TWI508787B - Adhesion mechanism - Google Patents

Description

Adhesive mechanism

The invention relates to an attachment device for an anisotropic conductive film, in particular to a sticking mechanism of the attaching device for using an anisotropic conductive film that is not used from a roll of anisotropic The conductive film is adhered to a recovery tape.

It is a common assembly technique to adhere a flexible substrate to a rigid substrate (circuit board or liquid crystal panel) by an anisotropic conductive paste (ACF) to electrically connect the flexible substrate to the rigid substrate. For automated continuous operation, the flexible substrate is fabricated in a tape form for convenient continuous transport, such as a COF tape using a Chip On Film (COF) package. The anisotropic conductive adhesive is also formed into a tape form, and is generally called an anisotropic conductive film. The tape-type anisotropic conductive film has two layers, one is a release tape, and the other is an anisotropic conductive tape attached to the release tape.

The COF tape is continuously conveyed to a punching device, and the punching device punches out a piece of COF sheet from the COF tape, and the tape-type anisotropic conductive film is continuously Transfer to a cutting device. The cutting device cuts the anisotropic conductive tape on the anisotropic conductive film at intervals, and cuts only the anisotropic conductive tape without cutting the release tape, so that the alien The conductive tape becomes a piece of time, and each segment is an anisotropic conductive film. Such a cutting device can refer to patents such as Taiwan I332897, I375843, I383718 and I411505.

The anisotropic conductive film that passes through the cutting device is then sent to an attachment device. Some of these anisotropic conductive films are pre-applied to COF sheets, while others are not used and need to be peeled off. Further, the attaching device attaches the anisotropic conductive film on the anisotropic conductive film to be attached to the COF sheet to the corresponding COF sheet, and these have been attached to the anisotropy. The COF sheet of the conductive film is then conveyed to a thermal compression apparatus, and a predetermined number of COF sheets are bonded to the liquid crystal panel by the thermal compression apparatus. In addition, the attaching device also adheres the anisotropic conductive film which is not used from the anisotropic conductive film to a recovery tape by the adhesive mechanism before performing the aforementioned attaching operation. The sticking mechanism can be referred to the mechanism of the peeling wheel, the adhesive tape supply wheel and the adhesive tape collecting wheel in the figure 9 of the Taiwan Patent No. I419244.

The invention provides a new and easy to disassemble and attaching adhesive mechanism, which is mainly used for adhering an anisotropic conductive film on an anisotropic conductive film to a recycling belt. More specifically, the adhesive mechanism of the present invention includes a base, a cutting board fixed to one side of the base, a blocking frame fixed to the cutting board, and a movable seat which is disposed on the base forward and backward. a mounting plate fixed to the base for driving the movable seat to move back and forth, and an assembly plate detachably disposed on the movable seat, a discharge shaft pivoted on the assembly plate and capable of rotating a receiving shaft, a sticking block fixed to the assembly board and having one end facing the cutting board, and a recovery belt driving device disposed on the movable seat for driving the receiving shaft to rotate. Wherein, the blocking frame has a through hole facing the anvil and maintaining a gap with the anvil, the gap for the anisotropic conductive film to pass. The discharge shaft is used to install a roll of the recovery belt for winding the recovery belt around the stick. When the movable seat moves forward from a point to an end point, the recovery belt passing through the end of the adhesive block passes through the through hole of the blocking frame and presses the anisotropy on the anisotropic conductive film. Conductive film.

The adhesive mechanism of the present invention further includes a quick release handle, and the assembly plate has a plurality of bolt holes and a through hole, the movable seat has a plurality of fixing tips which can form a plane, a bolt and a suction plate for sucking the assembly board a magnetic block. The fixing tips correspond to the bolt holes penetrating into the assembly board, and one end of the bolt corresponds to the through hole passing through the assembly board, and the quick release handle is screwed to the end of the bolt.

