JP2009037416A - Structure for mounting antenna, joint member, and transmitting/receiving system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a structure for mounting an antenna to easily hold an antenna in close proximity to RFID tags attached to variously shaped objects. <P>SOLUTION: The structure for mounting an antenna is used for mounting an antenna part 1b on a mold 3 to which an RFID tag 25 is attached. The antenna part 1b is mounted on the mold 3 to face the RFID tag 25 across a joint member 31. Thus, even if the mold 3 is mounted on a press and fixed, the antenna part 1b and the RFID tag 25 can be kept in close proximity to each other. Thus during molding using the mold 3, information can easily be transmitted and received between the antenna part 1b and the RFID tag 25. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an antenna mounting structure, a joint member used in the antenna mounting structure, and a transmission / reception system using the antenna mounting structure.

  Conventionally, there is a technique for managing an object using an RFID tag. In general, when managing an object using an RFID tag, the RFID tag is fixed to an object to be managed, and a reader / writer installed at each destination of the object to be managed is used to store information in the RFID tag. Reading and writing are performed. When reading and writing information, it is necessary to bring the RFID tag and the reader / writer antenna close to each other in order to transmit and receive signals.

Patent Document 1 describes a method of writing data obtained during molding in an RFID tag fixed to the mold in real time in order to manage the mold for molding. In order to write the data obtained during molding to the RFID tag in real time, it is necessary to fix the RFID tag and the reader / writer in close proximity during molding. Therefore, the method described in Patent Document 1 is that an RFID tag is attached to the outer periphery of a mold, and a rod with an antenna attached is inserted into a hole formed in the mold holder and at a position facing the RFID tag. That's it.
JP 2005-138115 A

  In general, there are various shapes of molds attached to one molding machine. Therefore, in the technique of the above-mentioned Patent Document 1, it is necessary to adjust the arrangement of the holes for inserting the rods to which the antennas are attached when the shape of the mold is changed. In this case, it is necessary to adjust the position of the mold holder or change the mold holder. This is difficult to implement when handling molds of various shapes. In addition, even if the mold has the same shape, it is necessary to adjust the mounting position of the RFID tag or antenna in order to adjust the distance between the RFID tag and the antenna each time it is mounted on the molding machine. is there. Moreover, in the method described in Patent Document 1, the object to be managed is limited to the mold, and the versatility is low.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an antenna mounting structure that allows an antenna to be easily held in proximity to RFID tags attached to objects of various shapes. It is another object of the present invention to provide a transmission / reception system using a joint member used in the antenna mounting structure, an RFID tag and an antenna mounting structure.

  The antenna mounting structure of the present invention is an antenna mounting structure for mounting an antenna on an object to which an RFID tag is mounted, and the antenna is mounted so as to face the RFID tag via a joint member. It is attached to a target object.

  In the antenna attachment structure of the present invention, the antenna is attached to the attachment object so as to face the RFID tag via the joint member. Therefore, regardless of the shape of the attachment object, the antenna can be easily held in a state where the antenna is brought close to the RFID tag fixed to the attachment object. Further, even when the attachment target is attached to the installation mechanism and the position is fixed, the antenna and the RFID tag can be held in a close proximity. Therefore, information can be transmitted and received between the antenna and the RFID tag reliably and easily during work using the attachment object.

  Preferably, in the antenna mounting structure, the antenna can be detached from the mounting target. In this case, the antenna can be easily removed from the attachment object, and the attachment object can be transported to another location. Information can be transmitted and received between the RFID tag attached to the attachment object and another antenna installed at the transportation destination.

  Preferably, in the antenna mounting structure, the joint member has a cylindrical shape, the RFID tag is positioned inside the one opening side of the joint member, and the antenna is positioned inside the other opening side of the joint member. Thus, the RFID tag and the antenna are attached. In this case, the RFID tag and the antenna are accommodated in the joint member, and the RFID tag and the antenna can be protected.

  Preferably, in the antenna mounting structure, the joint member is formed of a non-metal. In this case, the joint member covers at least a part of the propagation path of the radio wave between the RFID tag and the antenna, so that it is possible to suppress the disturbance of the propagation environment such as the radio wave being reflected on the surrounding metal. In particular, when the joint member is cylindrical and signals are transmitted and received between the RFID tag and the antenna inside the cylindrical joint member, it is possible to prevent disturbance of the propagation environment such as reflection of radio waves on surrounding metal. it can. Therefore, the signal propagation environment can be kept good regardless of the surrounding metal arrangement. Therefore, the signal transmission / reception state between the RFID tag and the antenna can be kept good.

