JPH07106728A - Rigid-flexible printed wiring board and manufacture thereof - Google Patents

Abstract

PURPOSE:To prevent the damage at the end part coming in contact with a rigid part of an exposed flexible part by sealing an end part of the rigid part near the exposed flexible part. CONSTITUTION:After integrating a flexible printed wiring board having a protective layer 6 on the surface with a rigid printed wiring board 8, the right printed wiring board 8 is partially removed to expose the flexible part 3 and the right part 1, 2. Then, the end parts of the rigid parts 1, 2 near the flexible part 3 are sealed by an insulated organic resin composite part. Thereby, even in case the rigid-flexible printed wiring board is folded, the damage of the protective layer 6 of the flexible part 3 or of the conductive layer 5 can be prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rigid flex printed wiring board in which a flexible printed wiring board and a rigid printed wiring board are integrated and a method for manufacturing the same.

[0002]

2. Description of the Related Art A circuit is formed by attaching a metal conductor such as copper foil to a film made of polyimide resin or polyester resin, and a cover film made of polyimide resin or polyester resin is adhered as a protective layer to the foldable flexible film. Printed wiring boards are known. Also known is a rigid printed wiring board in which a circuit is formed on a laminate obtained by stacking a prepreg, which is a sheet impregnated with a curable resin, on a base material such as glass cloth or paper and subjecting it to heat and pressure treatment. Further, a rigid flex printed wiring board in which these are integrated to form a flexible portion and a rigid portion is also known.

FIG. 2 is a sectional view of a conventional rigid flex printed wiring board, in which rigid portions 1 and 2 and a flexible portion 3 connecting them are continuously formed and integrated as shown in FIG. Is. As shown in FIG. 2, the flexible portion 3 covers the core material 4 of the flexible printed wiring board, the metal conductor 5 such as copper foil having excellent flexibility attached to both surfaces of the core material 4, and the metal conductor 5. A cover film 6B which is an insulating material is sequentially laminated, and an adhesive layer 6C is interposed between the cover film 6B and the metal conductor 5. The core material 4 is usually made of a polyimide resin film, a polyester resin film, or the like. A circuit pattern is formed on the metal conductor 5, and a conductive through hole may be formed through the core material 4. As the cover film 6B, an insulating film made of the same material as the core material 4 such as a polyimide resin or a polyester resin is usually used, and an adhesive layer 6C obtained by applying an acrylic adhesive or the like to the insulating film.
Glued by.

The rigid portions 1 and 2 are formed by laminating a rigid printed wiring board 8 on a portion having the same structure as the flexible portion 3 with a prepreg 7 interposed. That is, the cross-sectional structure of the flexible portion 3 extends not only to the flexible portion 3 but also to the rigid portions 1 and 2 as shown in FIG. 2, and the prepreg 7 and the rigid printed wiring board 8 are attached to the cover film 6B in these rigid portions 1 and 2. It is a laminate. Here, the prepreg 7 is a semi-cured state obtained by impregnating a base material such as glass cloth or paper with an epoxy resin and drying it. Reference numeral 9 in FIG. 2 is a circuit pattern formed on the rigid printed wiring board 8.

In the conventional rigid flex printed wiring board having such a structure, when forming the through hole 10, there is a problem that the throwing around of the through hole plating is not stable and the product yield is deteriorated. That is, the formation of the through hole 10 is performed with the rigid portions 1, 2
A through hole is formed by drilling in the through hole, the through hole is subjected to chemical copper plating, and then electrolytic copper plating is performed. The adhesive layer 6C of the cover film 6B is usually made of an acrylic material or the like. Adhesives are used, but this is caused by the chemical desmear treatment such as permanganate or the like, which is deteriorated by the plating treatment liquid, and the phenomenon that the end face recedes from the through-hole holes or elutes into the through-hole holes. Inhibits throwing power. As described above, in the conventional rigid flex printed wiring board, the throwing power of the plating is reduced due to the influence of the adhesive layer used in the cover film, the thickness of the through-hole plating becomes uneven, and the circuit connection reliability is reduced. However, there is a problem that the product yield is deteriorated.

