JP2000148923A - Ic card issuing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an IC card issuing system capable of reducing an issuing cycle time in which a non-contact type IC card is issued. SOLUTION: This IC card issuing system 300 has a card supplying device 20, a card carrying device 170 which carries a non-contact type IC card 10 discharged from the device 20, a data writer 40 which writes data in a semiconductor memory in the card 10 and a card stacker 60 which stores the card 10 discharged from the device 170. The device 170 lowers a card carrying speed when the card 10 is located in a data writable range from the writer 40, and the writer 40 writes data in the semiconductor memory in the card 10 located in the data writable range.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an IC card issuing system for issuing a non-contact IC card having a semiconductor memory in which data is written.

[0002]

2. Description of the Related Art FIG. 1 is an explanatory diagram showing an example of a conventional IC card issuing system. The IC card issuing system 100 includes a card supply device 20 for discharging the non-contact type IC card 10 and a card transport device 70 for transporting the non-contact type IC card 10 discharged from the card supply device 20.
And a data writing device 40 for writing data to a semiconductor memory in the non-contact type IC card 10, a card stacker 60, and a control device 80. Card stacker 60
Is a non-contact type IC having a semiconductor memory after data writing
The card 10 stores the non-contact type IC card 10 discharged from the card transport device 70. Data writing device 4
0 has an antenna 41 and an antenna control device 42 for controlling transmission and reception of the antenna 41. Control device 80
Is provided with a microcomputer. The card supply operation of the card supply device 20 and the data writing device 4
It controls the data writing operation of “0” and the card transfer operation of the card transfer device 70. The antenna control device 42 of the data writing device 40 is configured by a personal computer as an example, or the data writing device 40 is configured by a reader / writer device for a non-contact type IC card.

The IC card issuing system 100 repeats the following steps (1) to (4), and successively issues a non-contact IC card having a semiconductor memory in which predetermined data is written. (1) The card supply device 20 is a non-contact type IC card 1
0 is supplied to the card transport device 70. (2) The card carrier 70 is a non-contact type IC card 10
And stops the non-contact type IC card 10 immediately below the antenna 41. (3) The card writing device 40 transmits an electromagnetic wave from the antenna 41 to write data in the semiconductor memory in the non-contact type IC card 10. (4) The card transport device 70 transports the non-contact type IC card 10 after data writing and discharges it to the card stacker 60.

FIG. 2 is an explanatory diagram showing a card transport pattern in which the card transport device of the IC card issuing system of FIG. 1 transports a non-contact type IC card. Card supply device 20
The non-contact IC card 10 supplied from the card transporter 70 is transported by the card transporter 70 at a constant card transport speed Vm, decelerated at a constant acceleration from time T1, and at a time T2 the card transport belt of the card transporter 70. Stops to stop the non-contact IC card 10 immediately below the antenna 41. During the suspension period Tw from time T2 to time T3, the data writing device 40 uses the antenna 41 to write data to the IC chip in the non-contact IC card 10 by using the antenna 41. For example, the antenna 41 is configured by a coil, and a magnetic signal indicating data is transmitted from the coil to the non-contact type IC card 10. The non-contact type IC card 10 has a planar coil for converting the magnetic signal into an electric signal by electromagnetic induction, and the data from the planar coil is supplied to a data processing circuit in an IC chip. The circuit is configured to write and store the data in a semiconductor memory in the IC chip. The non-contact type IC card 10 accelerates at a constant acceleration from time T3 and reaches a constant card transport speed Vm at time T4, and the non-contact type IC card 10 is transported to the card stacker 60.
Is discharged.

[0005]

SUMMARY OF THE INVENTION Non-contact type IC card 1
The data writing time to the semiconductor memory within 0 may be from several hundred milliseconds to several tens of seconds, depending on the type of semiconductor memory and the contents of writing, and may vary greatly. When changing the write content, the data write time can be secured by changing the suspension period Tw of the non-contact IC card 10.

In the IC card issuing systems shown in FIGS. 1 and 2, data is written only when the card is stopped, and is not written while the card is being moved, so that the IC card issuing cycle time becomes longer. An object of the present invention is to provide an IC card issuing system capable of shortening an issue cycle time for issuing a non-contact type IC card.

