JP2004280567A - Card processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a card processor by which a card stored on a card housing section is simply subsequently used. <P>SOLUTION: The card housing section 37 is provided with a gage member 39 formed of a first passage port 41a allowing the passage of only one card and a second passage port 41b having an opening area larger than that of the first passage port 41a. The gage member 39 reciprocates by means of an arm member 51 and an electromagnetic solenoid 53 between a first moving position positioning the first passage port 41a on a card carrier path between a carrier path 11 and the card housing section 37 and a second moving position positioning the second passage port 41b on the card carrier path. In carrying the card C in the carrier path 11 to the card housing section 37, the gage member 39 moves to the second moving position to pass the card C through the second passage port 41b. In carrying the card C in the card housing section 37 to the carrier path 11, the gage member 39 moves to the first moving position to pass the card C through the first passage port 41a. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a card processing device.
[0002]
[Prior art]
As this type of card processing apparatus, there is known a card processing apparatus that stores processed cards according to the processing contents of card processing means for processing the cards (for example, see Patent Document 1). The card processing device described in Patent Document 1 includes a first card transport path for transporting a card inserted from a card insertion slot, card processing means provided in the card transport path for performing information processing, and a card processing device. A first card transport unit for transporting a card to the processing unit, a second card transport route extending from the first card transport route, and a second transport device provided in the second card transport route And a card storage section provided at the end of the second card transport path, wherein the card transferred to the second card transport path is dropped into the card storage section by its own weight.
[0003]
[Patent Document 1]
JP 2000-148917 A
[0004]
[Problems to be solved by the invention]
By the way, from the viewpoint of effective use of the card, there is a case where the user wants to reuse the card stored in the card storage unit. However, in the card processing apparatus having the above-described configuration, in order for the card stored in the card storage unit to be processed by the card processing unit, the card is once manually removed from the card storage unit, and the removed card is manually processed. Must be inserted into the card insertion slot, which takes time and labor, and does not provide a structure that can be easily reused.
[0005]
The present invention has been made in view of the above points, and an object of the present invention is to provide a card processing apparatus that can easily reuse a card stored in a card storage unit.
[0006]
[Means for Solving the Problems]
A card processing device according to the present invention includes a transport path for introducing a card inserted from a card insertion slot, a card processing unit that is provided near the transport path of the card in the transport path, and processes the card, and stores the card. Card storage unit for transporting a card in a transport path toward the card storage unit, and transporting a card stored in the card storage unit toward the transport path; and a card storage unit provided in the card storage unit. A gauge member formed with a first passage opening through which only one card can pass and a second passage opening having an opening area larger than the first passage opening; Between a first movement position where the first passage port is located on the card conveyance path between the storage section and the second movement position where the second passage port is located on the card conveyance path. Driving means for reciprocating with When the card in the transport path is transported toward the card storage section by the storage card transport section, the gauge member moves to the second movement position by the driving section, and the card storage section is moved by the storage card transport section. The driving means moves the gauge member to the first movement position when the card stored in the card is conveyed toward the conveyance path.
[0007]
The card processing device according to the present invention includes a transport path, a card processing unit, a card storage unit, a storage card transport unit, a gauge member, and a driving unit, and the storage card transport unit removes a card in the transport path. Since the gauge member moves to the second movement position by the driving means when the card is conveyed toward the card storage, the card conveyed toward the card storage passes through the second passage. Thereby, the card in the transport path can be quickly transported to the card storage unit. Further, when the card stored in the card storage section is transported toward the transport path by the storage card transport means, the gauge member is moved to the first movement position by the driving means. The passed card passes through the first passage. Thus, one of the cards stored in the card storage unit can be reliably transported to the transport path. As a result, the cards can be stored in the card storage unit, and the cards stored in the card storage unit can be easily reused.
[0008]
In addition, the driving unit has an engaging portion that engages with a projection provided on the gauge member, and includes an arm member that is swingably supported, and an actuator that swings the arm member, The arm member moves the gauge member to a first movement position when the arm member is set to the first swing position, and moves the gauge member to the second movement position when the arm member is set to the second swing position. Preferably. With such a configuration, it is possible to easily and inexpensively realize a configuration in which the gauge member can be reliably moved to the first movement position or the second movement position.
