Abstract: In an apparatus for detecting a collision of a handling device with an obstacle, comprising at least one gas-filled chamber, which is surrounded by a flexible sheath that is deformable by collision with an obstacle and has a flexible supporting structure, wherein the supporting structure forms a damping element, which, together with the sheath, mechanically damps the forces that act in the event a collision, and also comprising a pressure sensor for measuring the gas pressure inside the chamber, wherein the apparatus is able to be attached to the handling device in a manner covering at least a first and a second region of the handling device, the sheath and the supporting structure are formed in one piece with one another and provide different degrees of damping from one another in the first and the second region.

Abstract: A glass light-emitting tile may include a light-transmissive glass plate, a glass substrate and a light guide plate. The light guide plate may be arranged between the light-transmissive glass plate and the glass substrate. A light-emitting diode (LED) lamp may be provided on a side of the light guide plate. The light-transmissive glass plate and the glass substrate may be glued together using a sealant. The glass light-emitting tile may having a tile and/or a stone-textured coating that may be low cost, may provide a high production efficiency, and may provide flexible customization. The tile may be used indoors and/or outdoors.

Abstract: An object of the present invention is to suppress adhesion of scale to a surface of a ceramic heater that is used for fluid heating. The ceramic heater has a ceramic body and a coating layer. The ceramic body has a heat generation resistor. The coating layer contains glass as a main component and is formed so as to coat a surface of the ceramic body. The coating layer has a function of smoothing the surface of the ceramic body.

Abstract: Disclosed herein is a plane heater that generates heat by using graphene or the like as the conductive heat generation material thereof. The plane heater includes: a nonconductor substrate; a heat generation material applied to the nonconductor substrate; and a pair of electrodes configured to generate resistance heat in the heat generation material. The pair of electrodes include a first electrode configured to be connected to one pole of a power source, and a second electrode configured to be connected to the other pole of the power source. The sectional areas of at least some portions of the first electrode and the second electrode are determined such that a plurality of electric circuits formed by the first electrode, the heat generation material, and the second electrode can have the theoretically same resistance.

Abstract: A vehicle seating assembly includes a cushion and a seating surface. A thermally conductive tape includes at least two branches, the two branches coming together at a junction and extending in a direction parallel with the seating surface. The thermally conductive tape includes a plurality of thermoelectric devices and a lower conductor and an upper conductor in thermal contact with the plurality of thermoelectric devices. The thermoelectric devices are secured to the lower conductor and the upper conductor with the thermally conductive adhesive. The thermoelectric devices are configured to change temperature when a voltage is applied to the thermoelectric devices.

Abstract: Method of operating a flow sensor device (10) with a first sensor arrangement (11) for measuring a flow (F) of a fluid (g) and a further first fluid property (p1), and with a second sensor arrangement (12) for measuring a further second fluid property (p2); said method comprising the steps of operating said flow sensor device (10) for determining said further first fluid property (p1) by means of said first sensor arrangement (11), operating said flow sensor device (10) for determining said further second fluid property (p2) by means of said second sensor arrangement (12), comparing said further first fluid property (p1) and further second fluid property (p2) and producing a comparison result (R), and monitoring said comparison result and producing a fault signal (FS) in case of a fault state. The present invention relates to such a sensor device.

Abstract: The invention relates to an electrical heating device (10) for a motor vehicle with a heating resistor designed as a conductor track (12) on a substrate (20), wherein the conductor track is at least partially arranged in a bifilar format. The invention further relates to a motor vehicle having such an electrical heating system.

Abstract: Example systems, apparatuses, and methods are disclosed sensing a flow of fluid using a thermopile-based flow sensing device. An example apparatus includes a flow sensing device comprising a heating structure having a centerline. The flow sensing device may further comprise a thermopile. At least a portion of the thermopile may be disposed over the heating structure. The thermopile may comprise a first thermocouple having a first thermocouple junction disposed upstream of the centerline of the heating structure. The thermopile may further comprise a second thermocouple having a second thermocouple junction disposed downstream of the centerline of the heating structure.

