JP5857079B2 - Paper sheet processing device and game medium lending device - Google Patents

Description

The present invention relates to a paper sheet processing apparatus and a game medium lending apparatus for storing paper sheets such as banknotes.

  The paper sheet processing apparatus is a service device that provides various products and services by inserting paper sheets such as banknotes and coupons, for example, a gaming machine installed in a game hall, or a public place. It is incorporated in vending machines and ticket machines installed in the city. The paper sheet processing apparatus is configured to identify the validity of the input paper sheet and store the paper sheet determined to be valid.

  For example, a banknote processing apparatus provided in a gaming machine inter-table machine described in Patent Document 1 includes a banknote discriminator for identifying the authenticity of a banknote inserted from a banknote slot, and a plurality of banknotes identified as a true bill. And a stacker that stacks and stores (stacked storage).

  The stacker includes a plate-shaped pressing portion, a storage box having a bill intake port into which the pressing portion can be inserted on a surface facing the pressing portion, a driving unit that moves the pressing portion toward and away from the storage box, and storage It has a pressing plate disposed in the box so as to face the pressing portion, and a spring for biasing the pressing plate. The banknote inserted into the banknote insertion slot is transported through the banknote discriminator along the longitudinal direction of the banknote and sent out between the storage box and the pressing unit. With respect to the banknote width direction (the direction orthogonal to the transport direction), the width of the pressing portion and the opening width of the banknote intake port are slightly smaller than the width of the banknote. When a bill is conveyed between the storage box and the pressing portion, the pressing portion is moved toward the storage box by the driving means, and the bill is pushed into the storage box. The banknotes stored in the storage box are sandwiched between a spring-biased pressing plate and the inner surface of the storage box (specifically, the periphery of the banknote inlet).

JP 2002-331158 A

  In the banknote processing apparatus of Patent Document 1, both width-direction parts (both ends in a direction perpendicular to the transport direction) of the banknote sent out from the banknote discriminator between the storage box and the pressing part protrude from the pressing plate. By moving the pressing part to the storage box side, the part protruding from the pressing part of the banknote is bent by the pressing part and the banknote inlet, passes through the banknote inlet, and the banknote is in the storage box. Stored. Therefore, when the position of the banknote transported from the banknote discriminator is shifted in the banknote width direction (direction orthogonal to the transport direction), the length of the end protruding from the banknote pressing section is increased, and the pressing section is Even if it is moved to the storage box, it may not be possible to push all the banknotes into the storage box. That is, if the banknote conveyed from the banknote identification machine is not in a normal position, it may not be possible to store the banknote on the banknote stored in advance in the storage box.

  The present invention provides a paper sheet handling apparatus capable of being stacked and stored on a previously stored paper sheet even when the paper sheet is conveyed to a position shifted from a normal position. With the goal.

  The paper sheet processing apparatus of the present invention includes a storage unit that forms a storage space in which paper sheets are stacked and stored, a transport mechanism that transports paper sheets to the storage unit, and a paper sheet transported by the transport mechanism. A movable piece that is provided in a direction perpendicular to the conveyance direction of the paper and can move in and out of the storage space, and a rear end in the conveyance direction of the paper sheet conveyed to the storage unit by the conveyance mechanism is movable. After stopping the conveyance at the position facing the piece, the movable piece is moved in and out to move the rear end portion of the paper sheet at the position facing the movable piece to the storage space side, and the paper sheet And the like are stacked and stored in the storage space.

  According to said structure, the paper sheet processing apparatus is provided in the direction orthogonal to the conveyance direction of the paper sheet conveyed by the said conveyance mechanism, and is provided with the movable piece which can protrude and retract toward the said storage space. The movable piece is moved into and out of the movable piece after stopping conveyance at a position where the conveyance direction rear end of the paper sheet conveyed to the storage unit by the conveyance mechanism faces the movable piece. Since the rear end of the paper sheet in the conveying direction at the opposite position is moved to the storage space side and the paper sheets are stacked and stored in the storage space, the paper sheets are shifted in the width direction. Regardless of this, stacking (stacking storage) can be performed in a state where the rear ends of the paper sheets in the conveyance direction are aligned.

  In the paper sheet processing apparatus of the present invention, when the movable piece is positioned on the storage space side of the storage section, it forms a carry-in space for carrying the paper sheets transported by the transport mechanism into the storage section. You may comprise so that it may do.

  According to said structure, when a paper sheet is conveyed by the said conveyance mechanism, the said movable piece is arrange | positioned at the said storage space side, the said carrying-in space is ensured, and a paper sheet is passed through this carrying-in space. It can be stored in the storage space side. And it becomes possible to avoid obstructing the movement of the paper sheets carried in by the paper sheets stacked and stored in the storage space.

  The sheet processing apparatus of the present invention is formed in the wall portion of the storage unit, and a guide hole that moves in and out of the movable piece, and a guide piece that faces the movable piece and moves integrally with the movable piece. And a drive source for moving the movable piece in and out, and a control unit for controlling the drive source, and the control unit moves the movable piece to the storage space side by controlling the drive source. In this position, the guide hole closes the intrusion hole, and the conveyance mechanism stops the conveyance at a position where the rear end portion of the paper sheet faces the movable piece, and then moves the movable piece to the storage space. The movable piece is moved from the side to the carry-in space side so that the movable piece is submerged in the submerged / recessed hole, and then the movable piece is returned from the state submerged in the submerged / recessed hole so as to be positioned on the storage space side. It is also possible to adopt a configuration that performs operations

  According to this configuration, the control unit controls the drive source to close the intrusion hole with the guide piece at a position where the movable piece is moved to the storage space side, and After the paper sheet is conveyed to a position where the rear end portion in the conveyance direction faces the movable piece, the movable piece is moved from the storage space side to the carry-in space side, and the movable piece is submerged in the intrusion hole. In order to adopt a configuration in which a moving operation is performed to return the movable piece to the storage space side from the state in which the movable piece is immersed in the storage hole, the paper sheet is moved into the storage space. For example, when the paper sheets are stacked, the paper sheets are stacked in a stacked state while avoiding problems such as clogging due to the end of the paper sheets being caught in the intrusion hole. Stacking ends Kill.

  The paper sheet processing apparatus of the present invention can employ a configuration that includes a pair of contact members that sandwich the paper sheets stacked and stored in the storage space.

  According to the above configuration, when the movable piece is moved in and out by sandwiching the paper sheets stacked and stored in the storage space with the pair of abutting members, the transport direction of the paper sheets It becomes easy to hold in a state where the rear ends are aligned.

  In the paper sheet processing apparatus of the present invention, the paper sheet processing apparatus includes an insertion port into which the paper sheet is inserted, the storage portion is disposed at a position facing the movable piece, and is stacked between the movable piece. A pressing plate for holding the stored paper sheets is provided, and the pressing plate is moved in the direction of the storing portion from the movement of the paper sheets in the insertion port direction on the contact surface with the stacked and stored paper sheets. The structure which has a 1st control part with a large frictional force at the time of doing may be sufficient.

  According to said structure, when conveying the paper sheet inserted in the insertion port to a storage part, it can prevent that the lamination | stacking state of the paper sheet laminated | stacked and accommodated in the storage part is disturb | confused.

  In the paper sheet processing apparatus of the present invention, the movable piece is stacked and stored with the movable piece on the contact surface with the stacked sheets rather than the frictional force between the stacked sheets. The structure provided with the 2nd control part from which the frictional force between the left and right paper sheets becomes large may be sufficient.

  According to said structure, destabilization at the time of the accommodation of the paper sheets by the paper sheets laminated | stacked and accommodated in the accommodating part by the impact when a movable piece goes in and out with respect to carrying-in space shifts is prevented. be able to.

  According to the paper sheet processing apparatus of the present invention, even when the paper sheet is transported to a position deviated from the normal position, it can be stored on top of the previously stored paper sheet.

It is a perspective view which shows the installation state of the game media rental apparatus with which the banknote processing apparatus which concerns on Embodiment 1 was integrated. It is a perspective view of a bill processing device. It is a perspective view of the state which removed the front cover from the banknote processing apparatus of FIG. It is sectional drawing of a banknote processing apparatus, Comprising: It is a figure which shows the state in the middle of conveying the banknote received toward the accommodating part. It is the figure seen from the left side in FIG. 1 of a banknote processing apparatus. It is the figure seen from the right side in FIG. 1 of a banknote processing apparatus. It is a bottom view of a bill processing device. It is sectional drawing for demonstrating the operation | movement which laminates and accommodates the banknote conveyed in the accommodating part in the accommodating part. It is sectional drawing for demonstrating the operation | movement which collect | recovers the banknote laminated | stacked and accommodated in the accommodating part from an insertion port. It is a partial expanded sectional view of the vicinity of the stack gate, (a) shows the state where the stack gate is in the loading position, (b) shows the state where the stack gate is in the stacking position, (c) shows the stack gate being carried out The state in the position is shown. It is the perspective view which looked at the stack gate, the stack gate drive mechanism, and the pressing plate from the left side in FIG. It is the perspective view which looked at the press plate from the right side in FIG. FIG. 2 is a perspective view of an upper guide, an expansion mechanism, a pinch roller of a pair of conveying rollers, a variable mechanism, a cam plate, and a cam motor as viewed from the left side in FIG. 1. It is a figure which shows both surfaces of a cam board. (A) shows the relationship between the position of the engagement protrusion in the first cam groove when the cam plate is rotated in a state in which no banknote is stored in the storage section, and the relative distance between the drive roller and the pinch roller of the transport roller pair. (B) shows the relationship between the position of the engaging projection in the second cam groove and the opening width of the conveying path. It is a control block diagram of a banknote processing apparatus. It is a flowchart which shows the process sequence until the authenticity determination at the time of banknote money_receiving | payment. It is a flowchart which shows an overlap / shape check processing procedure. It is a flowchart which shows the process sequence which returns the banknote received. It is a flowchart which shows the process sequence which carries out lamination | stacking accommodation of the banknote determined to be a genuine note in a storage part. It is a flowchart which shows the process sequence which collect | recovers the banknote accommodated in the accommodating part from the insertion port. It is a perspective view of the banknote processing apparatus which concerns on Embodiment 2. FIG. It is a perspective view of the state which removed the left cover from the banknote processing apparatus of FIG. It is a disassembled perspective view of a banknote processing apparatus. It is a principal part perspective view of a banknote processing apparatus. It is a perspective view of the state where the right cover was removed from the bill processing device. It is explanatory drawing of a press board. It is the side view seen from the upper direction of a press board. It is a perspective view of a safety mechanism. It is explanatory drawing which shows the state by which the pinch roller was decomposed | disassembled. It is a perspective view of a cam board. It is explanatory drawing which shows the state of the cam groove of the one surface of a cam board. It is explanatory drawing which shows the state of the cam groove of the other surface of a cam board. It is explanatory drawing which shows operation | movement of each part based on the angular position of a cam board. It is explanatory drawing which shows operation | movement of each part by an expansion mechanism. It is explanatory drawing which shows operation | movement of each part by an expansion mechanism. It is explanatory drawing which shows operation | movement of each part by an expansion mechanism. It is explanatory drawing which shows operation | movement of a 1st arm. It is explanatory drawing which shows operation | movement of a 1st arm. It is explanatory drawing which shows operation | movement of a 1st arm. It is a flowchart which shows the process sequence until the authenticity determination at the time of banknote money_receiving | payment. It is a flowchart which shows the process sequence which carries out lamination | stacking accommodation of the banknote determined to be a genuine note in a storage part. It is a flowchart which shows the process sequence which returns the banknote received. It is a flowchart which shows the process sequence which returns the banknote received. It is a flowchart which shows an overlap / shape check processing procedure. It is explanatory drawing of an overlap check. It is explanatory drawing of a shape check. It is a flowchart of an authenticity determination process. It is a flowchart of a watermark image authenticity determination process. It is a flowchart of a watermark image authenticity determination process (light / dark reversal).

(Embodiment 1)
Hereinafter, the banknote processing apparatus 1 which is one Embodiment of the paper sheet processing apparatus of this invention is demonstrated. As shown in FIG. 1, the banknote handling apparatus 1 according to the first embodiment is incorporated into a game medium lending device (game machine platform machine) 200 installed between various game machines 201 such as a slot machine, for example. It is. The game medium lending device 200 includes other devices (for example, a coin processing device, a recording medium processing device, a power supply device, and a display device) on the upper side or the lower side of the banknote processing device 1. When the banknote M is inserted and the validity of the inserted banknote is determined, a gaming medium lending process corresponding to the banknote value or a writing process to a recording medium such as an IC card is performed. The banknote handling apparatus 1 has an insertion slot 2 into which a banknote M is inserted from the short side, and is incorporated in the game medium lending apparatus 200 so that the insertion slot 2 is oriented vertically. In addition, the kind of banknote deposited by the banknote processing apparatus 1 is not one type, but can deposit a plurality of types of banknotes having different lengths in the longitudinal direction.

(Schematic configuration of the banknote handling apparatus 1)
As shown in FIGS. 2 and 3, the banknote handling apparatus 1 has a frame 10 to which various members are assembled, a rectangular hole 3 a that exposes the insertion slot 2, and is arranged so as to cover the front wall 11 of the frame 10. And a front cover 3. Hereinafter, the banknote processing apparatus 1 is demonstrated using the front-back direction shown in FIG. 2 and FIG. 3, the left-right direction, and the up-down direction. The front wall 11 of the frame 10 is formed with a recess 11a having an opening on the left side. As shown in FIG. 4, the frame 10 has a wall portion 12 extending rearward from the right edge of the recess 11 a, an upper and lower wall 13 extending rearward from the upper and lower edges of the recess 11 a, and upper and lower walls 13 and rear ends of the wall portion 12. And a connected rear wall 14.

  The banknote handling apparatus 1 is provided behind the transport path 4 through which the banknote M inserted into the insertion slot 2 passes, and stores a plurality of banknotes M in the thickness direction (left-right direction). ) Possible storage part 5. The conveyance path 4 and the storage unit 5 are formed between the upper and lower walls 13.

  The banknote handling apparatus 1 according to the present embodiment is capable of transporting banknotes M inserted one by one into the insertion slot 2 to the storage unit 5, and a plurality of banknotes (or one sheet) stacked and stored in the storage unit 5. Bill) can be conveyed toward the insertion slot 2 and discharged from the insertion slot 2. Therefore, since the banknote accommodated in the storage part 5 can be collect | recovered from the insertion port 2, compared with the case where a banknote is collect | recovered from parts other than the insertion port 2, the efficiency of the collection | recovery operation | work of a banknote can be improved. Moreover, since the insertion port 2 into which a banknote is inserted serves as a discharge port for discharging the banknote accommodated in the storage part 5, compared with the case where an insertion port and a discharge port are provided separately, the thickness of the apparatus ( (Width in the left-right direction) can be reduced, and the apparatus can be miniaturized. Moreover, the banknote processing apparatus 1 of this embodiment conveys the banknote M inserted in the insertion port 2 so that conveyance may be stopped in the middle of conveying toward the accommodating part 5, and it may return to the insertion port 2. Is also possible.

(Conveying path 4 and insertion slot 2)
An in / out hole 12 a is formed at a position in front of the center portion in the front-rear direction of the wall portion 12. The conveyance path 4 is formed by a portion of the wall portion 12 and the upper and lower walls 13 that is on the front side of the intrusion hole 12a and an upper guide 20 that is disposed on the left side of the front portion of the wall portion 12 with respect to the intrusion hole 12a. Yes. In addition, the conveyance path 4 includes a reading unit 21 that can read the image information of the banknote, a pair of insertion conveyance rollers 22 and 23 that can clamp the banknote in the thickness direction, and a banknote detection sensor 24 that detects the presence or absence of the banknote M. , 25 are arranged.

  The upper guide 20 is a substantially plate-shaped member as shown in FIG. 13, and the front end portion thereof is disposed inside the concave portion 11 a of the front wall 11. The insertion port 2 is configured by a gap between the recess 11 a and the front end portion of the upper guide 20.

  As shown in FIG. 5, the front-rear center portions of the upper and lower ends of the upper guide 20 protrude in the vertical direction, and the protruding portions are arranged inside the slits 13 b formed in the upper and lower walls 13. A guide shaft 15 that is fixed to the frame 10 and extends in the left-right direction passes therethrough. Therefore, the upper guide 20 is movable in the left-right direction (the bill thickness direction) along the guide shaft 15. The upper guide 20 is driven in the left-right direction by an expansion mechanism 8 described later.

