JPH08267664A - Manufacture of laminate - Google Patents

Abstract

PURPOSE: To facilitate continuous forming of a laminate by simplifying a manufacturing process by a method wherein two sheets of prepregs obtained by superimposing glass fiber nonwoven fabric on a thermosetting resin varnish- coated surface on one side of a long fiber base material, and drying the laminate by heating, are superimposed by making the nonwoven fabric inside, and formed by pressurizing. CONSTITUTION: Thermosetting varnish is applied to an upper surface of a long base material 1 spread out from a spreading device with a coater 3 in order to obtain a specific film thickness. For the long base material, glass fiber nonwoven fabric is preferable from a standpoint of heat resistance. Besides, when formability and reduction of cost are especially required, cellulose base materials of kraft paper or the like are used. For thermosetting resin used for thermosetting varnish, epoxy resin is preferable, and further inorganic filler is more preferably blended therein. When the inorganic filler is added, punching formability and dimensional stability are maintained and improved, and besides thermal expansion coefficient in a Z-direction is decreased. Therefore, throughhole reliability can be also improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing a laminated board suitable for a printed circuit board used in electric equipment, electronic equipment, communication equipment and the like.

[0002]

2. Description of the Related Art Consumer electronic devices have become smaller and more sophisticated, and as a printed circuit board used for them, glass nonwoven fabric is used as an intermediate layer base material and glass woven fabric is used as a surface layer base material. A laminate (hereinafter referred to as a composite laminate) impregnated with a resin and heat-pressed is used. Recently, such composite laminates have been required to have the same punching workability and lower cost as those of the paper-based phenolic laminates conventionally used in this field.

Also in the field of industrial electronic equipment, composite lamellas which do not use woven glass cloth or whose use amount has been reduced have come to be used due to the need for cost reduction, but in view of performance, glass is used. It is inferior to the woven fabric substrate laminate in various points, and it has been required to have the same dimensional change and small warpage as those.

[0004]

In order to meet the various demands for composite laminates as described above, it is considered to use a resin varnish containing a single glass fiber without using a glass nonwoven fabric as an intermediate layer base material. However, although the dimensional change and the warp are improved, there are various problems in manufacturing and they have not yet been put into practical use. On the other hand, it has been studied to reduce the proportion of glass woven fabric or non-woven fabric for cost reduction, but cost reduction is not easy due to performance or manufacturing restrictions. Under these circumstances, the present invention has been completed as a result of various studies aimed at achieving cost reduction while maintaining and improving the performance as a composite laminate.

[0005]

Means for Solving the Problems The present invention comprises a step of applying a thermosetting resin varnish from one side of a long fiber base material, a step of superposing a glass fiber nonwoven fabric on the varnish application surface of the fiber base material, The present invention relates to a method for producing a laminated board, which comprises a step of heating and drying these laminates to obtain a prepreg, and a step of superposing the two prepregs with the non-woven fabric inside to heat and press-mold the laminate. The manufacturing process is simple, continuous molding is possible, and in terms of performance, it is possible to obtain the same or better than the conventional composite laminate.
In the present invention, an example (outline) of steps up to the production of a prepreg is shown in FIG.

A thermosetting resin varnish (2) is applied to the upper surface of the long base material (1) unwound from the unwinding device by a coater (3) so as to have a predetermined film thickness. As the long base material, a glass fiber woven cloth, a glass fiber non-woven cloth,
Synthetic fiber woven or non-woven fabric, kraft paper, linter paper and the like are not particularly limited, but glass fiber woven fabric is preferable from the viewpoint of heat resistance. On the other hand, cellulosic paper base materials such as kraft paper and linter paper are preferably used when punching processability and cost reduction are particularly required.

The thermosetting resin in the thermosetting resin varnish used in the present invention is preferably an epoxy resin, but in addition to this, a polyimide resin, a polyester resin, a phenol resin or the like can be used. Although such a thermosetting resin varnish can be used as it is, it is preferable to add an inorganic filler. If you add an inorganic filler,
It is possible to maintain and improve punching workability and dimensional stability, and also improve through-hole reliability because the coefficient of thermal expansion in the Z direction decreases. Such inorganic fillers include aluminum hydroxide, calcium carbonate, clay, talc, silica and the like, and the compounding ratio with respect to the resin is preferably 10 to 200% by weight. Below 10% by weight,
Through-hole reliability improvement effect is small, 200% by weight
If it exceeds, it becomes difficult to mix the inorganic filler.

