JP4525170B2 - Manufacturing method of flexible printed wiring board and flexible printed wiring board manufactured using the same - Google Patents

Description

  The present invention relates to a method for manufacturing a flexible printed wiring board on which various surface-mount type electronic components are mounted and embedded in an electronic device, and a flexible printed wiring board manufactured using the method.

  In recent years, flexible printed wiring boards having flexibility have been used as components constituting electronic circuits of various electronic devices. As a method for producing a flexible printed wiring board, first, a copper clad laminate for a flexible printed wiring board (hereinafter referred to as copper for FPC) in which a copper foil is bonded to one or both sides of a base film made of a polyimide film or the like using an adhesive or the like. The copper foil of the FPC copper-clad laminate is selectively etched into a predetermined pattern to form a conductor pattern. Next, after covering the surface of the conductor pattern with an insulating protective material having an opening for component mounting, the surface of the conductor pattern exposed from the opening for component mounting is subjected to surface treatment by plating or solder paste printing. Finally, external processing is performed using a mold or the like to produce a flexible printed wiring board having a predetermined shape.

Here, as a method of forming an insulating protective material on the surface of the conductor pattern, either a method of sticking an insulating coverlay film with an adhesive or a method of pattern printing the cover coat ink by a screen printing method or the like In general, a coverlay film is used when the flexible printed wiring board needs to have bending resistance. In addition, as a method for forming an insulating protective material using a coverlay film, a coverlay film having a predetermined shape, which has an adhesive layer on one side in advance and punched out, is formed into a conductor pattern and individualized to a predetermined size. A method of so-called batch processing, in which thermocompression bonding is performed on a base film (hereinafter referred to as a film wiring board), has been mainly described, for example, in (Patent Document 1). (Patent Document 1) describes a method in which a press reinforcing material or a release film is provided between a pair of hot plates, and a sheet-like coverlay film that is individualized on the film wiring board is thermocompression bonded and laminated. .
JP 59-100588 A

  However, the above conventional techniques have the following problems.

  (1) In the method described in (Patent Document 1), since a sheet-like cover lay film is laminated on an individual sheet-like film wiring board, a film for a hot press device is provided each time thermocompression bonding is performed. It was necessary to attach and remove the wiring board and the coverlay film, and there was a problem that work was complicated and productivity was lacking.

  (2) In addition, it is also possible to perform thermocompression bonding of the coverlay film to a plurality of film wiring boards in a batch using a multi-stage press. In this case, the temperature of the plurality of film wiring boards during pressurization and There was a problem that the difference in pressure distribution became large, the quality varied, and a large facility was required.

(3) Further, in the plating process, since it is necessary to perform plating on the exposed portion of the conductor pattern on the sheet-like film wiring board, the film wiring board is individually plated one by one, and the work is complicated. In addition to the lack of productivity, the quality of the plating film is not stable and the quality is poor.

  In (4) (Patent Document 1), a release film is used to prevent the coverlay film from sticking to the hot plate, but the release film is made of synthetic resin and has a thickness. Has cushioning properties as well as moldability. Accordingly, when the coverlay film is thermocompression bonded, unevenness is generated on the surface of the coverlay film at a portion where the wiring density of the conductor pattern is high, and the thicknesses of the adhesive layers on the upper surface and the lower surface of the conductor pattern are greatly different. In particular, if the thickness of the adhesive layer on the upper surface and the lower surface of the conductor pattern is greatly different at the bent portion of the flexible printed wiring board, there is a problem that the bending resistance is remarkably lowered.

  SUMMARY OF THE INVENTION The present invention solves the above-mentioned conventional problems, and is capable of producing a flexible printed wiring board having uniform quality and excellent bending resistance by using a roll-to-roll method without complicated operations and stability of quality. It aims at providing the manufacturing method of the outstanding flexible printed wiring board.

  Another object of the present invention is to provide a flexible printed wiring board having excellent bending resistance even when the wiring density of the conductor pattern at the bent portion is high.