[0007]

According to the present invention, there is provided an IC card issuing system comprising: a card transport device for transporting a non-contact IC card; and a data writing device for writing data to a semiconductor memory in the non-contact IC card. An IC card issuance system for issuing a non-contact type IC card having a semiconductor memory in which predetermined data is written, wherein the card transporting device is arranged so that data can be written from the data writing device to the data writing device. When the non-contact type IC card is located, the card transport speed is reduced, and the data writing device includes:
Data is written to the semiconductor memory in the non-contact type IC card located in the data writable range.

[0008] In the IC card issuing system according to the present invention, preferably, the card transport device is arranged such that when the non-contact type IC card is located in the data writable range,
The data writing device writes the data to the semiconductor memory in the non-contact type IC card whose card transfer speed is decreasing or increasing while decreasing the card transfer speed and then increasing the card transfer speed. In the IC card issuing system according to the present invention, more preferably, the data writing device writes data to a semiconductor memory in the non-contact type IC card that has stopped due to a reduced card transport speed.

In the IC card issuing system according to the present invention, the card transport device transports the non-contact type IC card and reduces the card transport speed when the non-contact type IC card is located in a data writable range. Let it. The data writing device is
Non-contact IC located in the data writable range
Since the data is written to the semiconductor memory in the card, the data can be written while the card is moving, and the issue cycle time can be reduced as compared with the case where the data is written only while the card is stopped.

[0010]

Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 3 is an explanatory diagram showing an example of an IC card issuing system according to the present invention.

The IC card issuing system 300 includes a card supply device 20 for discharging the non-contact type IC card 10.
A card transport device 170 that transports the non-contact type IC card 10 discharged from the card supply device 20,
A data writing device 40 for writing data to a semiconductor memory (not shown) in the non-contact IC card 10 is provided, and a non-contact IC card having a semiconductor memory in which predetermined data is written is issued. The card transport device 170 reduces the card transport speed V when the non-contact type IC card 10 is located in a range where data can be written from the data writing device 40, and the data writing device 40 The non-contact type IC card 10 located in a writable range
Write data to the semiconductor memory in the memory. The data writing device 40 has an antenna 41 and an antenna control device 42 that controls transmission and reception of the antenna 41.

Also, the IC card issuing system 300
It has a control device 180 and a card stacker 60. The card stacker 60 is a non-contact type IC card 10 having a semiconductor memory after data writing, and
The non-contact type IC card 10 discharged from 70 is stored. The control device 180 includes a microcomputer, and controls a card supply operation of the card supply device 20, a data writing operation of the data writing device 40, a card transportation operation of the card transportation device 170, and the like. The antenna control device 42 may be configured by a personal computer as an example, and the data writing device 40 and the control device 180 may be configured integrally with the personal computer. The data writing device 40 may be a reader / writer device for a non-contact type IC card.

The controller 180 outputs a card ejection signal S20 for instructing card ejection to the card supply device 20.
The card supply device 20 discharges one non-contact type IC card 10 to the card inlet 171 of the card transport device 170 based on the card discharge signal S20. Card carrier 17
No. 0 conveys the non-contact type IC card 10 using the motor 71 and the belt 74 moved by the rotation of the motor 71. A disk 71A is attached to the shaft of the motor 71, and a belt 79 is provided between the disk 71A and the pulley 72.
The belt 79 rotates with the rotation of the disk 71A and transmits the rotation of the disk 71A to the pulley 72. A belt 74 is stretched between the pulley 72 and the pulley 73, and the belt 74 moves with the rotation of the pulley 72, so that the belt 74 rotates. A belt 77 is stretched between the pulley 75 and the pulley 76,
The belt 77 moves at the same speed as the belt 74, and the belt 7
7 turns. The non-contact type IC card 10 discharged from the card supply device 20 is
1 and is conveyed in the direction of the card ejection port 172 while being sandwiched between the belts 74 and 77. Pulleys 75, 76
May be urged toward the pulleys 72 and 73 by elastic members such as springs.