  Preferably, in the antenna mounting structure, the RFID tag is fixed to the mounting target by fixing the RFID tag to the head of the bolt and fixing the screw portion of the bolt to the mounting target. . In this case, the RFID tag can be easily and reliably attached to the attachment object.

  Further, in the antenna mounting structure, the mounting target may be a metal.

  The joint member of the present invention is a joint member for attaching an antenna to an attachment object to which an RFID tag is attached, an attachment part attached to the attachment object, and a holding part for holding the antenna so as to face the RFID tag. It is characterized by providing.

  According to the joint member of the present invention, the antenna can be attached to the attachment object so as to face the RFID tag attached to the attachment object. Thereby, it can be easily held at a predetermined distance in which the antenna is brought close to the RFID tag fixed to the attachment object, regardless of the shape of the attachment object. Therefore, even when the attachment object is attached to the installation mechanism and the position is fixed, information can be easily transmitted and received between the antenna and the RFID tag during the operation using the attachment object. it can.

  Preferably, the joint member is formed in a cylindrical shape, the attachment portion is one opening, the holding portion is the other opening, the RFID tag is located inside the one opening, and the other opening The RFID tag and the antenna are attached to the attachment object so that the antenna is located inside the part. In this case, the RFID tag and the antenna are accommodated in the joint member, and the RFID tag and the antenna can be protected.

  Preferably, the joint member is made of a nonmetal. In this case, the joint member covers at least a part of the propagation path of the radio wave between the RFID tag and the antenna, so that it is possible to suppress the disturbance of the propagation environment such as the radio wave being reflected on the surrounding metal. In particular, when the joint member is cylindrical and signals are transmitted and received between the RFID tag and the antenna inside the cylindrical joint member, it is possible to prevent disturbance of the propagation environment such as reflection of radio waves on surrounding metal. it can. Therefore, the signal propagation environment can be kept good regardless of the surrounding metal arrangement. Therefore, the signal transmission / reception state between the RFID tag and the antenna can be kept good.

  The transmission / reception system of the present invention includes an RFID tag fixed to an attachment object, a joint member that is formed in a cylindrical shape and attached to the attachment object so that the RFID tag is located inside one opening, An antenna attached to an object to be attached via the joint member so as to be positioned inside the other opening side of the joint member, and a reader / writer that reads and writes information from and to the RFID tag via the antenna. Features.

  According to the transmission / reception system of the present invention, the antenna can be attached to the attachment object so as to face the RFID tag via the joint member. This makes it easy to hold the antenna close to the RFID tag fixed to the mounting object at a predetermined distance regardless of the shape of the mounting object, and read / write information between the RFID tag and the reader / writer. Can do. Therefore, even when the attachment object is attached to the installation mechanism and the position is fixed, information can be read and written between the RFID tag and the reader / writer during the operation using the attachment object.

  According to the present invention, it is possible to easily hold an antenna in the state of being close to an RFID tag attached to an object having various shapes. As a result, even when the attachment object is attached to the installation mechanism and the position is fixed, the antenna and the RFID tag can be held close to each other. Therefore, information can be easily transmitted and received between the antenna and the RFID tag during work using the attachment object.

  The best mode for carrying out the present invention will be described below in detail with reference to the accompanying drawings. In the description of the drawings, the same reference numerals are assigned to the same elements, and duplicate descriptions are omitted.

  The antenna mounting structure according to the present embodiment is for mounting an antenna on a management object to which an RFID (Radio Frequency IDentification) tag is attached. The management object is an object for managing information using an RFID tag, and in this embodiment, is a press mold (attachment object). Information on the mold is recorded on the RFID tag, and the reader / writer can read and write information on the RFID tag by transmitting and receiving information to and from the RFID tag via the antenna. FIG. 1 is a view showing a state in which an antenna is attached to a mold using the antenna attachment structure according to the present embodiment.