Preferably, the adhesive mechanism further comprises an active coupling portion pivoted on the movable seat and a driven coupling portion pivoted on the movable seat, wherein the recovery belt driving device is connected to the active coupling The coupling portion is driven to rotate; the adhesive block is located in front of the assembly plate, the receiving shaft has a receiving section in front of the assembly board and is used for winding the recovery belt and a receiving coupling behind the assembly board a receiving joint that engages the active coupling; the discharge shaft There is a discharge section located in front of the assembly board for mounting the roll recovery belt and a discharge coupling section located behind the assembly board, the discharge coupling portion being engaged with the driven coupling portion. More preferably, the active coupling portion, the driven coupling portion, the receiving coupling portion and the discharge coupling portion each have two engaging blocks, each of which has a semi-arc shape and each has a slope and a constant The opposite sides of the straight faces of each of the engaging blocks respectively follow the high side of the inclined surface of one of the engaging blocks and the lower side of the inclined surface of the other engaging block.

The adhesive mechanism of the present invention further includes a damper fixed to the movable seat, the damper connecting the driven coupling portion and providing a resistance to the driven coupling portion.

Furthermore, the adhesive mechanism of the present invention further includes a receiving cover and a discharge cover; the receiving shaft further has a screwing section extending forward from the receiving section, the receiving cover is snail The screwing section of the take-up shaft; the discharge shaft further has a screwing section extending forward from the discharge section, the discharge cover being screwed to the screwing section of the discharge shaft.

In addition, the sticking mechanism of the present invention may further include two guide rods disposed on the assembly board and respectively located beside the receiving shaft and the discharge shaft, the receiving shaft being located directly above the discharge shaft, located at the The guide bar next to the take-up shaft is directly above the guide bar located beside the discharge shaft. More preferably, the guide rod located beside the take-up shaft is rotatable, and the guide rod located beside the discharge shaft is fixed.

Compared with the prior art, the above-mentioned adhesive mechanism of the present invention can not only adhere the anisotropic conductive film which is not used on the tape-type anisotropic conductive film to the recovery tape in a sticky manner, but only borrows By the rotation of the quick release handle, the receiving shaft and the discharging shaft can be detached from the movable seat together with the assembled plate or assembled, and the whole disassembly and assembly process is relatively simple and fast.

Other inventive aspects and more detailed technical and functional descriptions of the present invention are disclosed in the following description.

1‧‧‧Base

11‧‧‧ drive

10, 111‧‧‧ slide rails

2‧‧‧ activity seat

21‧‧‧floor

210, 211‧‧‧ slide

22‧‧‧ top board

23‧‧‧ Fixed tip

24‧‧‧Magnetic blocks

25‧‧‧ bolt

26‧‧‧Stile

261‧‧‧ screws

27‧‧‧ Quick release handle

3‧‧‧Active Linkage

30‧‧‧Recycling belt drive

300‧‧‧Support board

31‧‧‧ Engagement block

310‧‧‧Bevel

311‧‧‧ Face to face

4‧‧‧ Driven Linkage

40‧‧‧damper

400‧‧‧Box board

41‧‧‧ Engagement block

410‧‧‧Bevel

411‧‧‧ Face to face

5‧‧‧ Assembly board

50‧‧‧Bolt hole

500‧‧‧Recycling belt

51‧‧‧Perforation

52‧‧‧guides

53‧‧‧guides

54‧‧‧Stained

55‧‧‧ Gears

6‧‧‧ receiving shaft

600‧‧‧ receiving section

601‧‧‧ screwing section

602‧‧‧Receipt Linkage

61‧‧‧ Engagement block

610‧‧‧Bevel

611‧‧‧ Face to face

62‧‧‧ receiving cover

7‧‧‧Discharge shaft

700‧‧‧Discharge section

701‧‧‧Spinning section

702‧‧‧Distribution Linkage

71‧‧‧ Engagement block

710‧‧‧ Face to face

711‧‧‧ Bevel

72‧‧‧Discharge cover

60, 70, 501‧ ‧ bearings

8‧‧‧Chopping board

80‧‧‧Barrier

9‧‧‧Reel tape type anisotropic conductive film

90‧‧‧ release belt

91‧‧‧ anisotropic conductive tape

910, 911‧‧‧ anisotropic conductive film

The first figure is a perspective view of a preferred embodiment of the adhesive mechanism of the present invention.

