JP4296680B2 - Laminate production method - Google Patents

Description

【００１７】
（測定方法）
１．エネルギーコスト：積層成形時の使用燃料量を比較例２に対して比率で求めた。
２．成形性：銅張積層板の銅箔をエッチングして、目視により外観を観察した。
３．反り：２５０ｍｍ角の銅張積層板のテストピースを１７０℃、３０分間加熱した後の最大反り量を測定した。
４．寸法変化率：穴間隔が２５０ｍｍの銅張積層板のテストピースを１７０℃、３０分間加熱した後の穴間隔の寸法変化率を測定した。
５．引張り強さ：銅張積層板の銅箔をエッチングして、１０×１００ｍｍに切断後テンシロンにて引張り強度を測定した。
６．銅箔引剥し強さ：ＪＩＳ Ｃ ６４８１により測定した。
７．半田耐熱性：５０×５０ｍｍ角の積層板を、２６０℃の半田浴に３分間フロートさせ、ふくれの有無を測定した。
８．絶縁抵抗：ＪＩＳ Ｃ ６４８１により測定した。
【００１８】
【発明の効果】
本発明の方法は、プリプレグの表裏の樹脂厚み差を２０μm以下にして加熱ロールでの樹脂溜まり量が表裏で均一にしたことを特徴とする。従って積層板の表裏の樹脂層厚みが均一となるので、反りが極めて少ない等、積層板品質が良好となる。さらにこのプリプレグを上方から加熱ロール間に供給し、この加熱ロールにより積層成形することによって、設備が小型化し、このことにより使用燃料が削減されるので、エネルギコストの削減、熱源設備からの排出ガスによる大気汚染の減少、及び省資源化を達成することができる。また、積層板製造時において、従来の横方向の移動による連続成形に比べ重力の影響が無くプリプレグ等のテンションが均一になるので、反りが極めて少ない等、積層板品質が良好となる。さらにロールプレスにより積層板を任意の長さに裁断できるため、従来発生していた耳等の端材部分が減り歩留まりが向上する。このように、原材料及び設備、工程の低コスト化の点で優れており、工業的な積層板の製造方法として好適である。
【図面の簡単な説明】
【図１】 本発明における積層板の製造工程を示す概略図。
【図２】 従来の連続法による積層板の製造工程を示す概略図。
【符号の説明】
１，１１ プリプレグ
２，１２ 加熱装置
３，１３ 金属箔又はフィルム
４，１４ 加熱ロール
５，１５ 積層板
６，１６ 裁断機
７，１７ 巻き取り機[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for manufacturing a laminate, and more particularly to a continuous method for producing a laminate suitable for a printed circuit board used in electrical equipment, electronic equipment, communication equipment, and the like.
[0002]
[Prior art]
There is a strong demand for miniaturization and higher functionality for printed circuit boards, but price competition is fierce. In particular, multilayer circuit boards, glass cloth base epoxy resin laminates, or glass nonwoven fabrics used for printed circuit boards are used as intermediate layers. As for the laminated board (composite laminated board) which used the woven fabric and the surface layer base material as a material, reduction of a price has become a big subject.
In recent years, electrical devices, electronic devices, communication devices, etc. have been digitized and require stable impedance in printed circuit boards. With this, copper-clad laminates that are the raw materials for printed circuit boards Thickness accuracy has been required.
In the case of laminating and forming a multilayer circuit board or a glass cloth base epoxy resin laminate or a composite laminate used for a printed circuit board as described above, a copper foil, a prepreg, a printed circuit board for an inner layer between hot plates, A multi-stage batch press in which a number of mirror plates or the like are stacked and heated and pressed is generally used. However, in such a multi-stage batch press, the heat history applied to each laminated plate during lamination molding differs depending on the position of each laminated plate in the hot platen, so there is a difference in quality such as formability, warpage, and dimensional change rate. Therefore, it was difficult to supply a product with less quality variation. Further, since the laminated plate is molded at a high pressure of ^{20 to} 100 kg / cm ² , there is a problem that the platen accuracy is not obtained by the resin flow.
Also, multi-stage batch presses require a huge amount of heat to heat and cool jigs required to form laminated plates such as hot plates, cover plates, cushion materials, etc. It was difficult to save energy for the global environment.
