JP4382869B2 - Molding method of hollow fiber reinforced plastic parts with flange - Google Patents

Description

  The present invention relates to a method for molding a fiber-reinforced resin hollow part integrally having a flange portion at the tip.

  As one of automobile parts, a hollow part having a flange at one end is often used. The flange portion is used as a coupling substrate for coupling with other members, and the body portion is made hollow so as to reduce the weight as a component. Conventionally, this type of hollow part has been mainly made of a metal material. However, attempts have been made to form a hollow part having a lighter weight by using a fiber reinforced resin.

  The fiber reinforced resin (FRP) is a combination of a thermosetting resin or a matrix resin of thermoplastic resin and a reinforced fiber, and is lightweight and excellent in strength characteristics. Examples of the thermosetting resin used include unsaturated polyester resins, epoxy resins, and polyimide resins. Examples of thermoplastic resins include polyethylene, polypropylene, and polyamide. Examples of the reinforcing fiber include carbon fiber, glass fiber, and aramid fiber.

  Several methods for making hollow parts using fiber reinforced resin have been proposed, and one of them is an internal pressure molding method. The internal pressure molding method is a method in which a hollow molding material is arranged in a cavity of a molding die, internal pressure is applied from the inside of the hollow material to bring the hollow material into close contact with the molding die, and heat molding is performed in that state. . When molding a fiber reinforced resin hollow part using the internal pressure molding method, it is difficult to integrally form the flange part during molding, and even if the conventional fiber reinforced resin hollow part does not have or has a flange part, it is molded In general, an appropriate flange portion is added to a subsequent fiber-reinforced resin hollow part in a subsequent process.

  An example of molding a fiber reinforced resin hollow part having an irregular cross section using the internal pressure molding method described above is described in Patent Document 1. There, a prepreg is wound around a mandrel having a circular cross section, and then the mandrel is pulled out to create a hollow part of the prepreg, a pressure bag is inserted into the hollow part of the hollow part of the prepreg, and the hollow into which the pressure bag is inserted The part is placed in a mold having a shape corresponding to the irregular shape of the hollow part and the prepreg for replenishment is arranged in the irregular shape part, and then molded by the internal pressure molding method, thereby forming a uniform cross section. An unusually shaped FRP hollow part is obtained.

  Patent Document 2 describes a structural member used in a building structure and a manufacturing method thereof, in which a hollow cylindrical liner (mold material) made of a stretchable material such as a thermoplastic resin is provided, An assembly in which reinforcing fibers are wound by a braiding method is prepared, and the assembly is placed in a mold, and then the reinforcing fibers are impregnated with a resin and cured. When the resin is impregnated, pressurized air is supplied into the liner (mold material) to prevent the liner from being deformed.

JP 2006-123475 A JP 2003-328498 A

  In the method described in Patent Document 1, a prepreg is wound around a mandrel (hollow core) having a circular cross section, and then the mandrel is pulled out to create a hollow part made of the prepreg. It takes a lot of time to wrap around a mandrel. In addition, hollow parts made of prepregs from which mandrels have been pulled out are weak in strength, and may cause local deformation, differences in wall thickness, and wrinkles when molding while pressing through a pressure bag. There is. In addition, since a mandrel having a circular cross section is used, the hollow part made of a prepreg is also substantially cylindrical, and in order to obtain a molded product having a deformed portion, it is separately provided in the mold corresponding to the deformed portion. It is necessary to place a prepreg. Therefore, in this internal pressure molding method, it is not possible to mold a molded product having a deformed cross section and having substantially the same thickness. Furthermore, since it is assumed that the mandrel is pulled out, it is difficult to form a flanged fiber-reinforced resin hollow part having a bent portion by this method. In order to obtain a molded product having a flange portion at the tip, an operation of assembling a prepreg in accordance with the shape of the flange portion at the tip of the main body is necessary, which increases the amount of work.

  In the method described in Patent Document 2, a reinforcing fiber is wound around a hollow cylindrical liner (mold material) by a braiding method to form an assembly which is a hollow part. By using this method, a hollow assembly having a non-circular cross section or a bent portion can be relatively easily made. However, Patent Document 2 has no description regarding molding of a fiber-reinforced resin hollow part having a flange at the tip.

  Therefore, an object of the present invention is to obtain a molding method capable of easily molding a fiber-reinforced resin hollow part in which a flange portion is integrally molded during molding while using an internal pressure molding method.

