JP5775801B2 - Data carrier and elongated shaft core member - Google Patents

Description

  The present invention relates to a data carrier attached to a shaft core member and a long shaft core member to which the data carrier is attached.

2. Description of the Related Art Conventionally, a configuration in which storage means for storing predetermined information is provided in a core tube in which a long stencil sheet is wound in a roll shape is known (see, for example, Patent Document 1).
In the configuration described in Patent Document 1, a wall portion is provided so as to block the entire opening on the one end portion side of the core tube, and a storage means is provided on the wall portion.

JP 2004-255701 A

  However, in the configuration described in Patent Document 1, since the wall portion covers the entire area of one opening of the core tube, when the core tube is supported by the support shaft in a state where the recording unit is attached to the core tube, the support is supported. The tip of the shaft cannot protrude from the wall. For this reason, there is an inconvenience that a restricting means such as a guide plate for restricting the axial movement of the core tube cannot be attached to the tip of the support shaft. Therefore, in the conventional configuration, in order to restrict and support the movement of the core tube in the axial direction, a special configuration is required, which may cause inconveniences such as a complicated apparatus structure.

  An object of the present invention is to provide a data carrier to which a data carrier main body capable of at least one of recording and reading can be attached without closing the entire opening of the shaft core member around which the long body is wound, and the data carrier An object of the present invention is to provide an elongated shaft core member to which a data carrier is attached.

In order to achieve the above object, the data carrier of the present invention is formed in a cylindrical shape whose both ends in the axial direction are open, and a long member can be wound around the outer peripheral surface. A data carrier to be attached, supported by at least one of the base sheet, the adhesive layer laminated on one surface of the base sheet, and the base sheet and the adhesive layer A data carrier body capable of recording and reading predetermined information, and the base sheet is along one part of the outer edge of each end face of the both ends of the shaft member , and one end An adherend-like edge having the other end, and one end and the other end of the adherend-like edge, and a clearance edge through which a support shaft fitted into the shaft member can be inserted. Is adopted.

The data carrier A of the present invention, the data both edges in the axial direction is formed on the opened tubular, and, with respect to the shaft member to the elongate body is configured to be wound on the outer peripheral surface, it is mounted The carrier is supported by at least one of the base sheet, the adhesive layer laminated on one surface of the base sheet, and the base sheet and the adhesive layer, and has predetermined information. A data carrier main body capable of at least one of recording and reading, and the base sheet includes an adherend-like edge along a part of an outer edge of each end face of the shaft core member, and the shaft It characterized in that it has a support shaft can be inserted a relief edge is inserted into the core member, and a first cutting tolerance portion along a part of the inner edge of the end face of the axis member.
Furthermore, in the data carrier of the present invention, it is preferable that the adhesive layer is provided only between the adherend-like edge and the first cutting permission portion.
Further, in the data carrier of the present invention, the first cutting permission portion is provided discontinuously, and the base sheet is located between the first cutting permission portions and the first cutting permission portion. It is preferable to have a connecting portion that connects the adherend-like edge side and the relief edge side.
Furthermore, the data carrier A of the present invention, the data both edges in the axial direction is formed on the opened tubular, and, with respect to the shaft member to the elongate body is configured to be wound on the outer peripheral surface, it is mounted The carrier is supported by at least one of the base sheet, the adhesive layer laminated on one surface of the base sheet, and the base sheet and the adhesive layer, and has predetermined information. A data carrier main body capable of at least one of recording and reading , wherein the base material sheet includes an adherend-like edge along a part of an outer edge of each end face of the shaft core member, and the shaft. wherein the support shaft is inserted into the core member has a relief edge which can be inserted, and a second cutting tolerance extending from the relief edge on the adherend similar edge direction.
And in the data carrier of this invention, it is preferable that the said data carrier main body is arrange | positioned ranging over the said cutting | disconnection permission part.
Moreover, in the data carrier of this invention, it is preferable that the said base material sheet has a notch in the said relief edge.