[0003]
Conventionally, a horizontal continuous belt press or the like has been developed as a laminated plate with little quality variation and equipment capable of energy saving. As shown in an example in FIG. 2, the prepreg 11 is unwound and preheated by a heating device 12 as necessary, and a metal foil or film 13 is supplied from the upper and lower sides of the prepreg. Then, the laminated plates 15 are formed by overlapping with one pair (or a plurality of pairs) of heating rolls 14 and heating and pressing. Thereafter, the paper is cut by the cutting machine 16 or wound on the winding machine 17. The laminated plate 15 is usually after-baked before or after cutting. However, in any of these methods, there is a problem that the front and back are different in terms of formability and copper foil adhesive force due to the difference in vertical direction due to gravity and the difference in the entrance angle of the material, and the warp due to the difference in the tension of the copper foil and the base material. There is a problem that the change in dimensions and the size are large, or in the belt press, there is a problem that pressure unevenness and temperature unevenness are easily generated when sandwiched between belts.
In particular, when the resin thicknesses on the front and back sides of the prepreg are different, there is a problem in that when the resin is sandwiched between belts and rolls, a resin pool is formed and a void is generated on the side where there is no liquid pool due to a difference in hydraulic pressure. Further, even when the difference in resin thickness between the front and back surfaces of the prepreg is made into a laminate, the difference in resin thickness between the front and back surfaces is directly caused, which is a problem of warpage.
[0004]
[Problems to be solved by the invention]
As described above, the conventional multi-stage press has a large quantity for heating and cooling jigs necessary for forming moldability, warpage, dimensional change rate, plate thickness, and other variations in quality due to heating of a large number of sheets. There was a problem of needing heat. Further, the horizontal continuous press has problems such as a decrease in adhesive strength of copper foil, a decrease in dimensional stability, and a warp due to a pressure difference due to gravity, a variation in temperature, a variation in tension on a material, and the like. In addition, there is a problem that the cause of warp and warpage increase due to the difference in resin thickness between the front and back surfaces of the prepreg.
The present invention eliminates the problems of conventional laminate forming methods, eliminates the internal residual stress in laminate forming, improves the warpage of the laminate, dimensional stability, has no bubbles, has good formability, and saves energy. An object of the present invention is to provide a method for manufacturing an inexpensive laminate of a mold.
[0005]
[Means for Solving the Problems]
In the present invention, one or a plurality of prepregs each having a resin attached to a sheet-like fiber base material are moved vertically from top to bottom, and a metal foil or film is superposed on one or both sides and heated between rolls. In the manufacturing method of a laminated board that is inserted from above into a continuous laminated molding, the difference in resin thickness between the front and back of the prepreg is set to 20 μm or less, and the amount of the resin pool in the heating roll is made substantially the same on the front and back. The present invention relates to a method for manufacturing a laminated board.
Furthermore, the present invention relates to a method of manufacturing a laminated board having a process of preheating before inserting a prepreg between rolls, in a laminated board having a metal foil on both sides, and between the both sides of the sheet-like fiber substrate and the metal foil. The present invention relates to a method for manufacturing a laminated board in which the difference in resin layer thickness is 10 μm or less.
[0006]
In the present invention, as the sheet-like fiber base material, in addition to glass fiber base materials such as glass cloth, glass non-woven cloth, and glass paper, woven or non-woven fabric made of paper, synthetic fiber, etc., metal fiber, carbon fiber, mineral fiber Woven fabrics, non-woven fabrics, mats, and the like, and the raw materials for these substrates may be used alone or in combination.
The resin attached to these sheet-like fiber base materials for producing a prepreg is generally a thermosetting resin, preferably an epoxy resin, a polyimide resin, a phenol resin, a melamine resin, or a modified resin thereof. In addition, resins such as thermoplastic resins and natural resins are also used, but are not limited thereto. The form of the resin when the resin is adhered to the substrate is usually a varnish dissolved in a liquid, particularly a solvent, but may be a powdered resin or a state in which a solid resin is heated and melted. In the case of a thermosetting resin, a curing agent and a curing accelerator are blended as necessary.
Moreover, a filler, a coloring agent, and a reinforcing material can be mix | blended in resin. When an inorganic filler is added as a filler, characteristics such as tracking resistance, heat resistance, and a decrease in coefficient of thermal expansion can be imparted. Such inorganic fillers include aluminum hydroxide, magnesium hydroxide, calcium carbonate, talc, wollastonite, alumina, silica, unfired clay, fired clay, barium sulfate and the like.
[0007]
Next, the obtained resin is uniformly applied onto the sheet-like fiber base material. The resin adhesion amount at this time varies depending on the fiber material, properties, and weight (per unit area) of the sheet-like fiber substrate, but is usually about 40 to 60% of the weight of the sheet-like fiber substrate. However, it is made to adhere so that the difference of the resin thickness in the front and back may become 20 micrometers or less on both surfaces of a base material. If the difference in resin thickness between the front and back surfaces is greater than 20 μm, a phenomenon of warping in the thicker direction occurs due to curing shrinkage or thermal expansion of the resin. The thickness difference is preferably as small as possible, and warpage is more effectively prevented at 10 μm or less.