Abstract: The invention relates to a planar heating element (1) comprising a PTC resistive structure (2), which is arranged in a defined surface region (3) of a first surface (4) of a support substrate (5), wherein electrical connection contacts (6) for connection to an electrical voltage source (7) are associated with the PTC resistive structure (2), wherein the PTC resistive structure (2)—starting from the two electrical connection contacts (6)—has at least one internal conductive trace (8) and a parallel connected, external conductive trace (9), wherein the internal conductive trace (8) has a greater resistance than the external conductive trace (9) and wherein the resistances of the internal conductive trace (8) and external conductive trace (9) are so sized that upon applying a voltage an essentially uniform temperature distribution is present within the defined surface region (3).

Abstract: The present invention relates to a snow removing apparatus of an LED traffic signal light. More specifically, the present invention relates to a snow removing apparatus of an LED traffic signal light which detects snow accumulated on the lens of a traffic signal light and heats heating coils installed in the lens to remove snow. The present invention, to achieve this purpose, is equipped with an infra-red emitting unit; an infra-red receiving unit that is installed inside a lens and receives infra-red reflected from the infra-red emitting unit; a CDS sensor installed inside a lens and which measures visible light to compensate the emitting output of the infra-red emitting unit, and; a heater that is installed in the lens and which is supplied power to generate heat, and is characterized in that the lens has a gentle curvature, with ceramic-coated coil securing grooves formed on the inside of the lens along its inside surface, with heater coils installed by inserting in the coil securing grooves.

Abstract: A refrigerator is provided. The refrigerator may include a main body having a storage compartment, a first door rotatably installed at a first side of the main body to open and close a first portion of the storage compartment, and a second door rotatably installed at a second side of the main body to open and close a second portion of the storage compartment. A first camera may be installed at the first door to take a picture of an interior of the first storage compartment during rotation of the first door, and a second camera may be installed at the second door to take a picture of the interior of the first storage compartment during rotation of the second door. A controller may combine plural pictures taken by the first camera and the second camera into a single corrected image of a region of the first compartment spanning from the first door to the second door.

Abstract: A heating device capable of suppressing electrically conductive parts that electrically connect power supply electrodes and heating resistors from generating heat. The heating device has heating resistors disposed in a longitudinal direction of an elongated base plate and connected through electrically conductive parts to power supply electrodes disposed on one longitudinal end portion of the base plate and supplied with electric power from the power supply electrodes. The electrically conductive parts are formed such that electrically conductive parts that can provide larger amounts of power supply each have a larger cross-sectional area perpendicular to a power supply direction.

Abstract: There is provided a heater according to an embodiment including a heat generating unit configured to generate heat by electric conduct ion; and a plurality of electrodes configured to be respectively disposed at facing side edges of the heat generating unit so as to be electrically connected to the heat generating unit and at least one side of the side edges is formed by cutting out a part thereof.

Abstract: A connection element includes a composite component with a cured epoxy resin, a first layer including a first thermoplastic polymer and an intermediate layer arranged between the composite component and the first layer, the first layer containing both the cured epoxy resin of the composite component and the first thermoplastic polymer of the first layer. The first thermoplastic polymer has a melting point above a curing temperature of the epoxy resin and is soluble at a temperature of at least 150° C. in the epoxy resin used for producing the composite component.

Abstract: A trimmable heater mat has a plurality of heater mat segments that together comprise a length of the heater mat. Each of the heater mat segments has a segment heater element connected to a power bus for generating heat. One or more of the heater mat segments can be severed from the others and removed from the heater mat to trim the length of the heater mat to a desired length. Heater mat segment boundary indicia on the heater mat indicate locations where one of the heater mat segments can be severed from the other remaining heater mat segments of the heater mat without interfering with the segment heater elements of the remaining heater mat segments or with the connections of the remaining segment heater elements to the power bus.

Abstract: A chuck for a plasma processor comprises a temperature-controlled base, a thermal insulator, a flat support, and a heater. The temperature-controlled base is controlled in operation a temperature below the desired temperature of a workpiece. The thermal insulator is disposed over at least a portion of the temperature-controlled base. The flat support holds a workpiece and is disposed over the thermal insulator. A heater is embedded within the flat support and/or mounted to an underside of the flat support. The heater includes a plurality of heating elements that heat a plurality of corresponding heating zones. The power supplied and/or temperature of each heating element is controlled independently. The heater and flat support have a combined temperature rate change of at least 1° C. per second.

