JP2018180944A - Card processor and detailed statement issuance device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a card processor and a detailed statement issuance device, which enable handling even with a special card.SOLUTION: A card processor 100 for processing a card-like medium on which magnetic information is recorded, includes: an insertion slot 304; a conveyance path 350 for conveying the medium; a first shutter 316 provided on the insertion slot side in the card processor; a second shutter 326 provided downstream of the first shutter in the conveyance direction of the medium; a medium detection sensor 341 provided between the first shutter and the second shutter for detecting the medium; an identification unit 302 for reading magnetic information of the medium; and a control unit for performing a mating action by causing a solenoid 311 to close the first shutter and causing a solenoid 318 to open the second shutter when the medium detection sensor detects the medium inserted through the insertion slot and conveying the medium to the identification unit along the conveyance path.SELECTED DRAWING: Figure 1

Description

  The present invention is a card processing apparatus for identifying a small rectangular card in which a unique number defined in ISO 7810 used in an automated teller machine ATM (Automated teller machine) or the like used in financial institutions such as banks is written. About.

  Patent Document 1 is known as a processing apparatus for handling a so-called magnetic card in which a thermoplastic synthetic resin is used as a base material to form a small rectangle and a magnetic material is embedded for the purpose of writing a unique number. In Patent Document 1, a medium (card) detection means is provided at the insertion slot on the transport path, and a card thickness detection means is provided behind it, and when the medium detection means is in a medium detection state and the card thickness detection means is thick, The shutter on the transport path in the closed state is opened, the medium (card) is transported to the inside of the card processing device, and the magnetic head in the card processing device reads the unique number written in the magnetic card.

JP, 2011-209981, A

  Recently, some financial institutions that issue magnetic cards have issued a design in which the photograph of the owner's face is printed in multicolor printing for the design of the magnetic card, in order to differentiate itself from other financial institutions. The However, photo printing on a magnetic card tends to decline because of the expense involved. Therefore, as shown in FIG. 13A, a part of one side of the rectangular card which does not include the magnetic stripe is largely cut as shown in FIG. As shown in (b), a financial institution has been issued which issues a goug-shaped card at the central part of the card on one side which does not contain a magnetic stripe.

  In the technology shown in Patent Document 1, when the card width detection sensor detects “medium present”, the suction condition is satisfied, so a so-called special shape as shown in FIG. 13 (a) and FIG. 13 (b) is special. In the case of a card, it is an error because the recess hardly crosses the width sensor, and it has been a problem that the card can not be sucked and transported inside the apparatus and can not be handled.

  In addition, even in the case of a transparent card made of a special material that uses a transparent member as the base material, the light from the width sensor is transmitted and an error occurs because the width of the card can not be detected. Similarly, it could not be handled and was a problem.

  An object of the present invention is to provide a card processing device and a statement slip issuing device which can handle even special cards.

  A card processing apparatus according to the present invention is a card processing apparatus for processing a card-like medium in which magnetic information is recorded, and the insertion port, a transport path for transporting the medium, and the insertion in the card processing apparatus. A first shutter provided on the mouth side, a second shutter provided downstream of the first shutter in the medium transport direction, a space between the first shutter and the second shutter A medium detection sensor for detecting the medium, an identification unit for reading magnetic information of the medium, and the first shutter when the medium detection sensor detects the medium inserted from the insertion port. And a control unit that performs a closing operation and opens the second shutter, and transports the medium along the transport path to the identification unit.

  The present invention is also configured as a statement slip issuing device provided with the card processing device.

  According to the present invention, even special cards can be handled.