In order to solve the above-mentioned problems, a method for producing a flexible printed wiring board according to the present invention is a method for producing a flexible printed wiring board using a roll-to-roll method, in which a plurality of conductor patterns are formed on at least one side. A first film feeding step of winding the base film from one reel while winding the base film from the other reel, and a cover having a predetermined shape having a thermosetting adhesive layer on one side with respect to the conductor pattern of the delivered base film a positioning step of positioning the lay film, a temporary bonding step of sequentially temporarily adhered to the base film coverlay film to cover the conductive material pattern, while feeding from one reel cover lay film is a base film which is temporarily adhered on the other hand A second film feeding step to be wound up by a reel and a temporarily attached coverlay A structure comprising: a thermocompression process for sequentially thermocompressing the film to the base film; and an adhesive layer curing process for curing the adhesive layer by heat-treating the base film on which the coverlay film is thermocompression wound on the reel. Have

  Thus, a method for producing a flexible printed wiring board having excellent productivity and quality stability, which can produce a flexible printed wiring board having uniform quality and excellent bending resistance using a roll-to-roll method without complicated operations. Can be provided.

  In order to solve the above-mentioned problems, the flexible printed wiring board of the present invention has substantially the same thickness of the adhesive layer on the upper surface side and the lower surface side of the conductive pattern in the portion bent when the flexible printed wiring board is built in an electronic device. It has a certain configuration.

  Thereby, even if the wiring density of the conductor pattern in a bending part is high, the flexible printed wiring board excellent in bending resistance can be provided.

  As described above, according to the flexible printed wiring board of the present invention, the following advantageous effects can be obtained.

According to the invention of claim 1,
(1) Since each manufacturing process is continuously performed by a roll-to-roll method, it is possible to provide a method for manufacturing a flexible printed wiring board that prevents variation in quality and has excellent quality stability.

  (2) It is possible to provide a method for manufacturing a flexible printed wiring board that can automate each manufacturing process and is excellent in productivity and labor saving.

  (3) The manufacturing method of the flexible printed wiring board excellent in productivity can be provided, without requiring complicated work, such as attachment and detachment to the hot press apparatus of a base film.

  (4) By performing positioning and thermocompression bonding in separate processes, it is possible to provide a high-quality flexible printed wiring board manufacturing method capable of improving positioning accuracy and reliability of filling of the adhesive layer.

  (5) Providing a method for manufacturing a high-quality flexible printed wiring board that can fill the adhesive layer around the conductor pattern between the base film and the coverlay film without gaps in the thermocompression bonding process and prevent the generation of voids. can do.

  (6) Since the adhesive layer is reliably filled between the base film and the coverlay film and then cured, it is possible to provide a method for producing a high-quality flexible printed wiring board that can reliably prevent the generation of voids.

According to invention of Claim 2, in addition to the effect of Claim 1,
(1) By sending the release film along the cover lay film, the cover lay film can be thermocompression bonded via the release film, so that the cover lay film can be prevented from sticking to a hot plate, The manufacturing method of the flexible printed wiring board which can be reliably thermocompression-bonded with a strong pressing force can be provided.

  (2) It is possible to provide a method for producing a flexible printed wiring board that can remarkably improve workability and productivity without requiring complicated work such as attaching / detaching a release film, which has been conventionally required.

According to invention of Claim 3, in addition to the effect of Claim 1 or 2,
(1) The manufacturing method of the flexible printed wiring board excellent in the bending resistance which can make the thickness difference of the contact bonding layer of the upper surface side and lower surface side of a conductive pattern small by a planarization process can be provided.

According to invention of Claim 4, in addition to the effect of any one of Claims 1 to 3,
(1) The manufacturing method of the flexible printed wiring board excellent in the quality stability which can form a plating film in the surface of the exposed conductor pattern continuously by the roll-to-roll method can be provided.

According to the invention of claim 5,
(1) The flexible printed wiring board which can improve a bending resistance remarkably by making the thickness of the contact bonding layer of the upper surface side and lower surface side of a conductive pattern substantially the same can be provided.

