JP2017126171A - Medium processor and automatic transaction device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a medium processor and an automatic transaction device having a simpler configuration than conventional ones and capable of being miniaturized easily.SOLUTION: A rotation center P1 of an eccentric plate 64 and a rotation center P2 of a shaft 53 of a gate roller 44 supported by the eccentric plate 64 are eccentric to each other, so that a distance between the shaft 53 of the gate roller 44 and a shaft 51 of a feed roller 43 can be adjusted by rotating the eccentric plate 64. In addition, since the shaft 53 of the gate roller 44 and the rotation center P2 of the eccentric plate 64 are placed in a hole 64h for bearing of the eccentric plate 64, miniaturization can be easily achieved compared with conventional ones. Moreover, it is not necessary to additionally include an energization member and the like attached on a conventional adjustment mechanism, so that a configuration can be made simpler than conventional ones.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a medium processing apparatus and an automatic transaction apparatus. For example, the present invention is applied to an automatic teller machine (ATM) that performs a desired transaction with a user via a bill as a medium. And suitable.

  2. Description of the Related Art Conventionally, an automatic teller machine used in a financial institution, for example, a deposit / withdrawal unit that exchanges banknotes with a user, a discrimination unit that discriminates the denomination, authenticity, etc. of banknotes, and banknotes. It has a temporary holding part which temporarily holds, a banknote cassette which stores a banknote for every denomination, and a conveyance part which conveys a banknote to each part via a conveyance way.

  The deposit / withdrawal part and banknote cassette of such an automatic teller machine are provided with a banknote separating device that separates stored banknotes one by one and feeds them to the transport path. The banknote separating device feeds the banknotes stored therein to a feed roller by a pickup roller, and separates the fed banknotes one by one by a feed roller and a gate roller arranged to face each other in a nested manner. It comes to pay out.

  In such a banknote separating apparatus, if the distance between the feed roller and the gate roller (that is, the meshing amount) is too small, multiple feeds for simultaneously feeding out a plurality of banknotes may occur, while the meshing amount is too large. And banknotes cannot be paid out, and banknote jams may occur. For this reason, in the banknote separator, it is necessary to adjust the meshing amount of the feed roller and the gate roller to an appropriate amount.

  Therefore, as shown in FIG. 14, the conventional banknote separating apparatus has an adjustment mechanism 502 for adjusting the meshing amount of the feed roller 500 and the gate roller 501. The adjusting mechanism 502 includes an L-shaped gate holder 504 that can rotate around a rotation shaft 503 provided at a central corner. A shaft 505 of the gate roller 501 is supported on one end side of the gate holder 504. The gate roller 501 is fed with the feed roller 500 as the gate holder 504 rotates in the clockwise direction and the counterclockwise direction in the drawing. It is possible to move in a direction away from the feed roller 500 and a direction approaching the feed roller 500.

  Further, the gate holder 504 of the adjustment mechanism 502 is urged by the spring 506 in a direction to bring the gate roller 501 closer to the feed roller 500, and the tip of the adjustment screw 507 provided on the other end side pushes the fixed portion 508. By being applied, the rotation angle is maintained.

  In this adjustment mechanism 502, the rotation angle of the gate holder 504 can be changed by rotating the adjustment screw 507, whereby the position of the gate roller 501 with respect to the feed roller 500, that is, the meshing amount of the feed roller 500 and the gate roller 501. Can be adjusted (see, for example, Patent Document 1).

JP-A-7-137870

  However, the conventional adjustment mechanism such as the adjustment mechanism 502 has a complicated structure, and furthermore, the rotation axis of the gate holder must be provided at a position away from the shaft of the gate roller, and thus it is difficult to reduce the size. Had the problem.

  The present invention takes the above points into consideration, and intends to propose a medium processing apparatus and an automatic transaction apparatus that can be easily miniaturized with a simpler structure than conventional ones.

  In order to solve this problem, in the present invention, a storage unit that stores a medium, a feed roller that separates banknotes stored in the storage unit and feeds them out of the storage unit, and a shaft supported by the shaft, A gate roller disposed opposite to the roller, a hole is formed inside, the center of the outer diameter is located in the hole, and the center of the outer diameter and the center of the inner diameter that is the center of the hole are An eccentric plate at a shifted position, and an adjustment mechanism for changing an interval between the feed roller and the gate roller; and the shaft is fitted to the hole and supported by the eccentric plate, and the adjustment is performed. As the eccentric plate rotates, the mechanism moves the gate roller in a direction away from and toward the feed roller. Varying the distance over La and the gate roller.

  With such an adjustment mechanism, both the shaft of the gate roller and the center of rotation of the eccentric plate are disposed in the bearing hole of the eccentric plate, so that the size can be easily reduced compared to the conventional adjustment mechanism, and the gate roller is Since a biasing member or the like that biases the feed roller is not required, the configuration can be simplified as compared with a conventional adjustment mechanism.

  The present invention can realize a medium processing apparatus and an automatic transaction apparatus that have a simple configuration and can be easily reduced in size as compared with the prior art.

It is a perspective view which shows the external appearance structure of an automatic teller machine. It is a side view which shows the internal structure of a banknote depositing / withdrawing machine. It is a side view which shows the internal structure of the banknote separation apparatus provided in the deposit or withdrawal part in 1st Embodiment. It is an AA 'arrow figure of FIG. It is a side view which shows the structure of the adjustment mechanism which the banknote separation apparatus of the deposit or withdrawal part in 1st Embodiment has. It is a figure accompanying description of operation | movement of the adjustment mechanism in 1st Embodiment. It is a side view which shows the internal structure of the banknote separation apparatus provided in the banknote storage cassette in 1st Embodiment. It is a BB 'arrow figure of FIG. It is a side view which shows the structure of the adjustment mechanism and eccentric plate in 2nd Embodiment. It is a top view which shows the structure of the adjustment mechanism in 2nd Embodiment. It is a side view which shows the structure of the adjustment mechanism (1) in other embodiment. It is a side view which shows the structure of the adjustment mechanism (2) in other embodiment. It is a side view which shows the structure of the adjustment mechanism (3) in other embodiment. It is a side view which shows the structure of the conventional adjustment mechanism.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the invention will be described in detail with reference to the drawings.

[1. First Embodiment]
[1-1. Automatic teller machine configuration]
As shown in FIG. 1, the automatic teller machine 1 is configured with a box-shaped housing 2 as the center, and is installed in a financial institution, for example, for a deposit transaction or a withdrawal transaction with a customer. Transactions related to cash. Here, in the case 2 of the automatic teller machine 1, the side facing the user is the front side, the opposite is the rear side, and the top, bottom, left and right as viewed from the customer facing the front side are the upper side, the lower side, respectively. Defined as left side and right side.

  The automatic teller machine 1 is provided with a customer reception unit 3 at the upper front of a housing 2. The customer reception unit 3 includes a card entry / exit 4, a deposit / withdrawal port 5, an operation display unit 6, a numeric keypad 7, a receipt issuance port 8, and the like, and directly exchanges cash, a passbook, etc. with the customer, and information on transactions. This is the part that accepts notifications and operation instructions.

  The card entry / exit 4 is a portion into which various cards such as a cash card are inserted or ejected, and a card processing unit (for reading an account number magnetically recorded on the various cards) on the back side of the card entry / exit 4 ( (Not shown) is provided. The deposit / withdrawal port 5 is a portion where a bill to be deposited by a customer is inserted and a bill to be dispensed to the customer is discharged. The operation display unit 6 is integrated with an LCD (Liquid Crystal Display) that displays an operation screen at the time of transaction and a touch panel for selecting a transaction type, inputting a personal identification number, transaction amount, and the like. The numeric keypad 7 is a physical key that accepts input of numbers and the like, and is used at the time of input operation such as a password or transaction amount. The receipt issuing port 8 is a part that issues a receipt on which transaction details are printed at the end of transaction processing.

  In the housing 2, a main control unit 9 that controls and controls the entire automatic teller machine 1, a banknote depositing and dispensing machine 10 that performs various processes related to banknotes, and the like are provided. The main control unit 9 is mainly configured by a CPU (Central Processing Unit) (not shown), and a predetermined program is stored from a storage unit such as a ROM (Read Only Memory), a RAM (Random Access Memory), a hard disk drive, or a flash memory. Are read out and executed to control each unit to perform various processes such as deposit transactions and withdrawal transactions.

