Systems, apparatuses, and methods for thermal dissipation on or from an electronic device are described. An apparatus may have a printed circuit board (PCB) having an edge connector. At least one integrated circuit device may be disposed on a surface of the PCB. A tubular heat spreader may be disposed along an edge of the PCB opposite the edge connector.

One example heat sink includes a heat dissipation substrate, a connector, and a fastener. The heat dissipation substrate is configured to dissipate heat for a packaged chip located on a circuit board, and the heat dissipation substrate is located on a surface that is of the packaged chip and that is opposite to the circuit board. A first heat dissipation substrate and a second heat dissipation substrate of the heat dissipation substrate each have a heat conduction surface that conducts heat with a chip in the packaged chip. Different heat conduction surfaces correspond to different chips.

One example heat sink includes a heat dissipation substrate, a connector, and a fastener. The heat dissipation substrate is configured to dissipate heat for a packaged chip located on a circuit board, and the heat dissipation substrate is located on a surface that is of the packaged chip and that is opposite to the circuit board. A first heat dissipation substrate and a second heat dissipation substrate of the heat dissipation substrate each have a heat conduction surface that conducts heat with a chip in the packaged chip. Different heat conduction surfaces correspond to different chips.

A thermal chamber multiple sides that form an enclosed chamber. The thermal chamber includes a first side of the multiple sides, the first side configured to adjustably mount an electronic circuit board within the enclosed chamber. The thermal chamber includes a second side of the multiple sides, the second side located opposite the first side and including one or more ports that expose the enclosed chamber. Each of the one or more ports is configured to receive a temperature control component that transfers thermal energy locally to and from a plurality of electronic devices of an electronic system that is coupled to and positioned above the electronic circuit board.

A flatpack air chiller device is disclosed. In embodiments, the air chiller device includes a primary chiller or pre-chiller subsystem and a secondary or main chiller subsystem within a housing. The pre-chiller subsystem receives and chills ambient air via cold-side contact with a primary thermoelectric device and directs the pre-chilled ambient airstream to the hot side of a secondary thermoelectric device. The secondary or main chiller subsystem is connected to a recirculating air stream, e.g., circulating through the interior airspaces, compartments, or bays of a galley structure. The pre-chilled ambient airstream absorbs heat from the secondary hot side to progressively chill the recirculating air stream, which is in contact with the cold side of the secondary thermoelectric device before recirculation back into the galley structure interior.

A flatpack air chiller device is disclosed. In embodiments, the air chiller device includes a primary chiller or pre-chiller subsystem and a secondary or main chiller subsystem within a housing. The pre-chiller subsystem receives and chills ambient air via cold-side contact with a primary thermoelectric device and directs the pre-chilled ambient airstream to the hot side of a secondary thermoelectric device. The secondary or main chiller subsystem is connected to a recirculating air stream, e.g., circulating through the interior airspaces, compartments, or bays of a galley structure. The pre-chilled ambient airstream absorbs heat from the secondary hot side to progressively chill the recirculating air stream, which is in contact with the cold side of the secondary thermoelectric device before recirculation back into the galley structure interior.

The invention relates to a heatsink for transferring heat from one or more electrical devices to a heat transfer medium. The heatsink includes a plurality of fins arranged on a frontside of the heatsink. The plurality of fins includes a first group of fins extending in a first planar direction and a second group of fins extending in a second planar direction angled in relation to the first planar direction. For example, the first group of fins may extend from the bottom to the top of the heatsink, while the second group of fins may extend from the first group of fins to the sides of the heatsink. In this way, the sides of the heatsink can be used as air outlets and the airflow through the heatsink can be increased.

An integrated circuit package comprising one or more electronic component(s); a first substrate including a first surface and a second surface of the first substrate; and a second substrate including a first surface and a second surface of the second substrate. The first substrate including a first first-substrate cavity on the first surface of the first substrate. The second substrate includes a first second-substrate cavity on the first surface of the second substrate. The second surface of the first substrate and the second surface of the second substrate is located between the first surface of the first substrate and the first surface of the second substrate; or the first surface of the first substrate and the first surface of the second substrate is located between the second surface of the first substrate and the second surface of the second substrate.

An integrated circuit package comprising one or more electronic component(s); a first substrate including a first surface and a second surface of the first substrate; and a second substrate including a first surface and a second surface of the second substrate. The first substrate including a first first-substrate cavity on the first surface of the first substrate. The second substrate includes a first second-substrate cavity on the first surface of the second substrate. The second surface of the first substrate and the second surface of the second substrate is located between the first surface of the first substrate and the first surface of the second substrate; or the first surface of the first substrate and the first surface of the second substrate is located between the second surface of the first substrate and the second surface of the second substrate.

An electronic card includes a substrate, an electronic device bonded to the substrate via a solder bump, and configured to include a first ceiling, and a cover fixed to the substrate, provided over the electronic device, and configured to include a second ceiling that faces the first ceiling, wherein the first ceiling or the second ceiling is provided with an annular member extending in a facing direction of the first ceiling and the second ceiling, the annular member forming an annular shape along a circumferential direction of the first ceiling, wherein the first ceiling and the second ceiling form a gap between the first ceiling and the second ceiling filled with a filling material inside the annular member, and wherein the second ceiling includes a through hole at a position that overlaps the filling material when viewed in a plan view of the second ceiling.