[0009]
Further, it is preferable that the arm member further includes a guide section for guiding a card conveyed from the card storage section toward the conveyance path at the first swing position. With this configuration, when the card stored in the card storage unit is conveyed toward the conveyance path by the storage card conveyance unit, the card can be surely conveyed into the conveyance path.
[0010]
In addition, it is preferable that a pair of the guides be provided in the card conveying direction by the insertion card conveying means at an interval shorter than the card length in the card conveying direction. With this configuration, the card can be transported more reliably to a position where the card can be transported by the inserted card transporter in the transport path.
[0011]
Further, it is preferable that the gauge member is provided with a spring member for pressing the card stored in the card storage section against the stored card transport means when the gauge member is moved to the first movement position. With such a configuration, the card stored in the card storage unit can be reliably pressed by the stored card transport unit, and a defective transport can be prevented with a simple configuration.
[0012]
The gauge member has a holding portion that is located on both sides of the card stored in the card storage portion and holds the card in cooperation with the spring member. When the card is moved to the position, it is preferable that the card conveyed by the storage card conveying means be positioned inside the holding portion by being elastically deformed by receiving a reaction force from the storage card conveying means. With this configuration, the card can be held by the holding unit using the movement of the gauge member.
[0013]
Further, it is preferable that the card storage section is provided below the transport path. With this configuration, the card storage unit can be laid out using the space below the transport path, the depth of the transport path in the card transport direction can be reduced, and the depth of the apparatus can be reduced. Can be made more compact.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
A card processing device according to an embodiment of the present invention will be described with reference to the drawings.
[0015]
FIG. 1 is a side view of the card processing device according to the present embodiment, and FIG. 2 is a front view of the card processing device according to the present embodiment. FIG. 3 is a perspective view of a gauge member included in the card processing device according to the present embodiment, and FIG. 4 is a perspective view of an arm member included in the card processing device according to the present embodiment.
[0016]
As shown in FIGS. 1 and 2, the card processing device 1 includes a housing 3, and the housing 3 includes a pair of left and right first and second side housings 5 and 7. A card insertion slot 9 for inserting the card C such that the width direction of the non-contact type IC card (hereinafter, simply referred to as “card”) C is vertical is provided at a substantially central position in the vertical direction on the front side of the housing 3. Have been. Further, a transport path 11 for introducing the card C inserted from the card insertion slot 9 is formed by the surfaces of the first and second side casings 5 and 7 facing each other. It extends from the insertion slot 9 along the card insertion direction.
[0017]
A drive motor 13 rotatable in forward and reverse directions is attached to the first side housing 5, and a first drive shaft 15 extending in the vertical direction is attached to a motor shaft of the drive motor 13. Are connected at the upper end. The first drive shaft 15 is rotatably supported by the first side housing 5, and a transport roller 17 is axially mounted at an intermediate portion. The transport roller 17 is arranged facing the transport path 11 from a window formed in the first side housing 5, and is driven to rotate by the drive motor 13.
[0018]
A second drive shaft 21 is connected to a lower end of the first drive shaft 15 via a universal joint 19. The second drive shaft 21 extends in the horizontal direction so as to be parallel to the card transport direction in the transport path 11, and is rotatably supported by the first side housing 5. The rotation of the drive motor 13 is transmitted to the second drive shaft 21 via the first drive shaft 15 and the universal joint 19. A drive pulley 23 is mounted on the second drive shaft 21 halfway.
[0019]
Below the drive pulley 23, a driven pulley 25 is provided which is arranged parallel to the second drive shaft 21 and is pivotally mounted on a shaft (not shown) rotatably supported by the first side housing 5. Have been. A transport belt 27 is stretched between the driving pulley 23 and the driven pulley 25, and the transport belt 27 faces the transport path 11 from a window (not shown) formed in the first side housing 5. In. As shown in FIG. 2, the transport belt 27 is provided at a predetermined interval from the card C so as not to come into contact with the card C transported in the transport path 11.