Abstract: A travel mug that is made of metal materials and can be used for microwave oven, including a container having a double-layered structure with an inner shell and an outer shell. The inner shell and said outer shell are joined by a joint in such a way that a cavity is provided therebetween, and a heat transfer medium is filled to at least part of said cavity. A microwave-heating plate is provided between the inner and outer shells. A handle is formed on one side of said outer shell. A pressure release device is provided at one side of said outer shell.

Abstract: An electrically conductive resistive layer is produced by thermally spraying an electrically conductive material onto the surface of a non-conductive substrate. Initially, the material layer arising therefrom has no desired shape. The material layer is then removed in certain areas so that an electrically conductive resistive layer having said desired shape is produced.

Abstract: Embodiments of the present invention provide apparatus and methods for performing rapid thermal processing. One embodiment of the present invention provides an apparatus for processing a substrate. The apparatus includes a heating source disposed outside a chamber body and configured to provide thermal energy towards a processing volume. The substrate support defines a substrate supporting plane, and the substrate support is configured to support the substrate in the substrate supporting plane. The heating source includes a frame member having an inner wall surrounding an area large enough to encompass a surface area of the substrate, and a plurality of diode laser tiles mounted on the inner wall of the frame member. Each of the plurality of diode laser tiles is directed towards a corresponding area in the processing volume.

Abstract: A resistance heater is shown and described. The resistance heater may include a body. The body may include at least one heating surface, the heating surface being generally smooth and generally flat and a recess formed in the body, at least a portion of the body having a cross-sectional shape selected from the group consisting of: generally U shape, generally I-shape, and generally H-shape, and where the cross-sectional shape extends along at least a portion of the body.

Abstract: Provided is a semiconductor device including an asymmetric electrode arrangement in which a plurality of electrodes are arranged asymmetrically in a vertical or horizontal direction.

Abstract: According to a first aspect of the present invention, there is provided a self-regulating electrical heating cable comprising: a first power supply conductor extending along the length of the cable; a second power supply conductor extending along the length of the cable; a third power supply conductor extending along the length of the cable; the first and second power supply conductors being in electrical connection with each other via a first electrically conductive heating element body having a positive temperature coefficient of resistance, and the second and third power supply conductors being in electrical connection with each other via a second electrically conductive heating element body having a positive temperature coefficient of resistance, and wherein, in use, the first, second and third power supply conductors are not physically connected to one another.

Abstract: The present invention relates to a ceramic-coated heater in which the outer surface of a heater rod is coated with ceramic to improve the physical properties thereof including durability, corrosion resistance, and the like, thereby enabling the heater to be used in water or air. The outer surface of the heater rod is coated with a ceramic composition to which an acrylic corrosion resistant wax is added, thereby strengthening the bonding force of the coating layer film, and thus improving the physical properties thereof including durability, corrosion resistance, and the like to enable the heater to be used in water. Therefore, the ceramic-coated heater of the present invention enables high thermal conductivity using less current and reduces energy consumption so that it can be utilized in a wide variety of industrial fields.

Abstract: The present invention relates to a multi-level and vertical assembling type PTFE heater and the methods of manufacture thereof. Said heater includes a vertical frame assembled by multi-poles and upper and lower retaining plates. Several levels of PTFE sleeves and electrical heating belts are alternatively disposed on the multi-poles. The number of the poles is determined in accordance with the size and capacity of a heater desired and the power and levels of PTFE electrical heating belts with heating needs. Multiple levels of PTFE electrical heating belts are formed in an assembling way, by which heaters with varied powers are easily produced and with the elements replaceable, will not be wholly wasted in event of an element damaged, thus the heater service life prolonged. Said heater has a better heating result than the one with only a single level of heating structure.

Abstract: A device and a method are provided, for shrinking a protective element (101) shrinkable by means of the supply of heat onto an optical waveguide (100). The method involves generating thermal radiation, reflecting it and focusing it onto a focus zone in which the protective element (101) is held. The device contains a heating element (10), which generates thermal radiation, a reflector (30), which focuses the thermal radiation emitted by the heating element onto the focus zone, and a mount (20), by means of which the protective element (101) can be held in the focus zone.

