JP5949896B2 - Sheet for fiber-reinforced plastic molded body and molded body thereof - Google Patents

Description

  The present invention relates to a sheet for a molded article useful as a precursor of a fiber reinforced plastic molded article using thermoplastic fibers as a matrix resin, and a fiber reinforced plastic molded article obtained by heating and pressing the molded sheet. In particular, it is formed using a thermoplastic resin fiber (Patent Document 1) called “super engineering plastic” that is heat resistant and highly flame retardant as a matrix resin, and is molded in a short time with flame retardancy. The present invention relates to a sheet that is useful as a stampable sheet that can be used, and a flame-retardant and high-strength fiber-reinforced plastic molded body obtained by heating and pressing the sheet. A member (precursor) before molding of a fiber reinforced plastic molded body using a thermosetting resin as a matrix resin is generally referred to as “prepreg”. The stampable sheet in the present invention is formed using a thermoplastic resin called a super engineering plastic as a matrix resin component, and is a precursor for producing a fiber-reinforced plastic molded body by heat and pressure molding The sheet corresponds to the “prepreg”.

  As a lightweight and high-strength composite material, a resin molded body reinforced with carbon fiber, glass fiber, or other reinforcing fibers has already been used in various fields such as sports, leisure goods, and aircraft materials. The resin used as a matrix in these carbon fiber reinforced resin molded products is mainly still an epoxy resin, an unsaturated polyester resin, or sometimes a thermosetting resin such as a phenol resin. However, in the case of these thermosetting resins, the impact resistance of the fiber reinforced resin molded product is inferior, and when the resin is impregnated into a fiber to make a prepreg, refrigerated storage is necessary and the pot life is limited and long-term There is a difficulty that it cannot be stored.

  Furthermore, the thermosetting resin needs to be cured by polymerization reaction in a state heated to a temperature of about 122 ° C to 177 ° C. However, since the polymerization reaction takes about 2 hours, the heat molding time becomes longer and the production takes place. There is also a problem that the property is low (Non-patent Document 1).

  On the other hand, when a thermoplastic resin is used as the matrix resin, the impact resistance of the fiber reinforced resin molded product is excellent, and the storage management of the resin and the fiber reinforced resin composite material in the state before molding processing is easy, and the molding time is short. Since there is an excellent point such as paddle, for example, research and development of a fiber reinforced resin molded body made of a fiber reinforced resin composite material using a thermoplastic resin as a matrix resin such as a polycarbonate resin, a polyester resin, or a polypropylene resin has been conducted.

  Generally, when producing a fiber reinforced resin molded body with these resins, as a method for producing a stampable sheet which is a sheet used as a precursor thereof, depending on the type of resin impregnation method for fibers, a melting method ( Hot melt methods), solvent methods, dry powder coating methods, powder suspension methods, resin film impregnation methods (film stacking methods), mixed weaving methods (Commingle), and the like have been proposed (Non-patent Document 1).

  The melting method is a manufacturing method in which a thermoplastic resin is melted by an extruder, continuous fibers are passed through a melting bath, and the resin is impregnated into the inside of the fiber. The solvent method is a resin (mainly amorphous resin) that is a solvent. This is a production method in which a reinforcing fiber is impregnated using a solution dissolved in (1).

  The dry powder coating method is a method in which dry powder is adhered to reinforcing fibers and heated in the next step to melt and impregnate the powder. The powder suspension method is a method in which reinforcing fibers are passed through a tank in which resin powder is uniformly dispersed in water or solvent, the powder is adhered to the reinforcing fibers, and heated in the next step to melt and impregnate the powder.

  The resin film impregnation method is a manufacturing method in which a resin film and reinforcing fibers are combined and the resin is melted and impregnated by a double belt press or an intermittent press method.

  The mixed weaving method (Comingle method) is a technique for producing a composite yarn by combining a reinforcing fiber and a thermoplastic resin fiber. The composite yarn is processed into a fabric (unidirectional, plain weave, braid, multiaxial fabric, etc.) to obtain an intermediate material, which is directly passed through a thermoforming process, and a thermoplastic resin fiber is combined with a reinforcing fiber to obtain a product.

  On the other hand, a technique has been proposed in which a short fiber of a thermoplastic resin and a reinforcing fiber are mixed and dispersed in air or water to form a sheet, and the thermoplastic resin short fiber and the reinforcing fiber are combined (Patent Document 2, Patent Document 3).

  In Patent Document 2, a proposal is made to heat and press-mold a web obtained by uniformly mixing carbon fibers as reinforcing fibers and a thermoplastic fibrous matrix resin in air or water and capturing them on a net. Patent Document 3 discloses a technique for heat-pressing a paper-making substrate obtained by dispersing reinforcing fibers and matrix resin fibers in a dispersion medium, mixing and then removing the dispersion medium. ing.

  However, a fiber reinforced resin molded article using a thermoplastic resin such as polycarbonate resin, polyester resin, or polypropylene resin as a matrix resin as described above has a thermosetting resin as a matrix resin in terms of heat resistance and flame retardancy. There is a disadvantage that it is inferior to the fiber reinforced resin molded product.

  Patent Document 4 discloses a sheet for a fiber-reinforced plastic molded body comprising a high-melting-point thermoplastic material and reinforcing fibers.

Japanese Patent No. 4832072 Japanese Patent Publication No.62-1969 JP 2011-157638 A Japanese Patent No. 4708330

“2007 Survey Report on Application of Thermoplastic Resin Composite Materials to the Machine Industry Field”, Next Generation Metals / Composite Research and Development Association, Japan Machinery Federation, March 2008

  With regard to thermoplastic resins, in recent years, thermoplastic resins with excellent heat resistance and chemical resistance have been actively developed, and the above-mentioned drawbacks that have become common knowledge about thermoplastic resins have been remarkably improved. Has been. Such thermoplastic resins are so-called “super engineering plastics” (super engineering plastics), such as polyphenylene sulfide (PPS), polyether ether ketone (PEEK), polyamide imide (PAI), polyether imide (PEI). (Non-Patent Document 1).

  The thermoplastic resin referred to as the “super engineering plastic” is one of the characteristics that not only has excellent physical properties but also extremely high flame retardancy, and the limiting oxygen index is 30 or more in the state of the resin block. There are many things. Although various attempts have been made to study stampable sheets using such super engineering plastics, there are the following problems.

  Stampable sheets manufactured by the melting method (hot melt method), solvent method, dry powder coating method, powder suspension method, resin film impregnation method (film stacking method) are harder than thermosetting prepregs before curing. The current situation is that it has no drape, low tack, and extremely poor handling (Non-Patent Document 1).

  Stampable sheets using super engineering plastics are characterized by a shorter molding time than thermosetting prepregs, but they are melted (hot melt), solvent, dry powder coating, powder suspension, resin Stampable sheets manufactured by the film impregnation method (film stacking method) have poor breathability, so if you try to mold in a short time, the bubbles that exist between the hot plate for pressing and the sheet cannot be removed, and the molten resin It is easy to generate defects such as defects in appearance and defects in strength.

  In addition, when stacking a plurality of stampable sheets in order to achieve a desired thickness of the molded product after heat and pressure molding, air is easily trapped between the stampable sheets, and defects are further improved than in the case of a single layer. It tends to occur.

  In addition, the woven fabric obtained by the mixed weaving method can give flexibility before forming, but generally has a lower productivity than the method in which short fibers are dispersed in air or water to form a sheet. It has the disadvantage of high cost.

  In order to avoid the above drawbacks, in Patent Document 2 and Patent Document 3, carbon fibers that are reinforcing fibers and thermoplastic fibrous matrix resin are uniformly mixed in air or water and captured on a net. A proposal has been made to heat-press the obtained web, and Patent Document 3 obtained by dispersing reinforcing fibers and matrix resin fibers in a dispersion medium, mixing and removing the dispersion medium. Although a technique for heat-pressing a papermaking substrate has been disclosed, such a web or papermaking substrate has a binder as an essential component in order to obtain process strength when moving to a pressing process after mat formation. .

  However, stampable sheets using thermoplastic resins, which are super engineering plastics with high heat resistance and flame retardancy, as matrix resins are exposed to temperatures as high as 300 ° C or higher during heat and pressure molding. Voids (hereinafter referred to as “voids”) are generated due to the vaporized binder, and both appearance and strength are likely to be reduced.

