JP2018156170A - Card processing unit and ticket machine - Google Patents

Abstract

A technique for shortening the time required to reinsert a card inserted in an incorrect posture is provided. A card processing unit (5) is capable of inserting a card (9) provided with an emboss (91) on a surface (9a), and includes an insertion slot (51) into which the card (9) is inserted and a claw part (56). When the card 9 is inserted in the first posture which is the correct insertion posture to the insertion slot 51, the claw portion 56 does not catch the emboss 91, and the front and rear are reversed without changing the direction of the surface 9a from the first posture. When the card 9 is inserted in the second posture, the emboss 91 is caught. [Selection] Figure 4

Description

  The present invention relates to a technique for regulating the posture of a card at the time of insertion.

  Many ticket vending machines that can be settled with a credit card take a card inserted from an insertion slot and read card information with a card reader provided inside. Further, in the conventional ticket vending machines, there are many cards that can be used for settlement limited to magnetic cards.

  In recent years, in order to improve card security, IC (Integrated Circuit) has been developed. For this reason, it has been proposed to apply IC card reading technology (see, for example, Patent Document 1 or 2) to ticket vending machines. In particular, in a ticket vending machine capable of reading a contact-type IC card, information on the IC card is read through the IC contact by bringing a connection terminal of the card reader into contact with an IC contact provided on the surface of the IC card.

  When reading a magnetic card or contact IC card with a card reader, the insertion posture when inserting these cards into the insertion slot is important. Only when the card is inserted in the correct posture, the card reader reads the card information. Reading is done correctly.

Japanese Patent Laying-Open No. 2015-195025 Japanese Patent No. 4530634

  On the other hand, if the card is inserted in an incorrect posture, the card reader cannot read the card information correctly, resulting in an error. As an example in which the card is inserted in an incorrect posture, if the magnetic card is inserted upside down, the information string recorded in the magnetic stripe cannot be read by the card reader, resulting in an error. As another example, when an IC card is inserted upside down, the connection terminal of the card reader cannot be brought into contact with the IC contact, resulting in an error.

  In the conventional ticket vending machine, when a card is taken in an incorrect posture, it is necessary to eject the card from the insertion slot and prompt the user to reinsert the card. The time required for such reinsertion is a cause of prolonging the time until the card information is correctly read.

  Therefore, an object of the present invention is to provide a technique for shortening the time required for reinserting a card inserted in an incorrect posture.

  The card processing unit according to the present invention is capable of inserting a card having an embossed surface, and includes an insertion slot into which the card is inserted and a claw portion. When the card is inserted in the first posture which is the correct insertion posture into the insertion slot, the emboss is not caught on the claw portion, and the front and rear are reversed from the first posture without changing the surface direction. When the card is inserted, the emboss is caught on the claw portion.

  According to the card processing unit, the posture of the card can be regulated so that the card is inserted into the insertion slot in the correct first posture. That is, when the card is inserted in the first posture, the claw portion is not caught by the emboss, and the passage of the card is permitted. On the other hand, when the card is inserted in the wrong second posture, the claw portion is caught by the emboss and the passage of the card is prevented. Therefore, the user can recognize at the time of insertion that the card has been inserted into the insertion slot in the wrong second posture, and can immediately change the card to the correct first posture and insert it again.

  In the card processing unit, the claw portion is preferably unevenly distributed to one side in the width direction of the insertion slot.

  In the card processing unit, in the insertion direction of the card into the insertion slot, the claw portion is preferably arranged at a position where the emboss is caught before half of the card is inserted into the insertion slot. According to this configuration, when the passage of the card is blocked, the card stops with more than half of the card coming out of the insertion slot. Therefore, the user can easily remove the card from the insertion slot.

  The card processing unit preferably includes a reversing unit and a reading unit. Here, the reversing unit reverses the card so as to be in the first posture when the orientation of the surface of the card inserted from the insertion slot is opposite to the orientation in the first posture. The reading unit can read card information from the card in the first posture. According to this configuration, even when the card 9 is inserted in the third posture with the front and back reversed from the first posture and the back side facing upward, the card posture is changed to the correct first posture by inverting the card. The card information can be read from the card in the first posture. Therefore, there is no need to return the card to the user and prompt re-insertion.

  As an example, the card includes a magnetic recording unit in which card information is magnetically recorded. When the reading unit cannot correctly detect the magnetic recording unit, the card is inverted by the inversion unit. As another example, the card has an IC contact connected to the reading unit, and when the reading unit cannot detect the IC contact, the card is reversed by the reversing unit.

  The ticket vending machine according to the present invention includes the card processing unit.

  According to the present invention, it is possible to shorten the time required to reinsert a card inserted in an incorrect posture.

