Abstract: An illustrative example embodiment of an antenna device includes a substrate, a plurality of antenna elements supported on the substrate, an integrated circuit supported on one side of the substrate, and a metallic waveguide antenna situated against the substrate. The metallic waveguide antenna includes a heat dissipation portion in a thermally conductive relationship with the integrated circuit. The heat dissipation portion is configured to reduce a temperature of the integrated circuit.

Abstract: An electronic device includes a printed circuit board (PCB) that supports an integrated circuit (IC) chip. The device also includes a lid over the IC chip. A thermal interface material (TIM) is configured to transfer thermal energy from the IC chip to the lid. A heat spreader forms a cavity in communication with the lid. The heat spreader is at least partially filled with a liquid that is configured to change phases during operation of the IC chip.

Abstract: An illustrative example embodiment of an antenna device includes a substrate, a plurality of antenna elements supported on the substrate, an integrated circuit supported on one side of the substrate, and a metallic waveguide antenna situated against the substrate. The metallic waveguide antenna includes a heat dissipation portion in a thermally conductive relationship with the integrated circuit. The heat dissipation portion is configured to reduce a temperature of the integrated circuit.

Abstract: An illustrative example embodiment of an antenna device includes a substrate, a plurality of antenna elements supported on the substrate, an integrated circuit supported on one side of the substrate, and a metallic waveguide antenna situated against the substrate. The metallic waveguide antenna includes a heat dissipation portion in a thermally conductive relationship with the integrated circuit. The heat dissipation portion is configured to reduce a temperature of the integrated circuit.

Abstract: An electronic device includes a printed circuit board that supports an integrated circuit (IC) chip and a thermal interface layer that is configured to transfer thermal energy from the IC chip. The thermal interface layer includes a containment frame that is non-electrically conductive and a thermal conductance pane that is inset in the containment frame.

Abstract: An electronics heat exchanger including a fluid flow body having a first panel, a second panel, and at least one fluid flow guide connecting the first panel and the second panel, a plurality of pedestals extending from the second panel, the plurality of pedestals including at least a first pedestal having a first height and a second pedestal having a second height, distinct from the first height, and wherein each of the pedestals is integral with the second panel.

Abstract: An electronic device includes a printed circuit board (PCB) that supports an integrated circuit (IC) chip. The device also includes a lid over the IC chip. A thermal interface material (TIM) is configured to transfer thermal energy from the IC chip to the lid. A heat spreader forms a cavity in communication with the lid. The heat spreader is at least partially filled with a liquid that is configured to change phases during operation of the IC chip.

Abstract: An electrical-circuit assembly includes an electrical-device and a heat-sink. The heat-sink has a base having a first-surface and a second-surface. The first-surface is in thermal communication with the electrical-device. The heat sink also has a lid having a third-surface and a fourth-surface. The third-surface faces toward the second-surface. The heat sink also has side-walls disposed between the base and the lid extending from the second-surface to the third-surface. The base, the lid, and the side-walls define a cavity. The heat sink also has a porous-structure extending from the second-surface toward the third-surface terminating a portion of the distance between the second-surface and the third-surface thereby defining a void between the porous-structure and the third-surface. The base, the side-walls, and the porous-structure are integrally formed of a common material. The porous-structure is characterized as having a contiguous-porosity network.

Abstract: An interface layer includes an electrically conductive compressible mesh that has wires that are interwoven and pores between the wires. A sinter paste is immobilized in the pores. The sinter paste includes electrically conductive particles.

Abstract: An electrical-circuit assembly includes an electrical-device and a heat-sink. The heat-sink has a base having a first-surface and a second-surface. The first-surface is in thermal communication with the electrical-device. The heat sink also has a lid having a third-surface and a fourth-surface. The third-surface faces toward the second-surface. The heat sink also has side-walls disposed between the base and the lid extending from the second-surface to the third-surface. The base, the lid, and the side-walls define a cavity. The heat sink also has a porous-structure extending from the second-surface toward the third-surface terminating a portion of the distance between the second-surface and the third-surface thereby defining a void between the porous-structure and the third-surface. The base, the side-walls, and the porous-structure are integrally formed of a common material. The porous-structure is characterized as having a contiguous-porosity network.

Abstract: A navigation system suitable for installation in a host-vehicle includes a navigation-device, a display, and a receiver. The navigation-device is configured to determine a first-location of a host-vehicle. The display is configured to show navigation-information to an operator of the host-vehicle. The navigation-information indicates the first-location relative to a map. The receiver is configured to receive profile-information associated with an other-vehicle. The profile-information includes a second-location of the other-vehicle. The system indicates the second-location on the map.

