JP2006092140A - Automatic transaction device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To transact without re-inserting a card in the case of error of an inserting direction of the card, when using the integrated card integrating an IC chip and a magnetic stripe. <P>SOLUTION: A rotary stand 30 changing directions of the card is arranged on a card reader and writer 21 of an automatic transaction device. IC contact existence information and IC contact position information are included in the magnetic stripe of the card, and these information is read out by a magnetic head 28. Based on the read-out information, the direction of the card is turned over by feeding the card to the rotary stand 30 if necessary, and transaction can be performed by connecting the IC contacts. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an automatic transaction apparatus used in a financial institution or the like, and more particularly, to an automatic transaction apparatus that enables a transaction even if a card is inserted from any direction.

  Conventionally, in a transaction using an automatic transaction apparatus, a magnetic card for transaction used by a customer is provided with one magnetic stripe. When a magnetic card is inserted into the apparatus from the wrong direction during a transaction, the apparatus side Rejected and returned to the customer. Then, the transaction was started by changing the insertion direction and inserting the magnetic card into the apparatus again. However, the operation of inserting the magnetic card again is troublesome for the customer who uses the automatic transaction apparatus.

  In recent years, the use of cash cards and credit cards as IC cards has progressed, and magnetic cards integrated with IC chips (hereinafter referred to as integrated cards) are rapidly spreading. In the case of such an integrated card, the complexity at the time of card insertion is further increased for the following reason.

  First, the integrated card will be described with reference to FIG. FIG. 23 is an explanatory view showing a general integrated card. In FIG. 23, the integrated card 1 is provided with a credit card magnetic stripe 2 and an IC chip contact 3 on the upper surface, and a cash card magnetic stripe 4 on the lower surface. The IC chip 3 stores cash card and credit card data, and when inserted into an IC card-compatible automatic transaction apparatus, cash transactions and credits are used without using the magnetic stripes 2 and 3. Trading is possible.

  FIG. 24 shows a card reader / writer of the automatic transaction apparatus. FIG. 24A is a plan view thereof, and FIG. 24B is a side view thereof. In FIG. 24, the card reader / writer 11 of the automatic transaction apparatus is provided with a conveyance path 12 for conveying a card, and a plurality of conveyance rollers 13, 14, and 15 are rotatably provided across the conveyance path 12. ing. An IC chip contact 16 is provided above the transport path 12, and a magnetic head 17 is further provided. As shown in FIG. 24A, the IC chip contact 16 and the magnetic head 17 are provided on the right side with respect to the card insertion direction.

  Next, customer operations when using an integrated card will be described. In this case, it is assumed that both cash card data and credit card data are stored in the IC chip 3. In addition, when the integrated card 1 is inserted into an automatic transaction apparatus compatible with an IC card, the magnetic stripe data is not used.

  Pattern 1. A case will be described in which the specification of the automatic transaction apparatus is compatible with the IC card, the customer's desired transaction is a cash transaction, and the integrated card is inserted from the left direction shown in FIG. In this case, since the IC chip contact 3 of the integrated card 1 is connected to the IC chip contact 16 on the apparatus side and the automatic transaction apparatus is compatible with the IC card, cash transactions are stored in the data stored in the IC chip. Will be done. That is, in this case, it is possible to access the cash card data stored in the IC chip, and the reinsertion operation of the integrated card 1 is not necessary.

  Pattern 2. A case will be described in which the specification of the automatic transaction apparatus is compatible with an IC card, the customer's desired transaction is a cash transaction, and the integrated card is inserted from the right direction shown in FIG. In this case, since the automatic transaction apparatus is compatible with the IC card, the cash transaction is performed based on the data stored in the IC chip. However, the IC chip contact 3 of the integrated card 1 is connected to the apparatus side. Since it is not connected to the IC chip contact 16, access to the cash card data stored in the IC chip is impossible, and re-insertion operation of the integrated card 1 is required.

  Pattern 3. A case will be described in which the specification of the automatic transaction apparatus is compatible with the IC card, the customer's desired transaction is a credit transaction, and the integrated card is inserted from the left direction shown in FIG. In this case, since the automatic transaction apparatus is compatible with the IC card, the credit transaction is performed by data stored in the IC chip. Further, since the IC chip contact 3 of the integrated card 1 is connected to the IC chip contact 16 on the apparatus side, it becomes possible to access the credit card data stored in the IC chip, and the reinsertion operation of the integrated card 1 is unnecessary. It becomes.

  Pattern 4. A case will be described in which the specification of the automatic transaction apparatus is compatible with the IC card, the customer's desired transaction is a credit transaction, and the integrated card is inserted from the right direction shown in FIG. In this case, since the automatic transaction apparatus is compatible with the IC card, the credit transaction is to be performed by the data stored in the IC chip, but the IC chip contact 3 of the integrated card 1 is on the apparatus side. Since it is not connected to the IC chip contact 16, it becomes impossible to access the credit card data stored in the IC chip, and it is necessary to reinsert the integrated card 1.