The second and third figures are perspective exploded views of the preferred embodiment of the present invention.

Figure 4 is a plan view of the preferred embodiment of the present invention.

The fifth figure is a schematic structural view of an anisotropic conductive film 9.

6 to 9 are schematic views of the operation of the preferred embodiment of the present invention.

1 to 3 show a preferred embodiment of the adhesive mechanism of the present invention, comprising a base 1, a movable seat 2 disposed on the base 1 and movable, and being disposed on the base 1 for driving the movable seat 2, a driving device 11 for moving, a cutting board 8 fixed to one side of the base 1, and a blocking frame 80 fixed to the cutting board 8 in parallel. As shown in the third figure, one side of the base 1 is provided with two slide rails 10, 111, and a bottom plate 21 of the movable base 2 is provided with two slide seats 210, 211, which are respectively correspondingly slided on the two slide rails 10, 111, in this manner, the movable seat 2 can move closer to the cutting block 8 or move away from the cutting block 8 relative to the base 1. The driving device 11 preferably uses a two-axis slide cylinder (or a slide cylinder) that fixes the face of the base 1 for driving the movable seat 2 for the aforementioned movement. In this example, the aforementioned slide rail 111 and slide 211 are essentially the slide portion of the two-axis slide cylinder. In addition, the barrier frame 80 also has a through hole 800 facing the anvil 8 and maintaining a gap with the anvil 8.

As shown in the first and second figures, the above-mentioned adhesive mechanism of the present invention further includes an assembly plate 5, a receiving shaft 6 pivoted on the assembly plate 5 and a discharge shaft 7, and a fixing shaft 7 A bonding block 54 of the assembly board 5 and having one end facing the anvil board 8, preferably further comprising two guiding rods 52 disposed on the assembly board 5 and located beside the receiving shaft 6 and the discharge shaft 7 respectively, 53. The assembly board 5 is detachably assembled to a top plate 22 of the movable seat 2. Specifically, the adhesive mechanism further includes a quick release handle 27, and the top plate 22 of the movable seat 2 is provided with a plurality of components. a flat fixed tip 23 (for example, a flat surface formed by three fixed tips 23), a bolt 25 capable of being screwed with the quick release handle 27, and two magnetic blocks 24 (only one or more may be provided), The assembly board 5 is provided with a plurality of bolt holes 50 for the corresponding fixing tips 23 to penetrate correspondingly, and a through hole 51 is provided for one end of the bolt 25 to pass through. Therefore, the assembly board 5 is easily assembled to the top board 22 Up, and supported by the fixed tip 23, at this time, the two magnet blocks 24 can also hold the metal assembled board 5 by their magnetic force, so that the assembled board 5 is more stably mounted on the top board 22. Finally, the quick release handle 27 is rotated to screw it to the end of the bolt 25, and the assembly of the assembled panel 5 is completed. When the assembly plate 5 needs to be disassembled, the assembly plate 5 can be detached from the top plate 22 of the movable base 2 by simply rotating the quick release handle 27 in the opposite direction to disengage the handle 25. The aforementioned disassembly and assembly process is simple and rapid.

As shown in the second and third figures, the receiving shaft 6 and the discharging shaft 7 are respectively by one axis. The bearings 60, 70 are pivotally mounted on the assembly plate 5, and the take-up shaft 6 is located above the discharge shaft 7. The discharge shaft 7 has a discharge section 700 located in front of the assembly panel 5 for mounting a roll of the recovery belt 500, and a discharge coupling portion 702 located behind the assembly panel 5. The discharge coupling portion 702 has two engaging blocks 71. Each of the engaging blocks 71 has a semi-arc shape and each has a sloped surface 711 and a straight surface 710. The opposite sides of the straight surface 710 of each of the engaging blocks 71 are respectively engaged with one of the engaging edges. The high side of the inclined surface 711 of the block 71 and the lower side of the inclined surface 711 of the other engaging block 71. In addition, the discharge shaft 7 further has a screwing section 701 extending forward from the discharge section 700. The sticking mechanism of the present invention further includes a discharge cover 72 that can be screwed to the screwing section 701. The cover plate 72 is used to prevent the recovery belt 500 from being detached from the discharge section 700.

