JP2012159906A - Card processing device equipped with stored card dispensing mechanism - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a card processing device equipped with a stored card dispensing mechanism capable of surely dispensing cards one by one from a card stacker even if a card has a deformation such as warpage.SOLUTION: In a card stacker 14 of a card processing device 1, cards are stored in a stacked state in a thickness direction. A stored card dispensing mechanism 90 which pushes out a card C1 stacked on a top of the card stacker 14 to a card conveyance path 13 is provided with a pair of card engaging claws 91, 92 capable of engaging from behind with a card end face Ca of a card in the opposite side from the direction of pushing out the card C1, at symmetrical positions separate from each other, and the claws are pressed against the surface of the card C1 by spring force. By sliding the card engaging claws 91, 92 forward with a claw sliding mechanism 95, the card C1 can be surely dispensed forward.

Description

  The present invention relates to a card processing apparatus provided with a card stacker used for a game machine. More specifically, the present invention relates to a card processing apparatus provided with a storage card feeding mechanism for reliably sending out storage cards stored in a stacked state in a card stacker toward a card transport path.

  In gaming facilities such as pachinko parlors, gaming media are lent out in order to play on the gaming machine in a machine between the gaming machines arranged adjacent to the gaming machine. In recent years, intermediary machines that can lend out game media using a recording medium such as a magnetic card or an IC card instead of cash have become widespread. Such an inter-machine includes a card processing device including a card reader / writer and a card stacker together with a money processing device such as a bill validator. For example, it is configured to issue a prepaid card in which an amount corresponding to the amount to be inserted is stored, and when the prepaid card is inserted, the monetary information held in the prepaid card is read and the gaming medium is lent out. .

  Patent Document 1 proposes a card issuing device that includes a read / write unit including an RF antenna. In this card processing apparatus, the card inserted from the card insertion / ejection port is sent to the read / write unit by a transport mechanism comprising a transport belt, and the card fed further from the read / write unit is stacked in a direction perpendicular to the transport direction. They are stored in a state. Thus, by arranging the read / write unit and the card storage unit in a tandem state along the linear conveyance path, the card issuing device can be made flat.

  Patent Document 2 proposes a similar card processing apparatus. In the card processing device disclosed herein, the pressing lever is moved in a direction orthogonal to the card conveying direction by a card that passes through the read / write unit including the RF antenna and is stored in the card storage unit. ing. Since the card stored in the card storage unit can be pushed down by the pressing lever, the read / written card can be stored in the card storage unit without interfering with the card stored in the card storage unit.

  In the card processing devices disclosed in these patent documents, the card is stored in a card storage unit (card stacker) in a state where the cards are stacked in the thickness direction, and the card is conveyed by a sliding claw member perpendicular to the stacking direction. By pushing in the direction, it is sent out to the side of the card transport path, for example, the read / write section.

Japanese Patent No. 3832176 JP 2005-92454 A

  Here, such a slide-type claw member needs to be hooked from the rear side on the rear end face of the uppermost card located at the top of the stacked cards and slid in the transport direction in this state. That is, since it is necessary to engage the claw member only with the rear end face of the narrowest width (thickness) in the uppermost card, a large engagement allowance cannot be taken. For this reason, if the card is deformed such as warping, the claw member may not be reliably hooked to the rear end surface of such a card. If the claw member does not reliably engage the rear end surface of the card, the card cannot be pushed out reliably.

  In view of these points, an object of the present invention is to propose a card processing device including a storage card payout mechanism that can be reliably pushed out of a card stacker even if the card has deformation such as warping. .

In order to solve the above-mentioned problem, a card processing device provided with a storage card payout mechanism of the present invention,
A card insertion outlet,
A card stacker that can store cards stacked in the thickness direction;
A card transport path from the card insertion / discharge port to the card stacker;
A card transport mechanism for transporting a card along the card transport path;
Among the storage cards stored in the card stacker, there is a storage card feeding mechanism that pushes the uppermost stacked card to the card transport path along the extrusion direction perpendicular to the card thickness direction. And
The storage card payout mechanism has a plurality of card engagement claws that can be engaged with a card rear end surface of the uppermost card opposite to the push-out direction at positions separated in a direction perpendicular to the card thickness direction. And a claw slide mechanism that pushes out each of the card engagement claws in the push-out direction.

  The storage card payout mechanism of the card processing apparatus according to the present invention includes a plurality of card engagement claws that can be engaged with the card rear end surface at different positions. If the card has deformation such as warping, even if a part of the card engagement claw cannot engage with the deformed part on the card rear end surface, the remaining card engagement claw is deformed on the card rear end surface. It can be engaged with the part that is not. Therefore, it is possible to reliably perform the operation of pushing out the cards one by one.

