JP2003168082A - Method and system for inspecting rf-id, and rf-id form being inspection object - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve efficiency by reducing a process by forming needed information after inspection by the inspection without typing or printing out useless information in an RF-ID (Radio Frequency Identification) form in an RF-ID inspecting method, inspection system and RF-ID form for inspecting whether a manufactured RF-ID is good or bad according to the form state of the manufactured RF-ID. <P>SOLUTION: An inspection processing means 13 transmits prescribed information to an inlet 12X of an inspection object for storage, receives the stored prescribed information transmitted from the inlet 12X, judges whether the inlet 12X is good or bad by comparing the received prescribed information with the transmitted prescribed information, and transmits to an optical processing means 17 typing information associated with the inlet 12X on the basis of the transmitted prescribed information. The optical processing means 17 directly emits light to a prescribed part of an RF-ID form attached with the inlet 12X to perform needed typing on the basis of the transmitted typing information. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to an RF-manufactured product.
The present invention relates to an RF-ID inspection method, an inspection system, and an RF-ID form for inspecting quality in an ID foam state.

[0002]

2. Description of the Related Art In recent years, RF-ID (Radio Fre
A technique relating to a non-contact type identification medium (a non-contact type IC card or the like) called a "Quality Identification" is rapidly advancing, and its use is also wide-ranging. Such an RF-ID inspection requires that
Generally, read / write is performed in a state in which what is called an inlet having a C module and an antenna is attached to a foam sheet. In the inspection in such a state, it is desired that the originally unnecessary information is not printed on the foam sheet, and the efficiency of post-inspection processing is desired to be improved.

Conventionally, an RF-ID with an inlet attached
When you inspect the performance, etc. in the form, send the data to the IC module of the inlet and store it, then send the data stored from the inlet to the inspection system side and receive it on the inspection system side. The quality of the inlet is determined by matching the data that has been stored with the data transmitted to the inlet.

[0004] Then, for the inlet which is regarded as a good product,
A unique ID (identifier) number or the like is sequentially stored, and this is sequentially read to obtain the ID number and the user name associated with the same from a database or the like, and electrostatically stored in any part of the RF-ID form. It is printed by a digital printer.
In this case, since the IC module may be broken during printing by the electrostatic printer, the stored data is read again to inspect for failure.

As another method, a bar code associated with the ID number or the like is printed in advance on any of the RF-ID forms, the bar code is read at the time of the inspection, and the ID associated with the bar code is read. A number or the like is acquired from a database or the like and stored in the IC module of the inlet, which is read to determine the quality, and
The ID number or the like is printed on any part of the RF-ID form by an electrostatic printer or the like. Then, in the same manner as described above, the stored data is read again to inspect for any failure.

[0006]

However, in any of the above-mentioned methods, there is a problem that the inspection must be performed again after printing by the electrostatic printer, resulting in many steps and reduced efficiency. In addition, it is required that nothing originally printed on the RF-ID form is originally printed and not printed. The former requires a bar code required only for inspection, and the latter requires the above-mentioned request. However, there is a problem that the number of steps is increased compared to the latter.

Therefore, the present invention has been made in view of the above problems, and reduces the steps of forming necessary information after inspection rather than inspection without printing or printing unnecessary information on the RF-ID form. An object of the present invention is to provide an RF-ID inspection method, an inspection system, and an RF-ID form for improving efficiency.

[0008]

In order to solve the above-mentioned problems, in the invention of claim 1, when an RF-ID is manufactured, an inlet having an IC module and an antenna is attached to an RF-ID foam. A method for inspecting an RF-ID that communicates with an inlet attached to the RF-ID form to be inspected and determines whether the quality is good, in which predetermined information is provided to the inlet to be inspected. Judgment of the quality of the inlet by comparing the step of transmitting and storing in the IC module of the inlet with the stored predetermined information from the inlet and receiving the predetermined information and comparing with the transmitted predetermined information And when the inlet is a non-defective product, the printing information associated with the inlet is optically processed based on the transmitted predetermined information. And a step of directly irradiating light on a predetermined portion of the RF-ID foam to which the corresponding inlet is attached, based on the print information transmitted by the optical processing means, and performing printing. The configuration includes and.