Abstract: A local resistance heating device, with a controlled atmosphere, includes two end members and a mid member. The two end members are respectively connected with an anode pole and a cathode pole. Each end member has an air channel. The air channel of one of the end members is adapted to connect with an output terminal of a gas supplier, and the air channel of the other one of the end members is adapted to connect with a sucking terminal of the gas supplier. The mid member is arranged between the two end members. The two end members and the mid member jointly define a heating room communicating with the air channels of the two end members.

Abstract: Provided are a heating device, a substrate processing apparatus, and a method of manufacturing a semiconductor device, which can suppress differences between heating bodies, and simultaneously, can suppress shearing of a holder due to thermal deformation of the heating element. The heating device comprises: a heating element including a mountain part and a valley part that are alternately connected in plurality in a meander shape with both ends being fixed; holding body receiving parts respectively installed at ends of the valley parts and formed as cutout parts having a width larger than a width of the valley part; an insulating body installed at an outer circumference of the heating element; and a holding body disposed in the holding body receiving part and fixed to the insulating body.

Abstract: A sheet heater that includes a sheet article composed of a conductive resin composition containing a conductive material and a resin, and a pair of metal plate electrodes, each of the electrodes being bonded to each of the ends of the sheet article, wherein when elements of the sheet article are detected at a portion 1 ?m depth from a surface of the metal plate electrode, a peak area ratio of silicon (Si) to metal ion (M) is 1/100 to 1, the metal ion M being most abundant of all metal ions detected at the portion, the peaks being obtained by measuring an X ray generated at the portion by applying an X ray to the portion with the scanning electron microscope-energy dispersive X-ray spectrometer.

Abstract: A heat generating body has a first electrode and a second electrode arranged opposed to each other, and also has a mesh-like electrically conductive membrane (mesh-like pattern) mounted in a curved surface shape between the first electrode and the second electrode. The first electrode and the second electrode are arranged so as to satisfy the relationship of (Lmax?Lmin)/((Lmax+Lmin)/2)=0.375, where Lmin is a minimum value of the distance between two opposite points which are on the first and second electrodes and on the electrically conductive membrane and Lmax is a maximum value of the distance.

Abstract: A method of operating a heating plate for a substrate support assembly used to support a semiconductor substrate in a semiconductor processing apparatus, wherein the heating plate comprises power supply lines and power return lines and respective heater zone connected between every pair of power supply line and power return line. The method reduces maximum currents carried by the power supply lines and power return lines by temporally spreading current pulses for powering the heater zones.

Abstract: A boiler for use in a machine for making hot beverages includes a heat diffuser with a first wall destined to be placed in contact with the liquid to be heated and a second wall opposite first wall, heating element consisting of at least one serigraphed or photo-engraved resistance arranged on second wall of heat diffuser and defining a pattern formed of at least on resistive track, a body which with first wall of heat diffuser defines a heating chamber inside which the liquid is to be heated. It also includes a bearing element shaped to bear on second wall of heat diffuser on at least one zone, the resistive track(s) being arranged on either side of the zone so that the bearing element receives at least part of the force transmitted by the liquid to heat diffuser and resulting from the pressurizing of liquid in the heating chamber.

Abstract: A flow heater (100, 200, 300, 400, 500) with a tube arrangement including at least one tube (105, 106, 205, 206, 305, 306, 404, 405, 406) for passing through a fluid to be heated or a plurality of fluids to be heated, and with a heater with a metal jacket, especially with a tubular heating body (102, 202, 302, 402, 502), in which the tubes (105, 106, 205, 206, 304, 305, 306, 404, 405, 406, 505) surround the heater. At least in partial areas of the heater, wall sections (113, 114, 213, 214, 311, 312, 313, 411, 412, 413, 513) of the tube arrangement (105, 106, 205, 206, 304, 305, 306, 404, 405, 406), which wall sections face the heater, are adapted to an outer contour of the heater, which heater may or may not include a heat transport tube (117, 317, 517), so that the wall sections are in flush contact with sections of this outer contour. The tube arrangement (105, 106, 205, 206, 304, 305, 306, 404, 405, 406, 505) is connected together and/or with the heater by a connection device.

