The purpose of the present invention is to provide a sandwich structure that has both excellent heat dissipation properties and excellent mechanical properties. In order to achieve this purpose, the sandwich structure of the present invention has the following structure. The sandwich structure includes a core member (I), and a fiber reinforced member (II) disposed on both sides of the core member (I), wherein the core member (I) includes a sheet-shaped heat conductive member (III) having an in-plane thermal conductivity of 300 W/m.K or more.

Provided is a method for manufacturing a fiber reinforced resin molded article capable of effectively reducing the occurrence of a preform with poor resin impregnation, and such a manufacturing device thereof. After it is detected that a predetermined amount (the same amount) of resin has been individually poured into a plurality of cavities provided in a mold, the fiber layers of preforms are impregnated (compressively filled) with resin. Pressure sensors for detecting a resin injection amount are used. When closing runners, a small gap is formed in the runners.

The purpose of the present invention is to provide a thermal conductor achieving both excellent light weight and excellent rigidity and also having excellent heat dissipation property. In order to achieve the above object, the thermal conductor according to the present invention has the following configuration. That is, a thermal conductor in which a sheet-shaped thermal conductive material (II) having an in-plane thermal conductivity of 300 W/m.Math.K or more is contained in a porous structure (I) configured of reinforcing fibers and a resin.

A band or belt designed as an elongate bearing, traction or drive element running around rollers or pulleys and made of an elastomer material, and preferably provided with embedded reinforcing elements or tension members extending in the longitudinal direction of the band or belt, having the following features: the band or the belt has one or more elongate tubular receptacles embedded in the elastomer material, in the cavity of which electronic components are arranged, preferably sensors, signal processing or control devices and/or transmission devices, the tubular receptacles are embedded in the elastomer material in such a way that their longitudinal axis or the direction of their greatest extent is oriented substantially transversely to the main bending direction of the band or belt.

Disclosed herein is a method of manufacturing heating elements for vehicle interior materials, which includes forming a base part having the same shape as a curved surface of a subject, forming an electrode part on an upper surface of the base part, and stacking a heating part on upper surfaces of the base part and electrode part. Accordingly, the heating element is manufactured in advance to have the same shape as the curved surface of the subject and then adhered to the subject so that the heating element is overlapped on and pressed against the subject without deformation. Thus, it is possible to make overall temperature distribution uniform and improve product quality.

In an embodiment a sensor includes a sensor element, a connecting element configured for electrical connection and a housing located on the sensor element, wherein the housing comprises a housing material with cured liquid silicone rubber (LSR) as a main component.

The subject of the invention is a support panel with cellular core structure and the manufacturing process for the support panel with cellular core structure which solve the technical problems of: facilitating the manufacture of the product, ensuring compactness of individual panels and manufacturing support panels with cellular structure (1) in a single step. The support plate with cellular structure (1) comprises at least the upper solid surface (2), the lower solid surface (3) and the cellular structure (4), whereby all of these components are made of any thermoplastic material; however, all of the components are made of the same material. The cellular structure (4) is constructed with energy directors (5) to prevent spacing between the cellular structure (4), the upper solid surface (2) and the lower solid surface (3). The pre-formed cellular core (4) is placed on the levelled thermoplastic material used to form the lower solid surface, after which the material is applied over the cellular core (4) up to the depth required to form the lateral surfaces and the upper solid surface (2). After heating and pressing the material, the support panel with cellular structure (1) is cooled under pressure, and then it is removed from the press mould.

A component comprising a sheet-like reinforcing component having a first stiffness and a sheet-like attachment made of an attachment material having a second stiffness, wherein the first stiffness is higher than the second stiffness, wherein the planar reinforcing component has an upper and lower side and the attachment is connected at least to the upper or lower side of the planar reinforcing component in a first partial area of the planar reinforcing component.

A tableted epoxy resin composition for encapsulation of semiconductor devices and a semiconductor device encapsulated using the tableted epoxy resin composition, the tableted epoxy resin composition satisfying the following conditions (i) a proportion of tablets of the tableted epoxy resin composition having a diameter of greater than or equal to 0.1 mm and less than 2.8 mm and a height of greater than or equal to 0.1 mm and less than 2.8 mm is about 97 wt % or more, as measured by sieve analysis using ASTM standard sieves; (ii) the tablets have a packed density of greater than about 1.7 g/mL; and (iii) a ratio of packed density to cured density of the tablets is about 0.6 to about 0.87.

The present invention is directed to a method of forming plurality of golf balls comprising steps of: providing plurality of inner cores; forming sheet of uncured rubber; forming plurality of preps in the sheet of uncured rubber such that each prep contains a concave top surface and is detachably connected to coupling material; loading the preps and coupling material into a core mold; loading plurality of inner cores into mold such that the inner cores are aligned with the concave surface of each prep; molding the preps about the inner cores to form outer core layers; and forming covers about outer core layers.