  The claw slide mechanism includes a common slider on which the card engaging claw is mounted and a common drive source for sliding the slider within a predetermined range along the push-out direction. It is desirable. According to this configuration, the slide mechanism can be made simple and inexpensive. In addition, since the plurality of card engagement claws can be slid in synchronization, the card is pushed out by the plurality of card engagement claws so that the card cannot be smoothly conveyed. Can be avoided.

  Further, in order to securely engage each card engagement claw with the rear end surface of the card having deformation such as warping, the claw slide mechanism of the present invention is configured such that each of the card engagement claws is interposed via an elastic biasing member. Preferably, each of the card engaging claws is pressed against the card surface of the uppermost card by the biasing force of the elastic biasing member. According to this configuration, since each card engagement claw always abuts against the card surface, the relative position between the card engagement claw and the uppermost card can always be kept constant regardless of whether or not the card is deformed. In other words, the card engaging claw can always be positioned at a position where it can engage with the rear end face of the card. Therefore, the card pushing operation can be reliably performed.

  Next, it is desirable that at least a pair of card engaging claws disposed at symmetrical positions in a direction orthogonal to the pushing direction is provided as the card engaging claws. By pushing out the rear end face of the car at the symmetrical position, the card can be sent out to the card transport path in a correct posture.

  On the other hand, in the card processing apparatus of the present invention, the card transport path is a linear transport path defined by a first transport path surface and a second transport path surface that face each other at an interval at which cards can be transported one by one. The first transport path surface may include a rear transport path surface portion extending rearward from the rear end of the first transport path surface.

  In this case, the card stacker has a card push-up member that can move toward and away from the rear-side conveyance path surface portion of the first conveyance path surface, and the card push-up member faces the rear-side conveyance path surface portion. A card delivery port is formed between the rear end of the second transport path surface and a portion of the first transport path surface facing the second transport path surface; The storage cards can be stacked in the thickness direction from the card push-up plate toward the rear conveyance path surface portion, and the card engagement claw is arranged at the rear end portion of the rear conveyance path surface portion. Projecting from the surface of the road surface portion toward the card push-up member, the uppermost card of the storage card is pushed out from the card delivery port to the card conveyance path along the rear conveyance surface portion. It is possible to adopt a configuration that.

  Further, in this case, the card transport mechanism includes a transport roller having an outer peripheral surface exposed at the rear transport path surface portion and contacting the card surface of the top card, and the top card by the storage card feeding mechanism. It is desirable that the transport path roller rotates in conjunction with the card pushing operation so that the uppermost card is sent out to the card transport path through the card delivery port. In this way, the card pushing operation by the card engaging claw of the storage card feeding mechanism and the card feeding operation by the transport roller can surely perform the operation of feeding the card from the card stacker to the card transport path.

  Next, in a card processing apparatus that handles a card capable of reading / writing information, such as a non-contact type IC card on which an RFID chip is mounted, a card at a read / write position on the card transport path A read / write unit for reading and writing information. In this case, the read / write position is a position where a rear side portion of the card to be read / written enters the card stacker from the card delivery port and overlaps the storage card. The card stacker includes a card push-down member that can project from the rear conveyance path surface portion toward the card push-up member in order to push down the storage card toward the card push-up member. By projecting, it is desirable that a gap for inserting the rear portion of the card to be read / written is formed between the rear conveyance path surface portion and the uppermost card of the storage card. .

  In this way, when the storage card stored in the card stacker and the card at the read / write position on the card transport path are partially overlapped, the card transport path can be shortened. In general, the card transport path requires one card transport path length to form a read / write position for reading and writing cards, and the card stacker also needs one card length, The transport path length from the card insertion / discharge port to the rear end of the card stacker needs to be more than twice the card length in the transport direction. According to the present invention, the conveyance path length can be shortened to a dimension not more than twice the card length in the conveyance direction, and a small and compact card processing apparatus with a short length dimension in the card conveyance direction can be realized.

(A) is a perspective view which shows the pedestal machine for game machines in which the card processing apparatus to which the present invention is applied is incorporated, and (b) is the pedestal machine body of the pedestal machine for game machines from the pedestal machine holder. It is a perspective view which shows the state pulled out. (A) is a perspective view which shows the card processing apparatus integrated in the game machine stand machine of FIG. 1, (b) is the disassembled perspective view. (A) is a longitudinal cross-sectional view which shows the internal structure of the card processing apparatus of FIG. 2, (b) is a side view which shows the conveyance path surface by the side of the apparatus main body unit. (A) is a perspective view showing a state in which the storage card payout mechanism of the card processing device of FIG. 2 is in the retracted position, (b) is a perspective view showing a state in which the storage card payout mechanism is in the forward position, c) is an exploded perspective view thereof. It is explanatory drawing which shows the card | curd sending-out operation | movement in the card processing apparatus of FIG. It is explanatory drawing which shows operation | movement from the standby state in the card processing apparatus of FIG.

  Hereinafter, an embodiment of a card processing apparatus to which the present invention is applied will be described with reference to the drawings. Although the card processing apparatus according to the present embodiment is incorporated in a gaming machine pedestal machine, the present invention can be similarly applied to a card processing apparatus used for equipment other than the gaming machine pedestal machine. Of course.