  Pattern 5. A case will be described in which the specification of the automatic transaction apparatus is not compatible with the IC card, the customer's desired transaction is a cash transaction, and the integrated card is inserted from the left direction shown in FIG. In this case, since the automatic transaction apparatus is not compatible with the IC card, the cash transaction is performed by the data of the magnetic stripe 4. In this case, since the magnetic stripe 4 of the cash card data cannot be read by the magnetic head 17, a reinsertion operation of the integrated card 1 is required.

  Pattern 6. The case where the specification of the automatic transaction apparatus is not compatible with the IC card, the customer's desired transaction is a cash transaction, and the integrated card is inserted from the right direction shown in FIG. 23 will be described. In this case, since the automatic transaction apparatus is not compatible with the IC card, the cash transaction is performed by the data of the magnetic stripe 4. In this case, since the magnetic stripe 4 of the cash card data can be read by the magnetic head 17, the reinsertion operation of the integrated card 1 becomes unnecessary.

  Pattern 7. A case will be described in which the specification of the automatic transaction apparatus is not compatible with an IC card, the customer's desired transaction is a credit transaction, and the integrated card is inserted from the left direction shown in FIG. In this case, since the automatic transaction apparatus is not compatible with the IC card, the credit transaction is performed by the credit card data of the magnetic stripe 2. In this case, since the magnetic stripe 17 of credit card data cannot be read by the magnetic head 17, the reinsertion operation of the integrated card 1 is not necessary.

  Pattern 8. A case will be described in which the specification of the automatic transaction apparatus is not compatible with the IC card, the customer's desired transaction is a credit transaction, and the integrated card is inserted from the right direction shown in FIG. In this case, since the automatic transaction apparatus is not compatible with the IC card, the credit transaction is performed by the credit card data of the magnetic stripe 2. In this case, since the magnetic stripe 17 of credit card data cannot be read by the magnetic head 17, a reinsertion operation of the integrated card 1 is required. The above patterns are summarized in Table 1.

他方、キャッシュ取引用の磁気ストライプとクレジット取引用の磁気ストライプの２本の磁気ストライプを備えた所謂ダブルストライプカードが開発されている。こうしたダブルストライプカードにおいても、取引によって挿入方向が決まっており、挿入方向を間違えた場合には再挿入をしなければならない。（特開平６−２５９６４０号公報参照）
特開平６−２５９６４０号公報

On the other hand, a so-called double stripe card having two magnetic stripes, ie, a magnetic stripe for cash transactions and a magnetic stripe for credit transactions, has been developed. Even in such a double stripe card, the insertion direction is determined by the transaction, and if the insertion direction is wrong, it must be reinserted. (See JP-A-6-259640)
JP-A-6-259640

However, in the transaction using the conventional automatic transaction apparatus, the insertion direction of the card 1 differs between the automatic transaction apparatus compatible with the IC card and the automatic transaction apparatus not compatible with the IC card even when performing the same cash transaction (the pattern 1 and the automatic transaction apparatus). Pattern 5 and patterns 2 and 6). Since there is a wide range of support for IC cards compatible with automatic transaction devices for each financial institution, customers who own integrated cards check whether each financial institution's automatic transaction device is compatible with IC cards. In addition, the insertion direction of the integrated card must be determined. This puts an unnecessary burden on the customer.
Further, even in a transaction using a double stripe card, if the insertion direction is wrong, re-insertion must be performed, which is still troublesome for a customer who uses the automatic transaction apparatus.

  In order to solve the above-mentioned problems, the present invention provides an automatic transaction apparatus that reads a magnetic information of a card and performs a transaction, and reads the direction conversion means for changing the direction of the card inserted into the apparatus and the card inserted into the apparatus. And a control means for driving the direction changing means based on the magnetic information to change the direction of the card.

  The card has a plurality of magnetic information recording units, and magnetic information can be read from any magnetic information recording unit regardless of which card is inserted into the device. However, it is determined whether or not the direction changing means is to be driven based on the read magnetic information.

  According to the present invention, regardless of the direction in which the card is inserted, it is determined whether or not it is necessary to change the direction of the card based on the information read from the card. Since the direction is changed by 180 degrees, even if the customer makes a mistake in the card insertion direction, desired processing can be performed without re-insertion.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Elements common to the drawings are denoted by the same reference numerals. 1 is a schematic side view showing a card reader / writer of an automatic transaction apparatus according to a first embodiment of the present invention, FIG. 2 is a schematic plan view showing the card reader / writer, and FIG. 3 is a schematic front view showing the card reader / writer. FIG.

  In these drawings, a card reader / writer 21 provided in the automatic transaction apparatus is formed with a conveyance path 22 for conveying a card, and a plurality of conveyance roller pairs 23, 24, 25 are provided across the conveyance path 22. ing. The conveyance roller pair 23 includes an upper conveyance roller 23a and a lower conveyance roller 23b. The upper conveyance roller 23a is supplied with driving force from a conveyance motor described later, and the lower conveyance roller 23b is connected to the upper conveyance roller 23a via a card. It is driven and rotated by pressure contact. The transport roller pair 23 draws the card inserted by the customer through the insertion slot 26 into the card reader / writer 21 and transports it to the IC card contact 27 or the next transport roller pair 24.