The present invention relates to a method for producing a flexible printed wiring board excellent in productivity and quality stability, which can produce a flexible printed wiring board having uniform quality and excellent bending resistance using a roll-to-roll method without complicated operations. A first film feeding step in which a belt-like base film having a plurality of conductor patterns formed on at least one side is fed from one reel while being wound around the other reel, and the conductor of the fed-out base film the pattern, and the temporary bonding step of sequentially temporarily adhered to the base film coverlay film to cover a positioning step of positioning the cover lay film of a predetermined shape, a conductive material pattern having a thermosetting adhesive layer on one side , While feeding the base film with the coverlay film temporarily bonded from one reel, A second film feeding step that is wound up by a roll, a thermocompression step in which the temporarily bonded cover lay film is thermocompression-bonded to the base film, and a base film on which the coverlay film is thermocompressed is wound around the reel. And an adhesive layer curing step of curing the adhesive layer by heat treatment in a state.

  An object of the present invention is to provide a flexible printed wiring board having excellent bending resistance even when the wiring density of a conductor pattern in a bent portion is high, and is bent when the flexible printed wiring board is incorporated in an electronic device. This was realized by making the thickness of the adhesive layer on the upper surface side and the lower surface side of the conductive pattern in the portion substantially the same.

  A first invention made to solve the above problems is a method for manufacturing a flexible printed wiring board using a roll-to-roll method, in which a strip-like base film having a plurality of conductor patterns formed on at least one side is provided on one side. A first film feeding step of winding on one reel while feeding from the other reel, and positioning a cover lay film having a predetermined shape having a thermosetting adhesive layer on one side with respect to the conductor pattern of the delivered base film A positioning process, a temporary bonding process in which the coverlay film is sequentially temporarily bonded to the base film so as to cover the positioned conductor pattern, and a base film to which the coverlay film is temporarily bonded is wound from one reel while being wound around the other reel. The second film feeding process to be taken and the coverlay film temporarily bonded A thermocompression process for sequentially thermocompression bonding to the film, and an adhesive layer curing process for curing the adhesive layer by heat-treating the base film with the coverlay film thermocompressed on the reel. ing.

  This configuration has the following effects.

  (1) While the base film is sent out in the first film feeding step and the second film feeding step, the temporary bonding step and the thermocompression bonding step are continuously performed by the roll-to-roll method, so that quality variation is prevented and the quality is improved. In addition to excellent stability, each manufacturing process can be automated.

  (2) A process of temporarily bonding the coverlay film to the base film while accurately positioning the coverlay film while feeding the base film from one reel to the other reel, and thermocompression bonding the temporarily bonded coverlay film to the base film Therefore, there is no need for complicated operations such as attaching and removing the base film to / from the hot press machine, and positioning and thermocompression are performed in separate processes, ensuring positioning accuracy and adhesive layer filling. Each can be improved.

  (3) By pressing the adhesive layer in an uncured or semi-cured state in the thermocompression bonding step, the adhesive layer can be filled around the conductor pattern between the base film and the coverlay film without a gap.

  (4) Since the adhesive layer curing step is provided, the adhesive layer can be completely cured to prevent peeling of the coverlay film, and after the adhesive layer is reliably filled between the base film and the coverlay film Since it hardens | cures, generation | occurrence | production of a void can be prevented reliably.

  Here, as the adhesive layer of the coverlay film, a layer containing a thermosetting resin such as epoxy, polyimide, or acrylic is used.

  As the positioning means in the positioning step, a means using a positioning pin and a positioning hole, a means for detecting the position by a mark or the like formed on the film, and the like are used.

  As a temporary bonding means in the temporary bonding step, a pair of hot plates for pressing the base film and the coverlay film, a hot roller press, or the like is used.

  As the thermocompression bonding means in the thermocompression bonding process, the same temporary bonding means is used. Set as appropriate.

  In the adhesive layer curing step, a reel around which a base film on which a coverlay film is thermocompression bonded is wound is placed in an oven and heat treated at a temperature and time corresponding to the type of the adhesive layer.

  In the first film feeding step, the base film is sent out intermittently. That is, when the base film is sent out for a predetermined length, the base film is temporarily stopped, the conductor pattern and the coverlay film are positioned and temporarily bonded, and then sent again, and the next conductor pattern is similarly positioned and temporarily bonded. . Similarly, in the second film feeding step, the film is intermittently fed out.

  2nd invention made | formed in order to solve the said subject is a manufacturing method of the flexible printed wiring board as described in 1st invention, Comprising: The strip | belt-shaped release film was wound before the thermocompression bonding process. A release film feeding step of winding the release film along the coverlay film from one reel and winding it with the other reel is provided.

  With this configuration, in addition to the operation of the first invention, the following operation is provided.

  (1) While the release film is fed from one reel along the cover lay film, the cover lay film is thermocompression-bonded via the release film by a hot plate of a hot press device, so the cover lay film is a hot plate, etc. Can be prevented, and workability and productivity can be remarkably improved without requiring complicated operations such as attaching and detaching a release film, which has been conventionally required.

  3rd invention made | formed in order to solve the said subject is a manufacturing method of the flexible printed wiring board as described in 1st or 2nd invention, Comprising: A cover-lay film is thermocompression-bonded before a contact bonding layer hardening process. A third film feeding step in which the base film is wound out from one reel while being wound out from the other reel, and a part of the surface of the coverlay film on the fed base film is sequentially pressed by a heated pressing member. And a flattening step for flattening.

  With this configuration, in addition to the functions of the first or second invention, the following functions are provided.

  (1) By reducing the thickness of the adhesive layer on the coverlay film side of the upper surface of the conductor pattern by the flattening step, the difference in thickness between the adhesive layer on the upper surface side and the lower surface side of the conductive pattern can be reduced, and bending resistance Can be improved.

  Here, in the third feeding step, the base film is intermittently sent out in the same manner as in the first and second feeding steps.

  In the flattening step, the bent portion (bent portion) of the flexible printed wiring board finally obtained by external processing is flattened. In particular, since a portion having a high wiring density of the conductor pattern is likely to have irregularities on the surface of the coverlay film, it is preferable to improve the bending resistance by flattening by a flattening step.

  Moreover, as a device used for the flattening step, a lower hot plate supporting the base film side, a heated pressing member having a predetermined cross-sectional shape for pressing a part of the cover film, and the like are used. In addition, it can also press with a pressing member in a high temperature atmosphere.

  A fourth invention made to solve the above-mentioned problems is the method for manufacturing a flexible printed wiring board according to any one of the first to third inventions, wherein the heat treatment is performed after the adhesive layer curing step. The base film is previously applied to the surface of the conductive pattern exposed from the opening of the coverlay film on the base film that has been sent out, and the fourth film feeding step of winding the base film from one reel while winding the base film from the other reel. And a plating step of sequentially performing electrolytic plating using the formed power supply pattern.

  With this configuration, in addition to the operation of any one of the first to third inventions, the following operation is provided.

  (1) A plating film can be continuously formed on the surface of the exposed conductor pattern by the roll-to-roll method, and it is excellent in stability of quality and can be automated, and is excellent in productivity and labor saving.

  5th invention made | formed in order to solve the said subject is a flexible printed wiring board manufactured using the manufacturing method of the flexible printed wiring board of any one of Claims 1 thru | or 4, Comprising: The adhesive layer on the upper surface side and the lower surface side of the conductive pattern in the portion bent when the flexible printed wiring board is incorporated in the electronic device has a configuration that is substantially the same.

  This configuration has the following effects.

  (1) The bending resistance can be remarkably improved by making the thicknesses of the adhesive layers on the upper surface side and the lower surface side of the conductive pattern substantially the same.

(Embodiment 1)
Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  Fig.1 (a) is a schematic diagram which shows the positioning process and temporary bonding process of the manufacturing method of the flexible printed wiring board in Embodiment 1 of this invention, FIG.1 (b) is a schematic diagram which shows a thermocompression bonding process. FIG. 1C is a schematic diagram showing the adhesive layer curing step.

  In FIG. 1, 1 and 2 are reels, 3 is a strip-like base film made of a polyimide film, 4 is a conductor pattern formed on the base film 3, and 5 is a positioning hole penetrating through a predetermined portion of the base film 3. 6 is a cover lay film punched into a predetermined shape, 6a is an adhesive layer of the cover lay film 6, 7 is an upper hot plate of the heat press apparatus, 8 is a positioning pin erected on the upper surface of the lower hot plate 9, Is a lower hot plate of the heat press apparatus, 10 is a positioning hole penetrating a predetermined portion of the coverlay film 6, 11 and 12 are reels, 13 is a strip-shaped release film, 14 is a take-up reel, and 15 is a coverlay. A film wiring board 16 is a base film 3 to which a film 6 is thermocompression bonded, and 16 is an oven.

As shown in FIG. 1A, first, the positioning holes 10 of the coverlay film 6 are inserted into the positioning pins 8 on the upper surface of the lower hot plate 9, and the coverlay film 6 is attached on the lower hot plate 9. At this time, the adhesive layer 6 a of the coverlay film 6 is attached so as to face the conductor pattern 4. Next, the roll-shaped base film 3 having the conductor pattern 4 on one side wound around the reel 1 is sent out between the upper hot plate 7 and the lower hot plate 9 (first film feeding step). Next, the upper hot plate 7 and the lower hot plate 9 are brought close to each other, the positioning pins 8 are inserted into the positioning holes 5 of the base film 3, and the position of the base film 3 is fixed (positioning step). Further, the upper hot plate 7 and the lower hot plate 9 are brought close to each other, and the cover lay film 6 and the base film 3 are clamped. Thereby, the coverlay film 6 is temporarily bonded onto the conductor pattern 4 of the base film 3 (temporary bonding step). This temporary bonding process is sequentially repeated for each conductor pattern 4 on the base film 3, and the coverlay film 6 is temporarily bonded. The base film 3 to which the coverlay film 6 is temporarily bonded is wound around the reel 2. In the first embodiment, positioning is performed using the positioning pins 8 and the positioning holes 5 and 10, but other positioning means such as positioning by image processing may be used.

  Next, after the winding of the base film 3 by the reel 2 is completed, a thermocompression bonding process is performed while the base film 3 is unwound from the reel 2. As shown in FIG. 1B, a release film 13 is wound around the reel 11, and a base film 3 with a coverlay film 6 temporarily bonded onto the conductor pattern 4 is wound around the reel 2. . The release film 13 and the base film 3 unwound from the reels 11 and 2 are sent out between the upper heating plate 7 and the lower heating plate 9 (release film feeding step, second film feeding step), and the upper heat It is sandwiched between the plate 7 and the lower hot plate 9 and sequentially thermocompression-bonded (thermocompression process). Thereby, the adhesive layer 6a is filled between the conductor patterns 4 without any gaps. Further, the release film 13 prevents the coverlay film 6 from sticking to the upper hot plate 7. The release film 13 is wound around the reel 12, and the base film 3 on which the coverlay film 6 is thermocompression bonded is sequentially wound around the take-up reel 14. In the first embodiment, a hot press apparatus including hot plates 7 and 9 is shown as the thermocompression bonding means. However, the present invention is not limited to this, and any apparatus capable of performing thermocompression bonding such as a heat roller press. That's fine. Further, the release film 13 does not have to be wound around the reel 11, and an individual sheet-like release film is sequentially inserted between the coverlay film 6 and the upper hot plate 7 and thermocompression bonded. You can also

  Next, an adhesive layer curing step is performed on the take-up reel 14 on which the base film 3 (film wiring board 15) to which the coverlay film 6 has been thermocompression bonded is taken up. As shown in FIG. 1 (c), the take-up reel 14 is inserted into an oven 16, and heat treatment is performed at a temperature and time optimal for curing the adhesive layer 6a of the coverlay film 6 (adhesive layer curing step). After the adhesive layer curing step, the take-up reel 14 is taken out of the oven 16 and the wound film wiring board 15 is fed out (fourth film feeding step), and the conductor pattern 4 is electrically formed on the base film 3 in advance. The electroplating process is continuously performed on a part of the conductor pattern 4 exposed from the opening of the cover lay film 6 by using a power supply pattern (not shown) connected in a continuous manner as an electrode (plating process). Further, after attaching an insulating reinforcing plate or the like to the back surface of the base film 3, it is punched into a predetermined shape by press working to obtain a flexible printed wiring board.

  Since the manufacturing method of the flexible printed wiring board in this Embodiment 1 is comprised as mentioned above, by performing each process continuously by the roll-to-roll method, the individualized base film, the release film, etc. It does not require complicated work to handle, and can be automated and mass-produced to provide excellent productivity, and it also has the effect of preventing quality variations such as the quality of the laminate and the quality of the plating film, and excellent quality stability. .

(Embodiment 2)
FIG. 2 is a schematic diagram showing a flattening step of the method for manufacturing a flexible printed wiring board in Embodiment 2 of the present invention.

In FIG. 2, 17 is a pressing member fixed to the upper hot plate 7, 18 is a reel, and X is a flat portion that is a flattened portion of the surface of the coverlay film 6. In addition, the thing similar to what was demonstrated in Embodiment 1 attaches | subjects the same code | symbol, and abbreviate | omits description.

  The manufacturing method of the flexible printed wiring board in the second embodiment is different from the first embodiment in that a third film feeding step and a flattening step are provided before the adhesive layer curing step. Hereinafter, the third film feeding step and the flattening step will be described with reference to FIG. As shown in FIG. 2, first, the base film 3 taken up on the take-up reel 14 in the thermocompression bonding process is sent out between the upper hot plate 7 and the lower hot plate 9 of the hot press device (third film feed). Process). At this time, the lower surface side of the base film 3 is supported by the lower hot plate 9. When the upper hot plate 7 is lowered toward the lower hot plate 9, the surface of a predetermined portion of the cover lay film 6 is pressed by the pressing member 17 to form a flat portion X (flattening step). The base film 3 in which the flat portion X is formed on the coverlay film 6 is sequentially wound around the reel 18.

  Next, the flexible printed wiring board produced as mentioned above is demonstrated using FIG.3 and FIG.4.

  FIG. 3A is a plan view of a flexible printed wiring board according to Embodiment 2 of the present invention, and FIG. 3B is an enlarged perspective view of a partial cross-section of a bent portion of the flexible printed wiring board. 4 (a) to (c) are cross-sectional views taken along line AA in FIG. 3 (a). 4A shows a cross section of the bent portion before the flattening step, FIG. 4B shows a cross section of the bent portion in the flattening step, and FIG. 4C shows the bent portion after the flattening step. The cross section of is shown.

  In the figure, 19 is a flexible printed wiring board according to the second embodiment, 20 is an opening of the coverlay film 6, 21 is a bent portion of the flexible printed wiring board 19, 22 is a base film side adhesive layer, and 23 is a coverlay film. It is a side adhesive layer.

  When the flattening process is not performed, the bent portion 21 (the portion bent when incorporated in the electronic device) of the flexible printed wiring board 19 shown in FIG. As shown in FIG. 3, the surface of the coverlay film 6 is uneven depending on the thickness of the conductor pattern 4.

  When the surface of a predetermined portion of the cover lay film 6 is pressed by the pressing member 17 in the flattening step as shown in FIG. 4B, the surface of the cover lay film 6 is flattened as shown in FIG. At the same time, the thickness Y of the coverlay film side adhesive layer 23 on the upper surface side of the conductive pattern 4 and the thickness Z of the base film side adhesive layer 22 on the lower surface side are substantially the same. Thereby, the bending resistance of the bending part 21 of the flexible printed wiring board 19 can be improved. That is, if the thickness of the upper and lower adhesive layers of the conductor pattern 4 is asymmetric, the tensile force applied to the conductor pattern 4 is increased, and the conductor pattern 4 that is weak against the tensile force is susceptible to damage such as disconnection or cracking. By making Y and thickness Z substantially the same and making the thickness of the upper and lower adhesive layers of the conductor pattern 4 symmetrical, the tensile force applied to the conductor pattern 4 can be reduced and the bending resistance can be improved.

  Since the flexible printed wiring board manufacturing method and the flexible printed wiring board 19 manufactured using the flexible printed wiring board according to the second embodiment are configured as described above, the wiring pattern of the conductor pattern 4 is high at the bent portion 21. Even so, the thickness Y of the coverlay film adhesive layer 23 on the upper surface of the conductor pattern 4 can be reduced by forming the flat portion X on the surface of the coverlay film 6 of the bent portion 21 in the flattening step. The thickness difference between the coverlay film adhesive layer 23 on the upper surface side of the conductor pattern 4 and the adhesive layer 22 on the lower surface side can be reduced, and the bending resistance can be improved.