  The method for manufacturing a flanged fiber reinforced resin hollow part according to the present invention is a method of molding a fiber reinforced resin hollow part integrally having a flange part at the tip by an internal pressure molding method, and is formed at the tip of a preformed hollow resin core. A step of connecting two cores, a step of forming a hollow laminated body by laminating at least reinforcing fibers on the outer periphery of the hollow resin core and the second core, and the second core being drawn out from the hollow laminated body Thereafter, a step of pressing the region from which the second core has been pulled out to form a hollow laminate having a flange at the tip, a step of arranging the hollow laminate in a molding die, and a placement in the molding die And a step of forming a hollow laminated body having a flange part into a flanged fiber-reinforced resin hollow part by an internal pressure molding method.

  In addition, the flanged fiber reinforced resin hollow part manufacturing method according to the present invention is a method of forming a fiber reinforced resin hollow part integrally having a flange portion at the tip by an internal pressure molding method, and the tip of a preformed hollow resin core Connecting a second core to the hollow resin core, laminating reinforcing fibers and a matrix resin on the outer periphery of the hollow resin core and the second core to form a hollow laminate, and from the hollow laminate to the first A step of pulling out the core of No. 2, a step of pressing the region where the second core of the hollow laminate is pulled out and forming it into a flange shape, a step of arranging the hollow laminate in a mold, and a molding And heating the hollow laminate disposed in the mold while applying an internal pressure to integrate the resin and the reinforcing fiber.

Further, the manufacturing method of the flanged fiber reinforced resin hollow part according to the present invention is a method of forming a fiber reinforced resin hollow part integrally having a flange portion at the tip by an internal pressure molding method, and the tip of the preformed hollow resin core A step of connecting the second core to the substrate, a step of laminating reinforcing fibers on the outer periphery of the hollow resin core and the second core to form a hollow laminate, and pulling out the second core from the hollow laminate A step, a step of pressing the region where the second core in the hollow laminate is pulled out, and forming the flange in a flange shape, and a step of arranging the hollow laminate in a mold,
A step of injecting a matrix resin into the mold, and a step of heating the hollow laminate disposed in the mold while applying an internal pressure to integrate the resin and the reinforcing fiber. .

  In the method for molding a flanged fiber-reinforced resin hollow part according to the present invention, a hollow laminate is obtained by laminating reinforcing fibers on a continuous body of a hollow resin core and a second core connected to the tip of the hollow resin core, Lamination of reinforcing fibers is easy. The second core is pulled out from the hollow laminate thus formed, and the reinforcing fiber in the pulled-out region is pressed to form, for example, a flat flange. Therefore, the flange portion is continuous with the main body portion which is a hollow portion. Thus, the strength is stable. Also, it is arranged in a mold, and heated while applying an internal pressure to the arranged hollow laminate, so that the resin and the reinforcing fiber are integrated. A lightweight and high-strength fiber-reinforced resin hollow part with a flange, which is integrally formed of continuous fiber-reinforced resin, is obtained.

  In the method for molding a flanged fiber reinforced resin hollow part according to the present invention, preferably, as a step before the step of disposing the hollow laminate in a mold, a pressurizing bag is provided in the hollow resin core of the hollow laminate. Including the step of inserting and arranging, the application of internal pressure to the hollow laminated body arranged in the mold is performed by applying pressure to the pressurizing bag.

  In this aspect, the member for winding the reinforcing fiber and the member to which the internal pressure applied at the time of the internal pressure molding acts directly are separated as a hollow resin core and a pressurizing bag, so that the hollow resin core functions only as a mandrel. It can be achieved, and for this reason, it is possible to reduce the thickness and weight. And since the bag for pressurization used at the time of internal pressure addition is removed from the hollow part after shaping | molding, the fiber-reinforced resin hollow part with a flange reduced sufficiently can be obtained.

  Also, the hollow resin core is pre-molded according to the shape of the fiber reinforced resin hollow part to be obtained, and the hollow resin core is left as it is in the hollow laminate, so that it has a three-dimensional variant with substantially the same thickness. A fiber-reinforced resin hollow part with a flange having a cross-section can be molded easily and at low cost.

  In the method for forming a flanged fiber reinforced resin hollow part according to the present invention, there is no particular limitation on the method for laminating the reinforcing fibers on the outer periphery of the hollow resin core and the second core, but it is easy to obtain a hollow part of any shape. The lamination is preferably performed by braiding braided yarns by a braiding method. Furthermore, for the reason that a greater strength against bending can be obtained with a thinner wall thickness, braiding of braided yarn by the braiding method is performed with a braided layer having an angle of 0 ° to the axis and an angle of θ to the axis. It is a more preferable aspect to laminate a certain braided layer alternately.