According to the second aspect of the present invention, when the RF-ID is manufactured, the inlet having the IC module and the antenna is attached to the RF-ID form, and the RF-ID form to be inspected is attached. An RF-ID inspection system that communicates with an attached inlet to determine pass / fail, wherein a system-side antenna for communicating with the inlet, and the system side with the inlet to be inspected Predetermined information is transmitted via the antenna and stored in the IC module of the inlet, and the stored predetermined information transmitted from the inlet is received and compared with the predetermined information transmitted for storing. By doing so, the quality of the inlet is judged, and if the inlet is a non-defective product, the inlet is judged based on the transmitted predetermined information. Based on the printing information transmitted from the processing means and the printing information transmitted from the processing means, the predetermined portion of the RF-ID form to which the corresponding inlet is attached is directly irradiated with light. And an optical processing means for performing printing.

According to the invention of claim 3, the RF according to claim 1
An ID inspection method and an inspection target RF-ID form in the RF-ID inspection system according to claim 2, wherein the inlet is affixed and necessary print information is formed in a predetermined portion. .

According to the inventions of claims 4 to 6, the "predetermined portion in which the print information is formed is an area to which the inlet is attached or a portion other than the area to which the inlet is attached". Yes, "the ink having a color different from that of the surface is formed at a predetermined portion where the print information is formed, and the information is formed by scraping off the ink by light irradiation by the light processing means" The "predetermined portion on which the print information is formed is formed by forming at least two layers of members different in color and shaving off the layer portion of the irradiation surface by light irradiation by the light processing means. It is a composition.

As described above, in order to transmit predetermined information to the inlet to be inspected and store it in the IC module of the inlet, receive the stored predetermined information transmitted from the inlet, and store it in the above. The quality of the inlet is determined by comparing it with the transmitted predetermined information, and when the inlet is a non-defective product, the print information associated with the inlet is transmitted to the optical processing means based on the transmitted predetermined information, Based on the print information transmitted by the optical processing means, a predetermined portion of the RF-ID form to which the corresponding inlet is attached is directly irradiated with light to perform necessary printing. That is, predetermined information to be stored at the time of inspecting the inlet is used as information to be finally stored, and necessary print information is directly formed by optical processing based on the stored predetermined information after the inspection.
It is possible to reduce the steps from the inspection to the formation of the necessary information after the inspection without printing unnecessary information on the ID form and to improve the efficiency.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of the present invention will be described below with reference to the drawings. In the present embodiment, the electromagnetic induction type is shown as the RF-ID, but it is also applicable to the electrostatic induction type.

FIG. 1 shows a block diagram of an RF-ID inspection system according to the present invention. In FIG. 1, RF-
The ID inspection system 11 is configured to include an inspection processing unit 13 and a drive structure unit 14 which are processing units for the inlet 12X to be inspected in each RF-ID form of continuous RF-ID forms. The inlet 12X to be inspected is composed of an antenna 21 and an IC module 22. The antenna 21 is a coil wound on a plane and receives a signal from the inspection processing means 13 or the inlet 12X. It plays a role of transmitting data to the inspection processing unit 13. Further, the IC module 22 is configured to include a processing unit 31, a memory 32 and a demodulation unit 33.

In the IC module 22, the memory 32 is for storing various information as a card, for example. The demodulation unit 33 demodulates the control signal and data from the radio wave received by the antenna 21 and converts the code as appropriate. Then, the processing unit 31 causes the memory 32 to store the received control signal and data and transmits the data stored in the memory according to the program.

The inspection processing means 13 comprises a control portion 41, a DB (database) 42, an inspection processing portion 43, and a data memory 44 as a processing means for determining whether the inlet 12X to be inspected is good or bad. Amplifier 4
5, modulator 46, transmitter 47, detector 48, data converter 49, carrier drive controller 50, antenna drive controller 5
1, interface (IF) section 52 and display means 5
3 is provided.

The control unit 41 has the inspection processing means 13
It controls the whole of, and the program according to this is set. DB42 is finally RF-ID
Information (including print information) such as a user name associated with an ID or the like stored in the memory 32 of the IC module 22 in the inlet 12X is stored. The inspection processing unit 43 performs inspection processing and determination on the inlet 12X by an inspection routine by a program. The data memory 44 mainly stores various setting data for communication, and serves as a temporary storage area (a buffer, which may be provided in the inspection processing unit 43) for inspection determination as appropriate. It also plays a role.

The data conversion unit 49 converts information when transmitting information to the inlet 12X to be inspected into, for example, "1" or "0", and the inlet 12X concerned.
The transmission data from is converted into, for example, "1" and "0".
The modulator 46 uses the information converted by the data converter 49 based on the transmission output from the transmitter 47, for example, FS.
Modulates to K (frequency shift keying) modulated wave. The power amplifier 45 power-amplifies the modulated wave modulated by the modulator 46, and the amplified modulated wave is transmitted from a system-side antenna described later. Then, the detection unit 48
Detects and demodulates the radio wave transmitted from the inlet 12X received by the system-side antenna.