[0020]
When the drive motor 13 rotates, the rotation is transmitted to the transport roller 17 via the first drive shaft 15, and the transport roller 17 rotates. At the same time, the rotation of the drive motor 13 is transmitted to the drive pulley 23 via the first drive shaft 15, the universal joint 19, and the second drive shaft 21, and the transport belt 27 runs.
[0021]
A first pinch roller 29 is provided at a position facing the transport roller 17 in the second side housing 7. The first pinch roller 29 is arranged facing the transport path 11 from a window formed in the second side housing 7. A second pinch roller 31 is provided at a position facing the drive pulley 23 in the second side housing 7. The second pinch roller 31 is arranged facing a transport path 11 from a window (not shown) formed in the second side housing 7. The first pinch roller 29 is rotatably supported by one end of a bracket (not shown) supported by the second side housing 7 so as to be swingable about a center portion as a swing center. The two pinch rollers 31 are rotatably supported at one end of the bracket.
[0022]
A biasing force is applied to the bracket by an elastic member (not shown) such as a compression coil spring, and the bracket always has a first pinch roller 29 close to the transport roller 17 and a second pinch roller 31. Are urged in a direction away from the conveyor belt 27. Also, an actuator (not shown) such as an electromagnetic solenoid is connected to the bracket, and the actuator swings the bracket against the urging force of the elastic member, whereby the bracket is moved to the first pinch roller 29. Are separated from the transport roller 17, and the second pinch roller 31 approaches the transport belt 27. The driving mechanism of the first and second pinch rollers 31 is described in the above-mentioned Patent Document 1 and the like, and the detailed description is omitted here.
[0023]
When the first pinch roller 29 is close to the transport roller 17, the card C can be held between the first pinch roller 29 and the transport roller 17, and the card C inserted from the card insertion slot 9 is transported. The Rukoto. When the rotation of the transport roller 17 (drive motor 13) is stopped, the transport of the card C is stopped, and the stop position of the card C in the transport path 11 is defined. Here, the drive motor 13, the first drive shaft 15, the transport roller 17, and the first pinch roller 29 are used to transport an inserted card C from the card insertion slot 9 to a transport path (an inserted card transport mechanism). Function).
[0024]
When the second pinch roller 31 is close to the transport belt 27, the card C can be held between the second pinch roller 31 and the transport belt 27, and the card C at the stop position of the transport path 11 is transported. The Rukoto. The drive motor 13, the first drive shaft 15, the universal joint 19, the second drive shaft 21, the drive pulley 23, the driven pulley 25, the transport roller 17, the second pinch roller 31, and the like are provided on the card C in the transport path 11. Functions as a storage card transfer mechanism (storage card transfer means) for transferring the cards stored in the card storage 37 to the transfer path 11.
[0025]
Outside the surface of the second side housing 7 that forms the transport path 11, an information processing board 33 provided near the transport path of the card C in the transport path 11 and serving as a card processing unit for processing the card C is provided. It is arranged. The information processing board 33 is provided with an antenna unit 35 (not shown) of the card C for wirelessly transmitting and receiving information.
[0026]
A card storage section 37 for storing the card C is provided below the transport path 11. The card storage section 37 is defined by the second side housing 7 and communicates with the transport path 11.
[0027]
A gauge member 39 is provided in the card storage section 37. As shown in FIG. 3, the gauge member 39 is continuous with a gauge portion 41 arranged orthogonal to the card C in the transport path 11 and one end of the gauge portion 41 in the card thickness direction. And a base portion 43 extending downward. The gauge portion 41 has a substantially slit-shaped first passage opening 41a through which only one card can pass, and a substantially slit-shaped second passage opening 41b having an opening area larger than the first passage opening 41a. Is formed. The first passage 41a and the second passage 41b extend in a card insertion direction, that is, a direction parallel to the card conveyance direction in the conveyance path 11. Further, a cutout portion 41c for preventing interference between the transport belt 27 and the gauge member 39 is formed in the gauge portion 41 so as to intersect with the first passage opening 41a and the second passage opening 41b. .