Further, as a means for solving such a problem, when an epoxy resin adhesive having resistance to a treatment liquid such as permanganate is used, a usual epoxy resin adhesive is flexible in its cured state. However, when the flexible portion is bent, it is not possible to follow the bending of the core material 4 and cracks occur in the adhesive layer 6C.

Further, as a fundamental problem, a film made of polyimide resin or polyester resin is used as the core material of the flexible printed wiring board. On the other hand, an epoxy resin is generally used as an organic material forming the rigid printed wiring board and the prepreg. Therefore, the rigid part is composed of different kinds of organic materials, and each material shows different dimensional changes due to the thermal history received in the process of integrating the rigid part and the flexible part. There is still a problem that misalignment occurs.

In order to solve the above-mentioned problems, the present inventors have used a glass cloth base epoxy resin having flexibility as a material for a flexible printed wiring board, and further used a protective layer of the flexible printed wiring board with an epoxy resin. Japanese Patent Application No. 5-195940 proposes that an organic insulating layer that is mainly composed of a resin and that is cured by light and / or heat and has flexibility even after curing is used.

By the way, when such a rigid flex printed wiring board is incorporated in a device, it is bent and used as shown in FIG. In the conventional rigid flex printed wiring board, the exposed flexible portion 3
Ends of the nuclear rigid parts 1 and 2 located in the vicinity 3a of are formed as substantially vertical surfaces. Therefore, when the rigid flex printed wiring board is bent in the state shown in FIG. 3, the rigid right-angled end portion of the rigid portion may damage the protective layer or the conductor layer of the flexible portion, and electrical conduction may be hindered. is there.

For the purpose of solving such a problem, a rigid flexible wiring is formed in which an end portion of the rigid substrate, which is close to the exposed portion of the flexible substrate, has a step portion which is gradually thinned toward the exposed portion side of the flexible substrate. A plate has been proposed by JP-A-62-174996. However, in order to provide such a stepped portion, the flexible portion is exposed, so that it is necessary to perform the cutting work twice or more in the step of cutting and removing the rigid portion. Yes, the process becomes complicated.

[0011]

SUMMARY OF THE INVENTION The present invention has been made as a result of studies in view of the above problems, and it is an object of the present invention to avoid the risk of damage to a flexible portion by a simple method. That is, the object of the present invention is, firstly, in a rigid flexprint wiring board, a rigid flexprint wiring board having a structure capable of easily avoiding damage to a portion of an exposed flexible portion in contact with the rigid portion. Is to provide. Secondly, to provide a method for easily manufacturing the rigid flex printed wiring board.

[0012]

The inventors of the present invention have achieved the present invention as a result of intensive studies to achieve the above object. That is, the rigid-flex printed wiring board according to the present invention has a structure in which a flexible printed wiring board having a protective layer on its surface and a rigid printed wiring board are integrated, and then the rigid printed wiring board is partially removed to expose an exposed flexible printed wiring board. In a rigid flex printed wiring board having a portion and a rigid portion, an end portion of the rigid portion adjacent to the exposed flexible portion is sealed with an insulating organic resin composition.

Further, in the method for manufacturing a rigid flex printed wiring board according to the present invention, after the flexible printed wiring board having a protective layer on the surface and the rigid printed wiring board are integrated, the rigid printed wiring board is partially In a method for manufacturing a rigid flex printed wiring board having a removed flexible portion and a rigid portion,
A process of forming a circuit on a flexible copper-clad laminate to process a flexible printed wiring board, and applying an organic resin that is cured by light and / or heat and has flexibility even after curing on both sides of the flexible printed wiring board. After that, the organic resin is cured by light and / or heat to form flexible organic insulating layers on both sides of the flexible printed wiring board to produce a flexible portion, and a circuit is formed on the rigid copper clad laminate. A step of processing the rigid printed wiring board to form a rigid portion, a step of integrating the flexible portion and the rigid portion using a prepreg, and partially removing the rigid printed wiring board to expose the flexible portion. The process and the process of sealing the end of the rigid part close to the exposed flexible part with the insulating organic resin composition. Characterized in that it comprises a.

