TW200422672A - RFID-equipped identification member and method of producing the same, and optical fiber cable using identification member - Google Patents

Abstract

An identification member (15) includes a long-sized tape body (25). The identification member includes a plurality of RFIDs (23) disposed on one surface of the tape body (25) at suitable longitudinally spaced intervals. The identification member includes a spacer (29) that is stuck to the vicinity of the RFID (23) to protect the latter from the external force and that is thicker than the RFID (23).

Description

200422672 Π) 发明. Description of the invention [Technical field to which the invention belongs] The present invention relates to an identification part of a wireless identification system having an RFID (Radio Frequency Identification) with a cable that can easily identify the purpose of the plurality of cables laid And manufacturing method thereof, and optical fiber cable using identification part. [Prior Art] For example, a plurality of optical fiber cables are laid in a groove. Take 2. There are machine rooms at intervals of 5 to 5 km, and most of the above cables are connected to the connection terminals of each machine room. The management of each cable of the connection terminal mentioned above and the removal of the cable must be performed to identify each cable. The conventional identification method is a method in which identification printing is applied to the outer surface of a cable, or an identification label is attached to a terminal portion of each cable. The printing for identification is to display the cable information such as the manufacturer name, year of manufacture, cable name, length, etc. on the surface of the cable with ink, thermal transfer, laser, etc. In the case of identification labels, for example, the cable information of the above-mentioned items is engraved on a thin metal plate and affixed to each cable, or is suspended by a metal wire (for example, JP-A-6-60750 (paragraph [0012 ] To [0013], refer to Figure 1.) Other cable identification methods are to attach the QR code printing paper printed on the two-dimensional QR code of the optical cable's layout related information to the outer skin of the optical cable. During maintenance, etc. Scan the QR code printing paper with a barcode reader and read the recorded information at the laying site. The QR code printing paper replaces the barcode -5- (2) 200422672, magnetic card, and 1C card also read the information of the optical cable (open 200 Bu 2 1 73 0 (paragraphs [0012] to [fig.]) However, in the conventional cable identification method, when the cable is printed, it is printed on the long side of the cable. Therefore, It is impossible to confirm that the roads buried in the trench or underground will not be exited. Except for the long section to remove the cover of the trench or the sand to make work. Therefore, the entire length of the identification printing is expected to be 1, because the number of characters that can be printed is about lm. And therefore contains the needed Information. The problem that Wen Sheng cannot judge when the identification printing rubs over a long period of time. When using the identification label method, install it at a long distance between cables. Therefore, the number of labels is increased, and the cost is written into the identification label. There is also a limit on the number of characters, containing the required information. The identification label is written with markings and the same as the identification printing. When a long time passes, the text method judges. When QR code is printed on paper, barcodes, magnetic cards, IC cards, etc The identification system of the outer skin has less written information. The time and friction become unrecognizable. The case where the cable needs to be identified is when the cable is re-pasted or removed for the purpose of determining the cable. However, the identification is made with a stamp or The QR code printing paper and bar code are not obvious, and the same, for example, refer to the special 0018]) The identification of the first line surface, when the number of characters changes, the cost of the long distance of the cable increases by m or less. The production line must be solid and also lifted. It is impossible to write all the characters. However, it will disappear and cause non-adhesion to the optical cable long system. -6-(3) (3) 200422672 When a plurality of cables are displayed, it will take a considerable amount of time to determine the information. However, if a different extension cable is cut, the cable will be generated. A malfunction caused by a slogan controlled by a wire or a suspension of information will cause a serious accident. [Abstract] The object of the present invention is to provide an identification member for easily identifying the intended cable from a plurality of cables. Invention Another object is to provide an identification member that reduces the adverse effects of an external force applied to a cable. The first feature of the invention is an identification member including the following elements. The identification member includes a long tape body. The identification member includes a plurality of RFID (Radio Freguency Identification) is arranged on the single side of the tape body at appropriate intervals in the long side direction. The identification member includes a spacer for protecting the RFID from external forces and sticking to the vicinity of the RFID and having a thickness larger than the RFID. The spacer has a long tape shape that can be adhered to one side of the tape body. The spacer is provided with a plurality of hole portions for accommodating the plurality of R F IDs inside. The spacer has a tape shape that can be adhered to one side of the tape body. The spacer is configured to hold the plurality of RFIDs and to be disposed on both sides thereof. The spacer is adhered to one side of the tape body. The spacer has a ring shape having a hole portion capable of accommodating the RFID. A second feature of the invention is an identification member including the following elements. Identification structure (4) (4) 200422672 The piece consists of a long tape body or a first buffer body. The identification member includes a plurality of RFIDs, and is arranged on one side of the tape body or the first buffer body at a proper interval in the longitudinal direction. The identification member includes a second buffer body. The above-mentioned RFID is covered with an external force applied to the RFID card and protected from outside, and is adhered to the tape body or the first buffer body. The second buffer system has a tape-like shape that can cover a plurality of RFIDs or a dish shape that can cover each RFID. A third feature of the invention is an identification member including the following elements. The identification member includes a long tape body 1. The identification member includes a plurality of RFIDs, and is arranged on one side of the first tape body at an appropriate interval in the longitudinal direction. The identification member includes a buffer, and the RFID is protected by absorbing the external force applied to the RFID, and the RFID is stacked between the first tapes. The identification member includes a second tape body, and the buffer body is covered from the outside and adhered to the first tape body. A fourth feature of the invention is an identification member including the following elements. The identification member includes a long tape body 1. The identification member includes a plurality of RFIDs, and is arranged on one side of the first tape body at an appropriate interval in the longitudinal direction. The identification member includes a second tape body, which covers the RFID from the outside and is adhered to the first tape body. The identification member includes a buffer body and is adhered to the outer side of the second tape body for protecting and absorbing external force applied to the R FID. A fifth feature of the invention is an identification member including the following elements. The identification member includes a long tape body 1. The identification member includes a plurality of R FIDs, and is arranged on one side of the first tape body at an appropriate interval in (5) (5) 200422672 in the long side direction. The identification member includes a sealing buffer, and the above-mentioned RFID protected by absorbing an external force applied to the RFID is sealed from the outside between the first tape body. The identification member includes a second tape body, and the sealing buffer body is covered from the outside and adhered to the first tape body. A sixth feature of the invention is a method for manufacturing an identification member including the following steps. The manufacturing method includes a step of arranging a plurality of RFIDs on one side of a long tape body with a proper interval in the long side direction of the tape body. The identification member includes pasting a spacer having a thickness greater than that of the RFID to protect the plurality of RFIDs from external forces, and the vicinity of the RFID. A seventh feature of the invention is a method for manufacturing an identification member including the following steps. The manufacturing method includes a step of arranging a plurality of RFIDs on a single side of a long tape body or a first buffer body with an appropriate interval in a long side direction of the tape body or the first buffer body. The manufacturing method includes a step of covering the outside of the RFID with a second buffer body protected by absorbing external force applied to the RFID, and attaching the second buffer body to a tape body or a first buffer body. An eighth feature of the invention is a method for manufacturing an identification member including the following steps. The manufacturing method includes a step of arranging a plurality of RFIDs on one side of a long tape of the first tape body in a long side direction of the first tape body at appropriate intervals. The manufacturing method includes overlapping the RFID tag which is protected by absorbing a force applied to the RFID and is held between the buffer body and the first tape body. The second tape body covers the buffer body from the outside and The step of sticking the second tape body to the first tape body. A ninth feature of the invention is a method for manufacturing an identification member including the following steps. The manufacturing method includes the steps of arranging a plurality of RFIDs on one side of the long tape body on the single side of the first tape (6) (6) 200422672 in the long side direction of the tape body at appropriate intervals. The manufacturing method includes a step of covering the RFID with a second tape