JP2011192850A - Sticking device and sticking method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sticking device and a sticking method that form sticking sheets having no gap between them along a longitudinal direction of a belt-like material and stick them on various workpieces. <P>SOLUTION: A mounting device 1 as an example of the sticking device is configured to stick a sticking sheet on a workpiece arranged on a table 80, and includes a belt-like material support mechanism 10 which supports the belt-like material M having a film for sticking sheet formation stuck on one surface of a base sheet, a pre-cutting mechanism 20 which cuts the film according to the size of the workpiece to form sticking sheets which connect along the length of the belt-like material M and are in-line contact with one another, and a sticking mechanism 50 which peels a sticking sheet from the base sheet and sticks the sticking sheet on the workpiece. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a pasting device and a pasting method.

  It is industrially practiced to attach a thin sheet to various workpieces such as fixing various workpieces or attaching a protective sheet to various workpieces. For example, when a semiconductor wafer is diced, the semiconductor wafer is disposed in an inner region of a ring frame, a dicing tape is attached to those surfaces, and the semiconductor wafer is fixed to the ring frame.

  As a method and apparatus for fixing a semiconductor wafer to a ring frame, there is an invention disclosed in Patent Document 1. The invention disclosed in Patent Document 1 includes a supporting means for supporting a strip-shaped material in which a film for forming a dicing tape is attached to a base sheet, and a pre-cutting means for forming a dicing tape by providing a cut on the film surface of the strip-shaped material. And a bonding means for peeling the dicing tape from the base sheet and bonding the dicing tape to the ring frame and the semiconductor wafer.

JP-A-2005-116929

  In Patent Document 1, the dicing tape formed by the precut means is formed in a substantially circular shape corresponding to the shape of the ring frame. The dicing tape is formed by passing a belt-shaped material between a roller having a cutter blade and a die receiver. Here, a roller having a cutter blade similarly formed in a closed loop is used in order to provide a substantially circular cut that is a closed loop in the band-shaped material.

  In order to form a cutter blade having a good blade section in a closed loop on the roller, a necessary minimum gap is provided between adjacent closed loops. This gap is specifically set to about 8 to 10 mm.

  Therefore, when a substantially circular dicing tape is formed by the pre-cutting means as described above, a gap of 8 to 10 mm is generated between adjacent dicing tapes, and the band material is wasted accordingly.

  The present invention has been made in view of the above matters, and an object of the present invention is to provide a sticking apparatus and a sticking method that can form a sticking sheet without gaps in the longitudinal direction of a strip-shaped material and stick it to various workpieces. There is.

The sticking device according to the first aspect of the present invention,
In the sticking device that sticks the sticking sheet on the work placed on the table,
A belt-shaped material support mechanism that supports a belt-shaped material having a film for forming a patch sheet attached to one surface of a base sheet;
A precut mechanism that cuts the film according to the size of the workpiece, forms a pasting sheet that is continuous in the longitudinal direction of the strip-shaped material, and each makes line contact;
A peeling mechanism that peels the sticking sheet from the base sheet, and sticks the sticking sheet to the workpiece; and
It is characterized by that.

Further, the pre-cut mechanism includes a cutting roller having a roller and a blade formed to protrude from the surface of the roller,
It is preferable that a part of the blade has a straight part parallel to the axis of the roller, and the sticking sheet is formed in linear contact with each other by cutting with the straight part.

In addition, the cutting roller is configured by winding a sheet-like blade provided with the blade on a sheet around the roller,
It is preferable that the blade at a position where the both ends of the sheet-shaped blade are in contact with each other by being wound around the roller is formed linearly along the rotation direction of the roller.

In addition, the adhesive sheet is peeled off from the base sheet by winding the belt-like material while being folded back by a release plate, and the adhesive sheet is sent out from the release plate onto the workpiece.
The workpiece is moved in a state in which the application sheet is pressed against the workpiece with an application roller, and the application sheet is attached to the workpiece,
It is preferable to include a control unit that stops the winding of the belt-shaped material earlier than the movement of the workpiece is stopped.

