Abstract: A novel inline pilot assembly and method of flame detection for use with combustion applications for oil or gas processing is provided wherein the pilot assembly includes a pilot novel assembly with a unique placement of fuel and induction holes to improve flame stability, promote flame anchoring near the diffuser, and discourage the pilot flame front from migrating forward away from the diffuser.

Abstract: A premix gas burner comprises a burner deck which comprises a fiber based substrate and a perforated plate or a screen supporting the fiber based burner substrate. The premix gas burner further comprises at least two contact wires that are forming a thermocouple. The contact wires are directly or indirectly fixed to the burner deck to measure a temperature of the burner deck when the premix gas burner is in operation. The fiber based substrate is locally at least partly connected directly or indirectly to the perforated plate or the screen in the region where the contact wires of the thermocouple are directly or indirectly fixed to the burner deck.

Abstract: Systems and methods for converting engine heat energy to electricity using a thermoelectric conversion device are provided herein. One example system may include an engine heat source, a thermoelectric conversion device for converting heat into electricity, and a heat pipe. The heat pipe is positioned so that when the temperature of the engine exhaust is too high, the excess heat may be transferred away from the thermoelectric conversion device to the heat sink via the heat pipe.

Abstract: An apparatus is provided that includes an engine, an exhaust system, and a thermoelectric generator (TEG) operatively connected to the exhaust system and configured to allow exhaust gas flow therethrough. A first radiator is operatively connected to the engine. An openable and closable engine valve is configured to open to permit coolant to circulate through the engine and the first radiator when coolant temperature is greater than a predetermined minimum coolant temperature. A first and a second valve are controllable to route cooling fluid from the TEG to the engine through coolant passages under a first set of operating conditions to establish a first cooling circuit, and from the TEG to a second radiator through at least some other coolant passages under a second set of operating conditions to establish a second cooling circuit. A method of controlling a cooling circuit is also provided.

Abstract: A thermoelectric generator assembly includes a thermoelectric generator with hot and cold junction flanges. The hot junction flange includes an adapter shaped for thermally coupling to a process vessel. The thermoelectric generator producing a thermoelectric power output. A heat sink thermally couples to ambient air and has a heat sink flange. A heat pipe assembly includes fluid in a circulation chamber. The circulation chamber has an evaporator flange mounted to the cold junction flange and a condenser flange mounted to the heat sink flange. At least a portion of the fluid transports heat from the evaporator flange to the condenser flange. When a heat pipe assembly on a cold junction flange is used with many of the types of heat flows that are available in process industries, more efficient thermoelectric power generation can be provided in the process industries.

Abstract: In one embodiment, a vortex tube has a gas inlet port, a cold gas outlet port and a hot gas outlet port. A thermoelectric potential generator having hot gas inlet port coupled to the hot gas outlet port of the vortex tube, a cold gas inlet port coupled to the cold gas outlet port of the vortex tube, and a thermoelectric element coupled in heat conducting relationship between the cold gas inlet port and the hot gas inlet port to promote the flow of heat/cold through the thermoelectric element from the hot gas flowing into the hot gas inlet port to the cold gas flowing through the cold gas inlet port. In another, a compressed gas source, a thermoelectric element having first and second sides, and an expansion nozzle are coupled in series. The expansion nozzle is coupled between the compressed gas source and the first side. The thermoelectric element includes an electrical output port.

Abstract: A thermoelectric power generator is disclosed for use to generate electrical power from heat, typically waste heat. An intermediate heat transfer loop forms a part of the system to permit added control and adjustability in the system. This allows the thermoelectric power generator to more effectively and efficiently generate power in the face of dynamically varying temperatures and heat flux conditions, such as where the heat source is the exhaust of an automobile, or any other heat source with dynamic temperature and heat flux conditions.

Abstract: Apparatus having a cooling device capable of both power generation using heat from a heat-generating component and cooling of the heat-generating component is provided. The cooling device has a heat-receiving part which receives heat conducted from a CPU, which is an external heat-generating component, a thermoelectric conversion part arranged to absorb heat from the heat-receiving part and having operating modes including a mode of cooling the heat-receiving part by being supplied with a current and a power generation mode of converting heat received from the heat-receiving part into a current and outputting the current, and a selecting part which makes a selection according to a temperature condition of the CPU as to in which one of the modes the thermoelectric conversion part should be operated.

Abstract: A thermoelectric generator includes a plurality of thermoelectric junctions embedded in each of a pair of thermally conductive and electrically non-conductive layers, these layers being separated by a thermally and electrically non-conductive layer. The junctions are connected to form a thermopile. An absorbent layer is provided adjacent one of the thermally conductive layers. A liquid such as water is applied to the absorbent layer, so that evaporation of the liquid from the absorbent layer enhances the temperature differential between the two thermally conductive layers.

Abstract: A process and apparatus (70) for making a large area photovoltaic device (22) that is capable of generating low cost electrical power. The apparatus (70) for performing the process includes an enclosure (126) providing a controlled environment in which an oven (156) is located. At least one and preferably a plurality of deposition stations (74,76,78) provide heated vapors of semiconductor material within the oven (156) for continuous elevated temperature deposition of semiconductor material on a sheet substrate (24) including a glass sheet (26) conveyed within the oven. The sheet substrate (24) is conveyed on a roller conveyor (184) within the oven (156) and the semiconductor material whose main layer (82) is cadmium telluride is deposited on an upwardly facing surface (28) of the substrate by each deposition station from a location within the oven above the roller conveyor.

Abstract: A low voltage high amperage thermopile generating and electron storage unit is disclosed wherein current is formed by heating and cooling alternate junctions of dissimilar metals arranged in a circular fashion and may be enhanced with an electrical flux pump. Current may be withdrawn using an ultra fast thermopile type switch to connect to an electrical load source.

Abstract: A method and apparatus are described for directly converting heat to electricity within an array of thermoelements and heat pipes. The thermoelectric generator contains two conduits for two fluid streams, and a plurality of thermal bridges connecting points in both fluid streams, placing them in an overall counterflow heat exchange relationship. Each thermal bridge comprises at least one heat exchange surface with the first fluid stream, at least one heat exchange surface with the second fluid stream and at least one heat pipe, delivering heat to and/or from the thermoelectric element. The rapid heat delivery capability of the heat pipes, in combination with the counterflow heat exchange relationship between the two fluid streams within the generator, are responsible for the simultaneous considerable improvement of efficiency and power density of the generator.

Abstract: A thermoelectric voltage generator utilizing heat from a vehicle exhaust to rovide a differential temperature through a plurality of thermoelectric elements comprised of serially connected alternate N- and P-type semiconductors having alternate electrical contacts between adjacent elements at a hot side and at a cold side to produce electrical energy in accordance with the Seebeck effect and in which the electrical energy is applied to an external device by way of connections at opposite ends of said plurality of thermoelectric elements.