KR101352944B1 - EMI Shielding Material and Method of manufacturing - Google Patents

Abstract

The present invention relates to a material having an elastic porous sheet-like electromagnetic noise shielding performance and a method of manufacturing the same, and more particularly, at least one surface of an elastic porous body having an independent bubble ratio of 80% or more in an elastic porous body having independent bubbles and continuous bubbles. Alternatively, a fibrous resin is bonded to the inside to prepare a composite of the fibrous elastic porous body, perforated in the thickness direction to form a through hole, and wet plating is applied to both surfaces and the through hole surface of the fibrous porous porous composite to impart electrical conductivity. It is to provide a sheet-shaped electromagnetic shielding material to be formed. The porous porous sheet-type electromagnetic shielding material manufactured by the present invention has not only excellent electromagnetic shielding properties but also excellent ductility and excellent compression recovery rate, and can block electromagnetic waves generated from electronic devices or measuring devices or unwanted electromagnetic waves penetrating from the outside. Can be.

Electromagnetic shielding, elasticity, porous body, perforation, wet plating, electroless plating, electroplating

Description

EMI Shielding Material and Method of manufacturing

Electromagnetic shielding technology

The present invention relates to a method for manufacturing an electromagnetic shielding elastic porous sheet, and more particularly, in the elastic porous body having an independent bubble and a continuous bubble, to provide a sheet-type electromagnetic shielding material which is formed elastically in which the ratio of the independent bubble is 80% or more. Electromagnetic

It is used to prevent electromagnetic interference (EMI) generated from electromagnetic waves or static electricity, and it is easy to adjust the resistance value of the sheet without obtaining any kind of porous synthetic resin, and to obtain uniform conductivity. The present invention relates to a method for manufacturing an electromagnetic shielding elastic porous sheet capable of effectively shielding electromagnetic waves of frequency.

In the face of the highly information society, various electronic devices are pursuing high integration and high precision with various functions, speed, and portability, and especially the electromagnetic waves generated from the internal RF circuit of portable electronic device products such as mobile communication terminals. It causes internal interference due to resonance through multiple reflections within the product, and deteriorates product quality due to deterioration of device performance and mechanical malfunction. In addition, malfunctions of other precision electronic devices (medical devices, aircraft precision instruments, etc.) when electromagnetic waves leak out of the electronic devices.

Providing a direct cause of the problem and further raising controversy over body harm in recent years, the shielding measures have been urgently requested.

Moreover, these telecommunication devices are becoming high performance, miniaturized, and lightweight through high integration, and the high integration of electric circuits increases the possibility of adverse effects of external devices due to electromagnetic leakage and threats of external radio noise. Therefore, electromagnetic interference has emerged as a serious problem, and researches on electromagnetic shielding to solve this problem are actively underway. Conventionally, there were conductive silicone gaskets and conductive shielding products to shield electromagnetic waves and static electricity generated from seams and openings of electronic devices, and shielding electromagnetic waves and static electricity by providing conductivity to cushions that support the LCD screen of digital devices. There was an example.

Since the cushion supporting the gasket or the LCD screen must basically have a certain thickness, it must satisfy both cushioning, moldability, and barrier to the external environment. Thus, porous synthetic materials such as general sponge, EPDM or polyurethane foam, etc.

Resin, rubber, silicone, etc. are used, but in order to impart conductivity to these kinds of materials, it is expensive to provide conductivity such as mixing, coating, and plating conductive metal components, and the process is complicated. There is a problem that the productivity is lowered.

In order to impart conductivity to the non-conductive porous synthetic resin, a plating method is generally used. There are many environmental and human hazards in this process, and there are risks in operation, and the conductive layer may be detached. Another method is casting to a porous synthetic resin (Casting), but in this case there is a problem that the physical properties are poor. Looking at the patent (utility model) document, Korean Utility Model Registration No. 264092 discloses an electromagnetic shielding material in which a conductive porous elastic material is impregnated in a liquid conductive resin, and a conductive resin is applied and cured on the inner and outer surfaces of the elastic material. There is a bar. In addition, Korean Patent Laid-Open Publication No. 2002-83189 discloses a lightweight composite material in which a polyurethane foam is deposited with a mixture consisting of a carbon material such as conductive carbon, activated carbon, and charcoal, an impregnated reagent such as potassium phosphate, and a water glass-based binder. have.