In addition, between the pre-cut mechanism and the bonding mechanism, there is a movable roller that applies tension to the belt-shaped material, and a sensor that detects a position of the movable roller, and tension that applies predetermined tension to the belt-shaped material. With an adjustment mechanism,
It is preferable that the moving speed of the belt-shaped material is adjusted based on the detected position of the movable roller, and the movable roller is held within a predetermined range.

The sticking method according to the second aspect of the present invention is:
In the sticking method of sticking the sticking sheet on the work placed on the table,
Send out a band-shaped material with a film for forming an adhesive sheet attached to one side of the base sheet,
Cutting the film according to the size of the work, continuous in the longitudinal direction of the strip-shaped material, and form a sticking sheet in line contact with each other,
Peeling the sticking sheet from the base sheet, and sticking the sticking sheet to the workpiece;
It is characterized by that.

Further, a cutting roller provided with a roller and a blade formed to protrude from the surface of the roller, and using a cutting roller having a linear portion parallel to the axis of the roller in a part of the blade,
It is preferable to form the sticking sheet in linear contact with each of the cuts by the straight portions.

  In addition, a sheet-shaped blade provided with the blade on a sheet is wound around the roller, and the blade at a position where both ends of the sheet-shaped blade are in contact with each other is formed linearly along the rotation direction of the roller. It is preferable to use the cutting roller.

In addition, the adhesive sheet is peeled off from the base sheet by winding the belt-like material while being folded back by a release plate, and the adhesive sheet is sent out from the release plate onto the workpiece.
The workpiece is moved in a state in which the application sheet is pressed against the workpiece with an application roller, and the application sheet is attached to the workpiece,
It is preferable that the winding of the belt-shaped material is stopped earlier than the movement of the workpiece is stopped.

  In the sticking device according to the present invention, it is possible to form a sticking sheet that is cut in the belt-like material and is continuous in the longitudinal direction of the belt-like material and is in line contact with each other. Since more adhesive sheets can be formed from one roll of strip material, the strip material can be used without waste, and the cost of the strip material can be reduced. Furthermore, since the consumption of the strip-shaped material is reduced, it is effective for resource saving.

It is a schematic block diagram of a mounting apparatus. It is a perspective view of a strip-shaped material. It is a perspective view of a cutting roller. (A) is a top view of a sheet-like cutter, (B) is a side view of a sheet-like cutter. It is a top view of the strip | belt-shaped material in which the sticking sheet was formed. It is a schematic block diagram of a tension adjustment mechanism. (A) is a state diagram when the movable roller is raised to the upper limit position, and (B) is a state diagram when the movable roller is lowered to the lower limit position. (A) is a state diagram when the movable roller overruns the upper limit position, and (B) is a state diagram when the movable roller overruns the lower limit position. It is a top view which shows the state by which the ring frame and the semiconductor wafer were arrange | positioned on the table. (A)-(C) are figures which show the mode of bonding. (A)-(D) are figures which show the mode of bonding. It is a top view which shows the state by which the semiconductor wafer was fixed to the ring frame.

  As a specific example of the sticking device and the sticking method, the mounting device and the mounting method will be described below with reference to the drawings. The mounting apparatus 1 is an apparatus used for fixing the semiconductor wafer W to the ring frame RF when dicing the semiconductor wafer W.

  As shown in FIG. 1, the mount apparatus 1 according to the present embodiment has a belt-shaped material support mechanism 10 that supports a belt-shaped material M in which a film F for forming a patch sheet S is adhered to one surface of a base sheet BS. A pre-cut mechanism 20 that cuts the film F in accordance with the size of the ring frame RF, continuously forms the strip-like material M in series in the longitudinal direction, and forms the adhesive sheet S in contact with each other, and the adhesive sheet And a bonding mechanism 50 that peels S from the base sheet BS, adheres the adhesive sheet S to the ring frame RF and the semiconductor wafer W, and fixes the semiconductor wafer W to the ring frame RF.

