A heater assembly with a pre-encapsulated heating element and a method of producing the pre-encapsulated heating element are provided. The heater assembly can include a channel defining an interior space and a pre-encapsulated heating element. The pre-encapsulated heating element can include a resistive heating element having a pre-encapsulated portion that is surrounded by a block of potting compound. The pre-encapsulated portion can be received with the interior space of the channel.

The present application belongs to the field of heat conducting materials technology, and in particular, to a preparation method of a heat conducting interface material. The present application discloses a preparation method of a heat-conducting interface material, which comprises: S1, stirring and mixing; S2. orientation process: putting a mixed material obtained in the step S1 into a hydraulic injection extruder, spitting the material out through a needle nozzle and arranging the material neatly in a container in a strip shape, and after stacking the material to ½-¼ of a height of the container, vibrating the material in a vibrating compactor and repeatedly performing stacking 2-4 times; S3, vacuum compaction; S4. curing; S5. slicing.

To provide a method for manufacturing an optical element, which improves the surface precision of the optical surface as well as reducing the birefringence at a low cost. A method for manufacturing an optical element 1090A having optical surfaces 1091 and 1092 and a non-optical surface 1093A that is adjacent to the optical surface 1092 via a ridge by injection molding includes forming the non-optical surface 1093A with a mold surface. The mold surface includes a sink forming area 1095 as a first area having a first surface roughness, and a high transfer area 1094 as a second area having a second surface roughness different from the first surface roughness. The second area is located outside the first area.

A composite member and a method for manufacturing polymeric material article are presented. The method comprising providing polymeric resin, providing selected amount of filler material, mixing filler material into the polymeric matrix to provide a polymeric filler mixture, compressing said polymeric filler mixture under pressure in the range of up to 350 bar, and curing said polymeric filler mixture to provide stable polymeric material. The resulting composite member is typically characterizes by having average filler to filler particle gap below 20 nm and substantially does not have air voids therein.

A heat conductive strip having a power terminal and a method for packaging the same, wherein the heating conductive strip having a power terminal packaged by the packaging method includes: a carbon fiber unit composed of a plurality of carbon fibers and having a carbon fiber portion; a plastic sleeve covering the carbon fiber unit and having a clamping end portion that covers the carbon fiber portion; a power terminal inserted into the carbon fiber unit and including: a first metal end in electrical contact with the carbon fiber portion, and a second metal end opposite to the first metal end and exposed out of the plastic sleeve; and a fixing member sleeved on the clamping end portion of the plastic sleeve to enable the clamping end portion, the carbon fiber portion and the first metal end to be integrated into one body.

The present disclosure relates to selective laser sintering printing and thermally conductive polymers used therein. Also described are processes for forming an article using selective laser sintering techniques.

The present disclosure relates to fused filament fabrication and thermally conductive polymers used therein. Also described are processes for forming an article using fused filament fabrication techniques.

A method of forming a polyolefin-perovskite nanomaterial composite which contains oriented electrically and thermally conductive pathways. The method involves milling a polyolefin with particles of a perovskite nanomaterial, molding to forma composite plate, and subjecting the composite plate to an AC voltage. The AC voltage forms oriented electrically and thermally conductive pathways by partial dielectric breakdown of the composite. The presence of the oriented electrically and thermally conductive pathways gives the polyolefin-perovskite nanomaterial electrical and thermal conductivity and dielectric permittivity higher than the polyolefin alone.

A plasticizing apparatus that plasticizes a material includes: a drive motor; a screw rotated by the drive motor and having a groove forming surface in which a groove is formed; and a barrel having a facing surface that faces the groove forming surface and provided with a heater and a communication hole. The barrel includes a first member, and a second member having thermal conductivity different from that of the first member, and the second member is provided closer to the communication hole than the first member.

A thermally conductive sheet having a binder resin, a first thermally conductive filler, and a second thermally conductive filler, wherein the first thermally conductive filler and the second thermally conductive filler are dispersed in the binder resin, and the specific permittivity and the thermal conductivity are different in the thickness direction B and the surface direction A of the thermally conductive sheet. A thermally conductive sheet includes step A of preparing a resin composition for forming a thermally conductive sheet by dispersing a first thermally conductive filler and a second thermally conductive filler in a binder resin, step B of forming a molded block from the resin composition for forming a thermally conductive sheet, and step C of slicing the molded block into a sheet and obtaining a thermally conductive sheet having different relative permittivity and thermal conductivity in the thickness direction and the surface direction.