JP2003168098A - RF-ID inspection system and RF-ID form to be inspected - Google Patents

Abstract

(57) Abstract: An object of the present invention is to provide an RF-ID inspection system and an R-ID inspection system for inspecting the quality of a manufactured RF-ID in a foam state.
An object of the F-ID form is to enable detection of an inlet at the time of inspection without performing unnecessary printing or printing on a portion other than the inlet sticking area in the RF-ID form. An RF-ID form has an inlet.
A timing mark is formed in a region where A is stuck in an invisible state, and after the timing mark is detected by the position detection unit 26 serving as a code recognition unit, the processing unit responds to the timing mark detection by the position detection unit 26. A configuration in which at least conveyance by the conveyance belt 22 is stopped, predetermined information is transmitted to the inlet 12A to be inspected via the system-side antenna 25, and the acceptability of the inlet 12A is determined according to a response from the inlet 12A. I do.

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 system and an RF-ID form for inspecting quality of an ID form.

[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
It is common to carry out read / write with a C module and what is called an inlet having an antenna attached to a foam sheet, and in the inspection in such a state, it is originally unnecessary for the foam sheet. It is desired that information or the like is not printed.

Conventionally, an RF-ID with an inlet attached
In the case of inspecting the performance and the like of the foam, it is performed for the inlet of each RF-ID foam by conveying the continuous IRF-ID foam with the inlets attached thereto from the viewpoint of inspection efficiency. The inlet is detected, and the inspection is started at that timing. That is, a timing mark is printed or printed on a portion of the RF-ID form other than the area where the inlet is attached, and when the timing mark is detected by the optical sensor, the conveyance is stopped and the inspection is started. It is what is done.

[0004]

However, originally R
It is required that nothing be printed or printed on the portion of the F-ID form other than the inlet attachment area. Also,
Even if a timing mark has to be formed to detect the inlet, there are some IC foam substrates that cannot print or print the above timing mark. Therefore, a marginal portion is provided on the form to print or print. However, the marginal part is a wasteful part in the first place, and there is a problem that the cost becomes high. Further, there is a problem that the optical sensor cannot detect when the timing mark is printed or other printing information is formed on the line to be printed.

Therefore, the present invention has been made in view of the above problems, and enables an inlet to be detected during inspection without performing unnecessary printing or printing on a portion of the RF-ID form other than the inlet attachment area. An object is to provide an RF-ID inspection system and an RF-ID form.

[0006]

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. The RF-of the inspection object which is conveyed to the inspection position by a predetermined conveying means.
An RF-ID inspection system that communicates with an inlet attached to an ID form to determine pass / fail, wherein a predetermined code is formed in a region of the RF-ID form to which the inlet is attached. A code recognition means for recognizing the code in the inlet attachment area of the RF-ID foam being conveyed, a system-side antenna for communicating with the inlet, and a system-side antenna for the inlet to be inspected. A processing unit that transmits predetermined information via the, determines the quality of the inlet according to the response from the inlet, and controls at least the transportation by the transportation unit according to the recognition of the code by the code recognition unit. And are configured to have.

According to the invention of claims 2 to 4, "the formed code is a bar code associated with the timing mark or the writing information to the IC module,
The code recognizing means is a mark detection sensor or a bar code reader. ”When the code formed of the predetermined material is a timing mark and is invisible in the state of the RF-ID foam, The code recognizing means is a light-transmitting type or a proximity type sensor. When the code formed of the predetermined material is a timing mark and is visibly formed in the state of the RF-ID foam. The code recognition means is a light transmission type, light reflection type or proximity type sensor. "

According to a fifth aspect of the present invention, there is provided an RF-ID form to be inspected in the RF-ID inspection system according to any one of the first to fourth aspects, wherein the inlet is attached to the area. A predetermined code is formed.

According to a sixth aspect of the invention, the code formed on the RF-ID foam is formed on the inlet base material or the RF-ID foam base material.