body from the outside and adhering the second tape body to the first tape body. The manufacturing method includes a step of attaching a buffer body for protecting and absorbing a force applied to the RF ID to the outside of the second tape body. The tenth feature of the invention is a method for manufacturing an identification member including the following steps. The manufacturing method includes a step of arranging a plurality of RFIDs on one side of a long tape of the first tape body in a long side direction of the first tape body at appropriate intervals. The manufacturing method includes a step of encapsulating the RFID from the outside to the first tape body by a sealing buffer protected by absorbing an external force applied to the RFID. The manufacturing method includes the steps of covering the sealing buffer with the outside of the second tape body 殂, and adhering the second tape body to the first tape body. A first feature of the invention is an optical fiber cable including the following elements. The optical fiber cable includes a sheath member and has a substantially cylindrical shape. The optical fiber cable includes a accommodating portion for accommodating a tension member and a plurality of optical fiber core wires inside the sheath member. The optical fiber cable includes an identification member, and is arranged inside or on the surface of the sheath member in the longitudinal direction. The identification member includes a long tape body. The identification member includes a plurality of RFIDs, which are arranged on one side of the tape body at appropriate intervals in the longitudinal direction. The identification member includes a spacer, and is adhered to the vicinity of the RFID for protection by absorbing external force applied to the RFID, and has a thickness larger than that of the RFID. The spacer has a long tape shape that can be adhered to one side of the tape body. The spacer is provided with a plurality of holes for accommodating the plurality of RFIDs inside -10- (7) (7) 200422672. The spacer has a tape shape that can be adhered to one side of the tape body. The spacer is configured to hold the plurality of RFIDs and is disposed on both sides of the RFID. The spacer is adhered to one side of the tape body. The spacer has a ring shape having a hole portion capable of accommodating the RFID. A twelfth feature of the invention is an optical fiber cable including the following elements. The optical fiber cable includes a sheath member and has a substantially cylindrical shape. The optical fiber cable includes a accommodating portion for accommodating a tension member and a plurality of optical fiber core wires inside the sheath member. The optical fiber cable includes an identification member, and is arranged inside or on the surface of the sheath member in the longitudinal direction. The identification member includes a long tape or a first buffer. The identification member includes a plurality of RFIDs, and is arranged on one side of the tape body or the first buffer body in the direction of the long side of the tape body at an appropriate interval. The identification member includes a second buffer, which is covered from the outside to absorb the external force applied to the RFID to protect the RFID, and is adhered to the tape body or the first buffer. The second buffer system has a long tape shape that can cover a plurality of RFIDs, or a dish shape that can cover each RFID. A thirteenth feature of the invention is an optical fiber cable including the following elements. The optical fiber cable includes a sheath member and has a substantially cylindrical shape. The optical fiber cable includes a accommodating portion for accommodating a tension member and a plurality of optical fiber core wires inside the sheath member. The optical fiber cable includes an identification member, and is arranged inside or on the surface of the sheath member in the longitudinal direction. The identification member includes a long tape body. The identification member system includes a plurality of RFIDs, which are arranged on the single side of the first adhesive tape at a proper interval in the long side direction. The identification member includes a buffer body and overlaps the first tape body so as to protect the RFID tag from absorbing the external force applied to the RFID tag. The identification member includes a second tape body and covers the buffer body from the outside and is adhered to the first tape body. A fourteenth feature of the invention is an optical fiber cable including the following elements. The optical fiber cable includes a sheath member and has a substantially cylindrical shape. The optical fiber cable includes a accommodating portion for accommodating a tension member and a plurality of optical fiber core wires inside the sheath member. The optical fiber cable includes an identification member, and is arranged inside or on the surface of the sheath member in the longitudinal direction. The identification member includes a long tape body. The identification member includes a plurality of RFIDs, and is arranged on one side of the first tape body at an appropriate interval in the longitudinal direction. The identification member includes a second tape body, and covers the RFID from the outside and adheres to the first tape body. The identification member includes a buffer body and is adhered to the outside of the second tape body for protection by absorbing external force applied to the RFID. A fifteenth feature of the invention is an optical fiber cable including the following elements. The optical fiber cable includes a sheath member and has a substantially cylindrical shape. The optical fiber cable includes a accommodating portion for accommodating a tension member and a plurality of optical fiber core wires inside the sheath member. The optical fiber cable includes an identification member, and is arranged inside or on the surface of the sheath member in the longitudinal direction. The identification member includes a long tape body. The identification member includes a plurality of RFIDs, and is arranged on one side of the first tape body at an appropriate interval in the longitudinal direction. The identification member includes an enclosing buffer, and encloses the above-mentioned RFID protected by absorbing an external force applied to the RFID between the first tape body from the outside. Identification -12- (9) (9) 200422672 Other components include a second tape body, which is covered with the sealing buffer from the outside, and is adhered to the first tape body. According to the feature of the above invention, since the RFID is protected with a spacer having a thickness larger than the thickness of the RFID in the vicinity, the mechanical strength of the identification member can be improved. Thereby, even if an external force is applied to the identification member, the spacer can absorb the external force and prevent the RFID from being damaged. By enclosing the RFID in the hole portion of the tape-shaped spacer which is thicker than the RFID, the RFID can be reliably protected. The two thick tape-shaped spacers located on both sides near the RFID can reliably protect the RFID. Surrounding the RFID with the hole portion of the annular spacer which is thicker than the RFID can reliably protect the RFID. According to the feature of the invention, the second buffer body covering at least one side of the RFID can absorb the external force applied to the RFID. This reduces the external force and impact transmitted to the RFID, and prevents the RFID from being damaged. When the first buffer body and the second buffer body are used, the RFID protection status can be made better. It is economically helpful to use a long tape body and a second buffer body. 〇 If the second buffer body can cover RFID, it can be applied in the shape of a dish even with a long tape shape. According to the feature of the invention, the second buffer body covering one side of the RFID can absorb the external force applied to the RFID. This reduces the external force and impact transmitted to the RFID, and prevents the RFID from being damaged. It is economically helpful to use the first buffer and the second buffer. -13- (10) (10) 200422672 According to the feature of the invention, the identification member can be easily manufactured on the manufacturing line. The manufactured identification member can absorb the external force applied to the RFID by a buffer covering one side of the RFID. This reduces the external force and impact transmitted to the RFID, and prevents damage to the RFID. By covering the buffer body between the first tape body and the second tape body, a stable state can be achieved. According to the feature of the invention, the identification member can be easily manufactured on the manufacturing line. The manufactured identification member can be stabilized by covering a plurality of RFID buffers between the first tape body and the second tape body. A buffer body is covered on the outer surface of the second rubber body. Accordingly, since the external force applied to each RFID can be absorbed by the buffer body, the external force and impact transmitted to the RFID can be reduced, and damage to the RFID can be prevented. According to the feature of the invention, the identification member can be easily manufactured on the manufacturing line. The manufactured identification member covers a plurality of RFIDs between the first tape body and the sealing buffer, and the external force applied to each RFID can be absorbed by the sealing by buffering. This reduces the external force and impact transmitted to the RFID and prevents the RFID from being damaged. Since the waterproofness of the identification member itself can be improved by enclosing the buffer, it is difficult to cause the RFID to be damaged by water immersion. According to the feature of the present invention, the identification means can arrange the RFIDs at a fixed interval in the long-length direction of the optical fiber cable. If a part of the optical fiber cable is exposed by this arrangement, for example, the cable information written to the RFID can be easily identified by a reader / writer. Therefore, it is possible to prevent erroneous cutting of the optical fiber cable, and it is possible to reduce a construction cost. Furthermore, since the identification member is arranged longitudinally on the cable, it is protected by a spacer thicker than the thickness of the RFID tag in the vicinity thereof. This can improve the mechanical strength of the identification member -14 · (11) 200422672. Even if an external force is applied to the identification member, the spacer absorbs the external force to prevent the RFID from being damaged. As a result, RFID information can be read