[0028]
At both ends of the gauge section 41 in the direction in which the first passage port 41a and the second passage port 41b extend, projections 45 protruding in the direction are provided. At both ends of the gauge portion 41, spring hooks 47 projecting in the same direction as the protrusions 45 are provided, and each spring hook 47 is provided between the spring housing 47 and the second side housing 7. A tension spring 49 is stretched.
[0029]
The gauge member 39 reciprocates between a first movement position and a second movement position by a gauge member drive mechanism (drive means) including an arm member 51 and an electromagnetic solenoid 53 as an actuator. The arm member 51 is a substantially shaft-shaped member extending in the card insertion direction, and both ends thereof are swingably supported by the first side housing 5. As shown in FIG. 4, the arm member 51 has first engagement portions 55 that engage with the protrusions 45 provided on the gauge member 39 near both ends thereof. The electromagnetic solenoid 53 has a movable iron core 57, and operates the movable iron core 57 in the longitudinal direction. An end of the movable iron core 57 is engaged with a second engagement portion 59 formed at one end of the arm member 51.
[0030]
When the movable iron core 57 is moved downward, as shown in FIG. 5, the second engaging portion 59 of the arm member 51 is pulled down, and the arm member 51 swings counterclockwise in the figure. Thus, the first swing position is set. At this time, since the first engagement portion 55 of the arm member 51 and the projection 45 of the gauge member 39 are in contact with each other and engaged, the swinging of the arm member 51 causes the gauge member 39 to It moves rightward in the figure while resisting the urging force of 49, and becomes the first movement position. Thus, the gauge member 39 is in a state where the first passage port 41a of the gauge section 41 is located on the card transport path between the transport path 11 and the card storage section 37.
[0031]
On the other hand, when the movable iron core 57 is moved upward, as shown in FIG. 6, the second engagement portion 59 of the arm member 51 is pushed up, and the arm member 51 swings clockwise in the figure. Then, it is set to the second swing position. At this time, the gauge member 39 moves to the left in the drawing along with the swing of the arm member 51 by the urging force of the tension spring 49, and assumes the second movement position. Thus, the gauge member 39 is in a state where the second passage port 41b of the gauge section 41 is located on the card transport path between the transport path 11 and the card storage section 37.
[0032]
As shown in FIGS. 1 and 2, a pressure spring 61 as a spring member is attached to the base portion 43 of the gauge member 39. The pressing spring 61 is a leaf spring, and presses the card C stored in the card storing section 37 against the transport belt 27 when the gauge member 39 moves to the first moving position. Thus, the urging force of the pressing spring 61 acts on the card C stored in the card storage section 37 in the thickness direction of the card C.
[0033]
As shown in FIG. 3, holding portions 63 for holding the card C of the card storage portion 37 in cooperation with the pressing spring 61 are provided at both ends of the base portion 43 in the card insertion direction. And is provided below the gauge portion 41 so as to extend therefrom. The portion of the holding portion 63 near the base portion 43 is formed in a thin shape, and is elastically deformable. The interval between the portions of the holding portion 63 near the base portion 43 is set slightly larger than the length of the card C in the card insertion direction. Further, the tip portion of the holding portion 63 bulges inward from the portion near the base portion 43 and is formed thick, and the interval between the tip portions is slightly longer than the length of the card C in the card insertion direction. It is set small. The distal end portion of the holding portion 63 is formed such that the length from the base portion 43 to the distal end portion is gradually increased toward the lower side and is inclined. The upper end position of the tip portion of the holding portion 63 is below the edge of the second passage opening 41b near the base 43 when viewed from the direction in which the second passage opening 41b extends. The lower end position of the portion is also substantially at the center of the second passage port 41b when viewed from the direction in which the second passage port 41b extends. The tip portion of the holding portion 63 is tapered so as to gradually increase in thickness from the tip side when viewed from the vertical direction (the card transport direction in the storage card transport mechanism).
