Abstract: Disclosed are systems for applying materials to components. The system comprises a tool operable for transferring a portion of a material from a supply of the material to a component. A first portion of the tool may be configured for cutting along a side or edge of the portion of the material. A second portion of the tool may be configured for tamping, pressing, or pushing against the portion of the material to cause uncut sides or edges of the portion of the material attached to the supply of the material to be torn, severed, detached, or separated from the supply of the material.

Abstract: According to various aspects, exemplary embodiments are disclosed of thermally-conductive EMI absorbers that generally includes thermally-conductive particles, EMI absorbing particles, and silicon carbide. The silicon carbide is present in an amount sufficient to synergistically enhance thermal conductivity and/or EMI absorption. By way of example, an exemplary embodiment of a thermally-conductive EMI absorber may include silicon carbide, magnetic flakes, manganese zinc ferrite, alumina, and carbonyl iron.

Abstract: According to various aspects, exemplary embodiments are disclosed of thermal interface materials, electronic devices, and methods for establishing thermal joints between heat spreaders or lids and heat sources. In exemplary embodiments, a method of establishing a thermal joint for conducting heat between a heat spreader and a heat source of an electronic device generally includes positioning a thermal interface material (TIM1) between the heat spreader and the heat source.

Abstract: The present application provides a female connector and a connector assembly. The female connector is used to connect to a PCB board internally provided with a signal layer and a drilling hole penetrating the signal layer, the female connector including: a female terminal having two ends, one end being a connecting end for mating with a male connector or a gold finger circuit board, and the other end forming a crimping pin to be inserted into a drilling hole and connected with the signal layer; a high-frequency radiation area being formed in the vicinity of a connection between the crimping pin and the drilling hole when the connecting end is mated with the male connector or the gold finger circuit board; and a wave-absorbing material is disposed in a spatial scope covered by the high-frequency radiation area.

Abstract: The present disclosure provides a female connector and a connector combination. The female connector includes: a female terminal having a first end for mating with a male connector or a gold finger circuit board, and a second end for connection with a PCB board, the female terminal being formed with at least one shape abruptly-changed portion between the first end and the second end, and a high-frequency radiation area being formed in the vicinity of the shape abruptly-changed portion when the first end is mated with the male connector or the gold finger circuit board; and a wave-absorbing material disposed in a spatial range covered by the high-frequency radiation area. By selectively disposing the wave-absorbing material in an area where a high-frequency radiation is easily generated during the use of the connector, crosstalk signals are absorbed, while normally transmitted electrical signals are retained, and an overall weight of the connector is light.

Abstract: Disclosed herein are thermal interface materials (TIMs) including memory foam cores. In an exemplary embodiment, a thermal interface material generally includes a memory foam core including a plurality of sides defining a perimeter. A heat spreader is disposed at least partially around the perimeter defined by the plurality of sides of the memory foam core.

Abstract: According to various aspects, exemplary embodiments are disclosed of frames for shielding assemblies including detachable or severable pickup members. Also disclosed are exemplary embodiments of shielding assemblies (e.g., board level shields, etc.) including the same.

Abstract: Disclosed are exemplary embodiments of thermal management and/or electromagnetic interference (EMI) mitigation materials including coated fillers (e.g., coated thermally-conductive, electrically-conductive, dielectric absorbing, and/or electromagnetic wave absorbing particles, sand particles coated with a binder, other coated functional fillers, combinations thereof, etc.). For example, a thermal management and/or EMI mitigation material may comprise a thermal interface material (TIM) including one or more coated fillers (e.g., coated thermally-conductive particles, sand particles coated with a binder, etc.), whereby the TIM is suitable for providing a thermal management solution for one or more batteries and/or battery packs (e.g., a battery pack for electric vehicle, etc.), or other device(s), etc.

Abstract: Disclosed are systems for applying materials to components. The system comprises a tool operable for transferring a portion of a material from a supply of the material to a component. A first portion of the tool may be configured for cutting along a side or edge of the portion of the material. A second portion of the tool may be configured for tamping, pressing, or pushing against the portion of the material to cause uncut sides or edges of the portion of the material attached to the supply of the material to be torn, severed, detached, or separated from the supply of the material.

Abstract: According to various aspects, exemplary embodiments are disclosed of frames for shielding assemblies including detachable or severable pickup members. Also disclosed are exemplary embodiments of shielding assemblies (e.g., board level shields, etc.) including the same.

Abstract: Exemplary embodiments are disclosed of EMI shields including electrically-conductive foam (broadly, electrically-conductive resiliently compressible porous material). An exemplary embodiment includes an electromagnetic interference (EMI) shield for an optical transceiver including transmitter and receiver optical sub-assemblies. The EMI shield includes a portion having openings configured for receiving the transmitter and receiver optical sub-assemblies therethrough to thereby allow the EMI shield to be fit over the transmitter and receiver optical sub-assemblies for installation along a portion of the optical transceiver. The EMI shield also includes sidewalls depending from the portion that includes the openings. Electrically-conductive resiliently compressible porous material (e.g., electrically-conductive foam, etc.) is along at least a portion of an outer perimeter defined by the sidewalls.

Abstract: A device for absorbing energy from an electronic component includes a low melting alloy layer including a first side and a second side opposing the first side, and coating layers substantially covering the first side and the second side of the low melting alloy layer. In some embodiments, the low melting alloy layer includes a polymer mixture and a plurality of low melting alloy particulates dispersed in the polymer mixture. Other example devices are also disclosed.

Abstract: Exemplary embodiments are disclosed of thermal management assemblies suitable for use (e.g., configured for heat spreading, etc.) with transceivers (e.g., small form-factor pluggable (SFP) transceivers, SFP+ transceivers, quad small form-factor pluggable (QSFP) transceivers QSFP+ transceivers, XFP transceivers, etc.) and other devices (e.g., memory card readers, etc.). In exemplary embodiments, a thermal management assembly comprises at least one flexible heat spreading material (e.g., a single graphite sheet, multiple graphite sheets, etc.) including portions wrapped (e.g., in different non-parallel directions, in parallel directions, etc.) around corresponding portions of a part, which may be configured to be coupled to and/or along a side of a device housing. The at least one flexible heat spreading material may be operable for defining at least a portion of a thermally-conductive heat path around the corresponding portions of the part.

Abstract: According to various aspects, exemplary embodiments are disclosed of thermal interface materials, electronic devices, and methods for establishing thermal joints between heat spreaders or lids and heat sources. In exemplary embodiments, a method of establishing a thermal joint for conducting heat between a heat spreader and a heat source of an electronic device generally includes positioning a thermal interface material (TIM1) between the heat spreader and the heat source.

Abstract: A method includes raising a pickup area of a pickup member including one or more arms extending between the pickup area and one or more sidewalls of a frame of a board level shield (BLS), such that the pickup area is raised relative to and above an upper surface of the one or more sidewalls of the frame, and such that the pickup area rotates in place as the pickup area is raised relative to and above the upper surface of the one or more sidewalls.

Abstract: A system for applying materials to components generally includes a tool operable for transferring a portion of a material from a supply of the material to a component. The tool may include a resilient material configured for tamping the portion of the material onto the component and/or for imprinting the portion of the material for release and transfer from the supply.

Abstract: Disclosed are exemplary embodiments of thermal interface materials with low secant modulus of elasticity and high thermal conductivity.