It is a figure which shows the structural example of a card processing apparatus (Example 1). It is a block diagram of a card processing device. It is a flowchart which shows the processing procedure of card processing (Example 1). It is a figure which shows a mode that the card | curd inhaled in card processing is conveyed. It is a figure which shows a mode that the card | curd inhaled in card processing is conveyed. It is a figure which shows the other example of fitting operation. It is a figure which shows a mode that the card | curd discharged | emitted in card processing is conveyed. It is a figure which shows the structure of a shutter. It is a figure which shows the structure of a shutter. It is a figure which shows the structure of a shutter. It is a figure which shows the example of the card | curd to which the reflector was attached. FIG. 1 is a diagram illustrating an example of a printer to which a card processing device is applied. It is a figure which shows the other example of the printer which applied the card processing apparatus. It is a figure which shows the example of the special shape card with an IC chip. It is a figure which shows the structural example of a card processing apparatus (Example 2). It is a flowchart which shows the process sequence of a card process (Example 2). It is a figure showing an example of a special shape card.

  Hereinafter, with reference to the accompanying drawings, embodiments of a card processing device and a statement slip issuing device in the present embodiment will be described in detail. FIG. 1 is a view showing a configuration example of a card processing device 100 in the present embodiment. The upper part of FIG. 1 is a side view of the apparatus, and the lower part is an AB upper view of the apparatus.

  As shown in FIG. 1, the card processing device 301 arranges the insertion port 304 on the transport path 350 having a width of the handling medium (FIG. 13 MW), and from the insertion port 304 to the position indicated by POS. By moving up and down in the direction to block the transport path 350, the transport path 350 is closed, and the outer shutter 316 (first shutter) provided on the insertion port side in the apparatus is disposed. Further, the card processing device 301 is provided with an outer shutter open / close detection sensor 312 for confirming the open / close of the outer shutter 316 and an outer solenoid 311 which can be kept open or closed for a predetermined time for driving the outer shutter 316. ing. Thus, the outer shutter 316, the outer shutter open / close detection sensor 312, and the outer solenoid 311 are provided at substantially the same distance from the insertion port 304 in the transport direction.

  Also, a medium (detection) for detecting the medium on the transport path 350 at a position between the first shutter and the second shutter indicated by PSD from the insertion port 304 inside the apparatus than the POS A sensor 341 is disposed, and a width (detection) sensor 342 is disposed inside the apparatus behind the sensor 341 to detect the medium width. Further, the transport path 350 is closed by moving up and down in a direction to block the transport path 350 from the insertion port 304 to a position indicated by PIS, which is inside the apparatus than the PSD, and the first shutter An inner shutter 326 (second shutter) provided downstream of the medium transport direction is also disposed. Further, the card processing device 301 is provided with an inner shutter open / close detection sensor 322 for confirming the opening / closing of the inner shutter 326 and an inner solenoid 318 for driving the inner shutter 326. A roller pair 352 is disposed on the inner side of the apparatus than the PIS and at a position indicated by PHR from the insertion port 304, and the roller pair 352 is connected to the conveyance motor 381 via a connecting system not shown. And a pair of transport rollers 353 for transporting the medium. The transport roller pair 353 is also driven and controlled by the transport motor 381 similarly to the roller pair 352. Further, in the card processing unit 301, an upper end detection sensor 347 for detecting the leading edge of the medium being conveyed is disposed at a position shown by PIL from the insertion port 304 on the inner side than the PHR and behind that The magnetic head 302, which identifies the inserted medium and has a read center at the position of MH in the width direction, is disposed. In addition, the distance between each arrange | positioned component is satisfy | filling PIS <PHR <ML <PIL.

  Subsequently, the configuration of the outer shutter 316 will be described. FIG. 7A is a view showing a configuration example of the outer shutter 316. As shown in FIG. In FIG. 7A, the conveyance direction front view (A) of the outer side shutter 316 and the side view (B) are shown.

  As shown in FIG. 7A, the outer shutter 316 is provided at its upper end and is connected to a rod-like contact member 720 having the same width as the transport width (MW) and the outer solenoid 311, and the contact member 720 is viewed from the lower side. And a supporting finger portion 710. The contact member 720 has a trapezoidal shape shown in FIG. 7B in order to suppress an impact when the medium abuts on the lower surface side or the thickness side of the medium conveyed to the outer shutter 316, but the collision surface May be other shapes such as a spherical shape, a triangular shape, or the like as long as the shape allows the shock from the medium to be released. The material of the contact member 720 is a physical property that is soft to the stress in the shear direction and does not damage the surface of the contacted object, but is strong to the stress in the compressive direction. In addition, as shown in FIG. 7B, in order to remove static electricity, the contact member 720 uses a member in which carbon fibers are woven and stacked in plain weave as a frame member 790, contains metal powder, and is a rubber agent to which conductivity is imparted. The flexible member 780 is formed to be trapezoidally covered. Needless to say, the finger portion may also be produced by the above method. Also, as shown in FIG. 7C, the contact member 720 may be configured as a contact roller 740 having the rotation axis A at the finger portion 710.