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a sectional view of an embodiment of a rigid flex printed wiring board according to the present invention, FIG. 2 is a sectional view of a conventional rigid flex printed wiring board, and FIG.
FIG. 4 is a sectional view of a conventional rigid flex printed wiring board in a bent state, FIGS. 4 to 11 show processing states of respective steps included in the manufacturing method of the present invention, (A) is a plan view, and FIG. (B) shows a sectional view. Here, 1 and 2 are rigid parts, 3 is a flexible part, 4 is a flexible core material forming a flexible printed wiring board, 5 is a metal conductor, 6 is a protective layer of an organic insulating layer having flexibility, and 6A is The protective layer before curing, 6B is a cover film,
6C is an adhesive layer, 7 is a prepreg, 8 is a rigid printed wiring board, 9 is a circuit pattern, 10 is a through hole, 1
1 is a light source such as an ultraviolet lamp or a heat source such as a heater, 1
Reference numeral 2 denotes a metal foil before circuit formation, and 13 denotes a sealing portion made of an insulating organic resin composition.

The flexible printed wiring board used in the present invention is manufactured from a flexible copper clad laminate. Two types of copper clad laminate can be used depending on the material composition. The first one is a film in which polyimide resin or polyester resin is used as an insulating layer as a core material, and copper foil is attached to both sides of the core material, but the material of the rigid flex printed wiring board is homogenized and the position is displaced. From the viewpoint of improving the dimensional stability of the prepreg, a prepreg made by impregnating a glass cloth base material with epoxy resin is used as the core material that becomes the insulating layer. Most preferred are This type of flexible printed wiring board is inferior in flexibility as compared with a product in which a film of polyimide resin or polyester resin is used as a core material, but in order to achieve the object, JIS C6471 is used.
Test method for copper-clad laminate for flexible printed wiring board 6.
In the folding endurance test described in item 6, the number of folding endurances must be 50 times or more. If the folding endurance is less than 50 times, the rigid flex printed wiring board is incorporated in the device during the manufacturing process of the rigid flex printed wiring board or during the step of mounting electronic components on the obtained rigid flex printed wiring board or after mounting the electronic components. The insulation layer or copper foil circuit will be damaged during the process. Specific examples of such a flexible copper-clad laminate include turn flex (Matsushita Electric Works; folding endurance 304 times), green flex (Shin-Kobe Electric machine; folding endurance 151 times), semi-flex (Jelectra; folding endurance). 105 times).

The thickness of the insulating layer of the flexible copper-clad laminate used in the present invention is generally 10 to 100 .mu.m, and the upper limit of the thickness of the copper foil is 70 .mu.m and generally no lower limit. As the type of copper foil, there are rolled copper foil, electrolytic copper foil, copper thin film by sputtering method, etc. There is also a method of pattern plating directly on the base film by an additive method, and therefore there is no particular lower limit to the copper foil thickness. The flexible copper clad laminate used in the present invention has the structure shown in FIGS. 4 (A) and (B).

In the present invention, the flexible printed wiring board is formed on the flexible copper clad laminate through a drilling step, a through hole plating step, a dry film, an etching resist forming step using a liquid resist, and an etching step. The example is the fifth
This is as shown in Figures (A) and (B). For flexible printed wiring boards, a method of forming an ultra-thin copper foil film on an insulating layer by a sputtering method, forming a plating resist on a laminated board, performing pattern plating, peeling the resist, and removing unnecessary copper foil. There is also a method of forming a plating resist for plating on the insulating layer and forming a pattern by electroless plating.