  A stampable sheet using a normal thermoplastic resin as a matrix resin, such as nylon or polypropylene, and a prepreg using a thermosetting resin as a matrix resin are not molded at such a high temperature. None of the above-mentioned prior art documents discloses a technique relating to a binder that can withstand the heating and pressing at a high temperature as described above.

  In addition, fiber reinforced plastic in which a matrix resin is impregnated with a sheet in which reinforcing fibers are aligned or a sheet in which reinforcing fibers are knitted in a cross shape shows a very high bending strength in the direction of the reinforcing fibers. The bending strength is weak in a direction different from the direction. As a method for improving this, there is a method of laminating and pressing a plurality of sheets composed of sheets in which reinforcing fibers are aligned or a sheet in which reinforcing fibers are knitted in a cross shape, with their fiber directions being shifted, Problems such as a complicated process and a decrease in the yield of the stampable sheet occur.

  In view of such circumstances, in the present invention, a stamper from which a fiber-reinforced resin molded article having high strength, high heat resistance, and excellent flame retardancy using a thermoplastic resin having high heat resistance and flame retardancy as a matrix resin is obtained. In a sheet useful as a bull sheet, in addition to obtaining a sufficiently strong fiber-reinforced resin molded article without generation of voids even in a very short heat-press molding time, as a stampable sheet An object of the present invention is to provide a sheet useful as a stampable sheet having high productivity and excellent handling properties in a processing process at a low cost.

  Furthermore, the fiber reinforced resin molded body after heat and pressure molding is excellent in the strength of the fiber in the reinforcing fiber sheet, and is also excellent in the strength in the direction different from the direction of the fiber in the reinforcing fiber sheet; An object is to provide a sheet that can be made.

  As a result of intensive investigations to solve the above problems, the present inventors, in a fiber reinforced plastic molded sheet using a heat-resistant and flame-retardant thermoplastic resin called a so-called super engineering plastic as a matrix resin, A non-woven sheet containing chopped strands of super engineering plastic fibers having a specific fiber diameter as a matrix resin component and a multilayer sheet in which reinforcing fibers are aligned or reinforcing fiber sheets woven in a cross shape are bonded together By forming and using the matrix fiber, the matrix fiber is sufficiently melted and penetrated into the reinforcing fiber sheet even when the heating and pressing time is shorter than that of a stampable sheet using a conventional high heat-resistant thermoplastic resin. The present inventors have found that a fiber-reinforced plastic molded body having sufficient strength can be obtained.

  Moreover, after making the said nonwoven fabric sheet into the nonwoven fabric sheet containing the chopped strand of a reinforcement fiber, forming the multilayer sheet | seat bonded with the reinforcement fiber sheet, and using it as a stampable sheet, in a reinforcement fiber sheet It has been found that a fiber-reinforced plastic molded body having not only high strength in the direction in which the reinforcing fibers are aligned but also strength in other directions is obtained.

  In addition, by bonding a nonwoven fabric sheet containing a chopped strand of a super engineering plastic fiber of a specific fiber diameter as a matrix resin component, and a reinforcing fiber sheet in which reinforcing fibers are aligned or reinforced fibers are knitted in a cross shape, It is possible to keep the breathability of the stampable sheet higher than a certain value (air can easily pass through), and even with a short heating and pressing time, no voids are generated, and the fiber reinforced resin has good appearance and strength. It has been found that a molded body can be obtained.

  In addition, the multilayer sheet including the nonwoven fabric sheet described above needs to contain a binder for binding the intersections of chopped strand (short fiber) super engineering plastic fibers and reinforcing fibers. In addition to selecting the blending ratio of the binder to be contained in the sheet for the fiber-reinforced plastic molded article and incorporating the binder so as to have a specific distribution state, the handleability as a stampable sheet is good, and heating is applied. It has been found that after pressure molding, a high-strength, fiber-reinforced resin molded article can be obtained with no voids and good appearance.

  Based on the above new findings, the present inventors have made the following inventions.

(1) A multilayer sheet (stampable sheet) in which a reinforcing fiber sheet and a nonwoven sheet containing a matrix resin component are bonded, and the nonwoven sheet has at least a critical oxygen index of 25 or more and a fiber diameter. A fiber reinforced plastic molded sheet (stampable sheet) comprising a matrix resin component composed of chopped strands of super engineering plastic fibers of 30 μm or less and a binder component.

(2) The nonwoven fabric sheet containing the matrix resin component has a chopped strand of reinforcing fiber, a critical oxygen index of 25 or more, a fiber diameter of 30 μm or less, and 4 times or less of the fiber diameter of the reinforced fiber chopped strand. The fiber-reinforced plastic molded sheet (stampable sheet) according to item (1), comprising a matrix resin component composed of chopped strands of super engineering plastic fibers and a binder component.

(3) JAPAN TAPPI Paper Pulp Test Method No. The sheet for fiber-reinforced plastic molded articles according to (1) or (2), wherein the air permeability defined in 5-2 is 200 seconds or less.

(4) The fiber reinforcement according to any one of items (1) to (3), wherein the amount of the binder component contained in the nonwoven fabric sheet is 10% by mass or less of the total fiber-reinforced plastic molded sheet. Plastic molded sheet (stampable sheet).

(5) The fiber-reinforced plastic molding according to any one of (1) to (4), wherein the binder component is unevenly distributed so that many portions thereof are present in a surface layer portion of the nonwoven fabric sheet. Body seat (stampable seat).

(6) The fiber-reinforced plastic molded sheet (stampable sheet) according to any one of (1) to (5), wherein the binder component is compatible with a matrix resin component made of the super engineering plastic fiber. ).

(7) The binder component according to any one of items (1) to (6), wherein the binder component is applied to the nonwoven fabric sheet by a coating method or an impregnation method as a solution or an emulsion containing the binder component. Sheet for fiber reinforced plastic molding (stampable sheet).

(8) The fiber reinforced plastic molding according to any one of (1) to (7), wherein a part of the binder component is a fibrous thermoplastic resin having a melting point lower than a glass transition temperature of the super engineering plastic fiber. Body seat (stampable seat).

(9) The fiber reinforced plastic molded sheet (stamper) according to item (8), wherein the matrix resin component is a polyetherimide resin and the binder component contains at least a modified polyester resin having a melting point of 80 ° C to 130 ° C. Bull seat).

(10) a solution or emulsion of the binder, an emulsion containing a copolymer containing at least one selected from methyl methacrylate and ethyl menu methacrylate as a monomer component, (7) and (8) according to claim Sheet for fiber reinforced plastic molding (stampable sheet).

(11) The blending ratio of the binder which is an emulsion is 0.5 mass% to 3.0 mass% with respect to the stampable sheet, and the blending ratio of the binder which is a fibrous thermoplastic resin is 1 mass with respect to the stampable sheet. The sheet (stampable sheet) for fiber-reinforced plastic molded articles according to item (10), wherein the sheet is% to 6% by mass.

(12) The reinforcing fiber sheet is a one-way continuous fiber selected from inorganic fibers such as glass fibers and carbon fibers, and organic fibers excellent in heat resistance such as aramid fibers and PBO (polyparaphenylene benzoxazole) fibers. A sheet for a fiber-reinforced plastic molded article (stampable sheet) according to any one of items (1) to (11), which is a sheet selected from a sheet aligned in a woven fabric or a woven fabric woven in a cloth shape.

(13) A stampable sheet comprising the fiber-reinforced plastic molded sheet according to any one of (1) to (12).

(14) Using the fiber-reinforced plastic molded sheet described in any one of (1) to (12) as a stampable sheet, the matrix resin component made of the super engineering plastic fibers is melted. A fiber-reinforced plastic molded body formed by heating and pressing under conditions.

(15) A method for producing a stampable sheet according to any one of (1) to (12), wherein the reinforcing fiber sheet has at least a critical oxygen index of 25 or more and a fiber diameter. Laminating a matrix resin component composed of chopped strands of super engineering plastic fibers having a thickness of 30 μm or less and a nonwoven fabric sheet containing a binder component, heat-treating, and partially melting and bonding the super engineering plastic fibers in the nonwoven fabric sheet A method for producing a stampable sheet.

  This specification is described in the specification and / or drawings of Japanese Patent Application Nos. 2012-44141, 2012-93479, 2012-155590 and 2012-280652 which are the basis of the priority of the present application. Includes content.

