RU178958U1 - INFRARED HEATER - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used to heat any premises, people, animals, various types of land, air and water transport. The device contains a radiating surface (glass) 1 with a heat-resistant mesh 2, a heating element 3, a heat-insulating material 4 and a reflector 5. The technical result is to increase the efficiency and reliability of the heater by increasing the strength of the radiating surface. 2 ill.

Description

The utility model relates to electrical engineering, in particular to electric heaters, and is intended for heating any premises, people, animals, various types of land, air and water vehicles.

Known film electric heater (RU 76764 U1, IPC Н05В 3/14, Bull. 27, 2008), containing a meander-shaped resistive heating element located between two flexible heat-resistant electrical insulation films and equipped with leads for connection to the electric network, and a radiating element made of thin aluminum foil installed between the external insulating film and the resistive element and the thinnest insulating film separated from it, as a heating element, a circuit consisting of stretched x and fixed on a heat-resistant electrical insulating film at the same distance from each other are rods of high-resistance wire with a constant cross section along the length, connected at the ends with each other using contact plates.

Known resistive heater (RU 22578 U1, IPC H01B 3/16, publ. 10.04.2002) containing a substrate of a dielectric material coated with a conductive layer, the conductive layer is made in the form of parallel strips of amorphous metal coated on both sides with a polymer film . The substrate is made of polyethylene foam, on one side of which aluminum foil is applied, and the outer surface of the conductive layer is fixed with a protective fabric, in which slots are made.

A common disadvantage of the heaters described above is that when the radiating surfaces of the devices are turned on, they heat up with different expansion coefficients, which leads to their cracking and, consequently, to a reduced service life.

The closest in technical essence to the claimed technical solution is a heat-emitting building decoration material (RU 87596 U1, IPC Н05В 3/14, 2006.1, Bull. 28, 2009), containing a sheet of a given size, on which from the side opposite the front surface, a flat radiant heating element is applied. An electric heater with an infrared radiation spectrum is used as a flat radiant heating element. The radiating sheet may be made of tempered glass, ceramic, marble, etc.

The main disadvantage is the heating of the radiating surface with a different expansion coefficient, which leads to the rapid degradation of this surface and its rapid destruction.

The objective of the proposed technical solution is to develop a heater with an increased resource of the operating mode, by increasing the life of the radiating surface.

The technical result is to increase the efficiency and reliability of the heater by increasing the strength of the radiating surface.

The technical result is achieved due to the fact that in a device containing a radiating surface, a heating element with an infrared radiation spectrum, a heat insulator, a reflector, the heat insulator being located between the heating element and the reflector, and a heat-resistant grid is attached to the radiating surface.

Equipping the radiating surface with a heat-resistant mesh allows you to increase its strength, which will increase the efficiency and reliability of the heater.

The proposed technical solution is presented by the following drawings.

In FIG. 1 shows a longitudinal section of an infrared heater;

in FIG. 2 shows a top view of an infrared heater.

The device comprises a radiating surface (glass) 1 with a heat-resistant mesh 2, a heating element 3, a heat-insulating material 4 and a reflector 5.

The device operates as follows.

The heating element 3 with an infrared radiation spectrum included in the electric network is heated to a nominal temperature (60-90 ° C), transfers its heat to the radiating surface 1, for example, tempered glass, which is equipped with a heat-resistant mesh 2, while a decorative coating is applied to the glass 1. The reverse side of the heating element 3 gives off heat to the insulating material 4, which does not allow most of the thermal energy to reach the reflector 5, and the remaining energy reaches the reflector 5 and forms the reflected component of the heat flux, which is already directed to the radiating surface 1.

Claims (1)

An infrared heater comprising a radiating surface, a heating element with an infrared radiation spectrum, a heat insulator, a reflector, the heat insulator being located between the heating element and the reflector, characterized in that a heat-resistant mesh is attached to the radiating surface.

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