The present application relates to a decorative member including a color developing layer including a light reflective layer and a light absorbing layer provided on the light reflective layer; and a substrate provided on one surface of the color developing layer, wherein the light absorbing layer includes a copper oxide (Cu.sub.aO.sub.x).

The present application relates to a decorative member including a color developing layer including a light reflective layer and a light absorbing layer provided on the light reflective layer; and a substrate provided on one surface of the color developing layer, wherein the light absorbing layer includes a copper oxide (Cu.sub.aO.sub.x).

Provided is a conductive composition for molded film that enables production of a molded film for which tensile force-induced reductions in conductivity are suppressed. The conductive composition for molded film contains a resin (A), conductive fine particles (B), and a solvent (C), wherein the solvent (C) contains, in 100 parts by mass of the solvent (C), at least 40 parts by mass of a solvent (C) that satisfies the following condition (1) and condition (2). (1) A boiling point of 180 C. to 270 C. (2) At least one of the following is satisfied: the polar parameter p of the Hansen solubility parameter (HSP) is 0p5.0, and the hydrogen-bond parameter h of the Hansen solubility parameter (HSP) is 9.8h4.0.

A method for manufacturing an integrated multilayer structure for sensing applications, including obtaining at least one film including a sensing area; arranging the at least one film with reactance sensing electronics for sensing of one or more selected target quantities or qualities and conversion thereof into representative electrical signals, said sensing electronics including at least one sensing element and an electrical connection configured to connect the sensing element to an associated control circuitry; and molding or casting, and configuring, at least one plastic layer so that the plastic layer defines an integrated, intermediate layer between the sensing electronics and the sensing area and that the sensing area is superimposed with the sensing element of the sensing electronics, wherein it is further provided at least one physical feature to locally reduce the electrical distance between the sensing area and the sensing element to improve the associated sensing sensitivity.

The present application relates to a decoration member including a substrate layer having a convex structure or a concave structure arranged two-dimensionally, and a method for preparing the decoration member.

A present application relates to a dispensing component for use with an urn liner. The dispensing component includes a spout formed of a polyethylene material and a flexible tube formed of a thermoplastic elastomer material. The spout and tube are formed together as a single component in a mold by co-injection of the polyethylene material and the thermoplastic elastomer material.

The purpose of the present invention is to provide a transfer sheet capable of providing hard coat properties and excellent weather resistance to a resin molded article such as organic glass. The transfer sheet has, in order, a base material film for mold release, a hard coat layer, a primer layer, and an adhesive layer. The weather resistance and adhesiveness of the hard coat layer and the primer layer are improved and hard coat properties and excellent weather resistance can be provided to a resin molded article being the transfer object, as a result of: the hard coat layer being formed from a cured product of a resin composition including a curable resin; and the primer layer being formed from a binder resin including a polyurethane having a mass-average molecular weight of 40,000-100,000 and including 1-30% by mass of an acrylic component.

A system for a vehicle comprises a body component of the vehicle that is formed of a microcellular foam and optionally having one or more decorative layers applied thereto and a radar device arranged behind the body component and configured to transmit/receive radar waves therethrough. A method of manufacturing a body component of a vehicle comprises obtaining a molten resin, introducing a gas or a chemical foaming agent into the molten resin to form a microcellular foam, injecting molding the microcellular foam by injecting the microcellular foam into a mold to form the body component, removing the body component from the mold, optionally applying one or more decorative layers to the body component, and arranging the body component in front of a radar device of the vehicle.

A final injection molded assembly and process for making same that eliminates paint and reduces areas of wasted chrome material. The final injection molded assembly has at least one first injection molded part of a non-plateable first material, at least one overmolded part of plateable second material, at least one pathway through the assembly and integrated features operable for selectively applying an electric current. The pathway creates a predetermined surface path arrangement for applying chrome to desired predetermined plateable areas. A shot of each material is delivered to an injection molding rotary device to produce the injection molded assembly which is then affixed to a chroming process line where electric current is applied. As the electric current is applied and chrome is delivered only the plateable second material will accept the chrome.

The invention relates to a component (1) comprising a planar decorative element (4) with a front side (5) and a rear side (6). A cover layer (9, 10) is arranged on each of at least two regions of the front side (5) of the planar decorative element (4), these at least two cover layers (9, 10) being spaced completely apart from one another, and said at least two cover layers (9, 10) and at least one region (12, 14) of the front side (5) of the planar decorative element (4) together forming a visible side (2) of the component (1).