  The conveyance roller pair 24 includes an upper conveyance roller 24a and a lower conveyance roller 24b. The upper conveyance roller 24a is supplied with a driving force from a conveyance motor described later, and the lower conveyance roller 24b is connected to the upper conveyance roller 24a via a card. It is driven and rotated by pressure contact. The transport roller pair 24 transports the card transported from the transport roller pair 23 to the magnetic head 28 or the next transport roller pair 25.

  The conveyance roller pair 25 includes an upper conveyance roller 25a and a lower conveyance roller 25b. The upper conveyance roller 25a is supplied with driving force from a conveyance motor described later, and the lower conveyance roller 25b is connected to the upper conveyance roller 25a via a card. It is driven and rotated by pressure contact. The transport roller pair 25 transports the card transported from the transport roller pair 24 to the next transport roller pair 29.

  The IC card contact 27 is a contact for performing data read or data write in the IC chip of the double magnetic stripe card with IC chip. The magnetic head 28 reads or writes a magnetic stripe specified by JISX6302.

  A turntable 30 is provided on the back side of the conveying roller pair 25 (the side opposite to the insertion port 26). The turntable 30 is for rotating the conveyed card by 180 degrees, and a gear 32 is attached to the lower center of the turntable 30 via a shaft 31. The turntable 30 has a transport path 33 formed in the upper part thereof, and a lower transport roller 29b of the transport roller pair 29 is rotatably provided. The lower conveyance roller 29b conveys the card together with the upper conveyance roller 29a provided in the upper unit 34.

  A light shielding plate 35 is provided at the bottom of the turntable 30. The light shielding plate 35 is for detecting the position of the turntable 30 by blocking light from the light emitting elements of the turntable sensors 36 and 37 including the light emitting element and the light receiving element. The turntable sensors 36 and 37 are provided symmetrically with respect to the shaft 31, and both use light emitting diodes as light emitting elements and phototransistors as light receiving elements.

  A gear 32 provided on the shaft 31 meshes with a gear 39 attached to the turntable motor 38. As the turntable motor 38 rotates, the turntable 30 rotates via the gear 39 and the gear 32.

  A double magnetic stripe card with IC chip (hereinafter sometimes simply referred to as a card) 1 has a configuration similar to that shown in FIG. That is, the card 1 is provided with a credit card magnetic stripe 2 and an IC chip contact 3 on the upper surface, and a cash card magnetic stripe 4 on the lower surface. The built-in IC chip stores data for cash cards and credit cards. When inserted into an IC card compatible automatic transaction device, cash transactions can be made without using magnetic stripes 2 and 3 And credit transactions are possible.

  FIG. 4 is a block diagram showing a card reader / writer of the automatic transaction apparatus according to the first embodiment. In FIG. 4, a control unit 41 controls the operation of the card reader / writer 21 and is connected to a main control unit 42 of the automatic transaction apparatus and is connected to each unit described below. The reading circuit 43 is a circuit that reads data in the IC chip from the card 1 and transmits it to the control unit 41, and is connected to the control unit 41 and the IC chip contact 27.

  The write circuit 44 is a circuit for writing data received from the control unit 41 to the IC chip of the card 1 and is connected to the control unit 41 and the IC chip contact 27. The reading circuit 45 is a circuit for reading the data of the magnetic stripe 2 or 4 of the card 1 and transmitting it to the control unit 41, and is connected to the control unit 41 and the magnetic head 28. The write circuit 46 is a circuit for writing data received from the control unit 41 to the magnetic stripe 2 or 4 of the card 1, and is connected to the control unit 41 and the magnetic head 28.

  The sensor circuit 47 is a circuit for driving a card detection sensor 48 for detecting the position of the card 1 inserted into the card reader / writer 21 and receiving an output signal from the card detection sensor 48. And a card detection sensor 48. Note that a plurality of card detection sensors 48 are not provided, but a plurality of card detection sensors 48 are provided at necessary portions of the conveyance path 22. The card detection sensor 48 is a reflection type optical sensor in which a light emitting diode and a light receiving transistor are integrally formed. The drive circuit 49 is a circuit that drives the transport motor 50. The transport motor 50 drives the transport roller pair 23, 24, 25 in the card reader / writer 21 described above.

  The sensor circuit 51 drives the rotary table sensors 36 and 37 provided at the lower part of the rotary table 30 and detects the position of the card 1 conveyed to the conveyance path 33 at the upper part of the rotary table 30. The output signal from these sensors 36, 37, 52 is received by the circuit that drives. The card detection sensor 52 is a reflection type optical sensor in which a light emitting diode and a light receiving transistor are integrally formed. The drive circuit 53 is a motor for driving the turntable motor 38.

  The sensor circuit 51, the drive circuit 53, and each part connected to them constitute a rotation mechanism 54. The direction change operation of the card 1 centering on the operation of the turntable 30 is performed by the rotation mechanism unit 54.