even if the medicine exerts a large external force. According to the feature of the invention, even if an external force is applied to the identification member, the hole portion of the tape-shaped spacer larger than the RFID surrounds the RFID p to protect the RFID. According to the feature of the invention, even if an external force is applied to the identification member, the two thick tape-shaped spacers on both sides of the A RFID can reliably protect the feature of the invention. The hole of the spacer surrounds the RFID to protect the RFID. According to the feature of the invention, since the RFID can be arranged at regular intervals in the length direction of the optical fiber cable by the identification member, Si information can be easily recognized. Therefore, it is possible to prevent erroneous cutting of the optical fiber cable, and to reduce engineering. In addition, since the identification member is arranged longitudinally on the cable, the second buffer body that covers less on one side of the RFID can absorb the external force applied to. This reduces the external force and impact transmitted to the RFID and prevents the RFID from being damaged. As a result, even if a large external force is applied to the cable, the RFID information is read. Using the first buffer and the second buffer can improve the RFID protection status. It is economically helpful when using long tapes and cushions. In the identification member, if the second buffer can be covered, even if the thickness of the cable is actually located in the RFID, the cost of fixing the cable can be assured so that the RFID can be prevented. The second long rule is -15 · ( 12) (12) 200422672 The tape shape can also be applied to the dish shape. According to the feature of the invention, since the RFID can be arranged at a fixed interval in the length direction of the optical fiber cable by the identification means, the cable information can be easily identified. Therefore, erroneous cutting of the optical fiber cable can be prevented, and a reduction in construction cost can be achieved. Moreover, since the identification member is arranged longitudinally on the cable, the external force applied to the RFID can be absorbed by the buffer body covering the RFID single side. This reduces the external force and impact transmitted to the RFID and prevents damage to the RFID. As a result, RFID information can be read even if a large external force is applied to the cable. By covering the planar buffer body between the first tape body and the second tape body, a stable state can be achieved. According to the feature of the invention, since the RFID can be arranged at a fixed interval in the length direction of the optical fiber cable by the identification means, the cable information can be easily identified. Therefore, erroneous cutting of the optical fiber cable can be prevented, and a reduction in construction cost can be achieved. In addition, since the identification member is arranged vertically on the cable, it is possible to stabilize the state by covering a plurality of RFID's between the first tape body and the second tape body. Furthermore, since the buffer body is covered on the outer surface of the second tape body, the external force applied to the RFID can be absorbed by the buffer body. This reduces the external force and impact transmitted to the RFID 'and prevents damage to the RFID. As a result, RFID information can be read even if a large external force is applied to the cable. According to the feature of the invention, since the RFID can be arranged at a fixed interval in the length direction of the optical fiber cable by the identification member, the cable can be easily identified -16- (13) (13) 200422672 information. Therefore, erroneous cutting of the optical fiber cable can be prevented, and a reduction in construction cost can be achieved. In addition, since the identification member is arranged longitudinally on the cable, the plurality of RFIDs are sealed between the first tape body and the sealing buffer, and the external force applied to the RFID can be absorbed by the sealing buffer. Thereby, the external force and impact transmitted to the RFID can be reduced, and the RFID can be prevented from being damaged. As a result, RFID information can be read even if a large external force is applied to the cable. Since the waterproofness of the identification member can be improved by enclosing the buffer, even if the cable is placed in a high-humidity environment, it is difficult to damage the RFID due to water intrusion. With this, RFID information can be read. [Embodiment] Hereinafter, an embodiment of the present invention will be described with reference to the drawings. Referring to Fig. 5, an optical fiber cable 1 according to this embodiment is a grooved cable serving as a receiving portion. The cable 1 is not limited to a trough shape, and may be a twisted or tube type cable. In this embodiment, a grooved cable is used for explanation. The cable 1 includes a tensile body 5 inserted in a substantially circular cross-section through the substantially center of the slotted rod 3 including a long ruler. The tensile member 5 is made of a material such as steel wire, FRP, and high-strength fiber. The cable 1 includes a plurality of grooves 7 on its outer peripheral surface. In this embodiment, the five grooves 7 are designed to be parallel to each other along the longitudinal direction of the groove rod 3. The cable 1 contains five cores (for example, 4-core tape-wound cores (tape core -17- (14) (14) 200422672 fiber) 9) in the five slots 7 as a unit. Called "4-core tape"). A total of 100 fibers are housed. As shown in Fig. 6, the 4-core adhesive tape 9 has four single core fibers 11 arranged in parallel. A coating layer 13 made of a resin is formed around the 4-core tape 9 and these are integrally manufactured into a tape shape. The optical fiber core wire accommodated in the groove 7 is not limited to the above-mentioned four-core tape 9 and other tape core wires, and may be other types of optical fiber core wires. Furthermore, in the cable 1, the continuous body (identifying member) 15 according to the embodiment of the present invention is arranged on the outer peripheral surface of the slotted rod 3 in the longitudinal direction. The connected body 15 includes an RFID (Radio Frequency Identification) 23. The RFID23 is arranged on a long tape-shaped member at a fixed interval in the longitudinal direction. The details are described later. As described above, each groove 7 stores a plurality of 4-core tapes 9. In a state where the elongated body 15 is arranged in the longitudinal direction on the outer peripheral surface of the grooved rod 3, the outer periphery of the grooved rod 3 is coated with a resin tape material (w r a p p i n g) 1 7 and wound laterally. The outer side of this lateral coating layer 17 is packaged with, for example, a sheath 19 of PE (polyethylene) resin. In addition to the above-mentioned PE, the packaging material of the sheath 19 can also use PVC (polyvinyl chloride), nonhalogen flame retardant material (ecological material), and environmentally friendly material. Then, the embodiment of the present invention will be described.的 连长 体 1 5. Referring to FIGS. 1 and 2, the connected body (identification member) 21 as the connected body 15 in the first embodiment includes a plurality of RFIDs 23, for example. -18- (15) (15) 200422672 RFID23 is arranged on one side of the long tape 1 of the first tape body 25 at a proper interval in the long side direction, and is fixed by bonding. The RFID23s of the first embodiment are arranged at a fixed pitch P, that is, at an lm pitch. The first tape body 25 is made of PET (polyethylene terephthalate). The first tape body 25 has a thickness of 30 μm and a width of 30 mm. One side of the first tape body 25 includes, for example, an adhesive material layer 27 such as a hot-melt resin in advance. In order to protect the RFID23 from external forces, a spacer 29 thicker than the RFID23 is pasted near the RFID23. In this first embodiment, the spacer 29 has a long tape shape that can be adhered to one side of the first tape body 25. The plurality of hole portions 31 in which the plurality of RFIDs 23 are housed are arranged at the same pitch P as that of the arrangement state of the RFIDs 23, for example, at a pitch of 1 m. The spacer 29 is made of polyethylene and has a thickness of 0.1. 8mm, width 30mm. The hole portion 31 has a diameter of 22 mm in a substantially circular shape. RFID23 series has a diameter of 20mm and a thickness of 0. 35mm dish. The spacer 2 9 is adhered on one side of the first tape body 25 through an adhesive material layer 27 so that each RF I D 2 3 is housed in the plurality of hole portions 31. The upper surface of the spacer 29 is provided with a second tape body 33 having the same material, thickness and width as those of the first tape body 25, and the first tape body 33 is adhered via an adhesive material layer 35 on the back side. Although the second tape body 33 is preferably configured to be a solid long body 21, it is not necessary to satisfy the function of the long body 21. In detail, as shown in FIG. 3, the RFID23 is a 1C chip with memory cable information stored in a plastic box 37 in a hollow, roughly disc shape. -19- (16) (16) 200422672 39. The RFID23 is equipped with an antenna coil 41 which is electrically connected to the 1C chip 39. The antenna coil 41 includes a disk-shaped core member 43. The antenna coil 41 is a coated copper wire 45 as a coil body wound around the magnetic core member 43 in a spiral shape. The RFID 23 uses radio waves transmitted from a read / write device using electromagnetic induction. The antenna coil 41 can read and write the cable information stored in the 1C chip 39. For example, many optical fiber cables are laid along the railway. The cable 1 is described as an example of the case where it is used as a plurality of optical fiber cables along the railway. Follow the line to 2. Machine rooms are installed at intervals of 5 to 5 km, and most cables 1 are connected to the connection terminals of each machine room. When managing the cables 1 and removing the cables, the cables 1 must be identified. At the time of identification of each of the cables 1, each of the cables 1 is arranged with RFID23 at a regular interval of 1 m in the long direction. By this arrangement, if a part of the cable 1 is exposed, the RFID 23 can be found. It is easy to obtain the cable information written to RFID23 by using a magnetically induced read / write machine. The read / write device can easily read and write the 1C chip 39 in the RFID 23. The information written to the RFID 23 is not erased due to the passage of time. 