WO2020178949A1 - Jig stand - Google Patents

Abstract

Provided is a jig stand that can omit a mold release treatment step in a process for molding a fiber-reinforced plastic laminate. A mold release film 40 is bonded to the surface of a jig stand 30. The mold release film 40 is formed by bonding an FEP film 41 and a silicon-based adhesive film 42. It is preferable that the mold release film 40 be thin (100 μm or less). The mold release film 40 is suitable for the jig stand 30 having a free surface. In general, the existing jig stand 30 is made of metal. The thin mold release film 40 is stretchable and can thus be bonded to the free surface of the jig stand 30 while suppressing the occurrence of wrinkles. The thin mold release film 40 does not affect the product shape accuracy. The thickness of the mold release film 40 is uniform as compared to the case of applying a conventional mold releasing agent. In an overall product manufacturing process, mold release treatment and cleaning can be omitted. As a result, the overall product manufacturing process for the fiber-reinforced plastic laminate can be simplified.

Description

Jig stand

The present invention relates to a jig base used when molding a fiber reinforced plastic.

In recent years, fiber reinforced plastics such as carbon fiber reinforced plastic (CFRP) (Carbon Fiber Reinforced Plastics) have been receiving attention. Utilizing the features of light weight and high strength, it is applied to various industrial fields as a material for aircraft and automobiles. In addition, glass fiber, quartz glass fiber, or aramid fiber may be used.

A brief explanation will be given of an example of a method for forming a fiber-reinforced plastic laminate. A prepreg sheet laminated body is laminated on a jig stand and shaped into a product shape. The prepreg sheet is formed by impregnating a reinforcing material such as carbon fiber with an uncured thermosetting resin, and is formed into a sheet shape.

Unsaturated polyester, epoxy resin, phenol resin, etc. are used as the thermosetting resin.

Further, the shaped fiber reinforced plastic laminate is bagged together with the jig table in a vacuum bag to evacuate, conveyed to an autoclave device, and heated and pressed. As a result, the resin is cured and a fiber-reinforced plastic laminate (product) is molded. Then, the product is demolded.

Note that thermoplastic resin such as polyamide resin or polypropylene resin may be used instead of the thermosetting resin. The thermoplastic resin is softened by heating and then solidified by cooling.

JP-A-2003-200510

The outline of the method for forming a fiber-reinforced plastic laminate has been explained above, but in reality, it includes several detailed steps. When the process becomes complicated, the product cost is affected. The complexity of the process increases the risk of failure. Therefore, it is important to reduce the number of steps.

　In some of the above detailed processes, there is a jig stand release process.

Prepreg contains uncured thermosetting resin. When the prepreg is laminated on the jig base, vacuumed, and heated and pressed using an autoclave, a part of the thermosetting resin may adhere to the jig base. This causes a problem when the product is demolded.

For such a problem, a release agent such as fluorine resin or silicon resin is applied (liquid coating) on the surface of the jig table in advance to form a release film.

The mold release process is often performed manually in each molding process of the fiber-reinforced plastic laminate. As a result, the working time becomes long, and uneven coating may occur. Uneven coating is also a cause of product defects.

The inventor of the present application considered omitting the mold release processing step.

The present invention solves the above problems, and an object of the present invention is to provide a jig base that can omit the mold release process.

The present invention for solving the above problems is a jig stand for placing a fiber sheet containing a resin, laminating, vacuuming, heating and pressurizing, and demolding to form a fiber reinforced plastic. A release film is adhered to the surface of the jig base.

This allows the mold release process to be omitted. As a result, the molding process of the fiber-reinforced plastic laminate (the entire product manufacturing process) can be simplified. Further, the thickness of the release film is uniform as compared with the case where the release agent is applied with a lot of unevenness.

Preferably, the release film includes a film composed of a tetrafluoroethylene/hexafluoropropylene copolymer.

Among the fluorinated films, the FEP film can be made thin.

Preferably, the release film has a thickness of 100 μm or less.

Due to the extensibility of the thin release film, it is possible to adhere to the jig base surface while suppressing wrinkling. A thin release film does not affect the product shape accuracy.

Preferably, the release film includes a silicone adhesive film.

By inserting a silicon adhesive film, the FEP film can be bonded to the surface of the jig stand.

-Preferably, the jig stand is already installed.

Preferably, the jig base has a free-form surface.

Preferably made of metal.

The release film of the present application is suitable for solving the problems when the metal jig stand is already installed or when the jig stand has a free surface.

By using the jig stand according to the present invention, the mold release process can be omitted. As a result, the molding process of the fiber-reinforced plastic laminate (the entire product manufacturing process) can be simplified.

