Abstract: Apparatus for rapid heating of a liquid including a heat source, a liquid flowpath defining element defining a liquid heating flowpath therein having a liquid inlet and a liquid outlet, a collection of flexible elongate thermal conductors located within the flowpath, the collection of flexible elongate thermal conductor portions being thermally coupled to the heat source and defining multiple liquid heating passageways through the flowpath whose configurations and cross-sectional dimensions change over time, thereby being resistant to clogging.

Abstract: An electric resistance radiant furnace that includes multiple panel emitters and at least one layer of metallic screen located between the panel emitters. In some embodiments, the panel emitters each include a ceramic body with an electric resistance wire embedded therein. Furnaces can be for heating an occupied space within a building and can also include a blower and controls and heat produced by electricity passing through the wire can be conducted through the ceramic body of each panel emitter and at least part of the heat can be radiated from the ceramic body to the metallic screen and then be transferred to air blown by the blower between the panel emitters and along the metallic screen. Concave or convex surfaces of curved layers of metallic screen can face opposite directions, can face the panel emitters, or both.

Abstract: A heating device includes a heater (2) having a heating portion (6) which generates heat by energization; a housing (4) which contains the heating portion and forms a passage (18) for a heating medium between the housing and the heating portion; a temperature detection means (26) for detecting the temperature of the heating medium in the passage; and an energization interrupting means for interrupting the carrying of current to the heater depending on the temperature of the heating medium detected by the temperature detection means. The temperature detection means is pressed into contact with the heating portion.

Abstract: A boiler for hot water heating mats, including: a hot water heating tank having a hot water discharging port, a hot water recovering port, and an electric heater; a hot water storage tank connected to the hot water heating tank, with a water charging port, an air exhausting port, a hot water inlet port and a hot water outlet port; a hot water discharging check valve; and a hot water recovering check valve. The heater is installed horizontally or inclinedly, and the interior space of the hot water heating tank is divided into a hot water heating chamber and a hot water discharging chamber. To ensure the heater remains partially submerged in water, the hot water discharging port may be formed at a height higher than the lower surface of the heater or a retaining wall may be installed on the bottom of the hot water heating tank.

Abstract: Electric heat for generating smoke from tobacco or the like in a hookah type smoking pipe. Electric heat is obtained from an electrically powered heating element which may be placed proximate the tobacco. The heating element may be contained within a housing which in turn may be placed above the smoking chamber of the hookah. The housing may have adjustably damped holes disposed to pass air over the heating element. Electrical circuitry serving the heating element may comprise a step down transformer and a voltage adjusting switch. The heating element may be integral with the hookah, may take the form of a separate component which is mountable over the smoking chamber of the hookah, or may comprise a free standing assembly which may be placed to stand adjacent to the hookah.

Abstract: The present invention discloses a water dispensing device including a water tank and at least one heating module. Each heating module includes a body and a heating plate, the body includes a groove, an input terminal located one end of the groove and connected the water tank, an output terminal located other end of the groove, and a plurality of ribs. The ribs formed on the bottom surface of the groove and the height is less than a depth of the groove, two arms of the ribs connect the sidewalls of the groove, and the density of the arrangement is decremented from the input terminal to the output terminal. The heating plate is covered the groove and doesn't contact the ribs, and the surface of the heating plate which is deviated from the groove has a plurality of heating units, be used to convert the power into the heat energy.

Abstract: An aircraft drain/fill fitting includes a housing adapted for being fitted into an opening between an aircraft interior and an aircraft exterior. The housing has an interior housing segment fluidly coaxially communicating with an exterior housing segment to define a liquid flow path therethrough, and a heater for applying heat to the interior housing segment. A hollow insert element is positioned in the interior housing segment in heat transfer contact with an inner wall of the interior housing segment. An elongate heat transfer probe is positioned in heat transfer contact with the hollow insert element and extends into the exterior housing segment to reduce the incidence of freezing of liquid in the exterior housing segment.