  Next, the operation of the first embodiment will be described. Before that, the configuration of the magnetic data of the magnetic stripes 2 and 4 of the card 1 will be described. FIG. 5 is an explanatory diagram showing the data configuration of the magnetic stripe of the credit card, and FIG. 6 is an explanatory diagram showing the data configuration of the magnetic stripe of the cash card.

  In FIG. 5, the data specification of the magnetic stripe 2 of the credit card includes a start code 2a, credit card information 2b, IC contact information 2c, end code 2d, and the like. The IC contact information 2c includes IC contact presence / absence information 2ca and IC contact position information 2cb.

  The IC contact presence / absence information 2ca is information indicating that the card has an IC contact or a card without an IC contact. When this data is “0”, it indicates that the card has no IC contact. When the data is “1”, it indicates that the card has an IC contact. Since the card 1 in the present embodiment is a card having an IC contact, the IC contact presence / absence information 2ca is “1”.

  The IC contact position information 2cb is information indicating whether or not the IC contact can be accessed without rotating the inserted card by 180 degrees. If this data is "0", the card need not be rotated by 180 degrees. It indicates that the IC contact can be accessed. If the data is "1", it indicates that the IC contact cannot be accessed unless the card is rotated 180 degrees. When the magnetic stripe 2 of the credit card is read, the IC contact can be accessed without rotating the card by 180 degrees, so the IC contact position information 2cb is “0”.

  In FIG. 6, the data specifications of the magnetic stripe 4 of the cash card are composed of a start code 2a, cash card information 4b, IC contact information 4c, end code 4d, and the like. The IC contact information 4c includes IC contact presence / absence information 4ca and IC contact position information 4cb.

  The IC contact presence / absence information 4ca is information indicating that the card has an IC contact or a card without an IC contact. When this data is “0”, it indicates that the card has no IC contact. When the data is “1”, it indicates that the card has an IC contact. Since the card 1 in this embodiment is an IC contact card, the IC contact presence / absence information 4ca is “1”.

  The IC contact position information 4cb is information indicating whether or not the IC contact can be accessed without rotating the inserted card by 180 degrees. If this data is "0", the card does not have to be rotated by 180 degrees. It indicates that the IC contact can be accessed. If the data is "1", it indicates that the IC contact cannot be accessed unless the card is rotated 180 degrees. When the magnetic stripe 4 of the cash card is read, the IC contact position information 4cb is "1" because the IC contact cannot be accessed unless the card is rotated 180 degrees.

  Next, the operation of the card 1 when the card 1 is inserted and a transaction is performed will be further described with reference to the drawings. Here, when a customer who owns a double magnetic stripe card 1 with an IC chip conducts a cash transaction with an automatic transaction apparatus compatible with the IC card, the double magnetic stripe card 1 with an IC chip is inserted from the left as shown in FIG. The operation in the case of having been performed will be described. 7 to 10 are operation explanatory views showing the operation of the card in this case.

  As shown in FIG. 7, when the customer inserts the double magnetic stripe card 1 with an IC chip from the insertion slot 26, the card 1 is detected by the card detection sensor 48, and a detection signal is sent to the control unit 41. The control unit 41 that has received the detection signal drives the transport motor 50 via the drive circuit 49 so that the card 1 is transported toward the turntable 30. When the conveyance motor 50 is driven, power is transmitted to the conveyance roller pairs 23, 24, and 25 connected by a belt (not shown), and the card 1 starts to be conveyed in the direction of the turntable 30.

  When the entire card 1 is pulled into the apparatus, the card detection sensor 48 notifies the control unit 41 via the sensor circuit 47 of a signal indicating that the entire card has been pulled. Upon receiving this notification, the control unit 41 transmits a drive stop instruction to the drive circuit 49 to stop the transport motor 50. At the same time, the control unit 41 notifies the main control unit 42 of the automatic transaction apparatus that the suction operation of the card 1 has been completed. (State shown in FIG. 7)

  Receiving the notification that the inhaling operation of the card 1 has been completed, the main control unit 42 instructs the control unit 41 to perform a magnetic read operation. Upon receiving the instruction for the magnetic read operation, the control unit 41 drives the transport motor 50 via the drive circuit 49 so that the card 1 is transported in the direction of the turntable 30. When the conveyance motor 50 is driven, power is transmitted to the conveyance roller pairs 23, 24, and 25 connected by a belt (not shown), and the card 1 starts to be conveyed again in the direction of the turntable 30.

  Next, the control unit 41 reads magnetic data from the magnetic stripe 2 of the card 1 by the magnetic head 28 via the reading circuit 45. When the entire card 1 passes through the magnetic head 28, a signal indicating that the card 1 has passed through the magnetic head 28 is sent to the control unit 41 via the sensor circuit 47. When the entire card 1 receives a signal passing through the magnetic head 28, the control unit 41 transmits a drive stop instruction to the drive circuit 49, stops the transport motor 50, and stops reading of magnetic data. (The state of the left card 1 shown in FIG. 8)

  Next, the control unit 41 transmits the read magnetic data to the main control unit 42. The specification of the magnetic stripe 2 of the credit card is as described in FIG. The read magnetic data includes IC contact presence / absence information 2ca and IC contact position information 2cb as IC contact information 2c. In the magnetic data read from the magnetic stripe 2, the IC contact position information 2cb is "0". It has become. Based on this information, the main control unit 42 determines that there is no need to rotate the card 1 and instructs the control unit 41 to perform an IC lead preparation operation.