  As shown in FIG. 2, the band-shaped material M has a structure in which a film F for forming the adhesive sheet S is attached to one surface of the base sheet BS. The film F is configured to be peelable from the base sheet BS. The belt-shaped material M is wound and supported by a winding roller 11 as the belt-shaped material support mechanism 10 in a roll shape.

  The belt-shaped material M is unwound from the unwinding roller 11 of the belt-shaped material support mechanism 10, passes through the pre-cut mechanism 20, the tension adjustment mechanism 30, and the bonding mechanism 50 in order, and then is wound on the winding roller 70.

  The strip-shaped material M is unwound mainly by the driving roller 60 and the winding roller 70. The drive roller 60 and the take-up roller 70 are each a direction in which the belt-shaped material M is pulled out from the take-out roller 11 as shown by an arrow and is taken up by the take-up roller 70 (hereinafter referred to as a forward direction) by a drive device such as a motor (not shown). It is also driven to rotate.

  The strip-shaped material M drawn from the unwinding roller 11 goes to the precut mechanism 20 via the guide roller 12. The unwinding roller 11 is rotationally driven in a direction opposite to the unwinding direction (hereinafter also referred to as a reverse direction) by a driving device such as a motor (not shown) so that the unrolled belt-like material M is not loosened. .

  The pre-cut mechanism 20 is mainly composed of a cutting roller 21 and a cutter receiving roller 26. The pre-cut mechanism 20 is a mechanism for forming the adhesive sheet S by cutting the film F of the band-shaped material M when the band-shaped material M passes between the cutting roller 21 and the cutter receiving roller 26. The cutting roller 21 is rotationally driven in the forward direction by a driving device (not shown).

  As shown in the perspective view of FIG. 3, the cutting roller 21 has a configuration in which a roller 25 and a blade 24 protruding in a radial direction from the surface of the roller 25 are formed. The blade 24 is formed in a substantially circular closed loop according to the shape of the ring frame RF.

  More specifically, the cutting roller 21 includes a roller 25 such that the sheet-like blade 22 shown in the plan view of FIG. 4A and the side view of FIG. It is configured to be wound around. The sheet-like blade 22 has a structure in which a blade 24 is erected on a sheet 23 and is integrally formed.

  The blade 24 of the sheet-like cutter 22 is formed so that two substantially semicircular arc-shaped blades 24 in plan view are in contact with each other. A straight portion 24a is formed at a location where each arc contacts. The linear portion 24 a is formed so as to be parallel to the axis of the roller 25 when the sheet-like blade 22 is wound around the roller 25.

  As shown in FIG. 4, the sheet-shaped blade 22 is wound around the roller 25, so that both ends of the sheet-shaped blade 22 (the left and right ends in FIGS. 4A and 4B) are in contact with each other. Then, the linear portion 24b and the linear portion 24c of the blade 24 are in contact with each other, and the linear portion 24d and the linear portion 24e of the blade 24 are in contact with each other, so that a substantially circular blade 24 corresponding to the shape of the ring frame RF is formed. . The length of the straight line 24a, the straight line formed by the straight line part 24b and the straight line part 24c, and the straight line formed by the straight line part 24d and the straight line part 24e are not less than the length that can be clearly recognized as a straight line, and the sheet. It is preferable that the length La in the roller rotation direction of the blade 22 and the length Lb from the straight portions 24b and 24c to the straight portions 24d and 24e are longer than the inner diameter of the ring frame RF. Specifically, when the inner diameter of the ring frame RF is circular, if the tangent is drawn to the arc of the blade 24, the straight portions 24a to 24e are parallel to the tangent and 0.1% of the diameter of the circle. It is preferably formed at a position spaced about 3% from the arc toward the center of the circle.

  Further, linear portions 24 b to 24 e are formed on the blades 24 positioned at both ends of the sheet-like cutter 22 along the rotation direction of the roller 25, respectively. Thereby, when winding the sheet-like cutter 22 around the roller 25 and installing it, alignment is easy.