The method for adhering the resin to the sheet-like fiber substrate is not particularly limited as long as the resin adheres satisfactorily, such as a method of immersing the substrate in a resin varnish, a coating method using various coaters, or a spraying method using a spray. The amount of resin on the front and back sides is controlled by the gap between the coater and the substrate in the case of various coaters. In the case of spraying, the amount of resin sprayed on the front and back is controlled. In particular, when the resin is solvent-free, the sheet-like fiber base material may be preheated. In this case, when the resin is attached to the sheet-like fiber base material, the base material may be horizontal. It may be vertical. Therefore, it can be made to adhere to the upper surface or lower surface or vertical surface of the sheet-like fiber substrate by coating. A prepreg is obtained by subsequent heating.
[0008]
The prepreg obtained as described above is usually once wound by a winder or the like. Thereafter, it is unwound and one or more sheets are stacked. One or a plurality of prepregs may be directly stacked without being wound up. Subsequently, a metal foil such as a copper foil or a film is superposed on one side or both sides thereof and passed between heating rolls in the vertical direction to form a laminate. In this case, it shape | molds through between a pair or several pairs of rolls. The material of the roll is usually a metal, rubber, ceramic or the like, but a material having a small coefficient of friction is preferable from the point described later. Although it is possible to use a cut prepreg, it is preferable that the prepreg is continuously formed without being cut.
About the temperature of a roll, the applicable range is 110-280 degreeC, for example, the range of 110-190 degreeC in the case of an epoxy resin and 210-280 degreeC in the case of a polyimide resin is preferable.
Further, the prepreg is preferably heated and melted by far infrared rays before passing between the heating rolls, so that molding defects due to insufficient heat amount can be prevented when molding with the heating roll.
[0009]
Hereinafter, regarding the manufacturing method of the laminated board of this invention, a lamination | stacking formation process is sequentially demonstrated based on drawing for each process about a typical example.
(Supply prepreg)
The wound prepreg 1 is unwound and transferred from the upper side to the lower side to be supplied between the heating rolls 4. If necessary, the prepreg 1 is unwound and then heated in advance by a heating device 2 such as a far infrared ray.
(Metal foil supply)
The wound metal foil 3 is unwound and supplied to both sides (or one side) of the prepreg 1.
(Heating roll)
The metal foil 3 is brought into contact with a predetermined position on the surface of the heating roll 4, the surface is moved with the rotation of the roll, overlapped with the prepreg 1, and laminated through a pair or a plurality of heating rolls 3 from above.
(Cutting or winding process)
The molded laminated plate 5 is cut into a required length by a cutting machine 6 or wound up on a winding machine 7. The laminate 5 is usually after-baked before or after cutting.
[0010]
【Example】
Hereinafter, the present invention will be described with reference to examples and comparative examples.
[0011]
Example 1
100 parts by weight of epoxy resin (brominated epoxy resin Ep5048, epoxy equivalent 675 manufactured by Yuka Shell Epoxy Co., Ltd.), 5 parts by weight of curing agent (dicyandiamide), 1 part by weight of curing accelerator (2-ethyl-4-methylimidazole) And 100 parts by weight of methyl cellosolve was mixed to obtain a varnish.
The obtained varnish is applied to a glass cloth of 100 g / m ^{2 with} a comma knife coater so that the total resin solid content is 100 g / m ² and the thickness of the solid resin layer on the front and back surfaces of the glass cloth is 20 μm. Impregnated. Subsequently, it dried for 3 minutes with 170 degreeC dryer, and obtained prepreg was wound up by the winder.
As shown in FIG. 1, the wound prepreg is transported almost vertically from above to below, and a copper foil having a thickness of 18 μm is supplied to both sides thereof, and a pair of heating rolls (gap 0.1 mm) are heated to 180 ° C. ) Heat-press molding in between. Thereafter, after-curing at 180 ° C. for 60 minutes, a double-sided copper-clad laminate having a thickness of 0.1 mm was produced.
[0012]
(Example 2)
Varnishes were obtained in the same manner as in the examples. The obtained varnish is applied to a glass cloth of 100 g / m ^{2 with} a comma knife coater so that the total resin solid content is 100 g / m ² and the solid resin layer thickness is 25 μm on the front surface and 15 μm on the back surface. After impregnation, it was dried for 3 minutes with a dryer at 170 ° C., and the obtained prepreg was wound on a winder.
Thereafter, a double-sided copper clad laminate having a thickness of 0.1 mm was produced in the same manner as in Example 1.