Abstract: A heating system is disclosed, which includes a main body having a duct formed therein, an air flowing guiding member, and a heating unit. The duct has an air inlet and an air outlet. The air flowing guiding member is disposed in the duct. The heating unit includes a substrate and a plurality of electronic components disposed on the substrate in a matrix form and embossed from a surface of the substrate, wherein each of the electronic components is capable of individually producing heat to directly heat up the air flowing in the duct. Also a heating system using the heating unit is disclosed.

Abstract: A heat sink is disclosed including a cold plate, a plurality of heat pipes, a plurality of fins, and a heating unit. The cold plate has a first surface adapted to thermally couple to a heat source. Each of the heat pipes has an evaporator section thermally coupled to the cold plate and a condenser section coupled to the evaporator section. The plurality of fins are thermally coupled to the condenser sections of the plurality of heat pipes. The heating unit is adapted to heat condenser sections of a subset of the plurality of heat pipes.

Abstract: An apparatus for heating a hydronic heating fluid comprising a casing body having an inlet and an outlet adjacent to the inlet and a fluid flow path between the inlet and outlets. The flow path extends along first and second substantially straight sections with a return bend therebetween. The apparatus further includes a heating element located within one of the first or second sections of the flow path. The second end may include a threaded heater bore aligned with the second section wherein the heating element is threadably insertable into the second section through the heater bore. The first end may include a pump in fluidic communication with the inlet, the pump being operable to draw the heating fluid in through the inlet and to discharge the heating fluid through the first section of the casing body.

Abstract: Electric heat for generating smoke from tobacco or the like in a hookah type smoking pipe. Electric heat is obtained from an electrically powered heating element which may be placed proximate the tobacco. The heating element may be contained within a housing which in turn may be placed above the smoking chamber of the hookah. The housing may have adjustably damped holes disposed to pass air over the heating element. Electrical circuitry serving the heating element may comprise a step down transformer and a voltage adjusting switch. The heating element may be integral with the hookah, may take the form of a separate component which is mountable over the smoking chamber of the hookah, or may comprise a free standing assembly which may be placed to stand adjacent to the hookah.

Abstract: The section bar (1) for a fluid flow heater for coffee machines has a longitudinal development with two opposing ends and a first tubular cavity (A), that is accessible at the opposing ends of the section bar (1), and a second cavity (B) having an opening (O) that extends along the longitudinal development of the section bar (1). A heater (10) having an encased resistor (2, 3) integrated in the first cavity (A) of the section bar (1) and a tubular fluid circulation conduit (4) inserted into the second cavity (B) of the section bar (1) and fixed by means of bending at least one lug (B1, B2, B3) around the tubular fluid circulation conduit (4), so that the opposing ends of the tubular fluid circulation conduit (4) emerge with respect to the opposing ends of the section bar (1).

Abstract: A flow heater is provided including a heating element, a channel heated by said heating element for heating liquid flowing therethrough, and temperature sensing means in thermal communication with both the heating element and the channel so as to be sensitive to the temperature of the liquid in the channel and the temperature of the heating element.

Abstract: Apparatus and methods for delivering a heated fluid. The apparatus includes at least a preheat zone, an expansion zone, and an expanded zone comprising a plurality of trim heaters, at least one fluid flow-distribution sheet, and an outlet. The apparatus may be used for delivering the heated fluid onto a moving fluid-permeable substrate.

Abstract: A feed gas conditioner.

Abstract: The invention relates to a electric heating device for heating fluids, comprising at least one heating resistor, a screw, which defines a helical flow channel, and a tube housing, which surrounds the screw. In accordance with this disclosure, the screw has a core in which the at least one heating resistor is arranged.

Abstract: An aircraft sink water heater includes an electric heater with coils engaging water tube coils. The system quickly heats a small volume of water in the tube coils, sufficient to wash a user's hands.

Abstract: Provided are a layered heat exchanger that can prevent deterioration of sealing property due to deformation of sealing portions of inlet and outlet header sections when a PTC heater is sandwiched between flat heat exchanger tubes, and is pressed to be brought into close contact with the flat heat exchanger tubes, and a heat medium heating apparatus and a vehicle air-conditioning apparatus using the layered heat exchanger.

