Abstract: According to various aspects, exemplary embodiments are provided of thermal interface material assemblies. In an exemplary embodiment, a thermal interface material assembly generally includes a thermal interface material having a first side and a second side. A dry material is along at least a portion of the first side of the thermal interface material. The dry material has a thickness less than 0.005 millimeters. At least one edge of the thermal interface material is sealed at least partially by the dry material.

Abstract: Example embodiments of the present disclosure generally relate to thermal interface material assemblies. In an example embodiment, a thermal interface material assembly generally includes a substrate and one or more pillars along a first and/or second side portion of the substrate.

Abstract: Example embodiments of the present disclosure generally relate to thermal solutions and methods for dissipating or removing heat from electronic devices using the same side of an anisotropic heat spreader. In an example embodiment, a thermal solution generally includes a heat removal structure and an anisotropic heat spreader. The anisotropic heat spreader is configured such that the heat removal structure and the heat source are in thermal contact with a same side of the anisotropic heat spreader and such that a thermally-conductive heat path is provided along that same side of the anisotropic heat spreader from the heat source to the heat removal structure. Heat from the heat source may be transferrable to the same side of the anisotropic heat spreader from which heat is also transferrable to the heat removal structure.

Abstract: According to various aspects of the present disclosure, exemplary embodiments are disclosed of thermally-conductive interface assemblies suitable for use in dissipating heat from one or more components of a memory module. The thermally-conductive interface assembly may generally include a flexible heat-spreading material having first and second sides and one or more perforations extending through the flexible heat-spreading material from the first side to the second side. The flexible heat-spreading material may be sandwiched between first and second layers of soft thermal interface material. A portion of the soft thermal interface material may be disposed within the one or more perforations. The thermally-conductive interface assembly may be positioned relative to one or more components of a memory module to provide a thermally-conductive heat path from the one or more components to the first layer of soft thermal interface material.

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: 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 generating components using thermoplastic and/or self-healing thermal interface materials. In an exemplary embodiment, a thermal interface material has a softening or melting temperature above a normal operating temperature of the one or more heat generating components. The thermal interface material is flowable to a thin bond line between a heat spreader or lid and one or more heat generating components when heated to at least the softening or melting temperature while under pressure.

Abstract: A thermal interface material is configured for use with an electronic device for transferring heat between heat generating components and heat removing components of the electronic device. The thermal interface material generally includes a first material (e.g., a gap filler, etc.) incorporating a contact resistance reducing material. The contact resistance reducing material operates to fill interstitial voids of surfaces of components in which the first material is installed to thereby reduce surface contact resistance between the first material and the component surfaces. The contact resistance reducing material may be applied to one or more side surfaces of the first material. Or, alternatively, the contact resistance reducing material may be blended in the first material.

Abstract: According to various aspects of the present disclosure, exemplary embodiments are disclosed of thermally-conductive interface assemblies suitable for use in dissipating heat from one or more components of a memory module. The thermally-conductive interface assembly may generally include a flexible heat-spreading material having first and second sides and one or more perforations extending through the flexible heat-spreading material from the first side to the second side. The flexible heat-spreading material may be sandwiched between first and second layers of soft thermal interface material. A portion of the soft thermal interface material may be disposed within the one or more perforations. The thermally-conductive interface assembly may be positioned relative to one or more components of a memory module to provide a thermally-conductive heat path from the one or more components to the first layer of soft thermal interface material.

Abstract: A circuit assembly generally includes a circuit board and at least one electrical pathway configured to couple a thermoelectric module to the circuit board. The circuit board and the at least one electrical pathway form part of the thermoelectric module when the thermoelectric module is coupled to the circuit board via the at least one electrical pathway. The thermoelectric module, including the portion of the circuit board forming part of the thermoelectric module, defines a footprint that is smaller than a footprint of the circuit board. As such, the circuit board is capable of supporting electrical components on the circuit board in a position outside the footprint defined by the thermoelectric module.

Abstract: A thermal interface material (TIM) assembly is provided for use in conducting heat away from heat generating components. The TIM assembly generally includes a substrate, a metal alloy coupled to at least one side surface of the substrate, and a coating material covering at least part of the substrate and at least part of the metal alloy. The substrate may include a metal foil, a heat dissipating unit, a heat generating component, etc. The metal alloy may include a low melting metal alloy coupled to the substrate to form multiple bumps along the substrate in a pattern. The pattern may be generic such that the TIM assembly may be used with multiple different heat generating components to effectively conduct heat away from the multiple different heat generating components, or it may correspond to particular locations on a heat generating component away from which heat is to be conducted.