[1-2. Configuration of banknote deposit and withdrawal machine]

  As shown in FIG. 2, the banknote depositing / dispensing machine 10 is configured around a box-shaped depositing / dispensing machine housing 20, and the control unit 21 (FIG. 1) controls the banknote depositing / dispensing machine 10. The control unit 21 is configured around a CPU (not shown), and controls and controls each unit by reading and executing a predetermined program from the storage unit 22 (FIG. 1) including a ROM, a RAM, a hard disk drive, a flash memory, and the like. Various processes such as deposit transactions and withdrawal transactions are performed.

  On the upper side in the banknote depositing / dispensing machine 10, a depositing / dispensing unit 23 connected to the depositing / dispensing port 5, a discrimination unit 24 for discriminating the denomination and authenticity of the banknote, and a temporary storage for depositing banknotes, etc. A holding unit 25 is provided. The deposit / withdrawal port 5 is provided with a shutter (not shown), and when the shutter is opened and closed, the deposit / withdrawal port 5 is opened and closed. The temporary storage unit 25 may be an integrated type in which banknotes are sequentially stacked on the stage, or may be a drum type in which banknotes are sequentially wound around a drum.

  A plurality of banknote storage cassettes 26 (26A to 26C) for storing banknotes by denomination and a reject box 27 are provided below the banknote depositing and dispensing machine 10. Furthermore, the conveyance part 28 which conveys a banknote to each part is provided in the inside of the banknote depositing / withdrawing machine 10 via the conveyance path 28R. The transport unit 28 transports banknotes along the transport path 28R by a roller, a belt, or the like (not shown). In addition, a selector is provided at the branch point of the transport path 28R, and the banknote transport destination can be switched by this selector.

  Further, each of the deposit / withdrawal unit 23, the temporary storage unit 25, and the banknote storage cassette 26 (26A to 26C) separates banknotes stored therein and feeds them to the transport path 28R. 25s and 26s.

  Furthermore, the bill depositing / dispensing machine 10 can be pulled out to the outside of the depositing / dispensing machine housing 20 as a lower unit 30 at the lower part including the bill storage cassette 26 (26A to 26C) and the reject storage 27. Yes.

  The banknote depositing / dispensing machine 10 has such a configuration, and the control unit 21 controls each unit based on the banknote discrimination result by the discrimination unit 24 to perform banknote depositing and dispensing processing.

  That is, the automatic teller machine 1 opens the shutter at the time of deposit transaction, and when the banknote is inserted into the deposit / withdrawal port 5 by the customer, the shutter is closed and the inserted banknote is fed out from the deposit / withdrawal unit 23 one by one. To the discrimination unit 24. Here, the automatic teller machine 1 transports the banknotes determined as depositable banknotes based on the discrimination result of the discrimination unit 24 to the temporary storage unit 25 and temporarily stores them, but is not suitable for depositing. Is returned to the deposit / withdrawal unit 23 and returned to the customer by opening the shutter.

  Thereafter, when the deposit transaction with the customer is confirmed, the automatic teller machine 1 conveys the banknotes stored in the temporary holding unit 25 to the discrimination unit 24 to obtain a discrimination result. Here, the automatic teller machine 1 conveys and stores the banknote determined to be storable based on the discrimination result of the discrimination unit 24 to the banknote storage cassette 26 (26A to 26D) corresponding to the denomination. . On the other hand, the automatic teller machine 1 transports and stores the banknotes determined to be unacceptable banknotes that are not suitable for storage to the reject box 27.

  Moreover, the automatic teller machine 1 recognizes the number of banknotes for each denomination required according to the amount requested by the customer during the withdrawal transaction, and the banknote storage cassette 26 (26A) according to the number of banknotes for each denomination. To 26D), the bills are fed out and conveyed to the discrimination unit 24 to obtain a discrimination result. Here, the automatic teller machine 1 determines that the banknote determined to be withdrawable on the basis of the discrimination result of the discrimination unit 24 to the depositing / withdrawing unit 23, and determines that the banknote is not suitable for withdrawal. The bills that have been sent are transported to the reject box 27 for storage. When the bills for the requested amount are accumulated in the deposit / withdrawal unit 23, the automatic teller machine 1 opens the shutter. As a result, the banknotes accumulated in the deposit / withdrawal unit 23 can be received, and the customer receives the banknotes.

[1-3. Configuration of banknote separator provided in deposit / withdrawal unit]
Next, the structure of the banknote separator 23s provided in the deposit / withdrawal unit 23 will be described in more detail. As shown in FIG. 3, the deposit / withdrawal unit 23 is provided with a banknote separator 23 s at the front of the storage unit 40 that stacks banknotes in the front-rear direction.

  The banknote separating device 23s is fed by the pickup roller 41 that picks up the banknotes accumulated in the storage unit 40, the bill press 42 that presses the banknotes accumulated in the storage unit 40 against the pickup roller 41, and the pickup roller 41. It has a feed roller 43 and a gate roller 44 for separating the banknotes one by one, and a feed roller 45 for feeding the separated banknotes to the transport path 28R.

  The pickup roller 41 is provided such that a part thereof protrudes from the front wall 40 f of the storage unit 40. The pick-up roller 41 is a friction part 41f in which a part of the outer peripheral surface is formed of a friction member such as rubber so that a bill can be reliably fed out. A plurality of (for example, two) pickup rollers 41 are provided on a shaft 50 extending in the left-right direction. The bill press 42 is a plate-like member that is slidable in the front-rear direction in the storage unit 40 in a state parallel to the front wall 40 f of the storage unit 40.

  The bill press 42 is stacked in a state in which bills are stacked between the bill press 42 and the front wall 40f of the storage unit 40, by sliding in a direction approaching the front wall 40f of the storage unit 40. Is pressed against the pickup roller 41. The pickup roller 41 rotates counterclockwise in the drawing so that the bill pressed by the bill press 42 is fed out to the feed roller 43 and the gate roller 44.

  The feed roller 43 is disposed downstream of the pickup roller 41 in the bill feeding direction (that is, below the pickup roller 41). Like the pickup roller 41, a part of the outer peripheral surface is a friction portion 43f. As shown in FIG. 4, a plurality of (for example, nine) feed rollers 43 are provided on a shaft 51 extending in the left-right direction. FIG. 4 is a view taken along the line AA ′ of FIG. 3, and is a view of the feed roller 43 and the gate roller 44 as viewed from the pickup roller 41 side.

  Specifically, the shaft 51 is provided with one feed roller 43A at the center in the left-right direction, and a feed roller portion 52A in which the left and right three feed rollers 43 are integrated with the left and right sides of the feed roller 43A. 52B, and one feed roller 43B and 43C are provided on the left side of the left feed roller portion 52A and the right side of the right feed roller portion 52B, respectively.

  The gate roller 44 is arranged to face the feed roller 43 in the thickness direction of the banknotes fed by the pickup roller 41 (that is, to be arranged behind the feed roller 43), and the entire outer peripheral surface is a friction portion. As shown in FIG. 4, a plurality of (for example, four) gate rollers 44 are provided on a shaft 53 extending in the left-right direction, and are arranged to face the plurality of feed rollers 43 in a nested manner. .

  Specifically, on the shaft 53, gate roller portions 54A and 54B in which the left and right gate rollers 44 are integrated are arranged at positions facing the two left and right feed roller portions 52A and 52B, respectively. . Further, in each of the gate roller portions 54 </ b> A and 54 </ b> B, part of the outer periphery of the two left and right gate rollers 44 is nested between the three left and right feed rollers 43. In this case, the overlap amount Lp between the outer peripheral surface of the feed roller 43 and the outer peripheral surface of the gate roller 44 is the meshing amount Lp of the feed roller 43 and the gate roller 44.

  The feed roller 43 and the gate roller 44 are engaged in a nested manner, and only the feed roller 43 rotates counterclockwise in FIG. The sheet is separated from the gate roller 44 and fed out one by one.

  The feed roller 45 is disposed downstream of the feed roller 43 in the banknote feeding direction (that is, downward) and opposed to the feed roller 43 in the banknote thickness direction. A plurality of (for example, three) feed rollers 45 are also provided on a shaft 55 extending in the left-right direction. Specifically, one feed roller 45 is disposed at a position facing the three feed rollers 43A, 43B, and 43C in total in the center and the left and right.

  The feed roller 45 rotates clockwise in FIG. 3 in the direction opposite to that of the feed roller 43 so that the banknotes fed by the feed roller 43 and the gate roller 44 are clamped between the feed roller 43 and It is sent out to a conveyance path 28R outside the deposit / withdrawal unit 23.

  As shown in FIG. 3, the deposit / withdrawal unit 23 is provided with a guide 56 along a path for feeding the banknote from the storage unit 40 to the transport path 28 </ b> R, and the banknote is stored along the guide 56. 40 is fed out to the conveyance path 28R.