Abstract: A boiler for heating a liquid, in particular water, and having at least one module in turn having a cylindrical conduit closed at the ends by two caps and fitted through with an electric resistor, which defines an annular channel between itself and the conduit, and is fitted in fluidtight manner to each cap and to the inner surface of the conduit by a respective single seal; the conduit having a tubular inlet fitting and tubular outlet fitting, which are located close to the opposite axial ends of the annular channel, are independent of the caps, and have respective channels extending radially with respect to and communicating with the annular channel; the tubular inlet and outlet fittings being complementary in shape.

Abstract: A water boiling device includes a heat tank unit received in a machine body, a high frequency induction heater, and a heat pipe unit. The heat tank unit includes first and second heating tanks in communication with each other. Outside water can flow into the first and second heating tanks. The high frequency induction heater includes a heat pipe induction coil and first and second induction coils. The heat pipe unit includes first and second heating pipes. An upper section of each heating pipe is received in one of the heating tanks, and a lower section of each heating pipe extends out of the heating tanks and is inserted into the heat pipe induction coil. The first and second heating tanks will heat up to heat the water in the first and second heating tanks when a high frequency current is passed through the heat pipe induction coil and first and second induction coils.

Abstract: A heater wire for removing condensation from a respiratory gas conduit. The heater wire includes at least one groove disposed thereon. The heater wire is positioned in a respiratory gas conduit.

Abstract: A feed gas conditioner can include embodiments having a cross heat exchanger. In embodiments, the cross heat exchanger can have a housing defining a flow passage in a first direction and a flow passage in a second direction. Heating elements in the flow passage in the first direction can heat fluidic materials. In embodiments, the feed gas conditioner can remove particles from the fluidic materials.

Abstract: A method and apparatus for heating or cooling a fluid is provided. In one embodiment, a heat exchanger is provided. The heat exchanger includes a first subassembly comprising an insert. The insert comprises a body having a blind passage formed axially in the body, a plurality of nozzles formed therein, and a first plurality of heat exchange elements disposed within the body. The heat exchanger also comprises a second subassembly comprising a sleeve and a second plurality of heat exchange elements disposed within the sleeve, wherein the insert is sealably engaged inside the sleeve and the insert and the sleeve cooperatively define a thin gap, and wherein each of the plurality of nozzles are disposed radially between the blind passage and the thin gap.

Abstract: A feed gas conditioner includes a passageway with a plurality of heating elements positioned within the passageway. A plurality of baffle assemblies can cause a fluid flowing through the feed gas conditioner to flow in a serpentine flow pattern so that the fluid flows transverse to at least a portion of the heating elements. The baffle assemblies can each include two or more baffle elements, the baffle elements being positioned at an angle relative to each other. The heating elements can pass through passages within one or more of the baffle elements.

Abstract: The invention relates to a line for transporting a hydrocarbon. The line includes a hollow inner tube extending in a longitudinal direction for transporting the fluid in the inner tube and having an electrically insulating outer surface. A heating layer is arranged on the inner tube and comprises carbon fibres embedded in a polymer material. A heat insulation layer is arranged around the heating layer. An outer tube is arranged around the heat insulation layer. The outer tube is designed to resist an outer pressure at least higher than 100 bar. Spacing means hold the outer tube at a distance from the inner tube in a fixed manner. Power supply means feed an electric current to the heating layer in order to heat the inner tube.

Abstract: A digital control system for a tankless water heater assembly designed to heat water on a continuous basis as it passes from a conventional water source and through a heating system. The digital control system comprises a display capable of displaying at least three display modes. The first display mode displays a power setting in the form of a bar graph, and real-time voltage used and efficiency in percentage form. The second display mode displays kilowatt usage and percentage draw. The second display mode is defined as a “generator mode” because a generator unit displays actual kilowatts the tankless water heater assembly is using. While in the second display mode, a user can manually adjust the kilowatts to be used. The third display mode displays amperage draw and actual power usage in percentage form.