  As shown in FIG. 21, the reading unit 21 is arranged at the center in the front-rear direction of the transport path 4 and is configured to be able to read almost the entire area in the width direction of the bill passing through the transport path 4. The reading unit 21 of the present embodiment is an image sensor that can read the reflected and transmitted images of banknotes, and includes a light receiving / emitting unit 21 a including a light receiving unit and a reflection light emitting unit installed on the wall 12, and an upper guide 20. And a light-emitting portion 21b for transmission installed in the. The light emitting / receiving unit 21 a is disposed substantially flush with the left surface of the wall portion 12, and the transmissive light emitting portion 21 b is disposed substantially flush with the right surface of the upper guide 20. The light emitting / receiving unit 21a and the light emitting unit for transmission 21b of the light emitting / receiving unit 21a can irradiate visible light and infrared light. The reading unit 21 irradiates light from both sides of the banknote M arranged in the transport path 4 and reads the image information of the banknote by detecting the transmitted light and the reflected light by the light receiving unit. The image information of the banknote read by the reading unit 21 is transmitted to the control circuit board 100 described later, and compared with the data of the genuine note stored in advance, the authenticity of the banknote is determined. The reading unit 21 may have a configuration other than the above as long as it is an image sensor.

  The first banknote detection sensor 24 is disposed in the vicinity of the insertion slot 2, and the second banknote detection sensor 25 is disposed in the vicinity of the rear end of the transport path 4. The first banknote detection sensor 24 is a retroreflective photosensor, and includes a sensor unit 24 a installed on the wall 12 and a prism unit 24 b installed on the upper guide 20. The second banknote detection sensor 25 is a retroreflective photosensor similar to the first banknote detection sensor 24, and includes a sensor section 25a installed on the wall section 12 and a prism section 25b installed on the upper guide 20. It is configured with. Note that the banknote detection sensors 24 and 25 may be sensors other than the above as long as the presence or absence of the banknote M can be detected.

  The insertion conveyance roller pair 22 is disposed between the first banknote detection sensor 24 and the reading unit 21, and the insertion conveyance roller pair 23 is disposed between the reading unit 21 and the second banknote detection sensor 25. Yes. The insertion conveyance roller pair 22 includes a driving roller 22a disposed on the wall portion 12 side and a pinch roller 22b disposed on the upper guide 20 side, and is disposed at two positions with an interval in the vertical direction. Like the insertion conveyance roller pair 22, the insertion conveyance roller pair 23 includes a driving roller 23a disposed on the wall 12 side and a pinch roller 23b disposed on the upper guide 20 side, and is spaced apart in the vertical direction. 2 places.

  The drive rollers 22 a and 23 a are fixed to a drive shaft 26 that is rotatably supported by the frame 10, and are disposed so as to slightly protrude from the left surface of the wall portion 12. The drive shaft 26 is driven by a transport mechanism 6 described later. The pinch rollers 22 b and 23 b are fixed to a shaft that is rotatably supported by the upper guide 20, and are disposed so as to slightly protrude from the right surface of the upper guide 20. The outer peripheral side portions of the drive rollers 22a and 23a are formed of a material having a high coefficient of friction with the bill.

  When the upper guide 20 is driven in the left-right direction by the expansion mechanism 8, the light-emitting portion 21 b for transmission, the prism portions 24 b and 25 b, and the pinch rollers 22 b and 23 b installed on the upper guide 20 also move, and the transport path 4 The opening width (width in the left-right direction) changes.

  During normal times (when banknotes are deposited), the upper guide 20 is closest to the wall portion 12, and the opening width of the transport path 4 is the smallest. At this time, the pinch roller 23b and the driving roller 23a are in contact with each other with an appropriate pressing force. In this state, as shown in FIG. 4, by rotating the drive shaft 26 and rotating the drive rollers 22 a and 23 a, one banknote M inserted into the insertion slot 2 is inserted by the insertion conveyance roller pair 22 and 23. It can be conveyed toward the storage unit 5.

  Further, when the banknotes M stored in the storage unit 5 are collected from the insertion slot 2, as shown in FIGS. 9B and 9C, the upper guide 20 is separated from the wall unit 12, The opening width of the conveyance path 4 is expanded. Therefore, even if the number of banknotes stored in the storage unit 5 is large, the banknotes can be collected from the same transport path 4 without the upper guide 20 being in the way.

  When the opening width of the transport path 4 is expanded and then returned to the original position, the relative distance between the transmitting light emitting part 21b of the reading unit 21 and the light receiving part of the light receiving / emitting unit 21a may be slightly different from that before expansion. is there. In the conventional optical sensor, if the relative distance between the light receiving unit and the light emitting unit changes even slightly, an error is likely to occur in the read data. By taking the depth, even if the relative distance between the light-emitting part 21b for transmission and the light-receiving part (21a) is slightly changed, an error is not easily generated in the read data.

  As described above, since the insertion port 2 is formed by the gap between the recess 11a of the front wall 11 and the front end portion of the upper guide 20, the upper guide 20 moves in the left-right direction, thereby opening the insertion port 2. The width (lateral width) changes. That is, the opening width of the insertion slot 2 is normally the minimum, similar to the opening width of the conveyance path 4, and is expanded when the banknote M stored in the storage unit 5 is collected from the insertion slot 2. . Since the opening width of the insertion slot 2 is narrow at the normal time, it is possible to prevent an illegal act of extracting a banknote from the insertion slot 2. Further, when the banknotes stored in the storage unit 5 are collected, the insertion port 2 expands, so that even if the number of banknotes stored in the storage unit 5 is large, it can be collected from the insertion port 2. .

  A gap cover 27 is attached to the front end of the upper guide 20 in order to close the gap between the rectangular hole 3 a of the front cover 3 and the upper guide 20 as the upper guide 20 moves. The gap cover 27 is rotatably connected to the upper guide 20. Further, the gap cover 27 has an engaging protrusion 27 a that engages with a guide groove 13 c formed on the upper and lower walls 13 of the frame 10. At normal times (when the opening width of the insertion slot 2 is the smallest), the engagement protrusion 27a is engaged with the front end portion of the guide groove 13c, and the gap cover 27 is formed between the front end portion of the upper guide 20 and the front cover. 3 is arranged so as to close the gap with the left edge of the rectangular hole 3a. As shown in FIG. 9B, when the upper guide 20 is moved away from the wall portion 12, the engagement protrusion 27a moves along the guide groove 13c, and the gap cover 27 rotates.

  A protrusion 20a projecting forward is formed at the lower end of the upper guide 20, and an upper guide detection sensor 28 capable of detecting the protrusion 20a is installed on the frame 10 (see FIG. 5). The upper guide detection sensor 28 is for monitoring an illegal act of moving the upper guide 20 in the expansion direction. The upper guide detection sensor 28 is a transmissive photosensor, and detects the protrusion 20a when the upper guide 20 is closest to the wall portion 12 (when the opening width of the transport path 4 is the smallest), and the upper guide detection sensor 28 detects the protrusion 20a. The guide 20 is installed so as not to detect the protrusion 20a when the guide 20 is separated from the wall 12 by a predetermined distance or more.

(Storage part 5)
The storage unit 5 is formed behind the front edge of the dropout hole 12a and has a storage space 5a in which bills are stacked and stored. The storage portion 5 is formed by a portion of the wall portion 12 and the upper and lower walls 13 that is on the rear side of the intrusion hole 12 a, the rear wall 14, and a storage lid 30 that is disposed facing the left side of the wall portion 12. Further, the storage unit 5 is provided with a stack gate 31, a pressing plate 32, a transport roller pair 33 capable of sandwiching bills in the thickness direction, and an empty sensor 34 for detecting the presence or absence of bills in the storage space 5a. ing.

  The storage lid 30 is rotatably connected to the vicinity of the rear end of the upper and lower walls 13 and can be manually opened and closed. The storage lid 30 is opened at the time of maintenance or when the storage unit 5 is jammed.

  The empty sensor 34 is disposed at a position where the vicinity of the rear end of the banknote stored in the storage unit 5 can be detected. More specifically, the empty sensor 34 is a position where the banknote is not detected before the rear end (front end) in the transport direction of the longest banknote deposited reaches an escrow position described later, and the storage unit 5 is arranged at a position where the longest banknote stored in 5 can be detected. The empty sensor 34 is a retro-reflective photosensor, and includes a sensor unit 34 a installed on the wall 12 and a prism unit 34 b installed on the storage lid 30. The empty sensor 34 may be a sensor other than the above as long as the presence or absence of the banknote M can be detected.

  The conveyance roller pair 33 includes a driving roller 33a disposed on the wall 12 side and a pinch roller 33b disposed on the storage lid 30 side, and is disposed at two positions with a space in the vertical direction. The separation distance between the insertion slot 2 and the transport roller pair 33 is shorter than the length in the banknote transport direction.

  The drive roller 33 a is fixed to a drive shaft 35 that is rotatably supported by the frame 10, and is disposed so as to slightly protrude from the left surface of the wall portion 12. The drive shaft 35 is driven by a transport mechanism 6 described later. The pinch roller 33 b is fixed to a support shaft 36 inserted through a slit 13 d formed in the upper and lower walls 13. The support shaft 36 is driven in the left-right direction by a variable mechanism 7 described later. When the support shaft 36 is farthest from the drive shaft 35, the pinch roller 33 b is exposed to the outside from the opening formed in the storage lid 30. The friction coefficient with respect to the banknote of the outer peripheral surface of the drive roller 33a is larger than the friction coefficient between banknotes. The friction coefficient of the outer peripheral surface of the pinch roller 33b may be larger or smaller than the friction coefficient between bills.

  Both front and rear edges of the intrusion hole 12a are formed in an uneven shape when viewed from the left-right direction (see FIG. 6). Moreover, as shown in FIG. 10, both front and rear edges of the lug hole 12a are formed in a chamfered shape. In addition, the upper and lower walls 13 are formed with slits 13a communicating with the appearance holes 12a. The slit 13a extends from the vicinity of the left end of the upper and lower wall portions to the right end. Further, the rear end of the upper guide 20 is formed to have substantially the same concavo-convex shape as the front edge of the intrusion hole 12a when viewed from the left-right direction (see FIG. 13).

  The upper and lower ends of the stack gate 31 are disposed inside the slit 13a, and are formed so as to be able to be inserted in the left and right holes 12a. The stack gate 31 is driven in the left-right direction by a stack gate drive mechanism 9 described later.

  As shown in FIG. 11, the stack gate 31 includes a stack portion 37 extending in the up-down direction (a direction orthogonal to the bill conveyance direction), a guide portion 38 disposed to be opposed to the right side of the stack portion 37 with a space therebetween, It has two connection parts 39 which connect the stack part 37 and the guide part 38 at both upper and lower ends. The connecting portion 39 is connected to the stack gate driving mechanism 9.

  In the stack portion 37, a plurality of convex portions 37a protruding forward are formed at equal intervals in the vertical direction. The convex portion 37a is formed at a position corresponding to the concave portion of the appearing hole 12a, and the front end of the stack portion 37 has a shape along the front edge of the appearing hole 12a when viewed from the left-right direction.

  The rear half of the right surface of the stack portion 37 (the surface facing the guide portion 38) protrudes to the right side, and has a shape in which the front and rear ends of the protruding portion are chamfered. Also, the right end of the front end of the stack portion 37 where the convex portion 37a is not formed has a chamfered shape. Further, the left rear end of the stack portion 37 has a chamfered shape.

  The guide portion 38 has a configuration in which straight portions 38a and wide portions 38b having a width in the front-rear direction larger than the straight portions 38a are alternately arranged in the vertical direction. The wide portion 38b is formed at a position corresponding to the concave portion of the intrusion hole 12a, and both front and rear ends of the guide portion 38 have a shape along the intrusion hole 12a when viewed from the left-right direction.

  Further, the substantially half of the rear side of the left side of the straight portion 38a (the surface facing the stack portion 37) protrudes to the left side, and the front and rear ends of the protruding portion are chamfered. The front end surface of the projecting portion is opposed to the front end surface of the projecting portion formed on the rear half of the right surface of the stack portion 37. Further, the left front end of the straight portion 38a has a chamfered shape. Further, the front and rear ends of the left surface of the wide portion 38b are chamfered.

  The stack gate 31 is moved to a position where the left surface of the guide portion 38 is substantially flush with the left surface of the wall portion 12 as shown in FIG. As shown in FIG. 10B, the stack portion 37 is driven over a position (hereinafter referred to as a stack position) where the stack portion 37 is immersed in the intrusion hole 12a. Therefore, the stack part 37 moves back and forth between the storage space 5 a and the space on the right side of the wall part 12. That is, the stack part 37 can be moved in and out of the storage space 5a. A space formed between the guide portion 38 and the stack portion 37 when the stack gate 31 is in the loading position is referred to as a loading space 31a. Also, as shown in FIG. 10C, the position of the stack gate 31 when the left surface of the stack portion 37 is substantially flush with the left surface of the wall portion 12 is referred to as a carry-out position.

  Of the two connecting portions 39 of the stack gate 31, the lower connecting portion 39 is provided with an L-shaped protrusion 39a protruding leftward and extending downward (see FIG. 11). Is provided with a stack gate detection sensor 40 capable of detecting the tip of the protrusion 39a (see FIG. 5). The stack gate detection sensor 40 is a transmissive photosensor that detects the protrusion 39a when the stack gate 31 is in the loading position, and the protrusion 39a when the stack gate 31 is separated from the loading position to the right by a predetermined distance or more. It is installed not to detect. The stack gate 31 is driven and controlled based on the detection result of the stack gate detection sensor 40.

  The pressing plate 32 is disposed opposite to the left side of the stack portion 37. The upper and lower ends of the pressing plate 32 are disposed inside the slit 13 a formed in the upper and lower walls 13. The other end of the torsion coil spring 41 whose one end is locked to the frame 10 is in contact with the upper and lower ends of the pressing plate 32, and the pressing plate 32 is urged to the right by the torsion coil spring 41.

  As shown in FIGS. 7 and 12, on the right surface of the pressing plate 32 (the surface facing the stack portion 37), a plurality of convex portions 32a protruding rightward and extending along the front-rear direction are equally spaced in the vertical direction. Is formed. The convex portion 32 a is formed at a position facing the convex portion 37 a of the stack portion 37.

  The front end portion of the pressing plate 32 is disposed on the left side of the rear end portion of the upper guide 20. Therefore, even if the pressing plate 32 is urged to the right by the torsion coil spring 41, it does not move further to the right by contacting the upper guide 20. Further, when the upper guide 20 moves in the direction of extending the conveyance path 4, the pressing plate 32 moves while being pressed by the upper guide 20.

(Transport mechanism 6)
The transport mechanism 6 rotates the drive shafts 26 and 35 to transport the banknote M sandwiched between the insertion transport roller pairs 22 and 23 or the transport roller pair 33. As shown in FIG. 7, the transport mechanism 6 includes pulleys 50, 51, 52 fixed to lower ends of the drive shafts 26, 35 of the drive rollers 22a, 23a, 33a, and a transport motor 53 (FIGS. 3 and 5). Reference), a pulley 54 fixed to the output shaft of the conveyance motor 53, a plurality of tension pulleys 55, and a belt 56 stretched over the pulleys 50 to 52, 54, 55. The transport motor 53 can be rotated forward and backward. When the transport motor 53 is driven forward, the drive rollers 22a, 23a, 33a rotate in the direction of transporting the bills M backward, and when the transport motor 53 is driven in reverse rotation. The drive rollers 22a, 23a, and 33a rotate in the direction in which the banknote M is conveyed forward.

(Stacked gate drive mechanism 9)
The stack gate drive mechanism 9 is for driving the stack gate 31 in the left-right direction. The stack gate drive mechanism 9 has two stack arms 60 respectively connected to the two connecting portions 39 of the stack gate 31, two eccentric cams 61, a drive shaft 62, and a stack gate motor 64 (see FIG. 11).

  The two stack arms 60 are arranged on both upper and lower sides of the upper and lower walls 13. The stack arm 60 is formed in a bifurcated shape, and is pivotally connected to a shaft 16 provided in the frame 10 at a bifurcated base. One end portion of the bifurcated portion of the stack arm 60 is rotatably connected to the connecting portion 39 of the stack gate 31. Further, the opposed surfaces of the bifurcated portion of the stack arm 60 are formed in parallel.

  The eccentric cam 61 is disposed between the forked portions of the stack arm 60. The two eccentric cams 61 are fixed to a drive shaft 62 that extends in the vertical direction. The centers of the two eccentric cams 61 are located on the same axis and are eccentric with respect to the center of the drive shaft 62.

  The drive shaft 62 is rotatably supported by the frame 10 at both upper and lower ends. A gear 63 is fixed in the vicinity of the lower end of the drive shaft 62, and the gear 63 meshes with an output gear 65 fixed to the output shaft of the stack gate motor 64.

  When the stack gate motor 64 is driven, the drive shaft 62 rotates, the eccentric cam 61 rotates while pressing the stack arm 60, and accordingly, the stack arm 60 swings about the shaft 16 to stack. The stack gate 31 connected to the arm 60 moves in the left-right direction.

