The present disclosure relates to a heater cover assembly for baseboard heater units and components thereof. The components include convertible end caps having cutouts and cover plates that can be used with baseboard heating units. The cutouts accommodate pipes or other obstructions that would otherwise prevent or hinder installation of the end cap.

The present invention relates to a heating device for heating a gas flow, in particular an exhaust gas flow of an internal combustion engine, said heating device comprising an electrically conductive heating element that can be flowed through by the gas flow in an axial direction and that has at least two heating segments that are sectionally separated from one another by a gap that is in particular open at one side; a carrier device having at least one electrically insulating carrier element that at least sectionally surrounds the heating element in a peripheral direction and/or at least sectionally covers a marginal region of at least one axial end face of the heating element, wherein the carrier element has at least one spacer section that projects into the gap; and a housing section in which the heating element and the carrier device are held.

An air-heating type heat not burn heating device, a ceramic heating element and a preparation method thereof are provided. The ceramic heating element includes a honeycomb ceramic body and a heating printed circuit. Porous channels are arranged in the honeycomb ceramic body, and the porous channels are circular holes or polygonal holes. The heating printed circuit is arranged around an outer surface of the honeycomb ceramic body to heat the air passing through the porous channels. According to the ceramic heating element, the surface made of high purity alumina honeycomb ceramic has high compactness, it is able to effectively prevent absorption of smoke dust particles, thus to effectively preventing odd smell; the high-purity alumina honeycomb ceramic has good thermal conductivity, with a thermal conductivity of 33 W/mk; the wall thickness and pore diameter in the honeycomb ceramic structure are both very small, and the thermal conductivity is extremely excellent.

There is provided an electric suspended radiant disk heater apparatus comprising: a central and vertical ceiling mount pole for hanging from a ceiling at an upper end thereof in use; a radiant heater disk element fastened at a lower end thereof, the radiant heater disk element being substantially co-axial with the ceiling mount pole, being substantially perpendicular to the ceiling mount pole and extending radially from the lower end of the pole; and an electric heater element thermally coupled to the radiant heater disk element to heat the radiant heater disk to radiate heat from a radiant heat emitting undersurface thereof.

A hot-air blower comprises a heat lamp with a rated power consumption of 180 W to 380 W, a lampshade having a socket for the heat lamp, a cylindrical outer casing with an inner diameter larger than a largest outer diameter of the lampshade, a lampshade fixing part coupled with the lampshade and fastened to the outer casing to allow the lampshade to be provided on a central axis of the outer casing, an impeller generating an air flow by rotation, a waterproof motor coupled with the impeller to rotate the impeller, and a motor fixing part coupled with the waterproof motor.

A sensor cleaning system for a vehicle is disclosed. In particular, the sensor cleaning system has anti-freezing and defrosting functions. The sensor cleaning system includes: an air tank configured to store compressed air; a heating element disposed in the air tank and configured to apply heat to the air tank; and a controller configured to operate the heating element when a preset condition is satisfied.

According to aspects of the embodiments, an integrated light and heat arrangement of low profile light-emitting diode (LED) fixture to harness both the light and the heat generated by the LEDs is described. New system architectures and example form factors are provided for the development of new LED fixtures for integrative lighting and heating arrangement to increase their overall luminaire system efficiency. The integrative lighting and heating arrangement of the LED fixture in low profile design can minimize interference of harvesting the heat from LEDs with their light output. The heat which would otherwise be wasted from LEDs is harvested for the purpose of heating up some nearby body, such as a body of air, or a component, or a lens to accomplish some benefits, including, for example, reduction in overall energy uses for space heating, cooling, and lighting and associated cost, and melting snow and de-icing on outdoor LED fixtures for safety and security.

An electric radiator is provided. The electric radiator includes: a housing provided with an air channel cover therein; a heating assembly disposed in the housing and defining a natural convection air channel with the air channel cover, an air supply inlet being formed at a first end of the natural convection air channel and an air supply outlet being formed at a second end of the natural convection air channel above the air supply inlet, air in the natural convection air channel being heated by the heating assembly to form a natural convection in the natural convection air channel; a mesh hood mounted onto a front surface of the housing and covering the heating assembly and the air supply outlet; a first temperature limiter mounted onto the heating assembly and adjacent to the air supply outlet in an up-down direction.

A heating module is provided by the present application, which includes a heat insulating tube, wherein a ventilation separator dividing the heat insulating tube into an upper tube chamber and a lower tube chamber is disposed therein, and a plurality of air guiding holes are provided in the ventilation separator, and an air intake structure is configured in the lower tube chamber; a receiving tube disposed inside the upper tube chamber, and an air heating assembly, wherein the air heating assembly is disposed inside the lower tube chamber.

The present invention is directed to personal heating devices, known as heated packs. Heated packs of the invention include a frame and a heating assembly disposed within the frame. The heating assembly may include a heating panel, an intelligent circuit, and a battery. In certain embodiments, one or more sides of the frame include a material configured to absorb heat or release heat in response to the energy outputted by the heating assembly. In further embodiments, the intelligent circuit is configured to change the temperature of the heating pack based a sensory input received by a user.