Abstract: In various embodiments, the invention provides a system for heating a liquid, such as, for example, water, comprising a plurality of liquid heaters, the inlets and outlets of which are respectively connected in a parallel flow relationship by respective manifolds, and configured to provide liquid having a temperature of greater than about 90 degrees Fahrenheit at a flow rate of greater than about 10 gallons per minute. In various embodiments, the present invention provides an electric tankless liquid heater system capable of delivering hot liquids, and in particular water, at even higher flow rates and or temperatures, including, but not limited to, flow rates greater than about: (1) 12 gpm; (2) 18 gpm; (3) 20 gpm; and (5) 20 gpm; and/or temperatures of greater than about: (1) 100° F.; (2) 120° F.; (3) 140° F.; and (4) 180° F.

Abstract: A high-pressure gas-heating device has a pressurized container (1) carrying a gas, a heating element (3) arranged in the pressurized container (1), and an insulation (2). The insulation (2) is arranged on the interior wall of the pressurized container (1). The pressurized container (1) is designed for pressures of to 100 bar, and at least one flow distributor element (5) is arranged in an inflow area of the pressurized container (1) to distribute the inflowing gas over the entire width of the heating element (3).

Abstract: A device having a tube for heating or heat retaining of fluid includes a first path in which a connection section of a cord heater led out of the tube and a lead wire connected to a power supply is provided, a second path provided between the tube and the first path, and a drainage path for removing leaked fluid of the second path. In this device, the connection section is sandwiched by a pair of first sealing members to retain a sealed state and the cord heater passes through the second path in a sealed state by a second sealing member. This device can effectively prevent gas or liquid from leaking into the space where the connection section of a lead wire and a cord heater is provided.

Abstract: A heat exchange assembly and apparatus and method employing the heat exchange assembly are provided. The heat exchange assembly includes a coolant-to-refrigerant heat exchanger and a heater. The heat exchanger includes a coolant inlet and a coolant outlet for passing a coolant through the heat exchanger, and a refrigerant inlet and a refrigerant outlet for separately passing a refrigerant through the heat exchanger. The heat exchanger cools coolant passing through the heat exchanger by dissipating heat from coolant passing through the heat exchanger to refrigerant passing through the heat exchanger. The heater is integrated with the heat exchanger and applies an auxiliary heat load to refrigerant passing through the heat exchanger to facilitate ensuring that refrigerant passing through the heat exchanger absorbs at least a specified minimum heat load, for example, to ensure that refrigerant egressing from the refrigerant outlet of the heat exchanger is superheated vapor refrigerant.

Abstract: A device includes an electrically heatable honeycomb body, particularly for treating an exhaust gas flow of a mobile internal combustion machine. The device includes sheet metal foils forming channels and being in electrical contact with a housing. The housing has a terminal for connection to a voltage source, a plurality of contact points disposed remotely from the terminal for contacting the sheet metal foils and a respective contact conductor between the terminal and each contact point. The contact conductors have the same electrical resistance. A motor vehicle having at least one such device is also provided.

Abstract: A tankless electric water heater is disclosed that optimizes energy efficiency while minimizing cost and size. A flow-through container surrounds an electric heating element having a surface that is everwhere in direct, unobstructed relationship with the container walls, forming therebetween a passage through which all of the water must pass in a laminar flow while in close proximity to the heater surface, preferably within one-quarter inch and more preferably within one-eighth inch. The entire heater surface is surrounded by water, and all emanated heat must pass into the water. Tubular embodiments can be straight, coiled, U-shaped, and/or S-shaped. Cup-shaped embodiments can direct the water in a counter-flow past inner and outer heating element surfaces. Electrical connectors can be positioned near to each other. Protruding fins can be included that increase heat contact with the water, and the fins can be aligned with the water flow to minimize turbulence.

Abstract: A feed gas conditioner.

Abstract: A dual wall axial flow electric heater for leak sensitive applications provides an improved corrosion and leak resistant assembly and includes protective tubes over electrical heater rods, double tubesheets spaced apart by a plenum and leak detectors positioned to sensor leaks through the walls of the protective tubes. The design includes the option of two or more tube bundles with each inserted into opposite ends of a shell surrounding the tube sheets and heaters. The design provides ease of maintenance since each heater rod can be replaced independently while the unit is in service. Variable heat flux is provided from standard single flux heater rods by providing protective tubes of varying diameters. A built-in thermowell is provided to allow the rod temperatures to be monitored directly. Hot spots are avoided by the use of turning baffles and vibration is avoided by use of spider baffles to support the tubes.

