JP2009187318A - Rfid inspection system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent a communication failure due to a reflected electric wave, and to stably inspect communication, in an RFID (Radio Frequency Identification) inspection system for inspecting the communication of an RFID of an IC tag, an IC label or the like. <P>SOLUTION: In this RFID inspection system, an inspecting tool 17 has: an umbrella electric wave reflection part 17A with an inspection opening part 20A for positioning an RFID 22A to be inspected; and a planar electric wave reflection part 17B with an antenna opening part 20B for positioning an antenna part 15 opposite to the inspection opening part 20A, regularly reflecting, around the antenna opening part 20B, the electric wave reflected by the umbrella electric wave reflection part 17A. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an RFID inspection system that performs communication inspection of RFID such as an IC tag and an IC label.

  In recent years, non-contact type IC tags, IC labels, and the like called RFID (Radio Frequency Identification) have rapidly spread, and their use is also wide-ranging. Such an RFID is formed on a continuous sheet for manufacturing efficiency and is individually inspected at a corresponding frequency by a reader / writer. Therefore, generation of interference waves due to reflection of radio waves is generated on the RFID to be inspected. It is necessary to perform stable communication while suppressing this.

  Conventionally, at the time of communication inspection of RFID formed on a continuous sheet, a shield member as proposed in the following patent document is provided as a method for suppressing generation of interference waves due to reflection of radio waves on the RFID to be inspected. It is known.

  Here, FIG. 5 shows a configuration explanatory diagram of a conventional IC card communication inspection apparatus. In FIG. 5, an IC card communication inspection apparatus 101 is provided with a radio wave absorber 103 on the inner wall of a metal shield box 102, an opening 104 is formed in a portion corresponding to the IC card to be inspected, and the shield box A reader / writer 105 is provided in 102, and a communication inspection is performed on the IC card 106 to be inspected conveyed to the opening 104 by the conveying belt 107 to determine whether the IC card 106 is good or bad. .

JP 2004-272437 A

  However, the IC card communication inspection apparatus 101 disclosed in the above patent document can absorb the radio wave to be reflected from the reader / writer 105 by the radio wave absorber 103 provided in the shield box 102. Since the radio wave absorber 103 is also present around the opening 104 where the IC card 106 to be inspected is located, the radio wave is absorbed in the surrounding area, and the stability of the communication state cannot be maintained. There's a problem.

  Further, even if the radio wave absorber 103 is not provided only in the peripheral portion of the opening 104, in that case, the metal portion of the shield box 102 is exposed, and the radio wave is reflected at the portion. This causes a problem that a communication failure occurs.

  Accordingly, the present invention has been made in view of the above problems, and an object of the present invention is to provide an RFID inspection system capable of preventing a communication failure due to a reflected radio wave and enabling a stable communication inspection.

  In order to solve the above-described problems, the invention of claim 1 is an RFID inspection system in which a reader / writer communicates with an RFID including an IC module and an antenna to be inspected via an antenna unit to inspect the quality. An umbrella-shaped radio wave reflection portion having an inspection opening for positioning the RFID to be inspected, and the antenna portion is positioned opposite the inspection opening to surround the umbrella-shaped radio wave reflection It is set as the structure which has the jig | tool for a test | inspection provided with the planar radio wave reflection part which reflects regularly the radio wave reflected by the part.

  In the invention of claim 2, at least a radio wave absorber is provided above the RFID on the inspection jig.

  According to the present invention, an umbrella-shaped radio wave reflection portion in which an inspection opening for positioning an RFID to be inspected is formed, and an antenna portion is positioned opposite to the inspection opening and the umbrella-shaped radio wave reflection portion is disposed around the antenna portion. By providing an inspection jig with a planar radio wave reflector that regularly reflects the radio wave reflected by the antenna, the radio wave reflected by the umbrella-shaped radio wave reflector of the radio wave output from the antenna unit is a planar radio wave. Since the light is regularly reflected by the reflecting part, it can be in an interference state, and as a result, the radio wave other than the radio wave reaching the inspection opening is made to be in a steady state. It is possible to block communication, prevent communication failure due to reflected radio waves, and enable stable communication inspection regardless of the output from the reader / writer antenna unit. A.

Hereinafter, the best embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows a configuration diagram of an RFID inspection system according to the present invention. FIG. 1A is a configuration diagram of an RFID inspection system, and FIGS. 1B and 1C are configuration diagrams of an inspection jig. In FIG. 1 (A), the RFID inspection system 11 takes up a continuous sheet (21, described with reference to FIG. 2) in which an RFID module having an IC module and an antenna on the surface is continuously provided from a continuous sheet supply unit 12. For example, the continuous sheet take-up unit 13 is conveyed by rotational driving (the continuous sheet supply unit 12 may be rotationally driven auxiliary), and the RFID detection unit 14 and the reader / writer antenna unit are included in the conveyance path. 15. A stamper 16 is arranged.