A belt 74,
Detecting means 78A and 78B are provided for detecting the non-contact type IC card 10 conveyed by being sandwiched between the two. The detecting means 78A and 78B may be each configured using an optical sensor in which a light emitting element and a light receiving element are combined. The detection of the card position based on the motor speed described later may be used instead. The position of the non-contact type IC card 10 being conveyed can be detected by the detecting means 78A and 78B. Detecting means 78A,
The detection signals S78A and S78B from 78B are supplied to the control device 180. The detection means 78A is arranged near the entrance where the non-contact type IC card 10 enters a range where data can be written from the data writing device 40. Detecting means 7
8B is located near the exit where the non-contact type IC card 10 advances in a range in which data can be written from the data writing device 40. The range in which the data writing device 40 such as a reader / writer device can write data to the semiconductor memory in the non-contact type IC card 10 on the conveyance path is used for conveying the non-contact type IC card 10 at a low speed for communication. By performing the test, the measurement can be performed in advance, and the communicable range can be the data writable range. The control device 180 may detect the position of the non-contact type IC card 10 based on the rotation speed of the motor 71. For example, a rotary encoder provided with a slit is
1, the number of rotations of the motor 71 can be detected, and the position of the non-contact type IC card 10 can be detected.

Upon receiving the detection signal S78A from the detection means 78A, the control device 180 outputs a predetermined motor control signal S71 to the motor 71 to reduce the rotation speed of the motor 71. As a result, the card transport device 170 lowers the card transport speed V, and moves the non-contact IC card 10 to the antenna 41 after a predetermined time Ta from the input of the detection signal S78A.
Stop just below. The input time of the detection signal S78A may be time T11 described later, and the predetermined time Ta may be set to Ta = T12-T11 using the times T11 and T12 described later. Upon receiving the detection signal S78A, the control device 180 sends a predetermined control signal S42 to the antenna control device 42.
The antenna controller 42 supplies data S41 to the antenna 41 based on the control signal S42, transmits an electromagnetic wave from the antenna 41 to the non-contact IC card 10, and outputs the data to the semiconductor memory in the non-contact IC card 10. Write data to For example, the antenna 41 is configured by a coil, and a magnetic signal indicating data is transmitted from the coil to the non-contact type IC card 10. Further, the non-contact type IC card 10 has a plane coil for converting the magnetic signal into an electric signal by electromagnetic induction, and the data from the plane coil is used in a data processing circuit in an IC chip in the non-contact type IC card. The data processing circuit is configured to write and store the data in a semiconductor memory in the IC chip. The non-contact IC card 10
May have a power supply circuit to generate a power supply voltage from an output signal of the planar coil, and use the power supply voltage as a power supply voltage for driving the IC chip.

The control device 180 outputs a predetermined motor control signal S71 after a predetermined time Tb (Tb> Ta) from the input of the detection signal S78A to increase the rotation speed of the motor 71. Alternatively, when the detection signal S78B is input, the control device 180 outputs a predetermined motor control signal S71 to increase the rotation speed of the motor 71. As a result, the card transport device 170 increases the card transport speed V, and sets the card transport speed when the non-contact IC card 10 moves out of the data writable range to the data writable range. Make it equal to the card transport speed when entering. Detection signal S
The input time of 78B may be set to time T13 described later, and the predetermined time Tb is set to Tb using the times T11 and T13 described later.
= T13-T11. The card transport speed V at the time of entering and exiting the data writable range is the maximum moving speed V of the non-contact IC card 10 on the transport path.
m. The data writing device 40 writes data into the semiconductor memory in the non-contact type IC card 10 in which the card transport speed V is decreasing within the data writable range. Non-contact IC card 10
Write data to the semiconductor memory in the memory. The non-contact type IC card 10 that has advanced into the data writable range includes:
After being discharged from the card discharge port 172, the card stacker 60
Is stored in

The control device 180 is a non-contact type IC card 1
A card ejection signal S20 is output to the card supply device 20 at such a timing that the next non-contact type IC card 10 enters the data writable range after 0 has entered the data writable range. When the non-contact IC card 10 moves out of the data writable range, the following non-contact IC card 10 moves into the data writable range after a predetermined margin time. In this way, the IC card issuing system 300 can successively issue non-contact IC cards having a semiconductor memory in which data is written.