It is the block diagram which showed the structure of the ticket vending machine which can apply the card processing unit of this invention. It is the front view which showed the ticket machine conceptually. It is the conceptual diagram which showed the structure of the card processing unit which concerns on 1st Embodiment. It is the (A) perspective view and (B) longitudinal cross-sectional view which showed the principal part of the card processing unit. (A) It is the enlarged front view of the insertion slot in which a card | curd is inserted, and the perspective view which showed the (B) nail | claw part seeing from the bottom face side. It is the perspective view which showed another attitude | position of the card | curd at the time of insertion. It is the enlarged front view which showed the modification of the nail | claw part. (A) (B) It is the perspective view which showed another attitude | position of the card | curd at the time of insertion. It is the conceptual diagram shown in the structure of the card processing unit which concerns on 2nd Embodiment. It is the block diagram which showed the structure of the control unit relevant to card processing. It is the flowchart which showed a series of flows of the card | curd process with respect to a contact-type IC card. (A)-(D) It is the figure which showed the inversion part at the time of execution of a card | curd process, and the motion of a card | curd. It is the flowchart which showed a series of flows of the card process with respect to a magnetic card. 6 is a flowchart showing a series of card processing for a card having both an IC contact and a magnetic stripe.

  FIG. 1 is a block diagram showing the configuration of a ticket vending machine to which the card processing unit of the present invention can be applied. FIG. 2 is a front view conceptually showing the ticket vending machine. As shown in FIGS. 1 and 2, the ticket vending machine includes a display unit 1, an operation unit 2, a ticket issuing unit 3, a currency processing unit 4, a card processing unit 5, a PIN pad 6, and a communication unit 7. And a control unit 8 connected to these units through a signal transmission line such as a cable. A ticket vending machine is installed at a station and issues tickets such as commuter passes, tickets, and coupon tickets to users. Furthermore, the ticket vending machine can perform a monetary process in which a transaction amount for issuing a ticket is settled with money and a settlement process in which the transaction amount is settled with a credit card. Here, money is a general term for coins and banknotes.

  Here, the credit card includes a magnetic card having a magnetic stripe (corresponding to a “magnetic recording unit” recited in the claims) on the surface and an IC card having an IC built therein. There are two types of IC cards, a contact type having an IC contact on the surface and a non-contact type having an antenna coil built-in. Some credit cards include both an IC and a magnetic stripe.

  The display unit 1 includes a display 11 provided in front of a ticket vending machine main body (hereinafter simply referred to as “main body”), and controls screen display of the display 11.

  The operation unit 2 has an input device for inputting information on a ticket to be purchased (hereinafter referred to as “ticket information”). The input device includes a touch panel 21 attached to the display 11 and a push button switch 22. The operation unit 2 detects a user's input operation on the touch panel 21 (a pressing position on the touch panel 21 pressed by the user with a finger), and outputs input operation data corresponding to the detected pressing position to the control unit 8. The operation unit 2 also outputs input operation data corresponding to the push button switch 22 pressed by the user to the control unit 8.

  The ticket issuing unit 3 performs a ticket issuing process for issuing a ticket. The ticket vending machine is provided with a ticket opening 31 on the front face of the main body, and the ticket issuing unit 3 discharges the issued ticket from the ticket opening 31.

  The money handling unit 4 accepts money inserted by the user, and discharges change when receiving an amount exceeding the transaction amount for issuing the ticket. Of the coins used for settlement, coins are inserted from a coin insertion slot 41A provided on the front face of the main body, and banknotes are input from a bill insertion slot 42A provided on the front face of the main body. Of the change, coins are discharged from a change coin receiving tray 41B provided on the front of the main body, and banknotes are discharged from a banknote discharge port 42B provided on the front of the main body. The money handling unit 4 has a money identifying unit (not shown) for identifying the denomination and authenticity of money inserted by the user and change to be returned to the user.

  The card processing unit 5 has an insertion slot 51 into which a credit card is inserted, takes in the card inserted from the insertion slot 51, and reads card information (card data) recorded on the taken-in card. The card processing unit 5 outputs the card information read from the card to the control unit 8, and after the settlement process is completed, the card processing unit 5 ejects the card from the insertion slot 51 and returns it to the user. Details of the card processing unit 5 will be described later.

  A PIN (Personal Identification Number) pad 6 is used for input operation of ticket information, input operation of an authentication code at the time of card settlement, and the like.

  The communication unit 7 communicates with devices such as various servers via a network. As an example, the communication unit 7 makes an authentication request to the authentication server by communicating with an authentication server that performs authentication at the time of card settlement. The authentication server performs card authentication in response to the authentication request, and returns an authentication result to the communication unit 7. Note that the communication unit 7 also communicates with station equipment such as an automatic ticket gate (not shown) and other ticket machines.

