Provided is an adsorption temporary fixing sheet having a sufficient shear adhesive strength in a direction parallel to its surface, having a weak adhesive strength in a direction vertical to the surface, and having excellent antistatic performance. The adsorption temporary fixing sheet includes a foam layer including an open-cell structure, and has a surface resistivity of from 1.0×10.sup.4 to 1.0×10.sup.10Ω/□, wherein, when a silicon chip vertical adhesive strength of a surface of the foam layer after 18 hours at each of such different temperatures as −30° C., 23° C., or 80° C. is represented by V1, V2, or V3 (N/1 cm.sup.2), and when a silicon chip shearing adhesive strength of the surface of the foam layer after 18 hours at each of such different temperatures as −30° C., 23° C., or 80° C. is represented by H1, H2, or H3 (N/1 cm□), relationships of V1<H1, V2<H2, and V3<H3 are satisfied.

A method of manufacturing a liquid crystal polymer film, which includes the following operations: providing a liquid crystal polymer powder; uniformly dispersing the liquid crystal polymer powder in a solvent to form a mixed solution; coating the mixed solution on a carrier board to form a coating layer; heating the coating layer to a first temperature to remove the solvent in the coating layer; heating the liquid crystal polymer powder to a second temperature after the solvent is removed to form the liquid crystal polymer film.

The present invention discloses a power-generating insole based on fabric integration, which comprises a power-generating insole body, a detachable outer layer and an electronic module; The power-generating insole comprises a first friction component, a second friction component and a fabric composite component; The first friction component is composed of a first electrode layer and a first polymer material; The first friction component and the fabric composite component are integrally formed; The second friction component is wrapped around the middle part of the fabric composite component, and is integrated with the first friction component and the fabric composite component; The detachable outer layer is wrapped on the surface of the power-generating insole body; The electronic module is connected to the power-generating insole body; The present invention has long service life, good flexibility, plasticity, is washing resistance and stability.

A laminated glass according to the present invention includes a first glass plate, a second glass plate, and an interlayer film. The interlayer film includes a laminated region including a first layer that is in contact with the first glass plate, a second layer that is in contact with the second glass plate, and a third layer disposed between the first layer and the second layer. When the relative dielectric constant of the first glass plate is denoted by ε.sub.g1, the relative dielectric constant of the second glass plate is denoted by ε.sub.g2, the relative dielectric constant of the first layer is denoted by ε.sub.m1, the relative dielectric constant of the second layer is denoted by ε.sub.m2, and the relative dielectric constant of the third layer is denoted by ε.sub.m3, relationships ε.sub.m1<ε.sub.g1, ε.sub.m1<ε.sub.g2, ε.sub.m2<ε.sub.g1, ε.sub.m2<ε.sub.g2, ε.sub.m3>ε.sub.m1, ε.sub.m3>ε.sub.m2 are established.

A vehicle interior panel includes a decorative layer formed from a material that blocks transmission of a range of wireless communication frequencies. Perforations are formed through the material so that the decorative layer permits wireless communication through the panel. The perforations may be formed in a pattern so that an illuminated pattern is displayed at a decorative side of the panel when backlit. The perforations can be made non-visible and enable the use of carbon fiber and other conductive materials in the decorative layer without sacrificing wireless communication capability.

One aspect of the present invention provides a light-transmitting electroconductive film 10 comprising a light-transmitting base material 11 and an electroconductive part 13 provided on one surface of the light-transmitting base material 11, wherein the electroconductive part 13 includes a light-transmitting resin 15 and plural electroconductive fibers 16 incorporated in the light-transmitting resin 15, and the electroconductive part 13 can conduct electricity from the surface 13A of the electroconductive part 13, and the electroconductive fibers 16 as a whole are unevenly distributed on the light-transmitting base material side than the position HL, which is located at half the film thickness of the electroconductive part 13 in the electroconductive part 13, and the electroconductive part 13 has a surface resistance value of 200Ω/□ or less, and the electroconductive film 10 has a haze value of 5% or less.

An interface in accordance with present embodiments includes a base and a theme portion disposed on the base. A first layer is disposed on the base and includes a mixture with metallic powder suspended within a translucent medium. A second layer is disposed on the base over the first layer and over the theme portion, and includes the mixture. A third layer is disposed on the base and on the theme portion over only portions of the second layer. The third layer includes paint and paint thinner. A fourth layer is disposed on the theme portion over the third layer and exposed portions of the second layer. The fourth layer also includes the mixture.

An anisotropic conductive film has first and second connection layers formed on a first layer surface. The first connection layer is a photopolymerized resin layer, and the second is thermo- or photo-cationically, anionically, or radically polymerizable resin layer. On the surface of the first connection layer on a second connection layer side, conductive particles for anisotropic conductive connection are in a single layer. The first connection layer has fine projections and recesses in a surface. An anisotropic conductive film of another aspect has first, second, and third connection layers layered in sequence. The first layer formed of photo-radically polymerized resin. The second and third layers are formed of thermo-cationically or thermo-anionically polymerizable resin, photo-cationically or photo-anionically polymerizable resin, thermo-radically polymerizable resin, or photo-radically polymerizable resin. On a surface of the first connection layer on a second connection layer side, conductive particles for anisotropic conductive connection are in a single layer.

The manufactured product for covering surfaces comprises a first decorative layer having a visible face and a laying face opposite to the visible face, the laying face being adapted to be turned towards a laying surface to be covered, and a second layer arranged on the laying face of the first layer and made of a magnetic material or a metal material.

A carrier tape, cover tape or static shielding bag for transportation of electronic components is constructed of polymers and carbon nanotubes being between 0.01% and 3% by weight. The carbon nanotubes may have any number of walls and any desired size of diameter dimension which is less than approximately 100 nm. The carrier tape, cover tape or bags including the carbon nanotubes have a static dissipative range measured between 1×10.sup.5 and 1×10.sup.12 Ω/sq and a light transmittance value of between 60% and 90%. The carrier tape, cover tape or bags including the carbon nanotubes reduce surface defects, high density entanglements and agglomerations. The static shielding bags including the carbon nanotubes may be formed as sheets which are manufactured into a desired size of bag.