On the other hand, the transfer drive control unit 50 generates a control signal for driving the above-described transfer drive unit 62, which transfers the inlets 12X for sequentially inspecting, based on a command from the control unit 41 to generate an IF unit. It is sent via 52 to the transport drive unit described later. In addition, the antenna drive control unit 51
Generates a signal for controlling a distance (communication distance) with respect to the target antenna 21 by moving a shield member and a system-side antenna, which will be described later, with respect to the inlet 12X based on a command from the control unit 41. The data is sent out to the antenna drive unit described later via the unit 52.

Further, the IF unit 52 includes a position detecting unit 1 which will be described later.
The position detection signal from 5 is input, and this signal is sent to the control unit 41. Further, the IF unit 52 sends a marking signal to the marker 16 when the control unit 41 acquires a signal for marking the quality (either) of the inspection result on the RF-ID foam (inlet 12X) to be inspected. To do. Then, the print information associated with the inlet 12X is sent to the laser processing unit 17 which is the optical processing unit from the control unit 41 via the IF unit 52 based on the predetermined information transmitted to the corresponding inlet 12X.
It is acquired from B42 and transmitted.

The laser processing means 17 appropriately scans and irradiates light directly on a predetermined portion of the RF-ID form to which the corresponding inlet 12X is attached, based on the transmitted print information. Is to do.
In the present embodiment, as the optical processing means, the case of performing processing by laser light is shown, but the present invention is not limited to this, and may be any one that irradiates light that can be processed by scraping paper, film, resin, or the like. As the light, for example, there is a light beam having a coherence property of almost a single wavelength.

The drive structure means 14 mounts a system side antenna 61 for communicating with the inlet 12X, and is composed of a conveyance drive portion 62 and an antenna drive portion 63. The transport drive unit 62 is for directly driving a belt transport unit described later. The antenna drive unit 63
Moves the system-side antenna 61 up and down in the direction of the inlet 12X as described above, and moves the RF-I
The Y movement is performed between the inlets 12X in the width direction of the D foam. The antenna drive unit 63 moves the shield member and the system-side antenna 61, which will be described later.

Here, FIG. 2 shows the RF-to-be-inspected in FIG.
The structure explanatory drawing of ID form is shown. FIG. 2A shows a continuous RF-ID foam 71. For example, an inlet sheet (simply referred to as an inlet) 12A is attached to a predetermined portion of a foam base material 72 such as paper. The F-ID form in which the IC module related information 73A such as ID and name is formed in a portion other than the contact area is continuous.

FIG. 2B shows an inlet 12A. The inlet 12A has an antenna 21 formed by a coil on one surface and a timing mark 22 formed inside the antenna 21. The IC module 23 is electrically connected to and mounted on both ends of the antenna 21. For example, the antenna 21 and the timing mark 22 are formed on one surface of an opaque member such as an opaque film or paper or a transparent member such as a transparent film, and then the IC module 23 is mounted as described above. Is.

Then, an adhesive or the like is applied to the surface of the inlet 12A on which the IC module 23 is formed, and then, as shown in FIG.
As shown in FIG. 5, the continuous foam sheet is attached to a predetermined portion of the corresponding individual RF-ID foam. When the base material of the inlet 12A is a transparent member, an opaque member such as paper is further attached on the attached inlet 12A to make the antenna 21, the timing mark 22 and the IC module 23 invisible. . Such an individual RF-ID form 71 is manufactured as a personal authentication card, a credit card, an electronic money card or the like by a manufacturing process in which the inlet 12A portion is generally known after the inspection.

FIG. 2C is a schematic cross-sectional view of the IC module associated information 73 portion, in which the ink layer 73 having a color different from that of the surface of the foam substrate 72 is formed.
A is formed by printing or the like, and the ink layer 73A is scraped off by laser light in accordance with print information described later to form the IC module related information 73. In addition, in the present embodiment, the case where the IC module related information 73 is formed on a predetermined portion other than the inlet sticking portion is shown. However, when the base material of the inlet 12A is opaque, an ink layer is formed on the back surface thereof. It may be formed in advance, and when the base material of the inlet 12A is transparent, the ink may be formed in advance on the surface which is an opaque member to be covered after sticking and which will be the surface after sticking.