In the IC card issuing system 300, the card ejection interval of the card supply device 20 is controlled by the card ejection signal S20 from the control device 180. Also,
The rotation speed of the motor 71 is controlled by the motor control signal S71 from the control device 180,
Is controlled. The detecting means 78
A, 78B, the detection signals S78A, S78B
The position of the non-contact type IC card 10 can be detected. The IC card issuing system 300 includes a card supply device 20 capable of controlling the card ejection interval of the non-contact IC card 10, a card transport device 170 capable of controlling the card transport speed V, and a position of the non-contact IC card 10. It has a means for detecting, a data writing device 40 for writing data to the semiconductor memory in the non-contact type IC card 10, and a control device 180 for controlling the entire IC card issuing system 300. The position of the non-contact type IC card 10 is
A, 78B.
It is possible to detect based on one rotation speed.

Hereinafter, a method of determining the card transport pattern of the card transport device 170 will be described. First, a non-contact type IC card 10 is used to measure a data writable range.
Is conveyed at a low speed, and by sequentially communicating between the non-contact type IC card 10 and the data writing device 40 such as a reader / writer device, the length X of the communicable range can be measured. This communicable range is a data writable range. This range can be automatically calculated based on the timing at which the non-contact type IC card 10 passes through the detecting means 78A and 78B, the card transport speed V, and the response status of the antenna control device 42. Further, in consideration of the individual difference of the communication distance for each IC card, a communicable range may be set to be smaller than the calculated value with a certain margin.

Next, data is written to the semiconductor memory in the non-contact type IC card 10, and the data writing time T is measured. The length X (cm) of the communicable range, the data writing time T (s), and the upper limit value Vm (cm / cm
s) and the acceleration / deceleration limit value A (cm / s ² ) to determine the card transport pattern. The unit symbol s indicates seconds. Assuming that the acceleration time and the deceleration time are equal to t ₁ (s) and the constant speed time from the end of the deceleration time to the start of the acceleration time is t ₂ (s), the following equation is established.

[0021]

T = 2t ₁ + t ₂ ... X = (Vm−At ₁ ) t ₂ +2 (Vm−At ₁ ) t ₁ + At ₁ ² .

By eliminating t ₂ from the above equation, the following equation is obtained, and the solution of this quadratic equation is expressed by the following equation.

[0023]

[Number 2] ^{_{At 1 2 -ATt 1 + (VmT}} -X) = 0 ... t 1 = ^{[AT ± {(AT) 2 -4A} (VmT-X)} 1/2 ] / 2A ...

For t _{1 in the} above equation, a solution satisfying the following condition is adopted. The condition not to convey in the reverse direction is represented by the following expression, and the condition not to overrun the communicable range is represented by the following expression. If both solutions do not satisfy the following equation, the change of the data writing time T is considered.

[0025]

[Number 3] _{Vm-At 1 ≧ 0 ... At} 1 2/2 + (Vm-At 1) t 1 ≦ X ...

As for the interval at which the non-contact type IC card 10 is conveyed, a margin is determined in consideration of transmission / reception collision (collision). In the case of a non-contact type IC card having an anti-collision function (collision prevention function), the margin may be set to zero. Data write time T and margin distance L
Is the issue cycle time for issuing one non-contact IC card 10.

As an example, the setting may be made as follows. Data write time T = 1s. The length X of the communicable range is 10 cm. The maximum value Vm of the card transport speed V = 100 cm / s. Acceleration and deceleration limit values A = 1000 cm / s ² . Margin distance L = 20 cm. In this case, t ₁ = 0.9 s is obtained as the first solution, and t ₁ = 0.1 s is obtained as the second solution.

Here, since the first solution does not satisfy the condition of the above equation, when the card transport pattern is determined using the second solution, the card transport pattern as shown in FIG. 4 is obtained. IC card issuing system 300 is a non-contact IC
The issue cycle time for issuing one card is 1.2 s, and the card supply device 20 ejects the non-contact type IC card every 1.2 s.