The solid content of the thermosetting resin varnish is usually 60 to 80% by weight when the inorganic filler is not blended, and 65 to 90% by weight when the inorganic filler is blended (the inorganic filler is also a solid content. Calculation). The coating amount of the thermosetting resin varnish varies depending on the coating amount of the glass non-woven fabric used in the following steps, or when the resin varnish is coated on the lower surface of the long base material, depending on the coating amount of the resin varnish. , usually length Shakumotozai 1m ² per, varnish solids 600
It is about 1400 g, and the coating thickness (before drying) is 0.2 to
It is about 1.0 mm.

As the coater 3, there are a comma roll coater, a knife coater, a die coater, a reverse coater, etc., but since the coating thickness is as thick as 0.2 to 1.0 mm, it is necessary to make the varnish viscosity high. . Therefore, a method capable of applying a high-viscosity varnish, for example, a comma roll coater or a knife coater is preferable.

After coating the thermosetting resin varnish on a long base material, a glass non-woven fabric (4) is superposed from the upper surface, while the thermosetting resin varnish is applied from the back surface as described below. . This coating is usually performed by a roll coater (5), but is not limited to this. As the glass nonwoven fabric, one having a basis weight of 20 to 150 g / m ² is usually used. The thermosetting resin varnish that is applied from the back to the long base material is to compensate for the fact that the thermosetting resin varnish initially applied is not sufficiently impregnated into the long base material. The amount of resin to be impregnated may be small, and in order to uniformly impregnate the resin, a resin solid content of about 10 to 30% by weight is usually used.

After that, a thermosetting resin-impregnated prepreg in which a glass nonwoven fabric is laminated on a long base material is obtained by heating and drying through a drying device (6). Since the total thickness of the base material is thick, the heating and drying conditions are slightly stronger than usual, and are 120 to 180 ° C. and about 1 to 5 minutes. Then, this prepreg is cut into a predetermined length by a cutter (7). Alternatively, it may be subjected to continuous molding without cutting.

The prepreg thus obtained is heated and pressure-molded by stacking two sheets with the glass nonwoven fabric side inside. In this molding, two prepregs cut into a predetermined length are usually stacked and heated and pressed by a large number of presses.
It is also possible to continuously heat and press two long prepregs, which are not cut, with one of them upside down. When the resin is an epoxy resin, the former molding method is usually performed, and the molding condition is usually 150 ° C to 150 ° C as in the case of the conventional composite laminated plate, although it depends on the fluidity of the impregnated resin.
180 ° C., pressure 20-70 kg / cm ² , time 60-1
Twenty minutes is suitable. Further, in the case of a polyester resin, the latter continuous molding method that enables low pressure molding can be adopted.

After the initial thermosetting resin has been applied to the long base material, a drying step by heating may be inserted before the glass nonwoven fabrics are laminated. By evaporating the solvent in this drying step, the B-stage of the resin after the glass nonwoven fabrics are superposed becomes easy.

[0014]

The composite laminated plate can be obtained by the steps as described above. However, in the present invention, the glass nonwoven fabric is laminated after the thermosetting resin varnish is applied to the long base material such as the glass woven cloth. Even if the resin varnish is applied from the rear surface after that, the application / impregnation process is simple, and the amount of the relatively expensive glass nonwoven fabric can be reduced. Further, since the glass non-woven fabric moves together with the long base material, the glass non-woven fabric is not cut and the glass fiber pits are not scattered. Therefore, there are few troubles at the time of manufacturing the composite laminate, and cost reduction can be achieved.

[0015]

EXAMPLES Next, examples of the present invention will be specifically described together with comparative examples.

Example A glass woven fabric (WE-18K RB-84 manufactured by Nitto Boseki), which is a long base material, is unwound, and subsequently, a varnish A for FR-4 having the following composition is used by a knife coater. Coating was performed so that the thickness was 0.9 mm (before drying). (Combined with varnish A) Epoxy resin 100 parts by weight (including curing agent dicyandiamide and curing accelerator) Inorganic filler (aluminum hydroxide) 80 parts by weight Ultrafine particle silica 20 parts by weight Solvent (methyl cellosolve) 50 parts by weight Next, upper surface side From above, glass non-woven fabrics with a basis weight of 75 g / m ² (EP-4075 manufactured by Nippon Vilene) are overlaid,
Varnish B having the following composition was applied to the back surface by a roll coater. (Combining varnish B) Epoxy resin (same as above) 30 parts by weight Solvent (methyl cellosolve) 70 parts by weight

Subsequently, the base material coated with the above-mentioned varnishes A and B was heated and dried at 140 ° C. for 3 minutes by a drying device to obtain a prepreg composed of a glass woven cloth and a glass nonwoven cloth. After cutting this into a predetermined length (2 m), two glass nonwoven fabrics are placed inside and two copper foils with a thickness of 18 μm are placed on top and bottom, and the temperature is 165 ° C. and the pressure is 6
Heat press molding at 0 kg / cm ² for 90 minutes to obtain a thickness of 1.
A 6 mm copper clad laminate was prepared.

