A portable heater with features to prevent or minimize fuel gelling is disclosed. The portable heater can include a fuel tank, a burner assembly, a combustion chamber tube, and a fuel line extending between the fuel tank and the burner assembly. In one aspect, at least a portion of the fuel line is heated by the combustion chamber tube. The fuel line can extend along an exterior side of the combustion chamber tube. Where the combustion chamber tube is an inner tube disposed within an outer combustion chamber tube, the fuel line can extend within an interstitial space defined between the combustion chamber inner and outer tubes. A preheater may also be provided in the fuel tank to preheat fuel proximate an inlet of the fuel line.

The present invention relates to a flow generating device. The flow generating device according to an embodiment of the present invention includes: a suction portion configured to suction air; a fan configured to introduce the air suctioned into the suction portion in an axial direction so as to discharge the suctioned air in a radial direction; a fan housing including a housing plate configured to support the fan, a guide wall protruding from one surface of the housing plate to surround at least a portion of an outer circumference of the fan, and a discharge portion disposed outside the guide wall; a cover configured to surround the fan and the fan housing; and at least one heater disposed between the outer circumference of the fan and the cover.

A portable indirect fuel fired heater includes a burner assembly having a fuel burner to deliver fuel from a fuel supply to a combustion chamber of the heater and a combustion air blower to deliver combustion air to the combustion chamber with the fuel for combustion in the combustion chamber to produce exhaust gases. A heat exchanger receives air to be heated in heat exchanging relationship with at least a portion of the combustion chamber. A sensor senses an oxygen level as a partial pressure of oxygen in the exhaust gases. A controller operates an actuator operatively connected to the burner assembly to controllably vary the delivery rate of combustion air and thus vary the ratio of the air and fuel responsive to the oxygen level sensed by the combustion sensor so as to maintain the sensed oxygen level at a prescribed set point level stored on the controller.

A system for coating removal comprises a frame having a platform extending within the frame. A plurality of heat lamps are mounted on the platform. The plurality of heat lamps are arranged to provide a heat density of at least 40 watts per square inch. A method of removing a coating is also disclosed.

A movable fluid fuel heater to heat air and to introduce it into an environment to be heated. The heater includes a flow rate variator device for varying the flow rate of oxidizing air introduced in the combustion chamber by a forced ventilation device between a minimum flow rate value and a maximum flow rate value. The heater also includes a reference device comprising a plurality of reference values of a parameter representative of the pressure and a plurality of reference temperature values of the environmental air upstream of the combustion chamber. The reference device is configured to suggest an optimal setting value to set the flow rate variator device, at each pair of values formed by a value of the plurality of reference values of a parameter representative of the pressure and a value of the plurality of reference temperature values.

Disclosed is an energy-saving and environment-friendly double-row air duct heater, including a bottom plate and a shell. A motor and fan blades are arranged on one end in the shell. The upper part of the shell is provided with a control device. A heating component is arranged on the other end in the shell. An air inlet is formed at the rear end of the shell, and an air outlet is formed at the front end of the shell. The heating component includes an air volume drainage device. Two groups of electric heating pipes are arranged on both sides of the air volume drainage device. Each group of electric heating pipes is composed of a plurality of vertically arranged electric heating pipes. An air guiding passage is formed between two adjacent electric heating pipes.

A foothold including a thermoelectric module includes a body having an air channel in which a suction fan is provided and a dissipation channel in which a dissipation fan is provided, and a cover including an air discharge portion disposed on the body. Further, the thermoelectric element is disposed between the dissipation heat sink and the cover.

A portable heating device for delivering warm air to the extremities of a user, for increasingly comfort and/or facilitating sleep. The portable heating device includes a heating module situated within a case, and a retractable and detachable hose that is able to attached to a hot air-releasing vent on the heating module to deliver the hot air to a desired space. The portable case includes an electronic display and a control unit for setting a desired temperature set point. The heating module is able to be powered by either a cable connected to an external power source and/or one or more internal batteries within the heating module.

Provided is a heating blower, comprising an air duct, a motor and a wind wheel arranged in the air duct, and a heating device arranged at a first air outlet of the air duct; the wind wheel is fixed to a rotating shaft of the motor; the heating device comprises a housing, an electric heater, a rotary assembly and an air deflector; the housing is sleeved on the first air outlet, forming an inner chamber, which comprises a first area facing directly to the first air outlet and a second area not facing directly to the first air outlet; the electric heater is arranged in one of the first area and the second area; one end of the air deflector is fixedly arranged on the rotary assembly, and the other end of the air deflector rotates with the rotary assembly between the first area and the second area, separating the first area and the second area, so that the first air outlet is communicated with one of the first area and the second area.

One or more techniques and/or systems are disclosed for a heating device may comprise a control assembly having a self-contained, on board power supply. A control unit may control the operation of the heater and the power supply may comprise a first power source in electrical communication with the control unit, wherein the control unit controls the operation of the first power source to selectively supply electrical power to at least a portion of the heating device; and, a second power source in electrical communication with the control unit, wherein the control unit controls the operation of the second power source to selectively supply electrical power to at least a portion of the heating device.