In this way, a predetermined code is formed in the area where the inlet is attached to the RF-ID form, and after the code is recognized by the code recognition means, the processing section causes the system-side antenna to be provided in the inlet to be inspected. Predetermined information is transmitted via the, the quality of the inlet is judged according to the response from the inlet, and at least the conveyance by the conveying means is controlled according to the recognition of the code by the code recognizing means. As a result, the inlet can be detected at the time of inspection without performing unnecessary printing or printing on a portion other than the inlet sticking region in the RF-ID form.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an RF-ID according to the present invention.
The block diagram of 1st Embodiment of a form is shown. Figure 1 (A)
Shows a continuous RF-ID form 11,
RF in which an inlet sheet (simply referred to as an inlet) 12A is attached to a predetermined portion of a foam base material such as paper
-The ID form is continuous.

FIG. 1B shows the inlet 12A. The inlet 12A has an antenna 13 formed by a coil on one surface thereof, and a timing mark 15 as a code inside the antenna 13. Is formed, and the IC module 14 is formed on both ends of the antenna 13.
Is electrically connected and mounted. For example, the IC module 14 is mounted as described above after the antenna 13 and the timing mark 15 are formed by screen printing or the like on one surface of an opaque member such as an opaque film or paper. Here, opaque means that the surface has a degree of transparency such that the surface cannot be visually recognized from the back side, and the same applies to the following corresponding embodiments.

Then, an adhesive or the like is applied to the surface of the inlet 12A on which the IC module 14 is formed, 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. Therefore, the antenna 13, the IC module 14, and the timing mark 15 are not exposed on the RF-ID form 11, and the timing mark 15 is invisible. Such an individual RF-ID form 11 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.

Therefore, FIG. 2 shows an RF-ID according to the present invention.
1 shows a schematic perspective view of an RF-ID inspection system for inspecting a foam. In FIG. 2, the RF-ID inspection system 21 is roughly classified into a conveyor belt 22, a shield member 23, and a drive which constitute one of conveyor means for sequentially conveying the inspection target RF-ID foam (inlet 12A) to the inspection position. It is composed of the mechanism 24. A processing system for performing the inspection processing is not shown here (shown in FIG. 3).

The conveyor belt 22 sequentially conveys the continuous RF-ID foam 11 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. Become.
The shield member 23 is formed of a conductive material such as metal or conductive resin in a plate shape or a net shape, and includes a system-side antenna 25 described later and the inlet 12 to be inspected.
It is interposed between X (here, below the inlet 12X). In addition, the shield member 23 has an opening 23 that allows the system-side antenna to face the target inlet 12X.
A is formed, and its peripheral portion is set to have a distance from the inlet 12X to be inspected to be larger than that of the surface where the opening 23A is formed, and radio wave transmission by the edge is performed in the vicinity of the RF-ID foam (inlet). ) Is not affected.

The drive mechanism 24 is below the inlet 12X to be inspected, and the shield member 2 is provided.
The system-side antenna 25
And Y drive for moving the carrier belt 22 in the width direction and Z drive for moving the carrier belt 22 in the vertical direction. On the other hand, in the vicinity of the inspection position above the conveyor belt 22, the code recognition means 26 for detecting (recognizing) that the inlet 12X to be inspected has been conveyed to the inspection position, and the inspection result after the inspection, the RF-ID form (inlet). Markers 27 for marking (12X) are arranged at appropriate positions.

Although the case where the shield member 23 and the drive mechanism 24 are arranged below the inlet 12X to be inspected is shown, the shield member 23 and the drive mechanism 24 are arranged above the conveyor belt 22.
Communication may be performed from above to the inlet 12X. In this case, the code recognizing means 26 and the marker 27 are appropriately arranged at positions avoiding the shield member 23 and the drive mechanism 24.

Here, FIG. 3 shows an RF-ID according to the present invention.
The block block diagram of the inspection system of RF-ID which inspects a form is shown. In FIG. 3, the RF-ID inspection system 21A includes each R of the continuous RF-ID form 11.
Inlet 12X to be inspected in F-ID form
On the other hand, the drive structure means 31 and the inspection processing means 32 are included.

The inlet 12X to be inspected is an IC composed of a processing unit 41, a memory 42 and a demodulation unit 43.
It is composed of a module 14 and an antenna 13. The antenna 13 is wound in a coil on a plane as described above, receives a signal from the inspection system 21A,
Or the inspection system 21A from the inlet 12X
It plays a role of transmitting data to the (system-side antenna 25).

In the IC module 14, the memory 42 is for storing various information as a card, for example. The demodulator 43 demodulates the control signal and data from the radio wave received by the antenna 13 and converts the code as appropriate. Then, the processing unit 41 performs a process of storing the received control signal and data in the memory 42 and transmitting the data stored in the memory according to the program.

The drive structure means 31 comprises a transport drive section 51.
The system-side antenna 25, which is composed of the antenna driving unit 52 and communicates with the inlet 12X, is mounted. The transport driving unit 51 is for directly driving the transport belt 22. As described above, the antenna drive unit 52 moves the system-side antenna 25 up and down in the direction of the inlet 12X so as to move in the Z direction, and moves the Y between the inlets 12X in the width direction of the RF-ID foam 11.
It should be noted that this antenna drive unit 52 is the same as the shield member 2 described above.
3 and the system side antenna 25 are moved.

The inspection processing means 32 constitutes a processing unit for determining the quality of the inlet 12X to be inspected, and is a control unit 61, an inspection processing unit 62, and a data memory 63.
The power amplifier 64, the modulator 65, the transmitter 66, the detector 67, the data converter 68, the carrier drive controller 69, the antenna drive controller 70, and the interface (IF) unit 7.
1 and display means 72.

The control unit 61 controls the inspection processing means 32.
It controls the whole of, and the program according to this is set. The inspection processing unit 62 performs an inspection process and a determination on the inlet 12X by a program inspection routine. The data memory 63 is
In addition to storing various data, it also serves as a temporary storage area (a buffer, which may be provided in the inspection processing unit 62) for inspection determination as appropriate. The various data include, for example, information (for example, identification information) to be stored in the memory 42 for each inlet 12X, various set values for inspection, and the like.

The data conversion unit 68 converts information when transmitting information to the inlet 12X to be inspected into, for example, "1" or "0", and also the inlet 12X.
The transmission data from is converted into, for example, "1" and "0".
The modulator 65 outputs the information converted by the data converter 68 based on the transmission output from the transmitter 66 to, for example, FS.
Modulates to K (frequency shift keying) modulated wave. The power amplifying section 64 power-amplifies the modulated wave modulated by the modulating section 65, and the amplified modulated wave is transmitted from the system-side antenna 25. Then, the detection unit 67
Is the inlet 12 received by the system antenna 25.
Radio waves transmitted from X are detected and demodulated.

On the other hand, the transport drive control unit 69 generates a control signal for driving the above-described transport drive unit 51 that transports the inlets 12X sequentially for inspection, based on a command from the control unit 61 to generate an IF unit. It is sent to the transport drive unit 51 via 71. In addition, the antenna drive controller 7
0 moves the shield member 23 and the system-side antenna 25 in the up-down direction with respect to the inlet 12X, and generates a signal for controlling the distance (communication distance) to the target antenna 13 based on a command from the control unit 61, The data is sent to the antenna drive unit 52 via the IF unit 71.

Further, a position detection signal from the position detection unit 26A as the code recognition means 26 is input to the IF unit 71, and this signal is sent to the control unit 61. Further, the IF unit 71 sends a marking signal to the marker 27 when a signal for marking the quality (either) of the inspection result on the RF-ID form (inlet 12X) to be inspected is acquired from the control unit 61. To do. The inlet 12X to be inspected has the position detection unit 26, which is formed when the timing mark 15 is formed of a metal material.
As A, for example, a proximity sensor or a light transmission type sensor is used. On the other hand, the timing mark 15 is not made of metal,
For example, when it is formed of printing ink, a light transmissive sensor is used for the position detection unit 26A, and the timing mark 15 can be detected by the light transmittance. In this case, the detection signal based on the pulse width may be specified in order to prevent erroneous detection on the antenna 13.

Next, FIG. 4 shows a flow chart of the inspection process of the RF-ID inspection system in FIGS. In FIG. 4, first, the drive amount for transporting the inspection target RF-ID foam (inlet 12X) of the RF-ID foam 11 sequentially supplied onto the transport belt 22 to the inspection position is set to the command of the control unit 61. Based on this, the transport drive control unit 69 outputs to the transport drive unit 51 via the IF unit 71 (step (S) 1).

When the position detector 26A detects the timing mark 15 of the inlet 12X to be inspected, the controller 61 stops the conveyor belt 22 via the conveyor drive controller 69 and the conveyor drive unit 51 to control the antenna drive. In the section 70, the drive amount (Y) for positioning the shield member 23 and the system-side antenna 25 at the lower center with respect to the inlet 12X at the inspection position is set as the Y-direction drive amount of the antenna drive section 52 in accordance with a command from the control section 61. Further, the drive amount (Z) that sets the system-side antenna 25 to the inlet 12X (antenna 13) as 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) for the inspection target is acquired from the data memory 63 and transmitted to the inlet 12X for the inspection target (S3). The inlet 12X
If there is a response (transmission of reply data) from (S
4) Upon receiving the reply data, the inspection processing unit 62 matches the transmission data with the reception data (S).
5). In the matching results (S5), if they match, it is determined to be a good product (S6), and if they do not match, it is determined to be a defective product (S7). If there is no response in S4, it is determined that the IC module 14 is defective and the inlet 12X is defective (S7).

If the inlet 12X is a defective product and the inlet 12X is marked, the control unit 61 instructs the marker 27 that the inlet 12X determined to be defective in S7 should be marked. Then, these determination results are stored in the data memory 63 (S8).

Then, the next inlet 12X to be inspected
If S1 is detected (S9), S1 to S8 are repeated for the inlet 12X to store the determination result in the data memory 63 (S8). 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 63, the inspection result is appropriately displayed on the display unit 72. (S10). The inspection result may be displayed for each inlet 12X or for each inspection result of a predetermined number of inlets 12X.

In this way, the inlet at the time of inspection can be detected without performing unnecessary printing or printing on a portion other than the inlet sticking area in the RF-ID form,
RF-ID form (inlet 12X) corresponding to this
It is possible to perform the quality inspection of.

Next, FIG. 5 shows a block diagram of a second embodiment of the RF-ID form according to the present invention. FIG. 5 (A) shows the continuous RF-ID form 11, and FIG. 5 (B) shows the inlet 12B to be attached. 5A and 5B, the inlet 12B
The antenna 13 and the timing mark 15 are formed on the film base material using a transparent film as the base material, and the IC module 14 is electrically connected and mounted on both ends of the antenna 13. The inlet 12B has an RF-ID formed by applying an adhesive on its forming surface.
It is attached to a predetermined portion of each RF-ID form in the form 11. Therefore, the timing mark 15 is visible on the RF-ID form.

The inlet 12B to be inspected as described above
2 is used as the code recognition means 26 for detecting the inlet 12B at the inspection position when the RF-ID inspection system 21 shown in FIG. 2 is used, for example, a proximity sensor, a light transmission type sensor or a light reflection type sensor is used. It That is, when the timing mark 15 is formed of a metal material, the position detection unit 26A can be used with any of a proximity sensor, a light transmission type sensor and a light reflection type sensor, while the timing mark 15 is not a metal material. For example, when it is formed of printing ink, a light transmission type sensor or a light reflection type sensor is used for the position detecting section 26A.

In this way, even when the timing mark 15 is formed visually, RF-
The inlet at the time of inspection can be detected without unnecessary printing or printing on the portion of the ID form other than the inlet attachment area, and the quality of the RF-ID form (inlet 12X) can be checked accordingly. Can be.

Next, FIG. 6 shows a block diagram of a third embodiment of the RF-ID form according to the present invention. FIG. 6 (A) shows the RF-ID foam sheet 11A before attachment of the inlet, FIG. 6 (B) shows the inlet 12C to be attached,
FIG. 6C shows a continuous RF with the inlet 12C attached.
-It shows the ID form 11. In FIG. 6 (A), the RF-ID foam sheet 11A before the attachment of the inlet, which is a predetermined portion inside the antenna 13 of the inlet to be attached in the inlet attachment area 16 to which the inlet is attached. Timing mark 1
7 is formed by printing, printing or the like.

On the other hand, in FIG. 6 (B), the inlet 1
In 2C, an opaque film is used for the base material, an antenna 13 is formed on the film base material, and IC modules 14 are electrically connected and mounted on both ends of the antenna 13. The inlet 12C has an adhesive applied to the formation surface thereof, and the inlet attachment area 16 of each RF-ID foam in the RF-ID foam 11 is applied.
It is attached to. Therefore, the timing mark 17 is invisible on the RF-ID form.

The inlet 12C to be inspected as described above
2 is inspected by the RF-ID inspection system 21 shown in FIG. 2, a proximity sensor or a light transmission type sensor is used as the code recognition means 26 for detecting the inlet 12C at the inspection position. That is, in the case where the timing mark 17 is formed of a metal material, for example, a proximity sensor is used for the position detection unit 26A, while when the timing mark 17 is formed of a printing ink instead of a metal material. A light transmissive sensor is used for the position detector 26A.

As described above, even when the timing mark 17 is formed invisible on the RF-ID form 11, unnecessary printing is performed on the RF-ID form in a portion other than the inlet sticking area. The inlet at the time of inspection can be detected without performing printing, and the quality inspection of the RF-ID foam (inlet 12X) corresponding to the inlet can be performed.

Next, FIG. 7 shows a block diagram of a fourth embodiment of the RF-ID form according to the present invention. FIG. 7 (A) shows the RF-ID foam sheet 11A before attachment of the inlet, FIG. 7 (B) shows the inlet 12D to be attached,
FIG. 7C shows a continuous RF with the inlet 12D attached.
-It shows the ID form 11. In FIG. 7 (A), the RF-ID foam sheet 11A before being attached with the inlet, which is a predetermined portion inside the antenna 13 of the inlet to be attached in the inlet attachment area 16 to which the inlet is attached. Timing mark 1
7 is formed by printing, printing or the like.

On the other hand, in FIG. 7B, the inlet 1
In 2D, a transparent film is used as the base material, and the antenna 13 is formed on the film base material.
The IC modules 14 are electrically connected and mounted on both ends of the device 3. The inlet 12D has an adhesive applied to the formation surface thereof, and as shown in FIG.
It is attached to the inlet attachment area 16 of each RF-ID form in the ID form 11. Therefore, the timing mark 15 is displayed on the RF-ID form.
Is visible.

The inlet 12D to be inspected as described above
2 is inspected by the RF-ID inspection system 21 shown in FIG. 2, a proximity sensor, a light transmission type sensor or a light reflection type sensor is used as the code recognition means 26 for detecting the inlet 12D at the inspection position. It That is, R
In the inlet sticking area 16 on the F-ID form 11,
In the case where the timing mark 17 is made of a metal material, the position detection unit 26A can be used with any of a proximity sensor, a light transmission type sensor and a light reflection type sensor, while the timing mark 17 is not made of a metal material, for example, When it is formed of printing ink, a light transmission type sensor or a light reflection type sensor is used for the position detecting section 26A.

In this way, even when the timing mark 17 is formed so as to be visible, the RF-
The inlet at the time of inspection can be detected without unnecessary printing or printing on the portion of the ID form other than the inlet attachment area, and the quality of the RF-ID form (inlet 12X) can be checked accordingly. Can be.

Next, FIG. 8 shows a block diagram of the fifth embodiment of the RF-ID form according to the present invention. FIG. 8 (A) shows the continuous RF-ID form 11, and FIG. 8 (B) shows the inlet 12E to be attached. In FIGS. 8A and 8B, the inlet 12E
Is a product in which a transparent film is used for the base material, the antenna 13 and the bar code 18 are formed on the film base material, and the IC module 14 is electrically connected and mounted on both ends of the antenna 13. .

An adhesive is applied to the forming surface of the inlet 12E, and as shown in FIG.
It is attached to the inlet attachment area of each RF-ID form in the form 11. Therefore, RF
-The barcode 18 is visually recognized on the ID form. The barcode 18 has information associated with the writing information to the IC module 14 mounted on the inlet 12E.

FIG. 9 is a block diagram showing the sixth embodiment of the RF-ID form according to the present invention. FIG. 9 (A) shows the RF-ID foam sheet 11A before attachment of the inlet, FIG. 9 (B) shows the inlet 12F to be attached,
FIG. 9C shows a continuous RF with the inlet 12F attached.
-It shows the ID form 11. In FIG. 9 (A), the RF-ID foam sheet 11A before attachment of the inlet, which is a predetermined portion inside the antenna 13 of the inlet to be attached in the inlet attachment area 16 to which the inlet is attached. The bar code 19 is formed by printing, printing or the like so that

On the other hand, in FIG. 9B, the inlet 1
In 2F, a transparent film is used as the base material, and the antenna 13 is formed on the film base material.
The IC modules 14 are electrically connected and mounted on both ends of the device 3. An adhesive is applied to the surface of the inlet 12F on which it is formed, and as shown in FIG.
It is attached to the inlet attachment area 16 of each RF-ID form in the ID form 11. Therefore, the barcode 19 is visible on the RF-ID form.

Here, FIG. 10 shows the RF of FIGS. 8 and 9.
-A block diagram of an RF-ID inspection system for inspecting an ID form. Inspection system 21 shown in FIG.
Is a BCR (bar code reader) 26B as the code recognizing means 26, and other configurations are the same as those in FIG. In this case, the data memory 63 includes the inlets 12 in the RF-ID form 11.
When the unique information is stored in the memory 42 of F, the data associated with the barcodes 18 and 19 is stored.

Therefore, FIG. 11 shows a flowchart of the inspection process in FIG. In FIG. 11, first of all, the drive amount of the RF-ID foam (inlet 12X) to be inspected among the RF-ID foams 11 sequentially supplied onto the conveyor belt 22 to the inspection position is set by the control unit 61. Based on the command, the transport drive control unit 69 causes the IF unit 71 to
It outputs to the conveyance drive part 51 via (S11).

The BCR 26B is the inlet 12 to be inspected.
When the X bar codes 18 and 19 are read, the controller 61 stops the conveyor belt 22 via the conveyor drive controller 69 and the conveyor driver 51, and the antenna drive controller 70 instructs the controller 61 to instruct. Inspection position inlet 1
The drive amount (Y) for positioning the shield member 23 and the system-side antenna 25 at the lower center with respect to 2X is the Y-direction drive amount of the antenna drive unit 52, and the system-side antenna 25 is used as the inlet 12X (antenna 13). On the other hand, the drive amount (Z) that is the basic distance is output as the Z-direction drive amount (S12). 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 read barcodes 18 and 19
The transmission data (identification information) for the inspection target associated with the information of (1) is acquired from the data memory 63 and transmitted to the inlet 12X of the inspection target (S13). The inlet 1
When there is a response from 2X (transmission of reply data) (S14), the reply data is received and the inspection processing unit 6
In step 2, the transmission data and the reception data are matched (S15). In the matching result (S15),
When they match, it is determined as a good product (S16), and when they do not match, it is determined as a defective product (S17). In addition, the above S14
If there is no response, the inlet 12X is determined to be defective as the IC module 14 is defective (S1).
7).

If the inlet 12X is a defective product and the inlet 12X is marked, the control unit 61 instructs the marker 27 to mark the inlet 12X which is determined to be defective in S17. Then, these determination results are stored in the data memory 63 (S18).

Then, the next inlet 12X to be inspected
If it is detected (S19), the inlet 12X
The determination result is stored in the data memory 63 by repeating S11 to S18 (S18). Then, the next inlet 12X to be inspected is not detected, and all the inlets 12X to be inspected are inspected.
When it is stored in No. 3, the inspection result is appropriately displayed on the display unit 72 (S20). The inspection results are displayed for each inlet 12X or a predetermined number of inlets 1X.
You may perform it for every 2X inspection result.