The take-up shaft 6 has a receiving section 600 located in front of the assembled panel 5 for winding up the recovery belt 500 and a receiving joint 602 located behind the assembled panel 5. The receiving coupling portion 602 has two engaging blocks 61. Each of the engaging blocks 61 has a semi-arc shape and each has a sloped surface 610 and a straight surface 611. The opposite sides of the straight surface 611 of each of the engaging blocks 61 are respectively engaged with one of the engaging edges. The high side of the ramp 610 of the block 61 and the lower side of the ramp 610 of the other engaging block 61. In addition, the receiving shaft 6 further has a screwing section 601 extending forward from the receiving section 600. The sticking mechanism of the present invention further includes a receiving cover 62 that can be screwed to the screwing section 601. The cover plate 62 serves to prevent the recovery belt 500 that has been taken up in the receiving section 600 from being detached.

As shown in the third figure, one of the guide rods 52 is pivotally mounted on the assembly plate 5 by a bearing 501, and thus is rotatable, and the other guide rod 53 is fixed to the assembly plate 5. Further, one end of the guide rod 52 has a gear 55 which is located behind the assembly plate 5 and is rotatable together with the guide rod 52.

The adhesive mechanism of the present invention, as shown in the second and third figures, further includes an active coupling portion 3 pivoted on a support plate 300 of the movable base 2 and pivoted on a frame plate 400 of the movable base 2. The driven coupling portion 4 and the recovery belt driving device 30 fixed to the support plate 300 preferably further include a damper 40 fixed to the frame plate 400. The support plate 300 is connected and fixed to the top plate 22 of the movable seat 2 by a plurality of bolts 26 and screws 261. The frame plate 400 is fixed to the bottom plate 21 of the movable seat 2. The active coupling portion 3 is correspondingly engaged with the receiving coupling portion 602, and the driven coupling portion 4 is correspondingly engaged with the discharging coupling portion 702, as shown in the fourth figure. Preferably, the recovery belt drive unit 30 is provided with a motor whose shaft is coupled to the active coupling portion 3 and which is driven to rotate. The damper 40 (e.g., a rotary damper) is coupled to the driven coupling portion 4 by its shaft and provides appropriate resistance to the driven coupling portion 4 to prevent excessive rotation of the driven coupling portion 4 due to inertia.

As shown in the second figure, the active coupling portion 3 has two engaging blocks 31, each of which has a semi-arc shape and each has a beveled surface 310 and a straight surface 311, and two opposite sides of the straight surface 311 of each of the engaging blocks 31. The sides are respectively connected to the high side of the inclined surface 310 of one of the engaging blocks 31 and the lower side of the inclined surface 310 of the other engaging block 31.

The driven coupling portion 4 also has two engaging blocks 41, each of which has a semi-arc shape and each has a slope 410 and a straight surface 411, and the opposite sides of the straight surface 411 of each of the engaging blocks 41 are respectively connected to one of the opposite sides. The high side of the ramp 410 of the engaging block 41 and the lower side of the ramp 410 of the other engaging block 41.

As shown in the fourth figure, when the assembly board 5 is assembled to the top panel 22 of the movable seat 2, the beveling surface 310 on the active coupling portion 3, the driven coupling portion 4, the receiving coupling portion 602, and the discharge coupling portion 702, Guided by 410, 610 and 711, the active coupling portion 3 can be quickly engaged with the receiving coupling portion 602, and the driven coupling portion 4 can also be quickly engaged with the discharge coupling portion 702. When the recovery belt driving device 30 drives the active coupling portion 3 to rotate under the control of a control system (for example, a PLC control system), the receiving shaft 6 is synchronously rotated by the transmission of the receiving coupling portion 602, in short The recovery belt driving device 30 drives the receiving shaft 6 to rotate by the interlocking of the active coupling portion 3 and the receiving coupling portion 602, thereby performing a winding operation.