  In addition to such a configuration, the banknote separating device 23 s has an adjustment mechanism 60 that adjusts the distance between the feed roller 43 and the gate roller 44 (that is, the meshing amount). As shown in FIGS. 4 and 5, the adjustment mechanism 60 has frames 61 provided at the left and right ends of the banknote separating apparatus 23 s. Since the adjustment mechanism 60 has a bilaterally symmetric configuration, the same portions on the left and right will be described with the same reference numerals.

  The left and right frames 61 are respectively formed with circular bearing holes 63 (FIG. 5) to which bearings 62 serving as bearings for the shaft 51 of the feed roller 43 are fixed. A bearing 62 is attached to the bearing hole 63. Furthermore, left and right ends of the shaft 51 are inserted into the left and right bearings 62. That is, the left and right frames 61 rotatably support the shaft 51 of the feed roller 43 via the bearings 62.

  Further, circular plate holes 65 (FIG. 5) into which the eccentric plates 64 are fitted are formed in the left and right frames 61, respectively, behind the bearing holes 63. The eccentric plate 64 has a circular disc shape and a hollow disc portion 64a in which a bearing hole 64h is formed on the inside, and a substantially fan-shaped plate shape, and a plurality of grooves 64g on an arc-shaped outer peripheral surface. It is comprised with the fan-plate part 64b formed in this.

  The hollow disc portion 64a has an eccentric structure in which the center P1 of the outer diameter and the center of the inner diameter (that is, the center of the bearing hole 64h) P2 are shifted by a predetermined distance d1 in a predetermined direction. This distance d1 is referred to as an eccentric distance d1. On the other hand, the fan plate portion 64b has a shape obtained by cutting out the center side of the fan shape into a triangular shape, and is parallel to the hollow disk portion 64a and shifted by one step in the thickness direction so that the hollow disk portion 64a It extends outward from the outer edge of one surface in the thickness direction.

  The fan plate portion 64b is formed so that the outer peripheral surface is along a circular arc concentric with the center P1 of the hollow disc portion 64a. The fan plate portion 64b is formed on the side opposite to the center P2 of the inner diameter when viewed from the center P1 of the outer diameter of the hollow disc portion 64a. Further, the fan plate portion 64b has seven grooves 64g formed on the arc-shaped outer peripheral surface, and the central groove 64g of the seven grooves 64g is the center of the outer diameter of the hollow disk portion 64a. It is formed on a line segment connecting P1 and the inner diameter center P2. Further, on both sides of the central groove 64g, one groove 64g is formed at a position deviated from the central groove 64g by 10 degrees, 20 degrees, and 30 along the arc-shaped outer periphery.

  The eccentric plate 64 is configured as described above, and is rotatably supported by the left and right frames 61 by fitting the hollow disc portions 64a into the plate holes 65 of the left and right frames 61, respectively. Further, as shown in FIG. 4, the left and right eccentric plates 64 have fan plate portions 64b, which are located outside the left and right frames 61, with the fan plate portions 64b being displaced in the thickness direction from the hollow disc portions 64a. 64b does not hinder the rotation of the hollow disk portion 64a. That is, the left and right eccentric plates 64 are supported by the left and right frames 61 so as to be rotatable around the center P1 of the outer diameter of the hollow disc portion 64a.

  Further, bearings 70 are attached to the respective bearing holes 64h (FIG. 5) of the left and right eccentric plates 64. Further, left and right ends of the shaft 53 of the gate roller 44 are inserted into the left and right bearings 70. That is, the left and right frames 61 rotatably support the shaft 53 of the gate roller 44 via the left and right eccentric plates 64 and the left and right bearings 70.

  Since the center P2 of the inner diameter of the hollow disc portion 64a of the eccentric plate 64 and the center of the shaft 53 of the gate roller 44 coincide with each other, the center of the shaft 53 of the gate roller 44 is relative to the rotation center P1 of the eccentric plate 64. It will be eccentric.

  A line segment connecting the shaft 51 of the feed roller 43 and the shaft 53 of the gate roller 44 and a line segment connecting the center P1 of the outer diameter and the center P2 of the inner diameter of the hollow disc portion 64a of the eccentric plate 64 are orthogonal to each other. The rotation angle of the eccentric plate 64 at that time (that is, the rotation angle shown in FIG. 5) is set as a reference angle. Further, the eccentric direction of the eccentric plate 64 at this time is the downward direction, the fan plate portion 64b is positioned above the direction opposite to the eccentric direction of the hollow disc portion 64a, and the center P1 of the outer diameter of the eccentric plate 64 is A central groove 64g of the fan plate portion 64b is located immediately above. Further, the distance between the center P3 of the shaft 51 of the feed roller 43 and the center P2 of the shaft 53 of the gate roller 44 (referred to as the inter-shaft distance) is defined as a reference inter-shaft distance d2 ′. The meshing amount Lp of the gate roller 44 is set as a reference meshing amount.

  Further, the adjustment mechanism 60 has the positions of the upper surfaces of the left and right frames 61 substantially equal to the positions of the outer peripheral surfaces of the fan plate portions 64b of the left and right eccentric plates 64. One groove 61g having the same shape as the groove 64g is formed at a position facing and communicating with the groove 64g at the center of the fan 64b of the eccentric plate 64 at an angle. The adjusting mechanism 60 rotates the eccentric plate 64 clockwise or counterclockwise in FIG. 5 so that the groove 64g on the eccentric plate 64 side communicating with the groove 61g of the frame 61 is sequentially switched. It has become.

  Further, a cylindrical portion 61s into which the winding portion 71a of the torsion spring 71 is fitted is provided at the upper part of the outer surface of each of the left and right frames 61, and is projected to the left and right cylindrical portions 61s. Each of the winding portions 71a of the torsion spring 71 is inserted. Furthermore, a fixing portion 61f for fixing one arm 71b of the torsion spring 71 is provided on the outer surface of each of the left and right frames 61 below the cylindrical portion 61s, and the torsion is provided on each of the left and right fixing portions 61f. One arm 71b of the spring 71 is fixed.

  The other arm 71 c of the torsion spring 71 extends from the columnar part 61 s to the groove 61 g and is bent in a direction from the outer side to the inner side of the frame 61. When the left and right torsion springs 71 are in a natural state in which no external force is applied, the distal ends of both the left and right frames 61 and the groove 64g on the side of the eccentric plate 64 that communicates with the groove 61g, respectively. When the bent portion enters, the left and right eccentric plates 64 are fixed so as not to rotate with respect to the left and right frames 61, respectively.

  In addition, the left and right torsion springs 71 can release the fixation of the left and right eccentric plates 64 by pushing the bent portion at the tip of the other arm 71c upward so as to remove it from the grooves 61g and 64g, and return to the original position by elastic force. By returning, the left and right eccentric plates 64 can be fixed by entering the grooves 61g and 64g again.

  In the adjusting mechanism 60, the left and right eccentric plates 64 are individually rotated from the reference angle in the clockwise direction and the counterclockwise direction in FIG. Here, if the clockwise direction in the figure is the + direction and the counterclockwise direction is the-direction, the adjusting mechanism 60 individually moves the left and right eccentric plates 64 to +30 degrees to -30 degrees around the reference angle. It will be rotated in the range. Further, since the groove 61g of the frame 61 and the groove 64g of the eccentric plate 64 communicate with each other when the eccentric plate 64 is rotated by 10 degrees, the left and right eccentric plates 64 can be fixed in units of 10 degrees.

  The adjustment mechanism 60 includes these left and right frames 61, left and right eccentric plates 64, and left and right torsion springs 71.

  Here, a method for adjusting the meshing amount Lp of the feed roller 43 and the gate roller 44 by this adjusting mechanism will be described. As described above, the left and right eccentric plates 64 of the adjusting mechanism 60 are unlocked and rotated by pushing the left and right torsion springs 71 upward.

  Here, as shown in FIG. 6A, when the eccentric plate 64 is rotated clockwise from the reference angle in the drawing, the gate roller is rotated with respect to the rotation center (ie, the center of the outer diameter) P1 of the eccentric plate 64. Since the center P2 of the shaft 53 of the shaft 44 is eccentric, the shaft 53 of the gate roller 44 moves in a direction away from the shaft 51 of the feed roller 43 (that is, rearward). That is, the adjusting mechanism 60 can adjust the shaft distance d2 to be larger than the reference shaft distance d2 ′ by rotating the eccentric plate 64 clockwise from the reference angle.

  When the rotation angle from the reference angle at this time is θ, the eccentric distance is d1, and the adjustment distance formed by the difference between the inter-shaft distance d2 and the reference inter-shaft distance d2 ′ is d3, the adjustment distance d3 = the eccentric distance d1 × sin θ. Become.