Comparison between conventional process and this process Excerpt of essential parts of product manufacturing process Heating and pressurizing profile in autoclave equipment Release film schematic structure Relationship between free-form surface and film thickness

-Overall product manufacturing process-

Fig. 1 is a comparison diagram of the outline of the conventional process related to product manufacturing and the outline of the process of the present application. FIG. 2 is an excerpt of an essential part of the product manufacturing process. The main part is common in the conventional process and the process of the present application.

First, the conventional process outline will be explained.

The upper part of FIG. 2 shows the jig base 30 before the start of manufacturing. First, the jig table 30 is released. Specifically, a release agent such as a fluorine-based resin or a silicon-based resin is applied (liquid coating) on the surface of the jig base in advance to form a release film.

Laminate a prepreg sheet on the jig table 30 and shape it into the product shape (middle stage in FIG. 2). After the lamination is completed, the uncured laminate is bagged together with the jig base 30 by a vacuum bag (lower part of FIG. 2).

Transfer the jig table 30 to the autoclave and heat and press. As a result, the resin is cured and a fiber-reinforced plastic laminate (product) is molded.

Fig. 3 shows an example of a heating and pressurizing profile in an autoclave device. The horizontal axis is time. However, this is an example and the present application is not limited to this.

First, reduce the pressure inside the vacuum bag to -0.1 MPa. Start heating under reduced pressure. Further, pressurization is started while maintaining the reduced pressure. The depressurized state is gradually returned to atmospheric pressure while increasing the pressure. The temperature at this time is about 120° C. (±10° C.) (first heating step). Further, the pressure is increased to 0.3 MPa.

Furthermore, the temperature is maintained at about 180°C (±20°C) for several tens of minutes to several hours and maintained for several hours (second heating stage). For example, in the case of an epoxy resin, curing starts at over 160°C. Then, the pressure is reduced to 60° C. or lower again for about 1 hour, and depressurization is started.

⑦ Unload the product from the autoclave with the jig table 30 and demold the product.

After the mold is removed, a part of the thermosetting resin that has extruded and hardened may adhere to the surface of the jig base 30. In some cases, the release film formed before product molding is deteriorated. Therefore, the surface of the jig base 30 is cleaned, and the mold release process is performed again. The release film is deposited by the re-release processing, and the release effect can be expected for the next use. The jig base is stored in this state.

Returning to FIG. 1, the process outline of the present application will be described. The process of the present application is almost the same as the conventional process. By the way, the release film 40 is adhered to the surface of the jig base 30. Thereby, in the process of the present application, the mold release treatment before and after molding can be omitted. Also, the cleaning process after molding is a simple operation of only blowing an air blow, and can be practically omitted. As a result, the molding process of the fiber-reinforced plastic laminate (the entire product manufacturing process) can be simplified.

-Release film basic composition-
FIG. 4 is a schematic configuration diagram of a release film. The release film 40 is adhered to the surface of the jig base 30. The release film 40 is formed of a first film (FEP film) 41 made of a tetrafluoroethylene/hexafluoropropylene copolymer and a second film 42 which is a silicon-based adhesive film.

The back surface of the first film 41 is surface-modified by plasma or the like, and is adhered to the second film 42. That is, the first film 41 is adhered to the surface of the jig base 30 via the second film 42.

The reason why the inventor of the present application particularly selected the FEP film among the fluorine-based release films was the focus on the film thickness (thinness). The thickness of the release film 40 is preferably 100 μm or less.

In the prototype model, the product name "A5000 CLEAR NP NP" of SOLVAY Cytec is used as a FEP film.
CEMENTABLE” was used. The product name "Polysil" of Taiyo Wire Mesh Co., Ltd. was used as the silicon-based adhesive film.

In the prototype model, the FEP film 41 had a thickness of 25 μm, the silicon-based adhesive film 42 had a thickness of 50 μm, and the release film 40 had a thickness of 75 μm (<100 μm).

The PTFE resin (polytetrafluoroethylene, so-called Teflon (registered trademark)) film, which is generally used among fluorine-based release films, tends to be thicker (for example, 1 mm or more) than the FEP film.

On the other hand, compared to the conventional release agent coating, the thickness of the release film is uniform.

-Details of jig table-
The present application is not limited to the existing jig base 30 or the free curved surface (may include a new installation, a flat surface, or a simple curved surface). In the case of having a curved surface (see the upper part of FIG. 2), the release film 40 of the present application is suitable.

-A free-form surface is a curved surface that is set by setting some intersections and curvatures in space and interpolating each intersection with a higher-order equation. It is different from a simple curved surface that can be represented by a simple mathematical formula such as a spherical surface or a cylindrical surface.