  The control unit 8 is a processing device such as a CPU (Central Processing Unit) or a microcomputer. The control unit 8 executes a payment process when the card authentication is normally completed.

  Details of the card processing unit 5 will be specifically described below. In addition, each part structure of the card processing unit 5 demonstrated below can be applied not only to a ticket vending machine but also to various apparatuses which can be settled with a card, and various cards which are not limited to a credit card are used. It can also be applied to processing equipment.

[1] First Embodiment FIG. 3 is a conceptual diagram showing a configuration of a card processing unit 5 according to a first embodiment. As shown in FIG. 3, the card processing unit 5 includes a credit card transport path 52 inserted from the insertion slot 51, a plurality of transport rollers 53 for transporting the credit card along the transport path 52, and Is provided. In the following, regarding the rotation of the transport roller 53, the rotation for moving the card 9 toward the various reading units (magnetic reading unit 54 </ b> A, etc.) along the transport path 52 is referred to as “forward rotation”. The rotation in which the card 9 is moved toward the insertion slot 51 is referred to as “reverse rotation”.

  In addition, the card processing unit 5 is provided with a reading unit that reads information on a corresponding card for each type of card that can be used for settlement at a ticket vending machine or the like. In the present embodiment, the card processing unit 5 includes a magnetic reading unit 54A that reads card information recorded in a magnetic stripe, a contact IC reading unit 54B that reads card information in the IC through IC contacts, and an IC through an antenna coil. And a non-contact IC reading unit 54C for reading the card information therein. In the card processing unit 5, one or several of these reading units may be selectively provided according to the type of card that can be used.

  The magnetic reading unit 54A can correctly read the information string (card information) recorded on the magnetic stripe from the head when the posture of the magnetic card is correct when reading the card information. On the other hand, when the orientation of the magnetic card is reversed, the magnetic reading unit 54A cannot correctly read the information string recorded in the magnetic stripe, and the control unit 8 determines that an error has occurred. .

  The contact-type IC reading unit 54B has a connection terminal that can be brought into contact with an IC contact when the IC card is placed in a reading execution position in a correct posture. Therefore, when the posture of the IC card at the reading execution position is correct, the contact-type IC reading unit 54B can read the card information in the IC through the IC contact by bringing the connection terminal into contact with the IC terminal. it can. On the other hand, when the posture of the IC card at the reading execution position is an incorrect posture, the contact type IC reading unit 54B cannot bring the connection terminal into contact with the IC contact. For this reason, the contact IC reading unit 54B cannot correctly read the card information, and the control unit 8 determines that an error has occurred.

  On the other hand, the non-contact IC reading unit 54C can read card information in the IC through the antenna coil regardless of the posture of the IC card.

  4A and 4B are a perspective view and a longitudinal sectional view, respectively, showing a main part of the card processing unit 5 according to the first embodiment. FIG. 5A is an enlarged front view of the insertion port 51. The card processing unit 5 includes a guide portion 55 that facilitates insertion of a credit card into the insertion slot 51 and a claw portion 56 that regulates the insertion posture of the credit card. FIG. 5B is a perspective view showing the claw portion 56 as seen from the bottom surface side.

  As described above, especially in the case of a magnetic card and a contact type IC card (including a combination of these cards), the posture of each of the magnetic reading unit 54A and the contact type IC reading unit 54B is to read the card information correctly. Is important to. That is, these cards are preferably inserted into the insertion slot 51 in a correct posture (hereinafter, this insertion posture is referred to as a “first posture”). On the other hand, many of these cards are provided with an emboss on the surface, and the present inventors have found that the card insertion posture is regulated using the emboss.

  Therefore, in the following, among the credit cards inserted from the insertion slot 51, the card 9 (see FIGS. 4A and 4B) provided with the emboss 91 on the surface 9a is restricted in the insertion posture by the claw portion 56. It is targeted. In particular, those in which the emboss 91 is unevenly distributed to one side in the width direction (short direction) of the card 9 are subject to restriction.

  The guide portion 55 includes a road surface 55a that supports the card 9 when inserted from below, and side surfaces 55b and 55c that restrict the left and right movement of the card 9 when inserted. And as for the guide part 55, the lower end edge of the insertion port 51 is comprised by the road surface 55a, and the left-right side edge of the insertion port 51 is comprised by each of the side surfaces 55b and 55c.

  The claw portion 56 is provided so as to protrude downward from the upper end edge 51a of the insertion port 51 when the insertion port 51 is viewed from the front. And the nail | claw part 56 is more than thickness T1 of the base material 92 (refer FIG. 4 (A) and (B)) of the card | curd 9 between the front-end | tip 56a and the road surface 55a (or lower end edge of the insertion port 51). In addition, a gap G including the emboss 91 and having a thickness less than T2 is formed.