  The mold 3 is composed of a lower mold 5 and an upper mold 7 and is installed in a press machine 9 when used. The lower die 5 is fixed at a predetermined position on the bolster 11 of the press machine 9, and in this state, four bar-shaped guides 13 protrude from the four corners of the upper surface of the lower die 5. The upper die 7 is set in the press machine 9 so as to move up and down along the guide 13 by inserting the guide 13 through through holes formed at the four corners thereof. The position where the mold 3 is fixed to the bolster 11 is determined according to the shape of the mold 3 and the press object.

  Between the lower mold 5 and the upper mold 7 fixed to the bolster 11, a metal roll material 15, which is an object to be pressed, is placed, and the upper mold 7 slides downward to form a sheet shape together with the lower mold 5. The roll material 15 is formed by pressing the roll material 15. For example, the press machine 9 produces a molded product such as a plug terminal from the roll material 15. A roll material 15 is inserted between one end of the mold 3 between the lower mold 5 and the upper mold 7, and is molded from the other end of the mold 3 and sent out. The vertical movement of the upper mold 7 and the feeding operation of the roll material 15 are controlled by the controller 17 via respective drive units (not shown).

  A sensor group 19 including various sensors is mounted on the press machine 9. The sensor group 19 detects the bottom dead center of the upper mold 7 (the position where it is lowered most), the load of the mold 3, the number of shots per minute, the number of accumulated shots, and the like. Then, the sensor group 19 outputs a signal indicating the detection result to the controller 17.

  A signal indicating the detection result is output to the server 21 by the controller 17. The server 21 includes a PLC (programmable logic controller), and inputs and outputs signals through the PLC. Further, the server 21 is equipped with an automatic detection program for predicting and judging an abnormality, and the server 21 detects an abnormality of the press 9 based on the detection result of the sensor group 19 and various databases. Various databases are a database for storing operation and production history, a database for storing information about the mold 3 such as the identification number of the mold 3 and the detection result by the sensor group 19, and a determination logic for detecting an abnormality. Database.

  When the server 21 detects an abnormality in the press machine 9, the server 21 outputs a signal to the controller 17 and stops the operation of the press machine 9 under the control of the controller 17. Thereby, an accident can be prevented and generation | occurrence | production of inferior goods can be suppressed. The server 21 manages various information related to the mold 3. By utilizing this, for example, the life of the mold 3 can be improved by exchanging and maintaining the mold 3 according to the cumulative number of shots.

  In addition, when the molded product is a precise product such as a terminal plug, if the bottom dead center is shifted by several tens of μm, the molded product is defective. Therefore, by managing the bottom dead center, the processing accuracy can be improved and the yield can be suppressed. Thus, productivity can be improved by monitoring and judging the state during processing in real time during molding.

  On the other hand, a signal indicating the detection result by the sensor group 19 is written by the controller 17 to the RFID tag attached to the mold 3 via the antenna 1. During the operation of the press 9, the sensor group 19 performs detection in real time, and the detection result is written to the RFID tag of the mold 3. The detection result is stored in the RFID tag of the mold 3.

  The RFID tag of the mold 3 stores identification information, delivery information, and the like of the mold 3. This identification information is read into the controller 17 via the antenna 1 when the mold 3 is set on the press 9 at the start of molding. The identification information of the mold 3 is output to the server 21 by the controller 17, and the server 21 determines whether or not the mold 3 is suitable for the target molding. That is, the controller 17 and the antenna 1 function as a reader / writer for the RFID tag.

  After completion of molding, the mold 3 is removed from the press machine 9 and transported to a storage warehouse or the like. At the time of storage, for example, the mold 3 is managed by reading and writing the RFID tag of the mold 3 with a handy type reader / writer. For example, the administrator reads information on the cumulative number of shots from an RFID tag by a reader / writer and determines whether or not to perform maintenance.

  As described above, the RFID tag of the mold 3 is fixed to the side surface of the mold 3 so that the handheld reader / writer can transmit and receive signals to and from the RFID tag when the mold 3 is stored. Further, during the operation of the press machine 9, the antenna 1 connected to the controller 17 via the flexible cable 23 and the RFID tag of the mold 3 are kept at a distance that allows transmission and reception of signals.

