A thermophotovoltaic generator having a solid body located in a combustion chamber of a burner, with the surface of the solid body being excited to a state of radiation by an air-fuel mixture that is supplied by a delivery unit to the burner, where it combusts, and the radiation strikes a photocell, which then generates electrical energy; and having an exhaust pipe discharging the hot combustion gases from the combustion chamber. A premixing chamber is closed from the combustion chamber to the outside by a porous solid body, the photocell is positioned opposite the porous solid body and upstream from the latter in the premixing chamber, a reflector is located downstream from the solid body and opposite the latter outside the premixing chamber so that it reflects the radiation produced by the combustion of the air-fuel mixture on the solid body in the opposite direction from the combustion gases flowing to the photocell, and the air-fuel mixture is delivered by the delivery unit to the premixing chamber so that the non-combusted air-fuel mixture flows around the photocell from behind, thus cooling it.

A thermophotovoltaic generator apparatus has: a burner that is supplied with a fuel and an air, and burns the fuel; an emitter heated by combustion heat produced by the burner; a photoelectric conversion cell that converts radiant light from the emitter into electric power; and a cell holder portion that holds the photoelectric conversion cell. A cooling device is provided for causing a cooling liquid to receive heat from the photoelectric conversion cell by contacting the cooling liquid and a back surface of the cell holder portion with each other. A surface of the cell holder portion that contacts the cooling liquid is a non-horizontal surface. The apparatus employs at least two kinds of cooling liquids.

A method and apparatus for the direct conversion of energy by thermovoltaic energy conversion having first and second tubesheets, at least one photon emitter plate secured to and extending from the first tubesheet, at least one cold plate secured to and extending from the second tubesheet, a plurality of thermovoltaic cells disposed along oppositely disposed exterior surfaces of the cold plate, and means cooperating with the tubesheet for maintaining a vacuum between the photon emitter plate and the cold plate.

A DC power system receives AC electrical power and DC electrical power from separate first and second sources simultaneously. The DC power system delivers DC electrical power to an output for use by a load requiring DC power. The DC power system includes a converter to convert AC electrical power to DC electrical power and a power sharing control device to control and distribute the DC electrical power to an output. The first source of DC electrical power includes a storage battery, which provides standby DC electrical power to the DC power system. It also includes a power sharing device, which maintains the storage battery fully charged for use at peak loads, when the DC output electrical power is insufficient to meet the DC load. The second source of DC electrical power is a cogenerator such as a fuel cell, a thermo photovoltaic generator or an internal combustion engine and an alternator for generating and delivering DC electrical power to the power sharing device, while producing and delivering waste heat for use of an external load requiring this heat.

The TPV generator unit insert has air circulation fans that supply air for both TPV cell cooling and heat transfer and room air circulation. Combustion air is supplied by a blower and mixed with natural gas or propane in a mixing chamber. Fuel and air mixing is enhanced by injecting the fuel counter to the air flow in an air supply tube within the mixing chamber. The fuel and air mixture is then injected into a combustion chamber and burned. The hot combustion gases then heat an IR emitter. Infrared radiation from the emitter is then incident on TPV cells, where electricity is produced. The hot by-product gases then transfer heat to the circulating room air in an upper plenum prior to exiting the room through the flue pipe. The yellow-orange glow from the emitter is visible through a front glass window, which then produces a very aesthetically pleasing effect. The rectangular unit is designed to include at least two cell panels at front and at the back. Each panel contains 40 cells and produces approximately 80 Watts. Each panel is approximately 2" high by 10" long. The unit then produces approximately 160 W for battery charging. The heat output is between 20,000 and 30,000 BTU per hour. The rectangular unit overall dimensions are 15" tall by 15" wide by 8" deep, though other dimensions and shapes are within the scope of this invention.