[0034]
When the gauge member 39 moves toward the first movement position, the tip portion of the holding portion 63 comes into contact with the card C which is conveyed by the conveyance belt 27 and is located outside the holding portion 63. When the gauge member 39 further moves toward the first movement position, the reaction force from the conveyor belt 27 acts on the tip portion of the holding portion 63 via the card C, and receives the reaction force to hold the holding member 63. The portions 63 are elastically deformed so as to increase the distance between each other. Due to this elastic deformation, the card C located outside the holding section 63 moves relatively to the gauge member 39 and is located inside the holding section 63.
[0035]
As shown in FIG. 4, the arm member 51 has a pair of guide portions 65 provided at a predetermined interval in the card transport direction by the transport roller 17. The guide section 65 guides the card C conveyed from the card storage section 37 toward the conveyance path 11 at the first swing position so as to contact the conveyance roller 17. The interval between the guide portions 65 is set to be shorter than the card length in the card transport direction by the transport rollers 17, and the guide portions 65 are arranged with the transport rollers 17 and the transport belt 27 interposed therebetween.
[0036]
Next, a card transport operation between the transport path 11 and the card storage unit 37 in the card processing device 1 having the above-described configuration will be described with reference to FIGS. 7 to 11 are schematic front views for explaining a card transport operation from the transport path 11 to the card storage section 37. FIGS. 12 to 15 are diagrams illustrating card transport from the card storage section 37 to the transport path 11. It is a schematic front view for explaining operation.
[0037]
First, the operation of transporting a card from the transport path 11 to the card storage 37 will be described. As shown in FIG. 7, the card C is in the stop position, and as a result of performing information processing such as rewriting of the value information in the card by the information processing board 33, the card C has no value information remaining in the card. When the card becomes a so-called used card, the card is conveyed from the stop position in the conveyance path 11 toward the card storage unit 37. Then, the electromagnetic solenoid 53 is brought into a non-driving state, the movable iron core 57 is moved upward, the arm member 51 swings to the second swing position, and the gauge member 39 moves to the second movement position. In FIG. 7, the first pinch roller 29 is in a state close to the transport roller 17, and the second pinch roller 31 is in a state separated from the transport belt 27.
[0038]
Then, as shown in FIG. 8, when the first pinch roller 29 separates from the transport roller 17 and the second pinch roller 31 approaches the transport belt 27, the card C at the stop position is moved to the second pinch. The roller 31 is held between the transport belt 27 and the roller 31. When the drive motor 13 rotates in the first direction with the second pinch roller 31 and the transport belt 27 sandwiching the card C, as shown in FIGS. It is transported toward 37. At this time, since the gauge member 39 is at the second moving position, the card C conveyed while being nipped between the second pinch roller 31 and the conveyor belt 27 passes through the second passage 41b of the gauge member 39. Enters between the holding portion 63 of the gauge member 39 and the transport belt 27. Further, the leading end portion of the holding portion 63 is formed to be inclined with respect to the card transport direction by the transport belt 27 as described above, and does not hinder the transport of the card C. In FIG. 10, the first pinch roller 29 is in a state close to the transport roller 17, and the second pinch roller 31 is in a state separated from the transport belt 27.
[0039]
When the card C is transported to the card storage section 37, the electromagnetic solenoid 53 is driven, and the movable iron core 57 is moved downward, so that the arm member 51 is moved to the first swing position as shown in FIG. The gauge member 39 swings to the first movement position. Accordingly, the card C that has been transported to the card storage section 37 and has entered between the holding section 63 of the gauge member 39 and the transport belt 27 moves from the outside to the inside of the holding section 63 due to the elastic deformation of the holding section 63. Then, it is held and aligned by the holding portion 63 and the pressing spring 61.
