unit members shown in FIG. 6 in sequence with connecting pins 31 as shown in FIG. 7. The specific structure of the conveying links 30 has already been explained, so an explanation will be omitted here. In FIG. 13, the flanges 40 of the rollers 39a and 39b of the conveying links 30 of the conveying chain 24 installed inside the casing 59 are loosely fitted into the guide rails 60, 60. As a result, the conveying links 30 move while being guided by the guide rails 60, 60.

In FIG. 12, a first electric motor 44a is provided as a drive source at the left end of the endless circular conveyor chain 24. On the other hand, a second electric motor 44b is provided as a drive source at the right end of the conveyor chain 24. These electric motors 44a and 44b are drive sources for moving the conveyor chain 24 in a circular motion as shown in FIG. 8. Specifically, a pulley 50 is attached to the output shafts 45a and 45b of the electric motors 44a and 44b, a pulley 52 is attached to the shafts of the first sprocket 25a and the second sprocket 25b that mesh with the conveyor chain 24, and a belt 46 is stretched between the pulley 50 and the pulley 52. The specific structures of the electric motors 44a and 44b and the sprockets 25a and 25b have already been explained, so they will not be explained here.

Thus, even in this embodiment in which the width L of the paper sheet transport device 8C is wide as shown in Fig. 12, a one-way clutch 47 is provided between the output shafts 45a, 45b of the motors 44a, 44b and the sprockets 25a, 25b as shown in Fig. 8 , so that the sprockets 25a, 25b are given some freedom to rotate independently in the direction of the arrow C. Therefore, even when two motors 44a, 44b are provided for one transport chain 24, it is possible to prevent abnormal loads from being applied to the sprockets 25a, 25b, and the sprockets 25a, 25b can rotate stably.

Fourth Embodiment
Fig. 14 shows yet another embodiment of the paper sheet transport device according to the present invention. The paper sheet transport device 8A shown in Fig. 1 had a plurality of bent portions 28. Also, the paper sheet transport device 8B shown in Fig. 11 had the detour portions 57a, 58b formed by a plurality of bent portions 28a to 28h. The paper sheet transport device 8D shown in Fig. 14 does not include any detour portions or bent portions, and is a paper sheet transport device in which the length of the play island is increased to meet the needs of users, etc., and which simply extends in a straight line.

In this embodiment, the endless loop conveyor chain 24 is longer, which generates a larger load than in the past. In response to this, the endless loop conveyor chain 24 is driven by multiple drive sources, electric motors 44a and 44b, so sufficient conveying force is obtained compared to when it is driven by a single drive source. In addition, by using multiple drive sources, the conveyor chain can be moved in a balanced manner throughout its length.

In addition, in FIG. 8, the one-way clutch 47 functions to transmit the power of the motors 44a and 44b to the conveyor chain 24 so that the conveyor chain 24 moves in one direction indicated by the arrow C, and also to allow the conveyor chain 24 itself to move in the same direction C. This allows the conveyor chain 24 to move stably in a circular motion even when a single conveyor chain 24 is driven by multiple drive sources and there is a slight variation in the drive force of each drive source.

Furthermore, the conveying chain 24 is formed by connecting a plurality of conveying frames 30 as shown in FIG. 7. When each conveying frame 30 moves around, it rotates and swings relative to the other conveying frames 30 adjacent to it, and moves back and forth. These movements of the conveying frames can cause the conveying chain 24 to lose its balance as it moves around. However, in this embodiment, the power transmission means 54 shown in FIG. 8 transmits the power of the driving sources 44a and 44b to the conveying chain 24 so that the conveying chain 24 moves in one direction (direction C), and allows the conveying chain 24 itself to move in one direction (direction C). Therefore, even if each of the plurality of conveying frames 30 rotates and swings or moves back and forth independently, the conveying chain 24 can be moved around stably without losing its balance.

Other Embodiments
Although the present invention has been described above with reference to preferred embodiments, the present invention is not limited to these embodiments and can be modified in various ways within the scope of the invention described in the claims.
For example , the above embodiments have illustrated the case of transporting banknotes in an amusement island that includes gaming machines such as pachinko machines, but the paper sheet transport device of the present invention can also be applied to the case of transporting banknotes in facilities other than amusement islands.

