CN110315660B

CN110315660B - Quasi-isotropic reinforcing sheet, FRP molded body, and method for producing FRP molded body

Info

Publication number: CN110315660B
Application number: CN201810264447.8A
Authority: CN
Inventors: 金森尚哲; 山﨑达也
Original assignee: Fukuvi Chemical Industry Co Ltd
Current assignee: Fukuvi Chemical Industry Co Ltd
Priority date: 2018-03-28
Filing date: 2018-03-28
Publication date: 2022-06-10
Anticipated expiration: 2038-03-28
Also published as: CN114770803A; CN110315660A

Abstract

The invention provides a quasi-isotropic reinforcing sheet which has excellent strength and excellent shaping property and can be molded into various shapes, an FRP molded body which takes the quasi-isotropic reinforcing sheet as a main material and has a protruding part which is difficult to break, and an efficient manufacturing method of the FRP molded body. In a quasi-isotropic reinforcing sheet S composed of a reinforcing fiber material F and a thermoplastic resin M, a plurality of UD sheet pieces (P) … formed by bonding and integrating continuous fibers in a state of being aligned in one direction are bonded in a state of being randomly oriented in the fiber direction of each sheet piece and in a state of being arranged in layers in a manner of being overlapped between the sheet pieces to form a sheet main body, and as the UD sheet piece P ■ P …, a sheet having a width of 2mm to 20mm, a length of 5mm to 70mm, and a ratio of width to length of 1: 1-1: 6 in the form of a square sheet.

Description

Quasi-isotropic reinforcing sheet, FRP molded body, and method for producing FRP molded body

Technical Field

The present invention relates to an improvement in prepreg sheets, and more particularly to a quasi-isotropic reinforcing sheet having excellent strength and formability, an FRP molded body having a slender protrusion part and made of the quasi-isotropic reinforcing sheet as a main material, and an efficient method for producing the FRP molded body.

Background

In recent years, Fiber Reinforced Plastics (FRP) composed of a matrix resin and a reinforcing fiber material such as carbon fibers or glass fibers have been used in various applications because of their excellent functionality. As FRPs, FRPs in which continuous fibers as reinforcing fiber materials are oriented in a longitudinal direction and FRPs in which a matrix resin is impregnated with a product obtained by flat weaving of continuous fibers are also known.

However, when the above conventional FRP using continuous fibers is formed into a desired shape by hot press working, the long continuous fibers extending over the entire sheet become a factor of hindering the following property to the press mold, and this causes a deterioration in the shaping property, resulting in a drawback that the shape to be formed is limited.

In addition, in the case of using the above-described conventional prepreg sheet, in order to form the elongated protrusion portion in a stripe shape (rib arch shape), it is necessary to thermally fuse or bond the protrusion piece and the main body portion which are separately molded, and if this method is adopted, the reinforcing fibers of the protrusion portion and the reinforcing fibers of the main body portion are cut at the base portion of the protrusion portion, and therefore, there is a problem that the base portion of the protrusion portion is easily broken.

On the other hand, there has been developed a prepreg sheet in which a UD sheet having continuous fibers aligned in one direction is finely cut, the resultant is aligned in a two-dimensional direction and integrated with a matrix resin (see patent document 1), and there is no mention in document 1 of a technique for producing an FRP molded body having elongated protrusions using such a prepreg sheet.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2016-27956

Disclosure of Invention

Problems to be solved by the invention

The present invention has been made in view of the above problems, and an object thereof is to provide a quasi-isotropic reinforcing sheet excellent not only in strength but also in formability into various shapes, an FRP molded body having a hardly breakable protrusion portion using the quasi-isotropic reinforcing sheet as a main material, and an efficient method for producing the FRP molded body.

Means for solving the problems

Means employed by the present inventors to solve the above problems will be described below with reference to the drawings.

That is, the present invention is characterized in that: in a quasi-isotropic reinforcing sheet S composed of a reinforcing fiber material F and a thermoplastic resin M, a plurality of UD sheet pieces P.P.. which are bonded and integrated with continuous fibers aligned in one direction are bonded in a state that the fiber directions of the sheet pieces are randomly oriented and in a state that the sheet pieces are overlapped to form a layer, thereby forming a sheet main body, and the UD sheet pieces P.P.. are used in a rectangular shape with a width of 2-20 mm, a length of 5-70 mm and a ratio of 1: 1-1: 6 of width to length.