Therefore, FIG. 3 shows a schematic perspective view of the inspection processing means portion in the inspection system of FIG. In FIG. 3, the inspection processing system 81 is roughly divided into R to be inspected.
A belt transport unit 82 that constitutes one of transport means for sequentially transporting the F-ID foam (inlet 12A) to the inspection position,
It is composed of a shield member 83 and a drive mechanism 84. The inspection processing means 13 for performing the inspection process is not shown here.

The belt conveyor 82 successively conveys the continuous RF-ID foam 71 supplied by a supply means (not shown), and the target RF-ID foam (inlet) at the inspection position is the inlet 12X to be inspected. Becomes The shield member 83 is formed of a conductive material such as metal or conductive resin into a plate shape or a net shape.
System side antenna 61 and inlet 12X to be inspected
And (here, below the inlet 12X). In addition, the shield member 83 has an opening 83A that allows the system-side antenna to face the target inlet 12X.
Is formed, and the peripheral portion thereof is set to have a distance from the inlet 12X to be inspected to be larger than the surface on which the opening 83A is formed, so that radio waves are transmitted by the edge in the vicinity of R.
The F-ID form (inlet) is not affected.

The drive mechanism 84 is below the inlet 12X to be inspected, and the shield member 8 is provided.
The system-side antenna 61
And Y drive for moving the belt conveying unit 82 in the width direction and Z drive for moving the belt conveying unit 82 in the vertical direction. On the other hand, the position detecting unit 15 that detects that the inlet 12X to be inspected has been conveyed to the inspection position near the inspection position above the belt conveying unit 82 by the timing mark 22.
And the marker 16 for marking the inspection result on the RF-ID foam (inlet 12X) after the inspection is arranged at an appropriate position.

The position detector 15 detects the invisible timing mark 22. When the timing mark 22 is made of a metal material, a proximity sensor or a light transmission type sensor is used. If not, a light transmission type sensor is used. The detection of the inspection position of the inlet 12X by the position detection unit 15 may be detected by the ink layer 73A. In this case, the inlet 1X is detected.
The timing mark 22 formed on 2A can be omitted. In this case, if the ink layer 73A contains a metal material, any of a proximity sensor, a light transmission type sensor, and a light reflection type sensor can be used as the position detection unit 15, and the ink layer 73A is made of a metal material. When not including, a light transmission type sensor or a light reflection type sensor is used.

By the way, the case where the shield member 83 and the drive mechanism 84 are arranged below the inlet 12X to be inspected has been described. However, the shield member 83 and the drive mechanism 84 are arranged above the belt conveyor 82 and communicate with the inlet 12X from above. May be performed. In this case, the position detection unit 15 and the marker 16 have the shield member 83 and the drive mechanism 8 respectively.
It is appropriately arranged at a position avoiding 4.

Therefore, FIG. 4 shows a flowchart of the inspection processing by the inspection processing means of FIG. In FIG. 4, first, a command from the control unit 41 is given to a driving amount for conveying the inspection target RF-ID foam (inlet 12X) of the RF-ID foam 71 sequentially supplied onto the belt conveyance unit 82 to the inspection position. Based on the
It outputs to the conveyance drive part 62 via 2 (step (S)
1).

The inlet 1 to be inspected by the position detector 15
When the 2X timing mark 22 is detected, the control unit 41 stops the belt transfer unit 82 via the transfer drive control unit 50 and the transfer drive unit 62, and the antenna drive control unit 51 causes the inspection by the control unit 41 command. The drive amount (Y) for positioning the shield member 83 and the system-side antenna 61 at the lower center with respect to the position inlet 12X is the Y-direction drive amount of the antenna drive unit 63, and the system-side antenna 61 is used for the inlet 12X (antenna). With respect to 13), the drive amount (Z) that is the basic distance is output as the Z-direction drive amount (S2). Note that, as described above, when the inlet 12X is inspected in the transport movement state, the drive amount (X) for moving the X in synchronization with the transport is output as the X-direction drive amount.

Therefore, the transmission data (identification information, etc.) for the inspection target is acquired from the DB 42 and the inlet 1 for the inspection target is acquired.
It is transmitted to 2X (S3). If there is a response (transmission of reply data) from the inlet 12X (S4),
Upon receiving the reply data, the inspection processing unit 43 matches the transmission data with the reception data (S5).
As a result of the matching (S5), when they match, it is determined as a non-defective product (S6), and predetermined information regarding the transmission data acquired from the DB 42 is sent to the laser processing means 17 as print information (S7).