  On the other hand, the long shaft core member of the present invention employs a configuration in which the data carrier of the present invention is attached.

  According to the present invention as described above, the base sheet that supports the data carrier main body is inserted through the adherend-like edge along a part of the outer edge of the shaft member and the support shaft that is inserted into the shaft member. Since it has a possible escape edge, it can be attached to the shaft core member without blocking the entire opening of the shaft core member. For this reason, for example, a member for restricting the movement of the shaft core member can be attached to the support shaft inserted so as to avoid the escape edge, and the long body can be fed and wound stably.

At this time, the relief edge of the base sheet is formed in an edge that linearly connects both ends of the adherend-like edge, thereby forming a simple shape that can reliably maintain the area that supports the data carrier body. Data carrier can be easily manufactured.
Moreover, a base material sheet can be cut | disconnected along the inner edge of an axial core member by providing the 1st cutting | disconnection allowance part along the inner edge of an axial core member in a base material sheet. For this reason, for example, when data carriers are attached to both ends of the shaft core member and the support shaft can be inserted from any direction of the shaft core member, either one of the data carriers is removed from the first cutting permission portion. Can be easily cut.
Furthermore, the base material sheet cut | disconnected in the 1st cutting | disconnection permission part adhere | attaches another site | part or a member by providing an adhesive bond layer only between a to-be-adhered body similar edge and a 1st cutting | disconnection permission part. Can be prevented.
In addition, by providing a connecting portion between the discontinuous first cutting allowance portions, the data carrier portion is prevented from being completely cut off from the shaft core member even if the first cutting allowance portion is cut. In addition, it is possible to prevent inconveniences such as the cut-out data carrier portion being fed out along with the long body or scattered around.
And a base material sheet can be easily cut | disconnected in a cross direction by providing the 2nd cutting | disconnection allowance part extended to a to-be-adhered body similar edge from a relief edge in a base material sheet.
In addition, the data carrier main body is arranged across at least one of the first cutting permission portion and the second cutting permission portion, so that the data can be stored when the first cutting permission portion or the second cutting permission portion is cut. The carrier body can be destroyed and not function. For this reason, even if data carriers are arranged at both ends of the shaft core member, the data carrier on the side where the support shaft is inserted is reliably destroyed by the support shaft, so information is erroneously recorded from both ends of the shaft core member. It is possible to prevent inconvenience such as recording information interference due to being read or read.
Furthermore, a base material sheet can be easily cut | disconnected from a notch by providing a notch in the relief edge of a base material sheet.

The side view which shows an example of the sticking apparatus to which one Embodiment of the data carrier and axial core member which concern on this invention is applied. The fragmentary sectional view of the support apparatus in the sticking apparatus of FIG. (A) is a front view of the data carrier of this embodiment, (B), (C), (D) is a front view which shows the respectively different modification of the data carrier which concerns on this invention. (A) is sectional drawing of the data carrier of this embodiment, (B), (C) is sectional drawing which shows each different modification of the data carrier which concerns on this invention. The front view which shows the other modification of the data carrier which concerns on this invention. The front view which shows the other modification of the data carrier which concerns on this invention.

Hereinafter, an example of a pasting device to which an embodiment of a data carrier and a shaft core member according to the present invention is applied will be described with reference to the drawings.
In each of the drawings, the shape and arrangement of each component are exaggerated for easy understanding of the contents of the present invention. Further, for example, when directions such as up, down, left, right, front, and back are shown without giving a reference figure in the present embodiment, all are based on FIG.

