A portable heat transfer apparatus including a combustion device, a thermoelectric convertor for receiving the heat of the combustion device at its high temperature side, transferring the heat from its low temperature side to a heat exchanger, and generating electric power depending on the temperature difference between the high temperature side and low temperature side. A heat medium forced circulating device is driven by the power generated from the thermoelectric converter for transferring heat medium to the heat exchanger. Also provided is a heat releasing device for circulating and releasing the heat medium exchanged of heat in the heat exchanger. Therefore, the heat exchanger can be heated through the thermoelectric converter while heating the thermoelectric converter with the combustion device, and by heating with the heat exchanger. The temperature difference between the high temperature side and low temperature side of the thermoelectric converter can be obtained rationally and sufficiently. Therefore, the apparatus is reduced in size and weight, and it is convenient for portable use.
The present invention relates to a method for energy conversion by gas flow over solid materials and also to a method for measurement of velocity of a gas flow over solid material such as doped semiconductors, graphite, and the like as a function of the 5 electricity generated in the solid material due to the flow of the gas along the surface thereof using a combination of the Seebeck effect and Bernoulli's principle.
In a power generating mechanism, a heat sink is mounted on a CPU of a notebook PC to diffuse heat generated by the CPU. A Seebeck element module is mounted in the heat sink to cause a large difference in temperature based on heat emitted from the heat sink and ventilation carried out by a fan unit. Electromotive force obtained from the Seebeck element module is used to drive selected components of the notebook PC.
There is provided an automatic burner driven generator system for powering a load. The Generator system generally comprises a burner unit for generating a thermal energy; a thermoelectric converter unit operatively coupled to the burner unit for transducing at least a portion of the thermal energy to a first electric power signal; a rechargeable battery unit operable to generate an output power signal for powering the load; a charging unit operably coupled to the thermoelectric converter and rechargeable battery units; and, a controller for automatically controlling the actuation of the units in programmed manner. The charging unit is operable to adaptively convert the first electric power signal to a second electric power signal for charging the rechargeable battery unit. The controller includes a microprocessor unit programmable configured to selectively actuate the units in accordance with a plurality of predetermined operational states.
A system for generating electrical energy includes heating a liquid to produce a vapor. The vapor is transported past electron collecting structure which collects electrons from the vapor. Electrons are added to the vapor prior to the vapor reaching the electron collecting structure by an antenna/diode combination.
The electric motor is equipped with an electronic control, for example in the form of a frequency converter (2) and comprises at least one Seebeck element (6) whose one side is connected to the motor (1) in a heat-conducting manner and whose other side is in heat-conducting connection with a cooling medium. The electrical output power of the Seebeck element (6) is led to the electronic control (2) of the motor (1).