  FIG. 2 shows a block diagram of the card processing apparatus 100. As shown in FIG. As shown in FIG. 2, the card processing device 100 reads magnetic information such as a magnetic stripe recorded on a medium, a main control unit 404 that controls each part of the card processing device 100, a conveyance unit 402 that conveys a medium, and It is configured to have an individual identification unit 450. The card processing apparatus 100 is also connected to a printer unit 940 that issues paper media such as statement slips. Further, the transport unit 402 includes various shutters and sensors shown in FIG. 1, a transport control unit 406 for controlling various motors and rollers for transporting the medium, an outer solenoid 311, an inner solenoid 318, and an outer shutter. A sensor 312, an inner shutter sensor 322, a width sensor 342, a conveyance motor 381, a medium sensor 341, and an upper end sensor 347 are configured. In addition, the individual identification unit 450 includes a magnetic control unit 452 that controls each unit of the individual identification unit 450, a magnetic analysis unit 453 that analyzes magnetic information of the medium, and an MS head 302 that reads the magnetic information of the medium. There is. The printer unit 940 also includes a printer control unit 462 that controls each unit of the printer unit 940 and a conveyance / printing mechanism 463 controlled by the printer control unit 462. The IC card control unit 465, the IC card contact unit, and the signal line 488 will be described later in a second embodiment.

  The main control unit 404 of the card processing apparatus 100 receives an operation mode indicating execution / non-execution of transport processing from the upper apparatus 401 configured by an ATM or the like via the signal line 471, opening instruction, suction / identification of medium, Receive various instructions necessary for processing the medium, including instructions for emission and recovery. When receiving these instructions, the main control unit 404 instructs the transport unit control unit 406, which mainly controls the transport unit 402 that is the transport element group of the medium, to perform transport instructions similar to “inhale” and “discharge”. An instruction is given via signal line 472. Further, the main control unit 404 instructs the magnetic control unit 452, which controls the individual identification unit 450 which is a group of identification elements of the medium, an instruction of individual identification (reading of magnetic information) through the signal line 482 Do. In particular, when an identification instruction is received from the upper apparatus 401, the process is executed in synchronization with the transport control unit 406 and the magnetic control unit 452. Hereinafter, the operation of the card processing apparatus 100 will be described with reference to FIGS. 3, 4A and 4B. In FIG. 3, it is assumed that the outer shutter 326 is opened by the outer solenoid 311 in response to the opening instruction from the host device 401.

  As shown in FIG. 3, when the instruction to execute the conveyance processing and the instruction of the “individual identification” are received from the upper apparatus 401 via the main control unit 406 (FIG. 4A (A)), the conveyance control unit 406 starts monitoring the medium sensor 341 connected via the signal line 479 (S320), and the medium sensor 341 detects that the medium H held by the user's hand H is inserted from the outside (S320; Yes, FIG. 4A (B)), the drive instruction of the conveyance motor 381 is given via the signal line 478 (S325).

