KR102027328B1 - Hybrid profile having xFRPcable-type prepreg and preparing method for the same - Google Patents

Abstract

Disclosed are a cable-type prepreg of a fiber-reinforced resin, a method of manufacturing the fiber-reinforced resin and a method of manufacturing the same, and a hybrid profile in which the prepreg of the fiber-reinforced resin is manufactured in a cable form and integrated therewith. Hybrid profile manufacturing method having a cable-type prepreg according to the present invention comprises the steps of preparing a metal profile, the step of preparing a cable-type prepreg to be bonded to the metal profile, and the cable-type prepreg laminated to prepreg lamination Forming a structure and then adhering to the metal profile; and bonding the prepreg laminate to the metal profile by pressing and heating.

Description

Cable-type prepreg of fiber-reinforced resin, its manufacturing method and hybrid profile using the same and manufacturing method therefor {Hybrid profile having xFRPcable-type prepreg and preparing method for the same}

The present invention relates to a cable-type prepreg of a fiber-reinforced resin for producing a prepreg of a fiber-reinforced resin in a cable form, and a method of manufacturing the same, and a hybrid profile and a method of manufacturing the same by combining it with a metal profile.

In general, fiber-reinforced resins are used in various industries as advanced materials that are stronger than steel and lighter than aluminum. Prepreg is an abbreviation of Preimpregnated Materials. It is a sheet-type product in which Matrix is pre-impregnated with Reinforced Fiber and is an intermediate material of a composite product. Carbon fiber, glass fiber, aramid fiber and the like are mainly used as reinforcing fibers, and epoxy resins, polyester resins, and thermoplastic resins are used as binders. Prepregs form a wide range of products depending on the type of fiber, the arrangement of the fiber and the type of binder used. Composites produced using prepregs have strength, stiffness, corrosion resistance, fatigue, wear resistance, impact resistance, and weight reduction compared to other materials. Since various properties such as weight reduction can be improved, it has recently been widely used in the production of aerospace, general industry, sports, and leisure goods.

Fibers with excellent physical properties are reinforced with resins (e.g. carbon fiber reinforced resin). In the case of short fibers, they are mixed with resins by a process such as injection molding and molded by pressing and heat in the same mold as the mold. In this case, there is a process using a resin impregnation or resin injection method, but a preform of a plate-type prepreg mainly combined with a matrix resin is formed by cutting and laminating, and then molded by pressing and heat in a mold such as a mold. At this time, the resin mixing, impregnation, and injection method for the fiber is excellent in productivity, but if the liquid viscosity of the resin is high, the integration with the fiber is not smooth, porosity occurs after curing, and if the liquid viscosity is low, the physical properties are poor.

The prepreg usage method by matrix resin for fiber is already pre-integration with fiber and is uniformly pressurized and cured in autoclave, so it has excellent physical properties and reliability but uses expensive non-productive equipment such as autoclave. According to the purpose of using the fiber reinforced resin, the process of cutting and laminating the sticky flat fabric in the prepreg state in the direction of the fiber arrangement is quite unproductive. In other words, productivity drops.

Resin film injection method is a method that takes advantage of the two methods, dry fabric of each layer in the cutting and lamination of the shape to be molded. That is, the resin film is closely adhered to the fiber pattern in advance, and repeatedly stacked in a form close to the finished shape, and then pressurized with a vacuum in a mold such as a mold, followed by curing and molding by applying heat, rather than mixing, impregnating and injecting liquid resin. It has excellent physical properties and high reliability, and resin film is melted and injected into a uniform thickness to a fiber pattern without expensive equipment such as autoclave applying uniform pressure, and dry fabric. That is, since the fiber pattern is not sticky, lamination is easier and productivity is relatively excellent.

The resin film injection method is dry pattern. That is, except that the fiber pattern is not sticky and easy to work, the cutting and lamination of the fiber pattern and the film should be repeatedly made alternately in each layer in the form of a mat, which is not easy, and may reduce the reliability of molding. have.