(Configuration of pasting device)
In FIG. 1, a sticking apparatus 1 sticks an adhesive sheet AS to a semiconductor wafer (hereinafter sometimes referred to as “wafer”) WF as a plate-like member. Here, the adhesive sheet AS is configured by laminating an adhesive layer AD on one surface of the base sheet BS. A release sheet RL is temporarily attached to the adhesive layer AD of the adhesive sheet AS, and the adhesive sheet AS and the release sheet RL constitute an original fabric RS as a long body. It is wound around the outer periphery of the shaft-shaped shaft member 24 and prepared in advance.
The affixing device 1 supports the shaft core member 24 around which the raw material RS is wound, and also supports the support device 2 that allows the adhesive sheet AS to be fed from the shaft core member 24, and the feeding means 3 that feeds the adhesive sheet AS. A pressing unit 4 that presses and sticks the fed adhesive sheet AS to the wafer WF, and a moving unit 5 that relatively moves the wafer WF and the pressing unit 4 are provided. The sticking device 1 is configured such that the overall operation is controlled by a control means 6 such as a personal computer or a sequencer.

The support device 2 includes a frame 21 and a support portion 22 provided on one surface of the frame 21. As shown in FIG. 2, the support portion 22 includes a support shaft 221, and the shaft core member 24 is inserted by inserting the support shaft 221 from one end side (left end side in FIG. 2) of the hollow portion of the shaft core member 24. Support.
The feeding means 3 is supported by the frame 21 as a whole, and is adhered from the release sheet RL by folding back the release sheet RL of the original RS and the first and second guide rollers 32 and 33 for guiding the original fabric RS. A peeling plate 34 for peeling the sheet AS, a driving roller 36 driven by a turning motor 35 as a driving device, a pinch roller 37 for sandwiching the peeling sheet RL between the driving roller 36, and a turning motor as a driving device 39 and a collection roller 38 for collecting the release sheet RL.
The pressing means 4 is made of an elastically deformable member such as rubber or resin, is rotatably supported by a support member (not shown), and can be moved up and down by a linear motor as a drive device (not shown).
The moving means 5 includes a table 51 on which a wafer WF is placed and can hold the wafer WF by suction holding means (not shown) such as a decompression pump and a vacuum ejector, and a driving device in which a slider 52 is fixed to the lower surface of the table 51. The table 51 can be moved in the left-right direction by sliding the slider 52.

(Configuration of support device)
Next, the support device 2 will be described in detail.
As shown in FIG. 2, the support shaft 221 has an axial base end side (left side in FIG. 2) penetrating the frame 21, and is rotated by a rotary bearing BC provided on the left side of the frame 21 in FIG. 2. Supported as possible.

The support shaft 221 can be inserted into the inner periphery of the shaft core member 24, and has a cylindrical large diameter portion 221A provided with a diameter slightly smaller than the inner diameter of the shaft core member, and the tip of the large diameter portion 221A in the axial direction. A tapered portion 221B that is provided on the side (right side in FIG. 2) and gradually decreases in diameter toward the distal end side, and a small diameter portion 221C that is provided at a distal end of the tapered portion 221B with a smaller diameter than the large diameter portion 221A.
The support shaft 221 is provided with a restricting means 25 that restricts movement of the shaft core member 24 fitted and inserted into the support shaft 221 in the axial direction and prevents the original fabric RS from collapsing. The restricting means 25 is provided in a hook shape on the base end side of the large-diameter portion 221A of the support shaft 221, and includes an inner guide plate 251 that restricts the movement of the shaft core member 24 in the left direction in FIG. The small-diameter portion 221 </ b> C includes an outer guide plate 252 whose movement is restricted via a boss 253.
The boss 253 supports the outer guide plate 252 and is provided with a through-hole 253A fitted into the small diameter portion 221C with a slight gap so as to be screwable into the boss 253, and fixes the boss 253 to the small diameter portion 221C. And a clamp lever 253C having a screw portion 253B.

  On the outer surface of the outer guide plate 252 (the surface on the right side in FIG. 2) is an annular loop antenna (hereinafter referred to as “mother antenna”) that is located on the outer peripheral side of the boss 253 and is formed by winding a conductor in a loop shape. 26 is provided.

