Flow control devices for convector heaters are provided. Such devices may include a casing in the shape of a cylindrical tube having in a first portion thereof, facing in a mounted condition towards the intake conduit of a convector heater, a plurality of first openings and in a second portion thereof, facing in the mounted condition towards the opposite side of the intake conduit, a plurality of second openings, the casing being arranged to be mounted onto the ceiling (S) in such a manner that the first and second openings allow the inside of the casing to be placed into communication with a first space (A1) beneath the ceiling (S) and with a second space (A2) above the ceiling (S), respectively; a closure member in the shape of a cylindrical tube which is mounted within the casing and is axially slidable relative to the latter between a first position, in which it leaves the first openings open and closes the second openings, and a second position, in which it closes the first openings and leaves the second openings open; and actuation elements for controlling the axial sliding movement of the closure member relative to the casing between the first and second position.

An electric fireplace (410) includes a fireplace housing (412) and a heater assembly (426) that is configured to generate heated air. The heater assembly (426) is configured to be installed substantially within the fireplace housing (412). The heater assembly (426) includes a heater body (445), a first grill cover (448) that is selectively couplable to the heater body (445), and a second grill cover (548) that is alternatively selectively couplable to the heater body (445). The first grill cover (448) has a first cover length (468), and the second grill cover (548) has a second cover length (568) that is different than the first cover length (468). The heater assembly (426) is selectively positionable within a cabinet (311) having a structural opening (311A), and a center shelf (360) that defines at least a portion of an upper side (311U) of the structural opening (311A). The heater assembly (426) is installed substantially adjacent to the center shelf (360).

A thermo-electric heating assembly for forced air, residential and commercial heating, ventilation and air conditioning (HVAC) systems includes a housing, a controller and a plurality of carbon nanotube (CNT) heating elements, arranged in the housing. The controller is adapted to respond to a signal received by the controller indicating a need for heat by powering the carbon nanotube (CNT) heating elements at a controlled electrical power level for a controlled period, commensurate with the indicated need for heat. The CNT heating elements include upper and lower metallic radiator, at least two composite containment vessel and at least two 3D CNT graphene films. The CNT heating elements preferably include a third composite containment vessel and a layer of MgSO.sub.4 or MgO.

An electric heater to heat a flow of a fluid having a jacket block comprising a plurality of longitudinal bores to allow the through-flow of a gas phase medium. An elongate heating element extends through each of the bores and is positionally stabilised within the jacket block via a plurality of stabilising fins that project radially inward to at least partially surround the elongate heating element within each of the bores.

The present disclosure is directed to systems and methods for providing an electrically operated fireplace that includes a one or more display panels, one or more reflective surfaces inclined at an angle with respect to the one or more display panels to reflect the video images of a flame displayed by the one or more display panels. One or more filters or privacy screens are disposed proximate the one or more display panels. Beneficially, the electrically operated fireplaces disclosed herein do not require the use of moving parts, such as a rotating mirror, to provide the images of the flames. Further, since video images are used to provide the flame effect, the flame effect may be varied simply by loading a new video image into the memory portion of the control circuitry used to provide the flame display.

An electric resistance radiant furnace is disclosed. Solid ceramic panel emitters having electric resistance wires embedded therein produce heat. A blower receives air from a return duct. Metallic screens are located between the panel emitters. A thermostat is connected to the wires and the blower. Heat is produced by each panel emitter. Part of the heat produced is radiated from the ceramic body to the metallic screens. Air flows in a parallel manner between the panel emitters and along the metallic-screens. The thermostat heat buildup by turning on the panel emitters controlling the blower. A short cycle air pass conduit accepts a portion of heated air from between the multiple panel emitters and to convey the portion of heated air to the return duct, such that the portion of heated air is mixed with return air, and a temperature of the return air provided to the blower is elevated.

A heating and humidifying device and a heating and humidifying method. The heating and humidifying device comprises a housing (1), a water tank atomizing set, a steam generator, a heating breathing pipeline, and a controller. A tank body (11) of the water tank atomizing set is buckled with a plurality of elastic pieces (5) in the housing by means of buckling strips on the outer side wall of the water tank atomizing set; the steam generator is snap fit with grooves (8) on the two sides of the housing (1) by means of the buckling pieces (29) on the two sides; a mist outlet (13) on the tank body (11) of the water tank atomizing set is connected to a connector (38) of the steam generator; a gas outlet (28) on the steam generator is connected to the heating breathing pipeline. The heating and humidifying method comprises the steps of: (1) water injecting atomization; (2) water mist gasifying; and (3) heat insulating and gas exhausting.

Disclosed is an air duct and an air system and methods and uses of said air ducts and air system. The air duct has electrically conductive elements integrated with the walls of said air ducts for insulation of walls of said air ducts, and/or heating of the air flowing through the air ducts. The air duct can be used in an air system, for instance an air system for purposes of air cleaning, heating, refrigeration, ventilation or air conditioning in a building or means of transport.

A heater device for warming a user has a heater panel including a planar heating element which generates heat by energization, a first heat radiation surface formed on one surface side of the heating element, and a second heat radiation surface formed on the other surface side of the heating element. The temperature of the first heat radiation surface is higher than the temperature of the second heat radiation surface. In the heater panel, the first heat radiation surface is configured as a non-contact heater that warms the user in a non-contact manner, and the second heat radiation surface is configured as a contact heater that warms the user in a contact manner.

The invention relates to a method of manufacturing a heating device (1) which has a fan (3) located behind a grid (2) in an interior (10). The fan (3) is mounted in the interior (10), and the grid (2) is mounted as a part of the heating device (1). The speed of the fan (3) is determined in a contactless manner by evaluating a reflection behavior of the fan (3) in that a light signal (50) is emitted through a recess (20) in the grid (2) in the direction of the fan (3), and/or is received through a recess (20) in the grid (2) from the direction of the fan (3). Furthermore, the invention relates to a heating device (1).