JP2013196052A - Inspection device and inspection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently inspect RFID tags arranged in a plurality of arrays, by one reader.SOLUTION: A shield part 23 has inspection windows 24 each of which corresponds to each of a plurality of arrays of RFID tags and allows communication between one RFID tag 11 in the corresponding array and a reader 21. With respect to each array of the plurality of arrays, the position of the inspection window 24 corresponding to the array is so set that, when an RFID tag 11 is put above the inspection window 24 corresponding to the array so that it can communicate with the reader 21, partial areas of RFID tags 11 having such sizes that the RFID tags 11 cannot communicate with the reader 21 are put above all of the other inspection windows 24.

Description

  The present invention relates to an inspection apparatus and an inspection method for inspecting an RFID tag.

  In recent years, the use of RFID (Radio Frequency Identification) tags (wireless tags) has become widespread. RFID tags have become popular especially in the field of logistics as an alternative to barcodes. In the RFID technology, a radio wave having a specific frequency is output from a reader toward the RFID tag, an electric circuit of the RFID tag is driven by the radio wave, and a reader receives a response signal emitted from the RFID tag. Thereby, the reader can communicate with the RFID tag.

  Before such RFID tags are generally shipped, non-defective / defective products are inspected based on a response signal from the RFID tag to an interrogation signal from a reader (see Patent Documents 1 and 2). For example, Patent Document 2 describes a method for inspecting a non-contact IC tag by passing a non-contact IC tag connecting body connected in a line in a row between the antenna surface of a reader and the surface of a passive antenna. Yes.

  However, in the technique described in Patent Document 2, non-contact IC tags arranged in a row are inspected using a single reader. Therefore, when inspecting non-contact IC tags arranged in a plurality of columns, a reader is provided for each column, and a method of inspecting a non-contact IC tag in a corresponding column by each reader and one reading A method of inspecting by sequentially moving the machine so as to overlap with the non-contact IC tags belonging to each column is conceivable. However, in the former method, since a plurality of readers are provided, the inspection speed increases, but the cost for the readers increases. On the other hand, although the latter method requires only one reader, a complicated mechanism for moving the reader is necessary, and the inspection speed is slow because the reader is moved.

  Therefore, in Patent Document 3, when a plurality of RFID tags are read with a single reader and a problem is found, the defective tags are shielded one by one or cumulatively by the shielding unit. An inspection method for finding out the above is disclosed. In the technique described in Patent Document 3, data of a plurality of RFID tags is read by one reader, and if there is no problem with all the data, it can be determined that all of the plurality of RFID tags are non-defective, and inspection efficiency is high. Become.

JP 2010-250443 A (released on November 4, 2010) JP 2007-200164 A (released on August 9, 2007) JP 2008-181477 A (released on August 7, 2008)

  However, in the technology of Patent Document 3, if even one RFID tag has a problem, in order to identify it, a defective tag can be identified by shielding a plurality of RFID tags one by one or cumulatively. It is necessary to find out. In this case, it is necessary to move the shielding part in order to shield each of the plurality of RFID tags by the shielding part, and the mechanism for the movement becomes complicated. Further, the plurality of RFID tags are inspected a plurality of times, and there is a problem that the inspection efficiency deteriorates.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an inspection apparatus and an inspection method capable of efficiently inspecting RFID tags arranged in a plurality of rows by one reader. And

  In order to solve the above problems, an inspection apparatus according to the present invention is an inspection apparatus that inspects the RFID tags while conveying RFID tags arranged in a plurality of rows along a column direction, and arranged in the plurality of rows. A reader that is installed at a predetermined position facing the RFID tag, and is capable of communicating with the RFID tags arranged in the plurality of rows at the predetermined position, and the RFID tag and the reader arranged in the plurality of rows. And a shield part that blocks communication between the RFID tag and the reader, and the shield part corresponds to each column of the plurality of columns, and one RFID tag belonging to the column And an inspection window that can communicate with the reader, and for each of the plurality of rows, one RFID tag belonging to the row can communicate with the reader in the inspection window corresponding to the row State In each row, the RFID tags do not overlap all other inspection windows, or are part of the RFID tag and overlap with a partial area of a size that cannot communicate with the reader. The position of the corresponding inspection window is set.

  According to the above configuration, when the RFID tag of the row is superimposed on the inspection window corresponding to a certain row in a state where it can communicate with the reader, the RFID tag does not overlap with the other inspection window, or communication with the reader is performed. Only impossible partial areas are overlaid. Thereby, it becomes possible to communicate with only one RFID tag, and the quality of the RFID tag can be inspected. When the inspection of the RFID tag in a certain row is completed, the RFID tag in the other row can be inspected by superimposing the RFID tag in the other row on the inspection window corresponding to the row so as to be able to communicate with the reader. it can. In this manner, it is possible to sequentially inspect the RFID tags in a plurality of rows one by one using one reader and without moving the reader.

  In addition, in order to inspect the next RFID tag after the inspection of one RFID tag is completed, it is necessary to transport the RFID tags arranged in a plurality of rows. The distance between the RFID tag located upstream of the inspection window and the inspection window closest to the inspection window is sufficient. Therefore, the time required for conveyance is shortened.

  As described above, an inspection apparatus capable of efficiently inspecting RFID tags arranged in a plurality of rows by one reader can be realized.