As shown in the fifth figure, a tape-type anisotropic conductive film 9 includes a release tape 90 and an anisotropic conductive tape 91 attached to the release tape. Since the tape-type anisotropic conductive film 9 is cut by a cutting device, the anisotropic conductive tape 91 on the tape-type anisotropic conductive film 9 has been cut into a plurality of different shapes. The square conductive films 910, 911, those anisotropic conductive films 910 that are prepared for attachment will be attached to the corresponding COF sheets in an attachment operation subsequently performed by an attachment device (not shown). (or other items, depending on the implementation), and those anisotropic conductive films 911 that are not used must be stripped before the attaching operation is performed. This stripping operation is adhered to by the present invention. The mechanism is implemented by the above-mentioned base 1 being assembled to the attachment device as part of it.

Referring to the sixth and seventh figures, after the recovery belt 500 is pulled out from the discharge shaft 7, it is sequentially wound around one end of the adhesive block 54, the guide rod 53 and the guide rod 52, and then connected to the receiving shaft 6. Section 600. Further, the tape-type anisotropic conductive film 9 that has passed through the cutting operation is conveyed through the gap between the anvil 8 and the barrier 80. When an unshaped anisotropic conductive film 911 on the tape-type anisotropic conductive film 9 reaches the cutting board 8, the driving device 11 is controlled by the control system. Under the system, the movable seat 2 is driven to move back and forth. When the movable seat 2 moves forward and approaches the cutting block 8, the adhesive block 54 will move forward, and thus press against the anisotropic conductive film 911 on the cutting block 8 (not used), as in the first As shown in Fig. 8, at this time, the recovery tape 500 at the end of the adhesive block 54 adheres to the anisotropic conductive film 911 by its own viscosity. When the movable seat 2 moves backward and leaves the cutting block 8, the adhesive block 54 and the recovery tape 500 thereon are moved backward, and the tape-type anisotropic conductive film 9 is blocked by the blocking frame 80, just now. The adhered anisotropic conductive film 911 is peeled off from the release tape 90 and adhered to the recovery tape 500 as shown in FIG. Next, the recovery belt driving device 30 drives the receiving shaft 6 to rotate, so that the receiving shaft 6 performs the winding operation of the winding recovery belt 500. At this time, the anisotropy which is previously peeled off and adhered to the recovery belt 500 The conductive film 911 is taken up by the take-up shaft 6 along with the recovery belt 500. When the next anisotropic conductive film 911 is transported to the anvil 8 and is facing the end of the sticking block 54, the driving device 11 will drive the movable seat 2 to move back and forth again, and the recovery belt driving device 30 will drive the receiving again. The shaft 6 is rotated, and as with the foregoing, the next anisotropic conductive film 911 is peeled off from the release belt 90 by the recovery belt 500, and is taken up and received by the take-up shaft 6.

As apparent from the above description, the adhering mechanism of the present invention adheres the anisotropic conductive film 911 which is not used on the tape-type anisotropic conductive film 9 to the recovery tape 500 in a sticky manner. Furthermore, the sticking mechanism of the present invention can remove the take-up shaft 6 and the discharge shaft 7 together with the assembly plate 5 from the movable seat 2 or assemble them by the rotation of the quick release handle 27, and the entire assembly is removed. The loading process is simple and fast.