  In the adjustment mechanism 60, as described above, the eccentric plate 64 is rotated from the reference angle in the clockwise direction in the drawing to 30 degrees in units of 10 degrees. That is, in the adjustment mechanism 60, the eccentric plate 64 is moved 10 degrees (sin θ = 0.17...), 20 degrees (sin θ = 0.34...), 30 degrees (sin θ = 0. 5), the adjustment distance d3 can be adjusted to increase the inter-shaft distance d2 while increasing the adjustment distance d3 by almost a constant amount.

  As described above, the adjustment mechanism 60 adjusts the meshing amount Lp between the feed roller 43 and the gate roller 44 to be smaller than the reference meshing amount by adjusting the inter-shaft distance d2 to be larger than the reference shaft-to-shaft distance d2 ′. be able to. Incidentally, when the eccentric plate 64 is rotated in the clockwise direction (+ direction) in the figure from the reference angle, the adjustment distance d3 continues to increase until at least +90 degrees from the reference angle. Therefore, in the adjustment mechanism 60, the rotation range in the + direction from the reference angle of the eccentric plate 64 is set to +30 degrees within +90 degrees.

  On the other hand, as shown in FIG. 6B, when the eccentric plate 64 is rotated counterclockwise in the figure from the reference angle, the shaft 53 of the gate roller 44 moves in a direction approaching the shaft 51 of the feed roller 43. Will do. That is, in the adjusting mechanism 60, the shaft-to-shaft distance d2 can be adjusted to be narrower than the reference shaft-to-shaft distance d2 ′ by rotating the eccentric plate 64 counterclockwise from the reference angle. Also in this case, adjustment distance d3 = eccentric distance d1 × sin θ.

  In the adjustment mechanism 60, as described above, the eccentric plate 64 is rotated from the reference angle in the counterclockwise direction in the drawing to 30 degrees in units of 10 degrees. That is, in the adjustment mechanism 60, the eccentric plate 64 is moved 10 degrees (sin θ = 0.17...), 20 degrees (sin θ = 0.34...), 30 degrees (sin θ = 0) from the reference angle in the counterclockwise direction in the figure. .5), the adjustment distance d3 can be adjusted in the direction of decreasing the inter-shaft distance d2 while increasing the adjustment distance d3 by a substantially constant amount.

  As described above, the adjusting mechanism 60 adjusts the meshing amount Lp between the feed roller 43 and the gate roller 44 to be larger than the reference meshing amount by adjusting the inter-shaft distance d2 to be narrower than the reference shaft distance d2 ′. be able to. Incidentally, when the eccentric plate 64 is rotated in the counterclockwise direction (− direction) in the figure from the reference angle, the adjustment distance d3 continues to increase until at least −90 degrees from the reference angle. Therefore, in the adjusting mechanism 60, the rotation range in the − direction from the reference angle of the eccentric plate 64 is set to −30 degrees within −90 degrees.

  Since the adjustment distance d3 can be expressed by the eccentric distance d1 × sin θ, for example, in order to finely adjust the meshing amount Lp of the feed roller 43 and the gate roller 44, the eccentric distance d1 is reduced or the rotation interval of the eccentric plate 64 is adjusted. (That is, the interval between the grooves 64g) may be made smaller than 10 degrees.

  As described above, the adjustment mechanism 60 can adjust the meshing amount Lp between the feed roller 43 and the gate roller 44 by a simple operation by simply rotating the eccentric plate 64. Actually, the operator rotates the eccentric plate 64 to adjust the meshing amount Lp to an appropriate meshing amount Lp, and then returns the torsion spring 71 to the original position to fix the rotational angle of the eccentric plate 64. Thereby, the meshing amount Lp is fixed at an appropriate meshing amount Lp.

  In this manner, the adjusting mechanism 60 of the deposit / withdrawal unit 23 adjusts the meshing amount Lp between the feed roller 43 and the gate roller 44.

  Further, since the adjusting mechanism 60 has eccentric plates 64 that can be independently rotated on the left and right ends of the shaft 53 of the gate roller 44, the adjusting mechanism 60 includes a gate roller portion 54 </ b> A provided on the left side of the center of the shaft 53. The meshing amount Lp with the feed roller portion 52A is adjusted mainly by the rotation of the eccentric plate 64 supported by the left frame 61, and the gate roller portion 54B and the feed roller portion provided on the right side from the center of the shaft 53. The meshing amount Lp with 52B can be adjusted mainly by the rotation of the eccentric plate 64 supported by the right frame 61. Further, by rotating the left and right eccentric plates 64 independently, the inclination of the shaft 53 of the gate roller 44 with respect to the shaft 51 of the feed roller 43 so that the shaft 51 of the feed roller 43 and the shaft 53 of the gate roller 44 are parallel to each other. Can also be adjusted.

  Further, the adjusting mechanism 60 rotates the eccentric plate 64 so that the shafts of the feed roller 43 and the gate roller 44 are rotated because the center P2 of the shaft 53 of the gate roller 44 is eccentric with respect to the rotation center P1 of the eccentric plate 64. The distance d2 can be adjusted. In this case, since the orbit of the shaft 53 of the gate roller 44 is a circular orbit, when the eccentric plate 64 is rotated, the shaft 53 of the gate roller 44 is only in the front-rear direction. There is also a slight movement in the vertical direction.

  As described above, when the shaft 53 of the gate roller 44 moves not only in the left-right direction but also in the up-down direction, for example, the feeding direction of the banknote by the feed roller 43 and the gate roller 44 which should be vertically downward shifts from the vertically downward to the front-back direction. It will be. However, even if the feeding direction is slightly deviated, a guide 56 is provided on the downstream side of the banknote feeding direction by the feed roller 43 and the gate roller 44, so that the fed banknote is normally conveyed along the guide 56. Is done.

  Incidentally, the adjustment of the meshing amount Lp between the feed roller 43 and the gate roller 44 of the deposit / withdrawal unit 23 is performed at the time of assembling the deposit / withdrawal unit 23, for example.

[1-4. Configuration of banknote separator provided in banknote storage cassette]
Next, the configuration of the bill separator 26s provided in the bill storage cassette 26 (26A to 26C) will be described in more detail. Since the bill storage cassettes 26A to 26C have the same configuration, only the configuration of the bill separation device 26s provided in the bill storage cassette 26A will be described here. As shown in FIG. 7, the banknote storage cassette 26 </ b> A is provided with a banknote separator 26 s on the upper part of the storage unit 80 that stacks banknotes in the vertical direction.

  The banknote separating device 26s includes a pickup roller 81 that feeds banknotes accumulated in the storage unit 80, a stage 82 that places the banknotes and presses the banknotes stacked in the storage unit 80 against the pickup roller 81, and a pickup roller. A feed roller 83 and a gate roller 84 for separating the banknotes fed by 81 one by one, and a feed roller 85 for feeding the separated banknotes to the conveyance path 28R.

  The pickup roller 81 is provided such that a part thereof protrudes from the upper wall 80 u of the storage unit 80. In the pickup roller 81, a part of the outer peripheral surface serves as a friction portion 81f so that bills can be reliably fed out. A plurality of (for example, two) pickup rollers 81 are provided on a shaft 90 extending in the left-right direction. The stage 82 is a plate-like member that can slide in the storage unit 80 in the vertical direction (vertical direction) in a state parallel to the upper wall 80u of the storage unit 80 (horizontal state).

  The stage 82 is configured to press the accumulated banknotes against the pickup roller 81 by sliding in a direction approaching the upper wall 80 u of the storage unit 80 in a state where the banknotes are accumulated on the stage 82. The pickup roller 81 rotates counterclockwise in the drawing so that the banknote pressed by the stage 82 is fed out to the feed roller 83 and the gate roller 84.

  The feed roller 83 is disposed downstream of the pickup roller 81 in the bill feeding direction (that is, in front of the pickup roller 81). Like the pickup roller 81, a part of the outer peripheral surface is a friction portion 83f. As shown in FIG. 8, a plurality of (for example, nine) feed rollers 83 are provided on a shaft 91 extending in the left-right direction. FIG. 8 is a view taken along the line BB ′ of FIG. 7 and shows the feed roller 83 and the gate roller 84 as viewed from the pickup roller 81 side.

  Specifically, the shaft 91 is provided with one feed roller 83A at the center in the left-right direction, and a feed roller portion 92A in which three left and right feed rollers 83 are integrated with the left and right sides of the feed roller 83A. 92B, and one feed roller 83B and 83C are provided on the left side of the left feed roller portion 92A and the right side of the right feed roller portion 92B, respectively.