  Further, the inspection apparatus according to the present invention is configured so that the RFID tags arranged in the plurality of rows sequentially overlap with the plurality of inspection windows corresponding to the plurality of rows so that one RFID tag can communicate with the reader. It is preferable to provide a conveyance control unit that conveys the tag.

  According to said structure, it test | inspects, conveying a RFID tag so that one RFID tag may overlap with a reader | reader sequentially in the state which can be communicated with respect to a some test | inspection window. Thereby, the RFID tag can be efficiently transported.

  Further, in the inspection apparatus of the present invention, it is preferable that the plurality of rows are two rows, and the distance between the reader and the inspection window corresponding to each row is equal.

  According to the above configuration, since the distance between the inspection window and the reader in each row is equal, the distance between the RFID tag superimposed on each inspection window and the reader is also equal. As a result, the inspection accuracy for each column can be made equal.

  Furthermore, in the inspection apparatus of the present invention, the RFID tags arranged in the plurality of rows are arranged at a predetermined pitch along the row direction, and are also arranged in a direction perpendicular to the row direction. When k is set, the inspection window corresponding to each of the plurality of rows is shifted in the row direction by 1 / k of the predetermined pitch, and the transfer control unit moves the RFID tags arranged in the plurality of rows to the predetermined row. It is preferable to convey by 1 / k of the pitch.

  According to the above configuration, the conveyance amount of the RFID tag for inspecting one RFID tag after the inspection of one RFID tag is always the same, and the conveyance control is easily performed.

  Furthermore, in the inspection apparatus according to the present invention, the shield part is a notch part in which, for each of the plurality of inspection windows, the shield part is not continuous along at least a part of the periphery of the inspection window along the circumferential direction of the inspection window. It is preferable to have.

  According to said structure, since the shield part has a notch part, the circumference | surroundings of an inspection window are not cyclic | annular, and a big eddy current does not generate | occur | produce by the change of the magnetic flux by the signal from a reader. That is, it is possible to prevent the electromagnetic induction that cancels the signal from the reader from occurring in the shield part.

  The inspection method of the present invention is an inspection method for inspecting the RFID tag while conveying the RFID tags arranged in a plurality of rows along the column direction, and is opposed to the RFID tags arranged in the plurality of rows. A reader that communicates with the RFID tag is installed at a predetermined position where it can communicate with the RFID tags arranged in the plurality of rows, and the RFID tag is disposed between the RFID tags arranged in the plurality of rows and the reader. And a shield part for blocking communication between the reader and the reader, and the shield part can communicate with one RFID tag belonging to the row and the reader corresponding to each row of the plurality of rows. For each row of the plurality of rows, when one RFID tag belonging to the row is overlapped on the inspection window corresponding to the row in a state where it can communicate with the reader, all of the rows Other tests The position of the inspection window corresponding to each row is set so that the RFID tag does not overlap with the window, or is a part of the RFID tag and overlaps a partial area of a size that cannot communicate with the reader. The RFID tags arranged in the plurality of rows are conveyed so that one RFID tag sequentially overlaps the plurality of inspection windows corresponding to the plurality of rows in a state where communication with the reader is possible, and the reading is performed. The RFID tag stacked on the inspection window is inspected in a state where communication with the reader is possible based on a response signal from the RFID tag by the machine.

  Also with the above configuration, it is possible to realize an inspection method capable of efficiently inspecting RFID tags arranged in a plurality of rows by one reader.

  As described above, according to the inspection apparatus and the inspection method of the present invention, there is an effect that RFID tags arranged in a plurality of rows can be efficiently inspected by one reader.

It is a perspective view which shows the sheet | seat in which the RFID tag which is a test object is arrange | positioned in multiple rows. It is a top view of the sheet | seat shown in FIG. It is the schematic which shows the inspection apparatus which concerns on one Embodiment of this invention. It is a figure which shows the positional relationship of a shield part and RFID tag when it sees from a reader. It is a figure which shows the flow of the inspection method which concerns on one Embodiment of this invention. It is a figure which shows the shield part which concerns on a modification. It is a figure which shows a magnetic field when an annular shield part is used. It is a figure which shows the RFID tag used in the verification experiment of test | inspection performance. It is a figure which shows the example of a test | inspection of the RFID tag shown in FIG. It is a figure which shows the positional relationship of the test | inspection window of a shield part, and a reader.

  Hereinafter, an inspection apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.

<Inspection target>
FIG. 1 is a perspective view showing RFID tags arranged in a plurality of rows to be inspected by the inspection apparatus of the present embodiment. As illustrated, the RFID tags 11 are formed on the sheet 10 in a state of being aligned in a plurality of rows along the longitudinal direction of the sheet 10. That is, the row direction of the RFID tag 11 and the longitudinal direction of the sheet are the same. In addition, the sheet | seat 10 is wound by roll shape as shown in figure, and is pulled out in the case of an inspection.

  FIG. 2 is a top view of the sheet on which the RFID tag is formed. As shown in the drawing, the plurality of RFID tags 11 are arranged in a plurality of rows with a predetermined row interval a without overlapping each other. In each column, the RFID tags 11 are arranged side by side at a predetermined pitch b. In the present embodiment, as illustrated, the RFID tags 11 are also arranged in a direction perpendicular to the column direction X. That is, the coordinates in the column direction X of the position where the RFID tag 11 is present are the same in any of a plurality of columns. In the present embodiment, the RFID tags 11 are arranged in two rows of the first row and the second row, but the number of rows is not limited in the present invention. In the following description, the number of columns in which the RFID tag 11 is arranged is two.

  In the present embodiment, the RFID tags 11 are formed in a plurality of rows on the sheet 10, but the present invention is not limited to this. For example, the RFID tags 11 may be arranged on a transport belt in a plurality of rows along the transport direction.

<Outline of inspection device>
FIG. 3 is a schematic view showing the inspection apparatus of the present embodiment. The inspection apparatus 20 according to the present embodiment includes a reader 21, an inspection plate 22 including a shield unit 23, an imaging unit 25, a conveyance control unit 26, a conveyance unit 27, and a determination unit 28.

  The reader 21 is fixedly installed on the pedestal 30 at a position facing the RFID tags 11 arranged in a plurality of rows and separated by a predetermined distance. The reader 21 transmits an inspection signal toward the RFID tag 11 positioned above, and receives a response signal from the RFID tag 11. The reader 21 sends a response present signal to the determination unit 28 when a response signal is received, and sends a no response signal to the determination unit 28 when no response signal is received. The reader 21 transmits an inspection signal and receives a response signal in the communication area 21a on the upper surface thereof. In the present embodiment, the entire upper surface of the reader 21 is a communication area 21a.

  The conveyance unit 27 conveys the sheet 10 in which the RFID tags 11 are arranged in a plurality of rows in a predetermined conveyance direction Y. The transport direction Y is the same as the row direction X of the RFID tag 11 (see FIG. 2). Therefore, the RFID tag 11 is transported along the column direction X.

The inspection plate 22 is fixed to a position above the reader 21 and a predetermined distance away from the reader 21, and is used to place the sheet 10 on which the RFID tags 11 are arranged in a plurality of rows on the upper surface. . Thereby, the distance between the RFID tag 11 and the reader 21 can be kept substantially constant. The distance between the inspection plate 22 and the reader 21 is the RFI to be inspected.
It is appropriately set according to the performance required for the D tag 11. Then, the sheet 10 is transported in the transport direction Y on the inspection plate 22 by the transport unit 27.

  Further, a shield portion 23 for blocking an inspection signal from the reader 21 is formed on the upper surface of the inspection plate 22. The shield unit 23 communicates the inspection signal and the response signal only between one RFID tag 11 to be inspected and the reader 21, so that the RFID tag 11 other than the RFID tag to be inspected and the reader This is for cutting off communication with the terminal 21. The present embodiment is characterized in that the shield portion 23 has a shape for sequentially inspecting the RFID tags 11 arranged in two rows one by one.

  That is, the shield part 23 is formed in a region facing (overlapping) the reader 21, a predetermined region on the upstream side in the transport direction Y of the RFID tag 11 from the region, and a predetermined region on the downstream side in the transport direction Y from the region. Has been. The sizes of the predetermined areas on the upstream side and the downstream side in the transport direction Y are determined according to the direction and distance in which the RFID tag 11 and the reader 21 can communicate with each other. That is, the shield part 23 is formed at least in an area where communication with the reader 21 is possible. As a result, it is possible to prevent normal inspection from being impossible due to the influence of communication with RFID tags 11 other than one RFID tag 11 to be inspected.

  FIG. 4 is a diagram illustrating a positional relationship between the shield unit and the RFID tag when viewed from the reader. In FIG. 4, the illustration of the inspection plate 22 is omitted for easy understanding of the positional relationship between the shield part 23 and the RFID tag 11. In FIG. 4, the position of the reader 21 is indicated by a broken line so that the positional relationship between the reader 21, the shield part 23, and the RFID tag 11 can be understood. Moreover, the A-A 'line | wire in FIG. 4 has shown the cross section shown in FIG.

  As shown in FIG. 4, in the present embodiment, the shield portion 23 overlaps the first shield portion 23 a disposed so as to overlap the RFID tag 11 in the first row and the RFID tag 11 in the second row. The second shield part 23b is arranged. Each of the first shield part 23a and the second shield part 23b includes an area facing the reader 21, an area extending upstream from the area in the RFID tag transport direction Y, and an area extending downstream. And have.

  The shield unit 23 is an area facing the reader 21 for each row of the RFID tags 11 in a plurality of rows, and shields the RFID tag 11 and the reader 21 so that they can communicate with each other in the passage region of the row. Has an inspection window 24 that does not exist. The inspection window 24 has a size slightly larger than that of the RFID tag 11. Accordingly, the reader 21 can inspect the RFID tag 11 that is located on the inspection window 24 and overlaps the entire area of the inspection window 24 as an inspection object.

  Here, since the shield part 23 has the inspection window 24 corresponding to each of a plurality of rows, a plurality of inspection windows 24 are formed. The positions of the plurality of inspection windows 24 are set so that only the RFID tag 11 positioned on any one of the inspection windows 24 is an inspection target. That is, for each row of the plurality of rows, when the entire region of one RFID tag 11 of the row is overlaid on the inspection window 24 corresponding to the row, does the RFID tag 11 not overlap all the other inspection windows 24? Alternatively, the position of the inspection window corresponding to each column is set so that only a partial area that is a part of the RFID tag 11 and cannot communicate with the reader 21 overlaps. The RFID tag 11 whose entire area overlaps the inspection window 24 is an inspection target.

In the present embodiment, as shown in FIG. 4, the shield part 23 includes a first inspection window 24a formed in the first shield part 23a and a second inspection window 24b formed in the second shield part 23b. Have. The first inspection window 24a is formed at a position shifted from the second inspection window 24b on the downstream side in the transport direction Y by ½ of the pitch b in the RFID tag 11. Here, as described above, the RFID tags 11 are also arranged in a direction perpendicular to the column direction. Therefore, as shown in FIG. 4, when the entire region of one RFID tag 11 belonging to the second row overlaps the second inspection window 24b corresponding to the second row, the first inspection corresponding to the first row Only a partial area of the RFID tag 11 in the first row overlaps the window 24a.

  Further, as shown in FIG. 10, the midpoint O between the center M of the first inspection window 24a and the center N of the second inspection window 24b overlaps the center of the reader 21 (center of the communication area 21a). The positions of the first inspection window 24a and the second inspection window 24b are preferably set. In other words, the reader 21 has the center M of the first inspection window 24a and the second inspection window 24b out of the points where the distance between the center M of the first inspection window and the center N of the second inspection window is equal on the upper surface of the pedestal. It is preferable that the center is located on the point having the shortest distance from the center N. As a result, the reader 21 can communicate at the same distance for both the RFID tag 11 positioned above the first inspection window 24a and the RFID tag 11 positioned above the second inspection window 24b. It can be inspected with accuracy.

  The inspection plate 22 also has an opening at the same position as the inspection window 24 of the shield portion 23. Thereby, the communication between the RFID tag 11 and the reader 21 can be more reliably performed.

  In this embodiment, since the entire upper surface of the reader 21 is the communication area 21a, the position of the inspection window 24 is set so that the middle point O overlaps the center of the reader 21, but the communication area 21a is If the upper surface of the reader 21 is decentered, the position of the inspection window 24 may be set so that the middle point O overlaps the center of the communication area 21a.

  The imaging unit 25 images the first inspection window 24 a and the second inspection window 24 b from below the inspection plate 22, and sends the captured image to the conveyance control unit 26.

  The conveyance control unit 26 controls the conveyance unit 27 based on a conveyance instruction from the determination unit 28 to convey the sheet 10 on which the RFID tag 11 is formed. The conveyance control unit 26 receives from the determination unit 28 a first conveyance instruction that is an instruction to superimpose the RFID tag 11 on the first inspection window 24a. Upon receipt of the first conveyance instruction, the conveyance control unit 26 conveys the sheet 10 while analyzing the captured image, and determines that the entire area of one RFID tag 11 is within the first inspection window 24a. The conveyance of the sheet 10 is stopped, and a determination start instruction is sent to the determination unit 28. Further, the transport control unit 26 receives from the determination unit 28 a second transport instruction that is an instruction to superimpose the RFID tag 11 on the second inspection window 24b. Upon receiving the second conveyance instruction, the conveyance control unit 26 conveys the sheet 10 while analyzing the captured image, and determines that the entire area of one RFID tag 11 is within the second inspection window 24b. The conveyance of the sheet 10 is stopped, and a determination start instruction is sent to the determination unit 28.

The determination as to whether or not the entire area of one RFID tag 11 overlaps in the inspection window 24 may be as follows, for example. That is, the imaging unit 25 captures an image in a state where the entire area of one RFID tag 11 overlaps the first inspection window 24a, and the captured image is stored in the transport control unit 26 in advance as a first reference image. deep. Similarly, the imaging unit 25 captures an image in a state where the entire area of one RFID tag 11 overlaps the second inspection window 24b, and the captured image is stored in advance in the transport control unit 26 as a second reference image. Keep it. When the first transport instruction is received, the transport control unit 26 obtains the degree of coincidence between the captured image captured by the image capturing unit 25 and the first reference image. What is necessary is just to judge that the whole area | region of the RFID tag 11 has overlapped on the 1 test | inspection window 24a. Similarly, when receiving the second conveyance instruction, the conveyance control unit 26 obtains the degree of coincidence between the captured image captured by the imaging unit 25 and the second reference image, and if the degree of coincidence is equal to or greater than a predetermined threshold, What is necessary is just to judge that the whole area | region of the RFID tag 11 has overlapped on the 2nd test | inspection window 24b.

  The determination unit 28 determines whether the RFID tag 11 is a good product or a defective product. The determination unit 28 alternately determines the RFID tags 11 in the first column and the second column. That is, the determination unit 28 determines one of the RFID tags 11 in the second column after determining one of the RFID tags 11 in the first column, and determines one of the RFID tags 11 in the second column. Determines one of the RFID tags 11 in the first column.

  The determination unit 28 sends a first conveyance instruction to the conveyance control unit 26 when inspecting the RFID tags 11 in the first row. Here, as described above, the first inspection window 24 a and the second inspection window 24 b are shifted by ½ of the pitch b along the conveyance direction of the sheet 10. Therefore, when the conveyance control unit 26 receives the first conveyance instruction in a state where the entire area of the RFID tag 11 overlaps the second inspection window 24b, the entire area of the next RFID tag 11 belonging to the first row is The sheet 10 is conveyed by ½ of the pitch b so as to overlap the first inspection window 24a. When the determination unit 28 receives a determination start instruction from the conveyance control unit 26, the determination unit 28 determines whether or not reception with a response is received from the reader 21 during a predetermined period. When receiving a response signal within a predetermined period, the determination unit 28 determines that the RFID tag 11 to be inspected is a non-defective product. On the other hand, when the determination unit 28 does not receive a response signal within a predetermined period, the determination unit 28 determines that the RFID tag 11 to be inspected is a defective product.

