KR102473089B1 - Electromagnetic shielding function composite material and its manufacturing method - Google Patents

Abstract

The present invention relates to a method for manufacturing an electromagnetic wave shielding functional composite material capable of manufacturing an electromagnetic wave shielding composite material with improved quality such as excellent electromagnetic wave shielding of low and high frequency bands and no layer separation after molding, and carbon fiber fabric Preparing a laminated material by sequentially stacking / glass mat / conductive metal thin film / glass mat / carbon fiber fabric; a backstitch step of backstitching the laminated material; cutting the sewn laminated material into a predetermined shape; After the cut laminated material is placed in the cavity of the hard lower mold, the upper mold made of silicon is molded, and the impregnating resin is injected through the resin inlet of the upper mold while internal air is sucked through the vacuum inlet of the upper mold. A resin injection step of injecting; and demolding the upper mold after the impregnation resin impregnated in the laminated material is cured.

Description

Electromagnetic shielding function composite material and its manufacturing method

The present invention relates to a composite material with electromagnetic wave shielding function and a method for manufacturing the same, and in particular, it is excellent in electromagnetic wave shielding of low and high frequency bands, and it is possible to manufacture an electromagnetic wave shielding function composite material with improved quality such as no layer separation after molding It relates to a method for manufacturing a composite material with electromagnetic shielding function.

Recently, due to the rapid development and mass spread of computers, electronic products, and communication devices, the generation of electromagnetic waves is increasing, and as the generation of noise due to electromagnetic waves in a wide range of frequencies is rapidly increasing, various problems such as the appearance of mutual failure between electronic products are being raised. have. In particular, in a situation where electronic equipment is applied to various safety devices and convenience devices for the safety of drivers and pedestrians in vehicles, and consumer interest in its functions is being maximized, low-power and high-integration of electronic components and circuits entering electronic equipment , High reliability is required in various aspects such as suppression of electromagnetic interference between electronic parts due to multifunctionalization, electromagnetic wave shielding, and immunity.

Conventionally, in order to effectively suppress electromagnetic interference between electronic products, it has been the best method to shield electromagnetic waves by surrounding electronic products with a metal housing or to construct an expensive electromagnetic wave shielding network. However, when an electronic product is wrapped with metal, expensive mold manufacturing costs are required, and the weight of the metal itself is disadvantageous in terms of reducing the weight of a vehicle to improve fuel efficiency.

In addition, with the spread of new and renewable energy, the supply of energy storage systems (ESSs) is increasing, and in particular, the household ESS (aka electric storage) market is developing rapidly recently.

These ESSs refer to devices that store energy remaining after use so that it can be used when needed, and is classified into small, medium, and large sizes according to capacity.

In addition, with the recent spread of renewable energy such as solar and wind power, the ESS market is also rapidly expanding, and in particular, home ESS installation is spreading to store surplus power during the week in homes where solar power generation facilities are installed.

On the other hand, patent documents 0001 to 0003 have been proposed in relation to technology for imparting an electromagnetic wave shielding function.

Patent Document 0001 relates to a conductive composite and an anisotropic conductive adhesive using the same, which includes a low melting point alloy filler composed of conductive particles that can be melted when heated, and a polymer having a curing temperature that becomes uncured at the melting point of the low melting point alloy filler. It is characterized in that the matrix is mixed with the low melting point alloy filler. Polymer composites containing conductive fillers are manufactured by the most common extrusion and injection molding, which are the most economical production methods and can achieve weight reduction and manufacturing cost reduction compared to electromagnetic shielding materials made of metal materials. However, the conventional polymer composite as described above has a disadvantage in that it is difficult to evenly disperse and distribute the conductive filler in the polymer during the process of manufacturing by extrusion and injection. In order to solve this difficulty in dispersion, various methods have been proposed, such as surface treatment of conductive fillers and addition of compatibilizers to increase the compatibility between fillers and polymers, but these problems lead to complexity of the manufacturing process and increase in manufacturing cost. there is

In addition, Patent Document 0002 relates to a method for manufacturing a transparent electromagnetic wave shielding agent, a shielding film layer, and a shielding film, wherein at least one material of metal, ceramic, or polymer, which is a transparent material, is dissolved in a solvent to create a base material in a solution state, the Mixing a predetermined amount of carbon nanotubes (CNT), carbon nanofibers (CNF), or nano-sized magnetic particles in a base material to maintain transparency, dispersing the material mixed in the base material Step, characterized in that it comprises the step of heat treatment to the dispersion-treated solution.

Patent Document 0003 is intended to provide a case for electronic devices and a battery case equipped with a composite material for electromagnetic wave shielding that is lightweight, has excellent electromagnetic wave shielding properties, and has high rigidity, and an electromagnetic wave shielding material composed of the composite material for electromagnetic wave shielding, carbon fiber. And in the composite material for electromagnetic wave shielding in which a fiber-reinforced resin molded body portion containing a matrix resin and a metal layer portion are laminated, the fiber-reinforced resin molded body portion contains carbon fibers having a weight average fiber length of 0.5 to 100 mm in a randomly dispersed state of 20 to 80 % by weight, characterized in that the thickness of the metal layer portion is 0.02 ~ 2 mm. Although there is an advantage of providing a lightweight composite material for electromagnetic wave shielding, there is a possibility that the metal layer portion may be peeled off.