  Next, the transport control unit 406 drives the inner solenoid 318 via the signal line 474 to bring the inner shutter 326 into the open state (FIG. 4A (C)), and the signal line 473. By driving the outside solenoid 311, the outside shutter 316 is closed, and the medium inserted from the outside is fitted [fitting operation] (S335, FIG. 4B (D)). As described above, in the fitting operation, the outer shutter 316 is closed, the inner shutter 326 is opened, and the outer shutter 316 is in contact with the lower surface of the medium being conveyed inside the apparatus. When the medium detection sensor 341 detects the medium inserted from the insertion port 304, the conveyance control unit 406 performs the fitting operation of closing the first shutter and opening the second shutter, thereby conveying the medium. It is conveyed along the line 350 to the magnetic head 302. In addition, as shown in FIG. 5, in the fitting operation of S335, the outer shutter 316 and the inner shutter 326 are physically connected by the connecting rod S, and a so-called seesaw structure having a fulcrum P at its center point is used. It is also possible. In FIG. 5, for example, when the outer solenoid 311 opens the outer shutter 316, the inner shutter 326 is operated by the connecting rod S to be closed, and when the outer solenoid 311 closes the outer shutter 316, the inner shutter 326 is closed. Acts on the connecting rod S to open. Although FIG. 5 exemplifies the case where the outer solenoid 311 is provided without the inner solenoid 318, the same effect can be obtained when the inner solenoid 318 is provided without the outer solenoid 311 and the inner shutter 326 is operated. I can do it.

  If the media continues to be inserted by the user, roller pair 352 grips the media leading edge, thereby enabling media transport.

  Next, the conveyance control unit 406 monitors the upper end (detection) sensor 347 provided downstream of the second shutter in the conveyance direction of the medium via the signal line 481, and the sensor detects the medium. It is determined whether it has been detected (S345). When it is determined that the sensor detects medium presence (S345: Yes), the conveyance control unit 406 starts measuring the conveyance time of the inserted medium (S355, FIG. 4B (D)). If the transport control unit 406 determines that the outer shutter sensor 312 has not detected the presence of the medium (S345: No), that is, the medium is further transported inside the apparatus by the roller pair 352, and the above-mentioned engagement operation for the medium is completed. When the outer shutter 316 completes closing the transport path, the time measurement is ended, and the inserted medium length is calculated (S360, FIG. 4B (E)). As the method of time measurement, measurement may be performed by the number of steps of the pulse motor or measurement by the encode counter of the servomotor, in addition to pure time measurement.

  The transport control unit 406 determines whether the medium length is a specified length as a result of the calculation (S365), and when it is determined that the medium length is a specified length (S365; Yes), the inner shutter 326 is closed (S3). S375) A signal to the effect that conveyance has been completed is output to the main control unit 404 (FIG. 4B (F)). Here, when the inner shutter 326 is closed, the outer shutter 316 is controlled to be opened. The main control unit 404 receives the signal, instructs the conveyance control unit 406 to carry out magnetic reading and conveyance, and instructs the magnetic control unit 452 to start magnetic reading by the MS head 302 via the signal line 482. The magnetic control unit 452 that has received the instruction starts magnetic reading by the MS head 302 (S 385), and instructs the magnetic analysis unit 342 to perform magnetic analysis via the signal line 483. Thus, the conveyance control unit 406 measures the time from when the medium upper end detection sensor 347 detects the medium to when the first shutter closes, and calculates the medium length based on the measured time, If the calculated length of the medium is a predetermined length, the second shutter is closed to cause the magnetic head 302 to read the magnetic information of the medium.

  Upon receiving the instruction, the magnetic analysis unit 453 analyzes the waveform information from the magnetic head 302 obtained through the signal line 484, encodes it, and transmits it as magnetic information (individual identification information) via the magnetic control unit 452 , And output to the main control unit 404. When the output magnetic information is received, the main control unit 404 instructs the conveyance control unit 406 to stop the magnetic reading and conveyance, and the conveyance control unit 406 stops the conveyance motor 381 (S395). Thereafter, the main control unit 404 transmits the magnetic information (individual identification information) to the host apparatus 401. If the instruction from the host device 401 or the setting in the main control unit 404 is an instruction or setting not to execute the time measurement of S355 or the length calculation process of S360, the medium is inserted, and the medium sensor 341 has a width When the sensor 342 detects the presence of the medium, the conveyance motor 381 is rotated, and the medium can be conveyed inside without performing these processing.

