Inverters for direct current (DC) to alternating current (AC) conversion may comprise switching elements which produce harmonic overtones. Inductive elements may be added into the inverters, such as to attenuate effects of harmonic overtones. Methods and systems for a casing suitable for reduced potting over its inductive elements is described. One or more heat dispersing elements may be disposed in the casing. Related systems and methods are also described.

A board level shield includes shield walls forming a shield chamber sized and shaped to receive an electrical component mounted to a host circuit board. The shield walls provide electrical shielding entirely around the shield chamber for the electrical component. The shield walls extend between a top and a bottom configured to be mounted to the host circuit board and connected to a ground layer of the host circuit board. The board level shield includes a shield opening at the top bounded by the shield walls and sized and shaped to receive a thermal bridge to allow the thermal bridge to extend through the shield opening to interface with the electrical component. The board level shield includes shield fingers extending from the shield walls into the shield opening. The shield fingers are configured to engage the thermal bridge at separable mating interfaces to electrically connect the shield fingers to the thermal bridge.

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 electronic device with a heat-dissipation structure is provided. The electronic device includes a housing, a heat-dissipation member, and a restriction member. The housing includes a first sidewall and a second sidewall. The first sidewall includes a first sidewall connection portion. The second sidewall includes a second sidewall connection portion. The heat-dissipation member includes a heat-dissipation member connection portion that is detachably connected to the first sidewall connection portion. The first sidewall connection portion restricts the freedom of movement of the heat-dissipation member connection portion in a first direction. The restriction member is disposed on the heat-dissipation member. The restriction member is wedged into the second sidewall connection portion. The second sidewall connection portion restricts the freedom of movement of the restriction member in the first direction.

A heat dissipation module is provided and includes a cold plate having a housing, and a frame body disposed on the housing and having two sidewalls and at least one first rib, where the two sidewalls are positioned at two sides of the housing, respectively, and the first rib is used to provide a deformation resistance so that the heat dissipation module will not be seriously deformed when secured.

An electronic device according to various embodiments of the disclosure may include: a housing which includes a first plate facing a first direction, a second plate facing a second direction opposite to the first direction, and a lateral member covering at least part of the space between the first and second plates; a display disposed to be visible in at least part of the first plate; a first circuit board which includes a first face facing the first direction and a second face facing the second direction, and which is disposed in the second direction of the display; a second circuit board which is disposed not to overlap at least in part with the first printed circuit board, and which is electrically coupled with the first circuit board; a socket mounted to the second circuit board; at least one or more metal structures disposed on the first circuit board to transfer, to another component, heat of at least one or more exothermic elements mounted on the first circuit board; and a ground path constructed in at least part of the second circuit board so as to be electrically coupled to the first circuit board or the metal member or the first circuit board and the metal structure.

A memory device and an electronic device is provided. The memory device may include a memory module including a module board and a memory connector located on one side of the module board, a first enclosure placed above the memory module and a second enclosure placed below the memory module, wherein the first enclosure includes a first main cover which covers upper faces of the module board and the memory connector, at least one clamping hole which penetrates the main cover at a position overlapping the memory connector, an inter-device fastening pillar protruding downward from a lower face of the first main cover, and a coupling hole which is located inside the inter-device fastening pillar on a plane and penetrates the inter-device fastening pillar and the main cover.

A module. In some embodiments, the module includes a substrate; a plurality of electronic components, secured to an upper surface of the substrate; a thermally conductive heat spreader, on the electronic components and in thermal contact with an electronic component of the plurality of electronic components; a standoff, between the substrate and the heat spreader; an alignment element, extending into the substrate; a hard stop, under the substrate; and a plurality of compressible interconnects, under the substrate, and extending through the hard stop. The electronic components may be within a sight area of the substrate. The module may be configured to transmit a compressive load from an upper surface of the standoff to a lower surface of the substrate through a load path not including any of the electronic components.

Wireless electronic devices include one or more wireless antennas to provide for wireless communications. The antenna cables are routed internally within the device and typically noise from components located on a circuit board may couple to the antenna cables and cause a degradation in wireless performance, impact antenna sensitivity and cause packet loss. Utilizing raised pathways in a heat sink utilized for thermal transfer of heat to a housing enables tunnels to be formed between the housing and the heat sink. Routing the antenna cables through the tunnels improves noise isolation for the antenna cables while still maintaining the heat transfer. The raised pathways are configured to not interfere with components on the circuit board or components included in the housing. The wireless antennas may be mounted within the housing instead of on the board so no portion of the antenna cables are located on the circuit board.

A case assembly and an electronic device are provided. The case assembly includes a metal case and a plastic cladding body. The metal case includes an inner side and an outer side, the inner side is opposite to the outer side. The metal case further includes a channel which is concavely disposed on the inner side to divide the inner side into a plurality of thermal insulation areas. The plastic cladding body is disposed on the metal case, and completely covers the outer side of the metal case. The electronic device includes a case assembly and a plurality of heart sources. The heart sources are corresponded to the thermal insulation areas on the inner side of the metal case respectively. Thus, the case assembly and the electronic device are able to prevent the heat produced from elements effect each other.