(Variable mechanism 7)
The variable mechanism 7 is for changing the relative distance between the pinch roller 33b and the drive roller 33a by moving the support shaft 36 (and the pinch roller 33b) in the left-right direction. The variable mechanism 7 is connected to a cam plate 90 to be described later, and the variable mechanism 7 operates by driving of a cam motor 94 that drives the cam plate 90. The variable mechanism 7 includes two arms 70 connected to upper and lower ends of the support shaft 36, two torsion coil springs 71, and a slide member 72 (see FIG. 13).

  The two arms 70 are disposed on both upper and lower sides of the upper and lower walls 13. The arm 70 is formed in a substantially L shape when viewed from the left-right direction. The arm 70 is rotatably connected to a shaft 17 provided in the frame 10 in the vicinity of the L-shaped corner. The support shaft 36 is rotatably connected to one of the L-shaped tips of the arm 70, and the other tip is in contact with the front surface of the slide member 72.

  The two torsion coil springs 71 are disposed between the arm 70 and the upper and lower walls 13, one end is locked to the upper and lower walls 13, and the other end is substantially intermediate between the shaft 17 and the support shaft 36 in the arm 70. Locked in position. The arm 70 is biased by the torsion coil spring 71 in a direction in which the slide member 72 is pressed (a direction in which the support shaft 36 is moved to the right).

  The slide member 72 is disposed on the right side of the wall portion 12 (see FIG. 6). Guide shafts 18 extending in the front-rear direction fixed to the frame 10 pass through both upper and lower ends of the slide member 72, and the slide member 72 is movable in the front-rear direction along the guide shaft 18. .

  An engagement protrusion 72 a is formed at the center in the vertical direction of the left surface (the surface on the wall portion 12 side) of the slide member 72. The engagement protrusion 72 a is engaged with a first cam groove 91 formed on the right surface of the cam plate 90 disposed on the left side of the slide member 72.

  The cam plate 90 has a disk shape and is supported at the center thereof so as to be rotatable on a shaft provided on the frame 10. A belt 93 is wound around the outer periphery of the cam plate 90, and the belt 93 is also wound around a pulley 95 fixed to the output shaft of the cam motor 94. Thus, the cam plate 90 is driven to rotate.

  As shown in FIG. 14A, the first cam groove 91 is formed in an annular shape, and is connected to the large diameter portion 91a having a constant diameter and both sides of the large diameter portion 91a, and the diameter continuously changes. The two intermediate portions 91b and the small-diameter portion 91c having a constant diameter and smaller than the diameter of the large-diameter portion 91a. The angle of the large diameter portion 91a is 200 degrees, the angle of the two intermediate portions 91b is 70 degrees, and the angle of the small diameter portion 91c is 20 degrees. In addition, the angle of each groove part 91a-91c is not limited to the value mentioned above.

  The engagement protrusion 72a of the slide member 72 is engaged with a portion of the first cam groove 91 that is behind the center of the cam plate 90 and has the same height as the center of the cam plate 90 in the vertical direction. .

  When the cam plate 90 rotates and the engagement protrusion 72a moves in the small diameter portion 91c, the distance between the engagement protrusion 72a and the center of the cam plate 90 is constant with the minimum value, and the slide member 72 is Stops at the foremost position. At this time, since the arm 70 is pressed against the slide member 72 by the torsion coil spring 71, the relative distance between the pinch roller 33b and the drive roller 33a is maximized as shown in FIG. 15A shows the position of the engagement protrusion 72a in the first cam groove A91 in a state in which no banknote is stored in the storage portion 5, and the relative distance between the centers of the pinch roller 33b and the drive roller 33a. It is a graph which shows a relationship, Comprising: The horizontal axis has shown the angle of 1st cam groove A91 on the basis of the circumferential direction center part of the small diameter part 91c. The position of the cam plate 90 when the engagement protrusion 72a is engaged with the small diameter portion 91c is referred to as a reference position, and the position of the pinch roller 33b at this time is referred to as a standby position.

  Further, when the engaging protrusion 72a moves in the large diameter portion 91a, the distance between the engaging protrusion 72a and the center of the cam plate 90 remains constant at the maximum value, and the slide member 72 is positioned at the rearmost position. Has stopped at. At this time, the arm 70 and the slide member 72 are separated from each other, and the pinch roller 33 b is pressed against the drive roller 33 a by the elastic force of the torsion coil spring 71. For this reason, in a state where no bill is stored in the storage unit 5, the relative distance between the centers of the pinch roller 33b and the drive roller 33a is minimum.

  Further, when the engagement protrusion 72a moves in the intermediate portion 91b in the direction toward the large diameter portion 91a, the separation distance between the engagement protrusion 72a and the center of the cam plate 90 gradually increases, and the slide member 72 moves backward. Moving. As a result, the arm 70 is rotated by the elastic force of the torsion coil spring 71, and accordingly, the support shaft 36 and the pinch roller 33b move to the right, and the relative distance between the pinch roller 33b and the drive roller 33a is reduced. In a state in which no banknote is stored in the storage portion 5, when the engagement protrusion 72a moves to the vicinity of the small diameter portion 91a, the pinch roller 33b contacts the drive roller 33a, and from there, the engagement protrusion 72a is further moved to the small diameter portion. When moved toward 91 a, the slide member 72 is separated from the arm 70, and the pinch roller 33 b is pressed against the drive roller 33 a by the elastic force of the torsion coil spring 71.

  Further, when the engagement protrusion 72a moves in the intermediate portion 91b in the direction toward the small diameter portion 91c, the separation distance between the engagement protrusion 72a and the center of the cam plate 90 gradually decreases, and the slide member 72 moves forward. To do. As a result, the arm 70 is pressed and rotated by the slide member 72, and accordingly, the support shaft 36 and the pinch roller 33b move to the left, and the relative distance between the pinch roller 33b and the drive roller 33a increases. In this way, the rotational movement of the cam plate 90 is converted into the horizontal movement of the support shaft 36 and the pinch roller 33b.

  A projection 72b extending rearward is formed at the rear end of the slide member 72, and a cam detection sensor 96 capable of detecting the tip of the projection 72b is installed on the frame 10 (see FIG. 6). . The cam detection sensor 96 is a transmissive photosensor, and is installed so as to detect the protrusion 72b when the cam plate 90 is at the reference position and not detect the protrusion 72b when the cam plate 90 is not at the reference position. ing. The cam plate 90 is driven and controlled based on the detection result of the cam detection sensor 96.

  Further, an L-shaped protrusion 70a is formed on the front end of the lower arm 70 of the two arms 70 so as to protrude downward and the front end extending forward. A detectable thickness detection sensor 97 is installed (see FIG. 5). The thickness detection sensor 97 is for detecting whether the thickness of the banknote stored in the storage unit 5 has reached a predetermined value (for example, the maximum thickness that can be stored). The thickness detection sensor 97 is a transmission type photosensor, and detects the protrusion 70a when the thickness of the banknote sandwiched between the transport roller pair 33 is equal to or greater than a predetermined value, and does not detect the protrusion 70a when the thickness is less than the predetermined value. It is installed as follows. The predetermined value is, for example, the thickness of about 50 banknotes.

  Here, the operation of the transport roller pair 33 and the stack gate 31 at the time of banknote deposit and banknote collection will be described. First, the operation when depositing banknotes will be described. During normal times (when banknotes are deposited), the cam plate 90 is disposed at the reference position, and the pinch roller 33b is disposed at the standby position as shown in FIG. Further, the stack gate 31 is disposed at the carry-in position, and the pressing plate 32 is pressed toward the stack portion 37 by the torsion coil spring 41.

  The banknote M inserted into the insertion slot 2 is carried into the storage unit 5 through the carry-in space 31a by the insertion conveyance roller pairs 22 and 23. When the rear end of the banknote M in the transport direction is transported to the position (escrow position) between the reading unit 21 and the second banknote detection sensor 25 by the pair of insertion transport rollers 22 and 23, the transport is temporarily stopped, and FIG. As shown to (a), after driving the pinch roller 33b to the drive roller 33a side and pinching a banknote by the conveyance roller pair 33, the drive roller 33a is rotated and the banknote M is conveyed by the conveyance roller pair 33. The holding force of the banknotes by the transport roller pair 33 at this time is set as follows according to the number of banknotes stored in the storage unit 5 stored in the RAM 103 described later.

  When the banknote M is carried into the storage section 5 in which the banknote M is not stored, the engagement protrusion 72a of the slide member 72 is engaged with the large diameter section 91a and the pinch roller is moved by the elastic force of the torsion coil spring 71. 33b is pressed against the driving roller 33a. That is, the elastic force of the torsion coil spring 71 becomes a clamping force for clamping the bill of the transport roller pair 33. The clamping force of the banknote by the conveyance roller pair 33 when the engagement protrusion 72a engages with the large diameter portion 91a is defined as Fa.

  When the banknote M is carried into the storage unit 5 in which the banknote M is already stored, the engagement protrusion 72a of the slide member 72 is an intermediate part 91b corresponding to the number of banknotes stored in the storage unit 5. The holding force of the banknotes by the transport roller pair 33 is set to a fixed holding force Fb smaller than the above-described holding force Fa. At this time, the relative distance between the pinch roller 33b and the drive roller 33a varies depending on the number of banknotes stored in the storage unit 5. The clamping force Fb is one sheet carried into the storage unit 5 without moving the banknote M already stored in the storage unit 5 (that is, without rotating the pinch roller 33b) when the drive roller 33a rotates. This value is such that only the bill M can be conveyed by the drive roller 33a. In this case, the frictional force between the driving roller 33a and the banknote is larger than the frictional force between the banknote being conveyed and the banknote adjacent thereto. Thereby, it is possible to further stack the banknotes carried into the storage unit 5 on the stacked banknotes while maintaining the stacked state of the plurality of banknotes already stored in the storage unit 5.

  As shown in FIG. 8B, the conveyance is stopped when the conveyance roller pair 33 conveys the bill M in the conveyance direction rear end to a position facing the stack portion 37. When the banknote M is carried into the storage section 5 in which the banknote M has already been stored, the cam plate 90 is rotated to a position where the engagement protrusion 72a of the slide member 72 is engaged with the large diameter section 91a. When driven, the pinch roller 33b is pressed against the drive roller 33a by the elastic force of the torsion coil spring 71, and the holding force of the bills by the conveying roller pair 33 is changed to the holding force Fa. At this time, the relative distance between the pinch roller 33b and the drive roller 33a differs depending on the thickness of the bills stored in the storage unit 5. Further, since the torsion angle of the torsion coil spring 71 varies depending on the thickness of the banknote stored in the storage unit 5, the clamping force Fa of the transport roller pair 33 varies depending on the thickness of the banknote stored in the storage unit 5. .

  Subsequently, as shown in FIG. 8C, the stack gate 31 is driven from the carry-in position to the stack position. At this time, when the pressing plate 32 moves to a position where it abuts on the upper guide 20 by the urging force of the torsion coil spring 41, the pressing plate 32 does not move further to the right, so that the pressing plate 32 and the stack portion 37 are separated. Therefore, the rear end portion in the transport direction of the banknote M carried in moves from the space between the stack portion 37 and the guide portion 38 over the stack portion 37 to the space between the stack portion 37 and the pressing plate 32. To do.

  Thereafter, as shown in FIG. 8D, the stack gate 31 is returned from the stack position to the carry-in position. By performing the above-described series of operations each time the banknote M is carried into the storage section 5, the banknote M can be stacked (stacked and stored) between the stack section 37 and the pressing plate 32 in the thickness direction. .

  As described above, in the present embodiment, the stack part 37 extending in the direction orthogonal to the banknote transport direction is moved in and out of the storage space 5a, so that the banknotes at the position facing the stack part 37 are transported. Since the rear end of the direction is moved to the storage space 5a side and the bills are stacked and stored in the storage space 5a, even if the bills carried into the storage portion 5 are shifted in the width direction from the normal position. Even so, it can be stacked and accommodated in a state in which the rear ends of the banknotes are aligned.

  Further, when the stack portion 37 is moved into and out of the storage space 5a, since the banknotes are sandwiched by the transporting roller pair 33 with the clamping force Fa, the banknotes stored in advance and the banknotes carried in are transported in the transport direction. It can be held with the rear end aligned. Furthermore, since the rear ends of both the left and right sides of the stack portion 37 are chamfered, when the stack portion 37 is moved in and out, the stack portion 37 can be smoothly moved to the rear end portion in the transport direction of the banknotes carried in. You can get over.

  Further, when the banknote is carried into the storage unit 5, the stack unit 37 is disposed at a position for securing the carry-in space 31 a, thereby preventing the banknote from being carried in by the banknote M already stored in the storage unit 5. Can be avoided. Moreover, since the guide part 38 is arrange | positioned in the position which blocks the in / out hole 12a when carrying in a banknote in the accommodating part 5, it can prevent that an edge part of a banknote gets caught in the in / out hole 12a, etc., and clogging generate | occur | produces. .

  Further, both front and rear edges of the intrusion hole 12a and both front and rear ends of the guide portion 38 are formed in a concavo-convex shape to be fitted to each other, and the rear end of the upper guide 20 and the front end of the stack portion 37 are fitted to each other. It is possible to prevent the edge of the banknote from being caught on the edge of the dropout hole 12a, the rear end of the upper guide 20 or the stack gate 31 when the banknote is carried into the storage section 5 because it is formed in an uneven shape. It is possible to prevent clogging.

  Next, the operation of the transport roller pair 33 and the stack gate 31 during bill collection will be described. When collecting a plurality of banknotes M stacked and stored in the storage unit 5 from the insertion slot 2, first, as shown in FIGS. 9 (a) and 9 (b), the stack gate 31 is unloaded from the loading position. The cam plate 90 is rotationally driven to a position where the engagement protrusion 72a of the slide member 72 is engaged with the large diameter portion 91a, and the pinch roller 33b is driven by the elastic force of the torsion coil spring 71. The holding force Fa of the bills by the pair of transport rollers 33 is set to the holding force Fa. As described above, the clamping force Fa depends on the twist angle of the torsion coil spring 71 and varies depending on the thickness of the banknotes stored in the storage unit 5. Further, the relative distance between the pinch roller 33 b and the driving roller 33 a varies depending on the thickness of the bills stored in the storage unit 5.

  Thereafter, as shown in FIG. 9C, the driving roller 33a is driven to rotate in the direction opposite to that at the time of inserting the banknote, so that the banknote M sandwiched between the transport roller pair 33 is transported toward the insertion slot 2. . At this time, the pinch roller 33b is also rotated by the conveyed banknote, and the frictional force between the conveyance roller pair 33 and the banknote is smaller than the frictional force between the banknotes. Therefore, a plurality of banknotes can be sandwiched and transported by the transport roller pair 33 without slipping between the banknotes. As a result, it is possible to improve the efficiency of banknote collection work.

  As described above, since the separation distance between the insertion slot 2 and the transport roller pair 33 is set to be shorter than the length in the banknote transport direction, the banknotes stored in the storage unit 5 are inserted only by the transport roller pair 33. It can be conveyed to a position protruding from the mouth 2.

  In addition, since the front edge of the in / out hole 12a and the front edge of the stack part 37 are formed in a concavo-convex shape that fits each other, the edge of the banknote is at the edge of the in / out hole 12a or the stack part 37 when collecting banknotes. Can be prevented from being caught, and clogging can be prevented.

  In addition, from the viewpoint of reducing the thickness (width in the left-right direction) of the device 1, it is preferable to reduce the number of banknotes that can be stored in the storage unit 5, but as the number of sheets that can be stored decreases, the storage unit 5 The maximum number of sheets that can be accommodated may be reached frequently, and it is necessary to perform the collection operation many times during the picture business. It preferably has a certain thickness. Thereby, it is not necessary to interrupt the game of the gaming machine 201 when collecting banknotes, or even if the game is interrupted, the interruption time can be shortened.

(Expansion mechanism 8)
The expansion mechanism 8 is for driving the upper guide 20 in the left-right direction. The expansion mechanism 8 is connected to the cam plate 90, and the expansion mechanism 8 operates by driving the cam motor 94. The expansion mechanism 8 includes two arms 80 connected to the upper and lower ends of the upper guide 20, two connection members 81, two coil springs 82, and a slide member 83 (see FIG. 13).

  The two arms 80 are disposed on both upper and lower sides of the upper and lower walls 13. The arm 80 is formed in a substantially L shape when viewed from the left-right direction. The arm 80 is rotatably connected to a shaft 19 provided on the frame 10 in the vicinity of the L-shaped corner. One end portion of the L-shape of the arm 80 is rotatably connected to the upper guide 20, and the other end portion is rotatably connected to the front end portion of the connecting member 81. The connecting member 81 is attached to the guide shaft 18 so as to be movable along the guide shaft 18.

  The slide member 83 is disposed behind the connecting member 81. The guide shaft 18 penetrates through both the upper and lower ends of the slide member 83, and the slide member 83 can move in the front-rear direction along the guide shaft 18. Both end portions of the coil spring 82 are connected to a connecting member 81 and a slide member 83. The connecting member 81 is urged toward the slide member 83 by a coil spring 82.

  The slide member 83 is disposed between the cam plate 90 and the wall portion 12, and an engagement protrusion 83 a is formed at the center in the vertical direction of the right surface (the surface on the cam plate 90 side) of the slide member 83. Yes. The engagement protrusion 83a is engaged with a second cam groove A92 formed on the left surface of the cam plate 90. As shown in FIG. 14B, the second cam groove A92 is formed in an annular shape, and is connected to the small diameter portion 92a having a constant diameter and both sides of the small diameter portion 92a. One intermediate portion 92b and a large-diameter portion 92c having a constant diameter and larger than the diameter of the small-diameter portion 92a. The angle of the small diameter portion 92a is 200 degrees, the angle of the two middle portions 92b is 70 degrees, and the angle of the large diameter portion 92c is 20 degrees. The large diameter portion 92c of the second cam groove A92 is formed on the back surface at a position shifted by 180 degrees from the small diameter portion 91c of the first cam groove A91. In addition, the angle of each groove part 92a-92c is not limited to the value mentioned above.

  The engagement protrusion 83a of the slide member 83 is engaged with a portion of the second cam groove A92 that is in front of the center of the cam plate 90 and has the same height as the center of the cam plate 90 in the vertical direction.

  When the cam plate 90 rotates and the engagement protrusion 83a moves in the small diameter portion 92a, the distance between the engagement protrusion 83a and the center of the cam plate 90 is constant with the minimum value, and the slide member 83 is The upper guide 20 is disposed on the rightmost side, and the opening width of the transport path 4 (and the insertion port 2) is minimized as shown in FIG. 15B. At this time, the connecting member 81 and the slide member 83 are separated from each other, and the pinch roller 23b is pressed against the drive roller 23a by the elastic force of the extended coil spring 82. FIG. 15B is a graph showing the relationship between the position of the engagement protrusion 83a in the second cam groove A92 and the opening width of the transport path 4, and the horizontal axis is the circumferential direction of the small diameter portion 92a. The angle of 2nd cam groove A92 on the basis of the center part is shown.

  Further, when the engagement protrusion 83a moves in the large diameter portion 92c, the separation distance between the engagement protrusion 83a and the center of the cam plate 90 is constant at the maximum value, and the slide member 83 is at the frontmost position. The upper guide 20 is disposed on the leftmost side, and the opening width of the transport path 4 (and the insertion port 2) is maximized.

  Further, when the engaging protrusion 83a moves in the intermediate portion 92b in the direction toward the large diameter portion 92c, the separation distance between the engaging protrusion 83a and the center of the cam plate 90 gradually increases, and the slide member 83 moves forward. Moving. As a result, the connecting member 81 is pushed forward by the slide member 83 and the arm 80 is rotated, and accordingly, the upper guide 20 moves to the left, and the opening width of the transport path 4 (and the insertion port 2). Becomes larger.

  Further, when the engagement protrusion 83a moves in the intermediate portion 92b in the direction toward the small diameter portion 92a, the separation distance between the engagement protrusion 83a and the center of the cam plate 90 gradually decreases, and the slide member 83 moves backward. To do. As a result, the connecting member 81 is moved backward integrally with the slide member 83 by the elastic force of the coil spring 82, the arm 80 is rotated, and accordingly, the upper guide 20 is moved in the right direction, and the conveying path. The opening width of 4 (and the insertion port 2) is reduced. When the engaging protrusion 83a moves to the vicinity of the small diameter portion 92a, the pinch roller 23b comes into contact with the driving roller 23a, and when the engaging protrusion 83a is further moved toward the small diameter portion 92a, the coil spring 82 is resisted. The slide member 83 is separated from the connecting member 81, and the pinch roller 23b is pressed against the drive roller 23a by the elastic force of the extended coil spring 82. As described above, the rotational motion of the cam plate 90 is converted into the lateral motion of the upper guide 20.

  When the engaging protrusion 72a of the variable mechanism 7 is engaged with the small diameter portion 91c, the engaging protrusion 83a of the expansion mechanism 8 is engaged with the circumferential central portion of the small diameter portion 92a. Therefore, at the normal time, the opening distance of the transport path 4 (and the insertion port 2) can be minimized while maximizing the relative distance between the pinch roller 33b and the driving roller 33a.

  When the engagement protrusion 72a of the variable mechanism 7 moves in the intermediate portion 91b and the relative distance between the pinch roller 33b and the drive roller 33a changes, the engagement protrusion 83a of the expansion mechanism 8 engages with the small diameter portion 92a. The opening width of the conveyance path 4 remains the minimum value and does not change. Therefore, after the banknotes are carried into the storage unit 5 by the insertion conveyance roller pairs 22 and 23, the pinch roller 33 b is moved to the driving roller 33 a side while maintaining the opening width of the conveyance path 4 to the minimum, and the conveyance roller pair 33. Bills can be pinched.

  Further, when the engagement protrusion 83a of the expansion mechanism 8 is engaged with the intermediate portion 92b and the large diameter portion 92c, the engagement protrusion 72a of the variable mechanism 7 is engaged with the central portion in the circumferential direction of the large diameter portion 91a. Therefore, when the banknotes stored in the storage unit 5 are collected from the insertion slot 2, the pinch roller 33 b is moved to the drive roller 33 a side while maximizing the opening width of the transport path 4, and the banknotes are collected by the transport roller pair 33. Can be pinched.

  In this embodiment, since the expansion mechanism 8 and the variable mechanism 7 are connected to one cam plate 90, the expansion mechanism 8 and the variable mechanism 7 are operated by one cam motor 94, and the upper guide 20 and the pinch roller 33b are moved. It is possible to drive. Therefore, the cost of the apparatus can be reduced as compared with the case where the upper guide 20 and the pinch roller 33b are driven by separate motors.

  Further, by using a cam mechanism that changes the direction of motion, the cam guide 94 can be driven to rotate, whereby the upper guide 20 and the pinch roller 33b can be driven in the left-right direction (the thickness direction of the bill). As compared with the case where the upper guide 20 and the pinch roller 33b are driven using a driving source (for example, an electric pusher) that is driven in the direction, the thickness of the device (the width in the thickness direction of the bill) can be reduced. Further, the structure can be simplified and the apparatus can be downsized as compared with the case where the upper guide 20 and the pinch roller 33b are driven using a rack and a pinion.

  Further, the first cam groove A91 and the second cam groove A92 of the cam plate 90 are operated by the expansion mechanism 8 to change the opening width of the conveyance path 4 and the insertion port 2, and the variable mechanism 7 is used to pinch the roller 33b and the drive roller 33a. Since the operation of changing the relative distance is not performed at the same time, the load on the cam motor 94 can be reduced, and the occurrence of failure can be reduced.

(Control circuit board 100)
FIG. 16 is a control block diagram of the banknote handling apparatus 1. As shown in FIG. 16, the banknote handling apparatus 1 includes a control circuit board 100 that controls the operation of each driving device described above. On the control circuit board 100, a CPU (Central Processing Unit) 101, A ROM (Read Only Memory) 102 and a RAM (Random Access Memory) 103 are mounted.

  In the ROM 102, the operation program of various driving devices such as the transport motor 53, the stack gate motor 64, the cam motor 94, various programs such as an authenticity determination program, and the like used when performing authenticity determination processing and the like. Permanent data such as data is stored. The reference data is acquired from the entire printing area of the genuine note banknote, and includes, for example, grayscale data regarding transmitted light and reflected light when infrared light and visible light are projected onto the banknote. In the present embodiment, the reference data is stored in the ROM 102, but may be stored in a dedicated storage unit.

  The CPU 101 generates a control signal according to an operation program stored in the ROM 102, inputs / outputs signals to / from the various driving devices described above via the I / O port 104, and controls the driving of the various driving devices. . That is, the CPU 101 is connected to the transport motor 53, the stack gate motor 64, and the cam motor 94 via the I / O port 104. These drive devices are operated according to the operation program stored in the ROM 102. The operation is controlled by a control signal from the CPU 101.

  In addition, the CPU 101 detects from various sensors such as the first banknote detection sensor 24, the second banknote detection sensor 25, the empty sensor 34, the stack gate detection sensor 40, and the cam detection sensor 96 via the I / O port 104. Signals are input, and drive control of the various drive devices described above is performed based on these detection signals.

  Specifically, the control based on the detection signal of the stack gate detection sensor 40 means that the stack gate motor 64 is driven a predetermined number of steps from the time when the stack gate detection sensor 40 detects the protrusion 39a. The stack gate 31 is moved from the carry-in position to the carry-out position or the stack position, and the stack gate motor 64 is driven until the stack gate detection sensor 40 detects the protrusion 39a, thereby returning the stack gate 31 to the carry-in position. It is.

  Further, the control based on the detection signal of the cam detection sensor 96 specifically means that the cam motor 94 is driven by a predetermined number of steps from the time when the cam detection sensor 96 detects the protrusion 72b. The cam plate 90 is rotated by a predetermined angle from the reference position, and the cam motor 94 is driven until the cam detection sensor 96 detects the protrusion 72b, thereby returning the cam plate 90 to the reference position.

  Further, a reading unit 21 is connected to the CPU 101 via the I / O port 104, and data read by the reading unit 21 is compared with reference data stored in the ROM 102, and a bill authenticity determination process is performed. Is executed.

  The RAM 103 stores data and programs used when the CPU 101 operates, and has a function of storing the number of banknotes stored in the storage unit 5.

  The CPU 101 is connected to a control circuit 200a of the game medium lending device 200 in which the game medium lending device 200 is incorporated, and a management server 203 that collectively manages a large number of gaming machines 201 and the game medium lending device 200. And information such as the amount and number of banknotes is transmitted.

  When the CPU 101 detects an illegal act by the upper guide detection sensor 28, the CPU 101 transmits a fraud detection signal to the management server 203 and the control circuit 200 a of the game medium lending device 200.

  Further, when the thickness of the banknote detected by the thickness detection sensor 97 reaches a predetermined value, the CPU 101 transmits a full signal to the management server 203 and the control circuit 200a of the game medium lending device 200. The control circuit 200a of the game medium lending device 200 that has received the full signal notifies the display device and the audio device incorporated in the game medium lending device 200 that the game medium lending device 200 is full.

  In addition, a banknote collection signal for instructing collection of banknotes stored in the storage unit 5 can be transmitted from the management server 203 to the banknote processing apparatus 1 by an operation of an administrator of the management server 203. Note that the banknote collection signal is transmitted when a full signal is transmitted to the management server 203 and the administrator collects banknotes, or when the banknotes of all banknote processing apparatuses 1 are collected after the game hall is closed.

(Processing when depositing banknotes)
Next, the processing operation of the banknote processing apparatus 1 when depositing banknotes will be described with reference to the flowcharts of FIGS.

  When the operator inserts the banknote M into the insertion slot 2, the opening width of the transport path 4 and the opening width of the insertion slot 2 are minimum. The pinch roller 33b is disposed at the standby position, and the stack gate 31 is disposed at the carry-in position.

  As shown in the flowchart of FIG. 17, when the banknote M is inserted into the insertion slot 2 and the banknote M is detected by the first banknote detection sensor 24 (step S1: Yes), black correction processing is started (step S2). ). The black correction process is to obtain a detection signal from the light receiving unit of the reading unit 21 in a state in which the light emitting states of the reflection light emitting unit and the transmission light emitting unit 21b are invalidated, and set the reference value of the lowest brightness ( Correction). Note that this black correction process may be completed by the start of the bill reading process by the reading unit 21 described later.

  Further, the transport motor 53 is driven to rotate forward (step S3), and the deposited banknote M is transported toward the storage unit 5 by the pair of insertion transport rollers 22 and 23. And when the conveyed banknote M passes the reading part 21, while starting the reading process of a banknote (step S4), an overlap / shape check process is performed (step S5).

  In the overlap / shape check process, as shown in the flowchart of FIG. 18, when the reading unit 21 reads a bill by a predetermined length (step S21: Yes), an average density value of pixels of the read image is calculated. (Step S22), it is determined whether or not the average density value is equal to or greater than a threshold value (reference data) stored in the ROM 102 (Step S23).

  When the calculated average density value is less than the threshold value (step S23: No), it is determined that the deposited banknotes are overlapped (a plurality of banknotes are stacked or the leading edge of the banknotes is bent). As shown in the flowchart of FIG. 19, the conveyance motor 53 is driven in reverse (step S <b> 31) to convey the banknote back to the insertion slot 2. Then, when the first banknote detection sensor 24 detects the front end of the banknote transport direction, the transport motor 53 is reversely driven by a predetermined amount (step S32: Yes, step S33), and a part of the banknote is inserted from the insertion slot 2. Let it be in the discharged state.

  If the calculated average density value is equal to or greater than the threshold value (step S23: Yes), the shape of the image read for a predetermined length is compared with the reference image stored in the ROM 102, and it is determined that they are not similar. (Step S24: No), it is determined that the banknote is torn or the like, and the conveyance motor 53 is reversely driven so that the banknote is immediately discharged from the insertion slot 2 (Steps S31 to S33).

  If it is determined that the shape of the read image is similar to the reference image (step S24: Yes), the bill reading process is continued as it is, and the reading unit 21 finishes reading the rear end of the bill in the conveyance direction ( Step S6: Yes), authenticity determination processing is started (step S7). Then, after the reading unit 21 finishes reading the rear end of the bill in the conveyance direction, the conveyance motor 53 is driven by a predetermined amount, and the rear end of the bill in the conveyance direction is moved between the reading unit 21 and the second bill detection sensor 25. Stop at an intermediate position (escrow position) (step S8).

  When it is determined that the bill is not a genuine note in the authenticity determination process (step S9: No), the transport motor 53 is driven in reverse so that the bill is immediately discharged from the insertion port 2 (steps S31 to S31). S33).

  Further, when it is determined that the banknote M is a genuine note in the authenticity determination process (step S9: Yes), and no banknote is detected by the empty sensor 34 as shown in the flowchart of FIG. 20 (step S10: No), By driving the cam motor 94 and engaging the engaging protrusion 72a of the slide member 72 with the large diameter portion 91a of the cam plate 90, the pinch roller 33b is moved to the driving roller 33a side, and the conveying roller pair 33 is moved. Thus, one banknote is clamped with the clamping force Fa (step S11).

  Moreover, when it determines with a banknote being a genuine note in an authenticity determination process (step S9: Yes) and a banknote is detected by the empty sensor 34 (step S10: Yes), of the banknote memorize | stored in RAM103. Depending on the number of stored sheets, the cam motor 94 is driven to engage the engagement protrusion 72a of the slide member 72 with a predetermined position of the intermediate portion 91b of the cam plate 90, whereby the pinch roller 33b is moved to the drive roller 33a side. And the banknotes are clamped with the clamping force Fb by the transport roller pair 33 (step S12).

  After steps S11 and S12, the conveyance motor 53 is driven to rotate forward (step S13). Then, when the second banknote detection sensor 25 no longer detects the banknote, the transport motor 53 is driven to rotate forward by a predetermined amount, and the rear end in the transport direction of the single banknote carried in is opposed to the stack portion 37. Stop at the position (step S14: Yes, step S15).

  Thereafter, the cam motor 94 is driven to engage the engaging protrusion 72 a of the slide member 72 with the large diameter portion 91 a of the cam plate 90, thereby driving the pinch roller 33 b, and Clamping is performed with the clamping force Fa (step S16). Note that when no banknote is detected in step S10 described above, the cam motor 94 remains stopped.

  Next, the stack gate motor 64 is driven, the stack gate 31 is once moved to the stack position, and the rear end portion in the transport direction of the loaded bill is moved between the stack portion 37 and the pressing plate 32. The stack gate 31 is returned to the carry-in position again (step S17). As a result, the rear end portion in the conveyance direction of the banknotes moves over the stack portion 37 and is disposed between the stack portion 37 and the pressing plate 32. Thereafter, the cam motor 94 is driven, and the pinch roller 33b is separated from the drive roller 33a and placed at the standby position (step S18). When the stack gate 31 is returned to the carry-in position, the number of banknotes stored in the RAM 103 is updated.

  When performing the above-described step S12, if the thickness detection sensor 97 detects that the thickness of the banknote sandwiched between the transport roller pair 33 has reached a predetermined value, the banknote processing apparatus 1 and the management server 203 play a game. A full signal is transmitted to the control circuit 200a of the medium lending device 200 to notify the necessity of collection. Moreover, when the thickness of a banknote reaches predetermined value, even if a banknote is inserted in the insertion port 2 after that, the processing operation at the time of banknote payment mentioned above is not performed. Thus, by managing the collection timing according to the thickness of the banknotes in the storage unit 5, the state of the banknotes (wrinkles etc.) compared to the case of managing according to the number of banknotes stored in the RAM 103. This makes it possible to collect banknotes more stably and reliably.

(Processing when collecting banknotes)
Next, the processing operation of the banknote processing apparatus 1 when collecting a plurality of banknotes M stored in the storage unit 5 will be described with reference to the flowchart of FIG.

  When the banknote collection signal transmitted from the management server 203 is received (step S41: Yes), the stack gate motor 64 is driven to move the stack gate 31 from the carry-in position to the carry-out position (step S42).

  Next, the cam motor 94 is driven to engage the engagement protrusion 72a of the slide member 72 with the large diameter portion 91a of the cam plate 90, thereby moving the pinch roller 33b from the default position to the drive roller 33a side. In addition, the banknotes are clamped with the clamping force Fa by the conveyance roller pair 33 and the engagement protrusion 83a of the slide member 83 is engaged with the large-diameter portion 92c of the cam plate 90, whereby the opening width of the conveyance path 4 is maximized. Thus, the upper guide 20 is moved (step S43).

  Subsequently, the conveyance motor 53 is driven in reverse (step S44), and the banknote bundle sandwiched between the conveyance roller pair 33 is conveyed toward the insertion slot 2. Then, when the first banknote detection sensor 24 detects the front end of the banknote transport direction, the transport motor 53 is reversely driven by a predetermined amount (step S45: Yes, step S46), and a part of the banknote bundle is inserted into the insertion slot 2. It is assumed that it has been discharged from. In addition, it is preferable to make the rotation speed of the motor 53 for conveyance at the time of banknote discharge slower than the rotation speed at the time of banknote insertion so that a plurality of banknotes can be reliably conveyed.

  Thereafter, when the banknote recovery person extracts and recovers the banknote bundle and no banknote is detected by the first banknote detection sensor 24 and the second banknote detection sensor 25 (step S47: No), the cam motor 94 is driven, The upper guide 20 is moved so that the opening width of the conveyance path 4 is minimized, and the pinch roller 33b is separated from the driving roller 33a and is arranged at the standby position (step S48). In addition, when a banknote is no longer detected by the first banknote detection sensor 24 and the second banknote detection sensor 25, the number of banknotes stored in the RAM 103 is initialized to zero.

  As mentioned above, although Embodiment 1 of this invention was demonstrated, it only showed the specific example and does not specifically limit this invention, A specific structure can be design-changed suitably. Moreover, the effect described in the said embodiment only enumerated the most suitable effect which arises from this invention, and the effect by this invention is not limited to what was described in the said embodiment.

  In the said Embodiment 1, although a pair of member (conveyance roller pair 33) is used as a conveyance member for conveying the banknote accommodated in the accommodating part 5, the structure of a conveyance member is limited to this. Is not to be done. For example, the conveyance member may be configured by a rotatable belt disposed on one side in the thickness direction of the bill and a roller disposed on the other side in the thickness direction of the bill.

  In the first embodiment, the pinch roller 33b is pressed toward the driving roller 33a by the torsion coil spring 71 when the banknote is held by the conveyance roller pair 33 at the time of banknote collection or stacking operation. The relative distance to the driving roller 33a is a value corresponding to the thickness of the bill. That is, the relative distance between the pinch roller 33b and the drive roller 33a is set to a value corresponding to the thickness of the banknote by the elastic force of the torsion coil spring 71, but only the shape of the cam groove 91 drives the pinch roller 33b. You may be comprised so that the relative distance with the roller 33a can be set to the value according to the number of accommodation of a banknote. That is, a portion of the cam groove 91 where the engagement protrusion 83a engages with the second large diameter portion 92c has a shape in which the diameter continuously changes, and the RAM 103 has The engagement position of the engagement protrusion 72a may be determined according to the stored number of stored banknotes.

  In the first embodiment, the stack gate 31 is connected to the stack portion 37 and the guide portion 38 at both ends in the extending direction, but may be connected only at one end portion in the extending direction. .

  In the first embodiment, the cam grooves 91 and 92 are formed in an annular shape. However, when the cam motor 94 can be rotated forward and backward, the cam grooves 91 and 92 do not have to be annular.

  In the first embodiment, the example in which the paper sheet processing apparatus of the present invention is applied to the banknote processing apparatus incorporated in the game medium lending apparatus has been described. However, the application target of the paper sheet processing apparatus of the present invention is this. It is not limited to.

  Moreover, in the said Embodiment 1, although the banknote processing apparatus 1 is installed in the direction where the longitudinal direction of the insertion port 2 becomes an up-down direction, the installation direction of the paper sheet processing apparatus of this invention is limited to this. is not. For example, you may install in the direction where the longitudinal direction of an insertion port becomes horizontal.

(Embodiment 2)
Next, banknote processing apparatus A1 which is other embodiment of this invention is demonstrated. In addition, the same code | symbol is attached | subjected to the same member as Embodiment 1, and it demonstrates centering on a different part from Embodiment 1. FIG.

(Left cover 111)
As shown in FIGS. 22, 23, and 24, the banknote handling apparatus A <b> 1 of Embodiment 2 includes a frame 10 to which various members are assembled, and a front cover 3 that is disposed so as to cover the front wall 11 of the frame 10. And a left cover 111 disposed so as to cover the left side portion from the right side wall 10a of the frame 10. Thereby, banknote processing apparatus A1 is formed in box shape by the right side wall 10a of the flame | frame 10, the front wall 11, and the left cover 111, and is protecting the banknote accommodated inside and various mechanisms.

  The left cover 111 has a notch 111a in the left wall 111b. The notch 111a is formed to expose the storage lid 30 to the outside. Thus, the banknote handling apparatus A1 can open and close the storage lid 30 without removing the left cover 111 from the frame 10. The left cover 111 is detachably fixed to the frame 10 by screw tightening.

(Expansion mechanism A8)
The expansion mechanism A8 is for driving the upper guide A20 and the pressing plate A32 in the left-right direction, and for moving the safety mechanism A112 biased in the left direction in the left-right direction. That is, the expansion mechanism A8 has a function of driving the upper guide A20, a function of driving the pressing plate A32, and a function of moving the safety mechanism A112 in FIG. Thereby, the cam pulley A90 rotated by the cam motor 94 that is a drive source of the expansion mechanism 8 is shared by the mechanism that realizes the above-described two types of drive functions and one type of movement function. FIG. 26 shows a state where the right cover 111 is removed from the frame 10.

(Expansion mechanism A8: drive function of upper guide A20)
The extension mechanism A8 includes two first arms A80 that support the protrusions A20a at the upper and lower ends of the upper guide A20 in the left-right direction, two connection members A81, two torsion coil springs A801, and a slide member 83. Thus, the drive function of the upper guide A20 is realized.

  The two first arms A80 are arranged on both upper and lower sides of the upper and lower walls 13. The first arm A80 is formed in a substantially L shape when viewed from the left-right direction. The first arm A80 is rotatably connected to an axis A19 provided on the frame 10 in the vicinity of the L-shaped corner.

  An axis A16 is provided at one end of the L-shape of the first arm A80. The shaft 16 is engaged with the front end portion of the connecting member A81 so as to be rotatable and movable in the left-right direction. On the other hand, the rear end portion of the connecting member A81 is connected to the slide member 83. The connecting member A81 is attached to the guide shaft 18 and is movable along the guide shaft 18. The guide shaft 18 has an axial center aligned in the front-rear direction. Accordingly, the connecting member A81 is moved only in the front-rear direction by the slide member 83. Then, the first arm A80 moves one tip portion provided with the axis A16 in the front-rear direction along with the movement of the connecting member A81 in the front-rear direction, and moves the other tip portion left and right around the axis A19. It is designed to move in the direction.

  The other L-shaped tip of the first arm A80 is branched into a right support A80a and a left support A80b. The right support portion A80a is in contact with the right side surface of the protrusion A20a of the upper guide A20. The first arm A80 is provided with a torsion coil spring A801. The torsion coil spring A801 has a central portion attached to an axis A19 that pivotally supports the first arm A80, a tip portion that is in contact with the left side surface of the protrusion A20a of the upper guide A20, and the protrusion A20a attached to the right side. It is fast. As a result, the other tip portions (the right support portion A80a and the left support portion A80b) of the upper guide A20 and the first arm A80 are urged in the right direction (the direction in which the insertion port 2 is closed) by the torsion coil spring A801. The cam motor 94 can move leftward (in the direction of opening the insertion port 2) via the protrusion A20a, the right support A80a of the first arm A80, and the like.

  On the other hand, as shown in FIGS. 32A, 32B, and 32C, the left support portion A80b of the first arm A80 can be fitted into the guide groove portion A20b of the upper guide A20. The guide groove A20b is formed in the left-right direction of the upper guide A20. The left end of the guide groove A20b is an open end on the left surface of the upper guide A20. On the other hand, the right end of the guide groove A20b is a closed end A20c on the right surface of the upper guide A20. As shown in FIG. 32C, the left support portion A80b of the first arm A80 is set so that the distal end abuts against the closed end A20c when the upper guide A20 is moved to the position where the insertion port 2 is closed. Yes. As a result, the upper guide A20 moves leftward (opening direction) when the left support portion A80b of the first arm A80 whose rotation is prohibited by the connecting member A81 comes into contact with the closed end A20c of the guide groove portion A20b. Movement is prohibited. As a result, the upper guide A20 is illegal because the upper guide A20 is forcibly moved from the outside in the left direction (opening direction) by firmly maintaining the closed state of the insertion port 2 by the first arm A80. It is possible to prevent acts.

(Expansion mechanism A8: drive function of pressing plate A32)
The expansion mechanism A8 includes two second arms A85 that support the protrusions A32b at the upper and lower ends of the pressing plate A32 in the left-right direction, two connection members A81, two torsion coil springs 41, and a slide member 83. Thus, the drive function of the pressing plate A32 is realized.

  The two second arms A85 are disposed between the upper and lower walls 13 and the stack arm 60, as shown in FIG. As shown in FIG. 25, the second arm A85 is formed in a substantially L shape when viewed from the left-right direction. The second arm A85 is pivotally supported by the frame 10 in the vicinity of the L-shaped corner. One L-shaped tip of the second arm A85 is in contact with the right side surface of the protrusion A32b of the pressing plate A32. The second arm A85 is provided with a torsion coil spring 41. The torsion coil spring 41 has a central portion attached to a shaft that supports the second arm A85, and a tip end portion is in contact with the left side surface of the protrusion A32b of the pressing plate A32, and biases the protrusion A32b in the right direction. doing.

  On the other hand, the other L-shaped tip of the second arm A85 is disposed so as to be able to abut on the protrusion A81a of the connecting member A81. When the connecting member A81 moves forward by the slide member 83, the connecting member A81 causes the projection A81a to abut on the other tip of the second arm A85 and moves one tip of the second arm A85 to the left. Thus, the pressing plate A32 is moved in the left direction. Further, when the connecting member A81 is moved rearward by the slide member 83, the connecting member A81 is pressed by moving the second arm A85 to the right by separating the protrusion A81a from the other tip of the second arm A85. The plate A32 is moved rightward by the urging force of the torsion coil spring 41.

(Expansion mechanism A8: movement function of safety mechanism A112)
As shown in FIG. 26, the expansion mechanism A8 has two connecting members A81 and a slide member 83, thereby realizing the moving function of the safety mechanism A112.

  The connecting member A81 has a first engagement groove A81b and a second engagement groove A81c. The first engagement groove A81b and the second engagement groove A81c are formed so that the protruding portion A1122a of the safety mechanism A112 is movably engaged. The safety mechanism A112 is urged leftward by a spring A1124. Details of the safety mechanism A112 will be described later.

  As shown in FIG. 31B, the first engagement groove A81b is formed on the wall 12 side of the front end portion of the right side wall in the connecting member A81. The second engagement groove A81c is connected to the first engagement groove A81b and is formed on the front side wall of the coupling member A81. When the connecting member A81 moves forward by the slide member 83, the connecting member A81 engages the protruding portion A1122a of the safety mechanism A112 with the first engaging groove A81b. As a result, the shutter portion A1121 of the safety mechanism A112 is placed on the right side of the conveyance path, so that the shutter A1121 is in a state of being submerged from the conveyance path. Further, as shown in FIG. 31C, the connecting member A81 is moved rearward by the slide member 83, and when the protruding portion A1122a of the safety mechanism A112 reaches the second engaging groove A81c, the safety mechanism A112 is moved in the left direction. By being biased, the protrusion A1122a is moved to the left end of the second engagement groove A81c. As a result, the shutter portion A1121 of the safety mechanism A112 is positioned on the left side of the conveyance path, and thus is projected into the conveyance path.

(Pressing plate A32)
As shown in FIG. 31A, the pressing plate A32 moved in the left-right direction by the arm A80 of the expansion mechanism A8 is disposed to face the left side of the stack portion A37. The upper and lower ends of the pressing plate A32 are disposed inside the slit 13a formed in the upper and lower walls 13 in FIG. As shown in FIG. 25, the other end of the torsion coil spring 41 whose one end is locked to the frame 10 is in contact with the projection A32b of the press plate A32. The press plate A32 is attached to the right side by the torsion coil spring 41. It is energized.

  As shown in FIG. 27A, a plurality of restricting portions A32a (first restricting portions) are formed on the right surface (the surface facing the stack portion A37) of the pressing plate A32. The restricting portion A32a is arranged at three locations of the upper region, the middle region, and the lower region of the pressing plate A32. As shown in FIG. 27B, each regulating portion A32a has a frictional force when moving in the direction of the storage portion on the contact surface with the paper sheet rather than moving in the direction of the insertion port 2 of the paper sheet. Is formed. If demonstrating it concretely, each regulation part A32a has the some protruding item | line part A32c. Each protrusion A32c is formed so as to protrude rightward and extend in the vertical direction, and is formed at equal intervals in the front-rear direction. The cross-sectional shape seen from the up-down direction of each protruding item | line part A32c is formed so that the line segment which goes to the top part from the center point of a bottom part may incline to the front side.

  Thus, the pressing plate A32 can prevent the stacked state of the paper sheets stacked and stored in the storage unit 5 from being disturbed when the paper sheets inserted into the insertion port 2 are conveyed to the storage unit 5. it can. In addition, when the paper sheets stored in the storage unit 5 are transported in the direction of the insertion port 2, it is possible to reduce the frictional force by the restricting unit A32a, and a transport failure occurs when the paper sheets are collected. The possibility can be reduced.

(Stack part A37)
As shown in FIG. 24, the stack portion A37 (movable piece) facing the pressing plate A32 has a contact surface with the stacked and stored paper sheets, rather than the frictional force between the stacked and stored paper sheets. A second restricting portion is provided in which the frictional force between the stack portion A37 and the stacked sheets is increased. For example, the second restricting portion is made of silicon rubber and is formed at least at a contact portion with the paper sheet. This prevents instability when storing the paper sheets due to the shift of the paper sheets stacked and stored in the storage section 2 due to the impact when the stack portion A37 moves in and out of the carry-in space 31a. Can do. Furthermore, instability at the time of storing paper sheets due to the shift of the paper sheets stacked and stored in the storage unit 5 due to an impact when an external force is applied to the banknote processing apparatus A1 can also be prevented.

(Safety mechanism A112)
As shown in FIG. 28, the safety mechanism A112 driven by the expansion mechanism A8 has a shutter member A1125. The shutter member A1125 includes a flat plate portion A1122, projecting portions A1122a and A1122a disposed on both end surfaces of the flat plate portion A1122, and a movement restricting portion A1123 and a shutter portion A1121 disposed at the center of the flat plate portion A1122. Have. The movement restricting portion A1123 is provided with a spring A1124, and the spring A1124 urges the shutter portion A1121 to advance into the transport path 4 with the movement restricting portion A1123 as a rotation center.

  The protrusion A1122a is movably engaged with the first engagement groove A81b and the second engagement groove A81c of the connecting member A81. As shown in FIGS. 31A and 31B, when the connecting member A81 is moved forward by the slide member 83, the safety mechanism A112 engages the protruding portion A1122a with the first engaging groove A81b, and the shutter portion A1121. Is moved from the conveying path 4 to a position where it is submerged. On the other hand, as shown in FIG. 31C, when the connecting member A81 is moved rearward by the slide member 83, the safety mechanism A112 engages the protruding portion A1122a with the second engagement groove A81c, and the biasing force of the spring A1124 The shutter part A1121 is moved to a position where it advances into the transport path 4. As a result, the safety mechanism A112 can prevent the paper sheets stored in the storage unit 5 from being pulled out when waiting for a transaction.

  In addition, since the safety mechanism A112 moves and stops moving the shutter portion A1121 by advancing and retreating the expansion mechanism A8, a dedicated movement switching mechanism that switches between moving and stopping the safety mechanism A112 (shutter portion A1121) is separately provided. Cost reduction is possible compared with the case of providing.

