In various aspects, the disclosure relates to a method of forming a molded article comprising: combining, to form a blend, a polymer base resin and a thermally conductive filler, wherein the thermally conductive filler comprises a platelet filler having a thickness between 100 nm and 10 microns; feeding the blend to a mold cavity of a suitable molding apparatus, wherein the mold cavity has a mold portion that may be retracted in a through-plane direction; foaming the blend to allow a pressure drop; and retracting the mold portion in the through-plane direction to provide the molded article.

An additive manufacturing technique includes depositing, via a filament delivery device, a filament onto a surface of a substrate. The filament includes a binder and a high entropy alloy powder. The technique also includes sacrificing the binder to form a preform and sintering the preform to form a component.

A heater assembly for an aerosol-generating device is provided, the heater assembly including: a bushing defining an aperture at a first end of the bushing and a cavity at a second end of the bushing; and an elongate electrical heater extending from the first end of the bushing, in which a portion of the elongate electrical heater extends through the aperture and into the cavity. An aerosol-generating device, and an aerosol-generating system, are also provided.

The present invention relates to a housing part, a housing and an electronic device. The housing part according to this invention comprises a first layer, said first layer being molded from a first composition comprising a1) 50-90 wt. % of a first amorphous polymer and b1) 10-50 wt. % of a first thermally conductive filler, the first composition having a thermal conductivity (TC1) of 4-40 W/(m*K), a second layer, said second layer being molded from a second composition comprising a2) 50-90 wt. % of a second amorphous polymer and b2) 10-50 wt. % of a second thermally conductive filler, the second composition having a thermal conductivity (TC2) of 0.5-10 W/(m*K), and the second layer being molded over the first layer by leaving at least one area of the first layer not being over-molded with the second layer for being exposed to at least one heat source, wherein, TC1 is at least 2 W/(m*K) larger than TC2, the amounts of al and b1 are based on the total weight of the first composition, the amounts of a2 and b2 are based on the total weight of the second composition, and the thermal conductivity is measured in-plane according to ASTM E1461-01. The housing part provided in this invention has high heat dissipating efficiency and mechanical properties as well as high dimensional stability.

A heater assembly for an aerosol-generating device is provided, the heater assembly including a bushing defining an aperture at a first end of the bushing and a cavity at a second end of the bushing; a potting compound disposed within the cavity; and an elongate electrical heater extending from the first end of the bushing, where a portion of the elongate electrical heater extends through the aperture and into the cavity. An aerosol-generating device, an aerosol-generating system, and a method of assembling a heater assembly for an aerosol-generating device are also provided.

Method for providing a heat exchanger block (B) with a housing (H), said heat exchanger block (B) comprising at least a first outer surface region (B1) and a second outer surface region (B2) opposite said first outer surface region (B1), said housing (H) comprising at least a first housing portion (W1) covering/engaging said first outer surface region (B1) of said heat exchanger block (B) and a second housing portion (W2) opposite said first housing portion (W1) and covering/engaging said second outer surface region (B2) of said heat exchanger block (B), said method comprising at least the following steps: a) moulding said first housing portion (W1) to said first outer surface region (B1); and b) moulding said second housing portion (W2) to said second outer surface region (B2).

A coated tubular construct for biological and industrial applications includes a plurality of channels, where each channel is radially surrounded by a wall comprising a first polymer, and a conformal coating comprising a second polymer is disposed on an outer and/or an inner surface of each wall. A method of producing a tubular construct includes 3D printing a template structure comprising a sacrificial material and a photoinitiator, and immersing the template structure in a first prepolymer solution comprising a first prepolymer and a co-initiator. During the immersion, the template structure is exposed to light, and the first prepolymer undergoes radical polymerization to conformally coat the template structure with the first polymer, forming a coated template. The sacrificial material is removed from the coated template, and a tubular construct comprising the first polymer is formed.

A thermal interface material is disclosed. The material includes: a sheet extending between a first major surface and a second major surface, the sheet including: a base material; and a filler material embedded in the base material. The base material may include anisotropically oriented thermally conductive elements. In some embodiments, the thermally conductive elements are preferentially oriented along a primary direction from the first major surface towards the second major surface to promote thermal conduction though the sheet along the primary direction. In some embodiments, the base material is substantially free of silicone. In some embodiments, the thermal conductivity of the sheet along the primary direction is at least 20 W/mK, 30 W/mK, 40 W/mK, 50 W/mK, 60 W/mK, 70 W/mK, 80 W/mK, 90 W/mK, 100 W/mK, or more.

An additively-manufactured heat exchanger includes fluidly-separated alternating first and second layers having respective flow channels which can include one or more features that is either a riblet or a turbulator. A riblet includes a riblet peak and/or a riblet valley, which has a riblet slope, and the riblet peak and/or riblet valley has a riblet axis that is generally parallel to either the first fluid flow direction or the second fluid flow direction. A turbulator includes a turbulator peak and/or a turbulator valley, which has a turbulator slope, and the turbulator peak and/or turbulator valley has a turbulator axis that is generally perpendicular to either the first fluid flow direction or the second fluid flow direction. The respective slope angles are generally 25-65 deg. relative to build-axis, thereby resulting in improved surface roughness and uniformity control during the build process.

A forming assembly configured to form a wick is disclosed. The forming assembly includes an expandable tube and a forming shell assembly. The expandable tube is hydraulically expandable to an expanded configuration. A wick mesh is configured to be wrapped about the expandable tube. The forming shell assembly includes a first forming shell comprising a first recess defined therein and a second forming shell comprising a second recess defined therein. The first recess and the second recess cooperate to define an outer diameter of the wick. The expandable tube and the wick mesh are positionable between the first recess and the second recess. The expandable tube and the forming shell assembly are configured to deform the wick mesh and form the wick based on the expandable tube hydraulically expanding towards the expanded configuration.