In the present invention, the protective layer covering the flexible copper clad laminate is formed of an organic insulating layer which is cured by light and / or heat and has flexibility even after curing. A protective layer is formed in consideration of resistance to permanganate treatment solution, solder heat resistance, and homogeneity of the material of all organic insulating layers that make up a rigid flex printed wiring board, and considering improvement in dimensional stability such as positional deviation. Most preferably, the base resin forming the organic insulating layer is mainly an epoxy resin. That is, the epoxy resin, a photosensitive group capable of reacting by light energy and cross-linking, for example, acryloyl group, vinyl group, cinnamoyl group, diazo group,
Introduce an azido group, etc., and add a photopolymerization initiator if necessary to apply it to the surface of the flexible printed wiring board,
The protective layer is formed by irradiating a predetermined amount of light such as ultraviolet rays to cure the resin. Alternatively, a resin composition prepared by mixing an epoxy compound with an amino compound, an acid anhydride, a phenol compound or the like as a curing agent is applied to the surface of a flexible printed wiring board and cured by heating to form a protective layer. It is also possible to use light curing and heat curing together.
The insulating material forming these protective layers is in a liquid state before coating and is applied to the surface of the flexible printed wiring board by a screen printing method, a roll coater method, a curtain coater method or the like. Further, these cured protective layers need to have flexibility in order to follow the flexibility of the flexible portion. That is, the number of folding endurances (a) in the folding endurance test described in Section 6.6 of JIS C6471 copper clad laminate test method for flexible printed wiring board of the flexible printed wiring board on which the protective layer is formed, and the protection It is necessary that the ratio of the flexible printed wiring board before layer formation to the folding endurance test (b) in the folding endurance test is (b) / (a) ≧ 1. The folding endurance ratio (b) / (a) is 1
In less than, during the manufacturing process of the rigid flex printed wiring board or during the step of mounting the electronic component to the obtained rigid flex printed wiring board or the step of incorporating the rigid flex printed wiring board into the device after electronic component mounting, etc., an insulating layer, The copper foil circuit or the protective layer will be damaged.

As an example of such an insulating material, a photo-curing type USR-11 (manufactured by Tamura Corporation; (b) / (a) = 1.0) as a UV curable type, Pana Sealer C
V7000 (Matsushita Electric Works; (b) / (a) = 1.2),
NPR-80 (manufactured by Nippon Polytech; (b) / (a) =
1.3) and the like, SR-29G (manufactured by Tamura Corporation; (b) / (a) = 1.8), Pana Sealer CV5303 (manufactured by Matsushita Electric Works; (b) / (a) = 1.
5), NPR-5 (manufactured by Nippon Polytec; (b) / (a)
= 1.7), and Probimer 52 (manufactured by Nippon Ciba Geigy; (b) / (a) = 2.
4) and the like, but are not particularly limited thereto. Etc.

In the present invention, an example of a step of applying the protective layer on the flexible printed wiring board and curing the same is shown in FIGS. 7 (A) and 7 (B). In this case, this is an example of forming a protective layer on the entire surface of the flexible printed wiring board.
It does not matter if a protective layer is formed on a portion of the flexible printed wiring board that is exposed from the exposed flexible portion to the rigid portion by an appropriate distance. Although the thickness of the protective layer depends on the thickness of the circuit copper foil of the flexible printed wiring board, it may be 20 to 100.
μ is common. However, although it is not particularly limited because it depends on the method of applying a liquid insulating material, the method of drying / curing, and the thickness of the copper foil, it is generally necessary to secure 5 μ in the thinnest portion. When the protective layer is formed by entering the rigid portion, the distance of the protective layer entering the rigid portion is not particularly limited, but is 0.5 to 5 mm.
Is preferred. According to the manufacturing method in which the liquid material is used as the protective layer and the cover film is not used, not only the reliability of the through hole is increased but also the pressing process for adhering the cover film to the flexible printed wiring board is saved. And can be manufactured at lower cost than the conventional rigid flex printed wiring board.

In the present invention, the rigid printed wiring board is a glass cloth base material epoxy resin, a glass cloth base material polyimide resin, a paper base material phenol resin, a glass cloth / glass nonwoven fabric composite base material epoxy resin, a glass cloth / paper composite base material. Although it is manufactured from a copper clad laminate made of epoxy resin, epoxy resin is used from the viewpoint of measuring the homogeneity of the material of all organic insulating layers that make up the rigid flex printed wiring board and improving the dimensional stability such as positional deviation. Is most preferably used. The rigid printed wiring board is formed by a step of forming an etching resist using a dry film, a liquid resist or the like on the copper clad laminate, and a step of forming a circuit by etching. The thickness of the insulating layer of the copper clad laminate is 0.
04-1.6 mm is common, and the thickness of copper foil is 9-7.
0 μ is common. An example of the rigid printed wiring board processed in this way is shown in FIGS. 7 (A) and 7 (B).
become that way.