  In the pre-cut mechanism 20, the belt-like material M is passed so that the film F surface of the belt-like material M faces the cutting roller 21, so that the blade 24 is made into a film by pressing and rotation of the cutting roller 21 and the cutter receiving roller 26. Cut into F and cut. Since the length of the blade 24 and the pressing force of the cutting roller 21 are set so that only the film F is cut, the adhesive sheet S is formed with the base sheet BS remaining.

  As the cutting roller 21 makes one rotation, one sticking sheet S is formed. And the cutting roller 21 rotates sequentially, and the some sticking sheet S is continuously formed in the longitudinal direction of the strip | belt-shaped material M. As shown in FIG.

  FIG. 5 shows a plan view of the strip-shaped material M in which the film F is cut by the cutting roller 21 and a plurality of substantially circular adhesive sheets Sa to Se are formed. In the sheet-like cutter 22, the adhesive sheets S are formed so as to be divided by the straight portions 24a of the blades 24. Therefore, the adhesive sheets S are formed in linear contact with the adjacent adhesive sheets S. As an example, the adhesive sheet Sb is formed in line contact with the adhesive sheet Sa and the adhesive sheet Sc in the longitudinal direction of the strip material M, respectively.

  Since each sticking sheet S is formed in contact with each other, the film F does not remain between the sticking sheets Sa to Se. For this reason, since the strip | belt-shaped material M can be used without waste and the number of the sticking sheets S which can be formed from one roll of strip | belt-shaped material M increases, the reduction of the cost of the strip | belt-shaped material M is realizable. Furthermore, since the consumption of the strip-shaped material M is reduced, it is effective for resource saving.

  Furthermore, since the blades 24 positioned on both ends of the roller 25 are linear, the strip-shaped material M having a short width can be used, which is more effective for cost reduction and resource saving.

  The band-shaped material M on which the adhesive sheet S is formed by the pre-cut mechanism 20 as described above goes to the tension adjustment mechanism 30. The tension adjusting mechanism 30 absorbs an error between the feeding speed of the band-shaped material M by the pre-cutting mechanism 20 and the feeding speed of the band-shaped material M by the driving roller 60, and the uniform-cutting sheet S is formed in the aforementioned pre-cutting mechanism 20. In addition, it is a mechanism that applies an appropriate tension to the band-shaped material M so that the band-shaped material M is not loosened in the bonding mechanism described later and the sheet S is easily peeled off from the base sheet BS.

  As shown in FIG. 6, the tension adjustment mechanism 30 mainly includes a movable roller position detection sensor 31, a sensor dog 32, a movable roller 33, and a spring 34.

  The movable roller 33 is suspended via a spring 34 that is an elastic body. The movable roller 33 is supported so as to be swingable in the vertical direction in FIGS. The strip-shaped material M passes above the movable roller 33. The sensor dog 32 is integrally provided so as to follow the movement of the movable roller 33 in the vertical direction without hindering the rotation of the movable roller 33.

  The movable roller position detection sensor 31 includes an upper limit sensor 31a, a common sensor 31b, and a lower limit sensor 31c arranged along the moving direction of the movable roller 33. The upper limit sensor 31a, the common sensor 31b, and the lower limit sensor 31c are sensors that detect the position of the sensor dog 32 provided integrally with the movable roller 33, respectively. The upper limit sensor 31a detects the upper limit position of the sensor dog 32, the lower limit sensor 31c detects the lower limit position of the sensor dog 32, and the common sensor 31b detects the overrun state of the sensor dog.

  For example, when the feeding speed of the strip-shaped material M in the pre-cut mechanism 20 is faster than the feeding speed by the driving roller 60, the movable roller 33 rises as shown in FIG. Then, the sensor dog 32 also rises following the rise of the movable roller 33. In this case, since the upper limit sensor 31a detects the sensor dog 32, the drive of the pre-cut mechanism 20 and / or the drive of the drive roller 60 is controlled. These controls are performed by the control unit 100. As shown by the size of the two arrows in FIG. 7A, the movable roller 33 is moved as shown by the white arrow by making the feed speed of the drive roller 60 relatively faster than the feed speed by the pre-cut mechanism 20. Lower and return to proper position. For example, what is necessary is just to control so that the drive of the cutting roller 21 of the precut mechanism 20 stops.