  Upon receiving the instruction for the IC lead preparation operation, the control unit 41 drives the transport motor 50 via the drive circuit 49 so that the card 1 is transported in the direction of the IC card contact 27. When the transport motor 50 is driven, power is transmitted to the transport roller pair 23, 24, 25 connected by a belt (not shown), and the card 1 starts to be transported in the direction of the IC card contact 27. As shown in FIG. 8, when the IC contact part 3 of the card 1 reaches the IC card contact 27, the card detection sensor 48 detects the arrival and notifies the control part 41 via the sensor circuit 47.

  The control unit 41 that is notified that the IC contact unit 3 of the card 1 has reached the IC card contact 27 transmits a drive stop instruction to the drive circuit 49 and stops the transport motor 50. At the same time, the control unit 41 notifies the main control unit 42 that the IC lead preparation operation has been completed.

  Receiving the completion notification of the IC read preparation operation, the main control unit 42 instructs the control unit 41 to perform the IC read operation. Upon receiving the instruction for the IC read operation, the control unit 41 reads the data in the IC chip via the reading circuit 43 and transmits the read data to the main control unit 42. The main control unit 42 that has received the read data from the IC chip instructs the control unit 41 to perform a card return preparation operation.

  Upon receiving the card return preparation operation instruction, the control unit 41 drives the transport motor 50 via the drive circuit 49 so that the card 1 is transported in the direction of the insertion slot 26. When the conveyance motor 50 is driven, power is transmitted to a pair of conveyance rollers 23, 24, and 25 connected by a belt (not shown), and the card 1 is conveyed in the direction of the insertion slot 26 as shown in FIG. start.

  As shown in FIG. 9, when the card 1 is conveyed to a position immediately before being ejected from the insertion slot 26, the position is detected by the card detection sensor 48 and notified to the control unit 41 via the sensor circuit 47. . The control unit 41 that is notified that the card 1 has been transported to just before the insertion slot 26 transmits a drive stop instruction to the drive circuit 49 to stop the transport motor 50. At the same time, the control unit 41 notifies the main control unit 42 that the card return preparation operation has been completed.

  Next, the main control unit 42 executes a transaction selected by the customer based on the data read from the IC chip of the card 1, that is, a transaction such as a payment transaction or a deposit transaction. Since this transaction operation is not directly related to the present invention, a description thereof will be omitted. When the transaction here is completed, the main control unit 41 instructs the control unit 41 to perform a card return operation.

  Upon receiving the card return operation instruction, the control unit 41 drives the transport motor 50 via the drive circuit 49 so that the card 1 is further transported in the direction of the insertion slot 26. When the transport motor 50 is driven, power is transmitted to the transport roller pairs 23, 24, and 25 connected by a belt (not shown), and the card 1 starts to be transported further toward the insertion slot 26. When the card 1 is transported to a position where the customer can remove the card 1, the card detection sensor 48 detects the position and notifies the control unit 41 via the sensor circuit 47. The control unit 41 that has been notified that the card 1 has been transported to a position where it can be removed transmits a drive stop instruction to the drive circuit 49 to stop the transport motor 50 and waits for the customer to remove the card 1.

  As shown in FIG. 10, when the card 1 is extracted by the customer, it is detected by the card detection sensor 48 and notified to the control unit 41. The control unit 41 that is notified that the card 1 has been removed notifies the main control unit 42 that the card return operation has been completed. The transaction operation in the case where the card 1 is inserted from the left direction shown in FIG.

  Next, a customer who owns a double magnetic stripe card 1 with an IC chip inserts the double magnetic stripe card 1 with an IC chip from the right direction shown in the figure in the case of performing a cash transaction with an automatic transaction apparatus compatible with the IC card. The operation in this case will be described. FIGS. 11 to 17 are operation explanatory views showing the operation of the card in this case.

  In FIG. 11, when the customer inserts the double magnetic stripe card 1 with IC chip from the right side shown in FIG. 23, the card 1 is detected by the card detection sensor 48 and a detection signal is sent to the control unit 41. The control unit 41 that has received the detection signal drives the transport motor 50 via the drive circuit 49 so that the card 1 is transported toward the turntable 30. When the conveyance motor 50 is driven, power is transmitted to the conveyance roller pairs 23, 24, and 25 connected by a belt (not shown), and the card 1 starts to be conveyed in the direction of the turntable 30. At this time, the light shielding plate 35 provided below the turntable 30 is positioned between the light emitting element and the light receiving element of the turntable sensor 36.

  When the entire card 1 is pulled into the apparatus, the card detection sensor 48 notifies the control unit 41 via the sensor circuit 47 of a signal indicating that the entire card has been pulled. Upon receiving this notification, the control unit 41 transmits a drive stop instruction to the drive circuit 49 to stop the transport motor 50. At the same time, the control unit 41 notifies the main control unit 42 of the automatic transaction apparatus that the suction operation of the card 1 has been completed.