In addition, in the above embodiment, an example was given of transporting paper notes as paper sheets, but the paper sheet transport device of the present invention can also be applied to transporting paper sheets other than paper notes.

1A, 1B, 1C, 1D: gaming island, 2: gaming machine, 3: gaming medium lending machine (paper processing means),
4A, 4B, 4C, 4D: gaming machine row, 6: banknote storage, 7: banknote insertion slot, 8A, 8B, 8C, 8D: paper sheet transport device, 9: frame, 10A: left side guide plate (guide member), 10B: right side guide plate (guide member), 11: upper groove, 12: lower groove, 15, 16, 17, 18: engagement protrusion, 19: transport unit, 22: partition plate, 23: protrusion, 24: transport chain, 25a: first sprocket, 25b: second sprocket, 28: bent portion, 29: banknote (paper sheet), 30: transport piece (transport unit member), 30a, 30b: transport piece, 31: connecting pin, 32: connecting portion, 33a, 33b: arm portion, 36: banknote abutment portion, 37: Connection hole, 38: hole for fitting sprocket, 39a, 39b: roller, 40: flange, 43a, 43b, 43c, 43d: guide rail, 44a: first electric motor (driving source), 44b: second electric motor (driving source), 45a, 45b: output shaft, 46: belt, 47: one-way clutch, 50: pulley, 51: shaft, 52: pulley, 54: power transmission means, 57a, 57b: detouring portion, 58: obstacle, 59: casing, 59a: guide member, 60: guide rail, 63: ridge, 64a, 64b: rotation transmission element, J: interval, K1, K2: space for chain, L: width, R1, R2, R3: banknote transport path, S1: space

Claims (6)

In a paper sheet transport device that transports paper sheets discharged from a paper sheet processing means,
A conveying path along which the paper sheets are conveyed;
a circular conveying chain that conveys the paper sheets along the conveying path;
At least two drive sources that drive the conveyor chain to move in a circular motion;
and a power transmission means for transmitting the power of the at least two driving sources to the conveyor chain,
The conveyor chain has a plurality of conveyor links connected by connecting pins,
the conveying piece has a paper sheet contact portion that conveys the paper sheet by frictional force,
The conveyor chain has an outgoing running portion and a return running portion, and the outgoing running portion and the return running portion each have at least one curved portion, and
the power transmission means functions to transmit the power of the drive source to the conveyor chain so that the conveyor chain moves in one direction, and to allow the conveyor chain itself to move in the one direction;
A paper sheet transport device according to claim 1, wherein the power transmission means belonging to each of the two drive sources transmits power in the same direction. A guide member is disposed opposite the conveyor chain,
2. The paper sheet transport device according to claim 1, wherein the transport path is formed between the transport chain and the guide member. the drive source is an electric motor,
The power transmission means is
a rotational transmission element that engages the conveying chain to move the conveying chain in a circular motion;
a one-way clutch provided between an output shaft of the electric motor and the rotation transmission element,
the one-way clutch can be in two states: a locked state in which the power of the output shaft of the electric motor is transmitted to the rotation transmission element, and an unlocked state in which the rotation transmission element rotates freely relative to the output shaft of the electric motor,
3. The paper sheet transport device according to claim 1, wherein the one-way clutch transmits the one-way power of the drive source to the rotation transmission element in the locked state, and allows the transport chain itself to move in the one direction in the unlocked state. 4. The paper sheet transport device according to claim 1, wherein the drive sources are provided at both ends of the transport chain, which are boundary portions between the outgoing travel portion and the return travel portion. The paper sheet is a banknote,
A banknote storage unit for storing the banknotes is provided,
the paper processing means is a gaming media dispensing machine that receives the paper money and dispenses gaming media;
5. The paper sheet transport device according to claim 1, wherein the transport path transports the paper sheets from the paper sheet processing means to the paper sheet storage vault. The transport piece has the connecting pin and a connecting portion,
The connecting portion is provided with a connecting hole for passing a connecting pin belonging to a transport frame to be connected,
The paper sheet contact portion is provided on a side surface of the connecting portion.
2. The paper sheet transport device according to claim 1.

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