(Platform machine for game machines)
FIG. 1A is a perspective view showing a game machine pedestal machine in which a card processing device to which the present invention is applied is incorporated, and FIG. 1B shows a game machine pedestal machine. It is a perspective view which shows the state pulled out from the intermediate machine holder. The gaming machine inter-table machine 100 in which the card processing device 1 according to the present embodiment is incorporated is arranged between gaming machines (not shown) constituting a gaming island in a gaming facility such as a pachinko parlor. The pedestal machine holder 101 fixed to the game island configuration frame (not shown), and the pedestal machine main body 102 inserted in a detachable state from the front side with respect to the pedestal machine holder 101 And.

  The pedestal machine main body 102 includes a flat and vertically long rectangular parallelepiped sheet metal case 103 and a plastic front panel 104 attached to the front surface. Inside the case 103, a control unit, a power supply unit, A card processing apparatus 1 is incorporated together with the money processing unit. A card slot 105 for card insertion / ejection is formed in a portion of the front panel 104 located on the front surface of the card processing apparatus 1, through which a card, in this example, a non-contact type in which an RFIC chip is mounted. An IC card C (hereinafter sometimes simply referred to as “card C”) is inserted and ejected. Note that the configuration and operation of the gaming machine pedestal machine 100 are the same as those generally known, and thus further description thereof is omitted.

(Card processing device)
FIG. 2A is a perspective view showing the card processing device 1 incorporated in the gaming machine table machine 100 of FIG. 1, and FIG. 2B is an exploded perspective view thereof. Referring to these drawings, the card processing device 1 has a flat rectangular parallelepiped shape that is long in the front-rear direction as a whole. The device body unit 2 and a detachable opening / closing device attached to the device body unit 2 Unit 3 is provided. The apparatus body unit 2 is a unit having a flat rectangular parallelepiped shape that is long in the front-rear direction of the apparatus, and a concave portion 4 having a constant width and a constant depth extending in the front-rear direction is formed on one side surface thereof. The opening / closing unit 3 has a rectangular parallelepiped shape that fits exactly into the recess 4, and a predetermined angle from a closing position 3 </ b> A attached to the recess 4 with the opening / closing center axis 5 extending in the vertical direction of the device at the rear end thereof as a center. It can be opened and closed within the range up to the open position, and is locked at the closed position 3A by a lock mechanism (not shown). The opening / closing unit 3 can be detached from the apparatus main body unit 2. An inlet guide unit 6 is fixed to the apparatus main body unit 2 by a fixing screw 7 at the front portion of the apparatus of the recess 4.

  FIG. 3A is a longitudinal sectional view showing the internal structure of the card processing apparatus 1, and FIG. 3B is a side view showing the conveyance path surface on the apparatus body unit 2 side. The internal structure of the card processing apparatus 1 will be described with reference to FIGS. On the front end surface 11 of the card processing device 1, a card insertion / discharge port 12 having a constant width is formed extending vertically in the center of the front end surface 11 in the width direction. In this example, a card insertion / discharge port 12 is formed between the apparatus main unit 2 and the inlet guide unit 6 attached to the front end portion of the recess 4 formed here. The card C can be inserted and discharged along the longitudinal direction via the card insertion / discharge port 12.

  Inside the card processing apparatus 1, a card transport path 13 having a constant width is formed extending linearly rearward from the card insertion / discharge port 12. The card transport path 13 is a passage having a width capable of transporting the cards C one by one in the longitudinal direction, and includes an entrance side card transport path 13A and a card transport path 13B extending rearward from the rear end of the entrance side card transport path 13A. And. The rear end 13b of the card transport path 13B is connected to the card stacker 14 that is wider than the card transport path 13B at a middle position in the longitudinal direction of the apparatus, and the rear end 13b is connected to the card delivery port of the card stacker 14. It has become. The card stacker 14 can be stored in a state where the cards C fed from the card transport path 13B are stacked in the apparatus width direction orthogonal to the transport direction of the card transport path 13, in other words, stacked in the thickness direction of the card C.

  The entrance-side card transport path 13A is formed between the apparatus body unit 2 and the entrance guide unit 6, and the rear-side card transport path 13B is formed between the apparatus body unit 2 and the opening / closing unit 3. That is, the entrance-side card transport path 13A faces the front portion of the first flat transport path surface 15 that defines the bottom surface of the recess 4 of the apparatus body unit 2 and a constant interval in the apparatus width direction. It is formed between the flat second conveyance path surface portion 16 defined by the inner side surface of the inlet guide unit 6. The card conveyance path 13B is formed between the first conveyance path surface 15 on the apparatus body unit 2 side and the flat second conveyance path surface portion 17 defined by the inner side surface of the opening / closing unit 3 facing the card conveyance path 13B. ing. The rear portion of the first conveyance path surface 15 is a rear conveyance path surface portion 15a extending rearward from the rear end 13b of the second conveyance path surface portion 17 (the card delivery port of the card stacker 14). A stacker opening 14a having a rectangular outline of the card stacker 14 formed on the side of the opening / closing unit 3 is opposed to the rear conveyance path surface portion 15a.

