A monolithic vapor chamber heat dissipating device uses a phase change liquid and one or more wicks to dissipate heat from a heat-generating system. The phase change liquid and one or more wicks may be directly coupled to the heat-generating system, or may be coupled to an intermediate evaporator substrate. The phase change liquid vaporizes as it absorbs heat from the heat-generating system. When the vapor rises and encounters a condenser substrate, the vapor condenses and transfers the heat to the condenser substrate. The condensed vapor is drawn by gravity and the one or more wicks to the phase change liquid coupled to the heat-generating system.

The invention is directed to a microfluidic device, which comprises distinct, parallel levels, including a first level and a second level. It further includes: a first microchannel, a second microchannel, and a node. This node comprises: an inlet port, a cavity, a via, and an outlet port. The cavity is formed on the first level and is open on a top side. The inlet port is defined on the first level; it branches from the first microchannel and communicates with the cavity through an ingress thereof. The outlet port, branches to the second microchannel on the second level. The via extends from the bottom side of the cavity, down to the outlet port, so the cavity may communicate with the outlet port. In addition, the cavity comprises a liquid blocking element to prevent an aqueous liquid filling the inlet port to reach the outlet port.

A thermal metamaterial device comprises at least one MEMS thermal switch, including a substrate layer including a first material having a first thermal conductivity, and a thermal bus over a first portion of the substrate layer. The thermal bus includes a second material having a second thermal conductivity higher than the first thermal conductivity. An insulator layer is over a second portion of the substrate layer and includes a third material that is different from the first and second materials. A thermal pad is supported by a first portion of the insulator layer, the thermal pad including the second material and having an overhang portion located over a portion of the thermal bus. When a voltage is applied to the thermal pad, an electrostatic interaction occurs to cause a deflection of the overhang portion toward the thermal bus, thereby providing thermal conductivity between the thermal pad and the thermal bus.

In various embodiments, component-level and product-level devices incorporated one or more low-profile cooling devices for dissipating heat. The low-profile cooling devices may include multiple benders arranged on a substrate. The benders are actuated so as to cause movement thereof, thereby producing an air flow.

A cooling system is described. The cooling system includes a cooling element having a central region and a perimeter. The cooling element is anchored at the central region. At least a portion of the perimeter is unpinned. The cooling element is in communication with a fluid. The cooling element is actuated to induce vibrational motion to drive the fluid toward a heat-generating structure.

An electro-optic device includes an interconnection board provided with an internal terminal, and a chip mounted on the interconnection board, and the chip is provided with a mirror, a drive element, and a chip-side terminal electrically connected to the drive element. The interconnection board includes a first surface on which an internal terminal is disposed, a second surface located on an opposite side to the first surface, a third surface connecting the first surface and the second surface to each other, and a fourth surface located on an opposite side to the third surface. The interconnection board is provided with a metal member exposed on the first surface and the second surface, and through holes (a first through hole and a second through hole) extending from the third surface to the fourth surface and having contact with the metal member.

In one or more embodiments, an apparatus generally comprises a microelectromechanical system (MEMS) module comprising a plurality of air movement cells and a power unit operable to control the plurality of air movement cells, and a housing configured for slidably receiving the MEMS module and positioning the MEMS module adjacent to a heat generating component of a network device. The MEMS module is operable to dissipate heat from the heat generating component and is configured for online installation and removal during operation of the heat generating component.

A MEMS micromirror device comprising, a reflective movable mirror, and a surrounding substrate coplanar to the mirror. A physical gap between the mirror and the surrounding substrate filled with fluid and finger structures extend from a perimeter of the movable mirror into the physical gap.

A cooling system is described. The cooling system includes a cooling element having a central region and a perimeter. The cooling element is anchored at the central region. At least a portion of the perimeter is unpinned. The cooling element is in communication with a fluid. The cooling element is actuated to induce vibrational motion to drive the fluid toward a heat-generating structure.

An electronic device comprising at least one electronic component mounted on a support and surrounded by a deformable casing containing a heat-conducting and electrically-insulating liquid, the device comprising a heat dissipation plate that is substantially parallel to the support and spaced apart therefrom, and heat exchange means for heat exchange by conduction between the casing and the plate, the heat-conducting and electrically-insulating liquid being selected and the casing being arranged so that thermal expansion of the oil leads to the casing applying force against the means for heat exchange by conduction.