[0040]
Subsequently, a card transport operation from the card storage unit 37 to the transport path 11 will be described. When the card is transported from the card storage section 37 to the transport path 11, as shown in FIG. 12, the first pinch roller 29 is separated from the transport roller 17 as an initial state, and the second pinch roller 31 is Is in a state close to the conveyor belt 27. Then, the electromagnetic solenoid 53 is driven to move the movable iron core 57 downward, and as shown in FIG. 12, the arm member 51 swings to the first swing position, and the gauge member 39 moves to the first swing position. Move to the movement position.
[0041]
When the drive motor 13 rotates in the second direction opposite to the first direction with the second pinch roller 31 and the conveyor belt 27 sandwiching the card C, as shown in FIGS. Of the cards C stored in the card storage section 37, the cards abutting on the transport belt 27 are transported toward the transport path. At this time, since the gauge member 39 is at the second movement position, the card C nipped and transported by the second pinch roller 31 and the transport belt 27 passes through the first passage 41a of the gauge member 39. . Even when a plurality of cards C are transported upward due to frictional resistance between the cards C and the like, only one card can pass through the first passage port 41a. 11, only one card C is conveyed. Further, the card C which is conveyed while being nipped between the second pinch roller 31 and the conveyor belt 27 is guided by the guide portion 65 as shown in FIGS. Touch As a result, the card C that is nipped and conveyed by the second pinch roller 31 and the conveyance belt 27 is conveyed to the conveyance path 11 as shown in FIG. In FIG. 10, the first pinch roller 29 is in a state close to the transport roller 17, and the second pinch roller 31 is in a state separated from the transport belt 27.
[0042]
As described above, in the card processing apparatus 1 of the present embodiment, the transport path 11, the information processing board 33, the card storage unit 37, the storage card transport mechanism (the drive motor 13, the first drive shaft 15, the universal joint 19, the second drive shaft 21, the drive pulley 23, the driven pulley 25, the transport roller 17 and the second pinch roller 31), the gauge member 39, and the gauge member drive mechanism (the arm member 51 and the electromagnetic solenoid 53). When the card C in the transport path 11 is transported toward the card storage section 37 by the storage card transport mechanism, the gauge member driving mechanism moves the gauge member 39 to the second movement position. The card C conveyed toward 37 passes through the second passage 41b. Thus, the card C in the transport path 11 can be quickly transported to the card storage 37. Further, when the card C stored in the card storage section 37 is transported toward the transport path 11 by the storage card transport mechanism, the gauge member driving mechanism moves the gauge member 39 to the first movement position. The card C conveyed toward the conveyance path 11 passes through the first passage 41a. Thus, one of the cards C stored in the card storage unit 37 can be reliably transported to the transport path. As a result, the card C can be stored in the card storage section 37, and the card C stored in the card storage section 37 can be easily reused.
[0043]
In the present embodiment, the gauge member driving mechanism includes an arm member 51 and an electromagnetic solenoid 53. When the arm member 51 is set to the first swing position by the electromagnetic solenoid 53, the gauge member 39 moves the gauge member 39 to the first swing position. Is moved to the second swing position by the electromagnetic solenoid 53, the gauge member 39 is moved to the second movement position. This makes it possible to easily and inexpensively realize a configuration in which the gauge member 39 can be reliably moved to the first movement position or the second movement position.
[0044]
In the present embodiment, an insertion card transport mechanism (the drive motor 13, the first drive shaft 15, the transport roller 17 and the first pinch roller 29) is provided, and the storage card transport mechanism (the transport belt 27) is inserted. The card C is provided at a predetermined distance from the card C so as not to come into contact with the card C conveyed in the conveyance path 11 by the card conveyance mechanism (conveyance roller 17). A guide section 65 is provided to guide the card C conveyed from the card storage section 37 toward the conveyance path 11 at the swinging position so as to contact the conveyance roller 17. Accordingly, even if the transport belt 27 is provided at a predetermined interval from the card C so that the transport belt 27 does not contact the card C transported in the transport path 11 by the insertion card transport mechanism, When the card C stored in the card storage section 37 is conveyed toward the conveyance path 11 by the conveyance mechanism, it is possible to surely convey the card C to a position where the card C can be conveyed by the conveyance roller 17 in the conveyance path 11. it can. The guide unit 65 may guide the card C conveyed from the card storage unit 37 toward the conveyance path 11 such that the card C does not contact the conveyance roller 17 and the first pinch roller 29.