The shaft core member 24 is formed in an open both ends type in which the raw material RS can be wound, that is, a cylindrical shape in which both end edges in the axial direction are opened. Each carrier 27 is attached.
As shown in FIGS. 3A and 4A, the data carrier 27 includes a base material sheet 271 made of resin, paper, and the like, and an adhesive layer 272 laminated on one surface of the base material sheet 271. And a data carrier body 273 having a chip CP and an antenna (hereinafter referred to as “child antenna”) AT for the chip CP and provided on the other surface of the base material sheet 271.

The base sheet 271 is avoided without interference between the adherend-like edge 271A along a part of the outer edge of the end surface 24A of the shaft member 24 and the small-diameter portion 221C of the support shaft 221 fitted into the shaft member 24. It is made into the substantially D shape which has the escape edge 271B which can be penetrated.
The escape edge 271 </ b> B is formed, for example, as an edge that connects both ends of the adherend-like edge in a straight line.

The data carrier main body 273 can read and store data using electromagnetic waves as a communication medium, and can transmit data. As such a data carrier main body 273, for example, a so-called RF memory or RFID tag composed of an IC chip (chip CP) and a transmitting / receiving conductive coil (child antenna AT) connected to the IC chip. Etc. can be illustrated.
The data carrier 27 is attached to the end surface 24A of the shaft core member 24 by an adhesive layer 272. As shown in FIG. 2, the data carrier 27 is supported by the support shaft 221 and the sub antenna AT and the main antenna 26. Are arranged so as to face each other.

Further, the reader / writer 7 is connected to the mother antenna 26, and the reader / writer 7 reads data stored in the data carrier main body 273 or writes data to the data carrier main body 273 under the control of the control means 6. Can be drunk.
The data communicated between the data carrier main body 273 and the main antenna 26 includes standard dimensions such as the type, material, product name, code, thickness, length, width, and diameter of the adhesive sheet AS, Lot number, length using the original fabric RS, remaining length of the original fabric RS, quality guarantee period of the adhesive sheet AS, the remaining number of adhesive sheets AS before and after the start of feeding, the number of adhesive sheets AS fed out, Adhesive sheet AS can be optimally fed out, recommended feeding speed, adhesive sheet AS can be optimally pasted, and recommended adhesive tension, recommended pressing force, etc. The contact information of the consultation desk can be illustrated. In short, as the data to be communicated, there are various management data relating to the operation control of the raw fabric RS which is a long body wound around the shaft core member 24 and the sticking device 1.
And the data read from the data carrier main body 273 can be displayed on the monitor which is not shown in figure provided in the sticking apparatus 1, or the sticking conditions of the said sticking apparatus 1 can be set based on the read data.

(Adhesion sheet pasting operation)
In the pasting device 1 described above, when the adhesive sheet AS is pasted on the wafer WF, first, the original fabric RS wound around the shaft core member 24 is supported by the support shaft 221. At this time, the data carrier 27 </ b> A on the side facing the inner guide plate 251 in the data carrier 27 comes into contact with the tapered portion 221 </ b> B of the support shaft 221 and is broken as the support shaft 221 is inserted. On the other hand, in the data carrier 27B on the side facing the outer guide plate 252, the small-diameter portion 221C of the support shaft 221 is inserted into the opening between the escape edge 271B and the inner edge of the shaft core member 24, as shown in FIG. Therefore, it is not broken. Next, when the boss 253 is inserted into the small-diameter portion 221C of the support shaft 221 and fixed by tightening the clamp lever 253C, the data carrier 27B is opposed to the main antenna 26 as shown in FIG.
Then, when the moving means 5 drives the single-axis robot 53 to carry the table 51 in the left direction and the detecting means such as an optical sensor (not shown) detects that the wafer WF has reached a predetermined position, the feeding means. 3 drives the rotation motors 35 and 39 to feed out the adhesive sheet AS, and the pressing means 4 presses and adheres the adhesive sheet AS to the transferred wafer WF.