Abstract: A flow-through heater includes a tubular housing and a heating element. The tubular housing defines a passageway. The heating element is provided in the passageway and attached to the tubular housing. The heating element includes a resistive wire and an electrically insulating coating on the resistive wire. The heating element includes a coiled wire portion coiled along a longitudinal axis of the tubular housing. The coiled wire portion defines a channel extending in a direction along the longitudinal axis to enable a fluid to flow therethrough. The coiled wire portion contacts the fluid when the fluid flows through the channel.

Abstract: An internal start-up heater (10) for an ammonia reactor (1), comprising longitudinal heating members (16) and a supporting structure for said heating members (16), the structure comprising plates (20A-20D) with parallel beams (22A-22D) in contact with said heating members (16), wherein the plates are arranged in plate sets formed by at least a first and a second plate having differently arranged supporting beams.

Abstract: A fluid heater 20 includes a duct pipe 26 through which a fluid to be heated flows, and a heating part 23 configured to heat the duct pipe 26. One or more fillers 30 is provided inside the duct pipe 26. A substrate processing apparatus 60 includes: a supply source 92 configured to supply a liquid of a volatile organic solvent; the aforementioned fluid heater 20 configured to heat the liquid of the organic solvent supplied by the supply source 92 so as to generate a steam of the organic solvent; and a chamber 65 configured to accommodate a substrate W and to dry the substrate W accommodated therein, to which the steam of the organic solvent generated by the fluid heater 20 is supplied.

Abstract: The invention relates to an apparatus for heating fluids, comprising a housing in which a duct runs, through which the fluid to be heated can flow and which leads from a housing opening for fluid to enter to a housing opening for fluid to exit. According to the invention, the duct extends in several convolutions along a housing wall carrying at least one heater housing, in which at least one electric heating element is arranged.

Abstract: A wash system for window glasses and/or headlamps of a vehicle, with a fluid line through which a fluid is conducted from a fluid reservoir into a nozzle and with a heating cable which is laid in the fluid line is disclosed. The heating cable is laid so as to enter the nozzle or to pass through the nozzle and to heat not only the fluid line but also the nozzle. One obtains a wash system that can be manufactured at low cost and ensures freeze protection at reduced energy expense by the fact that the heating cable is laid in a meander pattern in the nozzle.

Abstract: A tankless electric water heater is disclosed that optimizes energy efficiency while minimizing cost and size. A flow-through container surrounds an electric heating element having a surface that is everwhere in direct, unobstructed relationship with the container walls, forming therebetween a passage through which all of the water must pass in a laminar flow while in close proximity to the heater surface, preferably within one-quarter inch and more preferably within one-eighth inch. The entire heater surface is surrounded by water, and all emanated heat must pass into the water. Tubular embodiments can be straight, coiled, U-shaped, and/or S-shaped. Cup-shaped embodiments can direct the water in a counter-flow past inner and outer heating element surfaces. Electrical connectors can be positioned near to each other. Protruding fins can be included that increase heat contact with the water, and the fins can be aligned with the water flow to minimize turbulence.

Abstract: In various aspects, the present invention provides an electric tankless liquid heater system capable of delivering liquid, such as, for example, water, with an acceptable increase in output liquid temperature upon a sudden and substantial decrease in liquid demand. In various aspects, the electric tankless liquid heater comprises an inlet manifold and a plurality of liquid heaters the inlets of which are connected in a parallel flow relationship by the inlet manifold, and the outlets of which are each connected to a separate outlet conduit, and which is configured to provide water to a plurality of automatic water fixtures with a less than about 2° F. (about 1.1° C.) increase in output water temperature upon about a one-and-a-half-fold or greater decrease in water demand that occurs in less than about 500 milliseconds as measured by the increase time of the inlet liquid pressure.

Abstract: Apparatus and method for providing a heated cleaning fluid to a vehicle surface. The apparatus has an inlet port for receiving an amount of fluid; an outlet port for dispensing an amount of heated fluid; a heating element coil or tube covered with a plastic sheath that heats up fluid passing from the inlet to the outlet; and a control circuit for energizing at least a portion of the heating element with a voltage to heat the fluid passing from the inlet to the outlet. The apparatus also has expandable and compressible features and parts for protection against freezing.