'The read / write device can easily identify the destination cable 1 in a short time. Therefore, it is possible to prevent erroneous cutting of the optical fiber cable 1, and to reduce manufacturing costs. RFID23 uses 1C chip 39. Since the peripheral portion of the 1C chip 39 lacks mechanical strength, there is a concern that the rCID 39 is simply fixed to the continuous body of one side of the tape body, and the 1C chip 39 due to external force may be damaged. When the long body is arranged inside or on the cable 1, the RFID 1 2 3 -20 · (17) (17) 200422672 is broken due to the internal or external force of the cable, and the cable may not be identified . In addition, the continuous body 21 of the embodiment is opposite to the thickness of the RFID23 0 · 3 5 m m, and the thickness of the spacer 29 is 0. 8 m m. As shown in FIG. 1, the RFID 23 is surrounded and protected by a spacer 29. Therefore, even if an external force is applied to the continuous body 21, the spacer 29 absorbs the external force. This prevents breakage of the RFID 23. Next, a method for manufacturing the continuous body 21 will be described. The detailed description of the same parts as the above-mentioned connected body 21 is omitted. Referring to Fig. 4, an adhesive layer 27 is adhered to one side of the long first tape 25. One side of the first tape body 25 is adhered to a long tape-shaped spacer 29 by a pressure roller 47. The spacer 29 has holes 31 having a size that can hold RFID 23 at a fixed interval in advance in the longitudinal direction with a pitch P (1 m pitch in this embodiment). The first tape body 25 is made of PET and has a thickness of 30 // m and a width of 30 mm. The spacer 29 is made of polyethylene and has a thickness of 0. 8mm, width 30mm. The hole portion 31 is a substantially circular shape having a diameter of 22 mm. Then, an RFID device 49 is provided downstream of the pressurizing roller 47 (rightward in FIG. 4). The RFID 23 is supplied from the RFID supply device 49 into the hole portion 31 of the spacer 29. The RFID 23 is adhered to the adhesive layer 27 on one side of the first tape body 25. RFID23 series has a diameter of 20mm and a thickness of 0. 35mm dish. The plurality of RFID23s are arranged at a pitch of 1 m on the long side direction of one side of the first tape body 25, respectively. Then, the second tape body 33 having the same material, thickness, and width as the first tape body 25 is provided on the spacer 29, and the second tape body 33 is pasted through the adhesive layer 35 -21-(18) (18) 200422672. The spacer 2 9 and the second tape body 3 3 are adhered by a pressure roller 5 1. The continuous body 21 is manufactured by the above steps. Next, the continuous body 53 of the second embodiment will be described. The detailed description of the same parts as the long body 21 of the first embodiment is omitted. Referring to Fig. 7, the continuous body 53 is the first tape body 25 and the second tape body 33 are the same as the continuous body 21 of the first embodiment. It is characterized in that two pieces of tape-shaped spacers 5 5 hold RF ID 2 3 and are arranged on both sides thereof. The spacer 5 5 is made of polyethylene and has a width of 4 mm and a thickness of 0. 8mm long tape shape. The two spacers 55 are adhered to the adhesive layer 25 of the first tape body 25 along both side edges of the first tape body 25 in the width direction. The two spacers 5 and 5 are approximately centered between each other. The RFID 23 is adhered and fixed at intervals in the longitudinal direction of the first tape body 25. RFID23 is arranged at a fixed interval of lm pitch. The upper surface of the two spacers 55 is attached to the second tape body 33 on the upper surface of the first image via the adhesive layer 35 on the back surface. The second tape body 33 has the same material and thickness as the first tape body 25. The function of the elongated body 5 3 of the second embodiment is substantially the same as that of the aforementioned elongated body 21. Basically, the thickness of the spacer 55 is larger than the thickness of the RFID 23, so the RFID 2 is protected by the spacers 55 on both sides. . The external force applied to the elongated body 53 is absorbed by the spacer 55 to prevent the RFID 23 from being damaged. The manufacturing method of the continuous body 53 is to adhere two pieces of long tape to the adhesive material layer 2 7 adhered on one side of the long tape body 25 and the two tape edges along the width direction of the first tape body 25. Tape-like spacer 5 5. It is the same as the fourth figure of the first embodiment -22- (19) (19) 200422672, and it is adhered with a pressure roller 4 7. Then, the RFID 23 is supplied from the RFID supply device 49 to the substantially central portion between the two spacers 5 and 5 at a fixed interval lm pitch, and adhered to the adhesive layer 27 on one side of the first tape body 25. Then, the second tape body 3 3 is adhered to the two spacers 5 5 through the adhesive layer 3 5. The spacers 5 5 and the second tape body 33 are adhered with a pressure roller 51 in the same manner as in the case of Fig. 4 of the first embodiment. From the above steps, a long body 5 3 is produced. Next, the connected body 57 of the third embodiment will be described in detail. The detailed description of the same parts as the first and second embodiments described above is omitted. Referring to Fig. 8, the elongated body 57 is the same as the elongated body 53 of the second embodiment in a point where the RFID23 is held so that two pieces of tape-shaped spacers are arranged on both sides. It is characterized in that two spacers 59 are opposed to each RFID 23 and are arranged on both sides in the longitudinal direction of the first tape body 25. The spacer 59 extends in a direction (lateral direction) perpendicular to the longitudinal direction of the first tape body 25. The spacer 5 9 is adhered to one side of the first tape body 25 through an adhesive layer 27. The spacers 5 and 9 are made of polyethylene and have a width of 4 mm and a thickness of 0. 8mm, 30mm in length. The upper surface of the two spacers 59 and the one side of the first tape body 25 are attached to the second tape body 33 via the adhesive layer 35 on the back side in the first figure. The second tape body 33 has the same material, thickness, and width as those of the first tape body 25. The function of the connected body 57 of the third embodiment is substantially the same as that of the connected body 53 described above. Basically, the thickness of the RFID23 is relatively large. Therefore, the RFID59 is protected by the spacers 59 on both sides. -23- (20) (20) 200422672 Even if an external force is applied to the long body 57, the two spacers 5 and 9 absorb external force to prevent the RFID23 from being damaged. A method for manufacturing the continuous body 5 7 will be described. The longitudinal direction of the two tape-shaped spacers 59 is aligned with the lateral direction of the first tape body 25. The spacer 59 is an adhesive layer 27 supplied to one side of the first tape body 25 having a long length. The spacers 5 9 are positioned on both sides of the position where the R FID 2 3 should be pasted at a fixed interval of 1 m in the longitudinal direction of the first tape body 25. The spacer 5 9 is the same as in the case of Fig. 4 of the first embodiment, and is adhered with a pressure roller 4 7. Then, the RFID 23 is supplied from the RFID supply device 49 between the two spacers 59 described above, and is adhered on one side of the first tape body 25 with an adhesive layer 27. Next, the second tape body 3 3 is adhered to the upper surface of each of the spacers 59 and one side of the first tape body 25 via an adhesive layer 35 on the back surface of the second tape body 3 3. The RFID23 is adhered with a pressure roller 51 as in the case of Fig. 4 of the first embodiment. The continuous body 5 7 is manufactured by the above steps. Next, the continuous body 61 of the fourth embodiment will be described in detail. The detailed description of the same parts as the continuous body 21 of the first embodiment is omitted. With reference to FIG. 9, the continuous body 61 is the first tape body 25 and the second tape body 33 and the third tape body of the first embodiment. The long body 2 1 is the same. It is characterized in that a ring-shaped spacer 65 having a hole portion 63 capable of accommodating the RFID 23 is arranged at an appropriate interval and adhered and fixed to the longitudinal direction of the first tape body 25. In the fourth embodiment, it is arranged at a fixed interval of 1 m and is adhered to the adhesive layer 27 of the first tape body 25. The spacer 65 • 24-(21) (21) 200422672 is made of polyethylene and has a thickness of 0. 8 mm, the inner diameter of the hole portion 63 is 22 mm, and the outer diameter is 30 mm. The plurality of RFID23 is attached to the inside of the hole portion 63 of each spacer 65 through the adhesive layer 2 7 respectively! Tape 2 5 on one side. The upper surface of the spacer 65 and one surface of the first tape body 25 are adhered to the second tape body 33 through the adhesive layer 35 on the back surface in the first figure. The second tape body 33 has the same material, thickness, and width as those of the first tape body 25. The operation of the elongated body 61 of the fourth embodiment is substantially the same as that of the aforementioned elongated body 21. Basically, the thickness of R F I D 2 3 is relatively large. Therefore, since the thickness of the spacer 65 is large, the RFID 23 is surrounded and protected by the spacer 65. Even if an external force is applied to the continuous body 61, the external force can be absorbed by the spacer 65 to prevent the RFID 23 from being damaged. A method of manufacturing the continuous body 61 will be described. The adhesive layer 27 adhered to one side of the long tape body 25 is provided with a ring-shaped spacer 65 at a regular interval of 1 m in the longitudinal direction of the first tape body 25. The spacer 65 is positioned so that the hole portion 63 of the spacer 65 surrounds the position where the RFID 23 should be stuck. The spacer 65 is attached to the first tape body 25 by the pressure rollers 4 7 in the same manner as in the case of Fig. 4 of the first embodiment. Then, the RFID 23 is supplied from the RFID supply device 49 into the above-mentioned hole portion 63 of the spacer 65 and adhered to the adhesive layer 27 on one side of the first tape body 25. Then, the second tape body 33 is adhered to the upper surface of each spacer 65 and one side of the first tape body 25 by the adhesive layer 35 on the back surface of the second tape body 33. The second tape body 3 3, the spacer 65, and the first tape -25- (22) 200422672 body 25 are affixed with a pressure roller 5 1 as in the fourth figure of the first embodiment. The continuous body 61 ° is manufactured by the above steps. Then, it is confirmed that the $, 5, 3, 5, 7, and 61 in the form of the aforementioned brothers 1 to 4 are used in the optical fiber cable 1 shown in FIG. 5. Therefore, the continuous body 67 'of the comparative example was manufactured as follows. Referring to FIG. 10, in the connected body 6 7 of Comparative Example 1, the body 25 and the second tape body 33 and the RFID 23 and the RFID 23 state system are connected to the connected body 2 of the first to fourth embodiments 2 1, 6 1 the same. The continuous body 6 7 series has no spacers' and has an adhesive structure having a first tape 2 and a second tape body 33. [Comparative test 1] The continuous bodies 2 1, 5 3 of the above-mentioned first to fourth embodiments are opposed to the continuous body 67 of Comparative Example 1 individually, and the impact test method is based on the impact test (based on `` 2 7 (1 9 8 7): Basic environmental testing proced 2. 