On the other hand, in the matching result (S5),
If they do not match, it is determined as a defective product (S8). If there is no response in S4, the IC module 14
It is determined that the inlet 12X is a defective product (S8). Here, if the inlet 12X is a defective product, the inlet 12X is marked,
The control unit 41 commands the marker 16 to mark the inlet 12X which is determined to be defective in S8 (S9). Then, these judgment results are stored in the data memory 4
4 (S10).

Then, the next inlet 12X to be inspected
In the case of detecting (S11), the inlet 12X
Again, S1 to S9 are repeated to store the determination result in the data memory 44 (S10). Then, the next inlet 12X to be inspected is not detected, all the inlets 12X to be inspected are inspected, and when the quality is stored in the data memory 44, the inspection result is appropriately displayed on the display unit 53. (S12). In addition, the display of the inspection result,
Each inlet 12X or a predetermined number of inlets 12X
It may be performed for each inspection result.

Next, FIG. 5 shows a schematic perspective view of the laser processing means portion in the inspection system of FIG. 1, and FIG. 6 shows an explanatory view of the RF-ID form laser-processed after the inspection. The laser processing means 17 shown in FIG. 5 shows the main part of the laser processing means 17, and includes a stage 91, a belt conveying portion 82A,
82B, a laser irradiation unit 92, and a suction mechanism 93. The belt conveyors 82A and 82B are extensions of the belt conveyor 82, and the stage 91 is located between the belt conveyors 82A and 82B. That is, the belt transport unit 82A causes the stage 91 to be RF-
The belt carrying section 82B is for carrying the ID foam 71, and the belt carrying section 82B is an RF-I machined by laser on the stage 91.
It is for discharging the D foam. In addition, the belt conveyor 82 including the belt conveyor 82 shown in FIG.
The A and 82B may be configured in two stages so that the RF-ID foam 71 is sandwiched and conveyed.

The stage 91 is a pedestal for laser processing, and a predetermined number of holes (not shown) are formed on the surface thereof. In addition, the laser irradiation unit 92
Is the RF-ID of the inspection target located on the stage 91.
This is for directly irradiating the ink layer 73A formed on the foam with laser light based on the print information transmitted from the inspection processing means 13 to print the information such as the ID. The laser irradiation by the laser irradiation unit 92 is performed by scanning the RF-ID foam within the laser irradiation range by a drive control unit (not shown).

A suction mechanism 93 is provided on the stage 91. The suction mechanism 93 sucks and fixes the RF-ID foam by sucking through a hole formed on the surface of the stage 91 when the target RF-ID foam is positioned on the stage 91 during laser processing. The position shift is prevented during laser processing. In this case, the suction force is appropriately adjusted so that the sucked RF-ID foam does not undulate. Further, the suction mechanism 93 also plays a role of discharging smoke generated during laser processing.

In the laser processing means 17 as described above, the target RF-ID foam is carried by the belt carrying section 82A, carried on the stage 91, and the suction mechanism 93.
Performs suction drive to suction-fix the RF-ID foam to be processed. Then, based on the acquired print information, the laser light 15A emits the laser light 15A to the foam substrate 72.
The upper ink layer 73A layer is sequentially irradiated and laser-processed, and as shown in FIGS. 6A and 6B, the ink layer 73A has information related to the IC module (here, I
The ID) 73 stored in the C module is formed. Then, after the laser processing, the suction by the suction mechanism 93 is released, and the RF-ID form on which the information is printed is
The sheet is discharged to the belt conveying section 82B and conveyed to a stacker or the like.

As described above, the predetermined information such as the ID to be stored at the time of the inspection of the inlet 12X is used as the information to be finally stored, and the necessary printing information is laser light based on the stored information such as the ID after the inspection. By directly forming the required information on the RF-ID form, the process for forming the necessary information after the inspection can be reduced without forming unnecessary information by printing or printing the unnecessary information, thereby improving efficiency. It is intended.

In the above embodiment, the necessary information is formed on the ink layer 73A formed on the RF-ID foam, but at least the area for forming the necessary information is formed of a member having a different color. It can also be carried out by forming two layers and shaving off the layer portion of the irradiation surface by laser light irradiation by the laser processing means 17. Specifically, R
When the foam base material 72 of the F-ID foam 71 is formed of two layers of papers of different colors, or when the papers of different colors are attached to the area on the RF-ID foam where necessary information is formed, or of the inlet 12A. When the sheet base material is transparent and is applied so as to cover two layers of different color paper after application, or when the sheet base material is opaque, it covers after the application the paper that is different in color from the base material. There are cases where it is pasted on.