Conventional prepreg is in the form of a flat plate (mat), and the size and alignment of each layer of the mat must be precisely cut and laminated, and the operation is not easy, and in particular, the prepreg is more difficult to handle because of its stickiness. In order to solve this problem, an automatic lamination facility may be used, which may be expensive and difficult to apply depending on the size of the molded product. In addition, it is difficult to implement the shape of the corners by lamination of the mat, such as a portion where the shape of the corners is folded mat.

Therefore, the hybrid profile according to the prior art, for example, the hybrid hollow shaft may be applied to the fiber-reinforced resin GFRP, CFRP, or a mixed layer thereof inside the metal tube, the hybrid profile is used to integrate the fiber reinforced resin and the metal tube There was a difficult production problem.

Registered Patent No. 1746026

An object of the present invention is to solve such a problem, the conventional prepreg of the fiber-reinforced resin by impregnation, or the prepreg of the fiber-reinforced resin by the resin film injection method is not a mat type, the internal sticky resin film and the outside It is to provide a cable-type prepreg made of a dry (dry) fiber or a sheath of a suitable material and a method of manufacturing the same.

In addition, while using a cable-type prepreg to solve the problem of inefficient productivity and poor working environment, it is to provide a hybrid profile having a fiber-reinforced resin by a resin film injection method having excellent physical properties and a method of manufacturing the same.

In addition, in the case of using the conventional metal profile and fiber-reinforced resin profile, the former has a heavy and physical property, the latter is expensive and the workability and utilization by the joint with the surroundings each have problems. In order to solve the problem and take advantage, the fiber-reinforced resin is separately manufactured in the metal profile to be integrated by bonding or fitting, or the combination of the resin film injection type cable prepreg, lamination, vacuum pressurization and thermosetting process The present invention provides a hybrid profile having a cable-type prepreg integrating a profile and a fiber reinforced resin, and a method of manufacturing the same.

As a specific means for achieving the above object, the present invention comprises the steps of adding a reinforcing fiber and a resin film in parallel; Contacting the reinforcing fibers and the resin film; And integrating the reinforcing fibers and the resin film to form a cable.

Preferably, the reinforcing fibers and the resin film may be washed with air while being put in parallel.

Preferably, the step of forming the reinforcing fibers and the resin film in the form of a cable, it may further comprise the step of wrapping the outer shell on the outer surface.

Preferably, the step of forming the reinforcing fibers and the resin film in the form of a cable, it may further comprise the step of winding in the bobbin.

As another specific means for achieving the above object, the present invention comprises the steps of preparing a metal profile; Providing a cable type prepreg to be bonded to the metal profile; Stacking the cable type prepregs to form a prepreg stack structure and then attaching the cable prepregs to the metal profile; And pressing and heating the prepreg laminate structure to the metal profile.

Preferably, the step of stacking the cable-shaped prepreg and in close contact with the metal profile, the step of cutting the plurality of cable-type prepreg according to a pre-designed form; Stacking the cut cable-shaped prepregs to form the prepreg stack structure; And contacting the prepreg laminate structure to the metal profile.

Preferably, before cutting the plurality of cable-type prepreg, it may include the step of removing the outer shell of the cable-type prepreg.

Preferably, in the step of adhering the prepreg laminate structure to the metal profile by pressing and heating, the pressing may be performed at a vacuum pressure.

Preferably, before pressing and heating the prepreg laminated structure to the metal profile, the cable type prepreg may be in close contact with the inner side of the hollow of the metal profile, and may be removed after vacuum bag or molding at the center. Fillings may be inserted.

Preferably, a scratch may be formed on a junction surface of the prepreg laminate structure and the metal profile.

Preferably, a preload may be applied to prevent separation due to a difference in thermal expansion coefficient between the metal profile and the prepreg laminated structure before pressing and heating the prepreg laminated structure to the metal profile.

Preferably, the prepreg laminated structure may have a different diameter.