1: Tests Test Ea: Shock "). The load of the test conditions, the speed of 18 m / sec, was in contact with the RFID 23 from directly above the RFID 23. The number of tests is performed in units of one hundred times. The operation confirmation is performed every one hundred times. If the information is read, the test is continued. As shown in Table 1, the maximum number of times to read the information is confirmed. Trial set to 2 0 0 0 times. Comparison test of the effect of plugging the long body 21 The arrangement of the first tape 53, 57 and the post body 25, 57 and 61 were tested. Also IEC68-2-ures Part is tested in 40g 1 direction. Check. Upper limit of result test -26- (23) (23) 200422672 Table 1 Comparative example of continuous body 1st, 2nd, 3rd, 4th, 1st, 1st, 2nd, 3rd, 4th Times 2 00 times 2 000 times 2 000 times As can be seen from the above Table 1, in the connected body 67 of Comparative Example 1, after the shock of 5,000 times, the information of RFID 23 cannot be read. That is, the number of times of impact resistance is 5,000 times. The connected bodies 21, 53, 57, and 61 of the first to fourth embodiments can read information even if they are performed up to 2,000 times. Therefore, in any of the elongated bodies 2 1, 5 3, 5 7, and 61 of the first to fourth embodiments, the RFID 23 is protected by the absorption of the external force of the spacer 65. [Comparative Test 2] Furthermore, the effectiveness of the optical fiber cable 1 in which the connected bodies 21, 53, 57, 57 and 61 of the first to fourth embodiments were arranged longitudinally inside or on the surface of the cable was confirmed. The optical fiber cable 1 in the form in which the connected body 21 of the first embodiment is arranged in the longitudinal direction in FIG. 5 is representatively manufactured. The optical fiber cable in which the elongated body 67 of the comparative example 1 described above was longitudinally disposed inside the cable was manufactured as a comparative example 2 in the same manner as that shown in FIG. 5. In contrast, a comparative test is performed. That is, the test method is based on a crush test (based on JISC682 1). The test conditions were a 100 mm steel plate for a crush test, a certain cable surface of RFID23 as the upper surface, and a load was applied to the RFID23 portion. At this point, -27- (24) (24) 200422672 is applied for 1 minute. The applied load is increased to 5N / mm scale. Then, each test confirms whether or not the information from RFID23 is read. As shown in Table 2, confirm the test 荷 of the maximum applied load when reading the information. Table 2 The cable of Comparative Example 1 is used as the optical fiber cable (Comparative Example 2) The maximum withstand voltage (N / mm) of the cable using the long body of the first embodiment 5 15 As can be seen from Table 2 above, in Comparative Example 2 The optical fiber cable cannot read information when the applied load is 1 ON / mm. Information cannot be read when the optical fiber cable of this embodiment is 20 N / mm. Therefore, even in a cable state, the mechanical properties of the continuous body using the spacer of the present invention are excellent. Next, the connected body 69 of the fifth embodiment of the present invention will be described in detail. The detailed description of the same parts as the connected body 21 of the first embodiment is omitted. Referring to FIG. 11 to FIG. 13 to FIG. 13 and FIG. 13B, in the continuous body 69, the RFID 23 is arranged with a long tape on one side of the planar first buffer body 71 at an appropriate interval, and is fixedly attached to Its long side direction. The RFID23 is arranged at a fixed pitch P, that is, an lm pitch. The first buffer body 71 is made of a non-woven material, and has a thickness of 1 mm and a width of 30 mm. An adhesive layer 7 3 is provided on one side of the first buffer body 71 in advance. The first buffer body 71 is a water-absorbent polymer mixed with polyacrylic acid. • 28-(25) 200422672 In order to protect the RFID23 from external forces, the planar second buffer body 75 is adhered to the first buffer 71 by covering the RFID23 from the outside. The second buffer body 75 has a material, thickness, and width similar to those of the first buffer body 71, and is mixed with polyacrylic acid as a water-absorbing polymer. An adhesive material layer 77 is pasted on one side of the second buffer body 75 in advance. The first and second buffer bodies 7 1 and 7 5 absorb the external force with a material that is softer than the sheath 19 of the optical cable 1 arranged in the longitudinal direction. Therefore, it is preferable to use paper, nonwoven fabric, cotton, or the like because it is a material that is softer than the sheath 19. Soft plastics can also be used. The buffer material is not limited to a solid, and may be a gel or sealed to the vicinity of the RFID23. The greater the thickness of the first and second buffer bodies 7 1 and 7 5, the greater the effect can be obtained. Those coated with water-absorbing polymers such as starch, cellulose, polyvinyl alcohol, and polyacrylic acid, and adhesively coated and incorporated in the first and second buffer bodies 71 and 75 to improve water absorption may be used. The function of the long body 69 will be described. On at least one side of the RFID 23, the outer sheath 19 of the cable 1 has a hardness of at least 1 'and the second buffer body 71 75 covering at least the RFID 23. With this structure, even if an external force is applied to the continuous body, the first and second buffer bodies 71, 75 function as a cushioning material. By this action, the external force and the impact are transmitted to the RFID23 to prevent the RFID23 from being damaged. A water-absorbent polymer ′ having a waterproof effect is mixed with the first and second buffer bodies 71 and 75 to effectively prevent water intrusion into the RFID 23. Referring to FIG. 14, a method for manufacturing the continuous body 69 will be described. The RFID supply device 49 has a diameter of 20 mm and a thickness of 0.1 mm. The cover of the 35mm dish has the same fiber distribution as the RFID23 of -29-(26) (26) 200422672. The adhesive layer 7 3 adhered to one side of the first buffer body 71 having a long length is supplied with RFID23 to the longitudinal direction of the first buffer body 71 from the R FID supply device 49 at a fixed interval of 1 m. As a result, the RFID 23 is adhered to the adhesive layer 73 on one side of the first buffer body 71. Then, the second buffer body 75 covers the RFID 23, and the adhesive layers 73 and 77 are bonded to one side of the first buffer body 71 through the adhesive layers 73 and 77, respectively. The first and second buffer bodies 71 and 75 are adhered with a pressure roller 79 to produce a continuous body 69. Next, the continuous body 81 of the sixth embodiment will be described in detail. Detailed descriptions of the same parts as the long bodies 21 and 69 of the first and fifth embodiments are omitted. Referring to FIGS. 15A and 15B, in the continuous body 81, the RFID 23 is arranged at a fixed interval of 1 m in the long side direction of one side of the long first tape body 25 and is adhesively fixed. The first tape body 25 described above is made of PET, has a thickness of 30 // m, and a width of 30 mm. An adhesive layer 27 is provided on one side of the first tape body 25 in advance. Furthermore, in order to protect the RFID 23 from external forces, a tape-shaped second buffer body 75 having the same material, thickness, and width as that of the fifth embodiment and mixed with a water-absorbing polymer is used. The second buffer body 75 covers the RFID 23 from the outside and is adhered to the first tape body 25. The function of the long body 81 will be described. The second buffer body 75 on at least one side of the RFID 23 having a hardness less than that of the sheath 19 of the cable covers at least the RFID 23. With this structure, even if an external force is applied to the continuous body 81, the function of the second buffer body 75 as a buffer material described above can reduce the transmission of external force and impact to the RFID 23 and prevent the RFID 23 from being damaged. Since the second buffer body -30- (27) (27) 200422672 75 is mixed with a water-absorbing polymer, it is prevented from being immersed in the RFID23. A method for manufacturing the continuous body 81 will be described. In the manufacturing apparatus for the continuous elongated body 69 of the fifth embodiment shown in Fig. 14, the long tapered cushion body 71 is replaced with the first tape body 25. Since this manufacturing method is the same as the fifth embodiment, detailed description is omitted. Referring to FIG. 16, FIG. 17A, and FIG. 17B, in the continuous body 83, the RFID 23 is arranged at a fixed interval of 1 m in the long side direction on one side of the long tape-shaped first buffer body 71. And adhered and fixed. The first buffer body 71 described above is the same as that of the elongated body 69, and is made of a non-woven material, having a thickness of 1 mm and a width of 30 mm. An adhesive layer 73 is provided on one side of the first buffer body 71 in advance. Polyacrylic acid hydrazone was mixed with the first buffer body 71 as a water-absorbing polymer. Furthermore, in order to protect the RFID 23 from external forces, the second buffer body 85 having a dish shape is adhered to the first buffer body 71 so as to cover the RFID 23 from the outside. The material of the second buffer body 8 5 is a non-woven fabric having a thickness of 1 mm and a diameter of 25 mm. An adhesive material layer 7 7 is provided on one side of the second buffer body 85 in advance. The second buffer body 8 5 is a polyacrylic acid mixed with water as a water-absorbing polymer. The operation of the elongated body 83 is basically the