In this way, the timing marks 15,
The RF-ID can also be obtained by forming the barcodes 18 and 19 in place of 17 in the inlet attachment portion in a visible state.
The inlet at the time of inspection can be detected without performing unnecessary printing or printing on a portion other than the inlet sticking area in the form, and the quality inspection of the RF-ID foam (inlet 12X) corresponding to this can be performed. Is what you can do.

[0055]

As described above, according to the present invention, the RF-
A predetermined code is formed in the area where the inlet is attached to the ID form, and after the code recognition means recognizes the code, the processing unit transmits predetermined information to the inlet to be inspected through the system-side antenna. Adhering the inlet on the RF-ID foam by determining whether the inlet is good or bad according to the response from the inlet and controlling at least the conveyance by the conveying means according to the recognition of the code by the code recognizing means. It is possible to detect the inlet at the time of inspection without performing unnecessary printing or printing on a portion other than the area.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a first embodiment of an RF-ID form according to the present invention.

FIG. 2 R for inspecting an RF-ID form according to the present invention
It is a schematic perspective view of the inspection system of F-ID.

FIG. 3 R for inspecting an RF-ID form according to the present invention
It is a block block diagram of the inspection system of F-ID.

FIG. 4 is a flowchart of an inspection process of the RF-ID inspection system in FIGS. 2 and 3.

FIG. 5 is a configuration diagram of a second embodiment of an RF-ID form according to the present invention.

FIG. 6 is a configuration diagram of a third embodiment of an RF-ID form according to the present invention.

FIG. 7 is a configuration diagram of a fourth embodiment of an RF-ID form according to the present invention.

FIG. 8 is a configuration diagram of a fifth embodiment of an RF-ID form according to the present invention.

FIG. 9 is a configuration diagram of a sixth embodiment of an RF-ID form according to the present invention.

FIG. 10 is a block diagram of an RF-ID inspection system for inspecting the RF-ID forms of FIGS. 8 and 9;

11 is a flowchart of the inspection process in FIG.

[Explanation of symbols]

11 RF-ID form 12 RF-ID inlet 13 antennas 14 IC module 15,17 Timing mark 16 Inlet attachment area 18,19 barcode 21 RF-ID inspection system 22 Conveyor belt 25 System side antenna 26 Code Recognition Means 32 Inspection processing means

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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 communication is performed with respect to the inlet attached to the RF-ID form to be inspected, which is conveyed to an inspection position by a predetermined conveying means, An RF-ID inspection system for determining quality, wherein a predetermined code is formed in a region of the RF-ID form to which the inlet is attached, and the R is conveyed.
Code recognition means for recognizing the code in the inlet sticking area of the F-ID form, a system-side antenna for performing communication with the inlet, and a predetermined antenna for the inlet to be inspected via the system-side antenna A processing unit that transmits information, determines whether the inlet is good or bad in response to a response from the inlet, and controls at least the transport by the transport unit according to the recognition of the code by the code recognition unit. RF-ID inspection system characterized by: 2. The RF-ID inspection system according to claim 1, wherein the formed code is a bar code associated with a timing mark or information written in the IC module, and the code recognizing means. , An RF-ID inspection system, which is a mark detection sensor or a bar code reader. 3. The RF-ID inspection system according to claim 1 or 2, wherein the code formed of the predetermined material is invisible in the state of the RF-ID foam as a timing mark. , The code recognition means,
An RF-ID inspection system, which is a light transmissive or proximity sensor. 4. The RF-ID inspection system according to claim 1 or 2, wherein the code formed of the predetermined material is a timing mark and is visibly formed in the state of the RF-ID foam. , The code recognition means,
An RF-ID inspection system, which is a light transmission type, light reflection type, or proximity type sensor. 5. An RF-I to be inspected in the RF-ID inspection system according to claim 1.
An RF-type D-form, wherein the predetermined code is formed in a region to which the inlet is attached.
ID form. 6. The RF-ID form according to claim 5, wherein the code is the inlet base material or the RF-ID form.
RF-characterized in that it is formed on an ID foam substrate
ID form.