Abstract: A pressure-sensitive adhesive force expressing unit including: a thermal head including heater elements arranged along a width direction of a label, the thermal head being configured to heat the label, from an adhesive layer side to form openings in a function layer by the heater elements; and a controller for applying heat energy to the heater elements individually to control heat generation thereof, the controller being configured to control the application of heat energy to the heater elements so that opening lines in each of which the openings are arranged in the width direction of the label are formed in the conveyance direction and to control the application of heat energy so that adjacent at least two of the heater elements generate heat at the same time to form an opening group in which the openings are connected together in the width direction.

Abstract: The present invention is to provide a heating substrate equipped with a conductive thin film and electrodes. The heating substrate includes a transparent substrate, a plurality of electrodes formed on a first face of the substrate, and a conductive thin film formed on the first face of the substrate and including a plurality of regions electrically connected each other in parallel by the plurality of electrodes. Furthermore, a method of manufacturing a heating substrate equipped with a conductive thin film and electrodes according to an exemplary embodiment of the present invention includes forming the conductive thin film on a substrate, forming main electrodes so as to extend on the substrate while being adjacent to edges of the conductive thin film, and forming branched electrodes that are extended from the conductive thin film across one side of the conductive thin film while coming in contact with the conductive thin film.

Abstract: An embodiment of the present disclosure relates to a heating device comprising a carbon nanotube, which comprises a carbon nanotube layer containing aligned carbon nanotube carpet, a first electrode and a second electrode having a predetermined distance between each other and electrically connected to the carbon nanotube layer respectively, wherein a current produced by applying a voltage to the first electrode passes laterally via the diameter direction of the aligned carbon nanotubes from the first electrode to the second electrode. The present disclosure also includes methods for manufacturing the aligned carbon nanotube carpet.

Abstract: The present invention provides a semiconductor ceramic composition which is represented by a composition formula of [(Bi.A)x(Ba1-yRy)1-x](Ti1-zMz)aO3 (in which A is at least one kind of Na, Li and K, R is at least one kind of rare earth elements (including Y), and M is at least one kind of Nb, Ta and Sb), in which a, x, y and z satisfy 0.90?a?1.10, 0<x?0.30, 0?y?0.050 and 0?z?0.010 and an average distance between voids, which is an average value of a space between voids being internally present, is 1.0 ?m or more and 8.0 ?m or less.

Abstract: A heater assembly includes one or more first heating elements characterized by a first wattage density, and one or more second heating elements characterized by a second wattage density. The second wattage density is greater than the first wattage density. The one or more second heating elements are interspersed with the one or more first heating elements.

Abstract: An electrical heating device includes an open housing in which a layer structure is held under tension. The layer structure includes at least one radiator element and at least one heat emitting element with at least one PTC heating element. The layer structure further includes at least one spring element holding the layer structure in the housing under tension. The spring element is provided adjacent to a spring counter element. Spring tongues, formed on the spring element, interact with matching receptacles on the spring counter element. Displacement of the spring element in a direction essentially parallel to the planes of the layer structure stresses the layer structure within the housing. A method of assembling an electrical heating device is also disclosed.

Abstract: A surface heating device for a substrate treatment device with increased power density and improved homogeneity of heat radiation includes a jacket tube heater with straight tube sections and bent tube sections in which straight tube sections are arranged parallel to each other in a main plane and straight tube sections are connected to each other by bent tube sections, so that at least part of the bent tube sections are aligned sloped relative to the main plane.

Abstract: The described embodiment relates generally to the field of inductive heating. More specifically an inductive heater designed for use in assembling electronics is disclosed. A number of methods for shaping a radio-frequency (RF) receiver structure are disclosed for the purpose of completing an inductive bonding process without causing harm to adjacent electrical components.

Abstract: A heater includes at least one heating element having a resistance that varies non-linearly with respect to a temperature of the heating element. The heating element includes a first surface, a second surface opposite the first surface, a third surface extending between the first and second surfaces, and a fourth surface extending between the first and second surfaces, opposite the third surface. The heating element has a height defined between the first and second surfaces, and a width defined between the third and fourth surfaces, and wherein the width is less than the height. The heater also includes at least one electrode coupled to the first surface and configured to generate an electric field across the heating element and cause a current to flow through the heating element.