  A card transport mechanism 20 for transporting the card C is disposed in the card transport path 13B and the card stacker 14. The card transport mechanism 20 includes a first transport roller 21 and a second transport roller 22, an idler roller 23 that can be pressed against the first transport roller 21, and a drive motor for driving the first and second transport rollers 21 and 22. 24 and a gear train 25 for transmitting the driving force of the driving motor 24 to the first and second transport rollers 21 and 22. The first and second transport rollers 21 and 22 are synchronously rotated by the drive motor 24. Moreover, although the 1st conveyance roller 21 is arrange | positioned on the card | curd conveyance path 13B, the 2nd conveyance roller 22 is arrange | positioned in the card | curd stacker 14 in the back side vicinity position of the rear end 13b of the card conveyance path 13B. The distance between the first and second transport rollers 21 and 22 is shorter than the length of the card C in the transport direction. Among the components of the card transport mechanism 20, the idler roller 23 is mounted on the opening / closing unit 3 side, but the rest is mounted on the apparatus body unit 2 side.

  In the apparatus main unit 2, a solenoid-driven inlet shutter 26 is disposed between the card insertion / ejection port 12 and the first transport roller 21 in the inlet-side card transport path 13 </ b> A. When the entrance shutter 26 is opened, the card C can be inserted. When the end surface Ca of the inserted card C in the transport path loading direction is pushed into the nip portion of the first transport roller 21 and the idler roller 23, the card C Card conveyance by the conveyance mechanism 20 is enabled.

  A circuit board 27 is arranged in parallel to the back side of the first conveyance path surface 15 in the apparatus main body unit 2. The circuit board 27 is equipped with a control circuit that controls the drive of the card processing apparatus 1, and an RF antenna 28 (read / write unit) for reading / writing information in a non-contact state with respect to the card C. It is installed. The RF antenna 28 is mounted on the surface of the circuit board 27 facing the portion between the first and second transport rollers 21 and 22 in the card transport path 13B, as indicated by an imaginary line in FIG. It is a loop-shaped antenna.

  Here, the circuit board 27 is mounted with a plurality of card detectors used for carrying the card C. The card detection position by these card detectors will be described mainly with reference to FIG. First, an entrance lever 31 of a photo-interrupter type card detector is disposed in the vicinity of the card insertion / ejection slot 12 in the entrance-side card transport path 13A. The entrance lever 31 is urged to protrude into the entrance-side card transport path 13A, and is pushed in the apparatus width direction by the card C inserted into the card insertion / discharge port 12 and retracts from the entrance-side card transport path 13A. It can be pushed in the direction. The movement of the entrance lever 31 causes the photo interrupter mounted on the circuit board 27 to have the card C inserted into the entrance side card transport path 13A, and the card C is completely pulled out from the card insertion / eject port 12. Can be detected.

  A pair of photosensors 32 and 33 (first detectors) are arranged at the upper end and the lower end of the entrance-side card transport path 13A at a portion between the entrance shutter 26 and the first transport roller 21 in the entrance-side card transport path 13A. Has been. These photosensors 32 and 33 are for detecting that the card C is located at the card read / write position by the RF antenna 28. In this example, when the card C is positioned at the card read / write position, the rear edge portion of the read / write target card C (28) in the conveyance path loading direction is located at the detection position of the upper photosensor 32, From the detection position of the lower photo sensor 33, the position deviates in the carry-in direction. Based on the detection signals of both the photosensors 32 and 33, it can be detected that the card C is positioned at the card read / write position.

  Next, one photo sensor 34 (second detector) is disposed at the lower end portion of the card transport path 13B corresponding to the nip position of the first transport roller 21 and the idler roller 23 in the card transport path 13B. Yes. Based on the detection signal of the photo sensor 34, the leading end of the card C inserted from the card insertion / ejection port 12 is inserted into the nip portion of the first transport roller 21 and the idler roller 23 (at the start of transport), and It can be detected that the discharged card C has passed through the nip portion (at the end of conveyance).

  One photosensor 35 (third detector) is disposed at the lower end portion of the rear end 13b of the card transport path 13B. Based on the detection signal of the photo sensor 35, it can be detected that the card C sent to the card stacker 14 along the card transport path 13B has been stored in the card stacker 14.