  Further, the claw portion 56 has a shape in which the downstream edge of the emboss 91 in the insertion direction Di is caught when the card 9 is inserted. In this embodiment, the nail | claw part 56 is exhibiting the shape in which the contact surface 56b contact | abutted to the edge of the emboss 91 was formed (refer FIG. 4 (B)). The shape of the claw portion 56 is not limited to the shape in which the abutment surface 56b is formed, and may be deformed into various shapes such as a shape in which a tip is formed as long as the edge of the emboss 91 is hooked. it can.

  In this embodiment, the nail | claw part 56 is unevenly distributed to one side in the width direction Dw of the insertion port 51, as shown to FIG. 5 (A). Specifically, when the card 9 is inserted in the first posture (see FIG. 4A) which is the correct insertion posture into the insertion slot 51, the emboss 91 is not caught on the claw portion 56, whereas the first Without changing the orientation of the front surface 9a from the posture (with the front surface 9a facing upward, ie, with the rear surface 9b being in surface contact with the road surface 55a), the card 9 is in a second posture reversed (see FIG. 6). When is inserted, the claw portion 56 is provided so that the emboss 91 is hooked on the claw portion 56. More specifically, the nail | claw part 56 is formed in the area | region R1 of the half on one side from the center of the insertion port 51 in the width direction Dw. Within the region R1, the claw portion 56 may be partially formed as shown in FIG. 5A or may be formed over the entire region as shown in FIG.

  According to the claw portion 56, the posture of the card 9 can be regulated so that the card 9 is inserted into the insertion slot 51 in the correct first posture. That is, when the card 9 is inserted in the first posture, the emboss 91 passes through a region R2 that is different from the region R1 in the front view (see FIG. 5A). For this reason, the nail | claw part 56 is not caught in the emboss 91, and passage of the card | curd 9 is permitted. On the other hand, when the card 9 is inserted in the wrong second posture, the emboss 91 passes through the region R1 when viewed from the front (see FIG. 5A). For this reason, the nail | claw part 56 is caught in the emboss 91, and passage of the card | curd 9 is blocked | prevented. Therefore, the user can recognize at the time of insertion that the card 9 has been inserted into the insertion slot 51 in the wrong second posture, and can immediately insert the card 9 again in the correct first posture.

  Therefore, according to the card processing unit 5 of the present embodiment, it is possible to prevent the card 9 from being taken in the wrong second posture. As a result, even when the user inserts the card 9 in a wrong posture, the time required for reinsertion is shortened. Therefore, the time required for the card processing to be completed after the user starts inserting the card 9 is shortened.

  Further, in order to enable re-insertion by the user, the claw portion 56 is arranged at a position where the emboss 91 is caught before the entire card 9 is inserted into the insertion slot 51 in the insertion direction Di. Is preferred. As a result, when the passage of the card 9 is blocked, the card 9 stops in a state where a part of the card 9 comes out of the insertion port 51. Further, in order to facilitate re-insertion by the user, the claw portion 56 is arranged at a position where the emboss 91 is hooked before the half of the card 9 is inserted into the insertion slot 51 in the insertion direction Di. It is preferable (see FIG. 4B). Specifically, the claw portion 56 is arranged such that the distance L from the position where the emboss 91 abuts to the insertion port 51 is smaller than half the length of the card 9 (length in the longitudinal direction). When the passage of the card 9 is prevented by arranging the claw portion 56 at such a position, the card 9 stops in a state in which more than half of the card 9 has come out of the insertion port 51. Therefore, it becomes easy for the user to remove the card 9 from the insertion slot 51.

[2] Second Embodiment In the first embodiment, the card 9 has the back surface 9b facing upward (that is, the front surface 9a is directed toward the road surface 55a, see FIGS. 8A and 8B). When the card 9 is inserted into the card 51, the insertion posture of the card 9 is restricted as follows.

  That is, when the card 9 is inserted in the third posture (see FIG. 8A) with the front and back reversed from the first posture and the back surface 9b facing upward, the emboss 91 is viewed from the front (FIG. 5A). Pass through the region R2 in the reference). At this time, a portion of the card 9 where the emboss 91 is not formed is passed through the gap G between the road surface 55a and the claw portion 56. For this reason, the passage of the card 9 is permitted in the third posture.

  On the other hand, when the card 9 is inserted in the fourth posture (see FIG. 8 (B)) with the back surface 9b facing upward without changing the front and back from the first posture, the emboss 91 is viewed from the front (see FIG. 5 (A)). ) In the region R1. At this time, the portion of the card 9 where the emboss 91 is formed, in particular, cannot pass through the gap G because the thickness T2 is larger than the gap G between the road surface 55a and the claw portion 56. For this reason, the passage of the card 9 is prevented in the fourth posture.