  The gate roller 84 is disposed to face the feed roller 83 in the thickness direction of the bills fed by the pickup roller 81 (that is, disposed to face the lower side of the feed roller 83), and the entire outer peripheral surface is a friction portion. As shown in FIG. 8, a plurality of (for example, four) gate rollers 84 are provided on a shaft 93 extending in the left-right direction, and are arranged to face the plurality of feed rollers 83 in a nested manner. .

  Specifically, on the shaft 93, gate roller portions 94A and 94B in which two left and right gate rollers 84 are integrated are arranged at positions facing the two left and right feed roller portions 92A and 92B, respectively. . Further, in each of the gate roller portions 94A and 94B, a part of the outer periphery of the two left and right gate rollers 84 is nested between the three left and right feed rollers 83. In this case, the overlap amount Lp between the outer peripheral surface of the feed roller 83 and the outer peripheral surface of the gate roller 84 is the meshing amount Lp of the feed roller 83 and the gate roller 84.

  The feed roller 83 and the gate roller 84 are engaged in a nested manner, and only the feed roller 83 rotates counterclockwise in FIG. The sheet is separated from the gate roller 84 and fed out one by one.

  The feed roller 85 is disposed downstream of the feed roller 83 in the bill feeding direction (that is, in front), facing the feed roller 83 in the bill thickness direction. A plurality of (for example, three) feed rollers 85 are also provided on a shaft 95 extending in the left-right direction. Specifically, one feed roller 85 is disposed at each position facing the three feed rollers 83A, 83B, 83C in total in the center and the left and right.

  The feed roller 85 rotates clockwise in FIG. 7 in the direction opposite to that of the feed roller 83, so that the banknotes fed by the feed roller 83 and the gate roller 84 are sandwiched between the feed roller 83 and It is sent out to the conveyance path 28R outside the bill storage cassette 26A.

  The banknote storage cassette 26A is provided with a guide 96 along a path for feeding banknotes from the storage section 80 to the transport path 28R. The banknotes are transferred from the storage section 80 to the transport path 28R along the guide 96. It comes to pay out.

  In addition to such a configuration, the banknote separating device 26s includes an adjustment mechanism 100 that adjusts the interval (that is, the meshing amount) between the feed roller 83 and the gate roller 84. The adjustment mechanism 100 included in the banknote separator 26s of the banknote storage cassette 26A is obtained by changing the direction of the adjustment mechanism 60 included in the banknote separator 23s of the deposit / withdrawal unit 23 according to the positional relationship between the feed roller 83 and the gate roller 84. Since the configuration is the same, detailed description is omitted.

  That is, in the adjustment mechanism 100 included in the banknote separating device 26s of the banknote storage cassette 26A, the feed roller 83 and the gate can be easily operated just by rotating the eccentric plate 64, similarly to the adjustment mechanism 60 provided in the deposit / withdrawal unit 23. The meshing amount Lp of the roller 84 can be adjusted. The adjustment of the engagement amount Lp between the feed roller 83 and the gate roller 84 of the banknote storage cassette 26A is also performed, for example, when the banknote storage cassette 26A is assembled.

  In addition, about the banknote separation apparatus 25s of the temporary storage part 25, since it is the same structure as the banknote separation apparatus 26s of 26 A of banknote storage cassettes, description is abbreviate | omitted. Further, the banknote separating device 25s of the temporary storage unit 25 can also be provided with an adjustment mechanism (not shown) similar to the adjustment mechanism 100 provided in the banknote storage cassette 26A. In this case, the meshing amount of the feed roller and the gate roller can be adjusted by a simple operation by simply rotating the eccentric plate.

[1-5. Summary and Effect]
As described so far, in the first embodiment, the adjustment mechanism 60 that adjusts the interval between the feed roller 43 and the gate roller 44 (that is, adjusts the meshing amount Lp) in the banknote separating device 23s of the deposit / withdrawal unit 23. Was provided. The adjusting mechanism 60 has left and right frames 61 provided on both left and right sides of the shaft 51 of the feed roller 43 and the shaft 53 of the gate roller 44, and the shaft of the feed roller 43 is interposed by the left and right frames 61 via bearings 62. The left and right ends of 51 are rotatably supported.

  Furthermore, the adjusting mechanism 60 rotatably supports the eccentric plate 64 composed of the hollow disc portion 64a and the fan plate portion 64b by the left and right frames 61. The eccentric plate 64 is rotatably supported by the frame 61 by fitting the hollow disc portion 64 a into the plate hole 65 formed in the frame 61.

  The hollow disc 64a of the eccentric plate has an eccentric structure in which the center P1 of the outer diameter serving as the center of rotation and the center P2 of the bearing hole 64h formed on the inner side (that is, the center of the inner diameter) P2 are shifted. The bearing 70 is fixed to the hole 64h, and the left and right ends of the shaft 53 of the gate roller 44 are inserted into the bearing 70. Thereby, the center P2 of the shaft 53 of the gate roller 44 is eccentric with respect to the rotation center P1 of the eccentric plate 64.

  For this reason, in the adjustment mechanism 60, when the eccentric plate 64 is rotated, the shaft 53 of the gate roller 44 can be moved in a direction away from and closer to the shaft 51 of the feed roller 43 according to this. Thereby, the meshing amount Lp of the feed roller 43 and the gate roller 44 can be adjusted.

  Furthermore, in the adjusting mechanism 60, since the shaft 53 of the gate roller 44 and the rotation center P2 of the eccentric plate 64 are both disposed in the bearing hole 64h of the eccentric plate 64, the gate holder is positioned away from the shaft of the gate roller. Compared to a conventional adjustment mechanism in which a rotation shaft is provided, the size can be easily reduced. Since the adjustment mechanism 60 can be easily downsized in this way, the deposit / withdrawal unit 23 having the adjustment mechanism 60 can also be downsized.

  Further, in the adjusting mechanism 60, one of the plurality of grooves 64 g formed on the outer periphery of the fan plate portion 64 b of the eccentric plate 64 and one groove 61 g formed on the frame 61 determine the rotation angle of the eccentric plate 64. The tip of the arm 71c of the torsion spring 71 is fitted into the two grooves 64g and 61g in a communicated state so that the eccentric plate 64 is attached to the frame 61 at a predetermined rotation angle. The meshing amount of the feed roller 43 and the gate roller 44 can be fixed.

  As described above, the adjustment mechanism 60 does not require a biasing member or the like provided in the conventional adjustment mechanism, so that the configuration can be simplified as compared with the conventional adjustment mechanism.

  In addition, since the position of the eccentric plate 64 is fixed by the frame 61, the adjusting mechanism 60 has the eccentric plate 64 itself even if a force in the direction of increasing the engagement amount Lp is applied to the feed roller 43 and the gate roller 44. The meshing amount of the feed roller 43 and the gate roller 44 can be kept constant without moving away from the feed roller 43. For this reason, in the adjustment mechanism 60, even if the banknotes are fed out in a state of being fed by the pickup roller 41, they can be reliably separated one by one by the feed roller 43 and the gate roller 44.

[2. Second Embodiment]
Next, a second embodiment will be described. In the second embodiment, the configuration of the adjustment mechanism is different from that of the first embodiment. Since the configuration other than the adjustment mechanism is the same as that of the first embodiment, the first embodiment is referred to for the detailed description.

[2-1. Configuration of adjustment mechanism]
9 and 10 show an adjusting mechanism 200 according to the second embodiment. Here, the adjustment mechanism 200 provided in the banknote separating device 23s of the deposit / withdrawal unit 23 will be described as an example. However, as in the first embodiment, the banknote storage cassette 26 and the integrated temporary storage unit 25 are also provided. Assume that a similar adjustment mechanism is provided.

  9A is a side view showing the adjustment mechanism 200 in a state of being covered with the exterior cover 201 of the deposit / withdrawal unit 23, FIG. 9B shows the eccentric plate 202, and FIG. It is a top view which shows the adjustment mechanism 200 of the covered state. In FIGS. 9 and 10, the same parts as those of the adjusting mechanism 60 of the first embodiment are denoted by the same reference numerals.

  As shown in FIG. 9A, in the second embodiment, the left and right plate holes 65 formed in the left and right frames 61 of the adjustment mechanism 200 on the upper surface of the exterior cover 201 of the deposit / withdrawal unit 23, respectively. An operation hole 201 h that enables the operation of the eccentric plate 202 and the torsion spring 71 is formed above the upper portion of the operation hole 201 h.

  The left and right eccentric plates 202 rotatably supported by the left and right frames 61 each have a fan plate portion 202b extending from the hollow disc portion 202a to the upper operation hole 201h, and an arcuate outer periphery of the fan plate portion 202b. The surface is exposed to the outside from an operation hole 201 h formed on the upper surface of the exterior cover 201. Thus, the operator can touch the outer peripheral surfaces of the left and right eccentric plates 202 exposed from the left and right operation holes 201h to rotate the left and right eccentric plates 202.