  Receiving the notification that the inhaling operation of the card 1 has been completed, the main control unit 42 instructs the control unit 41 to perform a magnetic read operation. Upon receiving the instruction for the magnetic read operation, the control unit 41 drives the transport motor 50 via the drive circuit 49 so that the card 1 is transported in the direction of the turntable 30. When the conveyance motor 50 is driven, power is transmitted to the conveyance roller pairs 23, 24, and 25 connected by a belt (not shown), and the card 1 starts to be conveyed again in the direction of the turntable 30.

  Next, the control unit 41 reads magnetic data from the magnetic stripe 4 of the cash card of the card 1 by the magnetic head 28 via the reading circuit 45. When the entire card 1 passes through the magnetic head 28, a signal indicating that the card 1 has passed through the magnetic head 28 is sent to the control unit 41 via the sensor circuit 47. When the entire card 1 receives a signal passing through the magnetic head 28, the control unit 41 transmits a drive stop instruction to the drive circuit 49, stops the transport motor 50, and stops reading of magnetic data. (State of the card 1 on the right side shown in FIG. 12)

  Next, the control unit 41 transmits the read magnetic data to the main control unit 42. The specifications of the magnetic stripe 4 of the cash card are as described in FIG. The read magnetic data includes IC contact presence / absence information 4ca and IC contact position information 4cb as IC contact information 4c. In the magnetic data read from the magnetic stripe 4, the IC contact position information 4cb is "1". It has become. Based on this information, the main control unit 42 determines that the card 1 needs to be rotated, and instructs the control unit 41 to rotate the card 1.

  The control unit 41 that has received an instruction to rotate the card 1 drives the transport motor 50 through the drive circuit 49 so that the card 1 is transported in the direction of the turntable 30. By driving the transport motor 50, power is transmitted to the transport roller pairs 23, 24, 25, and 29 connected by a belt (not shown), and the card 1 starts to be transported toward the turntable 30. As shown in FIG. 12, when the card 1 arrives on the turntable 30, the card detection sensor 52 detects the arrival and notifies the control unit 41 via the sensor circuit 51. The control unit 41 that is notified that the card 1 has reached the turntable 30 transmits a drive stop instruction to the drive circuit 49, stops the transport motor 50, and stops the transport of the card 1.

  Next, the control unit 41 drives the rotation drive motor 38 via the drive circuit 53. When the rotation drive motor 38 is driven, the turntable 30 rotates via the gear 39, the gear 32, and the shaft 31. This is shown in FIG. Due to the rotation of the turntable 30, the light shielding plate 35 provided at the lower part of the turntable 30 comes out of the turntable sensor 36. As shown in FIG. 14, when the turntable 30 rotates 180 degrees, the light shielding plate 35 reaches the turntable sensor 37 on the opposite side and blocks light from the light emitting element of the turntable sensor 37. As a result, a rotation of 180 degrees of the turntable 30 is detected, and a detection signal is transmitted from the turntable sensor 7 to the control unit 41.

  Receiving the notification that the turntable 30 has rotated 180 degrees, the control unit 41 transmits a drive stop instruction to the drive circuit 53 to stop the rotation drive motor 38 and stop the turntable 30 from rotating. At the same time, the control unit 41 notifies the main control unit 42 that the card rotation operation has been completed.

  The main control unit 42 that has received the notification of the completion of the rotation operation of the card 1 instructs the control unit 41 to perform an IC lead preparation operation. Upon receiving the instruction for the IC lead preparation operation, the control unit 41 drives the transport motor 50 via the drive circuit 49 so that the card 1 is transported in the direction of the IC card contact 27. When the transport motor 50 is driven, power is transmitted to the transport roller pairs 23, 24, 25, and 29 connected by a belt (not shown), and the card 1 starts to be transported in the direction of the IC card contact 27. As shown in FIG. 15, when the IC contact portion 3 of the card 1 reaches the IC card contact 27, the position is detected by the card detection sensor 48 and notified to the control portion 41 via the sensor circuit 47.

  Upon detecting that the IC contact portion 3 of the card 1 has reached the IC card contact 27, the control portion 41 transmits a drive stop instruction to the drive circuit 49, stops the transport motor 50, and stops the transport of the card 1. Let At the same time, the main control unit 42 is notified that the IC lead preparation operation has been completed.

  Receiving the completion notification of the IC read preparation operation, the main control unit 42 instructs the control unit 41 to perform the IC read operation. Upon receiving the instruction for the IC read operation, the control unit 41 reads the data in the IC chip via the reading circuit 43 and transmits the read data to the main control unit 42. The main control unit 42 that has received the read data from the IC chip instructs the control unit 41 to perform a card return preparation operation.

  Upon receiving the card return preparation operation instruction, the control unit 41 drives the transport motor 50 via the drive circuit 49 so that the card 1 is transported in the direction of the insertion slot 26. When the transport motor 50 is driven, power is transmitted to the transport roller pairs 23, 24, and 25 connected by a belt (not shown), and the card 1 starts to be transported toward the insertion slot 26.