  Although the case where the medium is sucked is described above as an example, the case where the medium is discharged can be considered in the same manner. For example, as shown in FIG. 6A, the outer shutter sensor is that the transport motor 381 is transported in the discharge direction from the state in the vicinity of the MS head 302 after the magnetic information of the medium is read. It can detect by 312 and can report to the upper apparatus 401 via the conveyance control part 406 (FIG. 6 (B)).

  The positions of the medium sensor 341 and the width sensor 341 may be movable in consideration of the position of magnetic information such as a magnetic stripe attached to the medium. For example, as shown in the upper view of A-B in FIG. 1, a moving mechanism which is slide grooves 383 and 384 for moving the medium sensor 341 and the width sensor 341 in the width direction of the transport path 350 is provided. Provided with slide groove pairs 383 and 384 that can be attached to the position (in FIG. 1, the left end with respect to the suction direction) and a position symmetrical with the suction center axis (the right end with respect to the suction direction in FIG. It is good. As a result, as shown in FIG. 8, there is a card C with a highly reflective material 803 (in many cases, a film or label such as a premium seal or the like) on a specific part on the card surface. In the case of the sensor, since the highly reflective material 803 is present on the detection area 804 of the medium sensor 341, the medium sensor 341 can not detect the insertion of the card C at the position 808 due to the influence of disturbance light. Therefore, when the medium sensor 341 is moved to the position 809, false reading due to external disturbance light generated by the high reflection material 803 on the detection area 805 can be avoided. Further, although the example operation in the case of the fitting operation and the medium length measurement is described in the present embodiment, it is needless to say that the respective operations can be combined and implemented individually.

  FIG. 9A is a diagram showing an example of a statement printer used by a financial institution to which the card processing device shown in FIG. 1 is applied. In FIG. 9A, the card processing device 301 is provided as a card unit 960 in the lower part of the specification printer 901, and a printer unit 940 having the same transport path width as the card unit 960 is provided in the upper part. The printer unit 940 is configured to have a head 941 for printing information on a statement slip, and a cutter 942 for cutting the roll paper X into one statement slip.

  The conveyance path of the card unit 960 and the printer unit 940 is connected by an integrated discharge unit 950. The integrated discharge unit 950 is a mechanism for stacking and conveying the statement slip outputted from the printer unit 940 and the medium discharged from the card unit 960, and returning it to the customer. In the integrated discharge unit 950, the customer is required to convey the statement slip output from the printer unit 940, the conveyance roller 951 for conveying the medium discharged from the card unit 960 in an overlapping manner, the overlapped statement slip and the medium And a discharge port 952 for return to the Although not particularly shown, the printer unit 940 has a transport path for transporting the roll paper X and the statement slip, and the integrated discharge unit 950 has a transport path for transporting the overlapped statement slip and the medium. Have.

  The main control unit 404 and the printer unit 940 have a printer control unit 462 as shown in FIG. 2, and the printer control unit 462 is connected via a signal line 485. The printer control unit 462 is connected via a signal line 486 to a transport and printing mechanism 463 that transports, prints, and cuts the roll paper X and discharges it as a single sheet. For this reason, when an instruction of “individual identification” is received from the host apparatus 401, the main control unit 404 causes the printer control unit 462 to monitor a (substantially) residual detection sensor in the integrated discharge unit 950, and detects residualness. The printer control unit 462 instructs the conveyance / printing mechanism 436 to collect the residual medium. The main control unit 404 having received the residual medium recovery report via the printer control unit 462 instructs the conveyance control unit 406 to perform the above-described fitting operation, and conveys the medium to the integrated discharge unit 950. Thus, the card unit 960, the printer unit 940 for outputting the statement slip processed with the medium, and the common insertion slot for discharging the medium processed by the card unit 960 and the statement slip processed by the printer unit 940 Since the integrated discharge portion 950 having 952 is provided, the specification printer 901 can control to stack and discharge the medium and the statement slip.