-Industrial products such as aircraft and automobiles have free-form surfaces. The product shape follows the jig trapezoidal shape. Therefore, the jig base 30 has a free curved surface. For example, the jig base used for the prototype model shown in the upper part of FIG. 2 has a free-form surface.

Note that the jig base 30 is generally made of metal.

-Relation between free-form surface and film thickness-
FIG. 5 is an explanatory diagram showing the relationship between the free-form surface and the film thickness. The free-form surface was modeled. A downwardly convex curved surface (left side in the figure) and an upwardly convex curved surface (right side in the figure) are continuous.

With a downwardly convex curved surface, the curvature L2 of the film surface becomes larger (bent) than the curvature L1 of the jig table surface. On the other hand, in the case of a curved surface that is convex upward, the curvature R2 of the film surface is smaller than the curvature R1 of the jig table surface (the bending is loose).

The thicker the film, the more likely it is that errors will occur between the film surface shape and the jig table surface shape. As a result, the product shape accuracy is affected.

If it is a new jig stand, the surface shape of the jig stand may be designed by considering the error in advance, but it is preferable that the film is as thin as possible in order to suppress the error in the existing jig stand.

Furthermore, if the film is thick, it has rigidity, and wrinkles will occur if it is pasted on a free-form surface. On the other hand, a thin film has extensibility and follows a free-form surface, so that wrinkles do not occur.

～Remark 1 History of the application～
A low-density/high-density polyethylene film is often used for protection of prepreg sheets (prevention of dust adhesion), but an alternative FEP film was examined. In the process, it was examined to use a fluororesin-based release film containing a FEP film instead of the release film by applying a release agent.

The melting point of PTFE is 327°C, whereas the melting point of FEP is 260°C. From the viewpoint of heat resistance, PTFE seems to be a preferable material. By the way, in an autoclave, it is heated up to about 180°C. The inventor believed that the FEP film also had sufficient heat resistance against heating during autoclave molding, and confirmed this through experiments.

Next, I thought about bonding the FEP film to the surface of the jig table. As a result of the investigation, it was found that a thin silicon-based adhesive film is commercially available. It was confirmed by an experiment that the adhesive force of the silicon-based adhesive film is sufficient and the FEP film can be adhered.

Furthermore, we verified the risk that the thin release film would be damaged by repeated heating and pressing. Here, the inventor considered that deterioration due to oxygen contact does not occur because the method of use is characterized in that it is evacuated once during autoclave molding, that is, the risk of damage is low even with a thin release film.

The product molding was repeated 100 times or more using the jig stand of the present application, but it was confirmed that the release film was not damaged.

As mentioned above, the inventor has come up with the present invention through several trial and error processes.

-Remark 2: Supplement on ease of adhesion-
Since the release film 40 of the present application is thin and has stretchability, it follows a free curved surface. It also has good adhesiveness. Therefore, it can be easily adhered to the jig base 30. Moreover, once bonded, it can withstand repeated use.

Therefore, the release film adhesion work hardly burdens the whole process.

Even if it is damaged after repeated use, it can be easily replaced.

~Summary~
The release film 40 is adhered to the surface of the jig base 30. The release film 40 is formed by adhering the FEP film 41 and the silicon-based adhesive film 42. The release film 40 is preferably thin (100 μm or less). The release film 40 is suitable for a jig base 30 having a free surface. Generally, the existing jig table 30 is made of metal.

The thin release film 40 has extensibility and can be adhered to the free surface of the jig base 30 while suppressing wrinkling. The thin release film 40 does not affect the product shape accuracy. The thickness of the release film 40 is uniform as compared with the conventional release agent coating.

In the entire product manufacturing process, it is possible to omit mold release processing and cleaning processing before and after molding. As a result, the entire product manufacturing process of the fiber-reinforced plastic laminate can be simplified.

30 Jig stand 40 Release film 41 First film (FEP film)
42 Second film (silicon adhesive film)

Claims (7)

1. A jig stand on which a fiber sheet containing resin is placed, laminated, evacuated, heated and pressed, and demolded to form fiber reinforced plastic.
   A jig stand characterized in that a release film is adhered to the surface of the jig stand.
2. The jig base according to claim 1, wherein the release film includes a film composed of a tetrafluoroethylene / hexafluoropropylene copolymer.
3. The jig base according to claim 1 or 2, wherein the release film has a thickness of 100 µm or less.
4. The jig base according to any one of claims 1 to 3, wherein the release film includes a silicon-based adhesive film.
5. The jig base according to any one of claims 1 to 4, which is an existing one.
6. The jig base according to any one of claims 1 to 5, which has a free-form surface.
7. The jig base according to any one of claims 1 to 6, which is made of metal.

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