Abstract: A flameless cooking apparatus for use with liquid fuels and for indoor or outdoor use under field operations. The burner exhibits low CO and hydrocarbon emissions and meets standards for burner thermal efficiency when used with JP-8 fuel. The apparatus employs a catalytic burner having among its parts (i) a combustion catalyst; (ii) a conductive surface, e.g., cooking surface; and (iii) in between the catalyst and the conductive surface and in direct physical contact with both surfaces, a heat spreader for conductively transferring heat of combustion from the catalyst to the conductive surface. Also claimed are a method of heat flux and a method of cooking.

Abstract: The invention provides an apparatus for generating heat and transferring the heat to a heater head of an external combustion engine, preferably, a Stirling engine. Fuel and air are introduced into a combustion chamber and mixed to form an air/fuel mixture. The air/fuel mixture is combusted over a combustion catalyst positioned in physical contact with a heat spreader, which itself is positioned in physical contact with a heat acceptor surface. The heat acceptor surface is secured in thermal communication with the heater head. Depending upon the design of the heater head, heat flux from the heat acceptor surface into the heater head may occur radially or non-radially.

Abstract: The invention provides an apparatus and a method for transferring heat by conduction to the internal heat acceptor of an external combustion engine. Fuel and air are introduced into a combustion chamber and mixed to form an air/fuel mixture. The air/fuel mixture is directed into a catalytic reactor that is positioned in direct contact (non-spaced-apart relation) with the heater head. Heat is transferred via conduction from the catalytic reactor to the heater head; and the catalytic reaction products are exhausted with heat recuperation.

Abstract: A flameless cooking apparatus for use with liquid fuels and for indoor or outdoor use under field operations. The burner exhibits low CO and hydrocarbon emissions and meets standards for burner thermal efficiency when used with JP-8 fuel. The apparatus employs a catalytic burner having among its parts (i) a combustion catalyst; (ii) a conductive surface, e.g., cooking surface; and (iii) in between the catalyst and the conductive surface and in direct physical contact with both surfaces, a heat spreader for conductively transferring heat of combustion from the catalyst to the conductive surface. Also claimed are a method of heat flux and a method of cooking.

Abstract: The invention provides an apparatus for generating heat and transferring the heat to a heater head of an external combustion engine, preferably, a Stirling engine. Fuel and air are introduced into a combustion chamber and mixed to form an air/fuel mixture. The air/fuel mixture is combusted over a combustion catalyst positioned in physical contact with a heat spreader, which itself is positioned in physical contact with a heat acceptor surface. The heat acceptor surface is secured in thermal communication with the heater head. Depending upon the design of the heater head, heat flux from the heat acceptor surface into the heater head may occur radially or non-radially.

Abstract: The invention provides an apparatus and a method for transferring heat by conduction to the internal heat acceptor of an external combustion engine. Fuel and air are introduced into a combustion chamber and mixed to form an air/fuel mixture. The air/fuel mixture is directed into a catalytic reactor that is positioned in direct contact (non-spaced-apart relation) with the heater head. Heat is transferred via conduction from the catalytic reactor to the heater head; and the catalytic reaction products are exhausted with heat recuperation.

Abstract: A metallic thermocouple probe is capable of withstanding temperatures in excess of 1650.degree. C. in oxidizing environments. First and second electrically conductive leads of dissimilar metals are joined at an extreme sensing end and extend to a distant readout device. Metal oxide insulation such as beryllium oxide, magnesium oxide, and aluminum oxide, electrically isolates the conductive leads and thermally isolates them from the environment. The extreme sensing end of the thermocouple probe is encapsulated to render it impermeable to the formation of oxides thereon. This encapsulation includes a protective coating composed of a non-porous ceramic material, preferably a cementation applied disilicide. Additionally, a high temperature structural sheath overlies the insulation adjacent the extreme sensing end and a low temperature sheath overlies the insulation adjacent the first sheath distant from the extreme sensing end.

Abstract: The invention concerns the application of a layer of ceramic or glass particles to the surface of a substrate which is to be heated. The glass or ceramic particles are sized and mixed with an organic binder which yields a thin slurry consistency. The carrier or binder hardens. The part is subjected to a running environment with air flow directed across its surface, and then inspected after test to determine flow direction and possibly relative magnitude of the flow. This binder leaves essentially no residue after combustion and holds the glassy particles together so they adhere to the substrate at low temperature. The glass or ceramic particles in the coating are chosen to have a melting point below the operating temperature of the surface so that the applique will flow in the direction of gas movement. Additionally, the choice of melting point is made to give the coating a viscosity which permits enough "smearing" at the velocity and time of interest for visual inspection.