The prepreg 7 used in the present invention is made of glass cloth impregnated with epoxy resin, polyimide resin or the like and dried to be in a semi-cured state. From the viewpoint of homogeneity of the material, epoxy resin is used as the impregnating resin. Those using are preferably used. The thickness of the glass cloth is 0.03 ~
0.3 mm is common, and the resin content of prepreg is 40
Is generally 75% by weight, and the thickness of the prepreg after resin impregnation is generally 0.04 to 0.4 mm. One or more prepregs are used between layers.
In the present invention, the outer shape of the prepreg is processed by a punching die, N
It is performed using a C router or the like. The portion removed by the outer shape processing corresponds to the portion where the flexible portion is exposed in the final rigid flex printed wiring board. In the present invention, an example in which the outer shape of the prepreg is processed is as shown in FIGS. 8 (A) and 8 (B).

In the present invention, the flexible portion and the rigid portion are
When using a prepreg for integration, a pin, an eyelet, or the like is used to accurately maintain the positional relationship between the materials, and a hydropress, an autoclave press, or the like is used for thermocompression molding.
If necessary, use paper and synthetic resin cushion material,
The molding conditions cannot be said to be unique because they depend on the type of prepreg used, the cushion structure, the number of layers in one step, the pressing method, etc., but the pressure is generally 6 to 60 kg / cm ² , and the temperature is generally 160 to 200 ° C. is there. An example in which the rigid portion and the flexible portion are integrated by using a prepreg in the present invention is shown in FIGS. 9 (A) and 9 (B).

In the present invention, as a method of partially cutting and removing the rigid portion to expose the flexible portion, the rigid printed wiring board in the portion to be the flexible portion is selectively removed using a punching die, an NC router or the like. To do. At this time, in order to facilitate removal, it is desirable to previously form a groove on the side of the rigid printed wiring board that contacts the flexible printed wiring board. An example in which the rigid printed wiring board is partially removed to expose the flexible portion is shown in FIGS. 10 (A) and 10 (B).

The means for achieving the object in the present invention is to seal the end portions 3a of the rigid portions 1 and 2 adjacent to the exposed flexible portion 3 with the insulating organic resin composition. The insulating organic resin composition is a liquid curable resin composition, and the end portions 3 of the rigid portions 1 and 2 are adjacent to the flexible portion 3 exposed by a dispenser or the like.
After being applied along a, it is sealed by being cured by heat or light. The insulating organic resin composition preferably has a flexural modulus of 100 Kg / mm ² or less so that the cured product thereof can follow expansion or compression of the flexible portion when the rigid flex printed wiring board is bent. Examples of such materials include Semicoat 230 (manufactured by Shin-Etsu Chemical, flexural modulus 880 kg / mm ² ), HIR-250-1
(Hitachi Chemical, flexural modulus 160 Kg / mm ² ), CV516
0 (Matsushita Electric Works, bending elastic modulus 800 kg / mm ² ), Chip Coat 1320-200 (Hokuriku paint, bending elastic modulus 390
^{Kg / mm 2), CRP-} 3100 ( Sumitomo Bakelite Co., Ltd., including but flexural modulus 800 Kg / mm ²⁾ or the like is not limited thereto. An example in which the end portion of the rigid portion adjacent to the exposed flexible portion is sealed with the insulating organic resin composition is shown in FIGS. 11 (A) and 11 (B). This allows
Even when the rigid flex printed wiring board is bent, the sealing part that holds the bent part of the flexible part supports the bent part with elasticity,
It is possible to prevent damage to the protective layer of the flexible portion or the conductor layer.