Here, the control means 6 controls the reader / writer 7 before starting the pasting, and causes current to flow through the mother antenna 26, thereby generating transmission means such as magnetic flux, static electricity, and microwaves. Electric power is generated to read data written on the chip CP of the data carrier main body 273, and the entire pasting apparatus 1 is controlled based on the read data. This control is performed, for example, based on the recommended feeding speed of the adhesive sheet AS in the data written in the data carrier main body 273, or the table 51 is moved by the single-axis robot 53 based on the rotation speed of the rotation motors 35 and 39. To determine the moving speed to be moved, or to determine the amount of lifting / lowering of a direct acting motor (not shown) that raises and lowers the pressing means 4 based on the recommended pressing force, the torque applied to the output shaft, etc., and to set the pressing force Can do. In addition, the amount of raw material RS used can be subtracted from the amount of raw material RS taken up at the start of operation to manage the remaining amount of raw material RS, and the replacement time of raw material RS can be displayed.
At this time, since the mother antenna 26 and the child antenna AT of the data carrier main body 273 are opposed to each other, the child antenna AT can be always present at the passing position of the transmission means generated by the mother antenna 26. 7 can efficiently generate electromotive force in the child antenna AT via the mother antenna 26, and can reliably read the data written in the chip CP.

Further, the control means 6 controls the reader / writer 7 to generate an electromotive force during the rotation of the shaft core member 24 after the start of sticking, and writes data in the data carrier main body 273. Thus, even when the shaft core member 24 is rotating, the child antenna AT is always present at the passing position of the transmission means of the mother antenna 26, and the reader / writer 7 is connected to the child antenna 26 via the mother antenna 26. An electromotive force can be efficiently generated in the antenna AT, and data can be reliably written in the chip CP. As data written at this time, for example, the number of sheets using the adhesive sheet AS, the length using the original fabric RS, and the like can be exemplified.
When the adhesive sheet AS is attached to the predetermined number of wafers WF, the reader / writer 7 is controlled to write and store data in the data carrier main body 273. As data to be written at this time, for example, the remaining number of adhesive sheets AS after the start of feeding obtained by subtracting the number of used adhesive sheets AS from the remaining number of adhesive sheets AS before the start of feeding, or the remaining length of the original fabric RS Examples can be given. The number of used adhesive sheets AS can be calculated based on the number of times the rotation motor 35 is activated, the number of times detected by a detection means (not shown) that detects that the wafer WF has reached a predetermined position, and the like. The length using the anti-RS can be calculated based on the number of rotations, pulses, and the like of the rotation motor 35. In this way, for example, when changing to another original fabric RS before the entire adhesive sheet AS in one original fabric RS is used, data is written to the data carrier body 273 of the first original fabric RS. Therefore, when the original material RS is used again, it can be dealt with immediately by reading the data in the same manner as described above. Further, the stock of the raw fabric RS can be managed by transmitting the remaining number of the adhesive sheets AS stored in the data carrier main body 273 to an external computer (not shown).

(Effect of embodiment)
In the present embodiment as described above, since the data carrier 27 is attached without blocking the entire opening of the shaft core member 24, the support shaft 221 supports the original fabric RS wound around the shaft core member 24. In addition, the data carrier 27B on the outer guide plate 252 side can attach the restricting means 25 to the small diameter portion 221C of the support shaft 221 without breaking.

  In addition, since the data carriers 27 are attached to both axial end surfaces 24A of the shaft core member 24, it is necessary to select the insertion direction of the shaft core member 24 when attaching the shaft core member 24 to the support shaft 221. And can be inserted from any direction. Moreover, since the data carrier 27A on the inner guide plate 251 side can be destroyed when the shaft core member 24 is inserted into the support shaft 221, the surface of the data carrier 27A does not face the surface of the main antenna 26, and The antenna 26 does not communicate (interference) with the two data carriers 27A and 27B.

(Modification)
As described above, the best configuration, method and the like for carrying out the present invention have been disclosed in the above description, but the present invention is not limited to this.
That is, the invention has been illustrated and described with particular reference to certain specific embodiments, but without departing from the spirit and scope of the invention, Various modifications can be made by those skilled in the art in terms of material, quantity, and other detailed configurations. In addition, the description limited to the shape and material disclosed above is an example for easy understanding of the present invention, and does not limit the present invention. The description by the name of the member which remove | excluded the limitation of one part or all of such restrictions is included in this invention.