  In FIG. 9A, the integrated discharge unit 950 stacks and transports the statement slip outputted from the printer unit 940 and the medium discharged from the card unit 960, but as shown in FIG. 9B, the integrated discharge unit 950 Alternatively, the statement slip outputted from the printer unit 940 may be conveyed to the card unit 960, and the card unit 960 may be provided with the same configuration as the integrated discharge unit 950. In this case, since it is not necessary to provide the integrated discharge unit 950 individually, the specification printer 901 can be configured more compactly.

  In the first embodiment, the medium sensor 341 and the width sensor 342 are disposed at predetermined positions of magnetic information such as a magnetic stripe or the like, and slide grooves for moving these are provided. However, even when an IC chip is attached to the medium, erroneous reading may occur due to disturbance light as in the case of the medium attached with the reflective material shown in FIG. Then, the structure which avoids the misreading by disturbance light is demonstrated about the medium to which IC chip was attached.

  FIG. 10 shows a transparent identification card (hereinafter referred to as a transparent identification medium) with an IC chip such as a so-called IC card in which an IC chip is attached to the medium (with magnetic material) shown in FIG. 13 and a transparent substrate is used. It is. 11A shows an example of the card processing apparatus according to the first embodiment, further including an IC card contact unit 466 for reading information recorded in an IC chip and an IC chip detection sensor 1101 for detecting an IC chip. -B is a top view. As shown, an IC card contact portion 466, which is an IC chip reading portion, is provided further downstream in the medium transport direction than the second shutter. The card processing apparatus in the second embodiment is connected to the main control unit 471 via the IC card control unit 465 as shown in FIG. Similar to the medium sensor 341 and the width sensor 341, the IC chip detection sensor 1101 is provided with a moving mechanism having a slide groove for moving the IC chip detection sensor 1101 according to the position to which the IC chip is attached. Good. In this case, since it is necessary to move the IC card contact portion 466 to the same position in the width direction of the transport path, the IC card contact portion 466 may be provided with a similar moving mechanism.

  In addition, since the transparent identification medium as described above reflects external light from the oblique transport direction and is easily guided as disturbance light to the back of the transport path, the medium detection sensor 341 is likely to be erroneously detected. Therefore, the false detection preventing sensor 386 is disposed at a position along the upper edge of the magnetic stripe (a position dd on the center side of the conveyance path above the center line MH) for false detection prevention. In order to prevent false detection, the false detection preventing sensor 387 is disposed at a position along the lower edge of the magnetic stripe (position dd on the edge side of the transport path below the center line MH). Thus, the erroneous detection preventing sensors 386 and 387 are provided downstream of the IC chip reading sensor 1011 and the second shutter in the transport direction. The output values of the false detection prevention sensors 386 and 387 are configured as a logical sum. That is, when either of the false detection preventing sensors 386 and 387 detects the transparent identification medium, it is determined that the medium is present.

  The reason why the false detection preventing sensors 386 and 387 are disposed along the upper and lower edges of the magnetic stripe is that when the transparent identification medium having a notch as shown in FIG. In the case of reading of magnetic information such as stripes or reading of an IC chip, it may be obliquely transported to such an extent that it can be read correctly. In this case, if the false detection preventing sensors 386 and 387 are disposed at the center position MH of the MS head 302, detection of the non-transmissive portion of the transparent identification medium may not be possible. When one or a plurality of anti-skewing rollers 1106 connected to the transport motor 381 having a narrow trapezoidal shape on the MS head 302 side are disposed, it is possible to prevent the sheet from being obliquely transported as described above. The operation of the card processing apparatus according to the second embodiment will be described below with reference to FIGS.

  In order to suck the transparent identification medium, the medium sensor 341 and the width sensor 341 are manually or mechanically moved in the vicinity of the magnetic stripe which is the non-transmissive portion of the transparent identification medium in the previous step (arrow M in FIG. 11). . Further, as a premise, it is assumed that the host device 401 has not instructed the main control unit 404 to execute the fitting operation described in the first embodiment.