  In general, the distance at which signals can be transmitted and received varies depending on the communication wavelength used. For example, when a communication wavelength in the UHF band is used, the distance at which signals can be transmitted and received is relatively long. However, if a communication wavelength in the UHF band is used, the antenna becomes large, so that it is difficult to arrange it near the mold inside the press machine. If this UHF band antenna is disposed outside the press machine, the communication wave is reflected on the metal plate constituting the press machine, and thus the reliability of signal transmission / reception between the RFID tag and the antenna cannot be ensured. .

  For this reason, a small antenna using a communication wavelength of 530 KHz band is used as the antenna 1 according to the present embodiment. When a communication wavelength of 530 KHz band is used, the distance at which signals can be transmitted and received is relatively short. Therefore, in the antenna mounting structure of the present embodiment, the distance between the antenna 1 and the RFID tag is kept at 15 mm or less in order to reliably transmit and receive signals between the antenna 1 and the RFID tag.

  In general, an RFID tag and an antenna are not mechanically connected, and either one of the RFID tag and the antenna is brought close to the other to perform wireless communication at a predetermined distance. However, when the mold 3 is installed on the press machine 9, the position of the RFID tag attached to the mold 3 with respect to the press machine 9 differs depending on the mold 3. This is because the installation position of the mold 3 with respect to the press machine 9 varies depending on the situation, and the mold 3 having various shapes and sizes is installed in the press machine 9.

  On the other hand, it is troublesome to set the antenna at a distance of 15 mm or less with respect to the RFID tag every time the mold is installed in the press machine 9. From this, in this embodiment, when the mold 3 is installed in the press machine 9, the antenna 1 faces the RFID tag attached to the mold 3 so that the distance therebetween is 15 mm or less. The antenna 1 is removably attached to the mold 3. The antenna mounting structure and antenna mounting method according to this embodiment will be described in detail.

  As shown in FIG. 2, the RFID tag 25 is attached to the lower mold 5 with bolts 27. The joint socket 29 is attached to the lower mold 5 by the bolts 27. A cylindrical joint member 31 is attached to the lower mold 5 via the joint socket 29. The columnar antenna 1 is attached to the lower mold 5 by being attached to the joint member 31 via the joint socket 33. Subsequently, each member will be described in detail.

  As shown in FIG. 3, the bolt 27 is a hexagonal bolt having a head portion 27a and a screw portion 27b, and is made of metal such as steel. A disc-shaped RFID tag 25 is fitted in the head 27a. In the RFID tag 25, one of the opposing circular planes is a functional surface 25a for transmitting and receiving signals. The top surface of the head 27 a of the bolt 27 is formed with a recess so as to match the shape of the RFID tag 25. The RFID tag 25 is fitted in the recess so that the functional surface 25a is exposed. The RFID tag 25 is fixed to the bolt 27 so that the surface positions of the top surface of the head 27 a of the bolt 27 and the functional surface 25 a of the RFID tag 25 are aligned.

  As shown in FIG. 4, when the screw portion 27 b of the bolt 27 is screwed into the side surface of the lower mold 5, the RFID tag 25 is fixed to the lower mold 5 by the bolt 27. In the bolt 27, the maximum diameter of the head portion 27a (distance between opposite corners) is formed to be about 20 mm, and the thickness of the head portion 27a is about 10 mm.

  The joint socket 29 has a cylindrical portion 29a and a bottom portion 29b formed at one end of the cylindrical portion 29a. The cylindrical portion 29a is cylindrical and has an inner diameter larger than the maximum outer diameter of the head portion 27a of the bolt 27 so that the head portion 27a of the bolt 27 can be accommodated with a gap. The length of the cylindrical portion 29 a is about the thickness of the head portion 27 a of the bolt 27.

  The bottom portion 29b has a disc shape, and a through hole 29c is formed at the center thereof. The diameter of the through hole 29c is formed larger than the diameter of the screw part 27b so that the screw part 27b of the bolt 27 can be inserted into the through hole 29c of the bottom part 29b. The joint socket 29 is made of reinforced plastic. In addition, the joint socket 29 is preferably formed of a material having high chemical resistance so that the lower mold 5 can be cleaned with a chemical while attached to the lower mold 5.