  In the present invention, the lamination of the reinforcing fiber and the matrix resin in the step of forming the hollow laminate by laminating the reinforcing fiber and the matrix resin on the outer periphery of the preformed hollow resin core and the second core, In addition to sequentially laminating the reinforcing fiber layer and the matrix resin layer, it also includes laminating the reinforcing fiber and the fibrous matrix resin in the form of a thread on the outer periphery of the hollow resin core. .

  In the method for molding a flanged fiber reinforced resin hollow part according to the present invention, preferably, as a step before the step of disposing the hollow laminate in a mold, the hollow portion of the hollow laminate and a flanged portion The method further includes a step of sewing in the boundary area between the two. In this aspect, it is possible to reliably prevent the portion pressed in the flange shape from being unnecessarily opened by the applied internal pressure during the internal pressure molding.

  According to the molding method of the present invention, it is possible to obtain a flanged fiber-reinforced resin hollow part that is lightweight and extremely stable in strength. In addition, a flanged fiber reinforced resin hollow part having an irregular cross section or a bent portion can be easily and inexpensively molded in a sufficiently lightweight state and in a state where the wall thickness is substantially equal.

It is a figure which shows the preformed hollow resin core and 2nd core example which are used with the method of this invention, FIG.1 (a) shows the state which decomposed | disassembled and FIG.1 (b) shows the state connected integrally. The figure explaining an example of a hollow laminated body. The figure which shows the state which pulls out the 2nd core from the hollow laminated body shown in FIG. The figure which shows the hollow laminated body of the state which pressed the area | region where the 2nd core was pulled out, and was shape | molded in the flange shape. The figure which shows the other form of the hollow laminated body shown in FIG. The figure explaining an example which arrange | positions a hollow laminated body in a shaping | molding die, and shape | molds as a fiber reinforced resin hollow part with a flange. The figure explaining the other example of a hollow laminated body. The figure explaining the other example which arrange | positions the hollow laminated body shown in FIG. 7 in a shaping | molding die, and shape | molds as a fiber reinforced resin hollow part with a flange. The figure which shows the further another example which shape | molds a hollow laminated body as a fiber reinforced resin hollow part with a flange.

Hereinafter, the present invention will be described in more detail based on the description of embodiments with reference to the drawings.
The hollow resin core 10 shown in FIG. 1 is open at one end 11 side, closed at the other end 12 side, and has a bent portion 13 in the middle, and has a space 14 inside. The hollow resin core 10 is made of a thermoplastic resin such as an ABS resin, a PS resin, or a PC resin, and is preferably a resin that softens but does not melt at the temperature when a hollow fiber-reinforced resin component described later is molded. Material is used. The wall thickness may be about 1 mm. A two-part product may be formed by vacuum forming or the like and bonded to form a shape as illustrated, or may be integrally formed by blow molding or the like. The dimensions of the hollow resin core 10 are desirably offset from the outer shape of the flanged fiber-reinforced resin hollow part 50 to be molded to the inside by the thickness. Here, the thickness refers to the thickness of the fiber reinforced resin in the hollow portion of the flanged fiber reinforced resin hollow part 50.

  Reference numeral 15 denotes a second core, which is a hollow cylinder made of an aluminum material in this example. The second core 15 has such a shape that one end can be attached to the closed end 12 side of the hollow resin core 10 by an appropriate means. The length is set according to the length of the flange portion to be molded. The second core 15 is not limited to an aluminum material and can be made of any material such as a resin material as long as it can withstand the pressure of the reinforcing fiber laminated thereon.

  As shown in FIG. 1B, the second core 15 is temporarily joined to the closed end 12 side of the hollow resin core 10. A reinforcing fiber layer 21 is formed by laminating reinforcing fibers on the outer periphery, and a hollow laminated body 20 having a shape approximate to the shape of the fiber reinforced resin hollow part to be obtained is obtained. Here, the reinforced fiber may be a reinforced fiber used in a conventionally known fiber reinforced resin. For example, carbon fiber is preferably used. The hollow resin core 10 and the second core 15 are laminated while maintaining sufficient rigidity as a core (mandrel) and controlling the thickness of the reinforcing fiber layer when the reinforcing fibers are laminated at room temperature or below. Is easy. The method of laminating the reinforcing fibers on the outer periphery of the hollow resin core 10 and the second core 15 is also arbitrary, but preferably, the laminating is performed while adjusting the weave angle using a conventionally known braiding method (cylindrical weaving). To do. At this time, the braided layer without gaps is formed by weaving while controlling the clogging state of the weave by controlling the clogged state of the hollow resin core 10 by reducing the set angle θ and increasing the set angle θ of the large diameter portion. (Reinforcing fiber layer) 21 can be formed.

