The present disclosure provides a carrying apparatus and a carrying method, the carrying apparatus includes: a carrying part configured to carry an object to be carried; an adhesive assembly disposed on the carrying part, a viscosity of the adhesive assembly is variable, and the carrying apparatus is configured to selectively adhere to or separate from the object to be carried according to a change of the viscosity; and a supporting part disposed on the carrying part and configured to support the object to be carried so that the object to be carried separates from the carrying part.

A method for forming a unique, environmentally-friendly energy harvesting element is provided. A configuration of the energy harvesting element causes the energy harvesting element to autonomously generate renewable energy for use in electronic systems, electronic devices and electronic system components. The energy harvesting element includes a first conductor layer, a low work function layer, a dielectric layer, and a second conductor layer that are particularly configured in a manner to promote electron migration from the low work function layer, through the dielectric layer, to the facing surface of the second conductor layer in a manner that develops an electric potential between the first conductor layer and the second conductor layer. An energy harvesting component is also provided that includes a plurality of energy harvesting elements electrically connected to one another to increase a power output of the electric harvesting component.

According to one embodiment of the present invention, a thermoelectric leg comprises: a thermoelectric material layer comprising Bi and Te; a first metal layer and a second metal layer respectively arranged the thermoelectric material layer; a first adhesive layer arranged between the thermoelectric material layer and the first metal layer and comprising the Te, and a second adhesive layer arranged between the thermoelectric material layer and the second metal layer and comprising the Te; and a first plating layer arranged between the first metal layer and the first adhesive layer, and a second plating layer arranged between the second metal layer and the second adhesive layer, wherein the thermoelectric material layer is arranged between the first metal layer and the second metal layer, the amount of the Te is higher than the amount of the Bi in the thermoelectric material layer.

The present disclosure relates to a thermoelectric material, and more specifically to a superlattice thermoelectric material and a thermoelectric device using the same. The superlattice thermoelectric material has a composition of a following Chemical Formula 1:
(AX).sub.n(D.sub.2X′.sub.3).sub.m  ,<Chemical Formula 1> wherein, in the Chemical Formula 1, A is at least one of Ge, Sn, and Pb, X is a chalcogen element, and at least one of S, Se, and Te, D is at least one of Bi and Sb, each of n and m is an integer between 1 and 100, and A or X is at least partially substituted with a dopant.

A method of fabricating a thermoelectric device includes providing a thermoelectric device having a thermally conductive first plate, a thermally conductive second plate, and a plurality of thermoelectric elements in a region bounded by and including the first plate and the second plate. The plurality of thermoelectric elements is in thermal communication with the first plate and the second plate. The method further includes forming a polymeric coating in the region on at least one surface of the first plate, at least one surface of the second plate, and at least one surface of the plurality of thermoelectric elements.

A thermal display module configured to create a thermal pattern discerned by a visually impaired user to determine his or her surroundings. The thermal display module includes a plurality of thermoelectric modules, each of which are configured to cool or heat a pixel plate in close proximity to a user's skin. The cooling or heating of each of the thermoelectric modules create the thermal pattern discernable by the user.

A thermoelectric watch including a thermoelectric generator; a voltage booster connected to the thermoelectric generator; an energy management circuit connected to the voltage booster and configured to control the charging of at least one energy storage element, the energy management circuit including an output configured to change from a first logic state to a second logic state when the thermoelectric generator starts generating electrical energy, and to change from the second logic state to the first logic state when the thermoelectric generator finishes generating electrical energy.

A handheld device has a projector that projects a pattern of light onto an object, a first camera that captures the projected pattern of light in first images, a second camera that captures the projected pattern of light in second images, a registration camera that captures a succession of third images, one or more processors that determines three-dimensional (3D) coordinates of points on the object based at least in part on the projected pattern, the first images, and the second images, the one or more processors being further operable to register the determined 3D coordinates based at least in part on common features extracted from the succession of third images, and a mobile computing device operably connected to the handheld device and cooperating with the one or more processors, the mobile computing device operable to display the registered 3D coordinates of points.

A thermoelectric element according to an embodiment of the present invention comprises: a first metallic substrate; a first resin layer which is disposed on the first metallic substrate and comes in direct contact with the first metallic substrate; a plurality of first electrodes disposed on the first resin layer; a plurality of P-type thermoelectric legs and a plurality of N-type thermoelectric legs disposed on the plurality of first electrodes; a plurality of second electrodes disposed on the plurality of P-type thermoelectric legs and the plurality of N-type thermoelectric legs; a second resin layer disposed on the plurality of second electrodes; and a second metallic substrate disposed on the second resin layer, wherein a surface of the first metallic substrate that faces the first resin layer comprises a first region and a second region disposed inside the first region, wherein a surface roughness of the second region is greater than a surface roughness of the first region, wherein the first resin layer is disposed on the second region.

A ZrCoBi-based p-type half-Heusler material can have a formula: ZrCoBi.sub.1-x-ySn.sub.xSb.sub.y, where x can vary between 0.01 and 0.25, and y can vary between 0 and 0.2. An average dimensionless figure-of-merit (ZT) for the material can be greater than or equal to about 0.80 as calculated by an integration method for temperatures between 300 and 973 K. A ZrCoBi-based n-type half-Heusler material can have a formula: ZrCo.sub.1-xNi.sub.xBi.sub.1-ySb.sub.y, where x can vary between 0.01 and 0.25, and y can vary between 0 and 0.3. The material has an average dimensionless figure-of-merit (ZT) is greater than or equal to about 0.65 as calculated by an integration method for temperatures between 300 and 973 K.