[Object] To provide a thermoelectric material that reduces, when a thermoelectric conversion module is formed therefrom, contact resistance with an electrode and will not be peeled; the thermoelectric conversion module using the thermoelectric material; a method of producing the same, and a Peltier device.

[Solving Means] A thermoelectric material according to the present invention includes a thermoelectric substance and a solvent, and the solvent has a vapor pressure of 0 Pa or more and 1.5 Pa or less at 25° C., has a storage elastic modulus G′ in a range of 1×10.sup.1 Pa or more and 4×10.sup.6 Pa or less, and has a loss elastic modulus G″ in a range of 5 Pa or more and 4×10.sup.6 Pa or less.

A perpetual self-sustained frictionless maglev generator started from an external power or battery source is disclosed. The power from the generator can be remote at each station avoiding vulnerability from terrorist attacks. All automobiles, airplanes, watercraft, and space ships would be self-sustained and not require any fuel unless for emergency backup purposes only. They all can be measured/controlled by GPS on a distance used and charged for that use accordingly on a monthly basis. Nuclear disaster would not be a threat because the government could use this generator to power their apparatus instead.

A magnetic field propulsion unit includes a magnetic field generating device with multiple conductive lines conduct a current to generate a magnetic field; a contact breaker arrangement individually transitions each of the multiple conductive lines from a conductive state to a non-conductive state; an energy supply unit provides the magnetic field generating device with electrical energy; and a control unit controls the energy supply unit so that energy supply to each individual conductive line is controlled and control the contact breaker arrangement. The multiple conductive lines are arranged along a longitudinal axis. The control unit supplies a first conductive line with electrical energy so that a first magnetic field surrounding the first conductive line is generated, transitions the first conductive line to a non-conductive state, and supplies a second conductive line with electrical energy so that a second magnetic field is generated.

A magnetic field propulsion unit includes a magnetic field generating device with multiple conductive lines conduct a current to generate a magnetic field; a contact breaker arrangement individually transitions each of the multiple conductive lines from a conductive state to a non-conductive state; an energy supply unit provides the magnetic field generating device with electrical energy; and a control unit controls the energy supply unit so that energy supply to each individual conductive line is controlled and control the contact breaker arrangement. The multiple conductive lines are arranged along a longitudinal axis. The control unit supplies a first conductive line with electrical energy so that a first magnetic field surrounding the first conductive line is generated, transitions the first conductive line to a non-conductive state, and supplies a second conductive line with electrical energy so that a second magnetic field is generated.

A device is provided that includes a logic processor, a power storage cell, a sensor, a wireless logic and a power source. The power source is configured to harvest power in response to exposure to radio frequency (RF) energy using an antenna element of the device. The harvested power is transferred to the power storage cell such that when the power storage cell has a usable amount of power the logic processor (a) samples data using the sensor, (b) processes the sample data into a message that is encrypted, and (c) transmits the message using the wireless logic to an end node that is configured to receive the message from the device. When usable amount of power is not present in the power storage cell during any one of (a)-(c), data is saved in persistent memory until additional harvested power is present in the power storage cell.

The present invention provides a thermoelectric conversion module which can utilize sunlight and solar heat by using high output charge-transport-type thermoelectric conversion elements. The present invention provides A thermoelectric conversion module which comprises at least a thermoelectric conversion module-element in which charge-transport-type thermoelectric conversion elements are formed and a photothermal conversion substrate containing photothermal conversion material, wherein the thermoelectric conversion module-element comprises an insulating substrate, and n-type and/or p-type charge-transport-type thermoelectric conversion elements are formed on the insulating substrate, wherein the charge-transport-type thermoelectric conversion element comprises a charge transport layer and thermoelectric conversion material layers and electrodes, wherein the photothermal conversion substrate is disposed so that it absorbs external light and converts it into heat and transfers the heat to the electrodes or the thermoelectric conversion material layers disposed on the charge transport layers.

[Object] To provide a thermoelectric generation cell using a safe and inexpensive general-purpose thermoelectric material. [Solving Means] A thermoelectric generation cell, including: a fire-resistant-material frame (310) that holds a plurality of stacked thermoelectric generation units in a state of being insulated from adjacent thermoelectric generation units with each other; a heating section (311) of a plurality of stacked bodies of the thermoelectric generation units, the heating section being provided to the fire-resistant-material frame; and first and second cooling insulation oil sections (312a and 312b) that are provided at both sides of the fire-resistant-material frame, the first and second cooling insulation oil portions (312a and 312b) being provided on sides of first and second cooling sections of the thermoelectric generation units, the thermoelectric generation cell having a structure in which the thermoelectric generation units are bridged while being extended between the first cooling insulation oil section, the fire-resistant-material frame, and the second cooling insulation oil section.

A thermoelectric generator transmitter includes: a hollow exterior frame having open ends; a heat-receiving plate covering one of the open ends of the exterior frame; a columnar member standing on the heat-receiving plate; a thermoelectric generation module arranged for facilitating heat transfer between the columnar member and the thermoelectric generation module; a radiator plate covering a part of the other one of the open ends of the exterior frame, the part corresponding to a location of the thermoelectric generation module; a processor drivable by electricity generated by the thermoelectric generation module and capable of outputting a detection signal detected by a sensor to an external device; and a terminal that receives the detection signal of the sensor from the external device. An inside of the exterior frame is divided into a location of the thermoelectric generation module and the processor and a location of the terminal.

Disclosed herein is a complex generator including a hydrophilic fiber membrane coated with an adsorption material. Electrical energy is generated in such a manner that the adsorption material is adsorbed onto a polar solvent in some region of the hydrophilic fiber membrane by asymmetrical wetting of the polar solvent for the hydrophilic fiber membrane.

A thermoelectric conversion module is a thermoelectric conversion module in which a plurality of thermoelectric conversion elements are electrically connected to each other via a first electrode portion disposed on first end side of the thermoelectric conversion elements and a second electrode portion disposed on the second end side of the thermoelectric conversion elements; a first insulating circuit board provided with a first insulating layer of which at least one surface is made of alumina and the first electrode portion formed of a sintered body of Ag formed on the one surface of the first insulating layer is disposed on the first end side of the thermoelectric conversion elements; and a glass component is present at an interface between the first electrode portion and the first insulating layer.