Preferably, the metal profile may be divided into a plurality of zones by a partition of a metal material, such as a honeycomb structure in cross section, and the prepreg laminated structure may be pressed and heated in close contact with each of the plurality of zones.

As another specific means for achieving the above object, the present invention, the central wick; A first resin film layer adhered to surround the outer surface of the wick; A plurality of fibers arranged in a circular shape so as to surround the outer surface of the first resin film layer; And a second resin film layer adhered to surround the outer ends of the plurality of fibers.

Preferably, the second resin film layer may further include an envelope surrounding the film.

Preferably, a vacuum film for vacuum bagging may be provided between the wick and the first resin film layer.

Preferably, the prepreg laminated structure formed by closely stacking a plurality of cable-type prepregs of the fiber-reinforced resin may be bonded to one side of the metal profile.

Preferably, the metal profile may be divided into a plurality of zones by a partition of a metal material, such as a honeycomb structure in cross section, and the prepreg laminated structure may be pressed and heated in close contact with each of the plurality of zones.

As described above, the present invention has the following effects.

(1) The cable type prepreg of the present invention is a simple series of devices that are commonly used to form layers by layering and layering such layers, rather than cutting and layering each layer into a surface, as a filament of 3D printing. It can be combined and laminated at the same time to remove the dry outer shell, and in some cases can be used without removing the outer shell, and because it is a cable form can be varied in thickness to reduce the number of lamination, and to prevent the corners folded Various shapes can be realized, and processes such as filament winding can be applied in a continuous operation.

(2) The present invention is a hybrid profile manufacturing method, the effect of using a cable-type prepreg is easier to handle than a liquid resin, a variety of lamination is possible, because the cable form than the flat type of the matrix resin like filament The thickness of each layer can be adjusted according to the cutting, combination, and thickness by handling, so the productivity is excellent.

(3) In the present invention, as a subsidiary material for molding the prepreg, a vacuum bag, a perforated material, a peel ply, a breather, and a packing, etc. should be installed, and a cable type prepreg is used for forming a part of the subsidiary material as a cable component. It can be removed after molding or used as it is, so it has a simpler process than the mat type.

(4) In the hybrid profile manufacturing method of the present invention, in the case of integrating the fiber-reinforced resin into the closed hollow space of the metal profile, the molded part prefabricated and molded by the cable-type prepreg is pressed by the front end to the leader line. It is inserted into the hollow part, and the gap between the molded part and the profile can be filled by a series of devices with a suitable adhesive material to integrate the metal profile and the fiber reinforced resin, which is considerably more productive than other methods.

(5) In the present invention, when the physical properties of the product are to be increased, it is necessary to integrate the metal profile in the prepreg laminated state instead of inserting a molded product prepared in advance. For the installation, the outer surface of the prepreg laminate is sticky, whether it is mat type or cable type, so a gap is required, and even if a very thin dry (dry) shell is used, there is basically a gap required for insertion. If the gap is so large that it cannot be filled, the mat shape cannot change the size of each element, so the gap cannot be filled, but the cable type prepreg can use the cable type with a vacuum bag at each wick part. By increasing the size of the gap can also fill the gap and pressurize.

1 is a longitudinal cross-sectional view showing a cable-type prepreg structure according to the present invention.
Figure 2 is a cable-type prepreg according to the present invention, the longitudinal cross-sectional view showing a cable-type prepreg structure having a vacuum bagging film and a wick in the center with the outer shell removed.
3 and 4 is a manufacturing process diagram of the cable type prepreg according to the present invention.
5 and 6 are uncoiling and lamination process diagram of the cable type prepreg according to the present invention.
7 is a cross-sectional view showing the insertion of a prepreg molded article or the lamination of the prepreg in the closed hollow portion of the metal profile according to the present invention.
8 is a cross-sectional view illustrating the stacking of prepregs in the open portion of the metal profile according to the present invention.
9 is a hybrid profile manufacturing process chart according to the present invention, which is a process chart for joining or inserting a prepreg molded article into a metal profile.
FIG. 10 is a hybrid profile fabrication process according to the present invention, in which a prepreg is laminated or inserted into a metal profile. FIG.
11 shows an example of a sandwich panel having a honeycomb structure as a hybrid profile according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like elements throughout the specification.