  Similarly, the determination unit 28 sends a second conveyance instruction to the conveyance control unit 26 when inspecting the RFID tags 11 in the second row. Also in this case, when the second conveyance instruction is received in a state where the entire area of the RFID tag 11 is overlapped in the first inspection window 24a, the sheet 10 is conveyed by ½ of the pitch b. When the determination unit 28 receives a determination start instruction from the transport control unit 26, the determination unit 28 determines whether or not a response presence signal is received from the reader 21 during a predetermined period, and according to the result, the RFID tag 11 to be inspected is determined. Judge the quality.

  Note that the determination unit 28 alternately outputs the first conveyance instruction and the second conveyance signal. Thereby, the determination unit 28 determines the RFID tag 11 in the first row and the RFID tag 11 in the second row alternately. The determination unit 28 may automatically output the next conveyance instruction after determining the quality of the RFID tag 11. However, if the determination unit 28 determines that the RFID tag 11 is a defective product, the determination unit 28 notifies the operator of the fact, and even after receiving an inspection continuation instruction from the operator, the next conveyance instruction is output. Good.

<Flow of inspection method>
Next, the flow of the inspection method by the inspection apparatus 20 of this embodiment will be described with reference to FIG.

  First, a new sheet 10 (see FIG. 1) on which the RFID tag 11 is formed is installed in the inspection apparatus 20. At this time, the first RFID tag 11 is installed so as to be located on the upstream side in the transport direction from the inspection window 24 of the shield part 23.

In the present embodiment, as shown in FIG. 5, the second inspection window 24b is located upstream of the first inspection window 24a in the transport direction Y. Therefore, the determination unit 28 sends a second conveyance instruction to the conveyance control unit 26. As a result, as shown in the first row of FIG. 5, the entire region of the first RFID tag 11-b1 in the second row is transported so as to overlap the second inspection window 24b, and the determination unit 28 is transported by the transport control unit 26. Receives a judgment start instruction from At this time, if the RFID tag 11-b1 that overlaps the second inspection window 24b (that is, the RFID tag 11 to be inspected) is a non-defective product, the RFID tag 11-b1 can communicate normally. On the other hand, the first inspection window 24a located at a position shifted by 1/2 of the pitch b downstream of the second inspection window 24b in the transport direction Y has a partial area of the first RFID tag 11-a1 in the first row. Only overlap. Therefore, the reader 21 cannot communicate with the RFID tag 11-a1. Thereby, the reader 21 can confirm only the presence / absence of a response signal from the RFID tag 11-b1 overlapping the second inspection window 24b, and determines a signal (response present signal or no response signal) according to the confirmation result. To part 28. Then, the determination unit 28 determines that the RFID tag 11-b1 to be inspected is a non-defective product when it receives a response signal, and determines that it is a defective product when it receives a no response signal.

  Next, the determination unit 28 sends a first conveyance instruction to the conveyance control unit 26. As a result, as shown in the second row of FIG. 5, the entire region of the first RFID tag 11-a1 in the first row is transported so as to overlap the first inspection window 24a, and the determination unit 28 is transported by the transport control unit 26. Receives a judgment start instruction from At this time, if the RFID tag 11-a1 that overlaps the first inspection window 24a (that is, the RFID tag 11 to be inspected) is a non-defective product, the RFID tag 11-a1 can communicate normally. On the other hand, the partial region of the first RFID tag 11-b1 in the second row and the partial region of the second RFID tag 11-b2 in the second row overlap with the second inspection window 24b. For this reason, the reader 21 cannot communicate with the RFID tags 11-b1 and 11-b2 overlapping the second inspection window 24b. Thereby, the reader 21 can confirm only the presence / absence of a response signal from the RFID tag 11-a1 overlapping the first inspection window 24a, and determines a signal (response present signal or no response signal) according to the confirmation result. 28. The determination unit 28 determines that the RFID tag 11-a1 to be inspected is a non-defective product when it receives a response signal, and determines that it is a defective product when it receives a non-response signal.

  Thereafter, the determination unit 28 alternately outputs the second conveyance instruction and the first conveyance instruction, and alternately inspects the RFID tag 11-a in the second row and the RFID tag 11-b in the first row. That is, the RFID tags 11 arranged in two rows are conveyed so that one RFID tag 11 sequentially overlaps the first inspection window 24a and the second inspection window 24b in a state where communication with the reader 21 is possible. The RFID tag 11 is inspected one by one.

  That is, as shown in the third row of FIG. 5, when inspecting the second row k-th RFID tag 11-bk, the transfer control unit 26 determines that the entire region of the RFID tag 11-bk is the second inspection window. The conveyance is controlled so as to overlap with 24b. At this time, the first inspection window 24a includes a partial region of the first row k-1th RFID tag 11-a (k-1) and a partial region of the first row kth RFID tag 11-ak. It will overlap. Therefore, the reader 21 can normally communicate only with the second row k-th RFID tag 11-bk overlapping the second inspection window 24b. Then, based on the presence or absence of a response signal from the reader 21, the determination unit 28 can determine whether the second row k-th RFID tag 11-bk (that is, the RFID tag to be inspected) is good or bad.