However, simply impregnating the conductive solution in the porous material as described above makes it difficult to constantly adjust the amount of the conductive liquid applied, making it difficult to manufacture a sheet having uniform physical properties, and it is inexpensive to use more materials than necessary. There was a problem such as loss.

According to the present invention, the elastic porous sheet-type electromagnetic shielding material to be manufactured can block electromagnetic waves generated from electronic devices or measuring devices, or unwanted electromagnetic waves from outside, while having excellent electromagnetic shielding properties as well as excellent ductility and excellent compression recovery rate. To provide a sheet-shaped electromagnetic shielding material and a method of manufacturing the elastic foam so that the ratio of the independent bubble is 80% or more.

The present invention has been proposed in view of the limitations of the prior art, and in order to impart conductivity to the non-conductive porous synthetic resin material, in the elastic porous body having an independent bubble and a continuous bubble, a sheet-shaped electromagnetic wave elastically formed having an independent bubble ratio of 80% or more. It is an object to provide a shielding material and a method of manufacturing the same.

The present invention provides a sheet-shaped electromagnetic shielding material that is elastically formed in an elastic porous body having independent bubbles and continuous bubbles with a ratio of 80% or more of independent bubbles, so that electromagnetic interference generated from electromagnetic waves or electromagnetic interference generated by static electricity It is used for the prevention of EMI, and it is easy to adjust the resistance value of the sheet without regard to the type of porous synthetic resin, and it is possible to obtain uniform conductivity and effectively shield the electromagnetic wave of broadband frequency.

In the present invention, in the elastic porous body having independent bubbles and continuous bubbles, a fibrous resin is bonded to at least one surface or the inside of the elastic porous body having a ratio of 80% or more independent bubbles to prepare a composite of the fibrous elastic porous body, and then punched in the thickness direction. In the method of manufacturing the electromagnetic shielding material is formed by forming a through-hole, wet plating on both surfaces and the through-hole surface of the fibrous porous porous composite to impart electrical conductivity, the manufacturing method is a low concentration of alkali degreasing solution or acid Immersing in degreasing solution to ultrasonic cleaning; Dipping in a surface conditioner liquid containing a nonionic surfactant or a cationic surfactant to adjust the surface of the elastic porous body and the surface of the through-hole surface in a state where palladium catalyst and metal ions are easily adsorbed; Adsorbing a palladium catalyst; Electroless nickel plating process; Electroless copper plating process; And a final corrosion-resistant metal plating process.

The manufacturing method of the electromagnetic shielding elastic porous sheet of the present invention is characterized in that the polymer resin thin film is further applied after the final corrosion-resistant metal plating process. In the method for producing an electromagnetic shielding elastic porous sheet of the present invention, the polymer resin thin film is characterized in that it contains any one or more selected from the group consisting of metal oxides, metal hydroxides, bromines, and phosphorus flame retardants.

The present invention relates to an electromagnetic shielding gasket, which is formed by further applying an adhesive to the end face of the electromagnetic shielding elastic porous sheet manufactured by the method for manufacturing the electromagnetic shielding elastic porous sheet. In the electromagnetic shielding gasket of the present invention, the pressure-sensitive adhesive material is made of any one selected from conductive metal powder, conductive fiber, and conductive polymer, or a conductive pressure-sensitive adhesive material is formed by mixing conductive metal powder, conductive fiber, and conductive polymer. In the electromagnetic shielding gasket of the present invention, the pressure-sensitive adhesive contains at least one flame retardant selected from the group consisting of metal oxides, metal hydroxides, bromines, and phosphoruss.

In the present invention, in the porous porous body having independent bubbles and continuous bubbles, an elastic porous body having an independent bubble ratio of 80% or more is punched in the thickness direction to form a through hole, and the fibrous resin is bonded to at least one surface of the elastic porous body. In the manufacturing method of the electromagnetic wave shielding material which is formed by imparting electrical conductivity by wet plating on both surfaces and through hole surfaces of the fibrous porous porous composite after the composite of the porous body, the manufacturing method is a low concentration alkali degreasing solution Or ultrasonically washing by dipping in an acidic degreasing solution; Dipping in a surface conditioner liquid containing a nonionic surfactant or a cationic surfactant to adjust the surface of the elastic porous body and the surface of the through-hole surface in a state where palladium catalyst and metal ions are easily adsorbed; Adsorbing a palladium catalyst; Electroless nickel plating process; Electroless copper plating process; And a final corrosion-resistant metal plating process.