(Conveying roller pair A33)
As shown in FIG. 29, the conveyance roller pair A33 includes a drive roller 33a disposed on the wall 12 side and a pinch roller A33b disposed on the storage lid 30 side. The transport roller pair A33 is driven by the transport mechanism 6 to transport bills. The separation distance between the insertion slot 2 and the conveyance roller pair A33 is shorter than the length of the banknote in the conveyance direction.

  The drive roller 33 a is fixed to a drive shaft 35 that is rotatably supported by the frame 10, and is disposed so as to slightly protrude from the left surface of the wall portion 12. The drive shaft 35 is driven by the transport mechanism 6. The pinch roller A33b is fixed to the support shaft. The support shaft 36 is driven in the left-right direction by the variable mechanism 7. In a state where the support shaft 36 is farthest from the drive shaft 35, the pinch roller A33b is exposed to the outside through an opening formed in the storage lid 30.

  The friction coefficient with respect to the banknote of the outer peripheral surface of the drive roller 33a is larger than the friction coefficient between banknotes. The friction coefficient of the outer peripheral surface of the pinch roller A33b may be larger or smaller than the friction coefficient between bills.

  The pinch roller A33b has a first abutting member A331b that presses the paper sheet using an elastic force that changes its shape when coming into contact with the paper sheet and returns to the original shape from the deformed shape. Yes. The first contact member A331b is formed of a low-hardness elastic body such as urethane foam. Further, the first contact member A331b is formed in a short-axis annular shape, and four pieces are arranged at equal intervals in the vertical direction.

  The transport roller pair A33 is driven to rotate by the transport mechanism 6 so that the sandwiched paper sheets can be transported. The transport roller pair A33 is configured so that when the paper sheet inserted into the insertion port 2 is transported toward the storage unit 5, the pinch roller 33b and the driving roller are arranged so that the first contact member A331b contacts the paper sheet. The relative distance to 33a can be changed.

  As a result, when the paper sheet is transported toward the storage unit 5, the first abutting member A331b of the pinch roller A33b is stacked on the paper sheet stacked using the force generated by its elastic deformation. By abutting, a constant frictional force is applied between the paper sheet to be conveyed and the first abutting member A331b without depending on the state of the stacked paper sheets. Therefore, it is possible to stably perform operations when storing paper sheets.

  The pinch roller A33b includes a second contact member 332b that is formed to be harder than the first contact member A331b. The second contact member 332b is formed in a cylindrical shape. The second contact member 332b is inserted into the first contact member A331b. A concave fitting portion A3321b is formed in the circumferential direction on the outer peripheral surface of the second contact member 332b. The fitting parts A3321b are formed at equal intervals in four places in the vertical direction. The inner peripheral portion of the first contact member A331b is fitted to each fitting portion A3321b. The axis of the second contact member 332b is coincident with the axis of the first contact member A331b. That is, the transport roller pair A33 is configured such that the first contact member A331b and the second contact member 332b are arranged coaxially.

  The outer diameter of the second contact member 332b is such that the outer peripheral surface of the second contact member 332b is located on the inner side of the outer peripheral surface of the first contact member A331b fitted to the fitting portion A3321b. A value smaller than the outer diameter of the contact member A331b is set. The transport roller pair A33 is configured so that when the paper sheet stored in the storage unit 5 is transported toward the insertion port 2, the driving roller 33a and the driving roller 33a are brought into contact with the paper sheet. The relative distance to the pinch roller A33b is changed.

  As a result, when the paper sheet is collected to transport the paper sheet toward the insertion port 2, the second abutting member 332b is changed when the relative distance between the drive roller 33a and the pinch roller A33b is reduced. Since the first contact member A331b is harder than the first contact member A331b, the second contact member 332b can be brought into contact with the paper sheet as a result of the first contact member A331b being crushed. Accordingly, the first contact member A331b and the second contact member 332b having two types of elasticity can be used properly only by changing the relative distance of the conveying roller pair A33, that is, the movement amount of the pinch roller A33b. It becomes.

(Cam pulley A90)
As shown in FIG. 25, the slide member 83 of the expansion mechanism A8 is disposed behind the connecting member A81. The guide shaft 18 penetrates through both the upper and lower ends of the slide member 83, and the slide member 83 can move in the front-rear direction along the guide shaft 18. The slide member 83 is driven by rotation of a cam pulley A90 that is a cam plate.

  As shown in FIG. 30A, the cam pulley A90 is integrally formed in a disc shape. A gear portion A901 is formed on the outer peripheral portion of the cam pulley A90. The gear portion A901 is meshed with a belt 93 that is a timing belt. The engagement protrusion 83a of the slide member 83 shown in FIG. 29 is engaged with the second cam groove A92 formed on the left surface of the cam pulley A90. As shown in FIGS. 30A and 30C, the second cam groove A92 is formed in an annular shape, and is connected to both sides of the small diameter portion A92a having a constant diameter and the small diameter portion A92a. The two intermediate portions A92b and a large-diameter portion A92c having a constant diameter and larger than the diameter of the small-diameter portion A92a. A third cam groove A902 is formed on the left surface of the cam pulley A90.

  On the other hand, as shown in FIG. 30B, a first cam groove A91 is formed on the right surface of the cam pulley A90. The first cam groove A91 is formed in an annular shape, and has a large diameter portion A91a having a constant diameter, two intermediate portions A91b that are connected to both sides of the large diameter portion A91a, and the diameter continuously changes, and a diameter. The small-diameter portion A91c is constant and is smaller than the diameter of the large-diameter portion A91a. The details of the first cam groove A91 and the second cam groove A92 are the same as those of the first cam groove 91 and the second cam groove 92 of the first embodiment. Other configurations of the second embodiment are the same as those of the first embodiment.

(Operation by cam pulley A90)
As shown in FIG. 30B, a line segment connecting the rotation center point of the cam pulley A90 and the intermediate point of the small diameter portion A91c of the first cam groove A91 is the front-rear direction, and the rotation center point of the cam pulley A90 is the small diameter portion A91c. The state located in front of the intermediate point is assumed to be the rotational angle position of the 0-degree position (reference position) of the cam pulley A90. Then, as shown in FIG. 30D, when the cam pulley A90 rotates from the 0 degree position to the 360 degree position, the slide member 72 engaged with the first cam groove A91 and the connecting member engaged with the second cam groove A92. As A81 moves in the front-rear direction, the pinch roller A33b, the conveyance path 4, the shutter part A1121, and the pressing plate A32 operate at respective timings (rotational angle positions).

  Here, the 0-degree position (reference position) of the cam pulley A90 is detected by a cam detection sensor 96 as shown in FIG. Specifically, the cam detection sensor 96 detects the protrusion 72b formed at the rear end portion of the slide member 72, whereby the 0 degree position (reference position) of the cam pulley A90 is detected. The 0-degree position (reference position) of the cam pulley A90 is for resetting the error of the rotational angle position when the cam pulley A90 is rotationally driven by the cam motor 94. The reset operation based on the reference position may be performed at a predetermined time interval or at a predetermined rotation angle timing, or may be performed at a timing when the predetermined operation is shifted to the next operation, or from among a plurality of types of operations. It may be performed at the timing of performing one or more selected specific operations.

  The operation when the cam pulley A90 rotates from the 0 degree position to the 360 degree position will be specifically described. Although the description of the reset operation is omitted, the reset operation is performed at the timing when the predetermined operation moves to the next operation. As shown in FIG. 31A, when the cam pulley A90 is at the 0 degree position to the 10 degree position, the pinch roller A33b is lifted (moved leftward) and is stopped at the standby position farthest away from the drive roller 33a. . Further, the upper guide A20 supported by the arm A80 is moved in the right direction, so that the conveyance path 4 is closed. The shutter part A1121 is lowered from the stack part 37 (positioned on the right side), and is stopped at the buried position buried in the carry-in space 31a (conveyance path 4). The pressing plate A32 supported by the second arm A85 is in a closed state (positioned on the right side).

  When the cam pulley A90 rotates from the 10 degree position toward the 80 degree position, the pinch roller A33b starts to descend (moves in the right direction) and moves toward the drive roller 33a. At this time, the conveyance path 4, the shutter part A1121, and the pressing plate A32 maintain their respective states.

  When the cam pulley A90 is rotated from the 80 degree position toward the 100 degree position, the pinch roller A33b is stopped at the lowest position between the lowest rollers, the conveyance path 4 is closed, and the shutter portion A1121 is stopped at the buried position. And the pressing plate A32 is closed (positioned on the right side).

  When the cam pulley A90 reaches the 100 degree position, the conveyance path 4 starts to open. When the cam pulley A90 reaches the 110 degree position, the pressing plate A32 starts to open. When the cam pulley A90 reaches the 170 degree position, the transport path 4 and the pressing plate A32 are in the most open state. That is, as shown in FIG. 31B, the state where the pinch roller A33b has moved to the lowest position between the lowest rollers, the state where the conveying path 4 is opened most, the state where the shutter part A1121 has moved to the buried position, and the pressing plate A32 It will be in the most open state. This state is maintained while the cam pulley A90 rotates from the 170 degree position toward the 190 degree position.

  When the cam pulley A90 reaches the 190 degree position, the conveyance path 4 and the pressing plate A32 start to close. Then, immediately before the cam pulley A90 reaches the 260 degree position, the shutter part A1121 starts to rise, and when the cam pulley A90 reaches the 260 degree position, the shutter part A1121 rises the most so that the carry-in space 31a (conveyance) It will be in the state which moved to the protrusion position which advanced to the path 4). Moreover, the conveyance path 4 and the pressing plate A32 are in the most closed state. This state is maintained while the cam pulley A90 rotates from the 260 degree position toward the 280 degree position.

  When the cam pulley A90 reaches the 280 degree position, the pinch roller A33b starts to rise. When the cam pulley A90 reaches the 300 degree position, the shutter part A1121 starts to descend, and when the cam pulley A90 reaches the 330 degree position, the shutter part A1121 is lowered most so that the shutter part A1121 sinks from the loading space 31a. . When the cam pulley A90 reaches the 350-degree position, the pinch roller A33b rises most and moves to the standby position. As a result, the cam pulley A90 returns to the state of FIG. 31A at the 0 degree position.

(Processing when depositing banknotes)
Next, the processing operation of the banknote processing apparatus A1 when depositing banknotes will be described using the flowcharts of FIGS. 32 to 36 and FIGS.

  As shown in the flowchart of FIG. 32, when a bill is inserted into the insertion slot 2 and a bill is detected by the first bill detection sensor 24 (T1: YES), the shutter motor unit 94 is driven by driving the cam motor 94. A1121 is moved from the protruding position to the buried position, and the pinch roller A33b is moved from the minimum position between the rollers to the standby position (T2). That is, as shown in FIG. 31A, by moving the cam pulley A90 at the 270 degree position to the 0 degree position (reference position), the shutter portion A1121 of the safety mechanism A112 is buried in the conveyance path 4 and the pinch roller A33b is moved. Move to the standby position (DOWN → UP). Further, when the cam detection sensor 96 detects the protrusion 72b, the rotation angle position is reset.

  Thereafter, black correction processing is performed (T3). The conveyance motor 53 is driven to rotate forward (T4), and the received banknote is conveyed toward the storage unit 5 by the pair of insertion conveyance rollers 22 and 23. And when the conveyed banknote passes the reading part 21, while starting the reading process of the banknote which is a target object (T5), an overlap / shape check process is performed (T6).

  In the overlap / shape check process, as shown in the flowchart of FIG. 36, when the reading unit 21 reads a bill to be identified by a predetermined length (T41: YES), the sum of each pixel of the read image is calculated as a pixel. It is calculated as a total value, and it is determined whether or not the total pixel value is equal to or greater than a predetermined value (threshold value composed of reference data) stored in the ROM 102 (T42). Here, as shown in FIG. 37, in the case where the pixel has a numerical range such as 0 (black) to 255 (white), generally, banknotes (paper sheets) are placed outside the printing area. Since the margin area exists, the value of the pixel in the margin area increases. As a result, if the sum of the pixels (pixel total value) is equal to or greater than a predetermined value, it can be determined that there is an overlap. Note that infrared light and visible light can be applied as transmitted light.

  As shown in FIG. 36, when the pixel total value is equal to or greater than a predetermined value (T42: YES), the deposited banknotes are overlapped (a plurality of banknotes are stacked or the leading edge of the banknotes is bent). ). Then, as shown in FIG. 34, the conveying motor 53 is driven in reverse (T21), and the bill is conveyed so as to be returned to the insertion slot 2. When the first banknote detection sensor 24 detects the front end of the banknote transport direction, the transport motor 53 is reversely driven by a predetermined amount (T22: YES, T23), and a part of the banknote is discharged from the insertion slot 2. And Specifically, the banknote is discharged and stopped up to 38 mm after the banknote is detected.

  Thereafter, by driving the cam motor 94, the shutter portion A1121 is moved from the buried position to the protruding position, and the pinch roller A33b is moved from the standby position to the minimum position between the rollers (T24). That is, by moving the cam pulley A90 at the reference position (0 degree position) to the 270 degree position, the shutter part A1121 is protruded from the conveyance path 4, and the pinch roller A33b is moved to the minimum inter-roller position (UP → DOWN). Let Thereby, it is possible to prevent the paper sheets stored in the storage unit 5 from being pulled out when waiting for a transaction in which no banknote is inserted.

  As shown in FIG. 36, when the total pixel value is less than the predetermined value (T42: NO), it is determined that the deposited banknotes are not overlapped, and the shape of the image read for a predetermined length is subsequently determined. Then, it is compared with the reference image stored in the ROM 102 to determine whether or not they are similar (T43). More specifically, as shown in FIG. 38, the shape of the thick line portion in the figure is compared with the reference image. Note that infrared light and visible light can be applied as transmitted light.

  As shown in FIG. 36, when it is determined that they are not similar (T43: NO), it is determined that the banknote is torn or the like, and the conveyance motor 53 is reversed so that the banknote is immediately discharged from the insertion slot 2. Drive (T21 to T24).

  If it is determined that the shape of the read image is similar to the reference image (T43: YES), the bill reading process is continued as it is as shown in FIG. Then, when the reading unit 21 finishes reading the rear end of the bill conveyance direction (T7: YES), the authenticity determination process is started (T8). Details of the authenticity determination process will be described later. Then, after the reading unit 21 finishes reading the rear end of the bill in the conveyance direction, the conveyance motor 53 is driven by a predetermined amount, and the rear end of the bill in the conveyance direction is moved between the reading unit 21 and the second bill detection sensor 25. Stop at an intermediate position (escrow position) (T9).

  Next, in the authenticity determination process, when it is determined that the bill is not a genuine note (T10: NO), the transport motor 53 is driven in reverse so that the bill is immediately discharged from the insertion slot 2 (T21 to T21). T24).

  On the other hand, in the authenticity determination process, when it is determined that the bill is a genuine note (T10: YES), it is subsequently determined whether or not the bill is detected by the empty sensor 34 as shown in FIG. T11). When no banknote is detected (T11: NO), the cam motor 94 is driven to engage the engaging protrusion 72a of the slide member 72 with the large diameter portion A91a of the cam pulley A90, thereby driving the pinch roller A33b. Move to the roller 33a side. And a banknote is pinched | interposed with 1st strength by conveyance roller pair A33 (T12). Here, the first strength is stored under the condition that the pinch roller A33b is solid on the drive roller 33a (the friction coefficient of the contact surface of the roller with which paper sheets such as banknotes contact)> stored. The friction coefficient generated between paper sheets).

  On the other hand, when a bill is detected (T11: YES), the cam motor 94 is driven according to the number of stored bills stored in the RAM 103, and the engaging protrusion 72a of the slide member 72 is moved to the cam pulley A90. By engaging with a predetermined position of the intermediate portion A91b, the pinch roller A33b is moved to the drive roller 33a side. That is, the distance between the drive roller 33a and the pinch roller A33b varies depending on the number of stored sheets. And a banknote is pinched | interposed by 2nd strength with conveyance roller pair A33 (T13). Here, the second strength is that, under the condition that the pinch roller A33b is solidly attached to the drive roller 33a, (the friction coefficient of the contact surface of the roller with which the paper sheet contacts) <(the stored paper sheet) The coefficient of friction that occurs between classes).

  After executing T12 or T13, the conveyance motor 53 is driven to rotate forward (T14). Then, when the second banknote detection sensor 25 stops detecting the banknote, the transport motor 53 is driven to rotate forward by a predetermined amount (9.3 mm), and the rear end in the transport direction of the single banknote loaded is stacked. Stop at a position facing the part A37 (T15: YES, T16).

  Thereafter, the cam motor 94 is driven to engage the engaging protrusion 72a of the slide member 72 with the large-diameter portion A91a of the cam pulley A90, thereby driving the pinch roller A33b. Clamp with a strength of 1 (T17). This is because when the banknote is sandwiched between the stack gate 31 and the pressing plate A32, the banknote is pressed by the pinch roller A33b so that the banknote does not move.

