A system and method for energy harvesting in a data center has one or more collection devices, a thermoelectric device, and a controller for directing the operation of the thermoelectric device and other equipment in the data center. The waste heat generated by the servers in the data center is harnessed and directed into the thermoelectric device where the waste heat is converted to usable electrical energy under the direction of the controller. The recycled electrical energy is then combined with utility-input power and provided to the servers and other equipment in the data center for consumption.

Devices for generating electrical energy along with methods of fabrication and methods of use are disclosed. An example device can comprise one or more layers of a transition metal dichalcogenide material. An example device can comprise a mechano-electric generator. Another example device can comprise a thermoelectric generator.

A domestic kitchen appliance is provided. The domestic kitchen appliance includes a peltier device having a hot side and a cold side; a hot-side heat-sink attached to the hot side of the peltier device, the hot-side heat-sink configured to remove heat from the hot side of the peltier device and transfer the heat removed from the hot side of the peltier device to a cooking chamber; a cold-side heat-sink attached to the cold side of the peltier device, the cold-side heat-sink fluidly connected to an area to be cooled; and a voltage supply that supplies voltage to the peltier device to cause the peltier device to absorb heat from the cold-side heat-sink into the cold side of the peltier device and to expel heat from the hot side of the peltier device into the hot-side heat-sink. The area to be cooled is outside of the cooking chamber.

In a known method in which a cooling pipe that is fixed and rigid is used, variation in a distance from the center of an exhaust heat pipe to the outer surface of a thermoelectric conversion module, variation in the radius of curvature of the curved surface of a cooling pipe, and other factors produce a gap between the outer surface of the thermoelectric conversion module and the inside surface of the cooling pipe. The gap prevents the achievement of desired cooling performance and the improvement of power generation efficiency. A thermoelectric conversion module of the present invention includes two flexible substrates each made of a thin resin film and having mounting lands formed thereon, and a plurality of thermoelectric elements mounted on the mounting lands at high density, wherein one of the two flexible substrate has a plurality of slits to make the module easy to bend.

Systems and methods for wirelessly transmitting power across a room or space are disclosed herein. One such system is comprised of a power receiving element positioned to receive wireless power transfer, comprised of a power receiving cell and a retroreflector positioned proximate the power receiving cell, and a power transmission element configured to wirelessly transmit power towards the power receiving element. The power transmission element includes an optical power transmitter configured to emit a first laser beam with a first power density towards the receiving cell, a guard beam emitter positioned proximate the optical power transmitter and configured to emit a second laser beam with a second power density towards the retroreflectors, a light detector positioned proximate the guard beam emitter and configured to detect light reflected by the retroreflectors, and an interlock system configured to interrupt power transmission when a decrease in light incident from the retroreflectors is detected.

A ground-, sea- or aircraft-based laser transmission system can be implemented to remotely and wirelessly transmit power to an airship to be stored in an energy storage device, such as a battery. The airship can include an energy collection system having a plurality of photovoltaic cells arranged in an array and electrically coupled to the energy storage system. The energy collection system can also include one or more control link components positioned adjacent the array of photovoltaic cells. The control link components are configured to establish a control link between the airship and a power transmission system. The plurality of photovoltaic cells are configured to transfer laser beam transmitted energy from the power transmission system to the energy storage system.

We disclose an Infrared (IR) device comprising a first substrate comprising a first cavity; a dielectric layer disposed on the first substrate; a second substrate disposed on the dielectric layer and on the opposite side of the first substrate, the second substrate having a second cavity. The device further comprises an optically transmissive layer attached to one of the first and second substrates; a further layer provided to another of the first and second substrates so that the IR device is substantially closed. Holes are provided through the dielectric layer so that a pressure in the first cavity is substantially the same level as a pressure in the second cavity.

A device for powering electronic devices comprises a thermoelectric generator (TEG) applied over a temperature gradient. A combination of feed forward and feed back control of the TEG unit allows for continued operation that is robust to reversal of the temperature gradient, for example over the duration of a diurnal cycle.

A laminate includes, on a substrate, a first buffer layer substantially made of zirconium oxide or stabilized zirconia, a second buffer layer substantially made of yttrium oxide, a metal layer substantially made of at least one among platinum, iridium, palladium, rhodium, vanadium, chromium, iron, molybdenum, tungsten, aluminum, silver, gold, copper, and nickel, and a magnesium oxide layer substantially made of magnesium oxide, in this order.

A thermoelectric device may include a casing of tubular shape in which extends a plurality of modules of thermoelectric elements extending parallel to a longitudinal axis of the casing. Additionally, each module may include a plurality of thermoelectric elements having a cylinder or right prism shape with a central opening, a first fluid circulating through the central opening, and a second fluid circulating around the exterior periphery, and an enclosure capping said thermoelectric elements. Further, the enclosure may include at least an intake for the second fluid and a discharge for said second fluid. Furthermore, a number and dimensions of said thermoelectric element modules is optimized as a function of the ratio between a volume of the thermoelectric elements and a volume of the casing, a thickness of the enclosure and a distance between two adjacent modules.