In the present invention, a quasi-isotropic reinforcing sheet having excellent formability and ductility can be formed by using carbon fibers as the reinforcing fiber material F, using a polyamide resin, polypropylene, a fluororesin, or polyphenylene sulfide as the thermoplastic resin M, and by adjusting the fiber volume content of the sheet main body to 20% to 70% and the strain at break to 1.10 to 1.75% when a plurality of sheet main bodies are laminated and integrated to have a thickness of 2.0 mm.

On the other hand, in the present invention, in the FRP molded body mainly composed of the laminated body of the quasi-isotropic reinforcing sheet S, the strip-shaped protrusion 12 having a width of 0.5mm or more and a height of 5mm or more (preferably 20mm or more, and more preferably 50mm or more) is formed on the surface, and the main body 11 and the protrusion 12 are connected by the presence of the reinforcing fiber material F in the base portion B of the protrusion 12, whereby the protrusion having a small width and a large height can be formed so as to be hardly broken with respect to the main body.

Further, the portion 12a on the tip side and the portion 12b on the base side of the projection 12 are formed to have the same width, and the bending strength of the portion 12b on the base side is set to a value of-10% to + 30% with respect to the bending strength of the portion 12a on the tip side, whereby the projection 12 having a small strength difference depending on the portion can be formed.

In the present invention, when producing the FRP molded product, the following production method can be employed: the laminate of isotropic reinforcing sheets S is hot-press molded by a mold, and stripe-shaped protrusions 12 having a width of 0.5mm or more and a height of 5mm or more are formed on the surface of the body 11 of the molded body.

ADVANTAGEOUS EFFECTS OF INVENTION

In the present invention, a plurality of UD sheet pieces are bonded to each other in a state where the fiber directions of the sheet pieces are randomly oriented and in a state where the sheet pieces are arranged in layers so as to overlap each other, thereby forming a quasi-isotropic reinforcing sheet, and a rectangular sheet piece having a predetermined size is used as the UD sheet piece, whereby the shaping property of the prepreg sheet can be improved.

Further, if the quasi-isotropic reinforcing sheet is laminated and hot-press molded, the elongated stripe-shaped protrusion can be easily formed on the surface of the main body of the FRP molded body, and the reinforcing fiber material is disposed at the base of the formed protrusion so as to connect the main body and the protrusion, so that the elongated stripe-shaped protrusion can be formed at the base so as to be hardly broken.

Therefore, according to the present invention, it is possible to provide a quasi-isotropic reinforcing sheet which can be molded into various shapes by hot press molding, and an FRP molded body having a protrusion portion which is excellent in durability and which has the quasi-isotropic reinforcing sheet as a main material.

Drawings

Fig. 1 is an enlarged plan view showing a quasi-isotropic reinforcing sheet according to a first embodiment of the present invention.

Fig. 2 is a cross-sectional explanatory view showing a cross-sectional structure of a quasi-isotropic reinforcing sheet according to a first embodiment of the present invention.

Fig. 3 is an overall perspective view showing a UD sheet according to a first embodiment of the present invention.

Fig. 4 is an overall perspective view of an FPR molded body according to a second embodiment of the present invention.

Fig. 5 is an explanatory view of an X-X' cross section showing a cross-sectional structure of an FPR molded body according to a second embodiment of the present invention.

Fig. 6 is an explanatory view of a method of a verification test for the effect of the specification.

Description of reference numerals

1 FRP molded body

11 body part

12 projecting part

12a at the tip end side

12b bottom end side portion

S-quasi-isotropic reinforcing sheet

Pud sheet

F reinforced fiber material

M thermoplastic resin

B base

Detailed Description

First embodiment

A first embodiment of the present invention will be described with reference to fig. 1 to 3. In the figure, the quasi-isotropic reinforcing sheet is denoted by reference numeral S, and the UD sheet is denoted by reference numeral P. Further, a reinforcing fiber material is denoted by reference numeral F, and a thermoplastic resin is denoted by reference numeral M.