  Although the third posture is a posture in which passage is permitted, reading the card information by the magnetic reading unit 54A and the contact IC reading unit 54B results in an error. Therefore, the card processing unit 5 may be provided with a mechanism for changing the posture of the card 9 taken inside to the correct first posture. This will be specifically described below as a second embodiment.

  FIG. 9 is a conceptual diagram showing the configuration of the card processing unit 5 according to the second embodiment. As shown in FIG. 9, the card processing unit 5 further includes an inversion unit 57 that inverts the card 9. When the orientation of the surface 9a of the card 9 inserted from the insertion slot 51 is opposite to the orientation when the card 9 is in the first posture, the reversing unit 57 reverses the card 9 so as to be in the first posture. In the present embodiment, the reversing unit 57 is disposed between the insertion port 51 and various reading units (such as the magnetic reading unit 54A).

  The reversing unit 57 includes a belt unit 571, a roller unit 572, and a rotation driving unit 573. Between the belt portion 571 and the roller portion 572, a passage 521 that forms a part of the conveyance path 52 is formed.

  The belt portion 571 includes a driving roller 571A, a driven roller 571B, and a conveying belt 571C stretched around these, and the conveying belt 571C circulates according to the rotation of the driving roller 571A. The drive roller 571A is a roller that can selectively perform forward rotation and reverse rotation, and the transport belt 571C rotates in the same direction as the drive roller 571A.

  Hereinafter, with respect to the rotation of the drive roller 571A and the conveying belt 571C, the card 9 is read along various paths 521 with reference to the time when the belt portion 571 is disposed below the path 521. 54A or the like) is referred to as “forward rotation”, and rotation for moving the card 9 toward the insertion slot 51 along the passage 521 is referred to as “reverse rotation”. Therefore, when the belt portion 571 is disposed on the upper side with respect to the passage 521, the card 9 moves toward various reading portions (such as the magnetic reading portion 54A) by rotating the transport belt 571C forward. The card 9 moves toward the insertion slot 51 by rotating the transport belt 571C in the reverse direction.

  The roller portion 572 includes a pair of rollers 572A and 572B disposed to face the conveyance belt 571C with the passage 521 interposed therebetween. The rollers 572A and 572B are arranged such that the distance between them is smaller than the length of the card 9 (length in the longitudinal direction) and appropriate pressure is applied to the conveyor belt 571C. Therefore, the card 9 is smoothly transported along the passage 521 by the circulation of the transport belt 571C. Further, when the card 9 stops at a predetermined position in contact with any of the rollers 572A and 572B in the passage 521 (see FIG. 12B), the card 9 is sandwiched between the belt portion 571 and the roller portion 572 with an appropriate pressure. It will be.

  The rotation driving unit 573 interchanges the upper and lower sides of the belt unit 571 and the roller unit 572 by rotating the belt unit 571 and the roller unit 572 by 180 ° around the rotation shaft 573a (that is, reverse). Here, the rotation shaft 573a serving as the center of rotation is parallel to various rollers such as the drive roller 571A and coincides with a position on the passage 521 (preferably, an intermediate position in the conveyance direction of the card 9). Is set. Therefore, even when the upper and lower sides of the belt portion 571 and the roller portion 572 are exchanged by the rotation drive portion 573, the position of the passage 521 is hardly changed (see FIGS. 12B and 12C), and therefore the conveyance There is almost no step between the other part of the path 52.

  Hereinafter, among the rotational postures of the reversing portion 57, the posture in which the belt portion 571 is disposed on the lower side with respect to the passage 521 is referred to as “reference posture”, and the posture in which the belt portion 571 is disposed on the upper side with respect to the passage 521. Is “inverted posture”.

  According to the reversing unit 57, even when the card 9 is taken in the third posture (FIG. 8A), the card 9 is stopped at a predetermined position in the passage 521 in the reference posture. By rotating the reversing unit 57 so as to be in the reversed posture, the posture of the card 9 can be changed from the third posture to the first posture. At this time, since the card 9 is sandwiched between the belt portion 571 and the roller portion 572 at a predetermined position in the passage 521, the card 9 does not fall out of the passage 521 when the reversing portion 57 rotates. Thereafter, by rotating the conveyor belt 571C in the reverse direction, the card 9 in the first posture can be moved toward various reading units (such as the magnetic reading unit 54A).

  The reversing process for the card 9 described above is executed by the control unit 8 controlling the reversing unit 57. Details of the inversion process will be described below.