[0043]

As described above, according to the present invention, predetermined information is transmitted to the inlet to be inspected and stored in the IC module of the inlet, and the stored predetermined information transmitted from the inlet is stored. The quality of the inlet is judged by comparing it with the predetermined information received for storage and stored, and if the inlet is a non-defective product, the printing associated with the inlet based on the predetermined information transmitted. The information is transmitted to the optical processing means, and based on the print information transmitted by the optical processing means, a predetermined portion of the RF-ID foam to which the corresponding inlet is attached is directly irradiated with light to perform necessary printing. By performing printing, unnecessary steps of printing and printing unnecessary information on the RF-ID form can be performed, and the process for forming necessary information after inspection can be reduced and efficiency can be reduced. Those that can be achieved on.

[Brief description of drawings]

FIG. 1 is a block configuration diagram of an RF-ID inspection system according to the present invention.

FIG. 2 is a structural explanatory view of an RF-ID form to be inspected in FIG.

3 is a schematic perspective view of an inspection processing means portion in the inspection system of FIG.

FIG. 4 is a flow chart of an inspection process by the inspection processing means of FIG.

5 is a schematic perspective view of a laser processing means portion in the inspection system of FIG.

FIG. 6 is an explanatory diagram of an RF-ID form laser-processed after the inspection.

[Explanation of symbols]

11 RF-ID inspection system 12 inlets (RF-ID) 13 Inspection processing means 14 Drive structure means 15 Position detector 16 markers 17 Laser processing means 21 antenna 22 Timing mark 23 IC module 61 System side antenna 71 RF-ID form 72 Foam sheet base material 73 IC module related information 81 Inspection processing system

Continued front page    F-term (reference) 2C005 MA19 NA09 NA10 RA30                 5B035 AA04 BB09 BC08 CA23                 5B058 CA24 KA02 KA04 KA05 KA28                       YA20

Claims (6)

[Claims] 1. When an RF-ID is manufactured, the RF-ID
An inlet having an IC module and an antenna is attached to the form, and the RF-ID to be inspected
Communicate with the inlet attached to the form,
A method of inspecting an RF-ID for determining pass / fail, comprising: transmitting predetermined information to the inlet to be inspected and storing it in an IC module of the inlet; and transmitting the stored predetermined information from the inlet. A step of performing a quality judgment of the inlet by receiving the predetermined information and comparing it with the transmitted predetermined information, and when the inlet is a non-defective product, it is associated with the inlet based on the transmitted predetermined information. Transmitting the print information to the optical processing means, based on the print information transmitted by the optical processing means,
A method of inspecting an RF-ID, comprising: irradiating light directly to a predetermined portion of the RF-ID foam to which the corresponding inlet is attached to perform printing. 2. When the RF-ID is manufactured, the RF-ID
An inlet having an IC module and an antenna is attached to the form, and the RF-ID to be inspected
Communicate with the inlet attached to the form,
An RF-ID inspection system for determining pass / fail, comprising: a system-side antenna for communicating with the inlet; transmitting predetermined information to the inlet to be inspected through the system-side antenna; It is stored in the IC module of the inlet, the stored predetermined information transmitted from the inlet is received, and the quality of the inlet is determined by comparing with the predetermined information transmitted to store the information. Is a non-defective product, based on the print information transmitted from the processing unit, and a processing unit that transmits print information associated with the inlet based on the transmitted predetermined information,
An RF-ID inspection system, comprising: an optical processing unit that directly irradiates light onto a predetermined portion of the RF-ID foam to which the inlet is attached to perform printing. 3. An RF-ID form to be inspected in the RF-ID inspection method according to claim 1 and the RF-ID inspection system according to claim 2, wherein the inlet is attached to a predetermined portion. An RF-ID form in which necessary print information is formed. 4. The RF-ID form according to claim 3, wherein the predetermined portion where the print information is formed is a region other than the region where the inlet is attached or the region where the inlet is attached. RF-ID characterized in that
Form. 5. The RF-ID form according to claim 3 or 4, wherein the predetermined portion where the print information is formed,
At least ink whose color is different from the surface is formed,
Information is formed by scraping off the ink by light irradiation by the light processing means.
D form. 6. The RF-ID form according to claim 3 or 4, wherein the predetermined portion on which the print information is formed is formed of at least two layers of members having different colors, and is formed by the optical processing means. An RF-ID form characterized in that information is formed by shaving off a layer portion of an irradiation surface by light irradiation.