The present invention relates to a method for manufacturing a flexible printed wiring board on which various surface-mount type electronic components are mounted and embedded in an electronic device. In particular, according to the present invention, the roll-to-roll method is used to achieve uniform quality and resistance. The manufacturing method of the flexible printed wiring board excellent in productivity and the stability of quality which can manufacture the flexible printed wiring board excellent in the flexibility without complicated operation can be provided.

  The present invention relates to a flexible printed wiring board in which various surface-mount type electronic components are mounted and embedded in an electronic device. In particular, according to the present invention, even if the wiring density of a conductor pattern at a bent portion is high, A flexible printed wiring board excellent in flexibility can be provided.

(A) The schematic diagram which shows the positioning process and temporary bonding process of the manufacturing method of the flexible printed wiring board in Embodiment 1 of this invention, (b) The schematic diagram which shows a thermocompression bonding process, (c) The adhesive layer hardening process is shown. Pattern diagram The schematic diagram which shows the planarization process of the manufacturing method of the flexible printed wiring board in Embodiment 2 of this invention. (A) The top view of the flexible printed wiring board in Embodiment 2 of this invention, (b) The partial cross section principal part enlarged perspective view of the bending part of a flexible printed wiring board (A) The principal part arrow sectional drawing of the AA line of FIG. 3 (a) before the planarization process, (b) The principal part arrow sectional view of the AA line of FIG. 3 (a) in the planarization process. (C) Main part arrow sectional drawing of the AA line of Fig.3 (a) after a planarization process

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 2 Reel 3 Base film 4 Conductor pattern 5 Positioning hole 6 Coverlay film 6a Adhesive layer 7 Upper hot plate 8 Positioning pin 9 Lower hot plate 10 Positioning hole 11,12 Reel 13 Release film 14 Take-up reel 15 Film wiring board 16 Oven 17 Pressing member 18 Reel 19 Flexible printed wiring board 20 Opening portion 21 Bending portion 22 Base film side adhesive layer 23 Coverlay film side adhesive layer X Flat portion

Claims (5)

A method for manufacturing a flexible printed wiring board using a roll-to-roll method,
A first film feeding step of winding a belt-like base film having a plurality of conductor patterns formed on at least one surface thereof from one reel while winding it on the other reel;
A positioning step of positioning a cover lay film having a predetermined shape having a thermosetting adhesive layer on one side with respect to the conductive pattern of the base film that has been sent out,
A temporary bonding step of sequentially temporarily adhered to the base film the coverlay film to cover the conductive pattern,
A second film feeding step of winding the base film to which the coverlay film has been temporarily attached from one reel while winding the base film on the other reel;
A thermocompression bonding step of sequentially thermocompression bonding the coverlay film temporarily bonded to the base film;
An adhesive layer curing step of curing the adhesive layer by heat-treating the base film on which the coverlay film has been thermocompression bonded to a reel;
A method for producing a flexible printed wiring board, comprising: Before the thermocompression bonding step, a release film feeding step of winding the release film along the coverlay film from one reel on which a strip-shaped release film is wound and winding the release film on the other reel is provided. The manufacturing method of the flexible printed wiring board of Claim 1 characterized by the above-mentioned. Before the adhesive layer curing step,
A third film feeding step of winding the base film on which the coverlay film is thermocompression-bonded with one reel while feeding the other from one reel;
A flattening step of sequentially pressing and flattening a part of the surface of the coverlay film on the delivered base film with a heated pressing member;
The manufacturing method of the flexible printed wiring board of Claim 1 or 2 characterized by the above-mentioned. After the adhesive layer curing step,
A fourth film feeding step of winding the heat-treated base film from one reel while winding it on the other reel;
A plating step of sequentially performing an electroplating process on the surface of the conductor pattern exposed from the opening of the cover lay film on the fed base film, using a power feeding pattern previously formed on the base film;
The method for producing a flexible printed wiring board according to any one of claims 1 to 3, further comprising: It is a flexible printed wiring board manufactured using the manufacturing method of the flexible printed wiring board of any one of Claims 1 thru | or 4, Comprising: When the said flexible printed wiring board is built in the electronic device, it is bent. The flexible printed wiring board characterized in that the thickness of the adhesive layer on the upper surface side and the lower surface side of the conductive pattern in the portion is substantially the same.

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