Construction of quasi-isotropic reinforcing sheets

[1] Basic constitution of quasi-isotropic reinforcing sheet

First, a basic structure of the quasi-isotropic reinforcing sheet S will be described. In the present embodiment, as shown in fig. 1, a plurality of UD sheet materials P · P.. are bonded in a layered (two-dimensional) state in which the fiber directions of the sheet materials are randomly oriented (arranged such that the fiber directions of the sheet materials are not aligned), and the sheet materials are overlapped with each other, thereby forming a quasi-isotropic reinforcing sheet material S.

The quasi-isotropic reinforcing sheet S is configured such that a reinforcing fiber material F is impregnated with a thermoplastic resin M as a matrix resin as shown in fig. 2, and each UD sheet P constituting the quasi-isotropic reinforcing sheet S is formed by bonding and integrating continuous fibers (carbon fibers in the present embodiment) in a state in which the continuous fibers are aligned in one direction as shown in fig. 3. This makes it possible to form a quasi-isotropic reinforcing sheet S having excellent strength and formability.

[2] Relating to reinforced fibre materials

Next, each constituent element of the quasi-isotropic reinforcing sheet S will be explained. First, although carbon fibers are used in the present embodiment as the reinforcing fiber material F, fibers other than carbon fibers, for example, inorganic fibers such as glass fibers, aramid fibers, ceramic fibers, and metal fibers, organic fibers such as polyarylate fibers and PBO fibers, and the like can be used as long as they are high-strength fiber materials.

[3] Concerning the fiber volume fraction (Vf)

In addition, regarding the fiber volume content (Vf) of the reinforcing fiber material in the quasi-isotropic reinforcing sheet S, if the content of the reinforcing fibers is too low, sufficient strength cannot be obtained, and if the content of the reinforcing fibers is too high, the proportion of the resin becomes small, and sufficient formability becomes difficult to obtain, so it is preferable to adjust the fiber volume content within a range of Vf 20% to 70%.

[4] About thermoplastic resin

In addition, although a polyamide resin (nylon resin) is used in the present embodiment as the thermoplastic resin M, any other thermoplastic resin (acrylic resin, PET, polyethylene, polystyrene, polycarbonate, ABS resin, polyetherimide, fluorine resin, polyphenylene sulfide, or the like) can be used as long as it has impregnability for the reinforcing fiber material, and among them, a polyamide resin, polypropylene, fluorine resin, or polyphenylene sulfide is preferably used.

[5] Impregnation method for thermoplastic resin

In the present embodiment, the thermoplastic resin M is impregnated into the reinforcing fiber material F by laminating the thermoplastic resin M in a film form on the UD sheet P · P.. that is arranged in a layer form, and hot-pressing the thermoplastic resin M and the UD sheet P · P.. that are arranged in a layer form. In addition, the impregnation rate of the thermoplastic resin M is not necessarily required to be completely impregnated into all the reinforcing fibers F of the UD sheet P, and may be only to such an extent that the UD sheet P · P.. is bonded.

[6] Impregnation of thermoplastic resin

In the case of using a method of laminating films on the UD sheet P · P. Although the impregnation property is inferior to that of the polyamide resin, polypropylene or ETFE (a copolymer of tetrafluoroethylene and ethylene) can be used. The test results of the impregnation property of the thermoplastic resin are shown in the following table 1 for reference.

[ TABLE 1 ]

Thermoplastic resin	Film thickness [ mu ] m]	UD sheet 4 degree [ mu ] m]	Melting Point [. degree.C. ]]	Processing temperature of [ deg.C]	Evaluation of impregnation Property
						PET	25	60	255	280	×
PEN	25	60	264	280	×
						ETFE	25	60	225	280	△
PEI	25	60	215	330	×
						PPS	25	60	278	300	△
PEEK	25	60	340	380	×
						PP	20	50	160	200	△
PA6	20	50	225	270	○

[7] Regarding the shape of the UD sheet

In the UD sheet P shown in fig. 3, a sheet having a width W5mm × length L20mm is used in the present embodiment, and a rectangular sheet having a width W2mm to 20mm (preferably 5mm to 10mm), a length L5mm to 70mm (preferably 10mm to 30mm), and a ratio of width W to length L of 1: 1 to 1: 6 can be used in consideration of strength and shape formability. In the present specification, a direction parallel to the longitudinal direction of the reinforcing fiber material is defined as the longitudinal direction of the UD sheet P, and a direction perpendicular thereto is defined as the width direction.