  The joint socket 29 inserts the screw portion 27b of the bolt 27 into the through hole 29c, and accommodates the head portion 27a of the bolt 27 inside the cylindrical portion 29a. Further, when the bolt 27 is screwed into the mold 3, the bottom portion 29 b of the joint socket 29 is sandwiched and fixed between the head portion 27 a of the bolt 27 and the side surface of the lower die 5. In this state, there is a gap between the inner peripheral surface of the tubular portion 29 a of the joint socket 29 and the outer peripheral surface of the head portion 27 a of the bolt 27. Further, the end surface on the opening side in the cylindrical portion 29 a is the same position as the top surface of the head 27 a of the bolt 27 and the surface position of the exposed functional surface 25 a of the RFID tag 25.

  Thus, the lower mold 5 is managed in a state where the RFID tag 25 and the joint socket 29 are attached to the lower mold 5 via the bolts 27. In this state, since the RFID tag 25 is exposed, the handy reader / writer held by the administrator can be easily brought close to the RFID tag 25 to read / write information.

  As shown in FIG. 5, the antenna 1 has a cylindrical main body 1a and an antenna 1b attached to the tip of the main body 1a. The main body 1a functions as a handle of the antenna 1, and a cable 23 is connected to the proximal end. The front end surface of the main body 1a is planar, and a cylindrical antenna portion 1b having an outer diameter smaller than that of the main body 1a is connected to the front end surface. The front end surface 1 c of the antenna unit 1 b is formed in the same circular shape as the functional surface 25 a of the RFID tag 25.

  The antenna 1 of the present embodiment is formed so that the outer diameter of the main body 1a is about 20 mm, which is the same as the maximum diameter of the head 27a of the bolt 27, and the length thereof is about 55 mm. Moreover, the outer diameter and length of the antenna part 1b are about 12 mm. In addition, a thread groove is formed on the outer peripheral surface on the distal end side of the main body 1 a and functions as a male screw for attaching the joint socket 33 to the antenna 1.

  As shown in FIG. 6, the joint socket 33 is formed of a cylindrical reinforced plastic. The inner diameter of the joint socket 33 is about the same as the outer diameter of the main body 1a in order to accommodate the antenna portion 1b of the antenna 1 and the tips of the main body 1a. A screw groove is formed on the inner side of one opening portion of the joint socket 33 and functions as a female screw to be attached to the antenna 1.

  The joint socket 33 is attached to the antenna 1 by fitting the respective thread grooves of the joint socket 33 and the antenna 1. Thereby, the position of the joint socket 33 is fixed with respect to the longitudinal direction of the antenna 1. In this state, the joint socket 33 is in a state where the antenna portion 1b of the antenna 1 and the tips of the main body portion 1a are accommodated therein. In this state, the front end surface of the joint socket 33 is at the same surface position as the front end surface 1c of the antenna portion 1b.

  As shown in FIG. 7, the cylindrical joint member 31 includes a mounting portion 31a on one opening side, a holding portion 31b on the other opening side, and a protruding portion between the mounting portion 31a and the holding portion 31b. 31c. The attachment portion 31 a is a portion attached to the mold 3. The RFID tag 25 and the head portion 27a of the bolt 27 are accommodated inside the attachment portion 31a while being attached to the mold 3. The holding part 31 b is a part attached to the antenna 1. While attached to the antenna 1, the tip of the main body 1 a of the antenna 1 and the antenna portion 1 b are housed inside the holding portion 31 b together with the joint socket 33, and the holding portion 31 b holds the antenna 1.

  The protruding portion 31c is a portion having a width in the longitudinal direction of the joint member 31 of about 3 mm, and its inner peripheral surface protrudes inward to be thick. By forming the protruding portion 31c, the joint member 31 can enhance the strength. In addition, the internal diameter of the protrusion part 31c is comparable as the diameter of the functional surface 25a of the RFID tag 25 and the front end surface 1c of the antenna part 1b. The joint member 31 is made of non-metal, and is formed of, for example, reinforced plastic.

  The inner diameter of the joint member 31 is approximately the same as the outer diameter of the joint socket 33. As shown in FIG. 8, the joint member 31 can be fixed to the antenna 1 by press-fitting the tip of the main body 1 a of the antenna 1 inside the holding portion 31 b of the joint member 31. In this state, the position of the joint member 31 is fixed with respect to the position in the longitudinal direction of the antenna 1. The joint member 31 and the joint socket 33 may be fixed with an adhesive.