  On the other hand, when the feeding speed of the strip-shaped material M in the pre-cut mechanism 20 is slower than the feeding speed by the driving roller 60, the movable roller 33 descends as shown in FIG. The sensor dog 32 is also lowered following the lowering of the movable roller 33. In this case, since the lower limit sensor 31c detects the sensor dog 32, the drive of the precut mechanism 20 and / or the drive of the drive roller 60 is controlled. As shown by the size of the two arrows in FIG. 7B, the movable roller 33 is moved as shown by the white arrow by relatively lowering the feed speed of the drive roller 60 than the feed speed by the pre-cut mechanism 20. Ascend and return to proper position. For example, what is necessary is just to control so that the rotational speed of the cutting roller 21 of the pre-cut mechanism 20 may be increased.

  Further, as shown in FIGS. 8A and 8B, when the movable roller 33 is excessively raised or lowered due to some abnormality, the common sensor 31b cannot detect the sensor dog 32. When the common sensor 31b is unable to detect in this way, it may be controlled to notify the abnormality by stopping the driving of the mounting apparatus 1 or by using sound, light, display, or the like, assuming that an abnormality has occurred.

  Any sensor such as an infrared sensor or an ultrasonic sensor may be used as long as the sensor can detect the position of the sensor dog 32. Although the example using the sensor dog 32 has been described, a form in which the position of the movable roller 33 is directly detected may be used.

  The band-shaped material M passes through the tension adjusting mechanism 30 and then passes through the tension roller 41 and the guide roller 42. The tension roller 41 is rotationally driven by a driving device such as a motor (not shown). The tension roller 41 rotates so that a back tension is applied in the reverse direction so that the belt-shaped material M is moderately tensioned in the vicinity of the peeling plate 51 of the bonding mechanism 50 described later.

  Note that the driving unit such as each motor is controlled by the control unit 100 so that the force for feeding the belt-shaped material M in the forward direction by the driving roller 60 is larger than the force for applying the back tension in the reverse direction by the tension roller 41. Yes.

  The band-shaped material M that has passed through the tension roller 41 and the guide roller 42 is subsequently sent to the bonding mechanism 50.

  The bonding mechanism 50 is mainly composed of a peeling plate 51 and a bonding roller 52. The pasting mechanism 50 is a mechanism for pasting the pasting sheet S peeled from the base sheet BS by the peeling plate 51 to the ring frame RF and the semiconductor wafer W placed on the table 80 by the pasting roller 52.

  The table 80 is a table on which a substantially annular ring frame RF and a substantially circular semiconductor wafer W are placed. The table 80 is configured to be movable inwardly-outwardly (in the left-right direction in FIG. 1) of the mounting device 1 below the sticking roller 52.

  As shown in FIG. 9, the ring frame RF and the semiconductor wafer W are placed on the table 80 so that the semiconductor wafer W is disposed in the inner region of the ring frame RF. Each of the ring frame RF and the semiconductor wafer W is placed at a predetermined position on the table 80. For example, it is configured to be placed at a fixed position by a positioning pin protruding from the upper surface of the table 80 or a depression provided on the upper surface of the table. Further, an adsorption hole is provided on the upper surface of the table 80 so that it does not shift when the adhesive sheet S is adhered, and the ring frame RF and the semiconductor wafer W are held at predetermined positions of the table 80 by a decompression pump. May be.

  Next, the bonding process will be described with reference to FIGS. 10 and 11. First, the ring frame RF and the semiconductor wafer W are mounted on the table 80 as described above with the table 80 protruding outward from the mounting apparatus 1.

