A power converter system includes a printed circuit board having a first connector for receiving low voltage control signals and a second connector for receiving input voltages from one or more power generators and transmitting output voltages to a power distribution unit. Power devices are mounted onto the printed circuit board to manage the input voltages and to generate the output voltages. An enclosure is mounted around the printed circuit board and power devices. The power devices engage interior surfaces of the enclosure forming a conductive heat path between the power devices, the interior surfaces, and exterior surfaces of the enclosure. The heat path conductively transfers heat from the power devices to the exterior surfaces.

The present disclosure relates to a converter for an air conditioner. The converter includes a substrate; an inductor disposed in one side of the substrate, and comprising a core and a coil wound around the core; a switching element disposed in one side of the substrate, and selectively controlling a flow of a circuit; and a heat sink for absorbing heat generated from the switching element by contacting the switching element, wherein a lead-in hole is formed in one side of the substrate, and at least a portion of the inductor is disposed in the lead-in hole, thereby quickly discharging the heat generated by the inverter and more efficiently using a space.

In a vehicle camera device, a camera is housed inside a bracket of a base, and a stud bolt of the base is connected to a side door. Heat generated by the camera is transferred to the side door via the bracket, the base, and the stud bolt. Therefore, the heat generated by the camera can be efficiently released from the camera.

According to an example, a conduit sizeable in length and width comprises a first cover and a second cover. The first cover comprises a first interfacing area between a first component and a second component. The second cover comprises a second interfacing area between a third component and a fourth component. The first cover and the second cover comprise a third interfacing area.

An apparatus including: a base plate; a guide rail being disposed on the base plate; a sliding bar with a first side being disposed on the guide rail, wherein the sliding rail includes a wedge on a second side of the sliding bar opposite the first side; and a heat sink, wherein the base plate and the heat sink form a slot for insertion of a pluggable module at a front of the slot.

A heat dissipation apparatus and antenna assembly using the same is disclosed herein. According to an embodiment of the present disclosure, a heat dissipation apparatus configured to cool a circuit board including at least one heat generation element is provided, the heat dissipation apparatus including: a plate disposed to face the circuit board; a plurality of first heat dissipation fins disposed in a first direction on one surface of the plate spaced apart from the circuit board; and a blowing unit disposed to face the one surface of the plate, the blowing unit including at least one fan configured to discharge air toward the one surface of the plate, wherein a space between two adjacent first heat dissipation fins defines a side flow path configured to guide the air discharged from the at least one fan.

The present application provides a scenario temperature planning method and apparatus, a computer device, and a medium, where the scenario temperature planning method includes: obtaining original data in a current temperature planning cycle in a target scenario, where the original data is data generated based on a user's temperature adjustment operation; performing data merging and data elimination processing on the original data to obtain valid data; and adjusting temperature planning data of the current temperature planning cycle based on the valid data to obtain temperature planning data of a next temperature planning cycle of the current temperature planning cycle, so as to adjust a temperature in a target scenario in the next temperature planning cycle. The technical solution enables the adjusted temperature to meet the user's temperature requirements without requiring the user to manually plan and set the temperature, thereby improving user experience.

A heat exchanger includes a plurality of fins that are spaced from each other and are arranged to divide a heat medium flow passage into a plurality of narrow passages. Each fin incudes a plurality of thick wall portions and a plurality of thin wall portions which are alternately arranged in a passage longitudinal direction. Each adjacent two of the plurality of fins, which are adjacent to each other, are defined as one fine and another fin, and each of the plurality of thick wall portions of the one fin is opposed to an adjacent one of the plurality of thin wall portions of the another fin in a fin arrangement direction, and each of the plurality of thin wall portions of the one fin is opposed to an adjacent one of the plurality of thick wall portions of the another fin in the fin arrangement direction.

A computer device and a host module thereof are provided. The host module includes a case, a motherboard, and a power supply unit. The case includes a first side plate, a second side plate, a front panel, a rear panel, and a separation structure. The rear panel is located on an opposite side of the front panel. The first side plate, the second side plate, the front panel, and the rear panel enclose an internal space. The separation structure is located in the internal space, extends from the first side plate to the second side plate, and divides the internal space into a first part and a second part. The second part is located under the first part. The motherboard is disposed in the first part. The power supply unit is disposed in the second part, and is electrically connected to the motherboard.

A system for controlling temperatures within a rearview assembly may comprise a rearview assembly having a housing defining an opening and at least one of a display element and an electro-optic element disposed in the opening; and an in-cabin monitoring system comprising at least one printed circuit board; an imager disposed on one of the at least one printed circuit boards, an image signal processor in communication with the imager, at least one light source, and at least one heat spreader positioned within the housing. The heat spreader may be stamped aluminum. The imager may be at a distance from the at least one light source.