In this specification, terms such as "comprise" or "have" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described on the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, parts, or combinations thereof. In addition, when a part such as a layer, film, region, plate, etc. is said to be "on" another part, this includes not only when the other part is "right on" but also another part in the middle. Conversely, when a part such as a layer, film, region, plate, etc. is "below" another part, this includes not only the other part "below" but also another part in the middle.

Hereinafter, with reference to the drawings will be described in more detail the cable-type prepreg of the fiber-reinforced resin according to an embodiment of the present invention, a method for manufacturing the same and a hybrid profile using the same and a method for manufacturing the same.

Cable prepreg manufacturing method of the fiber-reinforced resin according to the first embodiment of the present invention, referring to Figure 4, the step of proceeding to the thickness and shape design of the cable-type prepreg (S10), the reinforcing fiber and the resin film In parallel with the step (S20), the step of contacting the reinforcing fibers and the resin film (S30), and the step of integrating the reinforcing fibers and the resin film to form a cable form (S50).

At this time, the reinforcing fibers and the resin film may be washed in the air while being put in parallel.

At this time, the reinforcing fibers and the resin film may be formed in the form of a cable, the outer surface may further comprise the step of wrapping the outer shell.

At this time, the reinforcing fibers and the resin film may be formed in the form of a cable, it may further include the step of winding in the bobbin.

On the other hand, the hybrid profile manufacturing method using a cable-type prepreg of the fiber reinforced resin according to an embodiment of the present invention, referring to Figures 9 and 10, preparing a metal profile (S110, S160) and the metal Preparing a cable type prepreg to be bonded to the profile (S120, S170), and stacking the cable type prepreg to form a prepreg laminated structure (S120, S170) and then closely attaching the metal profile (S130, S180) and pressing and heating the prepreg laminated structure to the metal profile may include bonding (S140 and S190).

In the preparing of the metal profile, the metal profile refers to a part manufactured in a shape having a predetermined cross section and extending a predetermined distance in the longitudinal direction and simultaneously having a metal material. Examples thereof include a hybrid profile provided by the present invention, and a sandwich panel having a honeycomb structure in the middle of the shape may be exemplified. Will come true.

As an example of the metal profile, a hybrid profile is typically used as an axis for transmitting engine driving force to a rear wheel in a vehicle.

In this case, the step of stacking the cable-type prepreg to closely contact the metal profile, the step of cutting the plurality of cable-type prepreg according to a pre-designed form, the laminated by cutting the cable-type prepreg to the prepreg Forming a laminated structure and the step of bringing the prepreg laminated structure in close contact with the metal profile.

At this time, before cutting the plurality of cable-type prepreg, it may include the step of removing the outer shell of the cable-type prepreg.

In this case, in the step of adhering the prepreg laminated structure to the metal profile by pressing and heating, pressurization may be performed by vacuum pressure.

In this case, before pressing and heating the prepreg laminated structure to the metal profile, the cable-shaped prepreg is in close contact with the inner side of the hollow of the metal profile, and a packing that can be removed after vacuum bag or molding at the center thereof. This can be inserted.

In this case, a scratch may be formed on a junction surface of the prepreg laminate structure and the metal profile. Such scratches increase the area of the joint surface, thereby increasing the adhesive force.

At this time, before the prepreg laminated structure is pressed and heated to be bonded to the metal profile, a preload may be applied to prevent separation due to a difference in thermal expansion coefficient between the metal profile and the prepreg laminated structure.

In this case, the prepreg laminated structure may have a different diameter.

On the other hand, the cable-shaped prepreg (10, 10 ') of the fiber reinforced resin according to an embodiment of the present invention, referring to Figures 1 and 2, the central wick (30, 30') and the wick (30) The first resin film layers 40 and 40 'adhered to surround the outer surface of the 30', and the plurality of fibers 20 and 20 'are arranged in a circular shape to surround the outer surface of the first resin film layer. And second resin film layers 41 and 41 'adhered to surround the outer ends of the plurality of fibers.