  More preferably, when the reinforcing fibers are laminated on the outer circumferences of the hollow resin core 10 and the second core 15 as shown in FIG. 2, the set angle with respect to the axis is 0 as shown in the AA cross section of FIG. The braid layers 22 having a degree and the braid layers 23 having a braid angle with respect to the axis of θ degrees are alternately laminated. In the figure, four reinforcing fiber layers 21 are shown, but the number of layers is arbitrary, and an appropriate number of layers is set in consideration of the required strength. By using the reinforcing fiber layer 21 in this form, the tensile strength in the longitudinal direction can be improved and controlled. Thereby, the hollow laminated body 20 of the same strength can be formed with the thinner reinforcing fiber layer 21, which can contribute to weight reduction. The time required for the work can be shortened, and when the prepreg is laminated by hand, the process that takes 4 to 5 hours can be suppressed to 30 minutes or less.

  In the example shown in FIG. 2, a matrix resin film 24 is further laminated between the braid layer 22 and the braid layer 23. The matrix resin may be a thermosetting resin such as an unsaturated polyester resin, an epoxy resin, or a polyimide resin, or may be a thermoplastic resin such as polyethylene, polypropylene, or polyamide. The flanged fiber-reinforced resin hollow part 50 to be obtained is selected as appropriate in consideration of the intended use and the required physical property values. For example, when a pillar for an automobile is manufactured with the flanged fiber reinforced resin hollow part 50, it is desirable to use a thermosetting resin.

  As shown in FIG. 3, the temporarily bonded second core 15 is pulled out from the formed hollow laminate 20. After pulling out, the region where the second core 15 is present in the hollow laminate 20 is pressed from above and below by appropriate means to form the flange-shaped portion 26 as shown in FIG. The flange-shaped portion 26 is generally formed in a flat plate shape, but may be pressed into a shape having a curvature, a shape having a bent portion, or the like according to the usage mode of the flanged fiber-reinforced resin hollow part 50.

  Preferably, as shown in FIG. 5, at least a boundary region between the flange-shaped portion 26 and the hollow portion is sewn with a sewing machine 27 or the like. This stitching may be performed over the entire flange-shaped portion 26 as shown in the figure. The thread used for sewing is preferably made of the same material as the thread forming the reinforcing fiber layer 21 (for example, carbon fiber), but a general thread such as a thermoplastic resin can also be used.

  Next, the pressurizing bag 30 is inserted and disposed in the internal space 14 of the hollow resin core 10 of the formed hollow laminate 20. The pressurizing bag 30 serves to transmit the pressure applied in the pressurizing bag 30 during molding to the reinforcing fiber layer 21 through the hollow resin core 10 and is elastic and easily deformed. For example, it is made of a material such as a synthetic rubber, a nylon sheet, a resin sheet such as a urethane sheet. The shape of the pressurizing bag 30 is preferably the same as the shape on the inner surface side of the hollow resin core 10. However, as long as the shape can be deformed by applying internal pressure and can be in close contact with the inner surface of the hollow resin core 10, the hollow resin The shape may be similar to the shape on the inner surface side of the core 10.

  And as shown in FIG. 6, the hollow laminated body 20 which inserted the bag 30 for pressurization into the internal space 14 of the hollow resin core 10 is arrange | positioned in the cavity of the shaping | molding die 40 provided with the heater (not shown). The molding die 40 includes a pressurized air supply valve 41 and an exhaust port 42 that connects the cavity space to the vacuum pump P at a position where the open end 11 of the hollow resin core 10 is located. Moreover, the cavity area | region corresponding to the flange-shaped part 26 formed in the above-mentioned hollow laminated body 20 is also provided.

  After closing the mold 40, the vacuum pump P is operated to evacuate the cavity. Thereby, the inside of the reinforcing fiber layer 21 of the hollow laminate 20 is deaerated. In this state, the heater is operated to raise the temperature to the melting temperature of the matrix resin film 24 disposed between the reinforcing fiber layers. Thereby, the molten resin is impregnated between the fibers. Before and after the resin is melted and impregnation is started, the pressurized air supply valve 41 is opened to supply pressurized air to the pressurizing bag 30. The pressure may be about 0.1 MPa to 1 MPa, or a higher pressure. By supplying pressurized air, an internal pressure is applied to the pressurizing bag 30, and the pressure causes the reinforcing fiber layer 21 to bulge outward through the softened hollow resin core 10. As a result, the reinforcing fiber layer 21 is pressed against the inner surface of the cavity and shaped. Since this shaping is performed at a pressure acting from the pressurizing bag 30 made of an elastic and easily deformable material as described above, the pressure is almost equal to the entire area corresponding to the hollow portion of the reinforcing fiber layer 21. Even in a region having an irregular cross section, the thickness does not become uneven.

  The pressure from the pressurizing bag 30 does not act on the flange-shaped portion 26 in the cavity, and is shaped only by clamping. However, the internal pressure acts on the boundary region between the rough portion 26 and the hollow portion, and tries to deform the flange portion 26 in the opening direction. The above-described stitching 27 is provided to prevent this deformation.

  When the matrix resin is a thermosetting resin, the temperature is further raised to the curing temperature and the temperature is maintained. Thereby, the resin is cured by forming a matrix with the reinforcing fibers, and becomes a fiber-reinforced resin. After the resin is cured, the internal pressure of the pressurizing bag 30 is released, cooled, and the mold is opened. By removing the flanged fiber reinforced resin hollow part with the cured resin from the mold and removing the pressurizing bag 30, the sufficiently lightened flanged fiber reinforced resin hollow part 50 according to the present invention can be obtained.

  FIG. 7 shows a hollow laminate 20A used in another form of the method for forming the flanged fiber-reinforced resin hollow part 50 according to the present invention. This hollow laminated body 20A is different from the hollow laminated body 20 shown in FIG. 2 only in that the matrix resin film 24 is not interposed between the fiber layers 22 and 23. Other configurations may be the same, and the same members are denoted by the same reference numerals and description thereof is omitted.

  FIG. 8 illustrates a case where the hollow laminated body 20A is disposed in the molding die 40A to mold the flanged fiber-reinforced resin hollow part 50. Here, the mold 40 </ b> A includes a resin injection port 43 so that the matrix resin 45 can be supplied from the resin tank 44 into the cavity via the port 43. Other configurations are the same as those of the mold 40 shown in FIG. 6, and the same members are denoted by the same reference numerals and description thereof is omitted.

  In molding, the hollow laminate 20A in which the pressurizing bag 30 is inserted into the internal space 14 of the hollow resin core 10 is disposed in the cavity of the molding die 40A. After closing the mold 40, the vacuum pump P is operated to evacuate the cavity. In this state, the heater is operated to raise the temperature to the melting temperature of the matrix resin 45, and the matrix resin 45 is supplied from the resin injection port 43 into the cavity. The supplied matrix resin 45 is impregnated between the fibers. When a sufficient amount of resin is supplied, the resin injection port 43 is closed.

  Before and after the resin supply is started, the subsequent procedure such as opening the pressurized air supply valve 41 and supplying pressurized air to the pressurizing bag 30 is the same as the molding procedure described with reference to FIG. Is omitted. Also by this molding method, it is possible to obtain a flanged fiber reinforced resin hollow part 50 having a substantially equal wall thickness and a sufficiently light weight.

  FIG. 9 shows still another example in which the hollow laminated body 20 is molded as a flanged fiber-reinforced resin hollow part 50. The hollow laminate 20 used here is the same as that described with reference to FIG. 4 or FIG. 5, and the mold 40 is also the same as that described with reference to FIG. However, the difference is that the pressure of the pressurized air entering from the pressurized air supply valve 41 is directly applied to the inner surface of the hollow resin core 10 without using the above-described pressurizing bag 30 in the molding. This molding method is also possible when the hollow resin core 10 has sufficient airtightness. This molding method can also be applied to a molding method using the hollow laminate 20 and the molding die 40A described with reference to FIG.

  As described above, the flanged fiber reinforced resin hollow part 50 obtained by the molding method according to the present invention is integrally made of a fiber reinforced resin in which a hollow main body portion and a flange portion are continuous, and is lightweight and has a flange portion. And the flanged fiber reinforced resin hollow part 50 having high mechanical strength including the boundary with the hollow main body portion is obtained.

  The molding method according to the present invention is particularly preferably used to make a flanged fiber-reinforced resin hollow part 50 having a three-dimensional irregular cross section and having a bent portion. Of course, it can also be used to make a flanged fiber reinforced resin hollow part 50 having a simple cross section such as a circular shape or a fiber reinforced resin hollow part 50 having a straight flange.

  Further, in the above description, the second core 15 has been described as a cylindrical shape, but it may be shaped like an open curved plate, provided that the peripheral lengths of the regions to be the flanges match. .

DESCRIPTION OF SYMBOLS 10 ... Hollow resin core 11 ... Open end 12 ... Closed end 13 ... Bending part 14 ... Internal space 15 ... 2nd core 20, 20A ... Hollow laminated body 21 ... Reinforcement fiber layer (brading layer)
22 ... Braiding layer 23 whose braiding angle with respect to the axis is 0 degrees ... Braiding layer 24 whose braiding angle with respect to the axis is? Degrees ... Resin film for matrix 26 ... Flange-like portion 27 ... Sewing 30 ... Pressurizing bag 40, 40A ... Mold 41 ... Pressurized air supply valve 42 ... Exhaust port 43 ... Resin injection port 44 ... Resin tank 45 ... Resin for matrix 50 ... Fiber reinforced resin hollow part with flange

Claims (7)

A method of molding a fiber reinforced resin hollow part integrally having a flange portion at a tip by an internal pressure molding method,
Connecting the second core to the tip of the preformed hollow resin core;
Forming a hollow laminate by laminating at least reinforcing fibers on the outer periphery of the hollow resin core and the second core;
After pulling out the second core from the hollow laminate, pressing the region from which the second core is pulled out to form a hollow laminate having a flange at the tip;
Placing the hollow laminate in a mold; and
A method of forming a flanged fiber reinforced resin hollow part, comprising at least a step of forming a hollow laminated body having a flange portion disposed in a molding die into a flanged fiber reinforced resin hollow part by an internal pressure molding method. A method of molding a fiber reinforced resin hollow part integrally having a flange portion at a tip by an internal pressure molding method,
Connecting the second core to the tip of the preformed hollow resin core;
Forming a hollow laminate by laminating reinforcing fibers and a matrix resin on the outer periphery of the hollow resin core and the second core;
Withdrawing the second core from the hollow laminate;
Pressing the region from which the second core in the hollow laminate is pulled out to form a flange shape; and
Placing the hollow laminate in a mold; and
A step of heating and applying the internal pressure to the hollow laminate disposed in the mold and integrating the resin and the reinforcing fiber;
A method for forming a hollow fiber-reinforced resin hollow part having a flange. A method of molding a fiber reinforced resin hollow part integrally having a flange portion at a tip by an internal pressure molding method,
Connecting the second core to the tip of the preformed hollow resin core;
Forming a hollow laminate by laminating reinforcing fibers on the outer periphery of the hollow resin core and the second core;
Withdrawing the second core from the hollow laminate;
Pressing the region from which the second core in the hollow laminate is pulled out to form a flange shape; and
Placing the hollow laminate in a mold; and
Injecting a matrix resin into the mold,
A step of heating and applying the internal pressure to the hollow laminate disposed in the mold and integrating the resin and the reinforcing fiber;
A method for forming a hollow fiber-reinforced resin hollow part having a flange.   As a step before the step of disposing the hollow laminate in the mold, the method includes a step of inserting and placing a pressure bag into the hollow resin core of the hollow laminate, to the hollow laminate disposed in the mold The method for forming a flanged fiber-reinforced resin hollow part according to any one of claims 1 to 3, wherein the internal pressure is applied by applying pressure to the pressurizing bag.   The method for molding a flanged fiber reinforced resin hollow part according to any one of claims 1 to 4, wherein the step of laminating the reinforced fibers on the outer periphery of the hollow resin core and the second core is performed by braiding. A method for molding a hollow fiber-reinforced resin hollow part with a flange, which is performed by weaving.   6. The method for forming a flanged fiber reinforced resin hollow part according to claim 5, wherein braiding of the braided yarn by the braiding method is performed such that the braided angle with respect to the axis is 0 degrees and the braided angle with respect to the axis is θ. A method for forming a flanged fiber-reinforced resin hollow part, which is performed by alternately braiding the braided yarn layers having the same degree.   As a step prior to the step of disposing the hollow laminate in a mold, the method further includes a step of sewing in a boundary region between the hollow portion of the hollow laminate and the flanged portion. The molding method of the fiber reinforced resin hollow part with a flange in any one of Claim 1 thru | or 6.

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