  The outer diameter of the joint member 31 is approximately the same as the inner diameter of the joint socket 29. The joint member 31 can be attached to the lower mold 5 via the joint socket 29 by press-fitting the attachment portion 31 a of the joint member 31 into the joint socket 29. Further, the position of the RFID tag 25 is fixed with respect to the position in the longitudinal direction of the joint member 31 by abutting the joint member 31 against the bottom 29 b of the joint socket 29. Therefore, the position of the antenna 1 fixed to the joint member 31 with respect to the RFID tag 25 is fixed. The joint member 31 can be easily attached to and detached from the joint socket 29 by human power.

  FIG. 2 shows a state where the antenna 1 is attached to the mold 3 via the joint socket 29 and the joint member 31. In this state, the functional surface 25a of the RFID tag 25 and the front end surface 1c of the antenna unit 1b face each other, and the distance between them is about 5 mm. Further, there is nothing to block between the functional surface 25a of the RFID tag 25 and the front end surface 1c of the antenna portion 1b, and the periphery thereof is covered with the joint member 31.

  FIG. 9 shows a state where the antenna 1 to which the joint socket 29 and the joint member 31 are attached is detached from the mold 3. In this state, since the joint member 31 accommodates the antenna portion 1b of the antenna 1, the antenna portion 1b can be protected. Further, the RFID tag 25 attached to the mold 3 can be easily read and written by a general handy reader / writer.

  In the antenna mounting structure according to the present embodiment described above, the antenna portion 1b is attached to the mold 3 so as to face the RFID tag 25 via the joint member 31. Therefore, no matter what the shape of the mold 3 is, it can be easily held in a state where the antenna portion 1b is brought close to the RFID tag 25 fixed to the mold 3. Further, even when the mold 3 is attached to the press machine 9 and the position is fixed, the antenna unit 1b and the RFID tag 25 can be held close to each other. Accordingly, information can be reliably transmitted and received between the antenna unit 1b and the RFID tag 25 during the molding operation using the mold 3.

  In the antenna mounting structure according to the present embodiment, the antenna 1 can be detached from the mold 3 by removing the joint member 31 from the mold 3. In this case, the antenna 1 can be easily removed from the mold 3 and the mold 3 can be transported to another place. Information can be transmitted and received between the RFID tag 25 attached to the mold 3 and the reader / writer installed at the transportation destination.

  Further, in the antenna mounting structure according to the present embodiment, the joint member 31 has a cylindrical shape, the RFID tag 25 is positioned inside one opening side of the joint member 31, and the other opening side of the joint member 31. The RFID tag 25 and the antenna 1 are attached so that the antenna unit 1b is positioned inside the antenna. Thereby, the RFID tag 25 and the antenna part 1b are accommodated in the joint member 31, and the RFID tag 25 and the antenna part 1b can be protected.

  In the antenna mounting structure according to the present embodiment, the joint member 31 is formed of a non-metal. As a result, transmission and reception of signals between the RFID tag 25 and the antenna unit 1 b are performed inside the cylindrical joint member 31. Therefore, it is possible to prevent disturbance of the propagation environment such as a signal propagating between the RFID tag 25 and the antenna unit 1b being reflected on the surrounding metal. Therefore, although the metal press 9 and the metal mold 3 are disposed around, the signal propagation environment can be kept good.

  Further, in the antenna mounting structure according to this embodiment, the RFID tag 25 is fixed to the head portion 27a of the bolt 27, and the screw portion 27b of the bolt 27 is fixed to the mold 3, whereby the RFID tag 25 is fixed to the mold. 3 is fixedly attached. As a result, the RFID tag 25 can be easily and reliably attached to the mold 3.

  In the above-described embodiment, a transmission / reception system using an antenna mounting structure is configured. The transmission / reception system includes an RFID tag 25 fixed to the mold 3, a joint member 31, an antenna 1 attached to the mold 3 via the joint member 31, and reading / writing information from / to the RFID tag 25 via the antenna 1. And a controller (reader / writer) 17 for performing the above.