  Next, the stack gate motor 64 is driven, the stack gate 31 is once moved to the stack position, and the rear end portion in the transport direction of the loaded bill is moved between the stack portion A37 and the pressing plate A32. The stack gate 31 is returned to the carry-in position again (T18). Thereby, the banknote conveyance direction rear-end part gets over stack part A37, and is arrange | positioned between stack part A37 and press plate A32. Thereafter, by driving the cam motor 94, the shutter portion A1121 is moved from the buried position to the protruding position, and the pinch roller A33b is moved from the standby position to the minimum position between the rollers (T24). That is, the cam pulley A90 located at the 90 degree position is moved to the reference position (0 degree position), and after the cam detection sensor 96 detects the protrusion 72b, the rotation angle position is reset, and further moved to the 270 degree position. As a result, the shutter portion A1121 is protruded from the conveyance path 4, and the pinch roller A33b is moved from the standby position to the minimum inter-roller position (DOWN → UP → DOWN). Thereby, it is possible to prevent the paper sheets stored in the storage unit 5 from being pulled out when waiting for a transaction in which no banknote is inserted.

  When the thickness detection sensor 97 detects that the thickness of the banknote held between the pair of transport rollers A33 has reached a predetermined value, the banknote processing device A1 controls the management server 203 and the game medium lending device 200. A full signal is transmitted to the circuit 200a to notify the necessity of collection. Moreover, when the thickness of a banknote reaches predetermined value, even if a banknote is inserted in the insertion port 2 after that, the processing operation at the time of banknote payment mentioned above is not performed. Thus, by managing the collection timing according to the thickness of the banknotes in the storage unit 5, the state of the banknotes (wrinkles etc.) compared to the case of managing according to the number of banknotes stored in the RAM 103. This makes it possible to collect banknotes more stably and reliably.

(Processing when collecting banknotes)
Next, the processing operation of the banknote processing apparatus A1 when collecting a plurality of banknotes stored in the storage unit 5 will be described with reference to the flowchart of FIG.

  When the banknote collection signal transmitted from the management server 203 is received (T31: YES), the stack gate motor 64 is driven to move the stack gate 31 from the carry-in position to the carry-out position (T32). The cam motor 94 is driven to drive the pinch roller A33b, the upper guide A20, and the pressing plate A32. And the banknote which exists between the pinch roller A33b and the drive roller 33a with the first strength is sandwiched (T33). More specifically, after the cam pulley A90 located at the 270 degree position is moved to the reference position (0 degree position) and the cam detection sensor 96 detects the protrusion 72b, the rotation angle position is reset, and then 180 degrees. By moving to the position, the upper guide A20 and the pressing plate A32 are moved to widen the conveyance path 4, and the shutter portion A1121 is moved from the protruding position to the buried position.

  Thereafter, the conveyance motor 53 is driven in reverse (T34), and the banknote bundle held between the conveyance roller pair A33 is conveyed toward the insertion slot 2. Then, when the first banknote detection sensor 24 detects the front end of the banknote transport direction, the transport motor 53 is reversely driven by a predetermined amount (38 mm) (T35: YES, T36), and a part of the banknote bundle is inserted into the insertion slot. 2 is discharged. In addition, it is preferable to make the rotation speed of the motor 53 for conveyance at the time of banknote discharge slower than the rotation speed at the time of banknote insertion so that a plurality of banknotes can be reliably conveyed. Specifically, the conveyance speed is 127 mm / s, and is set to half the speed in the insertion direction.

  When a banknote collector extracts and collects banknote bundles and no banknotes are detected by the first banknote detection sensor 24 and the second banknote detection sensor 25 (T37: NO), the cam motor 94 is driven to drive the upper guide A20. Then, the pressing plate A32 is moved to the standby position, the pinch roller A33b is moved from the standby position to the minimum position between the rollers, and the shutter A1121 is driven from the buried position to the protruding position (T38).

(Authenticity judgment processing)
When the authenticity determination process is executed at T8 in FIG. 32, the watermark image authenticity determination process (crease removal) is executed (T51), and then the watermark image authenticity determination process (light / dark reversal) is executed, as shown in FIG. (T52).

  More specifically, in the watermark image authenticity determination process, as shown in FIG. 40, a watermark image (person) is acquired from the standard image stored in the ROM 102 (T61). Then, the average density value of the vertical line at the coordinate [x, y] point is calculated (T62), the average density value of the horizontal line at the coordinate [x, y] point is calculated (T63), and the average density in front of the watermark image is calculated. The value is calculated (T64), the density value of each pixel of the corrected watermark image is calculated (T65), and the correlation coefficient R is acquired from the corrected watermark image g [x, y] (T66). The creases are removed by a series of these processes (T61 to T66).

  Thereafter, authenticity determination is performed. That is, it is determined whether or not the correlation coefficient R is greater than or equal to a threshold value (T67). If the correlation coefficient R is equal to or greater than the threshold value (T67: YES), it is determined to be a true bill (T68). On the other hand, if the correlation coefficient R is less than the threshold value (T67: NO), it is determined to be a fake bill (T69).

  In the watermark image authenticity determination process (light / dark reversal), as shown in FIG. 41, a watermark image s (a black mark) is acquired from the standard image stored in the ROM 102 (T71), and the acquired transparent image is used. A watermark image f (blanking mark) is acquired (T72), and a correlation coefficient R is acquired from the acquired watermark image f of the transparent image and the watermark image s of the standard image (S1). And it is determined whether the correlation coefficient R is more than a threshold value (T74). A series of these processes (T71 to T74) is a first stage process, and the watermark image f of the acquired transparent image is subjected to position correction (i = −4to−4, j = −4to + 4) and most correlated. Use high numbers as comparison targets.

  If the correlation coefficient R is not greater than or equal to the threshold value in the first stage processing (T74: NO), it is determined to be a fake bill (T79). On the other hand, if the correlation coefficient R is equal to or greater than the threshold value (T74: YES), the watermark image f (the insertion mark) is acquired from the acquired reflected image (T75), and the watermark image f of the acquired reflected image A correlation coefficient R is acquired from the watermark image s of the standard image (T76). And it is determined whether the correlation coefficient R is more than a threshold value (T77). A series of these processes (T75 to T77) is the second stage process, and the watermark image f of the acquired reflected image is subjected to position correction (i = −4to−4, j = −4to + 4) and most correlated. Use high numbers as comparison targets.

  If the correlation coefficient R is not greater than or equal to the threshold value in the second stage processing (T77: NO), it is determined to be a fake bill (T79). On the other hand, if the correlation coefficient R is equal to or greater than the threshold value (T77: YES), it is determined that it is a genuine note (T78).

(Overview)
As described above, the banknote handling apparatus 1 according to the first embodiment and the banknote handling apparatus A1 according to the second embodiment, as shown in FIGS. 4 and 5, and the insertion slot 2 into which paper sheets such as banknotes are inserted, A storage unit 5 in which the paper sheets inserted into the insertion port 2 are stored, and a transport mechanism 6 capable of transporting the paper sheets inserted into the insertion port 2 to the storage unit 5. Has a first configuration in which the paper sheets stored in the storage unit 5 can be conveyed toward the insertion slot 2 until the paper sheets are discharged from the insertion slot 2.

  In the first configuration, the transport mechanism 6 can transport the sheets inserted one by one into the insertion slot 2 to the storage unit 5 and a plurality of sheets stacked and stored in the storage unit 5. Has a second configuration that can be conveyed toward the insertion port 2.

  In the second configuration, the insertion port 2 can change the opening width in the thickness direction of the paper sheet, and transports the paper sheet stored in the storage unit 5 toward the insertion port 2 by the transport mechanism 6. In some cases, the opening width is extended to a third configuration.

  In the second or third configuration, the conveyance path 4 through which the paper sheet passes is provided between the insertion port 2 and the storage portion 5, and the conveyance path 4 has an opening width in the thickness direction of the paper sheet. The paper sheet stored in the storage unit 5 can be changed, and has a fourth configuration in which the opening width is expanded when the transport mechanism 6 transports the paper sheet toward the insertion port 2.

  In the first or second configuration, the banknote handling apparatus A1 according to the second embodiment has a pair of conveyance members capable of sandwiching paper sheets stored in the storage unit 5 in the thickness direction, as shown in FIGS. (Driving roller 33a / pinch roller A33b) One side of the conveying member (pinch roller A33b) is deformed when it comes into contact with the paper sheet, and is elastic to return to the original shape from the deformed shape. The first contact member A331b that presses the paper sheets using force is provided, and the transport mechanism 6 is configured to be able to transport the paper sheets sandwiched by the transport member. A fifth configuration in which the relative distance between the pair of transport members is changed so that the first contact member A331b is brought into contact with the paper sheets when the inserted paper sheets are transported toward the storage unit 5. Have.

  According to the above configuration, when storing the paper sheet that conveys the paper sheet toward the storage unit 5, the first contact member A <b> 331 b is applied to the stacked paper sheets using the force generated by its elastic deformation. By abutting, a constant frictional force is applied between the transported paper sheet and the transport member (the first contact member A331b of the pinch roller A33b) without depending on the state of the stacked paper sheets. Be able to. Thereby, it becomes possible to perform the operation | movement at the time of paper sheet accommodation stably.

  In the fifth configuration, the conveyance member (pinch roller A33b) on one side has a diameter smaller than that of the first contact member A331b and is formed to be harder than the first contact member A331b. And a support shaft 36 on which the first contact member A331b and the second contact member 332b are disposed, and when the paper sheets stored in the storage unit 5 are conveyed toward the insertion port 2, The sixth configuration changes the relative distance between the pair of transport members so that the contact member 332b contacts the paper sheet.

  According to the above configuration, the paper sheet and the second contact member 332b are brought into contact with each other at the time of collecting the paper sheet that conveys the paper sheet toward the insertion port 2. Since the second contact member 332b is harder than the first contact member A331b, the second contact member 332b contacts the paper sheet as a result of the first contact member A331b being crushed. As a result, it is possible to selectively use the two types of contact portions (the first contact member A331b and the second contact member 332b) simply by changing the movement amount of the transport member, and unnecessary configuration and control are unnecessary. It leads to cost reduction.

  In the first configuration, the transport mechanism 6 includes an abutting member (pinch roller A33b) that abuts the surface of the paper sheet stored in the storage unit 5 in the thickness direction of the paper sheet. The surface of the abutment portion in the abutment portion is formed in an uneven shape in which two types of elastic members (first abutment member A331b and second abutment member 332b) having different hardnesses are alternately arranged. When the sheets inserted one by one in the insertion slot 2 are transported to the storage unit 5, the surface of the convex elastic member (first contact member A331b) contacts the surface of the sheet, and the storage unit 5, when a plurality of paper sheets stacked and accommodated in the sheet 5 are conveyed toward the insertion port 2, the convex shape is elastically deformed and the surface of the concave elastic member (second contact member 332 b) is the surface of the paper sheet. The seventh configuration is provided so as to change the contact force that contacts the surface of the paper sheet.

  According to the above configuration, the transport mechanism 6 generates a contact force against the paper sheet when transporting the paper sheet one by one from the insertion slot 2 and when transporting the paper sheet stored in the storage unit 5 toward the insertion slot 2. The contact force can be easily changed by utilizing the difference in hardness between the contact members (first contact member A331b and second contact member 332b). As a result, when a paper sheet is inserted from the insertion slot 2, the contact force is weakened to prevent jamming and the like, and conversely, the paper sheet is transported to the insertion slot 2 in a state where the paper sheets are stacked in the storage unit 5. In other words, by increasing the contact force, it is possible to stably convey a stack of stacked sheets to the insertion slot 2.

  The banknote handling apparatus 1 according to the first embodiment and the banknote handling apparatus A1 according to the second embodiment are inserted into the insertion slot 2 and the insertion slot 2 as shown in FIGS. A storage section 5 capable of storing a plurality of sheets in the thickness direction, a transport member (transport roller pair 33 / A33) capable of sandwiching the paper sheets stored in the storage section 5 in the thickness direction, and a transport member And a transport mechanism 6 capable of transporting the paper sheets sandwiched by the head toward the insertion slot 2 until the paper sheets are discharged from the insertion slot 2.

  In the eighth configuration, the transport member is composed of a pair of members (drive roller 33a, pinch roller 33b, A33b) disposed on both sides in the thickness direction of the paper sheets stored in the storage unit 5, and is connected to the transport member. And a drive source (cam motor 94) that is movable in a direction in which a sheet is sandwiched between a pair of members, and a control unit (control circuit board 100) that controls the drive source. The ninth configuration controls the drive source so that the frictional force between the conveying member and the paper sheets is smaller than the frictional force between the paper sheets.

  In the eighth or ninth configuration, a conveyance path 4 through which the paper sheet passes is provided between the insertion port 2 and the storage portion 5, and the conveyance path 4 has an opening width in the thickness direction of the paper sheet. The tenth configuration can be changed and the width of the opening is expanded when the sheets stored in the storage unit 5 are conveyed toward the insertion port 2.

  In any of the eighth to ninth configurations, the banknote handling apparatus 1 / A1 has an eleventh configuration in which the distance between the insertion port 2 and the transport member is shorter than the length of the paper sheet in the transport direction. Yes.

  In the ninth configuration, in the banknote handling apparatus A1 of Embodiment 2, the shape of the one side member (pinch roller A33b) is deformed when coming into contact with the paper sheet, and the shape is changed from the deformed shape to the original shape. A first abutting member A331b that presses the paper sheets by using the elastic force, and the transport mechanism 6 can transport the paper sheets inserted into the insertion port 2 toward the storage unit 5, When the paper sheet inserted into the insertion port 2 by the transport mechanism 6 is transported toward the storage unit 5, the control unit moves the pair of members between the pair of members so that the first contact member A331b is in contact with the paper sheet. Has a twelfth configuration for performing control to change the relative distance.

  According to the above configuration, when storing the paper sheet that conveys the paper sheet toward the storage unit 5, the first contact member A <b> 331 b is applied to the stacked paper sheets using the force generated by its elastic deformation. By abutting, a constant frictional force is applied between the transported paper sheet and the transport member without depending on the state of the stacked paper sheets. Thereby, it becomes possible to perform the operation | movement at the time of paper sheet accommodation stably.

  In the twelfth configuration, the conveying member on one side has a second contact member 332b that is smaller in diameter than the first contact member A331b and formed harder than the first contact member A331b, and a first contact member. A shaft (support shaft 36) on which the contact member A331b and the second contact member 332b are arranged, and when the paper sheets stored in the storage unit 5 are conveyed toward the insertion port 2, the second contact is made. A thirteenth configuration is provided to change the relative distance between the pair of conveying members (conveying roller pair A33) so that the member 332b is brought into contact with the paper sheet.

  According to the above configuration, the paper sheet and the second contact member 332b are brought into contact with each other at the time of collecting the paper sheet that conveys the paper sheet toward the insertion port 2. Since the second contact member 332b is harder than the first contact member A331b, the first contact member A331b is crushed and the second contact member 332b contacts the paper sheet. As a result, it is possible to selectively use two types of contact members (first contact member A331b and second contact member 332b) simply by changing the movement amount of the transport member, and unnecessary configuration and control are not required. This leads to cost reduction.

  In the banknote processing apparatus A1 having the eighth configuration, the transport mechanism 6 is in contact with the surface of the paper sheet stored in the storage unit 5 in the thickness direction of the paper sheet (pinch roller A33b). The surface of the contact portion of the contact member has an uneven shape in which two types of elastic members having different hardnesses are alternately arranged, and the sheets 5 inserted one by one in the insertion slot 2 are stored in the storage portion 5. In the case where the surface of the convex elastic member is in contact with the surface of the paper sheet and a plurality of paper sheets stacked and stored in the storage unit 5 are transported toward the insertion port 2, The fourteenth configuration is configured to change the contact force that contacts the surface of the paper sheet such that the convex shape is elastically deformed and the surface of the concave elastic member contacts the surface of the paper sheet.

  According to the above configuration, the conveyance mechanism 6 has a contact force with respect to the paper sheet when the sheet is conveyed one by one from the insertion slot 2 and when the sheet stored in the storage unit 5 is conveyed toward the insertion slot 2. It is possible to easily change the contact force by utilizing the difference in hardness of the contact member. As a result, when a paper sheet is inserted from the insertion slot 2, the contact force is weakened to prevent jamming and the like, and conversely, the paper sheet is transported to the insertion slot 2 in a state where the paper sheets are stacked in the storage unit 5. In other words, by increasing the contact force, it is possible to stably convey a stack of stacked sheets to the insertion slot 2.