Abstract: A layered heater is provided that comprises at least one resistive layer defining a circuit configuration, the circuit configuration comprising at least one resistive trace oriented relative to a heating target and comprising a material having temperature coefficient characteristics such that the resistive trace provides power commensurate with demands of the heating target In one form, resistive traces of the resistive layer are an NTC material having a relatively high BETA coefficient and are oriented approximately parallel to a primary heating direction.

Abstract: A heating device capable of suppressing electrically conductive parts that electrically connect power supply electrodes and heating resistors from generating heat. The heating device has heating resistors disposed in a longitudinal direction of an elongated base plate and connected through electrically conductive parts to power supply electrodes disposed on one longitudinal end portion of the base plate and supplied with electric power from the power supply electrodes. The electrically conductive parts are formed such that electrically conductive parts that can provide larger amounts of power supply each have a larger cross-sectional area perpendicular to a power supply direction.

Abstract: An apparatus for use in controlling a temperature of an oblong-shaped molten glass-carrying vessel, such as a conduit for transporting the molten glass from one location to another location, by flowing a current through the vessel. The apparatus comprises a metal flange comprising a plurality of electrically-conductive rings that include an inner ring joined to the vessel's exterior wall and an outer ring surrounding the inner ring. The inner ring, for example, may include an outer perimeter that is substantially oblong. In some embodiments the inner ring comprises a notch that aids in making current density more uniform. In some examples the width of the inner ring, excluding the notch, does not substantially vary as a function of angular position relative to the vessel.

Abstract: A novel heat retainer/heat generator is provided using carbon nanotube (CNT) paper, particularly, a plane heating film suitable for use in an integrated gas supply system for supplying a special gas for semiconductor manufacturing. The plane heating film comprises a piece of electrically conductive paper created by mixing carbon nanotubes with pulp fiber, and processing the mixture into a sheet, electrodes disposed in an end area of the electrically conductive paper for supplying power to the electrically conductive film, and heat-resistive insulating films for laminating both sides of the electrically conductive paper. With the employment of carbon nanotubes, the plane heating film is improved in temperature characteristics, heat generating efficiency, and durability.

Abstract: The present invention relates to a heating element in which distortion of a view due to local heating around a heating line does not occur even when a heating value is high, and a method for manufacturing the same. More specifically, the heating element according to the present invention comprises a transparent substrate and conductive heating lines provided on the transparent substrate, in which a line width of the conductive heating line is 10 ?m or less and a distance between the conductive heating lines is 500 ?m or less.

Abstract: A hydration system comprises a bladder assembly defining a bladder chamber, a hose assembly, and a heating system comprising a heating element defining a loop portion. Liquids flow from the bladder chamber to the hose assembly. The loop portion is arranged within the hose assembly such that current flowing through the heating element inhibits freezing of liquids within at least a portion of the hose assembly.

Abstract: There is provided a thermostatic working element comprising: a housing for receiving an expansion medium; an electric heating element arranged in the housing and provided with connecting lines, wherein a base of a bottom side of the housing comprises an opening for passage therethrough of the connecting lines; and a gasket disposed between the electric heating element and the base of the bottom side of the housing, essentially surrounding the opening, wherein the housing further comprises a recess located in proximity to the electric heating element, configured to press the electric heating element and the gasket against the base of the bottom side of the housing and thereby sealing of the housing is facilitated.

Abstract: An apparatus has a chassis has a chassis inner face and a chassis outer face, at least one heating part accommodated in the chassis, wherein at least a portion of the heating part faces the chassis inner face with an internal space therebetween, and a film having a first face and a second face bonded to at least a portion of the heating part facing the chassis inner face. The chassis outer face is located on a side opposite the chassis inner face portion and in contact with an external space and having a radiation film interposed therebetween. The film includes a convex part, a concave part, or a repeated pattern of convex and concave parts in the first face or the second face. At least one of the first face and the second face is in contact with the internal space.

Abstract: A method and device for measuring the soot load in the exhaust gas systems of diesel engines using a sensor which is mounted downstream of a particulate filter and comprises a sensor element, to measure the operability of the particulate filter. According to the method, the soot load of the sensor element is measured resistively or capacitively using electrodes. The measuring voltage of the sensor element is controlled depending on at least one actual operating parameter of the diesel engine.