  For example, as a method for supporting the data carrier main body 273 on the base material sheet 271 in the present invention, a data carrier main body 273 is provided between the base material sheet 271 and the adhesive layer 272 as shown in FIG. Alternatively, as shown in FIG. 4C, the adhesive layer 272 may be provided on the surface. That is, the data carrier body 273 only needs to be supported by at least one of the base material sheet 271 and the adhesive layer 272.

In addition, as shown in FIG. 3B, the data carrier 27 may be provided with a first cutting permission portion 274 along the inner edge of the end surface 24 </ b> A of the shaft core member 24. The first cutting permissible portion 274 is formed, for example, in a perforated shape or a thin shape, and promotes cutting of the base sheet 271. When the support shaft 221 is inserted into the shaft core member 24, the inner guide plate The data carrier 27 on the side facing 251 is easily broken by the tapered portion 221 </ b> B of the support shaft 221.
In addition, since the data carrier main body 273 may be different from the material of the base material sheet 271, the data carrier main body 273 can be easily separated and collected by providing the first cutting permissible portion 274. . The data carrier 27 that is not used may be cut in advance by the operator from the first cutting permission portion 274 when the shaft core member 24 is pivotally supported by the support shaft 221.

Furthermore, as shown in FIG. 3B, a notch 275 may be provided in the relief edge 271B of the base sheet 271. Note that the cut 275 may be a cut 275A formed continuously with the end of the first cutting allowance 274 or a cut 275B not connected with the first cutting allowance 274.
By providing the notch 275A, it is possible to easily start cutting from the first cutting permission portion 274, so that the base sheet 271 and thus the data carrier 27 can be cut more easily. In addition, the base sheet 271 can be easily broken by making the cut 275B into a shape that is deeply cut as shown in FIG.

The adhesive layer 272 of the present invention is provided, for example, only in the region indicated by the mesh line in FIG. 3C, that is, only between the adherend-like edge 271A and the first cutting permissible portion 274, and the first cutting A portion surrounded by the allowable portion 274 and the relief edge 271B may be a non-adhesive region.
Further, the adhesive layer 272 is not limited to being formed in a belt shape as shown in FIG. 3C, and may be provided in a dot shape or a stripe shape for the purpose of reducing the amount of adhesive used.

Further, as shown in FIG. 3D, the base sheet 271 may be provided with a second cutting permission portion 276 extending in a direction from the escape edge 271B toward the adherend similar edge 271A. As shown in the figure, the second cutting permission portion 276 is not limited to being provided radially from the center of the relief edge 271B, and may be provided from any position of the relief edge 271B. In this case, the notch 275 may be provided continuously with the second cutting permission portion 276.
The second cutting permission portion 276 is provided continuously to the first cutting permission portion 274. However, the second cutting permission portion 276 is provided without being connected or without the first cutting permission portion 274. Or you may. In short, the first and second cutting permissible portions 274 and 276 and the cut 275 may be provided as necessary or may be optional.
Further, as shown in FIG. 3D, the first cutting allowance portion 274 is provided discontinuously, and between the non-continuous first cutting allowance portions 274, the adherend similar edge 271A side and the relief edge 271B. You may provide the connection part 277 of the state which connected the side. Thereby, it is possible to prevent the data carrier 27 portion cut by the first and second cutting permission portions 274 and 276 from being scattered around.

  Further, as shown in FIG. 5, the data carrier main body 273 is provided across at least one of the first cutting permission portion 274 and the second cutting permission portion 276, and the first and second cutting permission portions 274 are provided. , 276 may be broken so that the slave antenna AT is destroyed and no longer functions. The shape of the sub antenna AT can be formed in an appropriate shape such as a circle, an ellipse, or a polygon, as indicated by a two-dot chain line in FIG.