  Next, the structure of the card stacker 14 will be described mainly with reference to FIG. The card stacker 14 formed in the opening / closing unit 3 is formed on the rear side of the second transport path surface portion 17 and has a rectangular shape that can be stored in a stacked state by inserting one card C in the thickness direction. It is a concave part with a certain depth. The stacker opening 14a of the card stacker 14 faces the rear conveyance path surface portion 15a of the first conveyance path surface 15 on the apparatus body unit 2 side. The card stacker 14 is provided with a rectangular card push-up plate 41 (card push-up member) that defines the bottom surface of the card stacker 14 in a state of facing the rear conveyance path surface portion 15a. The card push-up plate 41 is pushed up toward the first conveyance path surface 15 by a truncated conical compression coil spring 42 (biasing member) from the back side. The push-up position 42A (biasing position) by the compression coil spring 42 is the center position of the card push-up plate 41 or a position behind the center position when viewed along the card transport direction. It matches.

  On the other hand, in the rear conveyance path surface portion 15a, the second conveyance roller 22 is exposed in the vicinity of the rear end 13b (card delivery port) of the card conveyance path 13B. A pair of solenoid-driven push-down members 43 and 44 that can be inserted into the card stacker 14 along the apparatus width direction are disposed at the rear position. The push-down members 43 and 44 are arranged at symmetrical positions in the vertical direction of the card stacker 14 (the short side direction of the stored IC card C).

  In the non-excited state, these push-down members 43 and 44 are in a retracted position retracted to the rear side of the rear conveyance path surface portion 15a as shown in FIG. 3A, and when energized, the rear conveyance path surface portion. From 15a toward the inside of the card stacker 14, the card is switched to a card push-down position where a thickness dimension of at least one card C has entered. Further, the card push-down position 43A by these push-down members 43, 44 is a position that is offset to the front side of the apparatus with respect to the push-up position 42A of the compression coil spring 42 when viewed along the card carrying direction. This is a position on the rear side of the apparatus with respect to the contact position 22A of the 22 storage card C (14).

  When the card push-down members 43 and 44 are projected into the card stacker 14, the storage card C (14) is pushed down against the push-up force of the push-up plate 41. In this example, the storage card C (14) is pushed down by the card push-up members 43 and 44 at the card push-down position 43A offset from the push-up position 42A of the push-up plate 41 by the compression coil spring 42 to the front side of the apparatus. As a result, the front portion of the storage card C (14) is pushed down with the pushing position 42A by the compression coil spring 42 as a fulcrum. Therefore, as compared with the case where the entire storage card C (14) is pushed down, the card conveyance path is reliably between the rear conveyance path surface portion 15a and the uppermost card C1 of the storage card C (14) with a small pushing force. A gap for feeding the card C from 13B can be formed.

  Next, at the rear end of the card stacker 14 in the front-rear direction of the apparatus, the uppermost card C1 stacked on the top of the storage cards C (14) stored in the card stacker 14 has the card thickness. A storage card feeding mechanism 90 that pushes in the pushing direction perpendicular to the direction, in this example, in the card carrying direction along the rear carrying path surface portion 15a and feeds it to the card carrying path 13B is arranged. The storage card payout mechanism 90 includes a pair of card engagement claws 91 and 92 protruding from the rear end portion of the rear conveyance path surface portion 15a, and these card engagement claws 91 and 92 via compression coil springs 93 and 94. And a supporting claw slide mechanism 95.

  The card engaging claws 91 and 92 are disposed at symmetrical positions in the vertical direction in the rear conveyance path surface portion 15a, and can be engaged with the rear end surface of the uppermost card C1 from the rear side. Further, the card engaging claws 91 and 92 can be reciprocated within a certain range in the longitudinal direction of the apparatus by a claw slide mechanism 95. By the storage card feeding mechanism 90 having this configuration and the second transport roller 22 of the card transport mechanism 20, the uppermost card C1 is reliably secured from the storage card C (14) stored in the card stacker 14 in a stacked state. It is possible to separate and send out the card C1 toward the card transport path 13B.

(Card transport path length)
In the card processing apparatus 1 having the above-described configuration, the read / write target IC card C (28) positioned at the card read / write position by the RF antenna 28 has a leading end portion in the transport path loading direction as shown in FIG. The stacker 14 enters a state where it enters the back from the card delivery port (the rear end 13b of the card transport path 13B) by a predetermined distance. At this card read / write position, the end surface Ca on the front end side in the conveyance path loading direction of the IC card C (28) is positioned immediately before the pair of push-down members 43 and 44, and the end surface Cb on the rear end side is a pair of photosensors 32. , 33. Therefore, the leading end portion of the IC card C (28) at the card read / write position in the transport path loading direction is the rear end of the storage card C (14) stored in the card stacker 14 in the transport path loading direction. It is in a state where it overlaps the end portion by a predetermined length. Further, both the first and second transport rollers 21 and 22 are in contact with the card C (28) at the read / write position.

