Various technologies described herein pertain to a heat spreader for an autonomous vehicle computing device. The heat spreader includes a top surface, a bottom surface, and a side surface. The top surface of the heat spreader is thermally conductive. The top surface of the heat spreader includes a section that is sized and shaped to align with a heat generating component (e.g., on a printed circuit board assembly). The top surface of the heat spreader is configured to receive heat from the heat generating component. The bottom surface of the heat spreader includes externally integrated fins. The heat spreader is configured to dissipate the heat from the heat generating component such that the heat from the heat generating component flows from the top surface to the externally integrated fins on the bottom surface.

A middle bezel frame with heat dissipation structure includes a main body, which includes a frame portion and at least one heat-exchange portion. The frame portion is located around and connected to the heat-exchange portion. The heat-exchange portion internally has an airtight chamber, in which at least one wick structure and a working fluid are provided. With these arrangement, the middle bezel frame has enhanced structural strength while provides good heat dissipation effect.

A multi-channel cold plate for cooling chip wherein a first set of cooling channels function as main cooling channels and a second set of cooling channels function as a secondary and/or backup cooling channels. The two sets of cooling channels are fluidly isolated from each other, such that cooling fluid from one sent of channels cannot flow or intermix with the cooling fluid of the other cooling channel. The secondary cooling channels can be operated when demand for heat removal is increased or when the main cooling channels is unable to manage the thermal condition of the chip properly.

Systems and methods for cooling an electronic device via interface of a heat-transfer conduit of the electronic device to a cold plate assembly are disclosed. According to an aspect, a system includes an electronic device including one or more electronic components. Further, the electronic device includes a heat-transfer conduit including a first end and a second end. The first end of the heat-transfer conduit is positioned to receive heat from the electronic component(s). The heat-transfer conduit is configured to conduct heat from the first end to the second end. Further, the system includes a cold plate assembly including a cold plate and a mechanism configured to permit movement of the cold plate. At the first position, the cold plate may contact the second end for receipt of heat from the heat-transfer conduit at the second end. At the second position, the cold plate is apart from the second end.

A thermal module with a heat pipe configured with a first portion configured for contact with an edge of a plurality of fins in a fin stack, a second portion configured for contact with a side of one fin in the fin stack and a sharp angled bend is formed between the first portion and the second portion to fluidly isolate the first portion from the second portion. The first portion comprises a usable length of the heat pipe that efficiently transfers heat based on phase transitioning by the fluid. The second portion is formed from at least some of the unusable length of the heat pipe. By configuring the heat pipe such that more fins contact the usable length of the heat pipe, heat transfer from the heat pipe to the fin stack is increased.

A basic structural body for constructing heat dissipation device and a heat dissipation device are disclosed. The heat dissipation device includes a first basic structural body having a wick structure formed on one side surface thereof; and the first basic structural body and the wick structure are structural bodies formed layer by layer. Two pieces of first basic structural bodies can be correspondingly closed together to construct a heat dissipation device internally defining an airtight chamber. In this manner, the heat dissipation device can be designed in a more flexible manner.

An electronic apparatus includes: a chassis; a heat generating element provided in the chassis; and a cooling device that has a cooling fin, a heat pipe connecting the cooling fin and the heat generating element, and a pressing assembly pressing the heat pipe against the heat generating element, and is provided in the chassis. The heat pipe has: a heat absorbing section that absorbs heat generated by the heat generating element; and a thin plate section having a thickness which is smaller than that of the heat absorbing section. The pressing assembly has: a base assembly relatively fixed to the chassis; and a bridge section that is provided integrally with the base assembly and placed on a surface of the thin plate section in such a manner as to extend over the heat pipe in a width direction.

A thin, single-layer thermally conductive jacket surrounds a PCA. One or more living springs integrated in the jacket exert compressive force on PCA components where cooling is desired. The compressive force creates and maintains a thermal contact though which heat is conducted out of the PCA components and into the jacket. The jacket conducts the heat (either directly or indirectly) to a liquid-cooled cold plate configured as a cooling frame surrounding one or more of the jacketed PCAs. The jacket, optionally through intermediate thermal transfer devices such as heat spreaders or heat pipes, transfers heat from components on the PCA to the cooling frame. Liquid flowing through the cooling frame's internal channels convects the heat out of the electronic device. Turbulence encouraged by turbulence enhancing artifacts including bends and shape-changes along the internal channels increases the efficiency of the convection.

A heat dissipation unit with floating section includes an upper plate and a lower plate, which are closed together to define a chamber in between them, and the chamber has a working fluid filled therein. The upper and the lower plate respectively include a front section, a read section, and a middle section located between the front and the rear section. The front section and the rear section of one or both of the upper and the lower plate have a plate thickness larger than that of the middle section, such that the middle sections form flexible floating sections that allow for a floating adjustment thereat, making the front and the rear sections of the heat dissipation unit to be located at two positions having a height difference between them.

The present disclosure provides an unmanned aerial vehicle (UAV) having a housing containing electronic components required of the UAV and a heat transfer device for cooling heat generated by said electronic components; at least one boom for connecting said housing to at least one propeller. The boom includes one or more inlet located on a first surface of the boom and within an airflow of said at least one propeller; at least one outlet on a second surface of the boom; a hallow channel extending in interior of the boom from said at least one inlet to said at least one outlet, wherein said airflow generated by said at least one propeller passes into said at least one inlet through the hollow channel to said at least one outlet providing cooling for said heat transfer device.