The manufacturing method of the electromagnetic shielding elastic porous sheet of the present invention is characterized in that the polymer resin thin film is further applied after the final corrosion-resistant metal plating process. In the method for producing an electromagnetic shielding elastic porous sheet of the present invention, the polymer resin thin film is characterized in that it contains any one or more selected from the group consisting of metal oxides, metal hydroxides, bromines, and phosphorus flame retardants.

The present invention relates to an electromagnetic shielding gasket, which is formed by further applying an adhesive to the end face of the electromagnetic shielding elastic porous sheet manufactured by the method for manufacturing the electromagnetic shielding elastic porous sheet. In the electromagnetic shielding gasket of the present invention, the pressure-sensitive adhesive material is made of any one selected from conductive metal powder, conductive fiber, and conductive polymer, or a conductive pressure-sensitive adhesive material is formed by mixing conductive metal powder, conductive fiber, and conductive polymer. In the electromagnetic shielding gasket of the present invention, the pressure-sensitive adhesive contains at least one flame retardant selected from the group consisting of metal oxides, metal hydroxides, bromines, and phosphoruss.

According to the present invention, in an elastic porous body having independent bubbles and continuous bubbles, an elastic porous body having an independent bubble ratio of 80% or more is punched in the thickness direction to form a through hole, and is immersed in an alkaline degreasing solution or an acidic degreasing solution to ultrasonic wave. Washing process; Dipping in a surface conditioner liquid containing a nonionic surfactant or a cationic surfactant to adjust the surface of the elastic porous body and the surface of the through-hole surface in a state where palladium catalyst and metal ions are easily adsorbed; Adsorbing a palladium catalyst; Electroless nickel plating process; Electroless copper plating process; And forming a conductive elastic porous body by wet plating both surfaces and through-hole surfaces of the elastic porous body in a process consisting of a final corrosion-resistant metal plating process to impart electrical conductivity, and then bonding conductive fibers to at least one surface of the conductive elastic porous body. To produce a composite of a conductive fiber elastic porous body.

The manufacturing method of the electromagnetic shielding elastic porous sheet of the present invention is characterized in that the polymer resin thin film is further applied after the final corrosion-resistant metal plating process. In the method for producing an electromagnetic shielding elastic porous sheet of the present invention, the polymer resin thin film is characterized in that it contains any one or more selected from the group consisting of metal oxides, metal hydroxides, bromines, and phosphorus flame retardants.

The present invention relates to an electromagnetic shielding gasket, which is formed by further applying an adhesive to the end face of the electromagnetic shielding elastic porous sheet manufactured by the method for manufacturing an electromagnetic shielding elastic porous sheet. In the electromagnetic shielding gasket of the present invention, the pressure-sensitive adhesive material is made of any one selected from conductive metal powder, conductive fiber, and conductive polymer, or a conductive pressure-sensitive adhesive material is formed by mixing conductive metal powder, conductive fiber, and conductive polymer. In the electromagnetic shielding gasket of the present invention, the pressure-sensitive adhesive contains at least one flame retardant selected from the group consisting of metal oxides, metal hydroxides, bromines, and phosphoruss.

The porous porous sheet-type electromagnetic shielding material manufactured by the present invention has not only excellent electromagnetic shielding properties but also excellent ductility and excellent compression recovery rate, and can block electromagnetic waves generated from electronic devices or measuring devices or unwanted electromagnetic waves penetrating from the outside. Can be.