[0026]

EXAMPLES Example 1 As shown in FIG. 1, a flexible copper-clad laminate, a glass / epoxy double-sided copper-clad laminate Turnflex R17.
66RF (Matsushita Electric Works: insulating layer thickness 70μ, copper foil 18
μ rolled copper foil) was used. As the protective layer, UV-curable photocoat USR-11 (manufactured by Tamura Corporation) was used. Specifically, the flexible copper clad laminate was drilled, plated with about 15 μm of copper, an etching resist was formed using a dry film, and a circuit was formed by etching. NPR-5 (manufactured by Nippon Polytex) was applied to the circuit-formed flexible printed wiring board with a roll coater to a thickness of 30 μm and cured in an oven at 150 ° C. for 20 minutes to form a protective layer.

As a rigid double-sided copper clad laminate, heat of 0.1
5mm, copper foil thickness 18μ on one side, 35μ on one side
A circuit was formed on the 5 μ side in the same manner as the flexible printed wiring board and blackened. As the prepreg, glass cloth base material epoxy resin-impregnated prepreg R1661 (manufactured by Matsushita Electric Works: thickness after molding 0.07 mm) was inserted into the Victoria type externally processed thread layers one by one, and the rigid section and the flexible section were formed using an autoclave press. Were laminated (temperature 180 ° C, pressure 1
5 kg / cm ² , time 100 minutes).

Drilling, permanganate desmear treatment, copper plating (plating thickness: about 25 μ) on the laminated substrate,
Pattern formation, solder resist film formation, character printing,
After the solder coating, the outer shape was processed using an NC router to expose the flexible portion. A semi-coat 230 (manufactured by Shin-Etsu Chemical Co., Ltd.) was applied along the end of the rigid portion near the exposed flexible portion using a dispenser. This was cured at 150 ° C. for 1 hour to obtain a rigid flex printed wiring board in which the end of the rigid portion close to the flexible portion was sealed.

According to this method, since there is no adhesive layer even when the through hole is drilled, the finished work is smooth, and permanganate treatment is carried out as a desmear treatment which is an essential condition in the multilayer structure. The plated state after electroless and electrolytic copper plating was also extremely uniform. Also, after the rigid flex printed wiring board is completed, JIS C5012 printed wiring board test method 9. The 9.3 thermal shock (high temperature immersion) test specified in the item of the weather resistance test was carried out for 100 cycles, but no abnormality was observed. The same JIS C5012 9. After carrying out the treatment of the 9.5 moisture resistance (steady state) test for 240 hours specified in the item of the weather resistance test, the solder at 260 ° C. was float treated for 20 seconds, but no abnormality was observed. Furthermore, when the folding endurance test described in JIS C6471 Copper Clad Laminate Test Method for Flexible Printed Wiring Board was performed on the flexible section, the protective layer and the copper foil circuit were not affected even when the number of reciprocating bendings exceeded 500 times. No damage was noted.

Comparative Example 1 In FIG. 2, MT-Neoflex (manufactured by Mitsui Toatsu Chemical Co., insulation layer thickness 25 μ, copper foil 18 μ rolled copper foil) using a polyimide resin film as a flexible copper clad laminate. And a cover film 6 used as a protective layer
Adhesive layer 6C was provided on B, and Pyralux product number LF-0210 (cover film thickness 25 μ, adhesive layer thickness 50 μ) manufactured by DuPont was used as a product having a structure in which 6B and 6C were combined. The sealing at the end of the rigid portion was not performed. A circuit was formed in the same manner as in Example 1 using a double-sided copper-clad laminate of MT-Neoflex. On the flexible printed wiring board on which this circuit was formed, the above-mentioned Piralux LF-0210 was laminated under the conditions of a temperature of 180 ° C., a pressure of 45 kg / cm ² , and a time of 50 minutes to form a protective layer. Thereafter, a rigid flex printed wiring board was obtained in the same manner as in Example 1.