[8] Thickness of quasi-isotropic reinforcing sheet and UD sheet

The thickness of the quasi-isotropic reinforcing sheet S is preferably set to a range of 0.3mm to 1.0mm, and the thickness of the UD sheet P is preferably set to a range of 40 μm to 100 μm. The average number of UD sheet sheets P · P.. to be stacked on the quasi-isotropic reinforcing sheet S in the thickness direction is designed to be in the range of 5.0 to 8.0 sheets in the present embodiment, but is preferably designed to be in the range of 2.0 to 15.0 sheets in consideration of the strength and the impregnation property of the resin.

[9] Physical property values of quasi-isotropic reinforcing sheet

The quasi-isotropic reinforcing sheet S is preferably designed so that the strain at break when the thickness is 2.0mm is 1.10 to 1.75%. Further, as a result of performing a fracture strain test when a plurality of sheets are laminated and integrated to have a thickness of 2.0mm, the quasi-isotropic reinforcing sheet S of the present embodiment was 0.71% in a conventional sheet laminate in which plain-woven sheets of carbon fibers were laminated and impregnated with a resin, and 1.53% in the sheet laminate of the present embodiment. The comparison of other physical property values is shown in table 2 below. In the table, the numerical values of "strain at break", "tensile strength" and "tensile modulus" were calculated according to JIS K7164, the numerical values of "flexural breaking strength" and "flexural modulus" were calculated according to JIS K7074, and the numerical values of "compressive strength" were calculated according to JIS K7076. The number n of test pieces in each laminate was 6, and the values in the table were the average values thereof.

[ TABLE 2]

Second embodiment

Constitution of FPR molded body

[1] Basic constitution of FPR molded body

Next, a second embodiment of the present invention will be described with reference to fig. 4 to 5. In the present embodiment, as shown in fig. 4, an FRP molded body 1 having a laminate of quasi-isotropic reinforcing sheets S (other conditions are the same as those in the first embodiment) using Vf 54% of UD sheet pieces having a width W5mm × a length L20mm as a main material is configured to have stripe-shaped protrusions 12 on the surface of a main body portion 11.

The stripe-shaped protrusion 12 may be designed to have a width of 0.5mm or more and a height of 5mm or more (preferably 20mm or more, and more preferably 50mm or more). In addition, as shown in fig. 5, a bent reinforcing fiber material F is made to exist at the base B of the above-described protrusion portion 12 to connect the main body portion 11 with the protrusion portion 12. This makes it possible to form the elongated rib-like projecting portion 12 more resistant to breaking than in the conventional case.

[2] Regarding the shape of the protrusion

In addition, as for the above-described projecting portion 12, in the present embodiment, as shown in fig. 5, the portion 12a on the tip end side and the portion 12b on the base end side of the projecting portion 12 are formed with the same width and in such a manner that the fiber volume content (Vf) is not greatly different. As a result, the bending strength of the portion 12b on the base end side is set to a value of-10% to + 30% with respect to the bending strength of the portion 12a on the tip end side, and the protrusion 12 having a small strength difference depending on the portion is formed.

Method for producing FPR molded body

In addition, when the FRP molded body 1 of the present embodiment is manufactured, the strip-shaped protrusion 12 having a width of 1.0mm to 6.0mm and a height of 20mm or more can be easily formed on the surface of the body 11 of the molded body by hot press molding the laminate of the isotropic reinforcing sheet S with a mold. In addition, by adopting this manufacturing method, it becomes possible to make the reinforcing fiber material F connecting the main body portion 11 and the protrusion portion 12 exist at the base portion B of the protrusion portion 12.

[ examples ] A method for producing a compound

[ test (i) for verifying Effect ]

Next, a verification test (i) of the effect of the present invention will be described. First, in this test, the type of quasi-isotropic reinforcing sheet serving as the main material of the FRP molded body and the size of the linear protrusions formed in the FRP molded body were changed, hot press molding was performed, and the formability was evaluated from the molding results.

Example 1

The same quasi-isotropic reinforcing sheet (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, dimensions of the UD sheet: 5mm in width × 20mm in length, fiber content: Vf 54%) as that used for the FRP molded body of the second embodiment was used, and a laminate of the sheets was hot-press molded using a mold having a concave portion 0.5mm in width and 45mm in depth. As a result, an FRP molded body having a protrusion with a width of 0.5mm and a height of 45mm on the surface of the body can be molded.