  The overlap dimension ΔL of these cards is set to the maximum dimension that does not cause a collision with the storage card C (14) when the card C (28) at the card read / write position is read / written by the RF antenna 28. ing. In this example, the overlap dimension ΔL is larger than the length dimension L (12) from the photosensors 32 and 33 to the card insertion / ejection port 12. Therefore, the total length L (13) of the card transport path 13 (13A, 13B) is shorter than the length dimension L (C) in the longitudinal direction of the card C. Further, the length L (14) from the card insertion / discharge port 12 to the rear end of the card stacker 14 is shorter than twice the length L (C) of the card C, and the total length L (1) in the longitudinal direction of the apparatus. Is twice the length dimension L (C) of the card C or slightly shorter than that.

  Thus, since the card conveyance path 13 (13A, 13B) can be short, the length dimension of the card processing apparatus 1 in the front-rear direction can be reduced. Moreover, since the card | curd C should just be conveyed along the short card | curd conveyance path 13, the card | curd C can be conveyed using a pair of conveyance rollers 21 and 22 instead of a conveyance belt. In other words, the pair of transport rollers 21 and 22 can be arranged at an interval narrower than the length L (C) in the transport direction of the card C, so that the card can be transported reliably. When a transport belt is used, there is a high risk of transport failure and card clogging due to the elongation of the belt due to long-term use, but the durability of the transport mechanism can be improved by using a transport roller.

  Further, the second transport roller 22 is disposed on the rear transport path surface portion 15 a facing the card stacker 14. Therefore, as shown in FIG. 3, the second transport roller 22 abuts on the rear portion of the card C (28) at the read / write position. When the card C (28) is not present at the read / write position, the card C (28) comes into contact with the front portion of the uppermost card C1 located at the top of the storage card C (14). Therefore, the card C (28) at the read / write position can be sent into the card stacker 14 using the second transport roller 22, and the card C1 in the card stacker 14 is sent out toward the card transport path 13. (See FIGS. 5 and 6).

(Storage card payout mechanism)
4A is a perspective view showing a state in which the storage card feeding mechanism 90 is in the retracted position, and FIG. 4B is a perspective view showing a state in which the storage card feeding mechanism 90 is in the forward movement position. (C) is the exploded perspective view. Referring to these drawings, the storage card payout mechanism 90 is provided on the end surface Ca (the front end surface in the card transport path loading direction) of the uppermost card C1 stacked on the top of the storage card C (14). On the other hand, a plurality of card engagement claws that can be engaged from the rear side at symmetrical positions separated in the vertical direction (symmetric positions separated in the card short side direction), in this example, a pair of upper and lower card engagement claws 91, 92. The card engagement claws 91 and 92 are mounted on the claw slide mechanism 95 via compression coil springs 93 and 94, respectively.

  The claw slide mechanism 95 has a common slider 96 that supports the card engagement claws 91 and 92, and the slider 96 is moved from the retracted position shown in FIG. 4A along the card pushing direction (card transport direction). 4B, a DC motor 97 (common drive source) for sliding between the forward positions shown in FIG. 4B and a power transmission mechanism 98 for converting the drive force of the DC motor 97 into the slide motion of the slider 96. I have. The power transmission mechanism 98 includes a cam gear 98b that is driven via a gear box 98a that decelerates the rotation of the DC motor 97, and a swing link 98c that swings within a predetermined turning angle range in the longitudinal direction of the apparatus by the cam gear 98b. A slider 96 is connected to the tip of the swing link 98c, and the slider 96 is attached to the apparatus main body unit 2 so as to be slidable in the front-rear direction.

  The pair of card engagement claws 91 and 92 are attached to the claw attachment portions 96a and 96b formed on the slider 96 via the compression coil springs 93 and 94 so as to be movable in the apparatus width direction. As can be seen from FIG. 3, the card engaging claws 91 and 92 protrude into the card stacker through an opening formed in the rear end portion of the rear conveyance path surface portion 15a of the apparatus main body unit 2. The front end surfaces of the card engaging claws 91 and 92 are formed with contact surface portions 91a and 92a that are pressed by a spring force against a portion on the rear edge side of the card surface of the uppermost card C1 of the storage card C (14). ing.

  The storage card payout mechanism 90 having this configuration includes a pair of card engaging claws 91 and 92 that can be engaged with the rear end surface of the card C1 at different positions. When the card C1 is deformed such as warp, even if one of the card engagement claws 91 and 92 cannot be engaged with the deformed portion on the card rear end face, the other card engagement claw is placed on the card rear end face. It can be engaged with a portion that is not deformed. Therefore, it is possible to reliably perform the operation of pushing out the cards C1 one by one.

  The pair of card engaging claws 91 and 92 are mounted on a common slider 96 and are synchronously driven by a common drive mechanism (DC motor 97, power transmission mechanism 98). Compared with the case where the slider and the drive mechanism are individually arranged, the slide mechanism can be made simple and inexpensive. Further, by sliding the pair of card engaging claws 91 and 92 in synchronization, it is possible to avoid the problem that the card C1 is pushed out in an inclined state and the card C1 cannot be smoothly conveyed.