  The sheet for a fiber-reinforced plastic molded body of the present invention is molded into a fiber-reinforced resin molded body that is free from voids and good in strength and appearance by being heated and pressed.

  According to the sheet for a fiber-reinforced plastic molded body of the present invention, it is possible to obtain a fiber-reinforced resin molded body having excellent strength not only in the direction of the reinforcing fibers but also in other directions.

  In the present invention, the “fiber reinforced plastic molded sheet” is a multilayer sheet formed by laminating a reinforcing fiber sheet and a nonwoven sheet containing thermoplastic resin fibers as a matrix resin component.

[Reinforced fiber sheet]
As the reinforcing fiber sheet used for the fiber-reinforced plastic molded sheet of the present invention, a sheet in which continuous fibers used in general fiber-reinforced plastic are aligned in one direction, or a woven cloth woven in a cloth shape is used. Can be used. The material of the reinforcing fiber used for the sheet composed of such continuous fibers is not particularly limited as long as sufficient strength according to the use as the fiber reinforced plastic body can be obtained, and inorganic such as glass fiber and carbon fiber. It is also possible to use organic fibers having excellent heat resistance, such as fibers, aramid fibers, PBO (polyparaphenylene benzoxazole) fibers, or the like. In addition, when using an organic fiber as a reinforced fiber used by this invention, the shaping | molding temperature at the time of forming a molded object by using the sheet | seat for fiber reinforced plastic molded objects as a stampable sheet is very high as 300-400 degreeC. Therefore, even if it is a fiber that does not have a softening point like para-aramid fiber or PBO fiber and has a thermal decomposition temperature higher than 400 ° C. or a thermoplastic fiber that has a softening point, it is a fiber whose softening temperature is higher than the molding temperature. is there.

  For example, in the case of a fiber-reinforced plastic molded sheet using inorganic fibers such as carbon fibers as the reinforcing fibers used in the reinforcing fiber sheet, bending strength and tensile strength can be obtained by heating and pressing at the melting temperature of the matrix resin fibers. -A fiber-reinforced plastic body having a high elastic modulus can be obtained.

  On the other hand, when high heat-resistant and high-strength organic fibers such as para-aramid fibers are used, a fiber-reinforced plastic body suitable for precision polishing equipment that requires high smoothness can be obtained. A fiber-reinforced plastic body formed as a stampable sheet using a fiber-reinforced plastic molded sheet containing organic fibers such as aramid as a reinforcing fiber is generally formed from a stampable sheet using inorganic fibers as reinforcing fibers. Because it has better wear resistance than fiber reinforced plastics, and even if a part of the fiber reinforced plastics is scraped off by rubbing etc., the shavings are softer than inorganic fibers, so there is less risk of damaging the object to be polished It is.

[Nonwoven fabric sheet]
The nonwoven fabric sheet used for the fiber-reinforced plastic molded sheet of the present invention is composed of a nonwoven fabric containing thermoplastic resin fibers and a binder that are at least melted by thermoforming to form a matrix resin.

  As the thermoplastic resin fibers used for the nonwoven fabric sheet, thermoplastic resin fibers called super engineering plastics (super engineering plastics), and low melting point thermoplastic resin fibers such as PET, PP, PE, etc., have a certain length. A method of forming a web by dispersing chopped strands cut into air and capturing them in a net (dry nonwoven fabric method), the above-mentioned super engineering plastic fibers and low melting point thermoplastic resin fibers such as PET, PP, PE, A nonwoven fabric sheet produced by a method (wet nonwoven fabric method) or the like in which chopped strands are dispersed in a solvent and then the solvent is removed to form a web is used.

  The low melting point thermoplastic resin fiber has a melting point of 180 ° C. or less, and examples thereof include fibers made of PP, PE, PET, modified PET, and the like, or core-sheath fibers thereof. The addition amount is preferably about twice or less than that of the binder component added to the nonwoven fabric sheet.

  A preferable combination as the binder component is a combination of an acrylic emulsion and a chopped PET fiber as a low melting point thermoplastic resin fiber. Specifically, it is 1 to 7 parts by mass of PET fiber with respect to 0.1 to 4 parts by mass of the acrylic binder. Preferably it is 2-6 mass parts of PET fiber with respect to 1-3 mass parts of acrylic binder, More preferably, it is 3-5 mass parts of PET fiber with respect to 1.5-2.5 mass parts.

[Super engineering plastic fiber]
The super engineering plastic fiber in the nonwoven fabric sheet used for the fiber-reinforced plastic molded sheet of the present invention is obtained by fiberizing a heat-resistant and flame-retardant thermoplastic resin.

  Examples of such thermoplastic resins include polyetheretherketone (PEEK), polyamideimide (PAI), polyphenylene sulfide (PPS), polyetherimide (PEI), polyetherketoneketone (PEKK), etc. It is not limited to this.

  The super engineering plastic fiber preferably has a critical oxygen index of 25 or higher and a glass transition temperature of 140 ° C. or higher in the fiber state. When the critical oxygen index of the super engineering plastic fiber component is 25 or more, the flame retardancy is excellent.

  In the present invention, the “limit oxygen index” represents an oxygen concentration necessary to continue combustion, and is a numerical value measured by the method described in JIS K7201. That is, a critical oxygen index of 20 or less is a numerical value indicating that combustion is performed in normal air.

  The super engineering plastic fibers in the nonwoven fabric sheet can be used without particular limitation as long as the fiber diameter is 30 μm or less, but those having a diameter of 20 μm or less are preferable, and those having a fiber diameter of about 1 μm can be used if they are easily available.

  Super engineering plastic fibers are required to be sufficiently fluid under temperature conditions of 300 ° C. to 400 ° C. when used as a stampable sheet for heat and pressure molding. Since it is required that the fiber state is sufficiently maintained although it is partially melted under the heat treatment conditions applied when the reinforcing fiber sheet and the nonwoven fabric sheet are bonded in the manufacturing process of the sheet for reinforced plastic molded body, The glass transition temperature of engineering plastic fibers is preferably 140 ° C. or higher. Moreover, even if it is a super engineering plastic fiber having a glass transition temperature of less than 140 ° C. such as PPS resin fiber, it can be used as long as the super engineering plastic having a resin deflection temperature of 190 ° C. or higher is made into a fiber. Such super engineering plastic fibers are melted by heating and pressurizing to form a resin block having a very high flame retardancy with a limiting oxygen index of 30 or more.

  When polyphenylene sulfide (PPS) fiber is used as the super engineering plastic fiber used for the fiber-reinforced plastic molded sheet of the present invention, the PPS resin has high chemical resistance and high heat resistance. A fiber reinforced plastic having excellent strength can be obtained.

  In addition, when polyetherimide (PEI) fiber is used as super engineering plastic fiber, PEI resin has excellent adhesion to carbon fiber and glass fiber, and the critical oxygen index is very high at 47 in the state of resin block, A fiber reinforced plastic having excellent strength and flame retardancy can be obtained.

  In addition, when polyether ether ketone (PEEK) fiber is used as the super engineering plastic fiber, a fiber reinforced plastic that is particularly excellent in chemical resistance and strength at high temperature can be obtained as compared with other super engineering plastics.

  The sheet for a fiber-reinforced plastic molded article useful as a stampable sheet of the present invention has a void in the sheet because a thermoplastic resin component called a super engineering plastic that forms a matrix by heat and pressure molding has a fiber form. Is present. Therefore, the resin is completely between the fibers as in the stampable sheet formed by the melting method (hot melt method), solvent method, dry powder coating method, powder suspension method, resin film impregnation method (film stacking method), etc. Unlike the stampable sheet embedded in the sheet, the sheet itself is flexible and draped before being heated and pressed, and the stampable sheet can be stored and transported in the form of winding, It is characterized by excellent handling properties, such as being able to be heat-pressed after being placed along.

  The fiber-reinforced plastic molded sheet of the present invention in which the resin that forms the matrix during heat-pressure molding is a super engineering plastic fiber is heat-pressure molded when processed into a fiber-reinforced plastic rather than a prepreg using a thermosetting resin. The original characteristics are that it takes a short time and is highly productive. In order to heat-press mold a sheet for fiber reinforced plastic molding as a stampable sheet in a short time, it is necessary that the super engineering plastic fiber used be melted quickly at a high temperature. The one where the fiber diameter of a fiber is thin is preferable. Since the number of contact points between fibers increases as the fiber diameter is thinner, the contact area between fibers increases, heat conduction becomes better, and the heat capacity of the fibers decreases, so the amount of heat required for melting is less Because it becomes. According to the study by the present inventors, the fiber diameter is preferably 30 μm or less, and more preferably 20 μm to 1 μm.