According to this method, when the through hole is drilled, since the adhesive layer is present, the finished work state is rough and smear is remarkable. Also, permanganic acid treatment was performed as desmear treatment to remove smear, and electroless and electrolytic copper plating were performed, but the adhesive layer was eluted in the through hole part or the adhesive layer was dug away. And the throwing power of the plating is extremely poor. In addition, a slight misalignment was found between the circuit patterns of the flexible printed wiring board and the rigid printed wiring board. A thermal shock (high temperature immersion) test similar to that in Example 1 was performed after the printed wiring board was completed, but disconnection occurred in the third cycle. Also, 260 after the moisture resistance (steady state) test treatment
Floating treatment was performed on the solder at 20 ° C. for 20 seconds, but peeling occurred between the cover film and the flexible printed wiring board in 3 pieces out of 10 pieces of the sample. Furthermore, JIS C
6471 Copper clad laminate for flexible printed wiring board Test method When the folding endurance test described in Section 6.6 was carried out on the flexible portion, cracks occurred in the cover film at the end of the rigid portion after the number of reciprocal bending was 500 times. .

Comparative Example 2 A rigid flex printed wiring board was manufactured in the same manner as in Example 1 up to the step of exposing the flexible portion, but the end portion of the rigid portion which was close to the flexible portion was not sealed. In this method, the appearance properties and characteristics showed the same performances as in Example 1, but in the folding endurance test, cracks occurred in the protective layer at the ends of the rigid portion after the number of reciprocal folding was 200 times.

[0033]

INDUSTRIAL APPLICABILITY As described above, the present invention uses an organic insulating material having excellent heat resistance and chemical resistance as well as flexibility as a protective layer for a flexible printed wiring board, and is inferior in heat resistance and chemical resistance. By eliminating the adhesive layer, it is possible to provide a rigid flex-printed wiring board with excellent workability of through-holes, good throwing power of plating, and extremely high reliability of through-holes.
In addition, since the cover film is not used as a protective layer for the flexible printed wiring board, the pressing process for adhering the cover film to the flexible printed wiring board can be saved, and the cost can be reduced compared to the conventional rigid flex printed wiring board. Further, the organic insulating layer constituting the rigid-flex printed wiring board is mainly epoxy resin, by eliminating the adhesive layer having poor heat resistance and the polyimide resin layer having poor dimensional stability,
It has excellent dimensional stability with no displacement in through-holes and wiring patterns, and has the same level of reliability as rigid printed wiring boards. In addition, the exposed end of the rigid part is close to the flexible part. By sealing with the resin composition, it is possible to provide a rigid flex printed wiring board having a highly reliable flexible portion.

[Brief description of drawings]

FIG. 1 is a sectional view of an embodiment of the present invention.

FIG. 2 is a cross-sectional view of a conventional rigid flex printed wiring board.

FIG. 3 is a sectional view of a conventional rigid flex printed wiring board in a bent state.

FIG. 4 is a diagram showing a flexible copper-clad laminate in the processing state of each step included in the manufacturing method of the present invention. (A) is a plan view, (B) is a sectional view

FIG. 5 is a diagram showing a flexible printed wiring board in a processed state in each step included in the manufacturing method of the present invention. (A)
Is a plan view, (B) is a sectional view

FIG. 6 is a diagram showing a coating / curing step when forming a protective layer on the surface of a flexible printed wiring board, among processing states of respective steps included in the manufacturing method of the present invention. (A) is a plan view, (B) is a sectional view

FIG. 7 is a diagram showing a rigid printed wiring board in a processed state in each step included in the manufacturing method of the present invention. (A) is a plan view, (B) is a sectional view

FIG. 8 is a view showing a prepreg that has been subjected to an outer shape processing in the processing state of each step included in the manufacturing method of the present invention. (A)
Is a plan view and (B) is a cross section.

FIG. 9 is a view in which a rigid portion and a flexible portion are integrated by using a prepreg in a processing state of each step included in the manufacturing method of the present invention. (A) is a plan view, (B) is a sectional view

FIG. 10 is a view showing a state in which the flexible printed wiring board is partially removed by cutting and the flexible portion is exposed among the processing states in each step included in the manufacturing method of the present invention. (A) is a plan view, (B) is a sectional view

FIG. 11 is a view showing a state in which an end portion of a rigid portion adjacent to an exposed flexible portion is sealed with an insulating organic resin composition, among processing states of respective steps included in the manufacturing method of the present invention. (A) is a plan view, (B) is a sectional view