  Further, the card engaging claws 91 and 92 are attached to the slider 96 so as to be movable toward and away from the card surface of the card C1, and are pressed against the card surface by the compression coil springs 93 and 94. Accordingly, the card engagement claws 91 and 92 are always in contact with the card surface, and the relative position between the card engagement claws 91 and 92 and the card C1 is always kept constant regardless of whether or not the card C1 is deformed. . As a result, the card engagement claws 91 and 92 can always be held in a state of being engaged with the rear end face of the card, and the pushing operation of the card C1 can be reliably performed.

  In addition to this, the pair of card engagement claws 91 and 92 are arranged at symmetrical positions in a direction (vertical direction) orthogonal to the card push-out direction. Therefore, the card C1 is pushed out in the correct posture without tilting upward or downward, so that the card can be drawn out smoothly.

(Card processing operation)
Next, FIG. 5 is an explanatory view showing a card delivery operation in the card processing apparatus 1, and FIG. 6 is an explanatory view showing an operation from the standby state to the completion of card taking in the card processing apparatus 1. The card processing operation by the card processing apparatus 1 will be described with reference to these drawings. First, as shown in FIGS. 5A1 to 5A3, it is assumed that a plurality of storage cards C (14) are stored in the card stacker 14 in a power-off state. In this state, the storage card C (14) in the card stacker 14 is pushed up by the card push-up plate 41 toward the rear conveyance path surface portion 15a of the first conveyance path surface 15, and the uppermost position located on the uppermost side thereof. The card C1 is pressed against the rear conveyance path surface portion 15a and the second conveyance roller 22 from which the outer peripheral surface is slightly exposed in the card stacker 14. Further, a pair of card engagement claws 91 and 92 are urged to the end surface Ca on the leading end side in the conveyance path loading direction of the uppermost card C1, and these engage with the end surface Ca on the card front end side from the rear side. ing.

  When the power is turned on, as shown in FIGS. 5 (b1) and 5 (b2), the pair of card engaging claws 91 and 92 of the storage card feeding mechanism 90 starts to slide forward, and these are engaged. The uppermost card C1 in the existing card stacker 14 is pushed forward. At the same time, the card transport mechanism 20 is driven, and the first and second transport rollers 21 and 22 start to rotate counterclockwise. As a result, the card C1 is separated from the other card C (14) and sent out from the card stacker 14 to the card transport path 13. After the card C1 is sent out by a predetermined distance, the claw slide mechanism 95 moves backward and returns to the original position. In contrast, the rotation of the transport rollers 21 and 22 is continued, and the card C1 is continuously sent out.

  When the rear end surface Cb of the sent card C1 in the transport path loading direction moves forward to a state located between the pair of photosensors 32 and 33, the transport of the card C1 is stopped. As a result, the card C1 is positioned at the card read / write position. As a result, the standby state shown in FIGS. 6A1 and 6A2 is formed. In this state, both the first and second transport rollers 21 and 22 are in contact with the card C1 at the card read / write position.

  In the card processing apparatus 1 in the standby state, as shown in FIGS. 6 (b1) and 6 (b2), when the card C2 is inserted from the card insertion / ejection port 12, the insertion of the card C2 is detected by the entrance lever 31. The When card insertion is detected, the card transport mechanism 20 is driven, and the card C1 held at the card read / write position on the card transport path 13 is stored in the card stacker 14 by the first and second transport rollers 21 and 22. Return to position.

  When it is detected by the photo sensor 35 that the card C1 has returned into the card stacker 14, the entrance shutter 26 is opened as shown in FIGS. 6C1 and 6C2, and the card C2 is moved to the first transport roller 21. Insertion is possible up to the nip position. When the card C <b> 2 is pushed in, the card C <b> 2 is taken in by the rotating first transport roller 21 and transported toward the rear side along the card transport path 13.

  Here, when the photo sensor 34 disposed at the nip portion of the first conveying roller 21 detects the card C2 being taken in, the card push-down members 43 and 44 project into the card stacker 14 in the card stacker 14, The storage card C is pushed in a direction away from the first conveyance path surface 15. As a result, as shown in FIGS. 6 (d1) and 6 (d2), in the card stacker 14, a gap into which the taken card C2 can be inserted is formed on the first transport path surface 15 side. When the leading end portion of the taken card C2 in the transport path loading direction is inserted into the card stacker 14, and the rear end surface Cb of the transport path loading direction reaches between the pair of photosensors 32 and 33, the card transport stops, Card capture is complete.

  In this manner, information is read from and written to the card C2 taken into the card read / write position. An end face Ca on the leading end side in the transport path loading direction of the card C2 taken in is a pair of card push-down members 43 and 44 and is positioned at the card read / write position. Accordingly, the card push-down members 43 and 44 also function as a stopper for positioning the taken card C2 at the card read / write position.