  Then, as shown in FIG. 10A, the table 80 moves inward of the mounting apparatus 1. Further, the front end portion of the sticking sheet Sa is peeled off from the base sheet BS and protruded from the peeling plate 51 until reaching the lower side of the sticking roller 52. Since the strip-shaped material M is rapidly reversed by the peeling plate 51 and wound while being folded back, the adhesive sheet Sa is peeled from the base sheet BS. Note that the sensor 90 detects that the adhesive sheet Sa has been normally peeled from the base sheet BS.

  Then, as shown in FIG. 10B, the table 80 stops when the end of the ring frame RF reaches below the sticking roller 52.

  Thereafter, as shown in FIG. 10C, the sticking roller 52 is lowered. By the pressing of the sticking roller 52, the end of the sticking sheet Sa is stuck to the ring frame RF.

  Subsequently, as shown in FIGS. 11A and 11B, the table 80 moves to the outside of the mounting device 1 while the pressing of the sticking roller 52 is maintained. As the table 80 moves, the ring frame RF and the semiconductor wafer W also move. Since the table 80 moves in a state where the adhesive sheet Sa is sent out from the release plate 51 and the pressure of the adhesive roller 52 is maintained, the adhesive sheet Sa is sequentially rotated with the ring frame RF and the semiconductor wafer while the adhesive roller 52 rotates. It will be affixed to W. In addition, the sticking sheet Sa is sent out at substantially the same speed in synchronization with the moving speed of the table 80.

  And as shown in FIG.11 (C), if the sticking roller 52 moves to the right end part vicinity of sticking sheet Sa, sending-out of sticking sheet Sa will be stopped. In this state, the table 80 continues to move (move to the left in the figure).

  In this way, it is preferable to stop the feeding of the adhesive sheet Sa earlier than the movement of the table 80. Since the adhesive sheets Sa and Sb are formed in contact with each other on the belt-like material M, if the movement of the table 80 and the feeding of the adhesive sheet Sa are stopped simultaneously, the adhesive sheet Sb in contact with the adhesive sheet Sa The end portion may be sent out and may be pressed by the sticking roller 52.

  Note that the control unit 100 stops the feeding of the adhesive sheet Sa earlier than the movement of the table 80 is stopped.

  Even if the feeding of the adhesive sheet Sa is stopped earlier than the stop of the movement of the table 80, the majority of the adhesive sheet Sa is already adhered to the ring frame RF and the semiconductor wafer W, so that the movement of the table 80 is not performed. Accordingly, the adhesive sheet Sa is separated so as to be peeled off from the base sheet BS.

  Then, as shown in FIG. 11D, when the table 80 further moves and the right end of the ring frame RF reaches below the sticking roller 52, the movement of the table 80 stops. And the sticking roller 52 raises and sticking is completed.

  The strip-shaped material M from which the patch sheet S has been peeled is taken up by the take-up roller 70 via the guide rollers 54, 61, 62 and 63.

  FIG. 12 shows a state where the application of the application sheet S is completed and the semiconductor wafer W is fixed to the ring frame RF.

  The rotation driving of the unwinding roller 11, the cutting roller 21, the tension roller 41, the driving roller 60 and the winding roller 70 and the linear movement of the table 80 are each driven by a driving device such as a motor (not shown). However, these are performed in synchronization with the control by the control unit 100.

  In the above embodiment, the mounting apparatus and mounting method for fixing the semiconductor wafer W to the ring frame RF using the adhesive sheet S have been described. However, the present invention is not limited to the above embodiment. For example, it can be used when a protective film is attached to a liquid crystal screen or the like. That is, by replacing the semiconductor wafer W and / or the ring frame in the above-described embodiment with various works, the present invention can be applied to the sticking of adhesive sheets to various works.