In this case, the second resin film may further include an outer shell 50 surrounding the film.

At this time, in the case of a sandwich panel having a honeycomb (honeycomb) structure in the middle of the panel portion, a cable-type prepreg is filled in the hollow portion of the honeycomb, and a vacuum film for vacuum bagging is provided between the wick and the first resin film layer. Can be.

On the other hand, the cable-shaped prepreg of the fiber reinforced resin according to another embodiment of the present invention, referring to Figures 1, 2, 7, so that the outer surface is in close contact with each other, so as to surround the outer periphery of the plurality of fibers It may include a resin film layer in close contact.

On the other hand, the hybrid profile according to an embodiment of the present invention may be made by bonding a prepreg laminated structure formed by closely stacking a plurality of cable-type prepreg of the fiber reinforced resin to one side of the metal profile.

In this case, the cable-type prepreg of the fiber reinforced resin may be laminated in a honeycomb form.

Referring to Figure 3, as a manufacturing process diagram of the cable-type prepreg, while putting a fiber 20 or dry fiber mat that can be reinforced as a reinforced resin at a predetermined angle (100), on the other hand, produced through the resin film manufacturing apparatus A certain thickness of the resin film 40a is put in parallel (110) is washed with an air jet and is in close contact (120) is integrated with the wick 30 and other auxiliary materials in the form of a cylindrical cable (130).

Since the cable-type prepreg should be stored, the envelope 50 is wrapped around the envelope 50 with a coiling 150 facility and wound around the bobbin of the cylindrical facility.

Referring to Figures 1 and 2, this is a cross-sectional structural view of the cable-shaped prepreg wound in this way, the core (30, 30 ') of the central portion, as a member surrounding it, the fiber (20, 20') or the resin in close contact with the fiber mat Film 40, 41, 40 ′, 41 ′, or a dry (dry) jacket 50 in the form of braids or bands, or wicks 30, 30 ′ and resin film 40 depending on the purpose as shown in FIG. 2. (41,40 ', 41') can be replaced by a vacuum film 60 ', which is a subsidiary material for vacuum bagging, which can ultimately pressurize and thermoset the fiber-reinforced resin, and a small vacuum bagging subsidiary material layer. Can be.

In more detail, the purpose of this is to connect the vacuum line 260a of each vacuum bagging of the cable-type prepreg to the main line and to use it as a pressurization. Voids can be minimized.

Referring to Figure 5, while storing the cable-shaped prepreg in the form of a coil uncoiling 160 while showing a process of manufacturing a fiber-reinforced molded article alone or a hybrid profile.

Uncoil the cable-type prepreg raw material (80) and pass it through the skin removal equipment (170), as a filament in a pre-designed size, cut with a precision cutter (180) and supply equipment (190). Each layer is made of a surface, and then laminated to form a prepreg laminated structure (200), to fabricate an independent fiber-reinforced molded article, or to join or insert the molded product into the fiber-reinforced resin mounting portion of a metal profile to form a hybrid profile. To make. Alternatively, the prepreg laminated structure is inserted into a predetermined position or shape of a metal profile together with subsidiary materials such as vacuum bagging (210), and then pressurized with vacuum and cured with heat to produce a hybrid profile (220) (FIGS. 6 and 9). , 10).

Referring to FIG. 7, a cross-sectional view of a molded product by cutting and stacking various cable-type prepregs 90 (90a, 90b, and 90c) is inserted into a closed hollow portion of the metal profile 1. It is a cross-sectional view which inserted the cable-type prepreg into the closed hollow part of the metal profile in the form comprised with the auxiliary material 3 for vacuum bagging. In this state, when the vacuum pressure and heat are provided, the voids are filled with the resin and integrated with the reinforcing fibers. Of course, after providing the vacuum pressure will be distorted toward the metal profile 1 in a cross-section different from FIG.