FIG. 4 is an explanatory diagram illustrating an example of a card transport pattern when the card transport device transports a non-contact type IC card. At time T11, the non-contact IC
The card 10 enters the communicable range (communicable range), the card transport device 20 starts reducing the card transport speed V, and the card transport speed V decreases from the maximum speed Vm.
At time T12, the card transport belts 74 and 77 of the card transport device 170 stop, the card transport speed V becomes 0, and the non-contact IC card 10 stops. Time T
In 13, the card transport device 20 determines the card transport speed V
Starts, and the card transport speed V increases. Time T
At 14, the noncontact IC card 10 moves out of the communicable range, and the card transport device 20 sets the card transport speed V to the maximum speed Vm. At time T15, the subsequent non-contact IC card 10 enters the communicable range, the card transport device 20 starts reducing the card transport speed V, and the card transport speed V decreases from the maximum speed Vm. At time T16, the belts 74 and 77 of the card transport device 170 stop, the card transport speed V becomes 0, and the subsequent non-contact IC card 10 stops. At time T17, the card transport device 20 starts accelerating the card transport speed V and increases the card transport speed V. At time T18, the subsequent non-contact IC card 10 advances in the communicable range, and the card transport device 20 sets the card transport speed V to the maximum speed Vm.

The time from time T11 to time T12 is
0.1 s. The time from time T12 to time T13 is 0.8 s. The time from time T13 to time T14 is 0.1 s. The time from time T14 to time T15 is 0.2 s. From time T15 to time T1
The time to 6 is 0.1 s. The time from time T16 to time T17 is 0.8 s. The time from time T17 to time T18 is 0.1 s.

The position of the non-contact type IC card 10 from time T11 to time T14 is a communicable range, and its length X is 10 cm. A period from time T14 to time T15 is a margin time, which is a time during which the subsequent non-contact IC card 10 moves on the transport path to the entrance of the communicable range. The margin distance L is set to 20 cm. The position of the subsequent non-contact type IC card 10 from time T15 to time T18 is a communicable range, and its length X is 10 cm. Leading contactless IC card 10
The distance on the transport path from the to the subsequent non-contact type IC card 10 is about 30 cm.

On the other hand, in the card transport pattern of the conventional IC card issuing system in which data is written only to the non-contact type IC card 10 while the card is stopped, the issue cycle time for issuing the non-contact type IC card is as follows. The data write time T is 1.0 s. Non-contact IC card 10
The time from the stop state to the maximum speed Vm is 0.1
s, it moves by 5 cm within this time, and the time from the maximum speed Vm to the stop state is 0.1 s. It moves by 5 cm within this time, and 10 cm at the maximum speed Vm of 0.1 s. It moves, and when these moving distances are added, it becomes 20 cm which is the margin distance. Therefore,
Issue cycle time is 1.0 + 0.1 + 0.1 + 0.1
= 1.3 s. As described above, according to the card transport pattern of the IC card issuing system of FIG. The issue cycle time can be shortened by s.

As another example, data write time T = 2 s
And a card transport pattern when the length X of the communicable range is 10 cm. The upper limit of acceleration / deceleration of the card transport is 10 cm / s ² , the maximum speed Vm of the card transport speed V is 10 cm / s, and the transport path before and after the margin distance is 20 cm. A card transport pattern that passes through a length of 10 (= X) cm for 2 s and has a maximum card transport speed Vm outside the communicable range is set. This card transport pattern is as shown in FIG.

FIG. 5 is an explanatory diagram illustrating an example of a card transport pattern in which the card transport device transports a non-contact type IC card. At time T21, the card transport speed V is the maximum speed Vm. At time T22, the non-contact type I
The C card 10 enters the communicable range, the card transport device 20 starts reducing the card transport speed V, and the card transport speed V decreases from the maximum speed Vm. At time T23, the belts 74 and 77 of the card transport device 170 stop, the card transport speed V becomes 0, and the non-contact IC card 1
0 stops. At time T23, the card transport device 2
0 starts acceleration of the card transport speed V. At time T24, the non-contact IC card 10 moves out of the communicable range, and the card transport device 20 sets the card transport speed V to the maximum speed Vm. At time T25, the card transport speed V is the maximum speed Vm, and the subsequent non-contact IC card 10 enters the communicable range. At time T26, the belts 74 and 77 of the card transport device 170 stop, the card transport speed V becomes 0, and the subsequent non-contact IC card 1
0 stops. At time T26, the card transport device 2
0 starts acceleration of the card transport speed V. At time T27, the subsequent non-contact IC card 10 moves out of the communicable range, and the card transfer device 20 sets the card transfer speed V
To the maximum speed Vm.