[0045]
Further, in the present embodiment, a pair of guide portions 65 are provided in the card transport direction by the insertion card transport mechanism with an interval shorter than the card length in the card transport direction. As a result, the card C can be more reliably transported to a position where it can be transported by the inserted card transport mechanism in the transport path 11.
[0046]
Further, in the present embodiment, the spring member that presses the card C stored in the card storage unit 37 against the transport belt 27 when the gauge member 39 moves to the first movement position is provided. As a result, the card C stored in the card storage section 37 can be reliably pressed against the transport belt 27, and a transport failure can be prevented with a simple configuration.
[0047]
In the present embodiment, the gauge member 39 has a holding portion 63 which is located on both sides of the card C in the card storage portion 37 and holds the card in cooperation with a spring member. When the gauge member 39 moves to the first movement position, the card C conveyed by the storage card conveyance mechanism is resiliently deformed by receiving a reaction force from the conveyance belt 27 so that the card C is positioned inside the holding portion 63. Let it. Thus, the card C can be held by the holding unit 63 by using the movement of the gauge member 39.
[0048]
In the present embodiment, the card storage section 37 is provided below the transport path 11. Thereby, the card storage portion 37 can be laid out using the space below the transport path 11, the depth of the transport path 11 in the card transport direction can be reduced, and the depth of the apparatus in the depth direction can be reduced. Compactness can be achieved.
[0049]
The present invention is not limited to the embodiments described above. For example, the card storage section 37 is provided below the transport path 11, but is not limited thereto, and may be provided above the transport path 11, or may be provided at the back side of the transport path 11. In addition, the card insertion slot 9 and the transport path 11 are provided so that the width direction of the card C is vertical. However, the present invention is not limited to this. It may be.
[0050]
Further, in the present embodiment, an insertion card conveyance mechanism for conveying the card C inserted from the card insertion slot 9 is provided, but the insertion card conveyance mechanism is not necessarily required. For example, the card C may be manually inserted to a stop position in the transport path 11. Further, the insertion card transport mechanism is not limited to the configuration in which the transport roller 17 and the first pinch roller 29 transport the card C, but may be configured to transport the card C by a transport belt or the like. . The storage card transport mechanism is not limited to the configuration in which the card C is transported by the transport belt 27 and the second pinch roller 31 described above, but may be configured to transport the card C by transport rollers or the like.
[0051]
In addition, the transport roller 17 and the transport belt 27 are driven by one drive motor 13, but a drive motor is provided for each of the transport roller 17 and the transport belt 27, and the transport roller 17 and the transport belt 27 are driven by each drive motor. You may comprise so that it may drive. Further, a bevel gear may be used instead of the universal joint 19.
[0052]
Further, the gauge member 39 is moved by the arm member 51 and the electromagnetic solenoid 53, but the gauge member 39 may be directly driven and moved by an actuator such as the electromagnetic solenoid 53.
[0053]
Further, although the card C is a non-contact type IC card, it may be a contact type IC card or a magnetic card.
[0054]
【The invention's effect】
As described above in detail, according to the present invention, it is possible to provide a card processing device capable of easily reusing a card stored in a card storage unit.
[Brief description of the drawings]
FIG. 1 is a side view of a card processing apparatus according to an embodiment.
FIG. 2 is a front view of the card processing apparatus according to the embodiment.
FIG. 3 is a perspective view of a gauge member included in the card processing device according to the embodiment.
FIG. 4 is a perspective view of an arm member included in the card processing device according to the embodiment.
FIG. 5 is a front view illustrating an operation of a gauge member and a gauge member driving mechanism included in the card processing apparatus according to the embodiment.
FIG. 6 is a front view illustrating an operation of a gauge member and a gauge member driving mechanism included in the card processing apparatus according to the embodiment.
FIG. 7 is a front view for explaining a card transport operation from the transport path to the card storage unit in the card processing apparatus according to the embodiment.