  As in the first embodiment, seven grooves 202g are formed on the outer peripheral surface of the fan plate portion 202b. Of the seven grooves 202g, the central groove 202g is formed on the hollow disk portion 202a. It is formed on a line segment connecting the center P10 of the outer diameter and the center P11 of the inner diameter. Further, on each side of the central groove 202g, one groove 202g is formed at a position shifted from the central groove 202g by 10 degrees, 20 degrees, and 30 degrees along the arc-shaped outer periphery.

  Furthermore, inside each of the left and right operation holes 201h formed on the upper surface of the exterior cover 201, grooves are formed at positions that communicate with the central groove 202g of the fan plate portion 202b of the eccentric plate 202 at the reference angle. One groove 201g having the same shape as 202g is formed.

  Further, a cylindrical part 201s into which the winding part 71a of the torsion spring 71 is fitted is provided at the upper part on the inner side of the exterior cover 201, and the torsion springs 71 are respectively provided on the left and right cylindrical parts 201s. The winding part 71a is inserted. Further, inside the exterior cover 201, fixing portions 201f for fixing one arm 71b of the torsion spring 71 are provided below the left and right columnar portions 201s, and the left and right fixing portions 201f are respectively connected to the torsion springs. One arm 71b of 71 is fixed.

  The other arm 71 c of the torsion spring 71 extends from the columnar part 201 s to the groove 201 g and is bent in a direction from the outer side to the inner side of the frame 61. As shown in FIG. 10, the left and right torsion springs 71 have bent portions at the leading ends of both the groove 201 g of the left and right exterior covers 201 and the groove 202 g on the side of the eccentric plate 202 communicating with the groove 201 g. The left and right eccentric plates 202 are fixed to the exterior cover 201 so as not to rotate.

  In the left and right torsion springs 71, the other arm 71c is exposed from the operation hole 201h, and the bent portion of the tip of the arm 71c exposed by the operator from the operation hole 201h is formed in the grooves 201g and 202g. The left and right eccentric plates 202 can be unlocked by pushing upwards so as to be removed, and by returning to their original positions by elastic force, the left and right eccentric plates 202 can be fixed again by entering the grooves 201g and 202g. Yes.

  Note that the adjustment method by the adjustment mechanism 200 having such a configuration is the same as that of the first embodiment, and thus the description thereof is omitted.

  As described above, the adjustment mechanism 200 according to the second embodiment is configured such that the fan plate portion 202b of the eccentric plate 202 is exposed from the exterior cover 201 of the deposit / withdrawal portion 23 and can be rotated. After the assembly of the portion 23 is completed, the meshing amount Lp between the feed roller 43 and the gate roller 44 of the deposit / withdrawal portion 23 can be adjusted.

  Further, by providing an adjustment mechanism similar to the adjustment mechanism 200 in the banknote storage cassette 26, the meshing amount Lp between the feed roller 83 and the gate roller 84 of the banknote storage cassette 26 can be adjusted after the assembly of the banknote storage cassette 26 is completed. Can do.

  Further, by providing a similar adjustment mechanism in the integrated temporary storage unit 25, the amount of engagement between the feed roller and the gate roller of the temporary storage unit 25 can be adjusted after the assembly of the temporary storage unit is completed.

[2-2. Summary and Effect]
As described so far, in the second embodiment, the left and right operation holes 201h are provided in the exterior cover 201 of the deposit / withdrawal unit 23, and the left and right eccentric plates 202 of the adjustment mechanism 200 are respectively connected to the left and right operation holes 201h. The outer peripheral surface of the fan plate portion 202b (that is, the portion where the groove 202g is formed) and the arms 71c of the left and right torsion springs 71 are exposed.

  Thereby, the rotation operation of the eccentric plate 202 and the fixing operation and the fixing release operation of the eccentric plate 202 using the torsion spring 71 can be performed from the operation hole 201 h of the exterior cover 201 of the deposit / withdrawal portion 23. By doing so, in the second embodiment, the engagement amount Lp between the feed roller 43 and the gate roller 44 of the deposit / withdrawal unit 23 can be adjusted after the assembly of the deposit / withdrawal unit 23 is completed.

  Further, by providing the same adjustment mechanism in the banknote storage cassette 26 and the integrated temporary storage unit 25, in the banknote storage cassette 26 and the integrated temporary storage unit 25, after the assembly is completed, the feed roller and the gate roller The amount of meshing can be adjusted.

  Further, after the assembly is completed in this way, the amount of engagement between the feed roller and the gate roller of the deposit / withdrawal unit 23, the bill storage cassette 26, and the temporary storage unit 25 can be adjusted. The amount of meshing can be adjusted without bothering disassembling the deposit / withdrawal unit 23, the banknote storage cassette 26 and the temporary storage unit 25 when the amount of meshing is reduced by cutting.

  In particular, in the banknote storage cassette 26, the operator can easily access the operation hole of the exterior cover by pulling it out from the depositing / dispensing machine housing 20, so that it is much easier than the depositing / dispensing unit 23 and the temporary storage unit 25. The meshing amount of the feed roller and the gate roller can be adjusted.

[3. Other Embodiments]
[3-1. Other Embodiment 1]
In the first embodiment described above, the plurality of grooves 64g are formed at equal intervals on the outer peripheral surface of the fan plate portion 64b of the eccentric plate 64. However, the present invention is not limited to this. A plurality of grooves 64g may be formed so that the distance between the grooves 64g increases as the distance increases. For example, 15 degrees (sin θ = 0.26...), 31 degrees (sin θ = 0.52...), 50 degrees (sin θ) from the central groove 64 g on both sides of the central groove 64 g along the arc-shaped outer periphery. = 0.77 ...) The grooves 64g may be formed at positions shifted from each other. In order to increase the adjustment distance d3 by a certain amount for each groove 64g, the position of the groove 64g may be determined so that the increase in the value of sin θ is constant.

  Further, the rotational angle of the eccentric plate 64 may not be fixed discretely, such as every 10 degrees, but may be continuously fixed at an arbitrary angle.

  Specifically, as shown in FIG. 11A, one fan plate 210b as the second member of the eccentric plate 210 extends in an arc shape and penetrates in the thickness direction instead of the plurality of grooves 64g. Holes 210h are provided. The hole 210h is provided along an arc of a circle concentric with the center P20 of the hollow disk portion 210a as the first member, and connects the outer diameter center P20 and the inner diameter center P21 of the hollow disk portion 210a. Centering on the line segment, each extends in the range of 30 degrees in the clockwise direction and the counterclockwise direction in the figure.

  On the other hand, on the frame 61 side, instead of the groove 61g, one screw hole 61h facing the hole 210h of the eccentric plate 210 is provided above the center of the plate hole 65. The screw hole 61h always communicates with the hole 210h of the eccentric plate 210 while the eccentric plate 210 rotates within a range of 30 degrees in the clockwise direction and counterclockwise direction in the drawing from the reference angle.

  Further, when a screw 211 that can be inserted into the hole 210h of the eccentric plate 210 and has a head having a diameter larger than the width of the hole 210h is screwed into the screw hole 61h, the space between the head of the screw 211 and the frame 61 is increased. The eccentric plate 210 is fixed to the frame 61 by sandwiching the fan plate portion 210 b of the eccentric plate 210.

  That is, in this case, as shown in FIG. 11B, the screw 211 is screwed into the screw hole 61h of the frame 61 through the hole 210h of the eccentric plate 210 with the eccentric plate 210 rotated to an arbitrary rotation angle. Thus, the eccentric plate 210 can be fixed at the rotation angle at this time. With such a configuration, the rotation angle of the eccentric plate 210 can be continuously fixed at an arbitrary angle. Such a configuration may be applied to the second embodiment.

[3-2. Other Embodiment 2]
In the first embodiment described above, the rotation angle of the eccentric plate 64 is fixed by the torsion spring 71 as a fixing member. However, the rotation angle is not limited to this, and the eccentric plate 64 is fixed by various elastic members. Also good. For example, as shown in FIGS. 12A and 12B, instead of the torsion spring 71, a plate spring 220 or a plate spring 221 is used as a fixing member, and the eccentric plate 64 is rotated by the plate spring 220 or the plate spring 221. The angle may be fixed.

  Specifically, in the leaf spring 220 shown in FIG. 12A, one end side is fixed to the frame 61 and the other end side is at a position facing the outer peripheral surface of the fan plate portion 64b of the eccentric plate 64, and the other end is located. A claw portion 220a is bent to the outer peripheral surface side (that is, downward) of the fan plate portion 64b.