[Comparative Example 1] The epoxy resin for FR-4 used in the examples was treated with the above solvent to obtain a resin solid content of 60% by weight (0.
It was diluted to 3 poise) to make a varnish. A glass woven fabric (WE-18 manufactured by Nitto Boseki Co., Ltd.) using this varnish in Examples.
KRB-84) was coated and impregnated by a dip method and dried to prepare a surface layer prepreg. Then, the diluted epoxy resin varnish for FR-4 was applied and impregnated on a glass nonwoven fabric (EP-4075 manufactured by Nippon Vilene) by a dip method and dried to prepare a prepreg for an intermediate layer. Then
A predetermined number of intermediate prepregs (4 sheets) are piled up, surface layer prepregs are piled up and down, and a thickness of 18 is piled up and down.
1.6 μm thick by stacking μm copper foil and heating and pressing
A copper clad laminate of was produced.

Comparative Example 2 A glass woven fabric prepreg for a surface layer was produced in the same manner as in Comparative Example 1. On the other hand, a varnish C for FR-4 having the following composition was prepared. (Combined with varnish C) Epoxy resin (same as varnish A) 100 parts by weight Inorganic filler (aluminum hydroxide) 80 parts by weight Ultrafine silica 20 parts by weight Solvent (methyl cellosolve) 65 parts by weight This varnish C is a glass nonwoven fabric (Japan Vilene) Made EP-
4075) was coated and impregnated by the dip method and dried to prepare a prepreg for the intermediate layer. Next, a predetermined number (three) of intermediate prepregs are stacked, surface layer prepregs are stacked on top and bottom, and 18 μm thick copper foils are further stacked on top and bottom of the prepregs and heat-pressed to form a copper clad with a thickness of 1.6 mm. A laminated board was produced.

With respect to the copper clad laminates obtained in the above Examples and Comparative Examples, punching workability, dimensional stability, warp bending strength, and Z-direction thermal expansion coefficient were measured. Table 1 shows the results.

[0021]

[Table 1]

Regarding the manufacturing cost, the method of the example has a simple process, and the amount of expensive glass fiber non-woven fabric used is reduced, so that the laminated plate obtained in the example is obtained in the comparative example. It was possible to reduce the cost by about 10% compared to the conventional one.

[0023]

According to the method of the present invention, it is possible to obtain a laminated plate which is free from deterioration of bending strength, has good punching workability, and has small warpage and dimensional change. Further, since it is excellent in cost reduction and the manufacturing process is simple, it is suitable as an industrial laminated plate manufacturing method.

[Brief description of drawings]

FIG. 1 is a schematic cross-sectional view showing a process up to producing a prepreg in a production process of the present invention.

[Explanation of symbols]

 1 Long base material 2 Varnish 3 Coater 4 Glass nonwoven fabric 5 Roll coater 6 Drying device 7 Cutter 8 Prepreg

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location B32B 31/20 7148-4F B32B 31/20 C08J 5/08 CFC C08J 5/08 CFC 5/24 CFC 5/24 CFC C08K 3/00 C08K 3/00 C08L 63/00 NKT C08L 63/00 NKT H05K 1/03 630 7511-4E H05K 1/03 630F

Claims (3)

[Claims] 1. A step of applying a thermosetting resin varnish from one side of a long fiber base material, a step of overlaying a glass fiber non-woven fabric on the varnish application surface of the fiber base material, and heating and drying these laminates. And a step of obtaining two prepregs with the non-woven fabric inside, and heat-pressing the two prepregs. 2. The method for producing a laminated board according to claim 1, wherein the thermosetting resin varnish contains an inorganic filler. 3. The method for producing a laminated board according to claim 1, further comprising a step of applying a thermosetting resin varnish from the opposite surface after the step of superposing the glass fiber nonwoven fabric on the varnish-coated fiber base material. .