Abstract: An assembly for coupling thermally a thermoelectric generator (TEG) to an exhaust manifold includes a first heat-exchanger, a first dielectric-layer, a TEG, and a direct-bond-copper-arrangement (DBC). The first dielectric-layer overlies a portion of the outer surface of the first heat-exchanger. The first dielectric-layer is formed by firing a thick-film dielectric material onto the stainless steel of the first heat-exchanger. The TEG defines a first contact suitable to be coupled thermally and electrically to the first conductor-layer. The DBC is interposed between the first dielectric-layer and the first contact of the TEG. The DBC is formed by an adhesion-layer formed of high-adhesion-copper-thick-film in contact with the first dielectric-layer, a bond-layer formed of copper-thick-film that overlies and is in contact with the adhesion-layer opposite the first-dielectric-layer, and a copper-foil-layer that overlies and is in contact with the bond-layer opposite the adhesion-layer.

Abstract: A navigation system suitable for installation in a host-vehicle includes a navigation-device, a display, and a receiver. The navigation-device is configured to determine a first-location of a host-vehicle. The display is configured to show navigation-information to an operator of the host-vehicle. The navigation-information indicates the first-location relative to a map. The receiver is configured to receive profile-information associated with an other-vehicle. The profile-information includes a second-location of the other-vehicle. The system indicates the second-location on the map.

Abstract: A liquid cooled power electronics assembly configured to use electrically conductive coolant to cool power electronic devices that uses dielectric plates sealed with a metal sleeve around the perimeter of the dielectric plates to form a device assembly. The configuration allows for more direct contact between the electronic device and the coolant, while protecting the electronic device from contact with potentially electrically conductive coolant. Material used to form the dielectric plates and the housing are selected to have similar coefficients of thermal expansion (CTE) so that the reliability of the seals is maximized.

Abstract: An assembly for coupling thermally a thermoelectric generator (TEG) to an exhaust manifold of an internal combustion engine. The exhaust manifold forms a first heat exchanger configured to couple thermally heat from exhaust gas to an outer surface of the first heat exchanger. The outer surface is preferably formed of stainless steel. A first dielectric layer is formed by firing a thick-film dielectric material onto the stainless steel of the first heat exchanger. A first conductor layer is formed by firing a conductive thick-film onto the first dielectric layer. A first paste layer of silver (Ag) based sintering paste is interposed between the first conductor layer and a first contact of the TEG. The first contact is sintered to the first conductor layer when the assembly is suitably arranged and suitably heated.

Abstract: An assembly for coupling thermally a thermoelectric generator (TEG) to an exhaust manifold of an internal combustion engine. The assembly includes a first heat exchanger configured to guide exhaust gas of an internal combustion engine past an opening defined by the first heat exchanger, and a heat sink configured to couple thermally the TEG to the exhaust gas and fluidicly seal the opening. The assembly is configured so the heat sink is directly exposed to the exhaust gas so that heat is efficiently transferred from the exhaust gas to the TEG.

Abstract: A self-circulating heat exchanger apparatus for dissipating heat from an electronic assembly. An enclosure defines a closed-loop circulation path for coolant. An electronic assembly capable of generating heat is installed into a vertical portion of the enclosure such that heat from the electronic assembly causes coolant in the vertical portion to rise, thereby inducing self-circulation of the coolant in the enclosure. The electronic assembly is coated with a combination of silicon nitride and PARYLENE® in order to protect electronic components from water based coolants such as a mixture of ethylene glycol and water.

Abstract: A liquid cooled power electronics assembly configured to use electrically conductive coolant to cool power electronic devices that uses dielectric plates sealed with a metallic seal around the perimeter of the dielectric plates to form a device assembly, and then forms another metallic seal between the device assembly and a housing. The configuration allows for more direct contact between the electronic device and the coolant, while protecting the electronic device from contact with potentially electrically conductive coolant. Material used to form the dielectric plates and the housing are selected to have similar coefficients of thermal expansion (CTE) so that the reliability of the seals is maximized.

Abstract: A liquid cooled power electronics assembly configured to use electrically conductive coolant to cool power electronic devices that uses dielectric plates sealed with a metal sleeve around the perimeter of the dielectric plates to form a device assembly. The configuration allows for more direct contact between the electronic device and the coolant, while protecting the electronic device from contact with potentially electrically conductive coolant. Material used to form the dielectric plates and the housing are selected to have similar coefficients of thermal expansion (CTE) so that the reliability of the seals is maximized.

Abstract: A liquid cooled power electronics assembly configured to use electrically conductive coolant to cool power electronic devices that uses dielectric plates sealed with a metallic seal around the perimeter of the dielectric plates to form a device assembly, and then forms another metallic seal between the device assembly and a housing. The configuration allows for more direct contact between the electronic device and the coolant, while protecting the electronic device from contact with potentially electrically conductive coolant. Material used to form the dielectric plates and the housing are selected to have similar coefficients of thermal expansion (CTE) so that the reliability of the seals is maximized.