same as that of the elongated body 69 of the fifth embodiment. Characteristic effect ... The second buffer body 85 in the shape of a dish reduces external force and impact applied to the RFID23, prevents the rFID23 from being damaged, and prevents the RFID23 from being immersed in water. A method of manufacturing the continuous body 83 will be described with reference to FIG. 18. The adhesive layer 7 3 adhered to one side of the long first buffer body 71 is supplied from R FID -31-(28) 200422672 to the device 49 so that the RFID23 is spaced at a fixed interval of 1 m from the first buffer body 71. The RFID 23 is adhered to the adhesive layer 73 of the first buffer S. Then, the buffer body supply device 87 has a second buffer body 85. The second buffer body 8 5 series dielectric layer 77 is adhered to the upper surface of the RFID 23. The RFID23 is covered with the pressurized name by the buffer body 85 and is then adhered to one side of the first buffer body 71. As described above, 3 is produced. Next, the connected body 89 of the eighth embodiment will be described. Details of the same parts of the continuous body 2 1 and 8 3 of the embodiment. With reference to FIG. 19A and FIG. 19B, the long sides of the first tape 25 of the continuous length ruler are aligned at a fixed distance and aligned. RFID23 is then fixed. The material of the first tape body has a thickness of 30 // m and a width of 30 mm. An adhesive layer 27 is provided on one side of J in advance. In order to protect the RFID 23 from external forces and cover the RFID 23, a disc-shaped second buffer body 25 is used. The second buffer body 85 is made of a non-woven material 1 mm and has a diameter of 25 mm. A material layer 7 7 is deposited on one side of the second buffer body 85. The second buffer body 8 5 is a mixed polyacrylic acid polymer. The function of the elongated body 89 is basically the same as that of the elongated body 69: the disc-shaped second buffer body 85 reduces external forces and impacts, prevents damage to the RFID 23, and is supplied to the single-sided system of the above-mentioned body 71. From this, the second plate 73 and the 77 I long body 83 are formed on the back of the plate, followed by Ryoko 7 9. The 1st and 7th detailed explanation is to omit the drop 89, and the 25 series is a PET spring 1 tape body 25 at a distance of 1 m. It is attached to the first quality from the outside 85 and has a thickness in advance. The same as water absorption. Its features up to RFID23 also prevent water intrusion. -32- (29) (29) 200422672 in RFID23. A method for manufacturing the continuous body 89 will be described. In the manufacturing apparatus for the continuous elongated body 83 of the seventh embodiment shown in FIG. 8, the long first buffer body 71 is replaced with the first tape body 25. Since the manufacturing method is the same as that of the seventh embodiment, detailed description is omitted. Next, the continuous body 91 of the ninth embodiment will be described. The detailed description of the same parts as those in the first and fifth embodiments is omitted;! And 69 are detailed. With reference to FIG. 20A and FIG. 20B, among the body 91, in the ninth embodiment The RFID 2 3 is arranged in a long distance direction of one side of the first tape body 25 having a long length at a fixed interval of 1 m and is adhesively fixed. The first tape body 25 is made of PET, and has a thickness of 30 // m and a width of 30 mm. An adhesive layer 27 is provided in advance on one side of the first tape body 25. Furthermore, in order to protect the RFID from an external force, a tape-like second buffer body 93 is held on the upper surface of the RFID 23 and is interposed therebetween Next, the material layer 77 is overlapped. The second cushion body 93 is made of a non-woven material and has a thickness of 1 mm and a width of 25 mm. An adhesive layer 77 is provided on the back surface of the second buffer body 93 in advance. Polyacrylic acid hydrazone was mixed with the second buffer body 93 as a water-absorbing polymer. The second tape body 33 having a long length is bonded to the first tape body 25 so as to be covered from the outside of the second buffer body 93 through the adhesive layer 27 on the back side. The material, thickness, and width of the second tape body 33 are substantially the same as those of the first tape body 25. -33- (30) (30) 200422672 The operation of the body 91 is basically the same as that of the body 69 of the fifth embodiment. Its characteristic function is to reduce the external force and impact of the second planar buffer body 93 on the RFID 23, prevent the RFID 23 from being damaged, and prevent the RFID 23 from being immersed in the water. A method for manufacturing the continuous body 91 is described with reference to FIG. 21. From the long side of the first tape body 25 of the RFID supply device 49, RFID 23 is supplied at a fixed interval of lm pitch to the adhesive layer 27 on one side of the first tape body 25 attached to the long tape. As a result, the RFID 23 is an adhesive layer 27 adhered to one side of the first tape body 25. Then, the 'second buffer body 93 is overlapped so as to hold the upper surface of the RFID23. The second buffer body 93 is adhered by a pressure roller 79 through an adhesive material layer 77. The second tape body 33 is adhered to the first tape body 25 so as to be covered from the outside of the second buffer body 93 through the adhesive layer 35 on the back side. Thereby, the second tape body 33 is adhered by the pressure roller 95. As described above, the continuous body 91 is manufactured. Next, the long body 97 of the tenth embodiment will be described. The detailed description of the same parts as the connected body 2 1 and 9 1 of the first and ninth embodiments is omitted. Referring to FIGS. 22A and 22B, RFID 23 is fixed to the long side of the connected body 97 in the longitudinal direction. The lm intervals are aligned and fixed to one side of the first tape body 25 having a long length. The first tape body 25 is made of PET, and has a thickness of 30 // m and a width of 30 mm. An adhesive layer 27 is provided on one side of the first tape body 25 in advance. The adhesive layer on the back side is covered from the outside of the RFID23. • 34- (31) (31) 200422672 35 The second tape body 33 is adhered to the tape body 25. The material, thickness and width of the second tape body 33 are substantially the same as those of the first tape body 25. Furthermore, in order to protect the above-mentioned RFID 23 from external forces, the planar second buffer body 9 3 is adhered to the outside of the second tape body 33 with an adhesive tape shape through an adhesive material layer 7 7. The second buffer body 93 is made of a non-woven material and has a thickness of 1 mm and a width of 25 mm. An adhesive layer 77 is provided on the back surface of the second buffer body 93 in advance. The second buffer body 93 is mixed with a polyacrylate as a water-absorbing polymer. The operation of the long body 97 is basically the same as that of the long body 69 of the fifth embodiment. Its characteristic action is that the second buffer body 93 reduces the external force and impact applied to the RFID 23, prevents the RFID 23 from being damaged, and prevents water from entering the RFID 23. A method for manufacturing the continuous body 97 will be described with reference to FIG. 23. The RFID 2 3 is supplied from the RFID supply device 49 to the adhesive material layer 27 adhered to one side of the long first tape body 25 at a fixed interval in the longitudinal direction of the first tape body 25. As a result, the RFID 23 is adhered to the adhesive layer 27 on one side of the first tape body 25. Then, the second tape body 33 is adhered to the first tape body 25 via the adhesive layer 35 on the back side so as to cover from the outside of the RFID23. Thereby, the second tape body 33 is adhered by the pressure roller 79. The second buffer body 93 is superposed on the upper surface of the second tape body 33, and is adhered by a pressure roller 95 through an adhesive material layer 77. Above, a continuous body 97 was manufactured. Next, the continuous body 99 of the eleventh embodiment will be described. The detailed description of the same parts as the connected bodies 21 and 69 of the first to thirty-fifth (32), (32) 200422672 and fifth embodiment is omitted. Referring to FIG. 24A and FIG. 24B, the RFID23 is aligned on the long body 99 'in the first embodiment at a fixed interval of 1 m in the long side direction, and the first tape body 25 is fixedly attached to the long body 99'. One-sided. The first adhesive tape body 25 is made of PET, and has a thickness of 30 / im and a width of 30 mm. An adhesive layer 27 ° is provided on one side of the first tape body 25 in advance. Furthermore, in order to protect the RFID 23 from external forces, a sealing buffer for sealing the RFID 23 is used, such as a gel made of a gel-like object.胶状 101。 The gel 101. The gel 101 is sealed from the outside of the RFID 23 between the RF ID 23 and the first tape body 25. Instead of the gel-like substance 101, the sealing buffer system may use a powder of a water-absorbing polymer. The second tape body 33 and the long tape body 25 are adhered to each other through the adhesive material layer 77 on the back surface so as to be covered from the outside of the gel-like body 101. The material, thickness, and width of the second tape body 33 are substantially the same as those of the first tape body 25. The operation of the elongated body 99 is basically the same as that of the elongated body 69 of the fifth embodiment. Its characteristic effect is to reduce the force and impact of the gel 101 or water-absorptive polymer powder applied to the RFID23, prevent the damage of the RFID23, and prevent water intrusion into the RFID23. A method for manufacturing the continuous body 99 will be described with reference to FIG. 25. From the RFID supply device 49, the RFID 23 is fed to the adhesive layer 27 attached to one side of the long tape of the first tape body 25 at a regular interval of 1 m from the long side of the first tape body 25. As a result, the RFID 23 is adhered to the first adhesive tape -36 · (33) 200422672 on one side of the adhesive layer 27 of the body 25. Then, the second tape body 33 is adhered to the first tape body 25 via the adhesive layer 77 on the back side so as to cover from the outside of the gel-like body 101. The second tape body 33 is adhered by a pressure roller 79. As described above, the continuous body 99 is manufactured. Then, the continuous bodies 69, 81, 83, 89, 91, 97, 99 of the fifth to eleventh embodiments described above are used for the optical fiber cable 1 shown in FIG. 5. In order to confirm the effectiveness, the following comparison was performed.