DESCRIPTION OF SYMBOLS 1 Mount apparatus 10 Strip | belt-shaped material support mechanism 11 Unwinding roller 12 Guide roller 20 Pre-cut mechanism 21 Cutting roller 22 Sheet-like blade 23 Sheet 24 Blades 24a-24e Linear part 25 Roller 26 Cutter receiving roller 27 Guide roller 30 Tension adjustment mechanism 31 Movable roller Position detection sensor 31a Upper limit sensor 31b Common sensor 31c Lower limit sensor 32 Sensor dog 33 Movable roller 34 Spring 41 Tension roller 42 Guide roller 50 Laminating mechanism 51 Peeling plate 52 Pasting roller 53, 54 Guide roller 60 Driving roller 61, 62, 63 Guide roller 70 Winding Roller 80 Table 90 Peeling Detection Sensor 100 Control Unit RF Ring Frame (Work)
W Semiconductor wafer (work)
M Band-shaped material F Film BS Base sheet S, Sa ~ Se Paste sheet

Claims (9)

In the sticking device that sticks the sticking sheet on the work placed on the table,
A belt-shaped material support mechanism that supports a belt-shaped material having a film for forming a patch sheet attached to one surface of a base sheet;
A precut mechanism that cuts the film according to the size of the workpiece, forms a pasting sheet that is continuous in the longitudinal direction of the strip-shaped material, and each makes line contact;
A peeling mechanism that peels the sticking sheet from the base sheet, and sticks the sticking sheet to the workpiece; and
A sticking device characterized by that. The pre-cut mechanism includes a cutting roller having a roller and a blade formed to protrude from the surface of the roller,
2. The adhesive sheet according to claim 1, wherein a part of the blade has a linear part parallel to the axis of the roller, and the adhesive sheet is formed in linear contact with each other by cutting with the linear part. Pasting device. The cutting roller is configured by winding a sheet-like blade provided with the blade on a sheet around the roller,
The sticking according to claim 2, wherein the blade is wound around the roller, and the blade at a position where both ends of the sheet-shaped blade are in contact with each other is formed linearly along the rotation direction of the roller. apparatus. The adhesive sheet is peeled off from the base sheet by winding the belt-like material while being folded back on a release plate, and the adhesive sheet is sent out from the release plate onto the workpiece.
The workpiece is moved in a state in which the application sheet is pressed against the workpiece with an application roller, and the application sheet is attached to the workpiece,
The sticking apparatus according to any one of claims 1 to 3, further comprising a control unit that stops the winding of the belt-shaped material earlier than the movement of the workpiece is stopped. A tension adjusting mechanism that includes a movable roller that applies tension to the belt-shaped material and a sensor that detects the position of the movable roller between the pre-cut mechanism and the bonding mechanism, and applies a predetermined tension to the belt-shaped material. With
The sticking according to any one of claims 1 to 4, wherein the moving speed of the belt-shaped material is adjusted based on the detected position of the movable roller, and the movable roller is held within a predetermined range. apparatus. In the sticking method of sticking the sticking sheet on the work placed on the table,
Send out a band-shaped material with a film for forming an adhesive sheet attached to one side of the base sheet,
Cutting the film according to the size of the work, continuous in the longitudinal direction of the strip-shaped material, and form a sticking sheet in line contact with each other,
Peeling the sticking sheet from the base sheet, and sticking the sticking sheet to the workpiece;
The sticking method characterized by this. A roller and a blade formed to protrude from the surface of the roller, and using a cutting roller having a linear portion parallel to the axis of the roller in a part of the blade,
The sticking method according to claim 6, wherein the sticking sheet is formed in linear contact with each other by cutting with the straight part.   A sheet-shaped blade provided with the blade on a sheet is wound around the roller, and the blade at a position where both ends of the sheet-shaped blade are in contact with each other is formed linearly along the rotation direction of the roller The sticking method according to claim 7, wherein a cutting roller is used. The adhesive sheet is peeled off from the base sheet by winding the belt-like material while being folded back on a release plate, and the adhesive sheet is sent out from the release plate onto the workpiece.
The workpiece is moved in a state in which the application sheet is pressed against the workpiece with an application roller, and the application sheet is attached to the workpiece,
The sticking method according to any one of claims 6 to 8, wherein winding of the belt-shaped material is stopped earlier than stop of movement of the workpiece.

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