The time from time T21 to time T22 is
2s. The time from time T22 to time T23 is
1 s. The time from time T23 to time T24 is
1 s. The time from time T24 to time T25 is
2s. The time from time T25 to time T26 is
1 s. The time from time T26 to time T27 is
1 s.

The time from time T21 to time T22 is a margin time, which is a time for the preceding non-contact type IC card 10 to move on the previous transport path which is the transport path to the entrance of the communicable range. The position of the preceding contactless IC card 10 from time T22 to time T24 is a communicable range,
Its length X is 10 cm. From time T24 to time T2
The time up to 5 is a margin time, which is a time during which the subsequent non-contact IC card 10 moves on the previous transport path, which is the transport path to the entrance of the communicable range. The distance on the transport path from the preceding non-contact type IC card 10 to the following non-contact type IC card 10 is about 30 cm.

On the other hand, the card transport pattern of the conventional IC card issuing system for writing data only to the stopped non-contact type IC card 10 is as shown in FIG. Time T31
, The card transport speed V is the maximum speed Vm. At time T32, the preceding non-contact IC card 10 enters the communicable range, the card transport device 170 starts to reduce the card transport speed V, and the card transport speed V decreases from the maximum speed Vm. At time T33, the belts 74 and 77 of the card transport device 170 stop, the card transport speed V becomes 0, and the non-contact IC card 10 stops. Only from time T33 to time T34, data writing to the semiconductor memory in the preceding non-contact type IC card 10 is performed. At time T34, the card transport device 20 starts accelerating the card transport speed V, and the card transport speed V increases. At time T35, the preceding non-contact IC card 10 moves out of the communicable range, and the card transport device 170 sets the card transport speed V to the maximum speed Vm. At time T36, the subsequent non-contact IC card 10 enters the communicable range, the card transport device 170 starts to reduce the card transport speed V, and the card transport speed V decreases. At time T37, the belts 74 and 77 of the card transport device 170 stop and the card transport speed V becomes 0,
The subsequent non-contact IC card 10 stops. Time T37
Only at time T38 from the subsequent non-contact IC
Data writing is performed on the semiconductor memory in the card 10. At time T38, the card transport device 20 starts accelerating the card transport speed V, and the card transport speed V increases.

The time from time T31 to time T32 is
2s. The time from time T32 to time T33 is
1 s. The time from time T33 to time T34 is
2s. The time from time T34 to time T35 is
1 s. The time from time T35 to time T36 is
2s. The time from time T36 to time T37 is
1 s. The time from time T37 to time T38 is
2s.

The time from time T31 to time T32 is a forward margin time, and is a time during which the non-contact type IC card 10 moves on the previous transport path which is the transport path to the entrance of the communicable range. From time T33 to time T34,
This is the data writing time T during which data is written to the non-contact IC card 10. From time T35 to time T36 is a margin time for the rear, and the non-contact type IC card 10 moves 20 cm. Leading non-contact IC card 1
The distance on the transport path from 0 to the subsequent non-contact type IC card 10 is about 30 cm. In the card transport pattern of FIG. 6, the issue cycle time is 6 s, and the card transport pattern of FIG. 5 is shorter by 2 s.

As described above, the IC card issuing system 3
In 00, data writing is performed while minimizing a decrease in the card transport speed V. Also, data is written while the card transport speed V is decreasing and increasing. Also, data is written using the entire communicable range.

On the other hand, data may be written to the semiconductor memory in the non-contact type IC card 10 only when the card transport speed V is decreasing, and only when the card transport speed V is decreasing and when the card transport speed V is stopped. The data may be written, or the data may be written only during the decrease in the card transport speed V and during the constant speed after the decrease. By doing so, it is possible to reduce the issue cycle time of the non-contact type IC card as compared with the case where data is written only while the card is stopped. Similarly, data may be written to the semiconductor memory in the non-contact type IC card 10 only while the card transport speed V is increasing, and only when the card transport speed V is stopped and after the card is stopped. Data may be written, or data may be written only while the card transport speed V is increasing at a constant speed and after the constant speed. By doing so, it is possible to reduce the issue cycle time of the non-contact type IC card as compared with the case where data is written only while the card is stopped.