Example 2

The same quasi-isotropic reinforcing sheet (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, dimensions of the UD sheet: 5mm in width × 20mm in length, fiber content: Vf 54%) as that used for the FRP molded body of the second embodiment was used, and a laminate of the sheets was hot-press molded using a mold having a concave portion 1.0mm in width and 45mm in depth. As a result, an FRP molded body having a protrusion with a width of 1.0mm and a height of 45mm on the surface of the body can be molded.

Example 3

The same quasi-isotropic reinforcing sheet (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, dimensions of the UD sheet: 5mm in width × 20mm in length, fiber content: Vf 54%) as that used for the FRP molded body of the second embodiment was used, and a laminate of the sheets was hot-press molded using a mold having a concave portion 2.0mm in width and 45mm in depth. As a result, an FRP molded body having a protrusion with a width of 2.0mm and a height of 45mm on the surface of the body can be molded.

Example 4

The same quasi-isotropic reinforcing sheet (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, dimensions of the UD sheet: 5mm in width × 20mm in length, fiber content: Vf 54%) as that used for the FRP molded body of the second embodiment was used, and a laminate of the sheets was hot-press molded using a mold having a concave portion 3.0mm in width and 45mm in depth. As a result, an FRP molded body having a protrusion with a width of 3.0mm and a height of 45mm on the surface of the body can be molded.

Example 5

The same quasi-isotropic reinforcing sheet (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, dimensions of the UD sheet: 5mm in width × 20mm in length, fiber content: Vf 54%) as that used for the FRP molded body of the second embodiment was used, and a laminate of the sheets was hot-press molded using a mold having a concave portion 5.0mm in width and 45mm in depth. As a result, an FRP molded body having a protrusion with a width of 5.0mm and a height of 45mm on the surface of the body can be molded.

Comparative example 1

A laminated body of reinforcing fiber material (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, fiber content: Vf 45%) obtained by laminating flat woven sheets and impregnating the sheets with a resin was hot-press molded using a mold having a concave portion with a width of 1.0mm and a depth of 45 mm. As a result, only the projections having a height of 3mm or less are formed on the surface of the body.

Comparative example 2

A laminated body of reinforcing fiber material (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, fiber content: Vf 45%) obtained by laminating flat woven sheets and impregnating the sheets with a resin was hot-press molded using a mold having a recessed portion 2.0mm wide and 45mm deep. As a result, only the projections having a height of 3mm or less are formed on the surface of the body.

Comparative example 3

A laminated body of reinforcing fiber material (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, fiber content: Vf 45%) obtained by laminating flat woven sheets and impregnating the sheets with a resin was hot-press molded using a mold having a recessed portion 3.0mm wide and 45mm deep. As a result, only the projections having a height of 3mm or less are formed on the surface of the body.

Comparative example 4

A laminated body of reinforcing fiber material (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, fiber content: Vf 45%) obtained by laminating flat woven sheets and impregnating the sheets with a resin was hot-press molded using a mold having a concave portion with a width of 5.0mm and a depth of 45 mm. As a result, only the projections having a height of 3mm or less are formed on the surface of the body.

Comparative example 5

The same quasi-isotropic reinforcing sheet (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, dimensions of the UD sheet: 5mm in width × 20mm in length, fiber content: Vf 54%) as that used for the FRP molded body of the second embodiment was used, and a laminate of the sheets was hot-press molded using a mold having a concave portion 0.1mm in width and 45mm in depth. As a result, the projections cannot be formed neatly on the surface of the body.

< summary of test results >

From the results of examples 1 to 5, it was confirmed that: by hot press molding using the quasi-isotropic reinforcing sheet of the present invention, it is possible to form a stripe-shaped protrusion having a width of 0.5mm to 5.0mm and a height of 45mm without any problem. From the results of comparative examples 1 to 4, it was confirmed that: it is difficult to form a strip-shaped protrusion having a width of 1.0mm to 5.0mm and a height of 45mm from a conventional quasi-isotropic reinforcing sheet. From the results of comparative example 5, it was confirmed that: even in the hot press molding using the quasi-isotropic reinforcing sheet of the present invention, it is difficult to form a projection having a width of 0.1mm or less.