  The banknote processing apparatus 1 according to the first embodiment and the banknote processing apparatus A1 according to the second embodiment, as shown in FIGS. 4 and 5, and a storage section 5 that forms a storage space in which paper sheets are stacked and stored, and storage A transport mechanism 6 for transporting paper sheets to the section 5, and a movable piece (stack section 37) provided in a direction orthogonal to the transport direction of the paper sheets transported by the transport mechanism 6 and capable of appearing in and out of the storage space The conveyance mechanism 6 stops the conveyance at a position where the rear end portion in the conveyance direction of the paper sheet conveyed to the storage unit 5 faces the movable piece, and then moves the movable piece to and from the movable piece. It has a fifteenth configuration in which the rear end portion of the paper sheets at the facing position is moved to the storage space side, and the paper sheets are stacked and stored in the storage space.

  In the fifteenth configuration, when the movable piece is positioned on the storage space side of the storage unit 5, the movable piece forms a carry-in space for carrying the paper sheets conveyed by the conveyance mechanism 6 into the storage unit 5. have.

  In the sixteenth configuration, an intrusion hole 12a formed in the wall portion of the storage portion 5 for allowing the movable piece to appear and retract, and a guide piece facing the movable piece and moving integrally with the movable piece (guide portion 38) And a drive source (stack gate motor 64) for moving the movable piece in and out, and a control unit (control circuit board 100) for controlling the drive source. The control unit is movable by controlling the drive source. After the piece is moved to the storage space side, the guide hole closes the intrusion hole 12a, and the conveyance mechanism 6 stops the conveyance at a position where the rear end of the paper sheet faces the movable piece. Moving from the storage space side to the carry-in space side to bring the movable piece into a state where it is immersed in the in / out hole 12a, and then returning from the state in which the movable piece is immersed in the in / out hole 12a to return to the storage space side 17th configuration to execute There.

  In any of the fifteenth to seventeenth configurations, the eighteenth configuration includes a pair of contact members (conveying roller pairs 33 and A33) that sandwich the sheets stacked and stored in the storage space. .

  In the bill processing apparatus A1 in the fifteenth configuration, the banknote processing apparatus A1 has an insertion port 2 into which a paper sheet is inserted, and the storage unit 5 is disposed at a position facing the movable piece, and is stacked and stored between the movable piece. A pressing plate A32 is provided to sandwich the paper sheets, and the pressing plate A32 moves in the direction of the storage unit 5 from the movement of the paper sheets in the direction of the insertion slot 2 on the contact surface with the stacked sheets. It has a nineteenth configuration having the first restricting portion A32a that has a large frictional force.

  According to said structure, when conveying the paper sheet inserted in the insertion port 2 to the accommodating part 5, it can prevent that the lamination | stacking state of the paper sheets laminated | stacked and accommodated in the accommodating part 5 is disturb | confused. .

  In the bill processing apparatus A1 in the fifteenth configuration, the movable piece is stacked and stored with the movable piece on the contact surface with the stacked and stored paper sheets, rather than the frictional force between the stacked and stored paper sheets. It has a twentieth configuration provided with a second restricting portion that increases the frictional force with the paper sheet.

  According to said structure, the destabilization at the time of the accommodation of the paper sheets by the paper sheets laminated | stacked and accommodated in the accommodating part 5 by the impact when a movable piece goes in and out with respect to carrying-in space will be prevented. can do.

  The banknote handling apparatus 1 according to the first embodiment and the banknote handling apparatus A1 according to the second embodiment are inserted into the insertion slot 2 and the insertion slot 2 as shown in FIGS. A storage unit 5 capable of storing a plurality of paper sheets stacked in the thickness direction, and a transport member (transport roller) capable of sandwiching the paper sheets stored in the storage unit 5 between one side and the other side in the thickness direction Pair 33 / A33), the transport mechanism 6 capable of transporting the paper sheets sandwiched by the transport member from the storage unit 5 to the insertion port 2, and the relative distance of the transport member between one side and the other side is changed. The twenty-first configuration includes a variable portion (variable mechanism 7) that can change the frictional force between the conveying member and the paper sheet and the frictional force between the paper sheets.

  In the twenty-first configuration, a drive source (cam motor 94) that is connected to the variable portion and is movable in a direction in which a sheet is sandwiched between one side and the other side of the transport member, and the drive source is controlled. Control unit (control circuit board 100) and a storage unit for storing the number of paper sheets stored in the storage unit 5, and the transport mechanism 6 is a paper sheet inserted into the insertion slot 2 The control unit has a twenty-second configuration that changes the relative distance according to the number of sheets stored in the storage unit.

  In the twenty-first or twenty-second configuration, a transport path 4 through which the paper sheet passes is provided between the insertion port 2 and the storage portion 5, and the transport path 4 has an opening width in the thickness direction of the paper sheet. It can be changed and has a twenty-third configuration in which the opening width is expanded when the paper sheets stored in the storage unit 5 are conveyed toward the insertion port 2.

  In the bill processing apparatus A1 of the twenty-second configuration, the member (pinch roller A33b) on one side deforms when it comes into contact with the paper sheet, and uses elastic force to return from the deformed shape to the original shape. The first contact member A331b that presses the paper sheet, the transport mechanism 6 can transport the paper sheet inserted into the insertion port 2 toward the storage unit 5, and the control unit transports the paper sheet. The relative distance between the pair of members is changed so that the first contact member A331b is brought into contact with the paper sheet when the paper sheet inserted into the insertion port 2 by the mechanism 6 is conveyed toward the storage unit 5. A twenty-fourth configuration for performing the above control.

  According to the above configuration, when storing the paper sheet that conveys the paper sheet toward the storage unit 5, the first contact member A <b> 331 b is applied to the stacked paper sheets using the force generated by its elastic deformation. By abutting, a constant frictional force is applied between the transported paper sheet and the transport member without depending on the state of the stacked paper sheets. Thereby, it becomes possible to perform the operation | movement at the time of paper sheet accommodation stably.

  In the twenty-fourth configuration, the conveying member on one side has a second contact member 332b that is smaller in diameter than the first contact member A331b and formed harder than the first contact member A331b, and a first contact member. A shaft (support shaft 36) on which the contact member A331b and the second contact member 332b are arranged, and when the paper sheets stored in the storage unit 5 are conveyed toward the insertion port 2, the second contact is made. The twenty-fifth configuration changes the relative distance between the pair of conveying members so that the member 332b is brought into contact with the paper sheet.

  According to the above configuration, the paper sheet and the second contact member 332b are brought into contact with each other at the time of collecting the paper sheet that conveys the paper sheet toward the insertion port 2. Since the second contact member 332b is harder than the first contact member A331b, the first contact member A331b is crushed and the second contact member 332b contacts the paper sheet. Thereby, it is possible to use two types of contact members properly only by changing the movement amount of the conveying member, and unnecessary configuration and control are not required, leading to cost reduction.

  In the bill processing apparatus A1 of the twenty-first configuration, the transport mechanism 6 is in contact with the surface of the paper sheet stored in the storage unit 5 in the thickness direction of the paper sheet (pinch roller A33b). The surface of the contact portion of the contact member has an uneven shape in which two types of elastic members having different hardnesses are alternately arranged, and the sheets 5 inserted one by one in the insertion slot 2 are stored in the storage portion 5. In the case where the surface of the convex elastic member is in contact with the surface of the paper sheet and a plurality of paper sheets stacked and stored in the storage unit 5 are transported toward the insertion port 2, The twenty-sixth configuration is configured to change the abutting force that abuts against the surface of the paper sheet so that the convex shape is elastically deformed and the surface of the concave elastic member abuts against the surface of the paper sheet.

  According to the above configuration, the transport mechanism 6 generates a contact force against the paper sheet when transporting the paper sheet one by one from the insertion slot 2 and when transporting the paper sheet stored in the storage unit 5 toward the insertion slot 2. It is possible to easily change the contact force using the difference in hardness of the contact member. As a result, when a paper sheet is inserted from the insertion slot 2, the contact force is weakened to prevent jamming and the like, and conversely, the paper sheet is transported to the insertion slot 2 in a state where the paper sheets are stacked in the storage unit 5. In other words, by increasing the contact force, it is possible to stably convey a stack of stacked sheets to the insertion slot 2.

  The banknote handling apparatus 1 according to the first embodiment and the banknote handling apparatus A1 according to the second embodiment are inserted into the insertion slot 2 and the insertion slot 2 as shown in FIGS. A storage unit 5 capable of storing a plurality of sheets stacked in the thickness direction, a transport mechanism 6 capable of discharging and transporting the paper sheets stored in the storage unit 5 toward the insertion port 2, and stored by the transport mechanism 6. 25th structure provided with the expansion mechanism 8 * A8 which changes the opening width of the insertion port 2 to the direction extended in the thickness direction, when conveying the paper accommodated in the part 5 toward the insertion port 2. have.

  In the twenty-fifth configuration, a pair of conveying members (conveying roller pair 33 / A33) capable of sandwiching sheets stored in the accommodating portion 5 in the thickness direction, and one conveying member (pinch roller 33b) of the pair of conveying members. A variable portion (variable mechanism 7) for moving A33b) toward the other conveying member (drive roller 33a), a cam (cam pulley A90) for operating the expansion mechanisms 8, A8 and the variable portion, and driving the cam A drive source (cam motor 94) and a control unit (control circuit board 100) for controlling the drive source are provided, and the pair of transport members are driven by the transport mechanism 6 to transport paper sheets, and the control unit When the paper sheets stored in the storage unit 5 are transported toward the insertion port 2 by the pair of transport members, the drive source is driven so as to sandwich the paper sheets stored in the storage unit 5. Control the variable part and open the insertion slot 2 Width, and has a structure of a 26 to control the expansion mechanism 8 · A8 to change in a direction to extend in the thickness direction.

  In the twenty-sixth configuration, the cam has a twenty-seventh configuration having a shape that stops the operation of one of the expansion mechanisms 8 and A8 and the variable portion during operation.

  In any one of the twenty-fifth to twenty-seventh configurations, the paper sheet that is disposed between the insertion port 2 and the storage unit 5 and that is inserted into the insertion port 2 is sandwiched in the thickness direction. Is provided with a pair of insertion conveyance members that can be driven so as to be conveyed toward the storage unit 5, and the expansion mechanism 8 / A 8 expands and changes the opening width of the insertion port 2, and the relative distance between the pair of insertion conveyance members The twenty-eighth configuration can be changed.

  In any one of the twenty-fifth to twenty-eighth configurations, the light emitting unit that is disposed on one side in the thickness direction of the paper sheet that passes between the insertion port 2 and the storage unit 5 and that emits light to the paper sheet A light receiving portion (light emitting / receiving unit 21a) that receives light from the light emitting portion and is disposed on the other side in the thickness direction of the sheet passing between the insertion opening 2 and the storage portion 5 (transmission light emitting portion 21b). The expansion mechanism 8 / A8 has a 29th configuration that can expand and change the opening width of the insertion slot 2 and can expand and change the relative distance between the light emitting unit and the light receiving unit. doing.

  In the twenty-ninth configuration, the reading unit 21 has a thirtieth configuration that is an image sensor.

  In the thirtieth configuration, when the control unit conveys a plurality of sheets stored in a stacking manner in the storage unit 5 toward the insertion port 2 by a pair of conveyance members, the control unit supplies a drive source (cam motor 94). By controlling the variable portion (variable mechanism 7) by driving, the relative force between the pair of conveying members is such that the frictional force between the conveying member and the paper sheet is smaller than the frictional force between the paper sheets. A thirty-first configuration for setting the distance is provided.

  In any of the 25th to 31st configurations, the control unit is connected to a storage unit that stores the number of sheets stored in the storage unit 5, and the sheets stored in the storage unit. In accordance with the number of sheets, the control unit has a thirty-second configuration that controls the variable unit to set the relative distance between the pair of transport members.

  In the banknote processing apparatus A1 of the twenty-sixth configuration, the paper path can pass between the insertion port 2 and the storage unit 5 and the transport path 4 can appear in and out of the transport path 4. And a shutter part A1121 for preventing the paper sheet from being conveyed in the direction of the insertion slot 2, and the shutter part A1121 has a thirty-third configuration configured to be operable by a cam (cam pulley A90). .

  According to the above configuration, it is not necessary to separately provide a drive source for driving the shutter portion A1121, leading to cost reduction.

  In the thirty-third configuration, the control unit 5 receives the storage unit 5 from when the paper sheet inserted into the insertion port 2 is stored in the storage unit 5 until the next paper sheet is inserted into the insertion port 2. The variable portion is controlled so as to sandwich the paper sheets stored in the paper, and the shutter portion A1121 is controlled to protrude into the conveyance path 4.

  According to the above configuration, it is possible to make it difficult to pull out the paper sheet by preventing the shutter part A1121 from pulling out and holding the paper sheet of the storage unit 5 by the pair of conveying members.

In the bill processing apparatus A1 of the twenty-sixth configuration, the pressing plate A32 disposed to face the paper sheets stored in the storage unit 5 and the paper sheet stored in the storage unit 5 in the thickness direction of the pressing plate A32 An urging portion (torsion coil spring 41) for maintaining a stacked state of a plurality of paper sheets stored in the storage portion 5 by urging toward the paper, and a paper sheet stored in the pressing plate A32. A second variable portion (second arm A85) that changes the relative distance of
The second variable unit is configured to be operable by a cam (cam pulley A90), and the control unit expands and changes the opening width of the insertion port 2 by the expansion mechanism A8, and also stores the paper stored in the pressing plate and the storage unit 5. A thirty-fifth configuration is provided to control the second variable unit so as to expand and change the relative distance to the leaves.

  According to the above configuration, the pressing plate can press the paper sheets by the biasing force of the biasing portion, while the second variable portion that expands and changes the opening width of the insertion port 2 can be operated by the cam. Has been. Thereby, since the pressing plate and the second variable portion operate independently, it is possible to prevent malfunctions when expanding the conveyance space.

1 Banknote processing device (paper sheet banknote processing device)
A1 banknote processing device (paper sheet banknote processing device)
2 Insertion Port 4 Transport Path 5 Storage Unit 6 Transport Mechanism 7 Variable Mechanism (Variable Section)
8 Expansion mechanism 12a Recessed hole 21 Reading unit 21a Light emitting / receiving unit (light receiving unit)
21b Light-emitting part for transmission
22, 23 Insertion and conveyance roller pair (a pair of insertion and conveyance members)
31 Stack gate 33 Transport roller pair (a pair of transport members)
37 Stack part (movable piece)
38 Guide (guide piece)
31a Loading space 64 Stack gate motor (drive source)
90 Cam plate (cam)
94 Cam motor (drive source)
100 control circuit board 101 CPU (control unit)
102 ROM
103 RAM (storage unit)

Claims (7)

A storage section that forms a storage space in which paper sheets are stacked and stored;
A transport mechanism for transporting paper sheets to the storage unit;
A movable piece that is provided in a direction orthogonal to the transport direction of the paper sheet transported by the transport mechanism, and that can move in and out of the storage space;
After the conveyance direction rear end of the sheet conveyed to the storage unit by the conveyance mechanism stops conveyance at a position facing the movable piece,
It is a hole for the movable piece to appear and appear, and the movable piece is caused to appear and disappear in an appearance hole formed in the wall portion of the storage portion , whereby the rear of the paper sheet located at a position facing the movable piece. A paper sheet processing apparatus, wherein an end portion is moved to the storage space side, and paper sheets are stacked and stored in the storage space.   The movable piece forms a carry-in space for carrying paper sheets conveyed by the conveyance mechanism into the storage unit when positioned on the storage space side of the storage unit. The paper sheet processing apparatus as described. A guide piece aforementioned movable piece facing, moves integrally with the movable piece,
A drive source for moving the movable piece in and out;
A control unit for controlling the drive source,
The control unit controls the drive source,
At the position where the movable piece is moved toward the storage space, the guide hole closes the intrusion hole,
After the conveyance mechanism stops the conveyance at a position where the rear end portion of the paper sheet faces the movable piece, the movable piece is moved from the storage space side to the carry-in space side, and the movable piece is moved to the loading space side. 3. The paper according to claim 2, wherein the paper is set in a state where it is immersed in an in / out hole, and thereafter, the in / out operation of returning the movable piece to the storage space side from the state of being immersed in the in / out hole is performed. Leaf processing equipment. The paper sheet processing apparatus according to any one of claims 1 to 3, characterized in that it comprises a pair of contact members for holding the stack housed paper sheets into the accommodation space. An insertion slot into which the paper sheet is inserted;
The storage unit is provided at a position facing the movable piece, and includes a pressing plate that sandwiches the paper sheets stacked and stored between the movable piece,
The pressing plate has a first restricting portion that has a larger frictional force on the contact surface with the stacked and stored paper sheets when the paper sheets are moved in the storage portion direction than in the insertion port direction. The paper sheet processing apparatus according to claim 1.   The movable piece has a frictional force between the movable piece and the stacked and stored paper sheets on the contact surface with the stacked and stored paper sheets, rather than a frictional force between the stacked and stored paper sheets. The sheet processing apparatus according to claim 1, further comprising a second restricting unit that increases the size of the sheet.   A game medium lending device installed in a gaming machine, comprising the paper sheet processing device according to any one of claims 1 to 6.