KR10-2011-0053058A (2011.05.19) KR10-0744517B1 (2007.07.25) JP 6003010 B2 (2016.09.16)

The present invention for solving such conventional problems is an electromagnetic wave shielding function composite material capable of manufacturing an electromagnetic wave shielding function composite material with improved quality such as excellent electromagnetic wave shielding of low and high frequency bands and no layer separation after molding. Its purpose is to provide a manufacturing method.

The present invention for achieving the above object,

preparing a laminated material by sequentially laminating carbon fiber fabric/glass mat/conductive metal thin film/glass mat/carbon fiber fabric;

a backstitch step of backstitching the laminated material;

cutting the sewn laminated material into a predetermined shape;

After the cut laminated material is placed in the cavity of the hard lower mold, the upper mold made of silicon is molded, and the impregnating resin is injected through the resin inlet of the upper mold while internal air is sucked through the vacuum inlet of the upper mold. A resin injection step of injecting;

After the impregnation resin impregnated in the laminated material is cured, demolding the upper mold;

Preferably, the conductive metal thin film is made of an aluminum thin film. In particular, the conductive metal thin film is preferably made of an embossed aluminum thin film.

In addition, the upper mold made of silicon is provided with one or more annular grooves formed on the bottom surface of the rim and a suction port formed to communicate with the annular groove,

After the upper mold made of silicon is seated on the lower mold, it is preferable to inhale internal air through the inlet to keep the upper mold made of silicon airtight with the hard lower mold and then mold the mold.

The impregnation resin may be composed of an unsaturated polyester resin, a curing agent and an accelerator.

In addition, the present invention provides a composite material with electromagnetic shielding function characterized in that it is manufactured by the above manufacturing method.

The manufacturing method of the electromagnetic shielding function composite material of the present invention is excellent in shielding electromagnetic waves in the low and high frequency bands because the carbon fiber fabric and the conductive metal thin film are laminated, and the laminated material is impregnated with the impregnation material after stitching, so that the electromagnetic wave in the harmonic band is impregnated. There is an effect of manufacturing a composite material with improved electromagnetic wave shielding function, such as that the conductive metal thin film for shielding does not separate the layers.

1 is a flowchart schematically showing a manufacturing method of a composite material with electromagnetic shielding function according to the present invention.
2 is a longitudinal cross-sectional view schematically showing a cross-sectional state of a laminated material.
3 is a perspective view schematically showing a conductive metal thin film.
4 is a perspective view schematically showing a sewn laminated material.
5 is a cross-sectional view schematically showing a state in which an upper mold made of silicon is combined on a lower mold in which a sewn laminated material is seated.

Hereinafter, the manufacturing method of the electromagnetic shielding function composite material of the present invention will be described in detail with examples as follows, and the scope of the present invention is not limited to the following examples.

1 is a flowchart schematically showing a manufacturing method of a composite material having electromagnetic wave shielding function according to the present invention.

As shown in FIG. 1, the manufacturing method of the electromagnetic shielding function composite material of the present invention largely includes a laminated material preparation step, a stitching step, a cutting step, a resin injection step, and a mold release step.

2 is a longitudinal cross-sectional view schematically showing a cross-sectional state of a laminated material, and FIG. 3 is a perspective view schematically showing a conductive metal thin film 13.

First, in the step of preparing the laminated material, the laminated material 10 is formed by sequentially stacking the carbon fiber fabric 11/glass mat 12/conductive metal thin film 13/glass mat 14/carbon fiber fabric 15 is the stage of preparation for

The carbon fiber fabrics 11 and 15 are for shielding electromagnetic waves in a low frequency band and improving physical properties such as strength. The wefts and warps of the carbon fiber fabrics 11 and 15 are a plurality of carbon fiber bundles spread-processed so that the impregnated resin can be smoothly impregnated between the carbon fibers of the carbon fiber fabrics 11 and 15 during the resin injection step. It is preferable to be made of a group of carbon fibers.

The glass mats 12 and 14 are used to give a sense of volume according to the thickness of the composite material and to reinforce physical properties such as strength.

3 is a perspective view schematically showing a conductive metal thin film.

The conductive metal thin film 13 interposed between the glass mats 12 and 14 is for shielding electromagnetic waves in a high frequency band and is made of an aluminum thin film or the like.

The conductive metal thin film 13 is made of an embossed aluminum thin film, etc., as shown in FIG. 3, in order to improve the adhesion strength with the glass mats 12 and 14 when the impregnation resin is injected and cured in the resin injection step. good night.

Next, the stitching step is a step of stitching (17) the laminated material 10 by improving the bonding strength of the laminated material 10 prepared in the laminated material preparation step.