  The arrangement position of the reader / writer antenna unit 15 becomes the inspection position in the transport path, the inspection jig 17 is arranged at the inspection position, and the holding rollers 18 and 19 are arranged on both sides of the inspection jig 17. That is, the continuous sheet supplied from the continuous sheet supply unit 12 passes through the vicinity of the RFID detection unit 14, is wound around the inspection jig 17 from the holding roller 18, changes its direction by the holding roller 19, and passes through the stamper 16. It becomes a conveyance path wound up by the continuous sheet winding unit 13.

  The RFID detection unit 14 is a sensor that detects an RFID to be inspected for the RFID being conveyed. The reader / writer antenna unit 15 is positioned below the inspection jig 17 (described later), for example, for communicating with RFID in an inspection discrimination means (not shown), and a conventional one can be used. Detailed description is omitted. The stamper 16 stamps an NG (for example, “x”) mark on the RFID that is determined to be defective as a result of the communication inspection.

  As shown in FIGS. 1B and 1C, the inspection jig 17 includes an umbrella-shaped radio wave reflection portion in which an inspection opening 20A for positioning the RFID (22A) to be inspected is formed. An antenna opening 20B for positioning the reader / writer antenna 15 facing the inspection opening 20A is formed, and a planar radio wave that regularly reflects the radio wave reflected by the umbrella-shaped radio wave reflection part 17A around the antenna opening 20B. The reflection part 17B is provided. That is, the umbrella-shaped radio wave reflection unit 17A is set with a curvature at which the radio wave transmitted from the reader / writer antenna unit 15 is incident so as to be regularly reflected by the planar radio wave reflection unit 17B.

  As the umbrella-shaped radio wave reflecting portion 17A and the planar radio wave reflecting portion 17B, a metal member such as stainless steel is adopted, and it is desirable that the umbrella-shaped radio wave reflecting portion 17B and the planar radio wave reflecting portion 17B be formed of a conductive material that can reflect radio waves and suppress transmission. In the present embodiment, the umbrella-shaped radio wave reflecting portion 17A and the planar radio wave reflecting portion 17B of the inspection jig 17 have been described as being integrated. However, even if they are separated, the same effect can be obtained. .

  Further, a covering portion 17C covered with a metal member may be provided integrally or freely attached to the reader / writer antenna portion 15 positioned below the antenna opening 20B as shown in the figure. As a result, the reader / writer antenna unit 15 can be positioned at the antenna opening 20B at the best portion of the radio wave output.

  The holding rollers 18.19 are disposed on both sides of the inspection jig 17, and are used for bringing the back surface of the continuous sheet into close contact with the inspection jig 17 on the umbrella-shaped radio wave reflection portion 17A. In other words, for example, the back surface of the continuous sheet is brought into close contact with the inspection jig 17 by the holding rollers 18 and 19 by the conveying force by the winding drive of the continuous sheet winding unit 13.

  Here, FIG. 2 shows an explanatory diagram of an example of an object to be inspected by the RFID inspection system of FIG. FIG. 2A is an explanatory view showing a state in which the continuous sheet is wound around the inspection jig, and FIG. 2B is an explanatory view of the continuous sheet. First, as shown in FIG. 2 (B), the inspection object is one in which, for example, RFIDs 22 are continuously attached in a row on a continuous sheet 21 of polyethylene terephthalate (PET) so as to be peeled at predetermined intervals.

  For example, the RFID 22 is formed by bonding copper foil onto a PET with an epoxy-based adhesive and forming each planar antenna by etching, and forming an IC module (IC chip or a predetermined circuit on the IC chip) between the antennas. Is mounted by reflow soldering or conductive adhesive, and is determined by the predetermined frequency (RFID antenna shape, etc.) between the antenna and the reader / writer antenna unit 15. Here, as the UHF band Communication) is performed. The RFID 22 has a predetermined resonance frequency depending on the shape, length, etc. of the antenna section, and receives the signal by resonating in response to the radio wave of the corresponding frequency from the reader / writer antenna section 15.

  As shown in FIG. 2A, the continuous sheet 21 provided with the RFID 22 is wound around the umbrella-shaped radio wave reflecting portion 17A of the inspection jig 17 via the holding roller 18, and is horizontally conveyed by the holding roller 19. Redirected to the path. Based on the detection by the RFID detection unit 14, the communication inspection is performed when only the RFID 22A is positioned in the inspection opening 20A formed in the umbrella-shaped radio wave reflection unit 17A of the inspection jig 17.

  FIG. 3 is an explanatory diagram of communication inspection using the inspection jig in FIG. In FIG. 3, the continuous sheet 21 wound around the umbrella-shaped radio wave reflecting portion 17 </ b> A of the inspection jig 17 is subject to inspection with the RFID 22 </ b> A positioned at the inspection opening 20 </ b> A. In the communication inspection, the RFID 22A to be inspected is received by resonating in response to the radio wave of the corresponding frequency (UHF band or HF band) from the reader / writer antenna unit 15, and is included in the radio wave from the reader / writer. In response to the command, data is transmitted from the RFID 22A, and pass / fail is determined.