  As shown in FIG. 12, when the transparent identification medium is inserted from the insertion port 304 by an external force, the conveyance control unit 406 determines that the medium sensor 341 is a non-transmissive portion of the transparent identification medium 1001. It is determined whether a part has been detected (S1205). When the transport control unit 406 determines that the medium sensor 341 detects the magnetic stripe portion (S1205; Yes), the drive of the transport motor 381 is started (S1210). Thereafter, as in the case of the first embodiment, whether or not the transport control unit 406 has detected that the transparent identification medium has passed the width sensor 342 by the external force of the user's hand or the like. If it is determined that the transparent identification medium has passed the width sensor 342 (S1215; Yes), the roller pair 352 grips the transparent identification medium, and the card processing device is determined. The power of the conveyance motor 381 is pulled into the interior of the unit 301. At this time, it is assumed that the IC chip detection sensor 1101 detects the presence of the IC chip.

  As in the first embodiment, the transport control unit 406 continues to draw in the transparent identification medium and determines whether the medium sensor 341 no longer detects the transparent identification medium (S1220). When the transport control unit 406 determines that the transparent identification medium is not detected (S1220; Yes), it is determined that the external force is pulled away from the external force, and the disturbance light of the surface of the transparent identification medium is determined. The outer shutter 316, which can be prevented, is closed (S1230). The transport control unit 406 is from the IC card contact portion 466 to the IC chip 1006 attached to the IC transparent identification medium, from the positional relationship between the medium sensor 341, the width sensor 342, the IC card contact portion 466, and the IC chip 1006. It is determined whether or not the distance is a predetermined distance (S1235, S1240). If the transport control unit 406 determines that the distance between the IC card contact portion 466 and the IC chip 100 is a predetermined distance (S1240; Yes), the transport motor 381 is stopped (S1245) . The transport control unit 406 joins the IC card contact portion 466 and the IC chip 1006, and determines whether the information recorded in the IC chip 1006 has been read (S1250).

  If the transfer control unit 406 determines that the information recorded in the IC chip 1006 has been read (S1250; Yes), it is considered that bonding is completed, individual information identification is performed (S1255), and the upper apparatus 401 is individually identified. Send information

  If it is determined in S1215 that the conveyance control unit 406 has not detected that the transparent identification medium has passed the width sensor 342 (S1215; No), the reason is that the driving of the conveyance motor 381 is started It is determined that the width sensor 341 is caused by flickering due to disturbance light, and the transport roller pair 353 further transports the transparent identification medium by the transport motor 381. Thereafter, the transport control unit 406 determines whether the false detection preventing sensor 386 or 387 detects the presence of the medium (S1260), and when it is determined that the presence of the medium is detected (S1260; Yes), the outer shutter 316 To prevent the influence of disturbance light (S1265), stop the conveyance motor 381, and drive the conveyance roller pair 353 in the discharge direction opposite to that before the conveyance of the transparent identification medium (S1270). ).

  The conveyance control unit 406 determines whether the width sensor 342 detects the transparent identification medium (S1275), and when it is determined that the width sensor 342 detects the transparent identification medium (S1275; Yes), conveyance is performed The driving of the motor 381 is stopped and the transport direction is reversed to set it as the suction direction (S1285). Further, the medium sensor 341 detects the above-mentioned transparent identification medium sucked (S1220), and the same processing from S1230 onwards. As described above, when the false detection preventing sensors 386 and 387 detect the medium when the medium detection sensor 341 does not detect the medium, the conveyance control unit 406 conveys the medium in the direction opposite to the conveyance direction and detects the medium. The medium detected by the sensor 341 is conveyed again to the IC card contact portion 466.

  Although two false detection preventing sensors are provided in the present embodiment, the number is arbitrary. Further, as in the case of the first embodiment, the transparent identification medium may be engaged with the shutter only at the time of suction, or may be engaged at the time of discharge.

  As described in the first and second embodiments, the detection of the identification card having a special shape which is not rectangular is conveyed inside while the shutter is engaged with the shutter instead of the width sensor in the card reader, and the shutter can not be closed. When the identification card is taken into the interior, it has a special shape that has conventionally been discharged or can not be inhaled as a foreign substance, and the identification card whose substrate has become transparent (it has become a special shape due to secular change The card (also including the card) can be transported inside the processing device to read individual information.