Claims (18)

In the elastic porous body having independent bubbles and continuous bubbles, a fibrous resin is bonded to at least one surface or the inside of the elastic porous body having a ratio of 80% or more independent bubbles to prepare a composite of the fibrous elastic porous body, and then perforated in the thickness direction. The method for producing an electromagnetic shielding material which is formed by imparting electrical conductivity by wet plating on both surfaces and through hole surfaces of the fibrous porous body composite, wherein the production method is a low concentration alkali degreasing solution or an acidic degreasing solution. Dipping and ultrasonic cleaning; Dipping in a surface conditioner liquid containing a nonionic surfactant or a cationic surfactant to adjust the surface of the elastic porous body and the surface of the through-hole surface in a state where palladium catalyst and metal ions are easily adsorbed; Adsorbing a palladium catalyst; Electroless nickel plating process; Electroless copper plating process; And final corrosion resistant metal plating process, In the manufacturing method, the polymer resin thin film is applied again after the final corrosion-resistant metal plating process, The polymer resin thin film contains any one or more selected from the group consisting of metal oxide-based, metal hydroxide-based, bromine-based and phosphorus-based flame retardants, An adhesive material is applied to the end face of the prepared electromagnetic shielding elastic porous sheet, The pressure-sensitive adhesive material is made of any one selected from conductive metal powder, conductive fiber and conductive polymer or a conductive adhesive material is formed by mixing conductive metal powder, conductive fiber and conductive polymer, The adhesive material is an electromagnetic shielding gasket, characterized in that it contains any one or more flame retardants selected from the group consisting of metal oxides, metal hydroxides, bromine-based and phosphorus-based. In an elastic porous body having independent bubbles and continuous bubbles, a porous porous body having an independent bubble ratio of 80% or more is formed in the thickness direction to form a through hole, and a fibrous resin is bonded to at least one surface of the elastic porous body to form a composite of a fiber elastic porous body. In the manufacturing method of the electromagnetic shielding material is formed by imparting electrical conductivity by wet plating on both the surface and the through-hole surface of the fibrous porous porous composite after the production, the manufacturing method is a low concentration alkali degreasing solution or acidic degreasing Immersing in the liquid and ultrasonic cleaning; Dipping in a surface conditioner liquid containing a nonionic surfactant or a cationic surfactant to adjust the surface of the elastic porous body and the surface of the through-hole surface in a state where palladium catalyst and metal ions are easily adsorbed; Adsorbing a palladium catalyst; Electroless nickel plating process; Electroless copper plating process; And final corrosion resistant metal plating process, In the manufacturing method, the polymer resin thin film is applied again after the final corrosion-resistant metal plating process, The polymer resin thin film contains any one or more selected from the group consisting of metal oxides, metal hydroxides, bromine and phosphorus flame retardants, An adhesive material is applied to the end face of the prepared electromagnetic shielding elastic porous sheet, The pressure-sensitive adhesive material is made of any one selected from conductive metal powder, conductive fiber and conductive polymer or a conductive adhesive material is formed by mixing conductive metal powder, conductive fiber and conductive polymer, The adhesive material is an electromagnetic shielding gasket, characterized in that it contains any one or more flame retardants selected from the group consisting of metal oxides, metal hydroxides, bromine-based and phosphorus-based. In an elastic porous body having independent bubbles and continuous bubbles, the porous porous body having an independent bubble ratio of 80% or more is formed in the thickness direction to form a through hole, and is immersed in an alkaline degreasing solution or an acidic degreasing solution and ultrasonically cleaned. ; Dipping in a surface conditioner liquid containing a nonionic surfactant or a cationic surfactant to adjust the surface of the elastic porous body and the surface of the through-hole surface in a state where palladium catalyst and metal ions are easily adsorbed; Adsorbing a palladium catalyst; Electroless nickel plating process; Electroless copper plating process; And forming a conductive elastic porous body by wet plating on both surfaces and through-hole surfaces of the elastic porous body in a process consisting of a final corrosion-resistant metal plating process to impart electrical conductivity, and then bonding conductive fibers to at least one surface of the conductive elastic porous body. To produce a composite of a conductive fiber elastic porous body, After the final corrosion-resistant metal plating process, the polymer resin thin film is applied again, The polymer resin thin film contains any one or more selected from the group consisting of metal oxide-based, metal hydroxide-based, bromine-based and phosphorus-based flame retardants, An adhesive material is applied to the end face of the prepared electromagnetic shielding elastic porous sheet, The pressure-sensitive adhesive material is made of any one selected from a conductive metal powder, a conductive fiber and a conductive polymer or a conductive adhesive material is formed by mixing the conductive metal powder, the conductive fiber and the conductive polymer, The adhesive material is an electromagnetic shielding gasket, characterized in that it contains any one or more flame retardants selected from the group consisting of metal oxides, metal hydroxides, bromine-based and phosphorus-based. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete