Abstract: An electric cooking device with a cooking surface. The cooking surface includes a first heating element positioned under the cooking surface arranged to heat substantially the entire cooking surface to a first power density and a second heating element positioned under a portion the cooking surface arranged to heat approximately half of the cooking surface to a second power density. The second power density can be greater that the first power density. The electric cooking device can include a temperature regulator and a selector connected to the first heating element and the second heating element arranged to selectively connect the first heating element or the second heating element through the temperature regulator to a power source.

Abstract: A control panel used in combination with a power unit to control the operation of a sauna. The control panel is equipped with a microprocessor that has software and proper circuitry to allow a user to use buttons to input information into the control panel regarding the time, temperature, and day on which heating within the sauna is to occur. Additionally, the power unit has a microprocessor with a pulse width modulation output that causes individual heating elements to continuously produce varying intensities of heat in order to maintain a consistent desired temperature, and/or intermittently radiate heat creating a wave of heat to be emitted by each individual heating element.

Abstract: A system includes a first heater located at the leading edge of a gas turbine structural member, a second heater located aft of the first heater, and a third heater located aft of the second heater. The first, second and third heaters are electrically-powered to prevent icing of the gas turbine structural member. Each of the heaters has a Watt density, and the Watt densities of the heaters differ from one another as a function of a magnitude of a cooling coefficient for airflow passing the vicinity of each heater.

Abstract: A gas heating device and a processing system for use therein are described for depositing a thin film on a substrate using a vapor deposition process. The gas heating device includes a heating element array having a plurality of heating element zones configured to receive a flow of a film forming composition across or through said plurality of heating element zones in order to cause pyrolysis of one or more constituents of the film forming composition when heated. Additionally, the processing system may include a substrate holder configured to support a substrate. The substrate holder may include a backside gas supply system configured to supply a heat transfer gas to a backside of said substrate, wherein the backside gas supply system is configured to independently supply the heat transfer gas to multiple zones at the backside of the substrate.

Abstract: A cooking appliance and method of operating the same is disclosed. The method includes energizing each of a first heating element, a second heating element, and a third heating element to a maximum power level to supply heat to a separately controlled cooking area, maintaining the second heating element at the maximum power level after a predetermined time interval has elapsed, and selectively energizing the first heating element and the third heating element to the maximum power level after the predetermined time interval has elapsed.

Abstract: A cooking appliance includes a plurality of heating elements and a plurality of user interface devices for receiving heating element settings. An input device for allows a user to arbitrarily selectively associate any one or more of the heating elements with any one or more of the user interface devices.

Abstract: A system for coating a substrate includes a heater that heats the substrate. The heater includes a two-dimensional array of a plurality of heat sources which supply heat to the substrate when the substrate is in the presence of the array of heat sources. The heater further includes a controller that controls the operation of each heat source to heat a localized area of the surface of the substrate according to a predetermined temperature profile for the substrate.

Abstract: A heating system in the form of a multi-layer, yet relatively thin and flexible panel. The panel contains a number of layers including first, second and third electrically insulating layers. A first electrically conductive resistive layer (heater layer) is sandwiched between the first and second insulating layers. A second electrically conductive resistive layer (resistive neutral plane layer) is sandwiched between the second and third insulating layers. The heater layer has a neutral electrical connection and a live electrical connection. The neutral and live electrical connections are electrically connected to each other at the panel only by electrically resistive material of the heater layer extending between the neutral and live electrical connections. The resistive neutral plane layer has a neutral electrical connection electrically connected with the neutral connection of the heater layer.

Abstract: A filament lamp includes multiple filament assemblies having filaments connected to paired leads, arrayed in order within a light emitting tube and following a tube axis thereof. Each lead is electrically connected in a seal area. Each filament is powered independently. The light emitting tube includes insulating walls or inner tubes between the filaments and leads that have openings through which the leads pass, and located along the tube axis in proximity to the inner wall of the light emitting tube. Multiple lead accommodation spaces corresponding to the number of leads are provided in the light emitting tube by the insulating walls with each lead passing through an opening in the insulating wall and placed without short circuits in its lead accommodation space.

Abstract: To fabricate a composite item, an infrared heat source is energized and a composite material is dispensed. The composite material includes a reinforcement and a resin. In addition, the composite material is applied to a substrate of previously applied composite material. The infrared heat source is configured to emit a wavelength of electromagnetic radiation that is absorbed by the resin to a relatively greater extent than the wavelength of electromagnetic radiation is absorbed by the reinforcement.

Abstract: Method for controlling a group of glow plugs in a diesel engine, which are connected with a direct current source via individual supply lines and which are to be controlled by a pulse width modulation process at the same temperature, at least in time average. The electric resistance of the glow plugs, less the resistance of the supply line to the heating element of the glow plugs, is determined during operation of the engine and a relative pulse width at which the glow plugs are to be operated is calculated from the value so obtained.

Abstract: The invention relates to a circuit layout for controlling at least one heating element, in particular a heating element for an electric cooking and/or baking device, with at least one electric temperature sensor for measuring the temperature of the heating element and/or a surface heated by said heating element and with safety electronics for automatic shut-off of the heating element when the temperature measured by the at least one sensor reaches and/or exceeds a temperature threshold value (TS).

Abstract: A multiple heater control system includes cables, connectors, and junction boxes for user-friendly daisy chain connections of heater controllers and heaters in various configurations or combinations of individually controlled heater series and/or master and slave heater series. The heater controllers include process control of AC power to the heaters and upper-limit safety shutoff that is substantially independent from the process control. The heater controllers also have variable levels of control, adjustment, display, and communications functionality in a base module that is expandable to various levels with expansion modules that are attachable to and detachable from the base module. Connector, cable, and junction configurations, adapters, and latch features enhance user friendliness.

Abstract: A heat trace assembly is provided that includes a heat trace section, an insulation jacket surrounding the heat trace section, and a plurality of standoffs disposed between the heat trace section and the insulation jacket. A corresponding plurality of passageways are formed between the heat trace section and the insulation jacket and between the plurality of standoffs. The standoffs can be a part of the insulation jacket and/or the heat trace section, and the standoffs can furthermore be integrally formed with or separately attached to the insulation jacket and/or the heat trace section.

Abstract: According to one aspect, a system for reducing peak power usage of an electromechanically controlled cooking appliance is provided. The system includes at least one infinite switch, one or more heating units, at least one of which comprising at least two separately controllable resistive heating elements, a control operatively coupled to the one or more heating units, the control being configured to receive and process a utility state signal indicative of the current state of an associated utility, wherein the one or more heating units include at least one relay switch configured to selectively enable and disable energization of one of the elements in response to the utility state signal.

Abstract: A dialysis system includes a first fluid heater, a second fluid heater, and a logic implementer configured to synchronize the duty cycles of the first and second heaters so that (i) power is not supplied to the first heater when power is supplied to the second heater and (ii) power is not supplied to the second heater when power is supplied to the first heater.

Abstract: A water heating system including a tank to store water, a temperature sensor positioned to detect a temperature of the water, and a temperature control element configured to alter the temperature of the water. The system also includes a controller configured to control the temperature of the water based on a first temperature threshold during a first time period and monitor the amount of time that the temperature control element is in either the activated state or the deactivated state during the first time period. The control then determines a second temperature threshold for a subsequent time period based on the monitored amount of time.

Abstract: A refrigerated oven having a cooking chamber in which is provided a heating elements and a refrigeration unit chamber in which is provided a refrigeration unit. The refrigeration unit is fluidly connected to the cooking chamber. Both the heating element and the refrigeration unit are selectively operable to either cool or heat the cooking chamber to thereby cool or heat a food item located therein. The refrigeration unit as preferably modular refrigeration unit that the slid into and out of the refrigeration unit chamber. Preferably, the refrigeration unit includes an evaporator that is thermally isolate is from a condenser. The condenser as preferably conductively coupled to a base supporting the elements of the modular refrigeration unit.

Abstract: A heating body is provided. The heating body includes a plurality of heating members having different thermal expansion coefficients and a tube in which the heating members are disposed. At least one of the plurality of heating members supports other heating member.

Abstract: A heater that may be applied to a substrate. The heater may include a graduating material deposited on at least a portion of a substrate, a resistive material and a thermal barrier dielectric coating. The resistive material may include at least two resistive compositions, wherein the resistivity of the material may be altered by varying the composition in given areas.

Abstract: An operating device for an electrical appliance, for example a cooking appliance, is provided with a deformable metallic control panel, underneath which an electret microphone cartridge is disposed. The membrane of the microphone cartridge can be coupled to the lower side of the control panel by means of an elastomer. When pressure is exerted on the control panel by a user pressing on the operating field and causing it to deflect, the membrane of the electret microphone is moved, which in turn causes movement in the microphone and causes a signal that can be evaluated as the operating input by a user.

Abstract: A cooking appliance including two or more independently controllable heating elements disposed on a cooktop of the cooking appliance; and a control circuit including two or more switches and configured to be operative in a first mode to enable each switch to independently control a respective one of the two or more independently controllable heating elements, and operative in a second mode to disable independent control of the two or more independently controllable heating elements, and enable one of the switches to simultaneously control the respective ones of the two or more independently controllable heating elements as a single unit.

Abstract: Method for heating at least one component of an SCR system using several resistive heating elements, according to which these heating elements are fed in parallel by a current source and according to which a current sensor is placed in series with the current source and all the resistors, which are connected in parallel.

Abstract: An electrostatic chuck (“chuck”) is provided for controlling a radial temperature profile across a substrate when exposed to a plasma. The chuck includes a number of independently controllable gas volumes that are each defined in a radial configuration relative to a top surface of the chuck upon which the substrate is to be supported. The chuck includes a support member and a base plate. The base plate positioned beneath and in a spaced apart relationship from the support member. The gas volumes are defined between the base plate and the support member, with separation provided by annularly-shaped thermally insulating dividers. Each gas volume can include a heat generation source. A gas pressure and heat generation within each gas volume can be controlled to influence thermal conduction through the chuck such that a prescribed radial temperature profile is achieved across the substrate.

Abstract: In the present invention, a thermal plate is divided into a plurality of thermal plate regions, and a temperature is settable for each of the thermal plate regions. A temperature correction value for adjusting the temperature within the thermal plate is settable for each of the thermal plate regions of the thermal plate. The line widths within the wafer for which the photolithography process has been finished are first measured, and Zernike coefficients of a Zernike polynomial indicating a plurality of in-plane tendency components are calculated from the measured values of the line widths within the wafer. Then, the temperature correction values for the regions of the thermal plate to bring the calculated Zernike coefficients close to 0 are calculated using a calculation model indicating a correlation between change amounts of the Zernike coefficients and the temperature correction values.

Abstract: Method for controlling a group of glow plugs in a diesel engine, which are connected with a direct current source via individual supply lines and which are to be controlled by a pulse width modulation process at the same temperature, at least in time average. The electric resistance of the glow plugs, less the resistance of the supply line to the heating element of the glow plugs, is determined during operation of the engine and a relative pulse width at which the glow plugs are to be operated is calculated from the value so obtained.

Abstract: In a heating unit, based on a required output amount Q, a control part 50 performs: (A) when the required output amount Q is not more than a predetermined set value, a control in which none of the heating devices 24a is continuously kept on throughout a heating cycle, and all or one or more heating devices 24a are controlled in a periodically divided manner; and (B) when the required output amount is larger than the predetermined set value, a control in which all or one or more heating devices 24a are continuously kept on throughout the heating cycle, and all or one or more heating devices 24a among the remaining heating devices 24a are controlled in the periodically divided manner during this heating cycle. At this time, a difference between the maximum number and the minimum number of the heating devices 24a that are simultaneously kept on during the heating cycle is made not more than 1.

Abstract: A multiple zone temperature controller for a hot runner injection molding system. The temperature controller includes inputs for signals from two or more thermocouples corresponding to two or more heating zones. The thermocouple inputs are time-division multiplexed and the output is amplified and input to a microcontroller. The microcontroller manages and controls operation of power switching stages for controlling the power supplied to heating elements corresponding to each of the heating zones. The multiplexer is a low impedance switch.

Abstract: For avoiding the selection and storage of PTC heating elements with different departures from rated heating power, additional tolerance PTC heating elements are held ready which uniformly have a lower rated heating power, preferably one half or third of the rated heating power, compared to the standard or primary PTC heating element. By the use of a second standardized heating element, i. e. the tolerance PTC heating element, the storage of a high number of PTC heating elements with different departures can be dispensed with and a cheaper manufacture can be permitted.

Abstract: A fluid heating system includes a fluid receptacle having a fluid reservoir, and a heating control system configured to heat fluid retained within the fluid reservoir. The heating control system includes a processing unit, at least one fluid temperature sensor positioned on or within the fluid receptacle, a heating element configured to heat fluid within the fluid reservoir, and a power switch disposed within an electrical path between the heating element and the processing unit. The processing unit is configured to selectively activate and deactivate the heating element through the power switch based on the fluid temperature detected by the fluid temperature sensor.

Abstract: An operating device for a cooktop has a cover with a control panel with a plurality of operating areas. Below the panel, several FSR sensors are positioned. When a control panel is pushed down by a process of operation, the FSR sensor changes its electrical resistance resulting in change of a signals that can be detected and interpreted as operation of the appliance by a user.

Abstract: A countertop toaster oven has an internal compartment heated by at least four heating elements and a door for the compartment. At least two of the heating elements are top elements, located adjacent to a ceiling of the compartment. Two of the heating elements are lower elements, located along a floor of the compartment. At least one of the elements is controllable to provide a variable wattage including one or more operational wattages that are for at least a portion of the heating cycle, intermediate between zero power and full power.

Abstract: A road finisher has a terminal box from which an electric supply circuit originates to supply electric current to at least one electric heating element for heating work components. A device for supervising the function of the at least one electric heating element includes an induction coil at the terminal box to sense current in the supply circuit and an indicator circuit, preferably of a light emitting diode, is connected to the induction coil for detecting and indicating a voltage induced in the induction coil by the current flowing in the supply circuit of a heating element. In a preferred embodiment, a cable gland is attached to the control box through which a current supply wire of the electric supply circuit passes, and an induction coil is located in the cable gland to sense the current in the supply wire.

Abstract: A method and apparatus for rapid temperature changes of thin samples is disclosed. The apparatus comprises of a thin-film resistive element embedded in a membrane, a narrow gap between the membrane and a heat sink, and a control circuit. The resistive element acts both as a heater and as a temperature sensor to reduce time constant of the control circuit. The gap between the membrane and the heat sink is filled with gas (e.g., N2 or He) acting as cooling medium with low thermal inertia. The temperature controller has a microsecond time constant, which allows adjusting rapidly the power applied to the membrane, depending on heat released/absorbed by a sample during an isotherm or during a given rate of temperature changes. The membrane has low thermal inertia and, coupled with high-speed temperature controller, allows controlled cooling and heating rates up to 100 000 K s?1 and higher. The method can be a core of any setup where controlled fast temperature-time profile of thin or small sample is desirable.

Abstract: A control system suitable for use with a bathing unit system having a water receptacle is provided. The control system comprises a heating module, a power source and a controller in communication with the heating module and the power source. The power source includes an energy storage member for storing energy collected from a solar panel, and is operative for supplying power generated from solar energy to the heating module. The controller is operative for causing the power source to supply power to the heating module at least in part based on first information derived from a temperature of the water within the water receptacle and second information derived from a condition associated with the power source. The controller is further operative for selecting between a first power source and a second power source for supplying power to the heating module.

Abstract: An intelligent user interface for the selection of predefined cooking profiles for a number of different foods to be cooked in a multi-purpose oven using infrared heating. When a food has not been predefined for cooking in the infrared multi-purpose oven, procedures used for conventional cooking technologies may converted to for use by the multi-purpose oven so as to obtain substantially the same cooking results for the desired food. The intelligent user interface may have menus of different foods for programming cooking profiles for the infrared multi-purpose oven. Predefined “hot buttons” may be used for quick selection of a cooking profile for a desired food (e.g., common foods such as popcorn, pizza rolls, chicken wings, oven fries, and other prepared and frozen foods), and/or a menu screen may be scrolled through to select a cooking profile for the desired food.

Abstract: A control panel used in combination with a power unit to control the operation of a sauna. The control panel is equipped with a microprocessor that has software and proper circuitry to allow a user to use buttons to input information into the control panel regarding the time, temperature, and day on which heating within the sauna is to occur. Additionally, the power unit has a microprocessor with a pulse width modulation output that causes individual heating elements to continuously produce varying intensities of heat in order to maintain a consistent desired temperature, and/or intermittently radiate heat creating a wave of heat to be emitted by each individual heating element.

Abstract: A heater controlling apparatus for controlling a heater that heats a sensing element of a gas sensor provided in an exhaust system of a diesel engine includes a device that changes a reference condition for controlling the heater after a start of the engine in a first operation based on an operational state before a stop of the engine in a second operation, which precedes the first operation.

Abstract: A hot melt adhesive hose assembly has a redundant control circuit fixedly mounted thereon which comprises a pair of heater circuits for heating a hot melt adhesive hose assembly to a predetermined temperature level, and a pair of temperature sensors which are used to sense the temperature of the hot melt adhesive hose assembly wherein the sensed temperature level will be used to control energization of the heater circuits in order to maintain the desired temperature level. A first one of the heater circuits is initially electrically connected to the hot melt adhesive hose assembly electrical circuitry, and in a similar manner, a first one of the temperature sensors is likewise electrically connected to the hot melt adhesive hose assembly electrical circuitry.

Abstract: The present invention provides a control system for a bathing unit that comprises a heating module, a temperature sensing entity and a heating module controller. The heating module includes a body that defines a passage through which water can flow, that has an inner surface and an outer surface. The heating module further includes a heating device that is operative for heating the water that flows through the body. The temperature sensing entity is mounted to the outer surface of the body such that the temperature sensing entity is in thermally conductive communication with water flowing through the body. The heating module controller is operative for obtaining temperature information associated with the temperature sensing entity for detecting at least in part on the basis of the temperature information the sufficiency of water flow through the body.

Abstract: In one aspect, a cooktop heating system that include a first cooktop heating element, a second cooktop heating element, and an interface device. The system also includes a controller for selectively associating the interface device with any one or both of the first cooktop heating element and the second cooktop heating element. In another aspect, the system includes at least one cooktop heating element, a potentiometer, and controller arrangement operatively connected between the potentiometer and the at least one cooktop heating element to determine heating of the at least one cooktop heating element responsive to the input provided by the potentiometer and control power provision to the at least one cooktop heating element responsive to the determination.

Abstract: A thermal head driving method of driving thermal heads is disclosed. The method includes a step of dividing the thermal heads into plural groups, providing for each of the groups a common potential terminal, a step of using a drive circuit to drive the thermal heads of one or more of the groups, and a step of applying an operating voltage to the common potential terminal of said one or more groups driven by the drive circuit.

Abstract: An electrical heating assembly (2) includes a control system (26). The control system (26) comprises cooking mode selection means (34) having a plurality of settings whereby a predetermined cooking mode is user-selectable for the electrical heating assembly (2), and cooking value selection means (36) adapted for user-selection of a cooking temperature within a predetermined temperature range. The control system (26) is adapted whereby operation of the cooking mode selection means (34) from one setting to at least one other setting results in a change in the predetermined temperature range provided by the cooking value selection means (36).

Abstract: A heating apparatus assembly and method are provided for heating a surface. The heating apparatus contains a substrate with a multiplicity of heating elements disposed upon at least one surface of the substrate where each element is individually controllable.

Abstract: A system for coating a substrate includes a heater that heats the substrate. The heater includes a two-dimensional array of a plurality of heat sources which supply heat to the substrate when the substrate is in the presence of the array of heat sources. The heater further includes a controller that controls the operation of each heat source to heat a localized area of the surface of the substrate according to a predetermined temperature profile for the substrate.

Abstract: A method of controlling a gas-fired water heater. A resistance input is received from a sensor configured to sense flammable vapor near the heater tank. The resistance input is compared to one or more previously received inputs from the sensor. Based on the comparing, one or more functions of the heater are controlled. This control method can be used to compensate for gradual ageing of the sensor.

Abstract: Methods and systems for controlling and adjusting heat distribution over a part bed are disclosed. In one embodiment, a technique for providing a calibrated heat distribution over a part bed includes determining the temperature distribution within a part bed, generating a zone heat distribution for a plurality of heat zones from the temperature distribution, analyzing the zone heat distribution to create an adjustment command to calibrate a heater for providing a substantially consistent temperature distribution within the part bed, and adjusting the heater based on the adjustment command.

Abstract: A heating apparatus includes a plurality of heating means that heat a heated object, a temperature measuring means that measures temperatures of some of the plurality of heating means, a heated object information storing means that stores, in a coordinate manner, heated object identification names, target heating temperatures at the heating means, and sets of heating ratios respectively assigned to the heating means, a heating information storage means that defines a relationship between temperatures during heating of the heating means up to the target heating temperatures and heating intensities at the temperatures, a heated object identification name obtaining means that obtains one of the heated object identification names, a heated object information reading-out means that reads out one of the target heating temperatures and one of the sets of heating ratios respectively assigned to the plurality of heating means, corresponding to the heated object identification name from the heated object information st

Abstract: An electrical heating device is disclosed that is suitable to vaporize air treatment chemicals from an impregnated substrate. The device is provided with a PCT heater held between electrical contacts and a spring that is compressed between the housing of the heating device and one of the electrical contacts to maintain pressure thereon in spite of thermal expansion of the housing, ensuring good electrical contact between the PCT heater and the electrical contacts.

Abstract: A heatable container suitable for material such as bitumen. The container includes a vessel for holding a flowable material having side wall zones, end wall zones and a base wall zone. The container also includes a heating system for transferring heat to at least the base wall zone as well as a zone disposed along a central longitudinal axis of the vessel. The heating system may also included at least two internal heating ducts for conveying a heat transfer medium, wherein the ducts are disposed substantially parallel relative to the central longitudinal axis of the vessel, and are vertically and horizontally spaced apart relative to one another.