  As shown in FIG. 16, when the card 1 is conveyed to a position immediately before being ejected from the insertion slot 26, the position is detected by the card detection sensor 48 and notified to the control unit 41 via the sensor circuit 47. . The control unit 41 that is notified that the card 1 has been transported to just before the insertion slot 26 transmits a drive stop instruction to the drive circuit 49 to stop the transport motor 50. At the same time, the control unit 41 notifies the main control unit 42 that the card return preparation operation has been completed.

  Next, the main control unit 42 executes a transaction selected by the customer based on the data read from the IC chip of the card 1, that is, a transaction such as a payment transaction or a deposit transaction. Since this transaction operation is not directly related to the present invention, a description thereof will be omitted. When the transaction here is completed, the main control unit 41 instructs the control unit 41 to perform a card return operation.

  Upon receiving the card return operation instruction, the control unit 41 drives the transport motor 50 via the drive circuit 49 so that the card 1 is transported in the direction of the insertion slot 26. When the transport motor 50 is driven, power is transmitted to the transport roller pairs 23, 24, and 25 connected by a belt (not shown), and the card 1 starts to be transported further toward the insertion slot 26. As shown in FIG. 17, when the card 1 is transported to a position where the customer can remove the card 1, the position is detected by the card detection sensor 48 and notified to the control unit 41 via the sensor circuit 47. The control unit 41 that has been notified that the card 1 has been transported to a position where it can be removed transmits a drive stop instruction to the drive circuit 49 to stop the transport motor 50 and waits for the customer to remove the card 1.

  When the card 1 is pulled out by the customer, it is detected by the card detection sensor 48 and notified to the control unit 41. The control unit 41 that is notified that the card 1 has been removed notifies the main control unit 42 that the card return operation has been completed. The transaction operation in the case where the card 1 is inserted from the right direction shown in FIG.

  In both cases described above, cash transactions have been explained. However, in the case of credit transactions, detailed explanation is not particularly given. However, in the case of insertion in the left direction shown in FIG. In the case of rightward insertion shown in FIG. 23, the card 1 is rotated 180 degrees to perform the transaction.

  As described above, according to the first embodiment, since the turntable for changing the orientation of the inserted card is provided, even if the customer makes a mistake in the insertion direction, the desired card is not returned to the customer once. It becomes possible to conduct transactions.

  Next, a second embodiment of the present invention will be described. FIG. 18 is a block diagram of a card reader / writer according to the second embodiment. In the second embodiment, in addition to the configuration of the first embodiment, guidance means is provided to provide guidance to the customer when the card insertion direction is wrong.

  In FIG. 18, a guidance control unit 55 and a display unit 56 are connected to the control unit 41 in addition to the elements described in the first embodiment. The guidance control unit 55 provides guidance to the customer about the correct insertion direction when the customer inserts the card in the wrong direction. The display unit 565 is provided in the automatic transaction apparatus and is in a position where it can be seen by the customer during operation. Other configurations are the same as those of the first embodiment.

  Next, the operation of the second embodiment will be described. Here, the guidance operation will be described. FIG. 19 is a flowchart showing the guidance operation of the second embodiment. In the description, the figure used in the first embodiment will be used.

  First, the customer selects a transaction item with an operation unit (not shown) of the automatic transaction apparatus. At that time, as shown in FIG. 20, the display unit 56 performs a display for allowing the customer to select whether the transaction using the IC card is desired or the transaction not using the IC card is desired (step 1). ).

  When the customer selects a transaction using an IC card (step 2), that is, when the “IC card” button 57 is pressed, the information is sent to the control unit 41. Thereafter, when the customer inserts the card from the insertion slot 26, the card is sucked into the card reader / writer and the magnetic data of the magnetic stripe of the card is read by the magnetic head 28 as described in the first embodiment. Note that if the customer selects a transaction that does not use an IC card in step 2, that is, if the “other than IC card” button 58 is pressed, the guidance operation is not performed, and thus the subsequent description is omitted.

  Here, it is assumed that the card inserted by the customer is a double stripe card compatible with an IC card or a double stripe card not compatible with an IC card. In any case, it is assumed that the magnetic stripe for the credit card of the card and the magnetic stripe for the cash card include the aforementioned IC contact presence / absence information and IC contact position information.

  The read magnetic data is sent to the control unit 41, and the IC contact presence / absence information and the IC contact position information in the magnetic data are sent from the control unit 41 to the guidance control unit 54 (step 3). The guidance control unit 55 determines whether or not the IC contact presence / absence information is “1” from the transmitted magnetic data (step 4). That is, it is determined whether the inserted card has an IC contact.

  Since the customer has selected the transaction using the IC card in Step 2, if it is determined that the IC contact presence / absence information is not “1”, the guidance control unit 55 cannot handle the guidance shown in FIG. The information is displayed on the display unit 56 (step 5). When it is determined that the IC contact presence / absence information is “1”, the guidance control unit 55 next determines from the magnetic data whether the IC contact position information is “1” (step 6).

