A thermoelectric conversion module has a long support, a plurality of first metal layers formed on one surface of the support at intervals in a longitudinal direction of the support, a plurality of thermoelectric conversion layers formed at intervals in the longitudinal direction of the support, and a connection electrode for connecting the thermoelectric conversion layers adjacent in the longitudinal direction of the support, and a second metal layer formed on the other surface of the support, in which the first and the second metal layers have low rigidity portions that have rigidity lower than rigidity of other regions and extend in a width direction of the support, the low rigidity portions of the first and the second metal layers are formed at the same positions in the longitudinal direction, and the support is alternately bent into a mountain fold and a valley fold at the low rigidity portions.

A thermoelectric module comprising a central thermoelectric assembly of cylindrical tubular shape inside which a first cold fluid flows and outside which a hot fluid flows. This module is characterized in that it also comprises at least one peripheral thermoelectric assembly having: an outer face in contact with a second cold fluid; an inner face positioned on a peripheral boundary surrounding the central thermoelectric assembly, said boundary defining a channel between said central and peripheral thermoelectric assemblies where the hot fluid flows.

The present invention relates to a soft actuator moving linearly against external stimuli whose expansion and contraction can be actively controlled, suggesting that the actuator of the invention overcomes the problems of the conventional soft actuators, The soft actuator of the present invention can be repetitively driven quickly and accurately by controlling heating and cooling by using thermoelectric effect and, the soft actuator of the present invention can realize bending, tensioning, compression, and rotational driving of a tubular device containing a driver.

A hybrid generator using a thermoelectric generation and a piezoelectric generation are provided. The hybrid generator includes first and second insulating layers spaced apart from each other; a thermoelectric structure disposed between the first and second insulating layers; a first electrode disposed on the second insulating layer; a piezoelectric structure disposed on the first electrode; a third insulating layer disposed on the piezoelectric structure; and a second electrode disposed on the third insulating layer.

Disclosed are apparatus and methodology for constructing thermoelectric devices (TEDs). N-type elements are paired with P-type elements in an array of pairs between substrates. The paired elements are electrically connected in series by various techniques including brazing for hot side and/or also cold side connections, and soldering for cold side connections while being thermally connected in parallel. In selected embodiments, electrical and mechanical connections of the elements may be made solely by mechanical pressure.

The present disclosure is related to structures for and methods for producing thermoelectric devices. The thermoelectric devices include multiple stages of thermoelements. Each stage includes alternating n-type and p-type thermoelements. The stages are sandwiched between upper and lower sets of metal links fabricated on a pair of substrate layers. The metal links electrically connect pairs of n-type and p-type thermoelements from each stage. There may be additional sets of metal links between the multiple stages. The individual thermoelements may be sized to handle differing amounts of electric current to optimize performance based on their location within the multistage device.

Provided herein is a thermoelectric element that includes a cold end, a hot end, and a p-type or n-type material having a length between the hot end and the cold end. The p-type or n-type material has an intrinsic Seebeck coefficient (S), an electrical resistivity (), and a thermal conductivity (). Each of two or more of S, , and generally increases along the length from the cold end to the hot end. The thermoelectric element may be provided in single-stage thermoelectric devices providing enhanced maximum temperature differences. The single-stage thermoelectric devices maybe combined with one another to provide multi-stage thermoelectric devices with even further enhanced maximum temperature differences.

A housing for a thermoelectric module can stably protect individual elements of the thermoelectric module such as thermoelectric elements, electrodes, and insulating boards, while maintaining power generation performance of the thermoelectric module. The housing for a thermoelectric module includes: a housing enveloping at least one thermoelectric module; and a heat barrier unit configured to prevent a flow of heat from being transferred through a sidewall of the housing.

Disclosed are apparatus and methodology for constructing thermoelectric devices (TEDs). N-type elements are paired with P-type elements in an array of pairs between substrates. The paired elements are electrically connected in series by various techniques including brazing for hot side and/or also cold side connections, and soldering for cold side connections while being thermally connected in parallel. In selected embodiments, electrical and mechanical connections of the elements may be made solely by mechanical pressure.

A semiconductor cell that allows thermally excited electron hole pairs to be harnessed as usable energy. The material bandgap and dopant levels of various layers allows for voltage potential and current to be created. The energy production results in a lowered temperature in the cell. Energy is transferred back to the cell in the form of heat from the surroundings via convection or conduction. Cell layout is a n n.sup.++-p.sup.++ p configuration and a module has multiple cells.