FIG. 8 is a front view for explaining a card transport operation from the transport path to the card storage unit in the card processing apparatus according to the embodiment.
FIG. 9 is a front view for explaining an operation of transporting the card from the transport path to the card storage unit in the card processing apparatus according to the embodiment.
FIG. 10 is a front view for explaining a card transport operation from the transport path to the card storage unit in the card processing apparatus according to the embodiment.
FIG. 11 is a front view for explaining a card transport operation from the transport path to the card storage unit in the card processing apparatus according to the embodiment.
FIG. 12 is a front view for explaining a card transport operation from the card storage unit to the transport path in the card processing apparatus according to the embodiment.
FIG. 13 is a front view for explaining a card transport operation from the card storage unit to the transport path in the card processing apparatus according to the embodiment.
FIG. 14 is a front view for explaining a card transport operation from the card storage unit to the transport path in the card processing apparatus according to the embodiment.
FIG. 15 is a front view for explaining a card transport operation from the card storage unit to the transport path in the card processing apparatus according to the embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Card processing apparatus, 3 ... Housing | casing, 9 ... Card insertion slot, 11 ... Transport path, 13 ... Drive motor, 17 ... Transport roller, 23 ... Drive pulley, 25 ... Driven pulley, 27 ... Transport belt, 29 ... No. 1 pinch roller, 31 ... second pinch roller, 33 ... information processing board, 37 ... card storage section, 39 ... gauge member, 41 ... gauge section, 41a ... first passage port, 41b ... second passage port Reference numerals 45, projecting portion, 47, spring hook portion, 49, tension spring, 51, arm member, 53, electromagnetic solenoid, 55, first engaging portion, 57, movable iron core, 59, second engaging portion , 63 ... holding part, 65 ... guide part, C ... card.

Claims (7)

A conveyance path for introducing a card inserted from the card insertion slot,
A card processing unit that is provided near the transport path of the card in the transport path and processes the card;
A card storage unit for storing the card,
A storage card transport unit that transports a card in the transport path toward the card storage unit, and transports a card stored in the card storage unit toward the transport path,
A gauge member provided in the card storage portion and having a first passage opening through which only one card can pass and a second passage opening having an opening area larger than the first passage opening;
A first movement position where the first passage port is located on a card transport path between the transport path and the card storage section; and a second movement position on the card transport path. Driving means for reciprocating between a second movement position where the mouth is located,
When the card in the transport path is transported toward the card storage section by the storage card transport means, the gauge member moves to the second movement position by the driving means, and the storage card transport means Wherein the gauge member is moved to the first movement position by the driving means when the card stored in the card storage section is transported toward the transport path. . The driving means,
An arm member that has an engaging portion that engages with a protrusion provided on the gauge member and is swingably supported;
An actuator for swinging the arm member,
When the arm member is set to a first swing position by the actuator, the arm member moves the gauge member to a first movement position. When the arm member is set to a second swing position by the actuator, the arm member moves the gauge member. The card processing device according to claim 1, wherein the card processing device is moved to a second movement position. The card processing apparatus according to claim 2, wherein the arm member further includes a guide unit that guides a card conveyed from the card storage unit toward the conveyance path at the first swing position. . 4. The card processing device according to claim 3, wherein a pair of the guide units are provided in the card transport direction by the insertion card transport unit with an interval shorter than a card length in the card transport direction. 5. . The gauge member is provided with a spring member that presses the card stored in the card storage unit against the storage card transport unit when the gauge member moves to the first movement position. The card processing device according to claim 1. The gauge member is located on both sides of the card stored in the card storage unit, and has a holding unit that holds the card in cooperation with the spring member,
When the gauge member moves to the first movement position, the holding unit elastically deforms by receiving a reaction force from the storage card transporting unit, thereby holding the card transported by the storage card transporting unit. The card processing device according to claim 5, wherein the card processing device is located inside the holding unit. The card processing device according to claim 1, wherein the card storage unit is provided below the transport path.

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