The invention relates to a cabin air inlet module (16). The cabin air inlet module (16) comprises a streaming channel body (8). The streaming channel body (8) comprises at least one wall which limits a streaming channel wherein incoming air (5) is supplied to a zone (2) of a cabin (3). The cabin air inlet module (16) comprises an electric heating element (9) which is used for heating the incoming air (5). According to the invention it is proposed that the electric heating element (9) is embodied as a two-dimensional heating element (in particular as a heating paper, a heating web, a heating foil or a heating varnish). The two-dimensional heating element extends along a wall of the streaming channel body (8).

The inventive cabin air inlet module (16) is arranged upstream with a small distance (25) from an inlet opening (6) into the zone (2) of the cabin (3). The inventive cabin air inlet module (16) is used for a tempering zones (2) of a cabin (3) of an airplane according to the needs.

A series of metallic heating elements of large sizes are presented. A conventional metallic tubular heating element is positioned into a hollow metallic profile, wherein additional high temperature resistant components are used in different assemblies, as required. A coiled resistance conductor is positioned within the interstice of two metallic tubes fitted into one another, wherein an electrically insulating powder or grit is used within the interstice, and to embed the coiled resistance conductor, and wherein additional high temperature resistant components are used in different assemblies, as required. The assemblies provide methods to reduce the use of electrically insulating powders and/or thermally conductive powders for large size heating elements, and more particularly for radiant purposes; and components are also presented to improve the emissivity of the outer surface of the radiant heating elements with a colorful look, for surface temperatures operating around and up to 500 C. to 600 C.

An electric heating device in an exhaust gas system, the device having an outer circumferential, circular, housing, wherein a rib structure is arranged in the housing. The rib structure can be heated by applying an electric current. The rib structure is arranged with rib rows parallel to one another in the housing, wherein the parallel-arranged rib rows are arranged such that they are electrically connected to one another in series or in parallel.

An electrical radiator type heating appliance comprises a case housing a heater member producing a first flow of calories (F1) when an input of the heater member is powered by a direct electric voltage. The heating appliance also comprises a voltage converter implanted in the case and comprising an input provided with connection elements for connecting the voltage converter to an electric power supply source and an output delivering a direct electric voltage adapted to directly or indirectly power the input of the heater member.

An electrical radiator type heating appliance (10) comprises a case (11) housing a heater member (12) producing a first flow of calories (F1) when an input (121) of the heater member (12) is powered by a direct electric voltage. The heating appliance (10) also comprises a voltage converter (14) implanted in the case (11) and comprising an input (141) provided with connection elements for connecting the voltage converter (14) to an electric power supply source (13) and an output (142) delivering a direct electric voltage adapted to directly or indirectly power the input (121) of the heater member (12).

A portable heater that includes a ceramic substrate with a heating element configured to define a field of direct radiation, a heat reflector with a concave reflective surface configured to define a field of reflective radiation, a grill cover mounted on the heat reflector, where the ceramic substrate is mounted on an interior side of the grill cover with the heating element facing the concave reflective surface such that the field of direct radiation onto the concave reflective surface is unobstructed.

A universal air heating device that can be attached to an existing device. The universal air heating device includes a housing, one or more heating elements contained within the housing, one or more temperature regulating elements for controlling the heating element(s), and an attachment mechanism for attaching the air heating device to an existing device.

A system configured to provide supplemental heating or cooling is provided. Some embodiments may include the fixture having an air movement device and a back surface configured for a flush mount on a wall, the back surface having a recess sized to substantially the same dimensions of a cover of an electrical outlet. The flush mount may provide a degree of permanence for the fixture that satisfies a criterion.

A heating appliance of the electric radiator type, including a housing containing a DC operated electrical energy storage device charged by an electrical power supply source outside the appliance, and at least one heating body that can be powered by the electrical power supply source and/or by the electrical energy storage device. The housing also comprises at least one air inlet arranged in a lower part of the housing to allow air to enter the space internally defined by the housing, and at least one air outlet arranged in an upper part of the housing to allow the air to leave the space. The electrical energy storage device is arranged across the air flow that circulates, in the space, from the at least one air inlet to the at least one air outlet, in a location situated, as observed in the direction of circulation of the flow, between the at least one air inlet and the at least one heating body.

A heating piping device for heating a fluid provided from the gas reservoir unit and introducing the heated fluid into a piping system includes at least one heating unit and a control module. The heating unit includes a mounting cylinder defining a heating space therein, a spiral channel in fluid communication with the gas reservoir unit, a heater member for heating the fluid in the spiral channel into the heated fluid, a flow control valve and a check valve. The control module controls the amount of the fluid flowing into the spiral channel, and the temperature of the heater member. The temperature of the heater member and the amount of the fluid can be adjusted to meet different manufacturing requirements. Unnecessary energy and flow consumption is avoided.