An intermediate material of a thermoplastic prepreg for a fuel cell separation plate comprises a hydrophobic thermoplastic resin film and a fiber base. The hydrophobic thermoplastic resin film has a degree of crystallization of 1 to 20%, a thickness of 3 to 50 μm, and (iii) a content of an electroconductive material of 1 to 20 wt. %. The film is laminated on at least one surface of the fiber base. The thermoplastic prepreg for a fuel cell separation plate is manufactured by pressurizing the thermoplastic prepreg intermediate material at a temperature higher than the melting point of the hydrophobic thermoplastic resin film. A fuel cell separation membrane manufactured using the thermoplastic prepreg intermediate material and thermoplastic prepreg is thin and light-weight, and have a good durability.

An impact-resistant film comprises at least one layer of an elastomeric polymer material and an adhesive layer.

A method of manufacturing a laminate including a fabric and a thermoplastic film, wherein the thermoplastic film is a multilayer film including an adhesive layer including a thermoplastic polyester elastomer and a barrier layer that is bonded to the adhesive layer, and that has a melting point that is higher than a melting point of the adhesive layer, and that includes a polymer, and wherein the fabric includes a polyester, the method including a step of adhering a side of the multilayer film with the adhesive layer to the fabric, while heating the multilayer film at a temperature below the melting point of the barrier layer.

The invention provides a method for fabricating a spacer fabric composite having a pattern, fabricating machine and composite fabricated by method thereof. The method comprises a film forming step, a patterning step, a laminating step and a hole opening step.

A high-CTI and halogen-free epoxy resin composition for copper-clad plates and uses thereof is provided. The formula of the high-CTI and halogen-free epoxy resin composition for copper-clad plates comprises 100˜140 parts of halogen-free phosphorous epoxy resin, 10˜35 parts of dicyclopentadiene phenolic epoxy resin, 32˜60 parts of benzoxazine, 1˜5 parts of phenolic resin, 0.05˜0.5 parts of accelerants; and 25˜70 parts of fillers, by weight. The copper-clad plates, prepared according to embodiments of the present invention, can reach the requirements of high CTI (CTI≧500V), high heat resistance(Tg≧150 ° C., PCT, 2 h>6 min) and the level of flame retardance of UL-94 V0, and they are widely used in the electronic materials of electric machines, electric appliances, white goods and so on.

A method for making a yoga pad includes a step of preparing a netted base; a step of cutting the netted base into two adhesive units; a step of attaching a foam pad to the netted layer of one of the adhesive layers; and a step of adhering a towel to the C-shaped resilient members of the adhesive layer to form a yoga pad. The C-shaped resilient members are combined with the fibers on the towel in axial direction so that the foam pad is detachably connected to the towel. The fibers of the towel are engaged with the openings of the free ends of the C-shaped resilient members to provide a resistance in lateral direction to the towel which does not easily shift relative to the foam pad.

An insulated composite fabric has an inner fabric layer, an outer fabric layer, and an insulating-filler layer enclosed there between. The insulating-filler layer is a textile fabric with at least one raised surface. One side of the insulating-filler layer comprises a first surface with relatively high pile, including regions of no pile or relatively low pile interspersed among regions of relatively high pile. The other side of the insulating-filler layer comprises a second surface with relatively high pile, including regions of no pile or relatively low pile interspersed among regions of relatively high pile. Interconnecting piles are formed with regions of the relatively high pile of the first pile surface and regions of the relatively high pile of the second pile surface.

A device for preparation of double fabric for down products comprises a printing means that can print an adhesive in a predetermined printing pattern on fabric; a drying means that can dry or fix the adhesive; a laminating means that can stack and laminate the fabrics on which an adhesive is printed; and a bonding means that can bond the fabrics with a cured adhesive by pressing with a predetermined pressing means and high-frequency heating to cure the adhesive; wherein said printing pattern and the pressing pattern are the same in pattern (shape), can be overlapped on the basis of the center line and have a difference in size (width) of 20% or less. Consequently, double fabric for down products thus manufactured has an excellent adhesiveness and durability and an aesthetically excellent pattern line with good clearness and finishing quality.

A process of manufacturing a down product comprises at least one bonding pattern line for the compartment separation without forming sewing holes by printing and drying a heat-reactive adhesive on the inner surface of an inner fabric, an optional mesh material and/or an outer fabric in a predetermined pattern, laminating said inner fabric, optional mesh material and/or outer fabric, and then high-frequency heating them under pressing with a pressing pattern the same as the printing pattern to bond the inner fabric, optional mesh material and outer fabric. Accordingly, it is possible to manufacture a down product having a bonding pattern line composed of a bonding line with excellent adhesiveness and durability and an aesthetically excellent pattern line with good clearness and finishing quality as well as to achieve a mass production of down products by mechanization and automation.

The present invention relates to a laminated composite material and a method for making the same. The laminated composite material includes a 3D fabric, an adhesion layer, and a resin surface layer. The 3D fabric has a plurality of arranged fibers to form an air permeable structure. The adhesion layer is disposed on a surface of the 3D fabric. The resin surface layer is disposed on the adhesion layer, where the resin surface layer includes at least one layer formed by curing a polyurethane (PU) solution.