  Although the fiber length of super engineering plastic fiber is not specifically limited, Since it manufactures with a wet or dry type nonwoven fabric method, Preferably it is about 3 mm-30 mm. When longer than this, a fiber will not disperse | distribute uniformly but the uniformity of a sheet | seat and the uniformity of a mixing ratio with a reinforced fiber will fall. On the other hand, if the length is shorter than this, the strength of the web is lowered, and breakage or the like is likely to occur in the manufacturing process as a stampable sheet. The fiber diameter and fiber length may be single, or those having different fiber diameters and fiber lengths may be blended and used.

  In the sheet for a fiber-reinforced plastic molded article of the present invention, the nonwoven sheet containing super engineering plastic fibers can be a nonwoven sheet containing chopped strands of reinforcing fibers. Thus, when it is a non-woven sheet that also contains chopped strands of reinforcing fibers, it is desirable that the super engineering plastic fibers and the chopped strands of reinforcing fibers are uniformly mixed in the non-woven sheet. It is preferable that the fiber diameters of the matrix resin fibers are approximate. From this viewpoint, the fiber diameter of the super engineering plastic fiber is preferably 4 times or less, more preferably 3 times or less of the fiber diameter of the reinforcing fiber blended in the nonwoven fabric sheet, Most preferably, the fiber diameters of the reinforcing fibers are equal or substantially equal.

  The chopped strands of reinforcing fibers used for the nonwoven fabric sheet may be the same or different fibers as the reinforcing fibers forming the reinforcing fiber sheet to be bonded to the nonwoven fabric sheet.

  As the chopped strand of the reinforcing fiber used for the nonwoven fabric sheet, since the molding temperature at the time of heat-press molding the sheet for fiber reinforced plastic molding of the present invention as a stampable sheet is very high, 300 to 400 ° C, Inorganic fibers such as glass fibers and carbon fibers, or organic fibers having excellent heat resistance are used. When organic fiber is used as the reinforcing fiber used in the nonwoven fabric sheet, it is a resin fiber that does not have a softening point and has a thermal decomposition temperature of 400 ° C. or higher unlike para-aramid fiber and PBO fiber, or a thermoplastic that has a softening point. When it is a resin fiber, it needs to be a resin fiber whose softening temperature is higher than the molding temperature.

〔binder〕
In the present invention, as the binder used for the nonwoven fabric sheet, acrylic resins, styrene / acrylic resins, thermoplastic resins, urethane resins, PVA resins and the like generally used for nonwoven fabric production can be used.

  The binder component is particularly preferably a resin component that is compatible with the resin when the super engineering plastic fiber that becomes the matrix after the heat and pressure molding is melted by the heat and pressure molding. When such a resin component is used as a binder, after heat and pressure molding, there is no interface between the matrix resin and the binder resin, so that it becomes high strength and further, the glass of the matrix resin caused by the binder resin. It has the feature that there is little decrease in the transition temperature.

  For example, when PEI fibers are used as the thermoplastic resin that becomes the matrix after heat and pressure molding, it is preferable to use PET or modified PET that is a binder component compatible with the resin when melted by heat and pressure molding. When PET or modified PET is used as a binder, the shape is powder, fibrous, or ordinary PET placed on the core, and the periphery is covered with modified PET having a melting point lower than that of the core. A sheath-structured PET fiber or the like is preferably used. As the modified PET, copolymerized PET (CoPET) is preferable, and examples thereof include urethane-modified copolymerized PET. A modified PET as described in JP-B-1-30926 may be used. As a specific example of the modified PET, in particular, Melty 4000 (a fiber in which all fibers are copolymerized polyethylene terephthalate) manufactured by Unitika is preferably exemplified. As the core-sheath binder fiber, Melty 4080 manufactured by Unitika, N-720 manufactured by Kuraray, or the like can be suitably used.

From the viewpoint of reducing the strength of the process when used as a stampable sheet and the loss of surface fibers, the modified PET preferably has a melting point of 140 ° C. or lower, more preferably 120 ° C. or lower. .

  The binder content in the nonwoven fabric sheet is preferably 10% by mass or less, more preferably 7% by mass or less as the content in all stampable sheets (sheets for all fiber-reinforced plastic molded articles). 0.05 mass% or more. Such a binder component generally has a lower limit oxygen index than a flame retardant super engineering plastic fiber component having a limit oxygen index of 25 or more. The flame retardancy required when used as a sheet may be impaired. Even if the air permeability of the stampable sheet is 200 seconds or less, voids are formed in the fiber reinforced plastic formed by generating a large amount of gas by thermal decomposition at the heating and pressing temperature. May form, or the binder itself may discolor and remain, resulting in a fiber-reinforced plastic with poor appearance and strength.

  From the above viewpoint, the content of the binder component in the nonwoven fabric sheet is preferably 10% by mass or less, more preferably 7% by mass or less, in the fiber reinforced plastic molded sheet. However, if the amount of the binder component in the nonwoven fabric sheet is too small, the overall strength when used as a stampable sheet may be insufficient, which may cause tearing during operation, and may be used as a stampable sheet. When doing so, there may be inconveniences that the fibers on the surface of the nonwoven fabric sheet may fall off and splash in the processing process, so the content of the binder component in the nonwoven fabric sheet is during handling of the fiber reinforced plastic molded sheet In such a case, the above-described disadvantage is not caused.

  It is preferable that the binder component used by this invention is unevenly distributed in the surface layer part of a nonwoven fabric sheet. In this case, the inner layer can be in a state of relatively less binder. By arranging the nonwoven fabric sheet in which the binder component is unevenly distributed in the surface layer portion on both surfaces of the fiber reinforced plastic molded sheet, the surface fiber of the fiber reinforced plastic molded sheet can be obtained even with a small amount of binder. Dropping is suppressed and sufficient workability is obtained. By using the nonwoven fabric sheet in which the binder component is unevenly distributed in the surface layer portion, the binder content in the entire fiber-reinforced plastic molded sheet can be reduced to 1% by mass or less.

  As a method for making the binder relatively present in the surface layer of the nonwoven fabric sheet, after forming a web by the wet nonwoven fabric method or the dry nonwoven fabric method, a liquid material in which the binder component is dissolved in a solvent, or an emulsion of the binder component (emulsion) ) Is applied by dipping or spraying, and then dried by heating. According to this method, since the solvent inside the web moves to the surface layers on both sides and evaporates during heating and drying, the binder also concentrates relatively on the surface layer as the solvent moves. In this case, it is preferable that the solvent move more because the uneven distribution of the binder component becomes stronger. When such a method is adopted, the moisture in the web can be adjusted by adjusting the binder solution concentration of the aqueous binder solution or emulsion, the wet suction in the wet nonwoven fabric manufacturing process, and the moisture suction force by dry suction. .

  In order to make the binder component unevenly distributed, the moisture content in the web is preferably 50% or more. However, if there is more moisture, the drying load increases and the production cost increases. Is preferably adjusted.

  The degree of uneven distribution of the binder component can be grasped by dividing the nonwoven fabric sheet into approximately 3 to 5 portions in the thickness direction (Z-axis direction) and measuring the amount of each binder component. The degree of uneven distribution of the binder component is preferably such that the amount of the binder in the inner layer is 1/2 to 1/10 with respect to the surface layer when the binder component is roughly divided into three equal parts.

  If the above measures are not sufficient, as a method of reducing the amount of binder component added, the nonwoven sheet is wet-made, and the machine direction (MD direction) and the perpendicular direction (CD direction) of the machine are adjusted by adjusting the jet wire ratio. It is also preferable to increase the intensity ratio (hereinafter referred to as “strength aspect ratio”). In general, when the strength aspect ratio is increased, the fibers tend to line up in one direction, and the density of the nonwoven fabric tends to increase. As a result, the intersections between the fibers increase, so that a sufficient surface strength can be obtained even with a small amount of binder. Such an effect can be clearly obtained usually when the strength aspect ratio is 1.5 or more, more clearly is 3.0 or more, and more clearly is 5.0 or more.

  On the other hand, if the strength aspect ratio is too strong, the transverse strength becomes weak and the handling property is poor. Considering this point, the preferred strength aspect ratio is 15 or less, more preferably 10 or less.

[Bonding method]
As a method of laminating the reinforcing fiber sheet and the nonwoven fabric sheet, the reinforcing fiber sheet and the nonwoven fabric sheet are alternately overlapped, and pressure-bonded at a temperature and pressure at which the matrix resin fibers in the nonwoven fabric sheet are slightly melted by a heating and pressing roll or the like. However, it is not limited to this method.

  The order and number of layers when the nonwoven fabric sheet with the reinforcing fiber sheet is laminated to form a multilayer sheet are not particularly limited, but the nonwoven fabric is not present on both surface layers of the fiber reinforced plastic molded sheet. It is preferable to arrange a sheet. Although the reinforcing fiber sheet has no adhesive force between the fibers, the nonwoven fabric sheet exhibits adhesiveness to the reinforcing fiber sheet by partial melting of the super engineering plastic fiber under the heat treatment conditions at the time of bonding, so both the front and back sides of the reinforcing fiber sheet By disposing the non-woven fabric sheet, it is possible to form a sheet for a fiber-reinforced plastic molded article useful as a stampable sheet having good handling properties in which fiber fraying or the like does not occur on both surfaces.

  It is possible to superimpose a plurality of reinforcing fiber sheets and arrange the non-woven fabric sheet on the upper and lower surfaces, but the thinner the reinforcing fiber sheet layer is, the shorter the matrix resin can be placed in the reinforcing fiber sheet during heating and pressing. Since it can be melt-infiltrated, when a plurality of reinforcing fiber sheets are laminated, it is preferable to laminate them alternately with the nonwoven fabric sheet.

The number of laminated reinforcing fiber sheets and non-woven fabric sheets is not particularly limited, but if the number of laminated sheets is too large, the fiber reinforced plastic molded sheet becomes too thick and the handling property deteriorates. It is preferable to adjust the number of stacked sheets within a range not exceeding 2000 g / m ² .

  According to the above method, a sheet for a fiber reinforced plastic molded body that is particularly useful as a stampable sheet can be produced. These sheets are cut into a flat plate immediately after the production of the sheet for a fiber reinforced plastic molded body, and then pressed. It can use suitably for a process.

  On the other hand, after manufacturing a sheet for a fiber-reinforced plastic molded product, transporting it to another location, then cutting it to an appropriate size and performing the pressing process, it is more costly to transport the sheet by winding it In addition, it is preferable in terms of the degree of freedom of cut size.

  However, in the case of manufacturing winding, it is a normal method to wind the sheet while applying a predetermined tension so as not to cause winding deviation. In this case, the sheets are rubbed or rubbed in the winding process. Therefore, if the interlayer strength of the sheet is weak, delamination occurs, and handling properties after unwinding during use are extremely deteriorated.

  On the other hand, when a fiber reinforced plastic molded sheet is produced by the above-described method, the reinforcing fiber sheet and the matrix resin sheet are bonded by hot pressing. In order to obtain the adhesive strength, it is necessary to soften and melt a part of the matrix resin during the hot pressing to bond them.

  However, as described above, since it is important for the fiber-reinforced plastic molded sheet of the present invention to ensure air permeability, the matrix resin fibers are melted to such an extent that sufficient strength can be obtained even when wound. In some cases, part of the matrix resin fibers may be converted into a film, and the air permeability may be impaired.

  In addition, the fiber reinforced plastic molded sheet in which the matrix resin is melted and cooled to form a film has lost flexibility, and when wound, the sheet breaks near the core. Sometimes.

  Furthermore, such a sheet for fiber-reinforced plastic molded articles that has lost its flexibility has a problem in that the ability to follow a mold or the like is poor and deep drawing cannot be performed.

  In order to eliminate such problems, sufficient interlayer strength can be obtained by using a thermoplastic resin fiber having a melting point lower than that of the matrix resin fiber as a binder and further heating and pressing at a temperature lower than the melting point of the matrix resin fiber. In addition, flexibility and air permeability suitable for use as a stampable sheet can be ensured.

  The super engineering plastic fiber used in such a fiber reinforced plastic molded sheet is not particularly limited, and the thermoplastic resin binder used is not particularly limited as long as it has a melting point lower than that of the super engineering plastic fiber. When a polyetherimide fiber is selected as the engineering plastic fiber, a modified polyester resin is particularly preferable.

  This is because the polyester resin is compatible with the polyetherimide fiber at the time of heat-melting, so that the excellent points such as flame retardancy and low smoke generation of the polyetherimide resin are hardly lost even after cooling. Moreover, as a compounding quantity of a modified polyester resin, a preferable range is 2%-10% with respect to a nonwoven fabric. If the amount is too small, it is difficult to obtain an adhesive effect. If the amount is too large, the modified polyester resin itself melts to form a film and impairs air permeability.

  When polyetherimide fiber is used as a matrix resin and a modified polyester resin is used as a binder, the preferred heating / pressurizing temperature at the time of bonding is 130 ° C. to 180 ° C., and sufficient interlayer strength is obtained in this range, Also, the flexibility of the sheet is not impaired. In such a case, by making the sheet width of the matrix resin fiber sheet slightly wider than the sheet width of the reinforcing fiber cloth, the matrix resin fiber sheets are firmly bonded to each other, and fraying of the ends of the reinforcing fiber cloth is caused. Since it can suppress, it is preferable.

[Fiber-reinforced plastic molded sheet]
In the fiber-reinforced plastic molded sheet of the present invention, if the content of the reinforcing fiber component in the fiber-reinforced plastic molded sheet is too small, the reinforcing effect of the molded plastic body by the reinforcing fibers becomes insufficient. If it is too large, the matrix resin cannot cover the fibers and voids are generated, so that the reinforcing effect of the molded plastic body becomes insufficient. The ratio of the total reinforcing fibers and the super engineering plastic fibers in the fiber reinforced plastic molded sheet is preferably 5/95 to 70/30, more preferably 20/80 to 60/40, in volume ratio.

  The reinforcing fiber in the fiber-reinforced plastic molded sheet is a chopped strand of reinforcing fiber that may be contained in a nonwoven sheet containing a matrix resin component, and a reinforcing fiber sheet that is bonded to the nonwoven sheet. Means all the reinforcing fibers used.

  When the nonwoven fabric sheet in the fiber reinforced plastic molded sheet is composed only of super engineering plastic fibers and a binder, the strength of the fiber reinforced plastic body obtained by heating and pressing as a stampable sheet is reinforced fiber. The strength is particularly high with respect to the bending force in the direction of the reinforcing fibers in the sheet. However, the strength in the direction other than the direction of the reinforcing fiber is weaker than the strength in the direction of the reinforcing fiber.

  When it is necessary to adjust the direction of the strength of the fiber reinforced plastic body depending on the use of the fiber reinforced plastic body, the fiber other than the direction of the fiber of the reinforced fiber sheet can be obtained by including the reinforced fiber in the nonwoven fabric sheet. Strength in the direction can be improved.

  When blending reinforcing fibers also on the nonwoven fabric sheet side, as described above, since there is a preferable range in the ratio of all reinforcing fibers and super engineering plastic fibers in the sheet for fiber reinforced plastic molding, It may be necessary to reduce it relatively. The compounding amount of the reinforcing fiber component in the nonwoven fabric sheet forming the sheet for the fiber reinforced plastic molded body is such that the strength of the fiber direction of the reinforcing fiber sheet of the fiber reinforced plastic body becomes weaker as the amount of the reinforcing fiber in the nonwoven fabric sheet is increased. This can be adjusted as appropriate. Such adjustment may be performed in a range in which the mass ratio of the reinforced fiber in the reinforcing fiber sheet in the fiber reinforced plastic molded sheet and the chopped strand of the reinforcing fiber in the nonwoven fabric sheet is 95/5 to 20/80. However, it is preferably performed in the range of 90/10 to 40/60.

  In general, it is difficult to prepare a stampable sheet in which a large amount of reinforcing fibers are uniformly dispersed in a matrix resin having a high melt viscosity, and there is a limit to the mixing ratio of the matrix resin and the reinforcing fibers. In the case of the fiber-reinforced plastic molded sheet according to the present invention, there is an advantage that the ratio of the reinforcing fiber and the matrix resin fiber can be set relatively freely according to the required strength of the fiber-reinforced plastic.

  In addition, stampable sheets manufactured by the melting method (hot melt method), solvent method, dry powder coating method, powder suspension method, resin film impregnation method (film stacking method), etc. Voids are generated by the air present between the stampable sheet and the stampable sheet, or by the volatile gas generated from the stampable sheet, etc. To do. The sheet for fiber-reinforced plastic molded body of the present invention in which a nonwoven fabric sheet using super engineering plastic fibers as a matrix resin and a reinforced fiber sheet are laminated and integrated is that the matrix resin is fibrous and rich in air permeability, When used as a stampable sheet or air content between the press plate and the stampable sheet, because the reinforcing fiber sheet is reinforced in one direction or a woven fabric (cloth) of reinforcing fibers that is highly breathable. Further, the volatile gas component generated from the fiber reinforced plastic molded sheet is easily extracted from the sheet at the time of pressing, and voids and the like are not easily generated even in a short heating and pressurizing process.

  The fiber-reinforced plastic molded sheet of the present invention preferably has an air permeability of 200 seconds or less measured by a method based on the JAPAN TAPPI paper pulp test method. This numerical value indicates that the smaller the number, the easier air can pass through (the better the air permeability).

  In the case of the sheet for fiber-reinforced plastic molded body of the present invention, since it is a laminate in which a nonwoven fabric sheet and a reinforced fiber sheet are bonded, if it becomes bulky, for example, it takes too much transportation cost or heat in the heating and pressing step. There is a concern that problems such as inconvenience may occur when inserting into a press machine, etc., but such problems are caused by the heat generated when the nonwoven fabric sheet containing super engineering plastic fibers and the reinforcing fiber sheet are bonded together. This can be solved by increasing the density as appropriate according to the press or thermal calendar conditions. When such a treatment for increasing the density is performed, the air becomes somewhat difficult to pass through, so that the air permeability measured by the method based on the JAPAN TAPPI paper pulp test method is increased in the range in which the air permeability can be maintained at 200 seconds or less. It is preferable.

  In addition, the strength aspect ratio of the nonwoven fabric sheet affects the physical properties of the reinforced fiber plastic body because the nonwoven fabric sheet melts after heating and pressure molding and is integrated with the reinforcing fiber when the nonwoven fabric sheet does not contain the reinforcing fiber. There is almost no.

  When the non-woven sheet contains chopped strands of reinforcing fibers, if the strength aspect ratio becomes strong, the orientation of the reinforcing fibers also becomes strong in the MD direction. Therefore, the obtained fiber reinforced plastic body also has a high strength in the MD direction. The CD direction tends to be weak.

  Thus, the direction in which the strength of the reinforced fiber plastic is particularly excellent can be adjusted by the strength aspect ratio of the nonwoven fabric sheet by including the chopped strands of the reinforcing fibers in the nonwoven fabric sheet.

[Fiber reinforced plastic]
The sheet for a fiber-reinforced plastic molded body of the present invention may be a single sheet or laminated to a desired thickness and heat-press molded with a hot press, pre-heated with an infrared heater or the like, and heated with a mold. By processing using a general stampable sheet heating and pressure molding method such as pressure molding, a fiber reinforced plastic excellent in strength and flame retardancy can be obtained.

  When the non-woven sheet containing the super engineering plastic fiber used for the fiber-reinforced plastic molded sheet of the present invention is a non-woven sheet that also contains chopped strands of reinforcing fibers, the non-woven sheet is not bonded to the reinforcing fiber sheet. The sheet can be made into a fiber-reinforced plastic body even if it is heated and pressed only with a non-woven sheet. For example, a fiber reinforced plastic body is formed by heating and pressing a non-woven sheet containing chopped strands of highly heat-resistant organic fibers as reinforcing fibers, chopped strands of super engineering plastic fibers as matrix resin fiber components, and a binder. It is also a sheet that can be. The fiber reinforced plastic body formed from a nonwoven sheet made of organic fibers such as aramid fibers is excellent in abrasion resistance, and even if shavings are generated due to abrasion, the shavings of organic fibers are as small as inorganic fibers. Since it is not hard, it has the feature that the shavings hardly damage other things. Therefore, it is suitable as a member of a machine or the like that polishes an object to be polished that requires high-precision polishing in which minute scratches are also a problem. The property as a fiber reinforced plastic body formed only by such a nonwoven sheet is a fiber reinforced product obtained by heating and pressing the stampable sheet of the present invention formed by bonding the nonwoven sheet to the reinforcing fiber sheet. It also has a plastic body.

  Hereinafter, although this invention is demonstrated based on the manufacture example for confirming the effect of this invention, this invention is not limited by these. In each production example, “part” and “%” represent “part by mass” and “% by mass” unless otherwise specified.

Production Example 1
PPS fibers having a fiber diameter shown in Table 1 (manufactured by Fiber Innovation Technology, fiber length 13 mm, critical oxygen index 41) were put into water. The amount of water added was 200 times that of PPS fibers (fiber slurry concentration 0.5%).

  A fiber slurry in which “Emanon 3199” (Kao Corporation, trade name) as a dispersant is added to this slurry so as to be 1 part by mass with respect to 100 parts by mass of PPS fibers, and the fibers are uniformly dispersed in water. Was prepared.

  Granular polyvinyl alcohol (PVA) (Unitika Ltd., trade name “OV-N”) was added to water so as to have a concentration of 10%, and stirred to prepare a binder slurry.

The granular PVA slurry was put into the fiber slurry, a wet web was formed by wet papermaking, and heated and dried at 180 ° C. to prepare a nonwoven fabric having a basis weight of 120 g / m ² with the binder amount shown in Table 1. .

One sheet of this nonwoven fabric is placed on each of the top and bottom of a carbon fiber cloth having a basis weight of 200 g / m ² (a carbon fiber cloth manufactured by NEWS-COMPANY (without 3K plain weave coating)), and heat-treated with a heat press at 220 ° C. Thus, a stampable sheet having a basis weight of 440 g / m ^{2 having} the air permeability shown in Table 1 was obtained.

Production Example 2
One non-woven fabric having a basis weight of 120 g / m ² produced in the same manner as in Production Example 1 above and below a carbon fiber cloth having a basis weight of 200 g / m ² (carbon fiber cloth made by NEWS-COMPANY (without 3K plain weave coating)). A stampable sheet having a weight per unit area of 440 g / m ² is obtained by heat treatment at 220 ° C. in a heat press in a time shorter than the heat press time in Production Example 1 to achieve the air permeability shown in Table 1. Obtained.

Production Example 3
A binder slurry prepared using the same binder as in Production Example 1 is added to the PPS fiber slurry prepared in the same manner as in Production Example 1 to form a wet web by the wet papermaking method, and then heated and dried at 180 ° C. Thus, a nonwoven fabric having a basis weight of 123 g / m ² was produced.

One piece of this nonwoven fabric is placed above and below a carbon fiber cloth having a basis weight of 200 g / m ² (a carbon fiber cloth manufactured by NEWS-COMPANY (without 3K plain weave coating)), and heated with a 220 ° C. hot press. A stampable sheet with a basis weight of 446 g / m ^{2 having} an air permeability shown in Table 1 was obtained by pressure treatment.

Production Example 4
One non-woven fabric having a basis weight of 120 g / m ² produced in the same manner as in Production Example 1 above and below a carbon fiber cloth having a basis weight of 200 g / m ² (carbon fiber cloth made by NEWS-COMPANY (without 3K plain weave coating)). A stampable sheet with a weight per unit area of 440 g / m ² is manufactured by heat treatment at 220 ° C. for a longer time than the heat press time in Production Example 1 to achieve the air permeability shown in Table 1. did.

Production Example 5
Except for changing the PPS fiber to a PPS fiber having a fiber diameter shown in Table 1 (manufactured by KB Selen Co., Ltd., fiber length 13 mm, critical oxygen index 41), in the same manner as in Production Example 1, the basis weight is 440 g / m ² . A stampable sheet was prepared.

Production Example 6
The PPS fibers having the fiber diameters shown in Table 1 (manufactured by Fiber Innovation Technology, limiting oxygen index 41), and the polyetherimide (PEI) fibers having the fiber diameters shown in Table 2 (Fiber Innovation Technology, glass transition temperature 220 ° C.) A nonwoven fabric having a basis weight of 120 g / m ² was produced in the same manner as in Production Example 1 except that the fiber length was changed to 13 mm and the limiting oxygen index was changed to 47).

One piece of this nonwoven fabric is placed above and below a carbon fiber cloth having a basis weight of 200 g / m ² (carbon fiber cloth manufactured by NEWS-COMPANY (without 3K plain weave coating)), and heated and pressed with a 220 ° C. hot press. By processing, a stampable sheet with a basis weight of 440 g / m ^{2 having} the air permeability shown in Table 1 was produced.

Production Example 7
One non-woven fabric having a basis weight of 120 g / m ² produced in the same manner as in Production Example 6 is provided above and below a carbon fiber cloth having a basis weight of 200 g / m ² (carbon fiber cloth made by NEWS-COMPANY (without 3K plain weave coating)). A stampable with a basis weight of 440 g / m ^{2 that has} the air permeability shown in Table 2 by being heated and pressed in a heat press at 220 ° C. in a time shorter than the heat press time in Production Example 6 A sheet was obtained.

Production Example 8
In Production Example 6, granular PVA (Unitika Ltd., trade name “OV-N”) is changed to PET / coPET modified core-sheath binder fiber (Unitika Ltd., trade name “Melty 4080”) to form a nonwoven fabric. A stampable sheet of Production Example 8 was produced in the same manner as Production Example 6 except that it was used.

Production Example 9
Put a binder slurry prepared using the same binder as in Production Example 6 into a PET fiber slurry prepared in the same manner as in Production Example 6 to form a wet web by wet papermaking, and heat dry at 180 ° C. Thus, a nonwoven fabric having a basis weight of 123 g / m ² was produced with the binder addition amount shown in Table 2.

One piece of this nonwoven fabric is placed above and below a carbon fiber cloth having a basis weight of 200 g / m ² (a carbon fiber cloth manufactured by NEWS-COMPANY (without 3K plain weave coating)), and heated with a 220 ° C. hot press. By performing the pressure treatment, a stampable sheet having a basis weight of 446 g / m ^{2 having} an air permeability shown in Table 2 was obtained.

Production Examples 10-15
PPS fiber having a fiber diameter of 27 μm (manufactured by Fiber Innovation Technology, fiber length: 13 mm, critical oxygen index 41) and PPS fiber having a fiber diameter of 16 μm (manufactured by Fiber Innovation Technology, fiber length: 13 mm, critical oxygen index: 41) A wet web of PPS fibers was formed in the same manner as in Production Example 1 except that the binder-containing liquid of the type shown in Table 3 was added to one side of the wet web so that the total binder addition amount shown in Table 3 was obtained. A PPS fiber nonwoven fabric with a basis weight of 120 g / m ² formed by spraying and drying by heating is used as a nonwoven fabric, and the nonwoven fabric is a carbon fiber cloth with a basis weight of 200 g / m ² (carbon fiber cloth manufactured by NEWS-COMPANY) (3K plain weave without coating)) Below, the above-mentioned binder supply surface is arranged on the outside one by one and subjected to heat and pressure treatment with a hot press at 220 ° C., whereby the basis weight 440 g / weight described in Production Example 10 to Production Example 15 in Table 3 is obtained. An m ² stampable sheet was obtained.

Production Examples 16-21
The PPS fiber (manufactured by Fiber Innovation Technology, fiber length: 13 mm, critical oxygen index 41) having a fiber diameter of 27 μm in Production Example 1 was changed to a PEI fiber (Fiber Innovation Technology, fiber length: 13 mm, critical oxygen index 41) having a fiber diameter of 15 μm. A wet web of PEI fibers was formed in the same manner as in Production Example 1 except that the binder-containing liquid of the type shown in Table 4 was added to one side of the wet web so that the total binder addition amount shown in Table 4 was obtained. A PEI fiber nonwoven fabric having a basis weight of 120 g / m ² formed by spraying and heating and drying is used as a nonwoven fabric, and the nonwoven fabric is a carbon fiber cloth having a basis weight of 200 g / m ² (a carbon fiber cloth made by NEWS-COMPANY ( 3K plain weave without coating)) up and down In addition, by placing one piece each on the outer side of the binder supply surface and subjecting it to heat and pressure treatment with a hot press at 220 ° C., the basis weight described in Production Examples 16 to 21 in Table 1 is 440 g / m. ² stampable sheets were obtained.

  In the binder liquid, a PVA aqueous solution in which “PVA117” manufactured by Kuraray was dissolved in hot water was used as the PVA aqueous solution. The styrene acrylic emulsion used was “GM-1000” manufactured by DIC, and the urethane emulsion used was “AP-X101” manufactured by DIC.

Production Examples 22-25
A glass fiber having a fiber diameter of 9 μm and a fiber length of 18 mm, and a polyetherimide (PEI) fiber (Fiber Innovation Technology, glass transition temperature 220 ° C., fiber length 13 mm, critical oxygen index 47) shown in Table 5 The glass fiber 25 was weighed so as to be a polyetherimide (PEI) fiber 75 having a fiber diameter of 26 μm with respect to the glass fiber 25, and was put into water. The amount of water added was 200 times the total mass of glass fibers and PEI fibers (fiber slurry concentration 0.5%).

  To this slurry, “Emanon 3199” (Kao Corporation, trade name) as a dispersant is added and stirred so as to be 1 part by mass with respect to a total of 100 parts by mass of glass fiber and PEI fiber, and the fiber is uniformly dispersed in water. A dispersed fiber slurry was prepared.

Granular polyvinyl alcohol (PVA) (Unitika Ltd., trade name “OV-N”) was added to water so as to have a concentration of 10%, and stirred to prepare a binder slurry. The granular PVA slurry was added to the fiber slurry, a wet web was formed by wet papermaking, and the mixture was heated and dried at 180 ° C. to obtain a nonwoven fabric having a basis weight of 140 g / m ² .

One piece of this nonwoven fabric is placed above and below a carbon fiber cloth having a basis weight of 200 g / m ² (a carbon fiber cloth manufactured by NEWS-COMPANY (without 3K plain weave coating)), and heated with a 220 ° C. hot press. The stampable sheet of Production Example 22 having a basis weight of 480 g / m ² was obtained by the pressure treatment.

  By reducing the density of the stampable sheet by shortening the time of the heating and pressurizing treatment by hot pressing at 220 ° C. in Production Example 22 as compared with that in Production Example 22, the stampable sheet of Production Example 23 was reduced. Obtained.

  In addition, granular polyvinyl alcohol (PVA) (Unitika Ltd., trade name “OV-N”) used for the nonwoven fabric in Production Example 22 was changed to PET / coPET-modified core-sheath binder fiber (Unitika Ltd., trade name “Melty”). 4080 ") except that the stampable sheet of Production Example 24 was obtained in the same manner as in Production Example 22.

  Further, the glass fiber in Production Example 22 was changed to a glass fiber having a fiber diameter of 6 μm and a fiber length of 18 mm, and a stampable sheet of Production Example 25 was obtained in the same manner as in Production Example 22.

Production Example 26
Two windings of a 280 mm wide PEI fiber sheet of the same composition as used in Production Example 17 were prepared, and one winding of a 250 mm wide carbon fiber cloth was prepared. From the top, a PEI fiber sheet, carbon The fiber cloth and the PEI fiber sheet were stacked in this order and subjected to heat and pressure treatment with a 180 ° C. heat calendar, and the obtained stampable sheet was wound around a 3-inch paper tube.

Production Examples 27-32
In the stampable sheet of Production Example 26, the core-sheath binder fiber (Kuraray N-720) using modified PET (melting point: 110 ° C.) for the sheath and PET fiber for the core in the PEI fiber nonwoven fabric is shown in Table 6. The styrene / acrylic resin emulsion liquid was added to one side of the wet web by a spray method so as to have the addition amount shown in Table 6, and was heated and dried to have a basis weight of 120 g / m ² . A stampable sheet was produced in the same manner as in Production Example 26 except that a PEI fiber nonwoven fabric was used as the nonwoven fabric.

  Regarding the stampable sheets of Production Examples 1 to 32, the handling property during the heating and pressurizing operation was evaluated based on the following criteria by observing the occurrence state of surface fiber scattering / dropping and the occurrence state of delamination.

<Spattering / dropping of surface fibers>
A: No scattering or dropping of fibers B: No scattering of surface fibers but no dropping of surface fibers C: Partial dropping of surface fibers occurs, but there is no hindrance to use as a stampable sheet <interlayer Peeling>
A: Delamination does not occur B: Interlaminar strength is slightly weak but there is no delamination C: Delamination is observed in part, but there is no problem in handleability as a stampable sheet D: Delamination location Increased handling becomes worse, but can be used as a stampable seat

Six stampable sheets obtained by the methods of Production Examples 1 to 32 above were stacked, inserted into a hot press preheated to 310 ° C., heated and pressurized for 60 seconds, cooled to 230 ° C., and fiber A reinforced plastic body was obtained.

  About the obtained fiber reinforced plastic body, the bending strength measured in the direction which makes the fiber direction of a carbon fiber cloth and a 45 degree angle with the method based on JISK7074 was shown to Tables 1-6.

  Further, the appearance of the obtained fiber reinforced plastic body was visually observed and evaluated according to the following criteria.

<Appearance of laminate after heat and pressure molding>
◎: Good with no voids, etc. ○: Slightly voids can be confirmed △: Voids are generated but there is no practical problem ×: The appearance is clearly bad due to voids, and it cannot be used as a product

  As shown in Tables 1 to 6, the sheet for a fiber-reinforced plastic molded body of the present invention is good in both strength and appearance by generating no voids by being heat-press molded as a stampable sheet. It could be formed into a fiber reinforced plastic molding.

  In addition, although the sheet | seat of manufacture example 3 has much granular PVA as 12 mass% and a binder odor appeared strongly at the time of heat press molding, there is no influence on evaluation as a molded object. In Production Example 5, since the fiber diameter of the PPS resin fiber was as large as 35 μm, the PPS resin fiber partially remained and the resin plate became non-uniform.

  When the amount of the binder particles added is increased as in Production Examples 1 to 9 and Production Examples 22 to 25, the interlayer strength increases, but the odor at the time of heat and pressure molding tends to increase.

  When the binder particles are not added as in Production Examples 10 to 21, the interlayer strength becomes weak. Moreover, although it is necessary to add a liquid binder at the minimum by the spray method in order to prevent scattering of surface fibers, all of the evaluation results showed that it can be used as a stampable sheet.

  In addition, a fiber reinforced plastic molded article having excellent strength in the other direction as well as the direction of the reinforcing fiber was obtained.

  The sheet for a fiber-reinforced plastic molded body of the present invention is manufactured by laminating a non-woven sheet and a reinforcing fiber sheet using super engineering plastic fibers, which are fibers of a thermoplastic resin having high heat resistance and flame retardancy, as a matrix resin. Therefore, the productivity of the sheet for fiber reinforced plastic molding is high.

  In addition, since it is supple and draped, it is possible to store and transport the stampable sheet in the form of winding, or it can be heat-pressed after being placed along a curved mold. Thus, a fiber-reinforced plastic body having a high bending strength, tensile strength, and elastic modulus can be obtained.

  Furthermore, because the nonwoven fabric, which is a matrix resin sheet, has a lower melting point than the matrix resin and contains a binder that is compatible with the matrix resin in the heat-melted state, the interlayer strength is strong and the handling property is excellent, and the flexibility is high It is useful as a stampable sheet that can be easily wound and transported, and can easily follow a complicated mold.

  Further, in the case of a fiber reinforced plastic molded sheet using organic fibers with high heat resistance and high strength such as para-aramid fibers as reinforcing fibers, it is formed from a stampable sheet using inorganic fibers such as glass fibers as reinforcing fibers. It has better wear resistance than fiber reinforced plastic body, and even if part of the fiber reinforced plastic body is scraped off due to rubbing etc., there is a risk that the shavings are softer than inorganic fibers such as glass fiber and damage the object to be polished Therefore, it is useful as a member used in precision polishing equipment that requires high smoothness.

  All publications, patents and patent applications cited herein are incorporated herein by reference in their entirety.

Claims (19)

A fiber reinforced plastic molded sheet obtained by bonding a reinforcing fiber sheet and a nonwoven sheet containing a matrix resin component, which is a method of JAPAN TAPPI paper pulp test method No. The air permeability specified in 5-2 is 200 seconds or less,
The nonwoven fabric sheet contains a matrix resin component and a binder component made of chopped strands of a thermoplastic super engineering plastic fiber having a critical oxygen index of 25 or more and a fiber diameter of 30 μm or less, and the amount of the binder component is the total fiber reinforcement A fiber-reinforced plastic molded sheet, which is 10% by mass or less of the plastic molded sheet. Nonwoven sheet containing the matrix resin component, and further contain chopped strands of reinforcing fibers, the super fiber diameter of engineering plastic fibers is less than 4 times the fiber diameter of the reinforcing fibers, fiber reinforced plastic according to claim 1, wherein Sheet for molded body. The sheet | seat for fiber reinforced plastic moldings of Claim 1 or 2 with which the said binder component is unevenly distributed so that many parts may exist in the surface layer part of the said nonwoven fabric sheet. The super engineering plastic fiber when the binder component is compatible with the matrix resin component made of the super engineering plastic fiber and the sheet for fiber reinforced plastic molding is heated and pressed at a temperature of 300 ° C. to 400 ° C. The sheet for fiber-reinforced plastic molded articles according to any one of claims 1 to 3 , which is a resin component that is integrated without any interface therebetween. The fiber diameter of the said super engineering plastic fiber is 1-20 micrometers, The sheet | seat for fiber reinforced plastic moldings of any one of Claims 1-4 . The sheet for fiber-reinforced plastic molding according to any one of claims 1 to 5 , wherein the super engineering plastic fiber is a polyetherimide (PEI) fiber. The fiber-reinforced plastic molded sheet according to claim 6, wherein the binder component comprises polyethylene terephthalate (PET) or modified polyethylene terephthalate (PET). A part of the binder component is a fibrous thermoplastic resin having a melting point lower than a glass transition temperature of the super engineering plastic fiber, for a fiber reinforced plastic molded article according to any one of claims 1 to 7. Sheet. The fiber reinforced plastic molded article according to any one of claims 1 to 8, wherein the matrix resin component is a polyetherimide resin and the binder component contains at least a modified polyester resin having a melting point of 80 ° C to 130 ° C. Sheet. The fiber reinforced plastic molded article according to any one of claims 1 to 9 , wherein the binder component comprises an emulsion containing a copolymer containing at least one selected from methyl methacrylate and ethyl methacrylate as a monomer component. Sheet. The binder component includes a copolymer containing at least one selected from methyl methacrylate and ethyl methacrylate as a monomer component and a fibrous thermoplastic resin,
The content of the copolymer is 0.5% by mass to 3.0% by mass and the content of the fibrous thermoplastic resin is 1% by mass to 6% by mass with respect to the fiber reinforced plastic molded sheet. The sheet for fiber-reinforced plastic molded bodies according to any one of claims 1 to 10 . The fiber-reinforced plastic molding according to any one of claims 1 to 11 , wherein the ratio of all reinforcing fibers and super engineering plastic fibers in the sheet for fiber-reinforced plastic molding is 5/95 to 70/30 in volume ratio. Body sheet. On both surfaces of the reinforcing fiber sheet, a nonwoven sheet containing a matrix resin component is stuck, fiber-reinforced plastic molded body sheet according to any one of claims 1 to 12. A plurality of nonwoven fabric sheet containing a matrix resin component is stuck, fiber-reinforced plastic molded body sheet according to any one of claims 1 to 13. Laminating a reinforcing fiber sheet, a matrix resin component made of chopped strands of super engineering plastic fibers having a critical oxygen index of 25 or more and a fiber diameter of 30 μm or less, and a non-woven sheet containing a binder component, followed by heat treatment and bonding A method for producing a sheet for a fiber-reinforced plastic molded body comprising:
In the fiber-reinforced plastic molded sheet, the amount of the binder component is 10% by mass or less of the total fiber-reinforced plastic molded sheet, and the JAPAN TAPPI paper pulp test method No. The said method whose air permeability prescribed | regulated to 5-2 is 200 second or less. It said binder component, as a solution or emulsion containing the binder components, Ru granted to the nonwoven sheet by a coating method or impregnation method, a method according to claim 15. A reinforcing fiber sheet, laminated nonwoven sheet containing a matrix resin component is carried out by hot press method according to claim 15 or 16. Super engineering plastic fiber glass transition temperature is laminated by a thermoplastic resin fiber having a lower melting point than the method of claim 17. The method of claim 17 or 18 are laminated by a part of the super engineering-plastic fibers of the nonwoven fabric in the sheet melts.