Further, the data carrier 27 may be, for example, a 1/2 annular shape, a 1/3 annular shape, a 3/4 annular shape, or the like as shown in FIG. That is, the clearance edge 271B corresponds to the outer periphery of the small-diameter portion 221C in the middle of the linear straight edge 271B1 that is continuous in the radial direction at both ends of the adherend-like edge 271A and the linear edges 271B1 at both ends. Alternatively, a shape provided with a notch edge 271 </ b> B <b> 2 that is larger than that may be used. The cutout edge 271B2 is not limited to the arc shape, but may be a polygon, an ellipse, or other shapes.
Further, although the adherend similar edge 271A is formed in a series of arcs, for example, a part of the adherend similar edge 271A may be formed in another shape such as a straight line. A shape that does not include an arc, such as a polygonal shape in accordance with the outer shape of the core member 24, may be used.
In short, in the present invention, the adherend-like edge 271A only needs to have a shape along a part of the outer edge of each end surface 24A of both end edges of the shaft core member 24. For example, the shaft core member has a hollow rectangular tube shape. In such a case, the shape of the adherend-like edge can be a shape composed of a plurality of straight lines. Further, the relief edge 271 </ b> B only needs to be formed in a relief shape that does not interfere with the tip small diameter portion 221 </ b> C of the support shaft 221.

The support shaft 221 may be configured to be non-rotatable with respect to the frame 21 and to support the shaft core member 24 so as to be rotatable. Further, the support shaft 221 is not provided with the tapered portion 221B, and the shaft core member 24 has a shape in which the small diameter portion 221C protrudes with a step of 90 degrees in a front view on a surface perpendicular to the axial direction of the large diameter portion 221A. If it is possible to support the above, an appropriate configuration used in normal machine design can be applied. Moreover, although the axial core member 24 pivotally supported by the support shaft 221 is formed in a cylindrical shape, it is not limited to a cylindrical shape such as a polygonal cylindrical shape.
Also, the restricting means 25 attached to the support shaft 221 may have other configurations as long as the shaft core member 24 can restrict the movement of the support shaft 221 in the axial direction.
Further, although the mother antenna 26 is described as being provided on the outer guide plate 252, it may be provided between the outer guide plate 252 and the boss 253, for example. In addition, although the mother antenna 26 is provided in an annular shape, the mother antenna 26 may be provided in, for example, a square shape. The mother antenna 26 is not limited to a loop antenna, and may be any device that can communicate with the data carrier 27.

  The data carrier main body 273 may be capable of only storing data, or may be capable of only transmitting data. Further, the data carrier main body 273 is not limited to an IC tag, an IC card, an RF memory, an RFID tag, or the like, but a so-called QR code (registered trademark) matrix type two-dimensional code, a so-called bar code one-dimensional code, Data recording or a magnetic sheet may be used. In short, the data carrier main body 273 may be a member capable of recording and reading predetermined information. When the data carrier body 273 is a bar code or QR code, a reader capable of reading the bar code or QR code may be used instead of the main antenna 26. In the case of a magnetic sheet, a magnetic field is generated to magnetize the magnetic material. Then, a so-called magnetic head that writes data or detects data change and reads data may be used. If the amount of information to be stored is small, such as a barcode or QR code, a code that can be accessed by a higher-level control means such as a higher-level computer is stored in these codes, and the higher-level control means performs the same as described above. The data may be received.

In the present invention, the material of the base material sheet 271 and the shaft core member 24 is arbitrary as long as it is a material capable of exhibiting a function that is not inconvenient in use, and the long material is also the base material sheet described in the above embodiment. Not only raw fabric RS with adhesive layer AD laminated on BS, but also belt-like adhesive sheet, paper, cloth, steel plate, belt, resin, wood board, long thread, string, wire, cord, tube, hose, A chain or the like can be exemplified, and a strip or wire that can be wound around the shaft core member 24 is sufficient.
Further, the apparatus to which the data carrier 27 and the shaft core member 24 according to the present invention can be applied is not limited to the sticking apparatus 1, and a long body such as a long body winding device or a long body feeding device is wound. Any device using an axial core member may be used.

