In some examples, a heating apparatus includes a light emitting diode (LED) array comprising an LED to heat a target object, and a heat sink thermally coupled to the LED array, to dissipate heat from the LED array, the heat sink comprising a plurality of refrigerant paths to pass a refrigerant through the heat sink in a plurality of different directions.

The invention comprises a solid state infrared source apparatus and method of use thereof, comprising: (1) an electrically conductive film comprising: an emission side and a back side opposite the emission side and a surface area to height ratio of at least five hundred to one; (2) a first dielectric film contacting the back side of the electrically conductive film; and (3) a reflective layer, the reflective layer embedded in the solid state source between the first dielectric film and a support layer, wherein the electrically conductive film emits infrared light upon warming with an electrical current during use, the infrared light sequentially reflecting off of the reflective layer, transmitting through the electrically conductive film, and emitting from the solid state source. Preferably the electrically conductive film comprises zinc oxide and the reflective layer is deposited into a basin in a second dielectric film.

A measurement device includes a measurement head configured to capture dimensional measurement data of a measurement object. A guide structure is configured to move and guide at least one of the measurement head and the measurement object in a measurement volume of the measurement device. A measurement unit is configured to capture positional data of the guide structure based on which a pose of the measurement head can be calculated. Multiple temperature sensor units are configured to capture temperature data about the measurement volume. Each temperature sensor unit includes a carrier element, a temperature sensor connected to the carrier element, and a heating element connected to the carrier element. A control system is configured to process the dimensional measurement data and the positional data and, based on the temperature data, correct at least one of the dimensional measurement data and the positional data.

A portable evaporator is disclosed. The portable evaporator includes an upper cover, a housing and a lower cover. Upper and lower ends of the housing are fixedly connected with connecting posts, the lower end of the housing is fixedly connected with the lower cover through the connecting posts, and the upper end of the housing is fixedly connected with a fastener through a first fixing screw. A middle of a lower end of the fastener is fixedly connected with an insulation part, and a lower end of the insulation part is fixedly connected with a metal container, an outer wall of the metal container is fixed with a halogen lamp. The heating appliance uses the halogen lamp as a heat source inside, which can work at a higher temperature.

Apparatus and method to prevent water spigot freezing, which utilizes a mounting collar to engage a discharge spout of a spigot, an incandescent lamp holder that locates the lamp within the discharge spout, and an intrinsically safe low voltage power supply, which may utilize a battery or utility power, to thereby couple thermal energy from the incandescent lamp into the spigot.

The present invention comprises a precision cooking oven that utilizes laser sheets to cook food, thus creating homogeneously heated and uniformly seared food bodies and surfaces. Laser sheets move back and forth evenly injecting heat into items being cooked. All food cold or hot areas can be eliminated since intersecting laser lines can be completely projected on and accommodate an item's exterior surfaces. Items with non-uniform cross-sections and properties can be cooked uniformly by controlling the exact amount of energy projected into differing sections of the food. The oven is also capable of cooking autonomously. Since laser sheets can be precisely controlled, cooking results can be very predictable once the boundary conditions for a thermal analysis are determined. The oven can detect the properties of the items to be cooked and thereafter compute the needed time and power to achieve the desired results stipulated by an oven operator.

The present invention relates to an integrated liquid-circulating dual pipe lamp comprising: a lamp unit which has a plurality of coils and filaments thereinside, and which has a position-fixing ring for fixing positions of the filaments; a lamp housing which has the lamp unit thereinside, and which has a circulation hole formed thereon so that liquid circulates outside the lamp unit at a predetermined temperature; watertight members which seal both end parts of the lamp housing, and into/through which both end parts of the lamp unit are inserted and penetrate; a liquid-circulation member which is coupled to the watertight member, which supplies a predetermined amount of liquid towards the circulation hole so as to circulate the same, and which discharges the circulating liquid according to the temperature of the liquid; and a reflection member in which the lamp housing is mounted.

Provided is a reflector comprising: an outer wall; and an inner wall which reflects the xenon lamp light from a xenon lamp toward an object to be light sintered, and which consists of inner side walls and an inner top wall which are spaced apart by a predetermined distance from the outer wall to allow cooling water for cooling heat generated by the xenon lamp light to flow, wherein at least a part of the inner side walls has the same thickness as at least a part of the inner top wall.

Examples disclosed herein relate to a lamp configured to provide heat for a processing chamber. The lamp includes a housing filled with a gas. A filament is disposed within the housing. The filament has an upper diameter, a lower diameter, and a length. A pair of electrodes is electrically coupled to the filament. A pair of pins is electrically coupled to the pair of electrodes. The pair of pins is configured to transfer energy to the filament. A ratio between either the upper diameter or the lower diameter to the length is about 0.3. The upper diameter is not equal to the lower diameter.

In some examples, a heating apparatus includes a light emitting diode (LED) array comprising an LED to heat a target object, and a heat sink thermally coupled to the LED array, to dissipate heat from the LED array, the heat sink comprising a plurality of refrigerant paths to pass a refrigerant through the heat sink in a plurality of different directions.