  Further, as shown in the fourth row of FIG. 5, when inspecting the k-th RFID tag 11-ak in the first row, the transfer control unit 26 determines that the entire area of the RFID tag 11-ak is the first inspection window. It conveys so that it may overlap with 24a. At this time, in the second inspection window 24b, the partial region of the second column k-th RFID tag 11-bk and the partial region of the second column k + 1-th RFID tag 11-b (k + 1) overlap. . Therefore, the reader 21 can normally communicate only with the RFID tag 11-ak that overlaps the first inspection window 24a. Then, based on the presence / absence of a response signal from the reader 21, the determination unit 28 can determine whether the first column k-th RFID tag 11-ak (that is, the RFID tag to be inspected) is good or bad.

<Modification 1>
In the above description, it is assumed that the shield part 23 is composed of the first shield part 23a and the second shield part 23b arranged in each row. However, the shield part 23 which integrated the shield for every row | line | column may be sufficient. For example, as shown in FIG. 6, an integral shield portion 23 that overlaps all the plurality of rows may be formed. In this case, the shield part 23 exists also between rows.

  However, as shown in FIG. 6, the shield portion 23 surrounding each inspection window 24 does not exist over the entire circumference of the inspection window 24, and at least part of the periphery of the inspection window 24 has the inspection window 24. It is preferable that the notch part 29 where the shield part 23 does not continue is formed along the circumferential direction. The notch 29 has, for example, a slit shape, and can be said to be an opening for opening the ring.

  Usually, the shield part 26 is formed of a metal plate or the like. In the metal plate, the movement of electrons is easy, and when an electromagnetic wave that is an inspection signal from the reader 21 is received, a current that cancels the electromagnetic wave is generated by an electromotive force due to electromagnetic induction. Here, when the shield part is formed in an annular shape over the entire circumference of the inspection window as shown in FIG. 7A, it is an inspection signal from the reader 21 as shown in FIG. 7B. When the magnetic flux is changed, a relatively large eddy current is generated along the annular shape in the annular shield portion as shown in FIG. As a result, as shown in (d), the magnetic flux of the inspection signal is canceled out by the magnetic flux generated by the eddy current, which may prevent accurate inspection.

  On the other hand, as shown in FIG. 6, when the shield part 23 has the notch part 29, a relatively large eddy current along the annular shape as shown in FIG. The problem that the magnetic flux of the inspection signal is hindered so that the inspection cannot be performed is eliminated.

<Modification 2>
In the above description, the case where the RFID tags 11 are arranged in two rows on the sheet 10 is taken as an example. However, as described above, the number of columns in which the RFID tags 11 are aligned is not limited to 2, and may be 3 or more. Even if there are three or more rows, the shield portion 23 is provided with inspection windows 24 corresponding to each row. Then, for each of the plurality of columns, when the entire region of the RFID tag 11 is superimposed on the inspection window 24 corresponding to the column, the partial region is a part of the RFID tag and cannot communicate with the reader 21 It is only necessary that the position of the inspection window 24 corresponding to each column is set so that only the two overlap. As a result, when the entire region of the RFID tag 11 is overlaid on the inspection window 24 in one row, only the partial region of the RFID tag is overlaid on the inspection window 24 in the other row, and the entire region is overlaid on the inspection window 24. Only the received RFID tag 11 can be accurately inspected. By sequentially performing this inspection for each column, even the RFID tags 11 arranged in a plurality of columns are efficiently inspected by the inspection device 20 including one reader 21 without moving the reader 21. be able to.

  For example, in the case of a sheet on which RFID tags 11 arranged in k rows and arranged in a direction perpendicular to the row direction are formed, the inspection window 24 corresponding to each row can be shifted in the row direction by 1 / k of the pitch b. Good. Then, the sheet may be conveyed by 1 / k of the pitch b. However, when the entire region of the RFID tag 11 is overlaid on the inspection window 24 in a certain row, the RFID tag so that the partial region of the RFID tag 11 that overlaps the inspection window 24 in another row cannot communicate with the reader 21. It is necessary to appropriately set the pitch b in the column direction when forming 11 on the sheet.

  Further, in the case where a plurality of rows of three or more are arranged, it is difficult to make the distance between the center of the reader 21 and the center of each inspection window 24 equal. For this reason, the inspection accuracy of each column is slightly different depending on the distance between the center of the inspection window 24 corresponding to the column and the center of the reader 21. If the inspection can be performed so that the difference in inspection accuracy can be ignored, the present invention can be applied even when the inspection is arranged in a plurality of rows of three or more.

Alternatively, the output of the reader 21 may be adjusted for each column so as to compensate for the difference in distance between the center of each inspection window 24 and the center of the reader 21. For example, the inspection accuracy can be unified for each column by inspecting the RFID tag 11 close to the reader 21 with a weak output.

<Other variations>
In the above description, the inspection window 24 has a size larger than that of the RFID tag 11, and the entire area of the RFID tag 11 is conveyed so as to overlap the inspection window 24. However, the inspection window 24 has a size larger than an area (communication area) necessary for receiving an inspection signal and sending a response signal in the RFID tag 11, and all of the communication areas of the RFID tag 11 are included. May be conveyed so as to overlap the inspection window 24. That is, if there is a part in the RFID tag 11 that is not related to communication, it is not necessary to superimpose the part on the inspection window 24. As described above, when the RFID tag 11 is overlapped with the inspection window 24, it is not always necessary to overlap the entire area of the RFID tag 11, and the RFID tag 11 may be overlapped with the inspection window 24 while being able to communicate with the reader 21.