[Explanation of symbols]

1, 2 Rigid part 3 Flexible part 3a Adjacent to the exposed flexible part Near the end of the rigid part 4 Core material 5 Metal conductor 6 Protective layer with flexibility 6A Protective layer with flexibility before curing 6B Cover film 6C Adhesion Agent layer 7 Prepreg 8 Rigid printed wiring board 9 Circuit pattern 10 Through hole 11 Light source or heat source 12 Metal foil before circuit formation 13 Sealing part

Claims (8)

[Claims] 1. A flexible printed wiring board having a protective layer on its surface and a rigid printed wiring board are integrated, and then the rigid printed wiring board is partially removed to have an exposed flexible portion and a rigid portion. A rigid flex printed wiring board, characterized in that an end of the rigid portion adjacent to the exposed flexible portion is sealed with an insulating organic resin composition. 2. The flexible printed wiring board according to claim 1, wherein a circuit is formed on a laminated board having metal conductors on both sides of a glass cloth base epoxy resin, and the method is JIS C6.
471 Copper-clad laminate for flexible printed wiring board Test method In the folding endurance test described in Section 6.6, the number of folding endurances is 50 times or more, the rigid flex printed wiring board. 3. The protective layer of the flexible printed wiring board according to claim 1, which is mainly composed of an epoxy resin, is formed of an organic insulating layer which is cured by light and / or heat and has flexibility even after curing, and JIS C6471 of flexible printed wiring board having protective layer formed thereon Test method for copper clad laminate for flexible printed wiring board 6.6
The folding endurance number (a) in the folding endurance test described in the item,
The ratio of the number of folding endurances (b) in the folding endurance test of the flexible printed wiring board before forming the protective layer is (b) /
(A) Rigid flex printed wiring board, wherein ≧ 1. 4. A rigid flexprint wiring board, wherein the cured organic resin composition according to claim 1 has a flexural modulus of 1000 Kg / mm ² or less. 5. A flexible printed wiring board having a protective layer on its surface and a rigid printed wiring board are integrated, and then the rigid printed wiring board is partially removed to have an exposed flexible portion and a rigid portion. In the method for manufacturing a rigid flex printed wiring board, a step of forming a circuit on a flexible copper clad laminate to process the flexible printed wiring board, and curing and curing both sides of the flexible printed wiring board by light and / or heat. A process of manufacturing a flexible portion by applying an organic resin having flexibility after that and then curing the organic resin by light and / or heat to form organic insulating layers having flexibility on both surfaces of the flexible printed wiring board. When,
A step of forming a circuit on a rigid copper clad laminate to process a rigid printed wiring board into a rigid portion, a step of integrating the flexible portion and the rigid portion using a prepreg, and a portion of the rigid printed wiring board A method for producing a rigid flexprint wiring board, comprising the steps of: removing the flexible portion to expose the flexible portion; and sealing an end of the rigid portion adjacent to the exposed flexible portion with an insulating organic resin composition. 6. The flexible printed wiring board according to claim 1, wherein a circuit is formed on a laminated board having metal conductors on both surfaces of a glass cloth base epoxy resin, and JIS C6
471 Copper-clad laminate for flexible printed wiring board test method In the folding endurance test described in section 6.6, the number of folding endurances is 50 times or more, a method for manufacturing a rigid flex printed wiring board. 7. The protective layer of the flexible printed wiring board according to claim 5, which is mainly composed of an epoxy resin, is formed of an organic insulating layer which is cured by light and / or heat and has flexibility even after curing, and JIS C6471 of flexible printed wiring board having protective layer formed thereon Test method for copper clad laminate for flexible printed wiring board 6.6
The folding endurance number (a) in the folding endurance test described in the item,
The ratio of the number of folding endurances (b) in the folding endurance test of the flexible printed wiring board before forming the protective layer is (b) /
(A) ≧ 1 is a method for manufacturing a rigid flex printed wiring board. 8. The method for producing a rigid flex printed wiring board, wherein the insulating organic resin composition according to claim 5 has a bending elastic modulus of 1000 Kg / mm ² or less.