  In the transmission / reception system of the present embodiment, since the antenna mounting structure described above is used, the antenna 1 can be easily attached to the mold 3 so that the antenna portion 1b and the RFID tag 25 face each other. Thereby, no matter what the shape of the mold 3 is, the antenna portion 1b is easily held at a predetermined distance close to the RFID tag 25 fixed to the mold 3, and between the RFID tag 25 and the controller 17 Can read and write information. Therefore, even when the mold 3 is attached to the press machine 9 and the position is fixed, information can be read and written between the RFID tag 25 and the controller 17 during the molding operation using the mold 3. .

  The present invention is not limited to the above embodiment, and various modifications can be made. For example, in the above embodiment, the object to be attached to the RFID tag 25 is the mold 3, but is not limited thereto. In the antenna mounting structure of the present invention, the antenna is mounted on the mounting target so that information can be transmitted and received between the RFID tag and the antenna. Therefore, it is necessary to read and write information on the RFID tag during work. When applied to the present invention, the present invention is particularly effective. Further, in the antenna mounting structure of the present invention, since the signal propagating between the RFID tag 25 and the antenna portion 1b can be prevented from being disturbed in the propagation environment such as being reflected on the surrounding metal, the metal management can be prevented. The present invention is particularly effective when applied to an object.

  For example, the attachment target of the RFID tag 25 may be a cutting jig. This example will be described with reference to FIG. FIG. 10 is a diagram showing a state in which the antenna is attached to the cutting jig using the antenna attachment structure according to the present embodiment.

  The cutting jig 41 is a jig that is attached to a cutting machine to cut the cutting object 43. A cutting object 43 is attached to the tip of the rod 47 held by the holding unit 45 of the cutting machine. The cutting jig 41 is attached to the base 51 of the cutting machine so that the blade 49 faces the cutting object 43. The pedestal 51 is configured to be slidable in the front-rear direction along the rail 53 arranged in parallel with the rod 47 that holds the cutting object 43. The pedestal 51 is configured to be slidable in the direction perpendicular to the longitudinal direction of the rail 53.

  In this state, when the holding portion 45 is driven to rotate, the cutting object 43 rotates around the rod 47. Then, the cutting jig 41 is advanced toward the cutting object 43 to cut the cutting object 43. In the present embodiment, the cylindrical cutting object 43 is processed into a substantially spherical shape.

  The RFID tag 25 and the joint socket 29 are fixed to the side surface of the base portion of the cutting jig 41 by bolts 27. The antenna 1 to which the joint member 31 is attached via the joint socket 33 is attached to the cutting jig 41 with the RFID tag 25 and the antenna portion 1b facing each other. In this state, the distance between the RFID tag 25 and the antenna unit 1b is kept at about 5 mm. Therefore, information can be transmitted and received between the antenna 1 and the RFID tag 25 during the cutting operation.

  Further, the antenna 1 can be removed from the cutting jig 41 by removing the joint member 31 from the cutting jig 41. In a state where the antenna 1 and the joint member 31 are detached from the cutting jig 41, the cutting jig 41 is managed by transmitting and receiving information to and from the RFID tag 25 of the cutting jig 41 with a handy type reader / writer. Can do.

  Moreover, in the said embodiment, in order to comprise the antenna 1 so that removal from the metal mold | die 3 and the cutting jig 41 was carried out, it comprised so that the attachment part 31a of the joint member 31 could be removed from the metal mold | die 3. FIG. However, the present invention is not limited thereto, and the antenna 1 may be configured to be removable from the holding portion 31b of the joint member 31 or the joint socket 33.

  Further, rubber may be sandwiched between the joint member 31 and the joint socket 29 and between the joint member 31 and the joint socket 33. Thereby, the vibration during the molding operation can be absorbed by the rubber.

  In the embodiment, the bolt 27 and the joint socket 29 protrude from the side surface of the mold 3. In contrast, as shown in FIG. 11, a recess 61a is formed on the side surface of the mold 61 so that the bolt and the joint socket do not protrude from the side surface of the mold, and the bolt 27 and the joint socket 63 are formed in the recess 61a. You may comprise so that it may accommodate. In this case, it is preferable that the functional surface 25 a of the RFID tag 25 is set to the same surface position as the side surface of the mold 61, and the tip portion of the tubular portion 63 a of the joint socket 63 is attached so as to protrude from the side surface of the mold 61. Thereby, the functional surface 25a of the RFID tag 25 can be protected. Also in this case, as shown in FIGS. 12 and 13, the antenna 1 can be detachably attached to the mold 61 so as to face the RFID tag 25. Therefore, similarly to the above-described embodiment, information can be reliably transmitted and received between the antenna unit 1b and the RFID tag 25 during the molding operation using the mold 61.