1‧‧‧Base

10‧‧‧Slide rails

2‧‧‧ activity seat

21‧‧‧floor

22‧‧‧ top board

23‧‧‧ Fixed tip

24‧‧‧Magnetic blocks

25‧‧‧ bolt

26‧‧‧Stile

27‧‧‧ Quick release handle

300‧‧‧Support board

5‧‧‧ Assembly board

52‧‧‧guides

53‧‧‧guides

54‧‧‧Stained

6‧‧‧ receiving shaft

62‧‧‧ receiving cover

7‧‧‧Discharge shaft

72‧‧‧Discharge cover

8‧‧‧Chopping board

80‧‧‧Barrier

Claims (8)

An adhesive mechanism for adhering an anisotropic conductive film on an anisotropic conductive film to a recovery tape, the adhesion mechanism comprising: a base; a cutting board fixed on one side of the base a blocking frame fixed to the cutting board and having a through hole facing the cutting board, and maintaining a gap with the anvil plate, the gap is for the anisotropic conductive film to pass; a movable seat can be moved forward and backward The base is adapted to approach the cutting edge of the base when the movable seat moves forward, and is away from the cutting block of the base when the movable seat moves backward; a driving device is fixed on the base for driving The movable seat is moved before and after; an assembly board is detachably and detachably mounted on the movable seat; a discharge shaft is pivoted on the assembly plate to be rotatable, and is used for installing a roll of the recovery belt; a sticking block fixed to the assembly board and having one end facing the cutting board. When the movable seat moves forward from a point to an end point, the recycling belt passing through the end of the sticking block passes through the blocking frame The through hole and the anisotropy against the anisotropic conductive film An electric film; a receiving shaft pivoted on the assembly board to be rotatable and used for winding the recovery belt around the adhesive block; and a recovery belt driving device disposed on the movable seat and used for The receiving shaft is driven to rotate. The adhesive mechanism of claim 1, further comprising a quick release handle, the assembly plate having a plurality of bolt holes and a through hole, the movable seat having a plurality of fixing tips and a bolt capable of forming a plane and a magnetic block for sucking the assembly board, wherein the fixing tips correspond to the plurality of bolt holes penetrating into the assembly board, and one end of the bolt corresponds to the through hole passing through the assembly board, and the quick release handle is snail Fit to the end of the bolt. The adhesive mechanism of claim 2, further comprising an active coupling portion pivoted on the movable seat and a driven coupling pivoted on the movable seat, wherein the movable coupling portion is pivoted The recovery belt driving device is connected to the active coupling portion and drives it to rotate; the adhesive block is located in front of the assembly board, and the receiving shaft has a receiving section located in front of the assembly board and used for winding the recovery belt and a receiving joint located behind the assembly board, the receiving joint is engaged with the active joint; the discharge shaft has a discharge section located in front of the assembly board for mounting the roll recovery belt and located at the A discharge coupling portion behind the assembly plate, the discharge coupling portion is engaged with the driven coupling portion. The viscous mechanism of claim 3, wherein the active coupling portion, the driven coupling portion, the receiving coupling portion and the discharge coupling portion each have two engaging blocks, each of the engaging blocks being The semi-arc shape has a beveled surface and a straight surface, and the opposite sides of the straight faces of each of the engaging blocks respectively follow the high side of the inclined surface of one of the engaging blocks and the lower side of the inclined surface of the other engaging block. The viscous mechanism of claim 3, further comprising a damper fixed to the movable seat, the damper connecting the driven coupling portion and providing a resistance to the driven coupling portion. The viscous mechanism of claim 3, further comprising a receiving cover and a discharge cover; the receiving shaft further has a screwing section extending forward from the receiving section, the receiving The material cover is screwed to the screwing section of the receiving shaft; the discharge shaft further has a screwing section extending forward from the discharging section, and the discharging cover is screwed to the discharging shaft The screwing section. The sticking mechanism of claim 1, comprising two guiding rods disposed on the assembly board and respectively located beside the receiving shaft and the discharging shaft, the receiving shaft being located on the discharging shaft Directly above, the guide bar located next to the take-up shaft is directly above the guide bar located beside the discharge shaft. The viscous mechanism of claim 7, wherein the guide bar located beside the receiving shaft is rotatable, and the guide bar located beside the discharge shaft is fixed.