  When it is determined that the IC contact position information is “1”, the guidance control unit 55 displays the guidance shown in FIG. 22 on the display unit 56 (step 7). The guidance shown in FIG. 22 requests that the card be inserted in the correct direction at the next transaction. By providing guidance in this way, it can be expected that the card will be inserted from the correct direction from the next transaction, and the transaction time can be shortened.

  When it is determined that the IC contact position information is “1”, the direction of the card is changed by the turntable 30 as described in the first embodiment, and the transaction using the IC chip is performed. If it is determined that the IC contact position information is “0”, since the card is correctly inserted, transaction processing is performed without displaying a guidance.

  As described above, in the second embodiment, when the customer inserts a card that cannot be used for the transaction he / she desires, since the guidance that the card should be exchanged is given, there is a reason why the customer cannot perform the transaction. You can see immediately and respond immediately. Also, even if the correct card is inserted, if the insertion direction is different, the transaction is executed at that time, and guidance indicating the correct insertion direction of the card is displayed, so that the customer inserts the correct card from the next transaction. It is expected that the card is inserted in the direction, and in that case, the rotation operation of the card becomes unnecessary, so that the transaction time can be expected to be shortened.

  In the above embodiments, transactions using an IC chip have been described. However, the present invention can also be applied to a case where a card owned by a customer is a double stripe card having no IC contact. In this case, information indicating that the transaction is a credit transaction is provided in the magnetic stripe 2 of the credit card, and information indicating that the transaction is a cash transaction is provided in the magnetic stripe 4 of the cash card.

  In a cash transaction, when a double stripe card is inserted such that the magnetic stripe 4 of the cash card is located on the side where the magnetic head 28 is located, information indicating that the transaction is a cash transaction is included in the magnetic data read by the magnetic head 28. Because there is, it does not rotate and trades as it is. In addition, when a double stripe card is inserted such that the magnetic stripe 2 of the credit card is positioned on the side where the magnetic head 28 is located, the magnetic data read by the magnetic head 28 has information indicating that it is a credit transaction. Rotate the card 180 degrees to make a cash transaction.

  In addition, in a credit transaction, when a double stripe card is inserted such that the magnetic stripe 4 of the cash card is located on the side where the magnetic head 28 is located, information indicating that the transaction is a cash transaction is included in the magnetic data read by the magnetic head 28. Since there is, the card is rotated and credit transactions are performed. In addition, when a double stripe card is inserted such that the magnetic stripe 2 of the credit card is positioned on the side where the magnetic head 28 is located, the magnetic data read by the magnetic head 28 has information indicating that it is a credit transaction. Perform credit transactions without rotating the card.

  In each of the above embodiments, an example is shown in which the present invention is applied to an automatic transaction apparatus, but the present invention is also applicable to a general-purpose card reader / writer.

1 is a schematic side view showing a card reader / writer of an automatic transaction apparatus according to a first embodiment. 1 is a schematic plan view showing a card reader / writer according to a first embodiment. 1 is a schematic front view showing a card reader / writer according to a first embodiment. It is a block diagram which shows the card reader / writer of the automatic transaction apparatus in 1st Embodiment. It is explanatory drawing which shows the data structure of the magnetic stripe of a credit card. It is explanatory drawing which shows the data structure of the magnetic stripe of a cash card. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of left direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of left direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of left direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of left direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of right direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of right direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of right direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of right direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of right direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of right direction insertion. It is operation | movement explanatory drawing which shows operation | movement of the card | curd in the case of right direction insertion. It is a block diagram of the card reader / writer of 2nd Embodiment. It is a flowchart which shows the guidance operation | movement of 2nd Embodiment. It is explanatory drawing which shows the display part which displays a selection item. It is explanatory drawing which shows a guidance display. It is explanatory drawing which shows a guidance display. It is explanatory drawing which shows a general integrated card. It is a schematic block diagram which shows the card reader / writer of an automatic transaction apparatus.

Explanation of symbols

1 Double magnetic stripe card with IC chip 2, 4 Magnetic stripe 3 IC chip contact 27 IC card contact 28 Magnetic head 30 Turntable 55 Guidance control unit

Claims (4)

In an automatic transaction device that reads the magnetic information of the card and performs transactions,
Orientation changing means for changing the orientation of the card inserted in the apparatus;
An automatic transaction apparatus comprising: control means for driving the direction changing means based on magnetic information read from a card inserted into the apparatus to change the direction of the card.   2. The automatic transaction apparatus according to claim 1, wherein the orientation changing means comprises a rotatable table on which a card can be placed and a driving means for rotating the table. The card has a plurality of magnetic information recording units, and magnetic information can be read from any one of the magnetic information recording units regardless of which card is inserted into the apparatus.
2. The automatic transaction apparatus according to claim 1, wherein the control means determines whether to drive the direction changing means based on magnetic information read regardless of which card is inserted into the apparatus.   4. The automatic transaction apparatus according to claim 1, further comprising guidance means for guiding a customer in a correct insertion direction when a card is erroneously inserted.

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