As the laminated material 10 is stitched 17 by filament yarn, the resin injection step injects the impregnation resin and then cures the material between the materials of the composite material, particularly the conductive metal thin film 13 and the glass mat 12. , 14), it is possible to prevent layer separation between layers, and there is an advantage in that handling of the laminated material 10 is improved during the cutting step.

And the cutting step is a step of cutting the laminated material 10 according to the shape of a product to be manufactured using a composite material. The cutting step is not greatly limited, such that the laminated material 10 can be cut by an existing cutting method, such as cutting using a laser cutting device.

Next, in the resin injection step, the cut laminated material 10 is seated in the cavity 310 of the hard lower mold 30, and then the upper mold 50 made of silicon is molded, and the upper mold 50 This is a step of injecting the impregnation resin into the resin inlet 530 of the upper mold 50 in a state in which internal air is sucked through the vacuum inlet 520 of ).

After the cut laminated material 10 is seated in the cavity 310 of the lower mold 30 of hard metal, etc., the upper mold 50 made of silicon is seated on the lower mold 30 .

The upper mold 50 made of silicon is provided with one or more annular grooves 510 formed on a lower surface of the rim and a suction port 512 formed to communicate with the annular groove 510 .

After the upper mold 50 made of silicon is seated on the hard lower mold 30, internal air is sucked through the inlet 512 to move the upper mold 50 made of silicon into the hard lower mold. It is better to keep the confidentiality in (30) and combine it.

After the upper mold 50 made of silicon is molded to the lower mold 30, the air in the cavity 310 of the lower mold 30 is sucked through the vacuum inlet 520 of the upper mold 50. maintain negative pressure. In addition, the impregnation resin is injected through the resin inlet 530 of the silicon upper mold 50 to impregnate the cut laminated material 10 with the impregnation resin.

The impregnation resin may use a thermosetting resin, but a room temperature curing resin capable of being cured at room temperature may be used. The room temperature curing resin consists of an unsaturated polyester resin, a curing agent and an accelerator.

The demolding step is a step of demolding the upper mold 50 after the impregnation resin impregnated in the laminated material 10 is cured.

As the impregnation resin impregnated in the layered material 10 is cured, the electromagnetic wave shielding function composite material is completed, and after the electromagnetic wave shielding function composite material is completed, the upper mold 50 is demolded.

As described above, the manufactured composite material with electromagnetic wave shielding function has excellent electromagnetic wave shielding in the low and high frequency bands because the carbon fiber fabrics 11 and 15 and the conductive metal thin film 13 are laminated, and the laminated material 10 has a stitching ( 17) By impregnating the post-impregnation material, there is an advantage in that the conductive metal thin film 13 for electromagnetic wave shielding in the harmonic band is not separated, and the quality is excellent.

10: laminated material,
11, 15: carbon fiber fabric,
12,14: glass mat
13: conductive metal thin film
30: lower mold,
50: upper mold

Claims (6)

preparing a laminated material by sequentially laminating carbon fiber fabric/glass mat/conductive metal thin film/glass mat/carbon fiber fabric;
a backstitching step of stitching the laminated material with filament yarn in order to improve the bonding force of the laminated material, prevent layer separation between the conductive metal thin film and the glass mat, and improve handling of the laminated material;
cutting the sewn laminated material into a predetermined shape;
After the cut laminated material is placed in the cavity of the hard lower mold, the upper mold made of silicon is molded, and the impregnating resin is injected through the resin inlet of the upper mold while internal air is sucked through the vacuum inlet of the upper mold. A resin injection step of injecting;
Including; demolding the upper mold after the impregnation resin impregnated in the laminated material is cured;
The wefts and warps of the carbon fiber fabric for shielding electromagnetic waves in the low frequency band and improving physical properties are processed by spreading the carbon fiber bundles so that the impregnation resin can be smoothly impregnated between the carbon fibers of the carbon fiber fabric during the resin injection step. It consists of a plurality of carbon fiber groups,
The conductive metal thin film interposed between the glass mats is made of an embossed aluminum thin film in order to shield electromagnetic waves in a high frequency band and to improve adhesion strength with the glass mat when curing after injecting an impregnation resin by the resin injection step, ,
The upper mold made of silicon is provided with one or more annular grooves formed on a bottom surface of the rim and a suction port formed to communicate with the annular groove,
After the upper mold made of silicon is seated on the lower mold, air is sucked in through the inlet to keep the upper mold made of silicon airtight with the lower mold and combined with the hard lower mold.
After the upper mold made of silicon is molded into the lower mold, the air in the cavity of the lower mold is sucked in through the vacuum inlet of the upper mold to maintain a negative pressure state, and the impregnated resin is supplied through the resin inlet of the upper mold made of silicon. A method of manufacturing an electromagnetic wave shielding function composite material, characterized in that by injecting an impregnation resin into the cut laminated material.
According to claim 1,
The impregnating resin is a method for producing an electromagnetic shielding function composite material, characterized in that consisting of an unsaturated polyester resin, a curing agent and an accelerator.
An electromagnetic wave shielding composite material characterized in that it is manufactured by the method of manufacturing the electromagnetic wave shielding composite material of claim 1 or 2. delete delete delete

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