Referring to FIG. 8, the cut and stacked cable type prepreg 90 is a cross-sectional view of the cable type prepreg 90 installed in the metal profile 1 in the form of the auxiliary material 3 for vacuum bagging. Again, providing vacuum pressure and heating will be distorted and complete. This hybrid profile may be applied when the steel part is frictionally moved on the conveyor at all times.

In the method of manufacturing a hybrid profile according to the present invention, the metal profile (1) replaces the role of a mold such as a mold of resin molding, and is a cable type in an open space and a closed hollow space of the metal profile (1). The molded article made of the prepreg 80 may be integrated by being bonded or inserted by hot fitting, or may be laminated or inserted into the corresponding part to be pressurized by vacuum and thermally cured to be integrated.

On the other hand, when it is necessary to increase the physical properties, it is necessary to integrate with the metal profile 1 in a prepreg laminated state instead of a preformed molded product. Since the stickiness of the outer surface hinders the insertion, it is wrapped in a dry (dry) outer shell 50 on the outer surface, and the prepreg lamination center part is made of the entire preform form in which the center part is flexibly composed of the vacuum bag (3) and the wick (30). After inserting it through the withdrawal operation (see FIG. 7) as described above, the outer shell 50 is peeled off and integrated into a vacuum and pressurized and thermally cured to expand the central portion configured flexibly.

In addition, when the gap between the metal profile 1 and the prepreg stack is so large that it cannot be filled by simply pressurizing it with a vacuum, the centers of the cable-type prepreg 90 elements surrounding the center are equally vacuum bag (3). It can be expanded by making the packing 4 and the vacuum treatment to both ends of the metal fitting 240, and may be filled with a gap by changing the size of the changing elements. That is, since the closed hollow shape of the hybrid profile is a mold-like frame, a plurality of vacuum lines may be formed in the form of pressurization in and out of the shape.

When forming a large-diameter tube shape in the hybrid profile of the present invention, a mandrel shape is formed at the center and the cable prepreg 90 is surrounded by the surroundings. It can also be pressurized by vacuum by making the leg of the leg connected.

Meanwhile, referring to FIG. 11, a cross-sectional view of a sandwich panel having a honeycomb structure using a cable type prepreg according to the present invention is shown.

Referring to FIG. 11, a plurality of hybrid profiles are inserted between sandwich panels 300. Alternatively, the sandwich panel 300 is partitioned into a plurality of zones 302 by a partition wall 310 made of metal, such as a honeycomb structure in cross section, between the two metal panels 301, and each of the plurality of zones 302 in FIG. 7. Similarly, after the cable-shaped prepreg 320 is inserted, the cable prepreg 320 is pressed, heated, and tightly sealed into the partition 310. Therefore, the prepreg will be distorted as shown in FIG. Each zone 302 is similar to making a hybrid profile, and the effect is the same, so that the stiffness can be maximized.

The honeycomb sandwich panel 300 may be difficult to manufacture because the area of each region 302 is very small, but may be implemented by manufacturing a terminal.

The sandwich panel 300 manufactured as described above may be used where a light material is required while having a predetermined thickness and rigidity, such as a vehicle body and a door.

Although one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments set forth herein, and those skilled in the art who understand the spirit of the present invention, within the scope of the same idea, the addition of components Other embodiments may be easily proposed by changing, deleting, adding, etc., but this will also be within the scope of the present invention.