[Comparative test 3] The hardness of the buffer body used in the fifth to eleventh embodiments and the sheath 19 of the optical fiber cable 1 was compared. The result 'is shown in Table 3. Table 3 PET tape Packaging (low-density polyethylene) Non-woven gel Gel hardness (JISA) 100 90 10 0

As shown in Table 3, the hardness of each material is PET (100) > low density polyethylene (90) > non-woven fabric () > gel (0) in order from hard. The hardness test is performed in accordance with JISK63 01. For the gel-like substance, use the same sample volume and measure as the JI SK 6 3 01 test. [Comparative test 4] For comparison, use the optical fiber cable shown in Figure 5: Use the 5th to -37- (34) (34) 200422672 1 1 The cable of the long body 69, 81, 83, 89, 91, 97, 99 of the embodiment; the cable of the long body 67 of the comparative example 1 described above (comparative example 2 above) Cable); and a cable (Comparative Example 3) in which the RFID23 monomer was embedded in the sheath 19 at intervals of 1 m in the longitudinal direction of the cable. The test method is based on a crush test (according to JI S C 6 8 2 1). The test conditions were the same as in Comparative Test 2. As a result, as shown in Table 4, it was confirmed that the maximum test load when the information was obtained was obtained. Table 4 Cables with RHD monomers embedded in optical fiber cables (Comparative Example 3) Cables of Comparative Example 1 (Comparative Example 2) Cables using the long body of the fifth embodiment are used in the sixth embodiment For the cable, use the longest cable of the seventh embodiment. The maximum withstand voltage 5 5 20 15 20 (N / mm) For the optical fiber cable, use the 8th and 9th and 10th and 11th. Form of the embodiment of the embodiment Form of the long body of the cable Long body of the cable Long body of the cable of the long body of the cable Maximum pressure 15 15 15 25 (N / mm) From Table 4 above, we know that The cable length of the 5th to 11th embodiment -38- (35) (35) 200422672 body (including the buffer body) cable is more than the cable embedded in the cable using RFID23 alone or Comparative Example 1 The cable has a high load until RFID23 is damaged and information cannot be read, and it has excellent mechanical properties. In other words, since the buffers such as the planar buffers 75, 85, and the gel-like body 101 embedded in the continuous body are softer than the sheath 19 of the cable 1, the external force transmitted to the RFID 23 is reduced. [Comparative test 5] The continuous body 99 of the first embodiment is compared with the gel body 101 in the second embodiment, and the continuous body of a water-absorbing polymer (polyacrylic acid) is used in comparison with the continuous body of Comparative Example 1. Waterproofness test of the waterproofness of the long body 67 and the RFID23 monomer. The test method is based on IEC5 2 9 and the test characteristics are IP grade. Each level of IP (Internation Protection) is as follows. The IP 65 grade is a structure opposed to jet water. According to this structure, using a nozzle with an inner diameter of 6.3 mm, even if 29.4 kPa of water is injected into a certain direction for 15 minutes from a distance of 3 m, water does not enter. The structure of IP 6 6 is opposite to the wave. According to this structure, even if 98 kPa of water is injected into a certain direction for 1 minute from a distance of 3 m using a nozzle ′ having an inner diameter of 1 2.5 m m, water does not enter. IP67 grade is a relative protective structure immersed in water. According to this structure, even if it was submerged to a depth of 1 m for thirty minutes, water did not enter. -39- (36) 200422672 Table 5 The continuous body of the RFID body of the RFID body of Comparative Example 1 The internal body of the RFID body of the RFID body of the first embodiment 1 is replaced by the gel body of the first embodiment of the gel body. Waterproof polymer with inner body sealed with water-resistant RFID with long body IP65 rating IP65 rating IP67 rating IP66 rating

As can be seen from Table 5 above, the waterproof body 99 of the first embodiment has a waterproof rating higher than that of the RFID23 single body or the multiple body of Comparative Example 1 and is excellent in water resistance. In particular, as a sealing buffer for sealing the RFID23, the gel 101 is more water-resistant than the powder of the water-absorbing polymer. Therefore, the waterproofness of the long body itself is improved by the buffer. This makes it difficult to cause damage to the RFID immersed in water even if the cable having the longitudinal body provided with the enclosed buffer is placed in a high-temperature environment. This becomes a cable that can read RFID information. The present invention is not limited to the above-mentioned embodiments, and other embodiments can be obtained by appropriate changes. [Possibility of Industrial Utilization] The identification member system of the invention is very useful for the identification of cables. In particular, the identification member is very useful for identifying cables buried in the ground. [Brief description of the drawings] -40- (37) (37) 200422672 Fig. 1 is a partial oblique view of a continuous body of the first embodiment of the present invention. Fig. 2 is a schematic perspective view of the entire long body of Fig. 1. Fig. 3 is a schematic perspective view of the RFID used in Fig. 1. FIG. 4 is a schematic explanatory diagram of the manufacturing steps of the connected body of FIG. 1. FIG. Fig. 5 is a cross-sectional view of the optical fiber cable using the extended body shown in Fig. 2; Fig. 6 is a cross-sectional view of, for example, a 4-core tape as an optical fiber core wire contained in the optical fiber cable of Fig. 5; Fig. 7 is a partial oblique view of a connected body according to a second embodiment of the present invention. Fig. 8 is a partial oblique view of a long body of a third embodiment of the present invention. Fig. 9 is a partial oblique view of a long body of a fourth embodiment of the present invention. FIG. 10 is a perspective view of a part of the connected body of Comparative Example 1. FIG. Fig. 11 is a partial perspective view of a concatenated body according to a fifth embodiment of the present invention. FIG. 12 is an oblique view of the entire long body of FIG. 11. FIG. 13A is a cross-sectional view in the longitudinal direction of the continuous body in FIG. 11. Fig. 13B is a cross-sectional view taken along the arrow XIIB-XIIB line of Fig. 13A. Fig. 14 is a diagram illustrating the manufacturing steps of the concatenated body of Fig. 11. Fig. 15A and Fig. 1B show The sixth embodiment of the present invention is -41-(38) (38) 200422672 connected body. Fig. 15A is a cross-sectional view of the long side of the continuous body. Fig. 15B is a sectional view taken along the line XVB-XVB of Fig. 15A. Fig. 16 is a partial perspective view of a long body of a seventh embodiment of the present invention. Fig. 17A is a cross-sectional view in the longitudinal direction of the continuous body. Fig. 17B is a sectional view taken along line XVIIB-XVIIB of Fig. 17A. Fig. 18 is a simplified explanatory diagram of the manufacturing process of the connected body shown in Fig. 16 Fig. 19A and 19B are connected bodies showing the eighth embodiment of the present invention. Fig. 19A is a cross-sectional view of the long side of the continuous body. Figure 19B is a cross-sectional view taken along the line XIXB-XIXB of Figure 19A. Figures 20A and 20B show a continuous body according to a ninth embodiment of the present invention. Fig. 20A is a cross-sectional view of the long side of the continuous body. Figure 20B is a sectional view taken along the line XXB-XXB of Figure 20A. Fig. 21 is a schematic explanatory diagram of the manufacturing process of the connected body shown in Figs. 20A and 20B. Figures 22A and 22B show the continuous body of the tenth embodiment of the present invention. Fig. 22A is a cross-sectional view in the longitudinal direction of the continuous body. FIG. 22B is a cross-sectional view taken along the line XXIIB-XXIIB of FIG. 22A. Fig. 23 is a schematic explanatory view of the steps of manufacturing a connected body in Figs. 22A and 22B. Fig. 24A and Fig. 24B show the continuous body according to the first i embodiment of the present invention. Fig. 24A is a cross-sectional view of the long side of the continuous body. Figure 24B is a sectional view taken along the line XXIVB-XXIVB in Figure 22A. -42- (39) (39) 200422672 Figure 25 is a diagrammatic illustration of the manufacturing steps of the conjoined body in Figures 24A and 24B. Main component comparison table 1: Optical fiber cable 3: Slot rod 5: Tension-resistant body 7: Slot 9: 4-core tape 1 1: Optical fiber single-core wire 13: Cover body 17: Coating 15, 21, 53, 57, 57 and 61 , 67, 69, 81, 83, 89, 99: il long body 1 9: outer skin

23: RFID 25: first tape body 27, 35, 73, 77: adhesive layer 29, 55, 59, 65: spacer 3 1, 6 3: hole 33: second tape body 37: box 39: 1C chip 4 1: Antenna coil -43- (40) (40) 200422672 4 3: Magnetic core member 4 5: Coated copper wire 4 7, 5 1, 7 9: Pressure roller 49: RFID supply device 71: No. 1 Buffers 75, 85, 93: Second buffer 87: Buffer supply device 1 〇1: Gel-44-

Claims (1)