Abstract: A circuit assembly generally includes a circuit board and at least one electrical pathway configured to couple a thermoelectric module to the circuit board for use as a heat pump in the circuit assembly. The circuit board and the at least one electrical pathway form part of the thermoelectric module when the thermoelectric module is coupled to the circuit board via the at least one electrical pathway. The thermoelectric module, including the portion of the circuit board forming part of the thermoelectric module, defines a footprint that is smaller than a footprint of the circuit board. As such, the circuit board is capable of supporting electrical components on the circuit board in a position outside the footprint defined by the thermoelectric module.

Abstract: According to various aspects of the present disclosure, exemplary embodiments include assemblies and methods for dissipating heat from an electronic device by a thermally-conducting heat path to the external casing. In an exemplary embodiment, a thermally-conductive structure which comprises graphite may be disposed about or define a battery area such that heat may be transferred to the external casing by a thermally-conductive heat path around the battery area through or along the thermally-conductive structure which comprises graphite.

Abstract: According to various aspects of the present disclosure, exemplary embodiments include assemblies and methods for dissipating heat from an electronic device by a thermally-conducting heat path to the external casing via one or more portions of an electromagnetic interference shield and/or thermal interface material disposed around the device's battery or other power source. In an exemplary embodiment, a thermally conductive structure which comprises elastomer may be disposed about or define a battery area such that heat may be transferred to the external casing by a thermally-conductive heat path around the battery area through or along the thermally conductive structure which comprises elastomer.

Abstract: A thermal interface material is provided for use to fill a gap between surfaces in a thermal transfer system to transfer heat between the surfaces. The thermal interface material includes a base material and thermally conductive particles dispersed within the base material. The thermal interface material is conditioned under reduced pressure (e.g., prior to being placed in the gap between the surfaces, while being placed in the gap, after being placed in the gap, etc.) and, within about forty-eight hours or less of conditioning, the conditioned thermal interface material is either positioned in a container that inhibits ambient gas from contacting it (either alone or applied to the surfaces), or used to transfer heat between the surfaces. As such, the thermal interface material is substantially free of cracks following exposure to thermal cycling comprising a temperature change of at least about 100 degrees Celsius for at least about 10 cycles.

Abstract: A circuit assembly generally includes a circuit board and at least one electrical pathway configured to couple a thermoelectric module to the circuit board for use as a heat pump in the circuit assembly. The circuit board and the at least one electrical pathway form part of the thermoelectric module when the thermoelectric module is coupled to the circuit board via the at least one electrical pathway. The thermoelectric module, including the portion of the circuit board forming part of the thermoelectric module, defines a footprint that is smaller than a footprint of the circuit board. As such, the circuit board is capable of supporting electrical components on the circuit board in a position outside the footprint defined by the thermoelectric module.

Abstract: An example thermoelectric module generally includes a first laminate having a dielectric layer and an electrically conductive layer coupled to the dielectric layer, a second laminate having a dielectric layer and an electrically conductive layer coupled to the dielectric layer, and thermoelectric elements disposed generally between the first and second laminates. At least one of the dielectric layers is a polymeric dielectric layer. The electrically conductive layers of the first and second laminates are at least partially removed to form electrically conductive pads on the respective first and second laminates. The thermoelectric elements are coupled to the electrically conductive pads of the first and second laminates for electrically coupling the thermoelectric elements together.

Abstract: According to various aspects of the present disclosure, exemplary embodiments are disclosed of thermally-conductive interface assemblies suitable for use in dissipating heat from one or more components of a memory module. The thermally-conductive interface assembly may generally include a flexible heat-spreading material having first and second sides and one or more perforations extending through the flexible heat-spreading material from the first side to the second side. The flexible heat-spreading material may be sandwiched between first and second layers of soft thermal interface material. A portion of the soft thermal interface material may be disposed within the one or more perforations. The thermally-conductive interface assembly may be positioned relative to one or more components of a memory module to provide a thermally-conductive heat path from the one or more components to the first layer of soft thermal interface material.

Abstract: Various potato graphite filler, thermal interface materials, EMI shielding materials and methods of making thermal interface and EMI shielding materials are disclosed. An example thermal interface material includes a matrix material and a graphite filler suspended in the matrix material. The graphite filler includes potato graphite particles.

Abstract: According to various aspects of the present disclosure, exemplary embodiments are disclosed of EMI shielding, thermally-conductive interface assemblies. In various exemplary embodiments, an EMI shielding, thermally-conductive interface assembly includes a thermal interface material and a sheet of shielding material, such as an electrically-conductive fabric, mesh, foil, etc. The sheet of shielding material may be embedded within the thermal interface material and/or be sandwiched between first and second layers of thermal interface material.

Abstract: According to various aspects, exemplary embodiments are provided of EMI shielding materials. In one exemplary embodiment, an EMI shielding material generally includes a conductive metal layer disposed on a thin carrier film. The EMI shielding material may be sufficiently compliant such that the conductive metal layer and thin carrier film are capable of conforming to an irregular surface when the EMI shielding material is applied to the irregular surface.