  FIG. 10 is a block diagram showing the configuration of the control unit 8 related to card processing. As shown in FIG. 10, the control unit 8 includes a conveyance processing unit 81, a reading processing unit 82, a determination processing unit 83, a reverse processing unit 84, an authentication processing unit 85, and a settlement processing unit 86. . Note that these processing units related to card processing may be included in the card processing unit 5.

  The card processing described below may be realized by causing the control unit 8 or the card processing unit 5 to execute a corresponding program. And such a program may be memorize | stored in portable memory (for example, flash memory etc.) in the readable state, and may be memorize | stored in the memory | storage part (not shown) with which apparatuses, such as a ticket vending machine, are equipped. .

  First, card processing when the card 9 is a contact IC card will be described. FIG. 11 is a flowchart showing a series of card processing flow in this case. FIGS. 12A to 12D are conceptual diagrams showing the operations of the reversing unit 57 and the card 9 when the card process is executed.

  When the posture of the card 9 inserted from the insertion slot 51 is the first posture or the third posture, the card 9 passes through the claw portion 56 and is taken into the inside. Then, the conveyance processing unit 81 rotates the conveyance roller 53 and the conveyance belt 571C in the normal direction, thereby conveying the card 9 to the reading execution position corresponding to the contact IC reading unit 54B and stopping it (Step S11 and FIG. 12). (A)). At this time, the reversing unit 57 functions as a transport unit that transports the card 9 in the reference posture state.

  Thereafter, the reading processing unit 82 controls the contact-type IC reading unit 54B to lower the connection terminal and attempt to contact the IC contact 93 (see FIG. 4A) (step S12). When the connection terminal comes into contact with the IC contact 93, the IC contact 93 is detected by the contact IC reading unit 54B.

  At the time of execution of step S12 or immediately after execution, the determination processing unit 83 determines whether or not the IC contact 93 is detected by the reading processing unit 82 (step S13). When the card 9 is inserted in the first posture, the connection terminal can be brought into contact with the IC contact 93. Therefore, in step S13, it is determined that “the IC contact 93 has been detected (Yes)”. On the other hand, when the card 9 is inserted in the third posture, the connection terminal cannot be brought into contact with the IC contact 93, and therefore it is determined in step S13 that “IC contact 93 is not detected (No)”.

  That is, it is determined by the determination process in step S13 whether the posture of the card 9 inserted from the insertion slot 51 is the first posture or the third posture. The determination process in step S13 may be performed based on the detection result obtained by optically detecting the IC contact 93 with an optical sensor or the like, for example, before stopping the card 9 at the reading execution position.

  If it is determined in step S13 that “IC contact 93 has been detected (Yes)”, the reading processing unit 82 controls the contact IC reading unit 54B, whereby the card information in the IC is read through the IC contact 93. Reading is executed (step S14). After completing the reading of the card information, the authentication processing unit 85 executes the card authentication process using the card information (step S15), and when the card authentication is normally completed, the payment processing unit 86 executes the payment process. (Step S16).

  Thereafter, the reading processing unit 82 controls the contact IC reading unit 54 </ b> B to raise the connection terminal, thereby separating the connection terminal from the IC contact 93. Then, the conveyance processing unit 81 reversely rotates the conveyance roller 53 and the conveyance belt 571C, thereby conveying the card 9 from the reading execution position to the insertion port 51 and ejecting it from the insertion port 51 (step S17).

  On the other hand, if it is determined in step S13 that "IC contact 93 is not detected (No)", the reading processing unit 82 controls the contact IC reading unit 54B to raise the connection terminal, thereby connecting the connection. The terminal is separated from the card 9. Thereafter, the conveyance processing unit 81 reversely rotates the conveyance roller 53 and the conveyance belt 571C, thereby returning the card 9 to a predetermined position in the passage 521 in the reversing unit 57 and stopping the card 9 (step S18 and FIG. 12B). ).

  Thereafter, the inversion processing unit 84 controls the inversion unit 57 to rotate the inversion unit 57 about the rotation axis 573a so as to be in the inversion posture (step S19 and FIG. 12C). Thereby, the upper and lower sides of the belt portion 571 and the roller portion 572 are interchanged, and accordingly, the card 9 is also reversed, and the posture of the card 9 is changed from the third posture to the first posture. That is, the posture of the card 9 is a correct posture that enables the card information to be read by the contact IC reading unit 54B.

  Thereafter, the conveyance processing unit 81 reversely rotates the conveyance belt 571C to move the card 9 in the first posture toward the contact IC reading unit 54B. Further, the conveyance processing unit 81 rotates the conveyance roller 53 arranged at least between the reversing unit 57 and the contact IC reading unit 54B to rotate the card 9 discharged from the reversing unit 57 with the contact IC. It is transported to the reading execution position corresponding to the reading unit 54B and stopped (step S20 and FIG. 12D).

  Thereafter, the reversing processing unit 84 controls the reversing unit 57 to rotate the reversing unit 57 about the rotation shaft 573a so as to be in the reference posture (step S21 and FIG. 12A). The rotation direction of the reversing unit 57 at this time may be the same as the rotation direction in step 18 or may be the reverse direction. In FIG. 11, the case of the reverse direction (reverse inversion) is shown.

  After execution of step S21, the processing from step S12 is executed, and after completion of the settlement processing in step S16, the card 9 is discharged from the insertion slot 51 in step S17, whereby the card processing is completed.

  Next, card processing when the card 9 is a magnetic card will be described. FIG. 13 is a flowchart showing a series of card processing flow in this case. When the card 9 is inserted from the insertion port 51, the conveyance processing unit 81 conveys the card 9 to the reading execution position corresponding to the magnetic reading unit 54A by rotating the conveyance roller 53 and the conveyance belt 571C in the forward direction ( Step S31).

  Thereafter, the reading processing unit 82 controls the magnetic reading unit 54A to read the information string recorded in the magnetic stripe 94 (see FIGS. 8A and 8B) (step S32). 54 A of magnetic reading parts may be distribute | arranged only in any one of the upper side of the conveyance path 52, and the lower side, and may be distribute | arranged 1 each in both. In the present embodiment, a magnetic reading unit 54 </ b> A is disposed below the conveyance path 52.

  Then, the determination processing unit 83 determines whether or not the magnetic stripe 94 is correctly detected by the magnetic reading unit 54A (step S33). Specifically, the determination processing unit 83 determines whether or not the information string recorded in the magnetic stripe 94 has been correctly read from the head by the magnetic reading unit 54A. When the card 9 is inserted in the first posture, the information string is correctly read from the top, and therefore it is determined in step S33 that “the magnetic stripe 94 has been correctly detected (Yes)”. On the other hand, when the card 9 is inserted in the third posture, the magnetic reading unit 54A cannot correctly read the information string, and therefore it is determined in step S33 that “the magnetic stripe 94 is not detected correctly (No)”. .

  That is, it is determined by the determination process in step S33 whether the posture of the card 9 inserted from the insertion slot 51 is the first posture or the third posture.

  If it is determined in step S33 that “the magnetic stripe 94 has been correctly detected (Yes)”, the authentication processing unit 85 performs the card authentication process using the information string (card information) read by the magnetic reading unit 54A. Execute (Step S34). Thereafter, the processes of steps S16 and S17 described above (see FIG. 11) are executed.

  On the other hand, if it is determined in step S33 that "the magnetic stripe 94 is not detected correctly (No)", the above-described processing of steps S18 and S19 (see FIG. 11) is executed. Thereafter, the conveyance processing unit 81 reversely rotates the conveyance belt 571 </ b> C to move the card 9 in the first posture toward the magnetic reading unit 54 </ b> A. Further, the conveyance processing unit 81 rotates the conveyance roller 53 disposed at least between the reversing unit 57 and the magnetic reading unit 54A in the normal direction, thereby causing the card 9 discharged from the reversing unit 57 to be transferred to the magnetic reading unit 54A. The sheet is conveyed to the corresponding reading execution position (step S35).

  After the execution of step S35, the processing from step S32 is executed. After the settlement processing in step S16 is completed, the card 9 is discharged from the insertion slot 51 in step S17, whereby the card processing is completed.

  Further, card processing when the card 9 is provided with both the IC contact 93 and the magnetic stripe 94 will be described. FIG. 14 is a flowchart showing a series of card processing flow in this case. In this case, first, in steps S31 to S33, the information sequence recorded in the magnetic stripe 94 is read, so that the posture of the card 9 inserted from the insertion slot 51 is either the first posture or the third posture. It is judged whether there is. That is, the posture of the card 9 is determined using the magnetic stripe 94. When it is determined in step S33 that the posture of the card 9 is the third posture, the processing from step S18 is executed, whereby the card 9 is reversed.

  On the other hand, when it is determined in step S33 that the posture of the card 9 is the first posture, the conveyance processing unit 81 rotates the conveyance roller 53 forward so that the card 9 is changed to the contact IC reading unit 54B. It is transported to the corresponding reading execution position and stopped (step S41). Thereafter, the reading processing unit 82 controls the contact IC reading unit 54B to lower the connection terminal and bring the connection terminal into contact with the IC contact 93 (step S42). Then, with the connection terminal in contact with the IC contact 93, the reading processing unit 82 controls the contact IC reading unit 54B to read the card information in the IC through the IC contact 93 (step S43). ). Thereafter, processing from step S15 including card authentication processing is executed.

  According to the above card processing, even when the card 9 is inserted in the third posture, the posture of the card 9 can be changed to the correct first posture by inverting the card 9 and becomes the first posture. The card information can be read from the card 9. Therefore, there is no need to return the card 9 to the user and prompt re-insertion. Therefore, the time required for the card processing to be completed after the user starts inserting the card 9 is shortened.

  In the card processing, the determination of whether the posture of the card 9 inserted from the insertion slot 51 is the first posture or the third posture (steps S13 and S33) is performed on the front surface 9a or the back surface 9b of the card 9. The formed hologram and various marks may be detected by a sensor, and the detection may be performed based on the detection result.

  The card processing described above may be a combination of processing for a contact IC card (see FIG. 11) and processing for a magnetic card (see FIG. 13). Further, when the card 9 is provided with both the IC contact 93 and the magnetic stripe 94, information indicating that the card 9 is provided with the IC contact 93 may be recorded on the magnetic stripe 94. . Then, when the information is read by the magnetic reading unit 54A and it is determined in step S13 that "IC contact 93 is not detected (No)", the reversal process (step S19) is executed. May be. Thereby, it becomes possible to determine more accurately whether or not the card 9 is in the third posture.

  In the card processing, of the rotation postures of the reversing portion 57, the posture in which the belt portion 571 is disposed on the upper side with respect to the passage 521 is referred to as “reference posture”, and the belt portion 571 is disposed on the lower side with respect to the passage 521. It is also possible to use the “inverted posture”. In this case, the card processing described above can be applied as it is by defining the rotation of the drive roller 571A and the conveyor belt 571C as follows. That is, with reference to the time when the belt portion 571 is disposed on the upper side with respect to the passage 521, the rotation that moves the card 9 toward the various reading units (the magnetic reading unit 54A and the like) along the passage 521 is “ The rotation for moving the card 9 toward the insertion port 51 along the passage 521 is referred to as “reverse rotation”.

  The reversing unit 57 is not limited to the above configuration, and can be changed as appropriate as long as it can selectively carry and reverse the card 9.

DESCRIPTION OF SYMBOLS 1 Display unit 2 Operation unit 3 Ticketing unit 4 Money processing unit 5 Card processing unit 6 PIN pad 7 Communication unit 8 Control unit 9 Card 9a Front surface 9b Back surface 11 Display 21 Touch panel 22 Pushbutton switch 31 Ticketing port 41A Coin insertion port 41B Change Coin tray 42A Bill insertion slot 42B Bill ejection slot 51 Insertion slot 51a Upper edge 52 Transport path 53 Transport roller 54A Magnetic reader 54B Contact IC reader 54C Non-contact IC reader 55 Guide 55a Road surface 55b, 55c Side surface 56 Claw Part 56a tip 56b contact surface 57 reversing part 81 transport processing part 82 reading processing part 83 judgment processing part 84 reversal processing part 85 authentication processing part 86 settlement processing part 91 emboss 92 base material 93 IC contact 94 magnetic stripe 521 path 571 belt part 571A Drive roller 571 B Drive roller 571C Conveying belt 572 Roller portion 572A, 572B Roller 573 Rotation drive portion 573a Rotating shaft Di Insertion direction Dw Width direction G Clearance L Distance R1, R2 Regions T1, T2 Thickness

Claims (7)

A card processing unit capable of inserting a card with an embossed surface,
An insertion slot into which the card is inserted;
When the card is inserted in the first posture, which is the correct insertion posture into the insertion slot, the emboss is not caught, and the second posture in which the front and back are reversed from the first posture without changing the orientation of the surface. When the card is inserted, the emboss is caught,
A card processing unit.   The card processing unit according to claim 1, wherein the claw portion is unevenly distributed to one side in the width direction of the insertion slot.   3. The claw part according to claim 1, wherein the claw portion is arranged at a position where the emboss is caught before half of the card is inserted into the insertion slot in the insertion direction of the card into the insertion slot. Card processing unit. A reversing unit for reversing the card so as to be in the first posture when the orientation of the surface of the card inserted from the insertion port is opposite to the orientation in the first posture;
A reading unit capable of reading card information from the card in the first posture;
The card processing unit according to claim 1, further comprising: The card has a magnetic recording unit in which the card information is magnetically recorded,
5. The card processing unit according to claim 4, wherein when the reading unit cannot correctly detect the magnetic recording unit, the reversing unit reverses the card. The card has an IC contact connected to the reading unit,
5. The card processing unit according to claim 4, wherein when the reading unit cannot detect the IC contact, the reversing unit reverses the card.   A ticket vending machine comprising the card processing unit according to claim 1.

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