[ test (ii) for verifying Effect ]

Next, the test (ii) for verifying the effect of the present invention will be described. In this test, a quasi-isotropic reinforcing sheet (reinforcing fiber material: carbon fiber, thermoplastic resin: polyamide resin, and UD sheet material: 5mm in width × 20mm in length, and Vf54 in fiber content) similar to that used for the FRP molded body of the second embodiment was used, and a laminate of the sheets was hot-press molded using a mold having a recessed portion 2.0mm in width and 60mm in depth, to prepare an FRP molded body having a protruding portion 2.0mm in width and 60mm in height on the surface of the main body portion as shown in FIG. 6.

Then, 3 test pieces (9 pieces in total, where n is 3) for each part having a length of 100mm were prepared by cutting out a sheet-like test piece (dimensions: width 15mm × length 120mm × thickness 2mm) from each part on the tip side, center part, and base end side of the protrusion of the FRP molded body and trimming the test pieces, and a 4-point bending test was performed according to JIS K7074 to calculate an average value. As shown in fig. 6, the test pieces on the top end side and the bottom end side were cut out with a gap of 5.5mm from the edge portions of the top end and the bottom end of the protrusion, and the test pieces on each part were cut out with a gap of 2.0mm between the test pieces.

< test results >

As a result of performing a 4-point bending test on each of the test pieces on the top end side, the center portion, and the bottom end side, it was confirmed that the numerical value of the bending failure strength of each portion varied within ± 10%, no large difference was observed between the test pieces, and the UD sheet pieces were uniformly dispersed in the protrusions without being biased. From this, it is understood that the molding method of the present invention is effective not only for molding a flat plate shape but also for molding a three-dimensional shape. Table 3, which summarizes the data of this test, is shown below.

TABLE 3

Claims

An FPR molded body which is an FRP molded body comprising a laminate of quasi-isotropic reinforcing sheets (S) as a main material, characterized in that strip-shaped protrusions (12) having a width of 0.5mm or more and a height of 5mm or more are formed on the surface of a main body (11), and a reinforcing fiber material (F) is present at the base (B) of the protrusions (12) to connect the main body (11) and the protrusions (12),

In the laminated body of the quasi-isotropic reinforcing sheet (S), the quasi-isotropic reinforcing sheet is composed of a reinforcing fiber material (F) and a thermoplastic resin (M), wherein, a sheet main body is formed by bonding a plurality of UD sheet pieces (P) (P) … in a state of randomly orienting the fiber direction of each sheet piece and in a state of being overlapped and arranged in layers among the sheet pieces, the UD sheet pieces (P) (P) … are formed by bonding and integrating continuous fibers in a state of being arranged in one direction, and furthermore, as the UD sheet pieces (P), a reinforcing fiber material (F) with a thickness of 40-60 [ mu ] M, a width of 2-20 mm, a length of 5-70 mm and a ratio of 1: 1-1: 6, wherein the average number of UD sheet pieces (P) (P) … stacked in the quasi-isotropic reinforcing sheet in the thickness direction is 2.0 to 15.0 sheets.
2. The FPR molded body according to claim 1, wherein the reinforcing fiber material (F) is carbon fiber, the thermoplastic resin (M) is polyamide resin, polypropylene, fluorine resin or polyphenylene sulfide, the fiber volume content of the sheet main body is 20% to 70%, and the breaking strain when the sheet main body is formed by laminating and integrating a plurality of the sheet main bodies to have a thickness of 2.0mm is 1.10 to 1.75%.
3. The FRP formed body as claimed in claim 1 or 2, wherein the tip end side portion (12a) and the base end side portion (12b) of the protrusion (12) are formed to have the same width, and the bending strength of the base end side portion (12b) is set to a magnitude of-10% to + 30% with respect to the bending strength of the tip end side portion (12 a).
4. A method for producing an FRP molded body according to any one of claims 1 to 3, characterized in that the laminate of quasi-isotropic reinforcing sheets (S) is hot-press molded using a mold, and stripe-shaped protrusions (12) having a width of 0.5mm or more and a height of 5mm or more are formed on the surface of the body part (11) of the molded body.