The card transfer speed V may be set to 0 between the end of the deceleration and the start of the acceleration to stop the non-contact type IC card 10, and the card transfer speed V may be stopped from the end of the deceleration to the start of the acceleration. May be maintained at a constant speed greater than zero. The non-contact IC card 10 may be configured to have a one-chip microcomputer, and the one-chip microcomputer may be configured to have the semiconductor memory. At the same time as performing position detection based on the motor rotation speed, if there is an installation space on the transport path of the non-contact IC card 10, a plurality of optical sensors and the like are installed as other detection means, and the non-contact IC card 10 The position may be detected sequentially. The above embodiment is an example of the present invention, and the present invention is not limited to the above embodiment.

[0043]

According to the IC card issuing system of the present invention,
Since the data writing device writes data to the semiconductor memory in the non-contact type IC card located in the data writable range, the data can be written while the card is moving, and only when the card is stopped. The issuing cycle time of the non-contact type IC card can be reduced as compared with the case of writing data.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram showing an example of a conventional IC card issuing system.

FIG. 2 is an explanatory diagram showing a card transport pattern in which a card transport device of the IC card issuing system of FIG. 1 transports a non-contact type IC card.

FIG. 3 is a schematic block diagram showing an example of an IC card issuing system according to the present invention.

FIG. 4 is an explanatory diagram showing an example of a card transport pattern in which the card transport device of the IC card issuing system of FIG. 3 transports a non-contact type IC card.

5 is an explanatory diagram showing an example of a card transport pattern in which a card transport device of the IC card issuing system of FIG. 3 transports a non-contact type IC card.

FIG. 6 is an explanatory diagram showing an example of a card transport pattern in which a card transport device of a conventional IC card issuing system transports a non-contact type IC card.

[Explanation of symbols]

10: Non-contact IC card, 20: Card supply device, 4
0: Data writing device, 41: Antenna, 42: Antenna control device, 60: Card stacker, 70, 170: Card transport device, 71: Motor, 71A: Disk, 72, 7
3, 75, 76 ... pulley, 74, 77 ... belt, 78
A, 78B: detecting means, 80, 180: control device, 10
0,300: IC card issuing system, 171: Card inlet, 172: Card outlet, V: Card transport speed.

Claims (7)

[Claims] 1. A non-contact type IC card, comprising: a card transport device for transporting a non-contact type IC card; and a data writing device for writing data to a semiconductor memory in the non-contact type IC card. An IC card issuance system for issuing a non-contact type IC card having the non-contact type IC card, wherein the card transport device is a card when the non-contact type IC card is located in a range where data can be written from the data writing device. An IC card issuing system for lowering a transport speed, wherein the data writing device writes data to a semiconductor memory in the non-contact type IC card located in the data writable range. 2. When the non-contact type IC card is located in the data writable range, the card transport device lowers the card transport speed and then increases the card transport speed. 2. The IC card issuing system according to claim 1, wherein data is written to a semiconductor memory in the non-contact type IC card whose card transport speed is decreasing or increasing. 3. The IC card issuance system according to claim 2, wherein said data writing device writes data to a semiconductor memory in said non-contact type IC card which has stopped due to a reduced card transport speed. 4. The card transport speed when the non-contact type IC card has entered the data writable range is equal to the card transport speed when the non-contact IC card has entered the data writable range. The IC card issuing system according to claim 1, wherein the speed is a maximum moving speed of the non-contact type IC card on a transport path. 5. The IC card issuing system according to claim 1, wherein said IC card issuing system has a detecting means for detecting a position of said non-contact type IC card on a transport path. 6. The card transporting device transports the non-contact type IC card using a motor and a belt that is moved by rotation of the motor. The IC card issuing system according to claim 1, wherein a position of the non-contact type IC card is detected. 7. The data writing device is a reader / writer device, and the data writable range is a range in which the reader / writer device can communicate with the non-contact type IC card. An IC card issuing system according to any one of the preceding claims.