200422672 (1) Scope of patent application 1. A recognition member, which is characterized by having: a long tape body; a plurality of RFID (Radio Freguency Identification) radio frequency identifications, attached to one side of the tape body Arranged in the long-side direction at appropriate intervals; and spacers are used to protect the RFID from external forces and stick to the vicinity of the RFID and have a thickness larger than the RFID. 2 · As the identification member of the scope of application for patent, wherein the spacer has a long tape shape that can be adhered to one side of the tape body, the spacer has a plurality of RFIDs respectively housed in the interior. A plurality of holes. 3. The identification member according to item 1 of the scope of patent application, wherein the spacer has a tape shape that can be adhered to one side of the tape body, and the spacer is configured to hold the plurality of RFIDs and to be disposed on both sides . 4. The identification member according to item 1 of the patent application scope, wherein the spacer is adhered to one side of the tape body, and the spacer has a ring shape having a hole portion capable of accommodating the RFID. 5. An identification member, comprising: a long tape body or a first buffer body; a plurality of RFIDs arranged on one side of the tape body or the first buffer body # at appropriate intervals on the long sides thereof Direction; and a second buffer body, which covers the above-mentioned RFID protected by absorbing external force applied to the RFID from the outside and is adhered to the above-mentioned tape body or first buffer -45- (2) (2) 200422672 punch. 6. The identification member according to item 5 of the patent application scope, wherein the second buffer system has a tape-like shape that can cover a plurality of RFIDs or a dish shape that can cover each RFID. 7. An identification member, comprising: a first tape body with a long length; a plurality of RFIDs arranged on one side of the first tape body at a suitable interval in the long-side direction; a buffer body, The RFID tapes protected by absorbing external force applied to the RFID are stacked between the first tape bodies; and the second tape body covers the buffer body from outside and is adhered to the first tape body. . 8. An identification member, comprising: a first tape body having a long length; a plurality of RFIDs arranged on one side of the first tape body at an appropriate interval in a longitudinal direction thereof; and a second tape body , The RFID tape is covered from the outside and adhered to the first tape body; and the buffer body is adhered to the outer side of the second tape body to be protected by absorbing external force applied to the RFID. 9. An identification member, comprising: a first tape body having a long length; a plurality of RFIDs arranged on one side of the first tape body at an appropriate interval of -46- (3) (3) 200422672 at an interval Its long side direction; a sealing buffer, which seals the RFID which is protected by absorbing an external force applied to the R FID from the outside, between the first tape body; and a second tape body, which covers the seal from the outside The buffer body is adhered to the first tape body. I 〇 · A method for manufacturing an identification member, characterized in that: a plurality of RFIDs are arranged on one side of a long tape body in a direction of a long side of the tape body at an appropriate interval, and the plurality of RFIDs are protected from The thickness of the spacer affected by the external force is larger than that of the RFID sticking near the RFID. II. A method for manufacturing an identification member, comprising: arranging a plurality of RFIDs at appropriate intervals on one side of a long tape body or a first buffer body with a proper interval between the long sides of the tape body or the first buffer body; The second buffer body protected by absorbing external force applied to the RFID covers the outside of the RF ID and adheres the second buffer body to a tape body or a first buffer body. 1 2 · A method of manufacturing an identification member, comprising: arranging a plurality of RFIDs at appropriate intervals on one side of a long tape of a first tape body in a long side direction of the first tape body to absorb and apply The RFID tag protected by the external force of the RFID is overlapped so as to live between the buffer body and the first tape body, and the second tape body covers the buffer body from the outside and adheres the second tape body to the first tape body. • 47- (4) 200422672 1 3-A method for manufacturing an identification member, characterized in that: a plurality of RFIDs are arranged on one side of a long tape tape body on one side of the first tape body with a proper interval therebetween at appropriate intervals. The second tape body is used to cover the RFID from the outside, and the second tape body is adhered to the first tape body. A buffer body for protecting the external force applied to the RFID is protected and adhered to the outer side of the second tape body. . 1 4. A method for manufacturing an identification member, comprising: arranging a plurality of RFIDs at appropriate intervals on a long side of a first tape body on one side of the first tape body in a direction of a long side of the first tape body; An enclosing buffer protected by the external force of the RFID, encapsulating the RFID from the outside to the first tape body, covering the enclosing buffer with the outside of the second tape body, and adhering the second tape body to the first Tape body. 15. An optical fiber cable, comprising: a sheath member, which has a substantially cylindrical shape; a storage portion, which contains a tension member and a plurality of optical fiber core wires inside the sheath member; and an identification member, which is in a longitudinal direction The identification member is arranged on the inside or the surface of the outer skin member, and the identification member includes: a long tape body; a plurality of RFIDs, which are arranged at appropriate intervals on one side of the tape body; 48- (5) (5) 200422672 It is listed in the long-side direction; and the spacer is adhered to the vicinity of the RFID to be protected by absorbing an external force applied to the RFID, and has a thickness larger than that of the RFID. 16. The optical fiber cable according to item 15 of the scope of patent application, wherein the spacer has a long tape shape that can be adhered to one side of the tape body, and the spacer has a plurality of RFID housings. Inside a plurality of holes. 17 · If the optical fiber cable according to item 15 of the scope of patent application, the spacer has a tape shape that can be adhered to one side of the tape body, and the spacer is configured to hold the plurality of RFIDs and arrange the RFID On both sides. 18. The optical fiber cable according to item 15 of the scope of patent application, wherein the spacer is adhered to one side of the tape body, and the spacer is provided with a ring shape having a hole portion capable of accommodating the RFID. 19. An optical fiber cable, comprising: a sheath member having a substantially cylindrical shape; a accommodating portion containing a tension member and a plurality of optical fiber core wires inside the sheath member; and an identification member arranged in a longitudinal direction On the inside or the surface of the outer skin member, the identification member includes: a long tape body or a first buffer body; a plurality of RFIDs attached to the single-sided interface of the tape body or the first buffer body -49- (6 ) (6) 200422672 Arranged in the long-side direction at appropriate intervals; and the second buffer is covered from the outside to absorb the external force applied to the RFID to protect the RFID, and is adhered to the tape or the first buffer . 20. The optical fiber cable according to item 19 of the patent application scope, wherein the second buffer system has a tape-like shape that can cover a plurality of RFIDs, or a dish shape that can cover each RFID. 21. An optical fiber cable, comprising: a sheath member, which is generally cylindrical; a storage portion, which contains a tension member and a plurality of optical fiber core wires inside the sheath member; and an identification member, which is in a longitudinal direction The identification member is disposed on the inside or the surface of the outer skin member, and the identification member includes: a first tape body with a long rule; a plurality of RFIDs arranged on a single side of the first tape body in a long side direction at an appropriate interval; The buffer body is superimposed so as to absorb the external force applied to the RFID to protect the RFID dwelling between the first tape body; and the second tape body covers the buffer body from the outside and adheres to the above The first tape body. 22 · —An optical fiber cable, comprising: a sheath member, which is generally cylindrical; • 50- (7) (7) 200422672 a storage section, which is configured to contain a tension member and a plurality of pieces inside the sheath member Optical fiber core wire; an identification member, which is longitudinally disposed inside or on the surface of the sheath member, the identification member includes: a first tape body with a long length; a plurality of RFIDs, connected on one side of the first tape body Arranged at appropriate intervals in the long-side direction; and a second tape body covering the RFID from the outside and sticking to the first tape body; and a buffer body sticking to the above for protecting and absorbing the external force applied to the RFID Outside of the second tape body. 2 3. An optical fiber cable, comprising: a sheath member, which is substantially cylindrical; a storage section, which contains a tension member and a plurality of optical fiber core wires inside the sheath member; and an identification member, which is longitudinal The identification member is disposed inside or on the surface of the outer skin member, and the identification member includes: a first tape body having a long length; and a plurality of RFIDs arranged on one side of the first tape body at an appropriate interval in a long side direction. ; The sealing buffer is used to seal the above-mentioned RFID protected by absorbing external force applied to the RFID between the first tape body; (8) 200422672 and the second tape body are used to cover the above-mentioned seal from the outside The buffer is adhered to the first tape body. -52-