[0013]
(Comparative Example 1)
Varnishes were obtained in the same manner as in the examples. The obtained varnish is applied to a glass cloth of 100 g / m ^{2 with} a comma knife coater so that the total resin solid content is 100 g / m ² and the solid resin layer thickness is 40 μm on the front surface and 10 μm on the back surface. After impregnation, it was dried for 3 minutes with a dryer at 170 ° C., and the obtained prepreg was wound on a winder.
Thereafter, a double-sided copper clad laminate having a thickness of 0.1 mm was produced in the same manner as in Example 1.
[0014]
(Comparative Example 2)
The prepreg produced in the same manner as in Example 1 was transported horizontally as shown in FIG. 2 (but not preheated), and 18 μm thick copper foil was supplied from both the upper and lower sides and heated to 180 ° C. Heat pressing was performed between a pair of heated rolls (gap 0.1 mm). Thereafter, after-curing at 180 ° C. for 60 minutes, a double-sided copper-clad laminate having a thickness of 0.1 mm was produced.
[0015]
(Comparative Example 3)
The prepreg obtained in Comparative Example 1 was cut into a certain length, and 18 μm thick copper foils were placed on the upper and lower surfaces thereof and placed between mirror mirror plates, and 10 sets of these were stacked, at a temperature of 165 ° C., pressure A double-sided copper-clad laminate was produced by heating and pressing at 8 kg / cm ² for 90 minutes.
[0016]
The characteristics of each copper clad laminate obtained as described above were measured. Furthermore, the energy cost required for molding was determined. These results are shown in Table 1.
[Table 1]

[0017]
(Measuring method)
1. Energy cost: The amount of fuel used at the time of laminate molding was determined as a ratio relative to Comparative Example 2.
2. Formability: The copper foil of the copper clad laminate was etched, and the appearance was visually observed.
3. Warpage: The maximum amount of warpage after a test piece of a copper-clad laminate of 250 mm square was heated at 170 ° C. for 30 minutes was measured.
4). Dimensional change rate: The dimensional change rate of the hole interval after heating a test piece of a copper clad laminate having a hole interval of 250 mm at 170 ° C. for 30 minutes was measured.
5. Tensile strength: The copper foil of the copper clad laminate was etched, cut to 10 × 100 mm, and the tensile strength was measured with Tensilon.
6). Copper foil peel strength: Measured according to JIS C 6481.
7). Solder heat resistance: A 50 × 50 mm square laminate was floated in a 260 ° C. solder bath for 3 minutes, and the presence or absence of blistering was measured.
8). Insulation resistance: Measured according to JIS C 6481.
[0018]
【The invention's effect】
The method of the present invention is characterized in that the resin thickness difference between the front and back surfaces of the prepreg is set to 20 μm or less so that the amount of the resin pool on the heating roll is uniform between the front and back surfaces. Therefore, since the resin layer thickness on the front and back of the laminated board becomes uniform, the quality of the laminated board is improved such that the warpage is extremely small. Further, the prepreg is supplied between the heating rolls from above and laminated with the heating rolls, thereby reducing the size of the equipment and thereby reducing the fuel used. Therefore, the energy cost is reduced and the exhaust gas from the heat source equipment is reduced. Air pollution can be reduced and resources can be saved. In addition, when manufacturing a laminate, the tension of the prepreg and the like is uniform and there is no influence of gravity compared to the conventional continuous forming by lateral movement, so that the laminate quality is improved, for example, the warpage is extremely small. Furthermore, since the laminated plate can be cut into an arbitrary length by a roll press, the end material portions such as ears which have been conventionally generated are reduced, and the yield is improved. Thus, it is excellent in terms of cost reduction of raw materials, equipment, and processes, and is suitable as an industrial laminate production method.
[Brief description of the drawings]
FIG. 1 is a schematic view showing a production process of a laminated board according to the present invention.
FIG. 2 is a schematic view showing a manufacturing process of a laminate by a conventional continuous method.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1,11 Prepreg 2,12 Heating device 3,13 Metal foil or film 4,14 Heating roll 5,15 Laminated plate 6,16 Cutting machine 7,17 Winding machine

Claims (3)

Move one or more prepregs with resin attached to a sheet-like fiber base material from the top to the bottom in the vertical direction, overlay metal foil or film on one or both sides, and insert between heated rolls from above In the method of manufacturing a laminated board that is continuously laminated and formed, the difference in the resin thickness between the front and back of the prepreg is 20 μm or less, and the amount of the resin pool on the heating roll is made substantially the same on the front and back. Method. The manufacturing method of the laminated board of Claim 1 which preheats before inserting a prepreg between rolls. The method for producing a laminated board according to claim 1 or 2, wherein in the laminated board having the metal foil on both sides, a difference in thickness of the resin layer between both sides of the sheet-like fiber base material and the metal foil is 10 µm or less.

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