  Further, when the pitch b of the RFID tag 11 is more than twice the length of the RFID tag 11 in the column direction, the entire area of the RFID tag 11 overlaps the first inspection window 24a. The positions of the first inspection window 24a and the second inspection window 24b may be set so that the RFID tag 11 does not overlap.

  In the above description, it is assumed that the RFID tags 11 are arranged in the direction perpendicular to the column direction on the sheet 10 (see FIG. 2). However, the RFID tags 11 may be arranged with a shift of ½ of the pitch b between the columns. In this case, the shield part 23 only needs to be formed with inspection windows 24 arranged in a direction perpendicular to the column direction. Even in this case, when the entire region of the RFID tag is overlaid on the inspection window 24 corresponding to the row for each of the plurality of rows, only the partial region of the RFID tag overlaps with all the other inspection windows 24. Become.

<Verification of inspection performance>
It was verified whether or not the communication between the RFID tag 11 other than one RFID tag 11 to be inspected and the reader 21 can be reliably shielded by the shield part 23 having the plurality of inspection windows 24 described in the above description. .

  Here, as shown in FIG. It verified using the sheet | seat in which the eight RFID tags 11 of (1)-(8) were formed. In addition, No. It has been confirmed in advance that the RFID tag 11 of (2) is a defective product and the other RFID tags 11 are non-defective products. In the verification, an inspection plate having a shield portion 23 shown in FIG. 6 that matches the arrangement of the RFID tag 11 on the sheet was used.

  As shown in FIG. The eight RFID tags 11 of (1) to (8) were sequentially conveyed so that the entire area overlapped with the corresponding first inspection window 24a or second inspection window 24b, and the communication status with the reader 21 was confirmed. In this verification, the pedestal 30 was moved up and down, and the distance (communication possible distance) between the maximum reader 21 and the RFID tag 11 that can communicate with the RFID tag 11 was measured.

No. (1), No. Regarding the seven RFID tags 11 of (3) to (8), the communicable distance was normally measured within the range of variations caused by manufacturing variations and measurement errors of the RFID tags 11. On the other hand, no. When the entire area of the RFID tag 11 of (2) is overlapped on the second inspection window 24b, the reader 21 cannot communicate with the RFID tag 11 even if the reader 21 is moved to the upper limit where it contacts the inspection plate 22. It was impossible. No. When the entire area of the RFID tag 11 of (2) is overlaid on the corresponding second inspection window 24b, as shown in FIG. (1) and No. The partial areas of the RFID tag 11 in (3) overlap. However, since the communicable distance was not measurable, the non-defective product No. 1 in which the first inspection window 24a and the partial area overlap each other was obtained. (1) and No. It can be seen that communication with the RFID tag 11 of (3) is not established. Accordingly, it was confirmed that the communication between the RFID tag 11 other than one RFID tag 11 to be inspected and the reader 21 can be reliably shielded by the shield portion 23 of the present embodiment.

<Summary>
As described above, the inspection apparatus 20 is an apparatus that inspects the RFID tags 11 while transporting the RFID tags 11 arranged in a plurality of rows along the row direction. The inspection device 20 is installed at a predetermined position facing the RFID tags 11 arranged in a plurality of rows, and can be communicated with the RFID tags 11 arranged in the plurality of rows at the predetermined position. A shield unit 23 is provided between the RFID tag 11 and the reader 21 arranged in a row and blocks communication between the RFID tag 11 and the reader 21.

  However, the shield portion 23 has an inspection window 24 that allows communication between one RFID tag 11 belonging to the row and the reader 21 corresponding to each row of the plurality of rows. The position of the inspection window 24 corresponding to each column is such that one RFID tag 11 belonging to the column can communicate with the reader 21 in the inspection window 24 corresponding to the column for each column. When overlapped, all the other inspection windows 24 are set so that a partial area that is a part of the RFID tag 11 and cannot communicate with the reader 21 overlaps.

  Thereby, it becomes possible to communicate with only one RFID tag 11 to be inspected, and the quality of the RFID tag 11 can be inspected. When the inspection of the RFID tag 11 in a certain row is completed, the RFID tag 11 in the other row is superposed on the inspection window 24 corresponding to the row so as to be able to communicate with the reader 21, thereby the RFID tag 11 in the other row. Can be inspected. In this way, the RFID tags 11 in a plurality of rows can be sequentially inspected one by one using one reader 21 and without moving the reader 21.

  In addition, in order to inspect the next RFID tag 11 after the inspection of one RFID tag 11 is completed, it is necessary to convey the RFID tags 11 arranged in a plurality of rows. On the other hand, only the distance between the RFID tag 11 located on the upstream side in the transport direction and closest to the inspection window 24 and the inspection window 24 is sufficient. Therefore, the time required for conveyance is shortened.