The type and material of the adhesive sheet AS in the present invention are not particularly limited. For example, the adhesive sheet AS has an intermediate layer between the base sheet BS and the adhesive layer AD, or has three layers such as other layers. The above may be used. The adhesive sheet AS may be a protective sheet, a dicing tape, a die attach film, or the like. Examples of the semiconductor wafer WF include a silicon semiconductor wafer and a compound semiconductor wafer. The adhesive sheet AS to be attached to the semiconductor wafer WF is not limited to a protective sheet, a dicing tape, and a die attach film, but any other sheet, An adhesive sheet AS having an arbitrary use and shape such as a film and a tape can be applied. Further, the plate member may be an optical disk substrate, and the adhesive sheet AS may have a resin layer constituting the recording layer. As described above, as a plate-like member, not only a glass plate, a steel plate, a resin plate, and other members, but also members and articles of any form can be targeted.
Further, the pressing means 4 may be configured by other than the one shown in the above embodiment, and the pressing means 4 is not limited in any way as long as the adhesive sheet AS can be attached to the plate-like member. A pressing member made of blade material, air spray, rubber, resin, sponge, or the like can be employed.

  The drive device in the embodiment includes an electric device such as a rotation motor, a linear motion motor, a linear motor, a single axis robot, an articulated robot, an actuator such as an air cylinder, a hydraulic cylinder, a rodless cylinder, and a rotary cylinder. In addition to these, a combination of them directly or indirectly may be employed (some of them overlap with those exemplified in the embodiment).

24 ... Axial core member 24A ... End face 27 ... Data carrier 221 ... Support shaft 271 ... Base material sheet 271A ... Adherence-like edge 271B ... Relief edge 272 ... Adhesive layer 273 ... Data carrier body 274 ... First cutting permissible portion 275 ... Cut 276 ... Second cutting allowance part 277 ... Connection part RS ... Original fabric (long body)

Claims (4)

A data carrier that is attached to an axial core member that is formed into a cylindrical shape having both ends in the axial direction open and that is capable of winding a long body on an outer peripheral surface,
A base sheet;
An adhesive layer laminated on one side of the base sheet;
A data carrier body supported by at least one of the base material sheet and the adhesive layer, and capable of recording and reading predetermined information.
The base sheet is along an outer edge of each end face of each end edge of the shaft core member, and has an adherend-like edge having one end and the other end, and one end and the other end of the adherend-like edge And a relief edge through which a support shaft fitted into the shaft core member can be inserted. A data carrier that is attached to an axial core member that is formed into a cylindrical shape having both ends in the axial direction open and that is capable of winding a long body on an outer peripheral surface,
A base sheet;
An adhesive layer laminated on one side of the base sheet;
A data carrier body supported by at least one of the base material sheet and the adhesive layer, and capable of recording and reading predetermined information.
The base sheet includes an adherend similar edge along a part of an outer edge of each end face of the both end edges of the shaft core member, a relief edge through which a support shaft fitted into the shaft core member can be inserted, and the shaft features and to Lud Takyaria that has a first cutting tolerance portion along a part of the inner edge of an end face of a core member. A data carrier that is attached to an axial core member that is formed into a cylindrical shape having both ends in the axial direction open and that is capable of winding a long body on an outer peripheral surface,
A base sheet;
An adhesive layer laminated on one side of the base sheet;
A data carrier body supported by at least one of the base material sheet and the adhesive layer, and capable of recording and reading predetermined information.
The base sheet includes an adherend-like edge along a part of an outer edge of each end face of the shaft core member, a relief edge through which a support shaft fitted into the shaft core member can be inserted, and the relief features and to Lud Takyaria that has a second cutting tolerance portion extending in the adherend similar edge direction from the edge. An elongated shaft core member to which the data carrier according to any one of claims 1 to 3 is attached.

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