  Moreover, in the said embodiment, although the attaching part 31a of the joint member 31 was attached to the metal mold | die 3 via the joint socket 29, and the holding | maintenance part 31b hold | maintained the antenna 1 via the joint socket 33, it was comprised. Is not limited to this. The attachment portion 31 of the joint member 31 may be directly attached to the mold 3 or the bolt 25 without using the joint socket 29. Further, the holding portion 31b of the joint member 31 may hold the antenna 1 directly without using the joint socket 33.

It is a figure which shows the state which attached the antenna to the metal mold | die using the attachment structure of the antenna which concerns on this embodiment. It is sectional drawing which shows the state which attached the antenna to the metal mold | die using the mounting structure of the antenna which concerns on this embodiment. It is a perspective view which shows the volt | bolt used in the attachment structure of the antenna which concerns on this embodiment, and the RFID tag was inserted. It is sectional drawing which shows the state by which the RFID tag was attached to the metal mold | die which concerns on this embodiment. It is a perspective view which shows the antenna which concerns on this embodiment. It is a perspective view which shows the state by which the joint socket was attached to the antenna which concerns on this embodiment. It is the perspective view and cross-sectional perspective view which show the joint member which concerns on this embodiment. It is a perspective view showing the state where the joint member concerning this embodiment was attached to the antenna. It is sectional drawing which shows the state which removed the antenna from the metal mold | die using the attachment structure of the antenna which concerns on this embodiment. It is a figure which shows the state which attached the antenna to the cutting jig using the attachment structure of the antenna which concerns on this embodiment. It is sectional drawing which shows the state by which the RFID tag was attached to the metal mold | die which concerns on the modification of this embodiment. It is sectional drawing which shows the state which attached the antenna to the metal mold | die using the mounting structure of the antenna which concerns on the modification of this embodiment. It is sectional drawing which shows the state which removed the antenna from the metal mold | die using the mounting structure of the antenna which concerns on the modification of this embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Antenna, 1b ... Antenna part, 3 ... Mold (attachment object), 17 ... Controller (reader / writer), 25 ... RFID tag, 27 ... Bolt, 27a ... Head, 27b ... Screw part, 31 ... Joint member , 31a ... mounting portion, 31b ... holding portion, 41 ... cutting jig (attachment object).

Claims (10)

An antenna mounting structure for mounting an antenna to a mounting object to which an RFID tag is mounted,
The antenna mounting structure, wherein the antenna is mounted on the mounting target so as to face the RFID tag via a joint member.   The antenna mounting structure according to claim 1, wherein the antenna is removable from the mounting object. The joint member has a cylindrical shape,
The antenna is attached so that the RFID tag is located inside one opening side of the joint member and the antenna is located inside the other opening side of the joint member. Item 3. The antenna mounting structure according to Item 1 or 2.   The antenna mounting structure according to claim 1, wherein the joint member is formed of a non-metal.   2. The RFID tag is attached to the attachment object by fixing the RFID tag to a bolt head and fixing a screw portion of the bolt to the attachment object. The antenna mounting structure according to any one of? 4.   The antenna mounting structure according to claim 1, wherein the mounting object is a metal. A joint member for attaching an antenna to an attachment object to which an RFID tag is attached,
An attachment part to be attached to the attachment object;
A holding unit for holding the antenna so as to face the RFID tag;
A joint member comprising: Formed in a cylindrical shape,
The mounting portion is one opening,
The holding portion is the other opening;
8. The antenna is attached to the attachment object so that the RFID tag is located inside one opening and the antenna is located inside the other opening. Joint member.   The joint member according to claim 6 or 7, wherein the joint member is made of a non-metal. An RFID tag fixed to an attachment object;
A joint member attached to the attachment object so that the RFID tag is positioned inside the one opening side formed in a cylindrical shape;
An antenna attached to the attachment object via the joint member so as to be located inside the other opening side of the joint member;
A reader / writer that reads and writes information from and to the RFID tag via the antenna;
A transmission / reception system comprising:

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