DESCRIPTION OF SYMBOLS 1 Card processing apparatus 2 Apparatus main body unit 3 Opening / closing unit 4 Recessed part 5 Opening / closing center axis 6 Entrance guide unit 7 Fixing screw 11 Front end surface 12 Card insertion discharge port 13 Card conveyance path 13A Inlet side card conveyance path 13B Card conveyance path 13b Rear end 14 Card stacker 14a Stacker opening 15 First transport path surface 15a Rear transport path surface portions 16, 17 Second transport path surface portion 20 Card transport mechanism 21 First transport roller 22 Second transport roller 22A Contact position 23 Idler roller 24 Drive motor 25 Gear Row 26 Entrance shutter 27 Circuit board 28 RF antenna 31 Entrance lever 32, 33 Photo sensor 34 Photo sensor 35 Photo sensor 41 Card push-up plate (card push-up member)
42 Compression coil spring (biasing member)
42A Card push-up position 43, 44 Card push-down member 43A Card push-down position 90 Storage card payout mechanism 91, 92 Card engagement claw 91a, 92a Contact surface portion 93, 94 Compression coil spring 95 Claw slide mechanism 96 Slider 97 DC motor 98 Power transmission Mechanism 98a Gear box 98b Cam gear 98c Swing link C Card C (28) Read / write target card C (14) Storage card C1 Card C2 stored at the top Card inserted card Ca Card end face Cb Card end face ΔL Card overlap dimension L (1) Length dimension L (12) in the longitudinal direction of the apparatus Length dimension L from the card insertion / discharge port L (13) Card transport path length dimension L (14) Card stacker to card stacker Length dimension to rear end L (C) Length dimension in card transport direction

Claims (7)

A card insertion outlet,
A card stacker that can store cards stacked in the thickness direction;
A card transport path from the card insertion / discharge port to the card stacker;
A card transport mechanism for transporting a card along the card transport path;
Among the storage cards stored in the card stacker, there is a storage card feeding mechanism that pushes the uppermost stacked card to the card transport path along the extrusion direction perpendicular to the card thickness direction. And
The storage card payout mechanism has a plurality of card engagement claws that can be engaged with a card rear end surface of the uppermost card opposite to the push-out direction at positions separated in a direction perpendicular to the card thickness direction. And a claw slide mechanism that pushes out each of the card engagement claws in the push-out direction. In claim 1,
The claw slide mechanism includes a common slider that supports the card engaging claw and a common drive source for sliding the slide within a predetermined range along the push-out direction. A card processing apparatus provided with a storage card payout mechanism. In claim 1 or 2,
The claw slide mechanism supports each of the card engaging claws via an elastic biasing member,
Each of the card engagement claws is pressed against the card surface of the uppermost card by the biasing force of the elastic biasing member. In any one of claims 1 to 3,
A card processing apparatus provided with a storage card feeding mechanism, wherein the card engaging claws include at least a pair of card engaging claws arranged at symmetrical positions in a direction orthogonal to the pushing direction. In any one of claims 1 to 4,
The card conveyance path is a linear conveyance path defined by a first conveyance path surface and a second conveyance path surface facing each other at an interval at which cards can be conveyed one by one, and the first conveyance path surface is the first conveyance path surface. A rear conveyance path surface portion extending rearward from the rear end of the conveyance path surface;
The card stacker
A card push-up member that can move toward and away from the rear conveyance path surface portion of the first conveyance road surface, and a biasing member that biases the card push-up member toward the rear conveyance road surface portion. And
A card delivery port is formed between the rear end of the second conveyance path surface and a portion of the first conveyance path surface facing the second conveyance path surface,
The storage card can be laminated in the thickness direction from the card push-up plate toward the rear conveyance path surface portion,
The card engaging claw protrudes from the surface of the rear conveyance path surface portion toward the card push-up member at the rear end portion of the rear conveyance path surface portion.
A card processing apparatus provided with a storage card feeding mechanism, wherein the uppermost card of the storage card is pushed out from the card delivery port to the card transport path along the rear transport path surface portion. In claim 5,
The card transport mechanism includes a transport roller that has an outer peripheral surface exposed at the rear transport path surface portion and contacts the card surface of the top card,
The storage is characterized in that the transport path roller rotates in conjunction with the pushing operation of the top card by the storage card feeding mechanism, and the top card is sent out to the card transport path through the card delivery port. A card processing apparatus having a card payout mechanism. In claim 6,
A read / write unit that reads / writes information from / to a card at a read / write position on the card conveyance path;
The read / write position is a position in a state where the rear side portion on the card stacker side of the read / write target card enters the card stacker from the card delivery port and overlaps the storage card,
The card stacker includes a card push-down member that can protrude from the rear conveyance path surface portion toward the card push-up member in order to push down the storage card toward the card push-up member.
By projecting the card push-down member, a gap for inserting the rear side portion of the card to be read / written is formed between the rear side conveyance path surface portion and the uppermost card of the storage card. A card processing apparatus provided with a storage card feeding mechanism.

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