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.

Disclosed is a computing device, comprising a frame, a computing apparatus, a controller, a power source and a heat dissipation device, wherein the computing apparatus is arranged in the frame and comprises a power source interface; the power source comprises a power source connection end, and also comprises a connection box connected to the frame; the power source interface extends from the frame into the connection box; the power source connection end extends into the connection box; and the power source interface and the power source connection end are connected in the connection box via one or more conducting bars.

A quick release mechanism includes a fixed component, a first assembly, and a second assembly. The fixed component has a guiding portion and a first positioner. The first assembly includes an engagement component and a return component. The engagement component is pivotably disposed on the fixed component and includes a first protrusion part, a first press part, and a second positioner. The return component keeps the engagement component in an engaged position. The second assembly is removably inserted into the guiding portion. The second assembly includes a second protrusion part and a contact part. The engagement component is movable away from the engaged position by abutting of the second protrusion part on the first protrusion part or by abutting of the contact part on the first press part during insertion of the second assembly into the guiding portion.

A magnet mount assembly is provided for quickly mounting and releasing the portable electronic device to various objects, including stands, clamps and/or holders (i.e., support mount) to support the portable electronic device in elevated positions at a variety of angles. The magnet mount assembly may attach to the back of the temperature control device or electronics case or to the back of the portable devices by, for example, connecting to the universal mount. The mount may further include pong pins or other electrical connectors for supplying power and/or data to the cooling mount and/portable electronic device when the magnet mount assembly.

In some embodiments, apparatuses and methods are provided herein useful for environmental control inside an enclosure including an enclosure, an exhaust fan located in proximity to an outlet of the enclosure, a temperature sensor located proximate the exhaust fan and configured to provide exhaust air temperature data, a first sensor located proximate a supply intake of one of one or more electronic equipment and configured to provide sensor data associated with air that is supplied to the one of the one or more electronic equipment, a fan control unit (FCU), and a power control unit (PCU). The FCU is configured to adjust fan speed of the exhaust fan. The PCU is configured to receive the sensor data from the first sensor; receive the exhaust air temperature data; and provide the fan speed control data to the FCU based on the sensor data and the exhaust air temperature data.

In one or more embodiments, an information handling system fan may include: a hub; multiple fan blades radially attached to the hub and configured to rotate perpendicularly to a longitudinal axis of the information handling system fan; an electric motor; a drive shaft parallel to the longitudinal axis of the information handling system fan that attaches the electric motor to the hub; and a housing that houses the hub, the multiple fan blades, and the electric motor. In one or more embodiments, the housing may have a concave portion perpendicular to the longitudinal axis of the information handling system fan, in which the housing may include a first vent in the concave portion of the housing to intake air as the multiple fan blades rotate and in which the housing may include a second vent configured to exhaust the air as the multiple fan blades rotate.

A power transmitter includes a transmitter antenna includes at least one coil configured to transmit the power signal to the power receiver, the at least one coil and a shielding comprising a ferrite core and defining a cavity, the cavity configured such that the ferrite core substantially surrounds all but the top face of the at least one coil. The power transmitter includes a housing configured for housing, at least, the transmitter antenna. The housing defines an airflow opening configured to provide an airflow to a first airflow channel and to a second airflow channel. The first and second airflow channels configured to provide the airflow to one or more of a top face of a mobile device thereon and a bottom face of the mobile device.

A wireless charging device is provided. The plurality of protrusion portions are utilized to form the first gap between the top plate and the mobile device, so as to increase the distance formed between the top plate and the mobile device. Consequently, the first interfacial thermal resistance formed between the transmitter coil assembly and the receiver coil located in the mobile device is increased, and the second heat source generated from the transmitter coil assembly is dissipated through the wireless charging device instead of being transferred to the receiver coil located in the mobile device. In that, the temperature of the mobile device is controlled to be under the tolerance temperature threshold value during the charging process of the wireless charging device. Consequently, the charging power is enhanced, and the charging speed is increased.

An electronic apparatus (1) includes a cooling fan (5) configured to generate an airflow that cools a part mounted on a circuit board (50), a flow passage wall (34) defining a flow passage of the airflow fed from the cooling fan (5), and a dust collecting chamber Ds configured to capture dust in the airflow and store the captured dust, the dust collecting chamber Ds being provided to the flow passage wall (34). According to this, the amount of the dust fed to air supply targets such as a heat sink and a power supply unit together with air can be reduced.

An inlet module is adapted to be disposed on a housing of an electronic device, and includes an insert board and at least one adjusting plate. The insert board has a plurality of first air passages, at least one second air passage, and at least one positioning unit. The second air passage is located between two of the first air passages, and has an area larger than that of each first air passage. The adjusting plate has an opening having an area smaller than that of the second air passage. The adjusting plate is operable to be positioned at a position where the opening and the second air passage are overlapped with each other, thereby reducing an area of the airflow passing through the second air passage.