  From the above, it is possible to efficiently inspect the RFID tags 11 arranged in a plurality of rows by one reader 21.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  In the above-described embodiments, the determination unit 28 and the conveyance control unit 26 of the inspection apparatus 20 are stored in a ROM (Read Only Memory), a RAM (Random Access Memory), or the like by a calculation unit such as a CPU (Central Processing Unit). It can be realized by executing a program stored in the means and controlling input means such as a keyboard, output means such as a display, or communication means such as an interface circuit. Therefore, various functions and various processes of the production line management apparatus according to the present embodiment can be realized simply by a computer having these means reading the recording medium storing the program and executing the program. In addition, by recording the program on a removable recording medium, the various functions and various processes described above can be realized on an arbitrary computer.

This recording medium includes a memory (not shown) for processing by a microcomputer,
For example, a ROM or the like may be a program medium, or although not shown, a program reading device is provided as an external storage device, and the program medium can be read by inserting a recording medium therein. May be.

  In any case, the stored program is preferably configured to be accessed and executed by the microprocessor. Furthermore, it is preferable that the program is read out, and the read program is downloaded to a program storage area of the microcomputer and the program is executed. It is assumed that this download program is stored in advance in the main unit.

  The program medium is a recording medium configured to be separable from the main body, such as a tape system such as a magnetic tape or a cassette tape, a magnetic disk such as a flexible disk or a hard disk, or a disk such as a CD / MO / MD / DVD. Fixed disk, IC card (including memory card), etc., or semiconductor ROM such as mask ROM, EPROM (Erasable Programmable Read Only Memory), EEPROM (Electrically Erasable Programmable Read Only Memory), flash ROM, etc. In particular, there are recording media that carry programs.

  In addition, if the system configuration is capable of connecting to a communication network including the Internet, the recording medium is preferably a recording medium that fluidly carries the program so as to download the program from the communication network.

  Further, when the program is downloaded from the communication network as described above, it is preferable that the download program is stored in the main device in advance or installed from another recording medium.

  The present invention can be applied to an inspection apparatus for inspecting an RFID tag.

10 sheet 11 RFID tag 20 inspection device 21 reader 22 inspection plate 23 shield part 23a first shield part 23b second shield part 24 inspection window 24a first inspection window 24b second inspection window 25 imaging part 26 shield part 26 transport control part 27 Conveying section 28 Judging section 29 Notch M Center N Center O Middle point X Row direction Y Conveying direction

Claims (6)

An inspection apparatus for inspecting the RFID tag while conveying RFID tags arranged in a plurality of rows along the row direction,
A reader installed at a predetermined position facing the RFID tags arranged in the plurality of rows and capable of communicating with the RFID tags arranged in the plurality of rows at the predetermined position;
A shield portion arranged between the RFID tags arranged in the plurality of rows and the reader, and a shield part for blocking communication between the RFID tag and the reader;
The shield portion has an inspection window corresponding to each row of the plurality of rows so that one RFID tag belonging to the row can communicate with the reader,
For each of the plurality of rows, when one RFID tag belonging to the row is overlapped with the reader in a state in which the reader can communicate with the reader, RFID tags are placed in all the other inspection windows. The position of the inspection window corresponding to each column is set so that the partial areas that do not overlap or are part of the RFID tag and cannot communicate with the reader overlap. Inspection device.   A conveyance control unit configured to convey the RFID tags arranged in the plurality of rows so that one RFID tag sequentially overlaps the plurality of inspection windows corresponding to the plurality of rows in a state where communication with the reader is possible; The inspection apparatus according to claim 1. The plurality of columns are two columns,
3. The inspection apparatus according to claim 1, wherein the distance between the reader and the inspection window corresponding to each column is equal. The RFID tags arranged in the plurality of rows are arranged at a predetermined pitch along the row direction, and are also arranged in a direction perpendicular to the row direction.
When the number of rows of the plurality of rows is k, the inspection window corresponding to each of the rows is shifted in the row direction by 1 / k of the predetermined pitch.
The inspection apparatus according to claim 2, wherein the conveyance control unit conveys the RFID tags arranged in the plurality of rows by 1 / k of the predetermined pitch.   The shield part has, for each of the plurality of inspection windows, a notch part in which the shield part is not continuous along the circumferential direction of the inspection window at least at a part of the periphery of the inspection window. 5. The inspection apparatus according to any one of 1 to 4. An inspection method for inspecting the RFID tag while transporting RFID tags arranged in a plurality of rows along the row direction,
A reader that communicates with the RFID tags is installed at a predetermined position facing the RFID tags arranged in the plurality of rows and capable of communicating with the RFID tags arranged in the plurality of rows,
Between the RFID tags arranged in the plurality of rows and the reader, a shield part for blocking communication between the RFID tag and the reader is installed,
The shield portion has an inspection window corresponding to each row of the plurality of rows so that one RFID tag belonging to the row can communicate with the reader,
For each of the plurality of rows, when one RFID tag belonging to the row is overlapped with the reader in a state in which the reader can communicate with the reader, RFID tags are placed in all the other inspection windows. The position of the inspection window corresponding to each column is set so that it does not overlap or is a part of the RFID tag, and the partial areas of a size that cannot communicate with the reader overlap.
The RFID tags arranged in the plurality of rows are conveyed so that one RFID tag sequentially overlaps the plurality of inspection windows corresponding to the plurality of rows in a state where communication with the reader is possible. An inspection method for inspecting an RFID tag superimposed on an inspection window in a state in which communication with the reader is possible based on a response signal from the RFID tag.

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