  When the leaf spring 220 having such a configuration is in a natural state, the claw portion 220a is fitted into the groove 61g of the frame 61 and the groove 64g of the eccentric plate 64 communicating with the groove 61g. The plate 64 is fixed so as not to rotate with respect to the frame 61. In addition, the leaf spring 220 can release the fixation of the eccentric plate 64 by pushing the claw portion 220a at the tip upward so as to remove it from the grooves 61g and 64g, and return to the original position by the elastic force, so that the claw portion again. 220a enters the grooves 61g and 64g to fix the eccentric plate 64.

  On the other hand, the leaf spring 221 shown in FIG. 12B is fixed to the frame 61 at both ends so as to straddle the fan plate portion 64b of the eccentric plate 64 in the rotation direction, and the surface on the fan plate portion 64b side (that is, the bottom surface). ) Is provided with a protrusion 221a that protrudes toward the outer peripheral surface side (that is, downward) of the fan 64b. In addition, the leaf spring 221 is provided with a protrusion 221b that protrudes on the opposite side to the protrusion 221a at the center of the surface opposite to the surface on the fan plate 64b side (that is, the upper surface).

  When the leaf spring 221 having such a configuration is in a natural state, the protrusion 221a is fitted into the groove 61g of the frame 61 and the groove 64g of the eccentric plate 64 communicating with the groove 61g. The plate 64 is fixed so as not to rotate with respect to the frame 61. In addition, the plate spring 221 can release the fixation of the eccentric plate 64 by an operator by pinching the protruding portion 221b and lifting the protruding portion 221a upward so as to remove the protruding portion 221a from the grooves 61g and 64g. By returning, the protrusion 221a enters the grooves 61g and 64g again to fix the eccentric plate 64. In addition, you may apply the leaf | plate springs 220 and 221 which consist of such a structure to 2nd Embodiment.

  Furthermore, you may make it fix the rotation angle of the eccentric plate 64 not only using such an elastic member but using various fixing members. For example, the rotation angle of the eccentric plate 64 is fixed by fitting a rod-shaped fixing member made of metal or the like into the groove 61g of the frame 61 and the groove 64g of the eccentric plate 64 communicating with the groove 61g. You may make it do.

[3-3. Other Embodiment 3]
Furthermore, in the first embodiment described above, in the eccentric plate 64, the fan plate portion 64b is provided on the side opposite to the center P2 of the inner diameter when viewed from the center P1 of the outer diameter of the hollow disc portion 64a. However, the present invention is not limited to this. For example, as shown in FIG. 13A, the fan plate portion 64b is provided on the same side as the center P2 of the inner diameter as viewed from the center P1 of the outer diameter of the hollow disc portion 64a. You may do it.

  As described above, when the positional relationship between the center P2 of the inner diameter and the fan plate 64b as viewed from the center P1 of the outer diameter of the hollow disc portion 64a is changed, the rotational direction of the eccentric plate 64 and the increase / decrease in the inter-shaft distance d2 The relationship will also change.

  That is, as shown in FIG. 13B, an eccentric plate 64x having a fan plate portion 64b provided on the same side as the center P2 of the inner diameter when viewed from the center P1 of the outer diameter of the hollow disc portion 64a is When rotating in the rotating direction, the shaft 53 of the gate roller 44 moves in a direction approaching the shaft 51 of the feed roller 43, contrary to when the eccentric plate 64 is rotated in the clockwise direction, and the distance between the shafts d2 is adjusted in a direction narrower than the reference shaft distance d2 ′.

  On the other hand, although illustration is omitted, when the eccentric plate 64x is rotated in the counterclockwise direction in the drawing, the shaft 53 of the gate roller 44 is opposite to the case where the eccentric plate 64 is rotated in the counterclockwise direction. The feed roller 43 moves in a direction away from the shaft 51, and the inter-shaft distance d2 is adjusted to be wider than the reference inter-shaft distance d2 ′.

  Thus, in the eccentric plate 64x in which the fan plate portion 64b is provided on the same side as the inner diameter center P2 when viewed from the outer diameter center P1 of the hollow disc portion 64a, the eccentric plate 64x is rotated in the clockwise direction. The inter-shaft distance d2 is reduced, and the inter-shaft distance d2 is increased when the shaft is rotated counterclockwise.

  In this case, when viewed from the operator, the eccentric plate 64x is rotated clockwise to bring the fan plate portion 64b closer to the feed roller 43, thereby reducing the inter-shaft distance d2 and moving the fan plate portion 64b away from the feed roller 43. Thus, since the distance d2 between the shafts is increased by rotating the eccentric plate 64x in the counterclockwise direction, the relationship between the rotation direction of the eccentric plate 64x and the increase / decrease in the distance d2 between the shafts becomes more intuitive and easy to understand. Further, the meshing amount of the feed roller 43 and the gate roller 44 can be adjusted.

  Similarly, in the second embodiment, the fan plate portion 202b may be provided on the same side as the inner diameter center P11 when viewed from the outer diameter center P10 of the hollow disk portion 202a. In addition, the center P1 of the outer diameter and the center P2 of the inner diameter of the hollow disc portion 64a of the eccentric plate 64 need only be shifted.

[3-4. Other Embodiment 4]
Furthermore, in the first embodiment described above, the angle when the central groove 64g of the fan plate portion 64b of the eccentric plate 64 is in a position communicating with the groove 61g of the frame 61 is defined as the reference angle of the eccentric plate 64. did. Here, for example, the central groove 64g can be easily distinguished from the other grooves 64g by coloring the central groove 64g with a color different from that of the other grooves 64g or by sticking a seal to the central groove 64g. You may do it.

  In this way, the operator can easily check which groove 64g of the plurality of grooves 64g is the groove 64g corresponding to the reference angle, and therefore how much the eccentric plate 64 is in which direction from the reference angle. It becomes possible to easily and accurately grasp whether the meshing amount is adjusted by rotating. The same applies to the second embodiment.

[3-5. Other Embodiment 5]
Furthermore, in the first embodiment described above, the fan plate portion 64b is located outside the left and right frames 61 by positioning the fan plate portion 64b displaced in the thickness direction from the hollow disc portion 64a of the eccentric plate 64. Does not hinder the rotation of the hollow disk portion 64a. For example, a groove (not shown) or a hole having a size larger than the movable range of the fan part 64b is provided in the left and right frames 61, and the fan part 64b is rotated in the groove or hole. The fan plate portion 64b does not hinder the rotation of the hollow disc portion 64a and does not protrude outside the frame 61, so that the fan plate portion 64b is not damaged. Can be prevented.

[3-6. Other Embodiment 6]
Furthermore, in the first embodiment described above, the rotation range of the eccentric plate 64 is set to a range of +30 degrees to −30 degrees with the reference angle as the center. However, the rotation range of the eccentric plate 64 is not limited to this, as long as the adjustment distance d3 is within a range of +90 degrees to -90 degrees when the eccentric plate 64 is rotated in the + direction or the − direction. It may be made wider or narrower. Moreover, you may provide the stopper which contacts the fan-plate part 64b so that the eccentric plate 64 may not rotate exceeding the rotation range in the left and right frames 61.

[3-7. Other Embodiment 7]
Furthermore, in the second embodiment described above, the fan plate portion 202b of the eccentric plate 202 extends to the operation hole 201h of the exterior cover 201 and is exposed. However, the present invention is not limited to this, for example, the first embodiment. An operation knob (not shown) is connected to the fan plate portion 64b of the eccentric plate 64 having the same structure as that of the eccentric plate 64 via a gear (not shown), and the operation knob is exposed from the operation hole 201h. The eccentric plate 64 may be rotated.

[3-8. Other Embodiment 8]
Furthermore, in the first embodiment described above, the bearing 70 is attached to the bearing hole 64 h as a hole formed inside the eccentric plate 64, and the shaft 53 of the gate roller 44 is inserted into the bearing 70. The eccentric plate 64 supports the shaft 53 of the gate roller 44 via the bearing 70.

  Not limited to this, the bearing 70 may be omitted, and the eccentric plate 64 may directly support the shaft 53 of the gate roller 44. In this case, for example, instead of the bearing hole 64h, a shaft hole (not shown) corresponding to the diameter of the shaft 53 is formed inside the eccentric plate 64, and the shaft 53 is formed in the shaft hole. So that the eccentric plate 64 directly supports the shaft 53 of the gate roller 44. As with the bearing hole 64h, the shaft hole is formed such that its center is deviated from the center P1 of the outer diameter of the eccentric plate 64, and the center P1 is located in the shaft hole. Shall.