Abstract: A heating device is provided in a water passageway in a washing or rinsing machine and has a heating element in proximity with a sensor. In one embodiment, the heating element is mounted using a holder in an opening in a wall wherein the wall forms the water passageway. On the holder is also provided a conductivity measuring device which projects into the water passageway. The heating device and conductivity measuring device form a module.

Abstract: Provided is a small-sized in-line heater which is also capable of rapid heating. This in-line heater includes a ceramic heater, and two piping blocks each including a lid member and a piping block body in which a flow pipe is formed. The piping blocks are disposed to face each other with the ceramic heater interposed in between.

Abstract: A high-pressure gas-heating device has a pressurized container (1) carrying a gas, a heating element (3) arranged in the pressurized container (1), and an insulation (2). The insulation (2) is arranged on the interior wall of the pressurized container (1). The pressurized container (1) is designed for pressures of to 100 bar, and at least one flow distributor element (5) is arranged in an inflow area of the pressurized container (1) to distribute the inflowing gas over the entire width of the heating element (3).

Abstract: An electric heating element with radiant tube comprising a radiation pipe (1) and an electric heating element (2, 3) contained in said pipe, wherein the heating element has legs that run to and fro in the pipe, and wherein the heating element is connected at one end of the pipe close to a furnace wall with electric power outlets through which electric current is fed to the element, wherein the element is supported in the pipe by ceramic discs (9) that are provided with through-penetrating holes through which the legs of the elements extend, and wherein two elements (2, 3) are disposed sequentially in said radiation pipe along its long axis.

Abstract: A tankless hot water heater includes a pipe, at least one heating element, sensors, an input means and a microprocessor. The pipe has an inlet and an outlet. The at least one heating element is configured to heat water flowing through the pipe. At least one sensor is configured to measure a temperature of water flowing through the pipe prior to heating by the at least one heating element. At least one sensor is configured to measure a flow rate of water flowing through the pipe. The input means is configured for entering a set point for a temperature of water heated by the at least one heating element. The microprocessor is configured to receive as input the temperature of water flowing through the pipe prior to heating, the flow rate of water flowing through the pipe, and the set point for a temperature of heated water, and the microprocessor is configured to provide as output a power setting to the one or more heating elements.

Abstract: A tankless water heater comprising a pipe, at least one coil around the pipe, at least one heating element located within the pipe and responsive to an electromagnetic field generated by the coil, and a controller to apply an alternating current (AC) signal to the at least one coil, the AC signal applied at a predetermined frequency and magnitude to cause the heating element to heat water flowing in the pipe to a predetermined temperature through induction heating.

Abstract: A device having a tube for heating or heat retaining of fluid includes a first path in which a connection section of a cord heater led out of the tube and a lead wire connected to a power supply is provided, a second path provided between the tube and the first path, and a drainage path for removing leaked fluid of the second path. In this device, the connection section is sandwiched by a pair of first sealing members to retain a sealed state and the cord heater passes through the second path in a sealed state by a second sealing member. This device can effectively prevent gas or liquid from leaking into the space where the connection section of a lead wire and a cord heater is provided.

Abstract: A ceramic heater, a heat exchange unit, and a warm water washing toilet seat are provided which have excellent temperature rise characteristics and can reduce the time required to reach a predetermined water temperature. A ceramic heater (5) has a pattern watt density of 50 W/cm2 and above, and a surface watt density of 25 W/cm2 and above. Accordingly, the ceramic heater (5) has a short start-up time and excellent temperature rise characteristics. Further, the thickness of a core is reduced to between 0.5 mm and 1.9 mm (accordingly, circular tube thickness is between 1 mm and 2.4 mm), and this enables heat from the ceramic heater (5) can be efficiently transmitted to water that flows in the circular tube, making the ceramic heater (5) excellent in temperature rise characteristics. Accordingly, a gap between a heat exchanger (3) and the ceramic heater (5) is not necessary to be excessively narrowed.