  Note that the conveyance control unit 406 performs the above-mentioned fitting operation and / or medium according to an instruction from the higher-level device 401 connected to the card processing device 301 or a setting inside the card processing device 301 (for example, a setting stored in memory in advance). The calculation of the length of may be selectable. By making such a process selectable, it is possible to select these processes for the card processing device 301 as necessary.

301: Card processing device 302: Magnetic head 304: Insertion port 311: Outer (side) solenoid 312: Outer (side) shutter (open / close detection) sensor 316: Outer shutter 318: inner (side) solenoid 322: inner (side) shutter (Open / close detection) sensor 326: inner (side) shutter 341: medium (detection) sensor 342: width (detection) sensor 347: upper end (detection) sensor 350: conveyance path 352, 353: roller pair 381: conveyance motor 382: sensor Mounting slide groove pair 383: Sensor mounting slide groove pair 401: Host device 402: Transport unit 404: Main control unit 406: Transport unit control unit 450: Individual identification unit 452: Magnetic control unit 453: Magnetic analysis unit 462: Printer control unit 463: Transport and printing mechanism 465: IC card control unit 466: IC card contact point 710: finger portion 720: contact bar 40: contact roller 780: Flexible member 790: skeletal material 840,940: printer unit 850,950: Integration emitting unit 860,960: card unit

Claims (9)

A card processing apparatus for processing a card-like medium having magnetic information recorded thereon, the card processing apparatus comprising:
An insertion slot,
A transport path for transporting the medium;
A first shutter provided on the insertion port side in the card processing device;
A second shutter provided downstream of the first shutter in the conveyance direction of the medium;
A medium detection sensor for detecting the medium provided between the first shutter and the second shutter;
An identification unit for reading the magnetic information of the medium;
When the medium detection sensor detects the medium inserted from the insertion port, the first shutter is closed, the fitting operation for opening the second shutter is performed, and the medium is moved along the transport path. A control unit for conveying to the identification unit;
A card processing apparatus comprising: The medium detection sensor is movable in the width direction of the transport path by a movement mechanism.
The card processing device according to claim 1, characterized in that: An IC chip detection sensor that detects an IC chip attached to the medium;
And an IC chip reading unit provided downstream of the second shutter in the conveyance direction of the medium.
The control unit transports the medium, of which the IC chip is detected by the IC chip detection sensor, to the IC chip reading unit along the transport path.
The card processing device according to claim 1, characterized in that: The IC chip reading sensor and a false reading prevention sensor for detecting the medium downstream of the second shutter in the transport direction,
When the medium detection sensor does not detect the medium, the control unit transports the medium in the direction opposite to the transport direction and the medium detection sensor detects the medium when the false reading prevention sensor detects the medium. Transport the transferred medium to the IC chip reading unit again,
The card processing apparatus according to claim 3, characterized in that: The first shutter and the second shutter are connected by a connecting member and opened and closed by a seesaw structure having a fulcrum at the center of the first shutter and the second shutter.
The card processing device according to claim 1, characterized in that: The first shutter or the second shutter is configured by a trapezoidal flexible member or roller at a contact portion with the medium.
The card processing device according to claim 1, characterized in that: A media end detection sensor is provided downstream of the second shutter in the transport direction of the media, for detecting the media end.
The control unit measures a time from when the medium end detection sensor detects the medium to when the first shutter closes, and calculates and calculates the length of the medium based on the measured time. When the length of the medium is a predetermined length, the second shutter is closed to cause the identification unit to read the magnetic information of the medium.
The card processing device according to claim 1, characterized in that: The control unit can select the fitting operation and / or the calculation of the length of the medium according to an instruction from a host device connected to the card processing device or setting in the card processing device.
The card processing apparatus according to claim 7, characterized in that: The card processing apparatus, a printer unit for outputting a statement slip to be processed with the medium, and the common insertion slot for discharging the medium processed by the card processing device and the statement slip processed by the printer unit Integrated release unit,
A statement slip issuing device comprising:

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