1: Metal Profile 2: Hollow Center
3: vacuum bag and subsidiary material layer 4: vacuum packing
10, 10 ': Cable type prepreg 20, 20': Fiber
30, 30 ': wick 40, 40', 41, 41 ': resin film layer
50: jacket 60: vacuum film
80: Cable type prepreg (uncoiled state)
90, 90a, 90b, 90c: Cable type prepreg (removal, cut)
100: fiber supply equipment 110: resin film supply equipment
120: integrated equipment 130: air jet cleaning and integrated equipment
140: sheath supply equipment 150: coiling
160: uncoiling 170: skin removal equipment
180: precision cutter 190: prepreg supply equipment
200: lamination work equipment 210: vacuum bagging
220: hybrid profile manufacturing equipment 230: preload jig
240: preload bracket 250: bonding and filling liquid tank
250a: liquid binder input line 260: vacuum pump
260a: vacuum line

Claims (18)

delete delete delete delete Preparing a metal profile;
Providing a cable type prepreg to be bonded to the metal profile;
Stacking the cable type prepregs to form a prepreg stack structure and then attaching the cable prepregs to the metal profile; And
Pressing and heating the prepreg laminate to the metal profile;
Including,
Before attaching the prepreg laminated structure to the metal profile by pressing and heating, the cable-type prepreg is in close contact with the inner side of the hollow of the metal profile, and a filler that can be removed after vacuum bag or molding is inserted in the center. Hybrid profile manufacturing method using a cable-type prepreg of the fiber reinforced resin. The method of claim 5,
The step of stacking the cable-type prepreg and in close contact with the metal profile,
Cutting the cable type prepreg into a plurality of pieces according to a predesigned shape;
Stacking the cut cable-shaped prepregs to form the prepreg stack structure; And
Bringing the prepreg laminate structure into close contact with the metal profile;
Hybrid profile manufacturing method using a cable-type prepreg of fiber reinforced resin comprising a The method of claim 6,
Before cutting the plurality of cable-type prepreg, the hybrid profile manufacturing method using a cable-type prepreg of fiber reinforced resin comprising the step of removing the outer shell of the cable-type prepreg. The method of claim 5,
The method of manufacturing a hybrid profile using a cable-type prepreg of the fiber-reinforced resin is a vacuum pressure in the step of bonding the prepreg laminated structure to the metal profile by pressing and heating. delete The method of claim 5,
A hybrid profile manufacturing method using a cable-type prepreg of fiber reinforced resin having a scratch formed on the joining surface of the prepreg laminated structure and the metal profile. The method of claim 5,
Before pre-bonding the prepreg laminated structure to the metal profile by pressing and heating, the cable-shaped preprep of fiber reinforced resin which gives a preload in order to prevent separation due to the difference in thermal expansion coefficient between the metal profile and the prepreg laminated structure. Hybrid profile manufacturing method using legs. The method of claim 5,
The prepreg laminated structure is a hybrid profile manufacturing method using a cable-type prepreg of fiber reinforced resin having a different diameter. Preparing a metal profile;
Providing a cable type prepreg to be bonded to the metal profile;
Stacking the cable type prepregs to form a prepreg stack structure and then attaching the cable prepregs to the metal profile; And
Pressing and heating the prepreg laminate to the metal profile;
Including,
The metal profile is divided into a plurality of zones by a partition of a metal material like a honeycomb structure in cross section, and the hybrid profile using a cable-type prepreg of fiber reinforced resin in which the prepreg laminated structure is pressed and heated in each of the plurality of zones. Manufacturing method. Central wick;
A first resin film layer adhered to surround the outer surface of the wick;
A plurality of fibers arranged in a circular shape so as to surround the outer surface of the first resin film layer;
A second resin film layer adhered to surround outer ends of the plurality of fibers;
Cable type prepreg of fiber reinforced resin comprising a. The method of claim 14,
Cable-type prepreg of the fiber-reinforced resin further comprising an outer shell surrounding the second resin film layer. The method of claim 14,
Cable-type prepreg of the fiber-reinforced resin provided with a vacuum film for vacuum bagging between the wick and the first resin film layer. The method according to any one of claims 14 to 16,
And a prepreg laminated structure in which a plurality of cable-type prepregs of the fiber-reinforced resins are laminated in close contact with each other. The method of claim 17,
The metal profile is divided into a plurality of zones by a barrier rib made of metal, such as a honeycomb structure in cross section, and the hybrid profile using a cable-type prepreg of fiber reinforced resin in which the prepreg laminated structure is pressed and heated in each of the plurality of zones. .

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