  In this way, the shaft 53 of the gate roller 44 may be fitted into the hole formed inside the eccentric plate 64 via the bearing 70, or the gate roller 44 directly without using the bearing 70. The shaft 53 may be fitted. The same applies to the second embodiment and the other embodiments 1 to 7 described above.

[3-9. Other Embodiment 9]
Furthermore, in each embodiment mentioned above, although this invention was applied to the deposit or withdrawal part 23, the banknote storage cassette 26, and the temporary storage part 25 as a medium processing apparatus and a medium accommodation delivery part, this invention is applied to this. Not limited to this, as long as it has a medium separating device for separating and feeding out a medium, the present invention is also applicable to a medium processing device and a medium storing and feeding unit having a different configuration from the deposit / withdrawal unit 23, the bill storage cassette 26, and the temporary storage unit 25. it can.

  Furthermore, in each embodiment mentioned above, although this invention was applied to the automatic teller machine 1 as an automatic transaction apparatus, not only this but the automatic transaction apparatus which has a medium separation apparatus which isolate | separates and pays out a medium. For example, the present invention can be applied to an automatic transaction apparatus having a configuration different from that of the automatic teller machine 1. For example, even if it is an automatic transaction apparatus which handles media other than banknotes, such as paper and a ticket, if it is an automatic transaction apparatus which has a medium separation apparatus which isolate | separates and pays out a medium, it is applicable.

  Furthermore, in the above-described first embodiment, the eccentric plate 64 is configured by the hollow disc portion 64a as the first member and the fan plate portion 64b as the second member. Moreover, in 2nd Embodiment mentioned above, the eccentric plate 202 was comprised with the hollow disc part 202a as a 1st member, and the fan-plate part 202b as a 2nd member. Not limited to this, for the first member, a hole is formed on the inner side, the center of the outer diameter is located in the hole, and the center of the outer diameter and the center of the inner diameter that is the center of the hole. As long as it is a disc-shaped member at a position shifted from each other, a member having a shape or size different from that of the hollow disc portions 64a and 202a may be used. Moreover, about the 2nd member, if it is a member which has a circular-arc-shaped outer peripheral surface which is a part of a circle concentric with the 1st member, a member having a different shape and size from the fan plate portions 64b and 202b is used. Also good.

[3-10. Other Embodiment 10]
Furthermore, the present invention is not limited to the above-described embodiments. That is, the scope of the present invention is applicable to embodiments in which a part or all of the first and second embodiments described above and other embodiments are arbitrarily combined, and embodiments in which a part is extracted. It extends.

  INDUSTRIAL APPLICABILITY The present invention can be widely used in a medium separating apparatus that separates media and an automatic transaction apparatus having a medium separating apparatus.

  DESCRIPTION OF SYMBOLS 1 ... Automatic teller machine, 23 ... Deposit / withdrawal part, 25 ... Temporary holding part, 26 ... Banknote storage cassette, 28 ... Conveyance part, 28R ... Conveyance path, 40, 80 ... Storage part, 41 81 ... Pickup roller, 43, 83, 500 ... Feed roller, 44, 84, 501 ... Gate roller, 50, 51, 53, 55, 90, 91, 93, 95, 505 ... Shaft, 52, 92 …… Feed roller portion, 54, 94 …… Gate roller portion, 60, 100, 200, 502 …… Adjustment mechanism, 61 …… Frame, 61g, 64g, 201g, 202g …… Groove, 61h …… Screw hole, 62, 70 ... Bearing, 63 ... Bearing hole, 64, 64x, 202, 210 ... Eccentric plate, 64a, 202a, 210a ... Hollow disc, 64b, 202b, 210b ... Fan plate portion, 64h ...... bearing hole, 71 ...... torsion spring, 201 ...... exterior cover, 201h ...... operation hole, 210h ...... holes, 220, 221 ...... plate spring.

Claims (13)

A storage section for storing the medium;
A feed roller that separates banknotes stored in the storage unit and feeds them out of the storage unit;
A gate roller supported by a shaft and disposed opposite to the feed roller;
A hole is formed on the inner side, the center of the outer diameter is located in the hole, and there is an eccentric plate at a position where the center of the outer diameter is shifted from the center of the inner diameter that is the center of the hole. And an adjustment mechanism for changing the interval between the feed roller and the gate roller,
The shaft is fitted to the hole and supported by the eccentric plate,
The adjusting mechanism is configured to change a distance between the feed roller and the gate roller by moving the gate roller in a direction away from and closer to the feed roller as the eccentric plate rotates. A medium processing apparatus. A bearing is attached to the hole of the eccentric plate,
The medium processing apparatus according to claim 1, wherein the shaft is inserted into the bearing and supported by the eccentric plate. In the eccentric plate, a plurality of grooves are formed along the rotation direction of the eccentric plate,
The adjustment mechanism is
The medium processing apparatus according to claim 1, further comprising a fixing member that fits into a groove formed in the eccentric plate and fixes a rotation angle of the eccentric plate. The fixing member is made of an elastic member, and is fitted into a groove formed in the eccentric plate in a natural state, and is elastically deformed to be disengaged from the groove formed in the eccentric plate. 4. The medium processing apparatus according to 3. The adjustment mechanism is
The medium processing apparatus according to claim 1, further comprising a frame that rotatably supports the feed roller and the eccentric plate. The eccentric plate is
The hole is formed inside, the center of the outer diameter is located in the hole, and the center of the outer diameter and the center of the inner diameter which is the center of the hole are shifted from each other. And a second member having an arcuate outer peripheral surface which is formed on the outer side of the first member and is a part of a circle concentric with the first member, and the outer peripheral surface of the second member The plurality of grooves are formed in
The frame includes
A groove communicating with the groove formed in the second member is formed;
The fixing member is fitted in both the groove formed in the second member of the eccentric plate and the groove of the frame and fixes the eccentric plate to the frame, thereby fixing the rotation angle of the eccentric plate. The medium processing apparatus according to claim 5. The eccentric plate is
The medium processing apparatus according to claim 6, wherein the second member is formed on a side opposite to a side where the center of the inner diameter is located when viewed from the center of the outer diameter of the first member. . The eccentric plate is
The medium processing apparatus according to claim 6, wherein the second member is formed on the same side as the side on which the center of the inner diameter is located when viewed from the center of the outer diameter of the first member. An exterior cover covering the adjustment mechanism;
The adjustment mechanism is
The medium processing apparatus according to claim 1, wherein a part of the eccentric plate is exposed from an operation hole formed in the exterior cover. The adjustment mechanism is
When the eccentric plate is rotated in one direction from the reference angle, the gap between the feed roller and the gate roller is increased, and when the eccentric plate is rotated in the other direction from the reference angle, the feed roller and the gate roller The position of the center of the outer diameter, the position of the center of the inner diameter, and the rotation range from the reference angle of the eccentric plate are selected so that the interval is narrowed. The medium processing apparatus as described. The eccentric plate is
The medium processing apparatus according to any one of claims 1 to 10, wherein the gate roller is rotatably provided on one end side and the other end side of the shaft of the gate roller. The adjustment mechanism is
A frame that rotatably supports the feed roller and the eccentric plate;
The eccentric plate is
The hole is formed inside, the center of the outer diameter is located in the hole, and the center of the outer diameter and the center of the inner diameter which is the center of the hole are shifted from each other. And a second member formed on the outer side of the first member and having a hole extending in an arc shape that is a part of a circle concentric with the first member,
The frame includes
While the eccentric plate rotates, a hole that communicates with the hole formed in the second member is formed at all times,
Furthermore, the adjustment mechanism includes:
It has a fixing member that fixes the rotation angle of the eccentric plate by fitting both the hole formed in the second member of the eccentric plate and the hole of the frame and fixing the eccentric plate to the frame. The medium processing apparatus according to claim 1. A medium transport path;
A medium storing and feeding unit for storing the medium transported through the transport path and separating the stored medium one by one and feeding the medium to the transport path;
The medium storing and feeding part is
A storage section for storing the medium;
A feed roller for separating and feeding out the banknotes stored in the storage unit to the transport path;
A gate roller supported by a shaft and disposed opposite to the feed roller;
A hole is formed on the inner side, the center of the outer diameter is located in the hole, and the center of the outer diameter is shifted from the center of the inner diameter, which is the center of the hole. An adjustment mechanism for changing a gap between the feed roller and the gate roller,
The shaft is fitted to the hole and supported by the eccentric plate,
The adjusting mechanism is configured to change a distance between the feed roller and the gate roller by moving the gate roller in a direction away from and closer to the feed roller as the eccentric plate rotates. An automatic transaction apparatus characterized by

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