  That is, the radio wave output from the reader / writer antenna unit 15 of the antenna opening 20B of the planar radio wave reflection unit 17B travels while spreading, and the radio wave 15A traveling directly to the RFID 22A (inspection opening 20A) to be inspected, and the others There is a radio wave (reflected wave) 15B reflected by the umbrella-shaped radio wave reflecting part 17A due to spreading, and the radio wave 15B reflected by the umbrella-shaped radio wave reflecting part 17A is specularly reflected (regularly reflected wave 15C) by the planar radio wave reflecting part 17B. .

  If the reflected wave 15B incident on the planar radio wave reflecting portion 17B is specularly reflected, the phase of the regular reflected wave 15C is reversed at this time, and the regular reflected wave 15C cancels the continuously incident reflected wave 15B. It becomes a state. Therefore, the radio wave output from the reader / writer antenna unit 15 is in an interference state other than the radio wave 15A traveling to the RFID 22A to be inspected (inspection opening 20A), that is, a steady state, and the reflected wave 15B and the regular reflected wave 15C are converted into the RFID 22A ( It is not incident on the inspection opening 20A).

  Thus, the radio wave reflected by the umbrella-shaped radio wave reflection unit 17A out of the radio wave output from the reader / writer antenna unit 15 located in the antenna opening 20B is regularly reflected by the planar radio wave reflection unit 17B. In other words, the radio wave other than the radio wave reaching the inspection opening 20A is in a steady state, so that the radio wave can be blocked without using a radio wave absorbing member or the like, and communication using reflected radio waves is possible. A failure can be prevented, and a stable communication test can be performed regardless of the magnitude of the output from the reader / writer antenna unit.

  Next, FIG. 4 shows another configuration diagram of the communication inspection in FIG. In FIG. 4, a shield material 31 is disposed above a predetermined number of RFIDs 22A, 22 on a continuous sheet 21 wound on an inspection jig 17, and a radio wave absorber 32 is provided on the inner surface of the RFID 22A, 22 side. It is a configuration. In the figure, the case of a reverse concave shape is shown for efficiency, but a plate shape may be used if the size is set appropriately.

  The shield material 31 may be a metal material made of the same material as that of the inspection jig 17, for example. As the radio wave absorber 32, for example, a non-electrically conductive material such as rubber or resin, or a high electrical resistor including magnetic particles having soft magnetic properties such as ferrite can be applied.

  The shield material 31 can reflect the radio waves from outside and avoid the influence on the RFID 22A to be inspected, and the radio wave absorber 32 absorbs radio waves that have passed through the continuous sheet 21 between the RFIDs 22A and 22. The influence on the RFID 22A to be inspected can be avoided by preventing the reflection by passing through the other. In that sense, it is sufficient that the radio wave absorber 32 is provided at least, and the shield material 31 ensures reliability.

  As described above, by providing at least the radio wave absorber 32 above the RFIDs 22A and 22 on the inspection jig 17, it is possible to further prevent communication failure due to reflected radio waves with respect to the RFID 22A to be inspected, and to stabilize Communication inspection can be made possible.

  The RFID inspection system of the present invention can be used for communication inspection performed in the RFID manufacturing process or at the user acceptance stage after shipment.

It is a block diagram of the RFID test | inspection system in this invention. It is explanatory drawing of an example of the object test | inspected with the RFID test | inspection system of FIG. It is explanatory drawing of the communication test | inspection by the test jig | tool in FIG. It is another block diagram of the communication test | inspection in FIG. It is structure explanatory drawing of the conventional IC card communication inspection apparatus.

Explanation of symbols

11 RFID inspection system 12 Continuous sheet supply unit 13 Continuous sheet take-up unit 14 RFID detection unit 15 Reader / writer antenna unit 16 Stamper 17 Inspection jig 17A Umbrella-shaped radio wave reflection unit 17B Planar radio wave reflection unit 18, 19 Holding roller 20A Inspection Opening 20B Antenna opening 21 Continuous sheet 22 RFID
31 Shield part 32 Radio wave absorption part

Claims (2)

An RFID inspection system in which a reader / writer communicates with an IC module to be inspected and an RFID including an antenna via an antenna unit to inspect the quality.
Provided with an umbrella-shaped radio wave reflection portion in which an inspection opening for positioning the RFID to be inspected is formed, and the antenna portion is positioned facing the inspection opening and reflected by the umbrella-shaped radio wave reflection portion in the vicinity thereof An RFID inspection system comprising an inspection jig provided with a planar radio wave reflecting portion for regular reflection of a transmitted radio wave.   2. The RFID inspection system according to claim 1, wherein at least a radio wave absorber is provided above the RFID on the inspection jig.

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