RU13416U1 - ELECTRIC HEATING PANEL - Google Patents

Abstract

1. The electric heating panel, containing two panels with air space, inside which there is a heating element fixed in ceramic plates, characterized in that the space between two heat-emitting panels is filled with an inner layer of cellular concrete, which allows to obtain a directed heat flux due to low thermal conductivity, a heating element located in the figured grooves of aerated concrete. 2. Electric heating panel, characterized in that the curly grooves with heating elements are filled with an electrical insulating cement composition. 3. The electric heating panel, characterized in that the cellular concrete is lined on both sides with a material having high thermal conductivity, low electrical conductivity and high moisture resistance.

Description

The utility model relates to the field of heating and can be used for heating industrial and residential premises, as well as garages, construction utility wagons, shopping pavilions, car service centers, garden houses, etc.

A flexible electric heater is known, comprising an insulated cover in which an insulation panel is fixed with parallel rows arranged, resistive elements with current leads (1).

The disadvantages are the complexity of the design, the complexity of the connection, low reliability of the contact connection, limited scope.

Known panel electric heater containing a housing made of metal with an insulated heating element (2).

The disadvantage is the complexity of manufacturing technology, the reliability of the design for electrical insulating properties.

Closest to this utility model is a panel heating element containing a front panel made of natural stone with an electric heater fixed to its back side using heat-resistant glue, made in the form of bonded ceramic plates or synthetic films and placed between them and applied to the surface one of them is an electric heating element and a reflective panel, the inner surface of which is made mirrored and is located at a predetermined distance from the electric Heater with the formation of open outward airspace.

The disadvantage is the complexity of the design, the complexity of the manufacturing process, requiring high costs, limited application, low heat transfer, low degree of electrical protection when using adhesive components as environmentally hazardous substances during installation.

The utility model is aimed at improving heat transfer, simplicity of design, energy saving, cheaper manufacturing, ensuring a high degree of protection against electrical fire safety, environmental friendliness during assembly and operation.

Structurally, the panel is a rectangular, supporting frame, inside of which, in a layer of cellular concrete as the main structural element with curly grooves, a loop-shaped heating element is laid, which is a spiral of high-resistance material.

When assembling the panel, the electric heating layer of cellular concrete is placed in the frame, curly grooves with a heating element

filled with filler from an insulating cement composition.

The panel is lined on both sides with the use of building and finishing material with a high coefficient of thermal conductivity, in particular ceramic material, which acts as heat-emitting panels.

The essence of the utility model is illustrated by the drawing, where Fig. 1 shows a general view without facing and filler, and Fig. 2 shows a cross section of an electric heating panel.

For the manufacture of an electric heating panel, cellular concrete with a low coefficient of thermal conductivity (Table 1) was used as the inner layer, which ensures low heat loss for heating the panel itself. Aerated concrete has a porous structure, low bulk density, high fire resistance and frost resistance, is easy to machine and can be poured into molds.

As the inner layer, the use of expanded polystyrene concrete and other foamed thermal insulation and assembly materials that are not fire hazardous, containing a minimum of components harmful to health and adversely affecting the environment and a reasonable reduction in energy costs is allowed.

The electric heating panel is assembled and operates as follows:

In the frame 1, an inner layer of cellular concrete 2 is placed, in the figured grooves of which a heating resistive element 3 is located. The element is a spiral made of a material with high resistivity, which is easily fixed in the grooves due to spring properties, i.e., its geometry.

Consequently, there is no need for any fasteners.

Then, the curly grooves are filled with an insulating cement composition. On both sides, the surface of the inner layer is faced with a screed made of an insulating cement composition - ceramic tiles.

The panel has conclusions 4 for connecting to a stationary three-wire electrical network with a zero protective conductor (Figure 1).

The work is as follows.

The heat given off by the electric heating panel (Fig. 2) is directed to a heated room. This is due to the fact that the electric heating element 3, placed in curly grooves, transfers heat through a heat-conducting filler 5, a screed used to the heat-emitting panels 4 from ceramic tiles with high thermal conductivity.

Heat transfer is carried out by thermal conductivity, the temperature difference in the medium is a prerequisite for the occurrence of heat transfer in it, and the design of the panel with different coefficients of thermal conductivity of its constituent materials allows

carry out directed heat transfer to heat-emitting panels.

In this utility model, the inner layer of aerated concrete 2 has a low coefficient of thermal conductivity X (tab. 1), and the heat-emitting panels X.2 and the filler X3 have a higher coefficient, so the heat flux has a directed movement to the heat-emitting panels.

The electric heating panel has a low inertia and therefore energy is not wasted on heating the panel itself and there is a rapid heating of the heat-emitting panels.

Heated heat-emitting panels become a source of intense thermal radiation and scatter the heat flux into the surrounding space by radiation and convection, depending on the location of the electric heating panel.

Using the electric heating panel will provide:

1. An increase in heat transfer and a decrease in energy consumption due to the use of cellular concrete as the inner layer of an electric heating panel.

2. Regulation of the heat transfer of the panel through the use of materials for heat-emitting panels with various heat-conducting abilities.

3. Cost-effective due to the rapid achievement of the operating temperature (cellular concrete has low thermal conductivity), thermal energy is sent directly to the heat-emitting panels.

4. High reliability due to the relatively low operating temperature of the heating element + 140 ° C.

5. The degree of protection IP43 will allow the use of this design in wet rooms.

Sources of information:

1.AC 847526 H05V 3/36

2.AC 714663 H05V 3/30

3.Pat. RF 2038545 F24H 3/04

Author 23.0 & 39 / & / Olishevets V.N., Comparative table of used thermophysical indicators of materials in electric heating panels.

Claims (3)

1. The electric heating panel, containing two panels with air space, inside which there is a heating element fixed in ceramic plates, characterized in that the space between two heat-emitting panels is filled with an inner layer of cellular concrete, which allows to obtain a directed heat flux due to low thermal conductivity, a heating element located in the figured grooves of aerated concrete.  2. Electric heating panel, characterized in that the curly grooves with heating elements are filled with an electrical insulating cement composition. 3. Electric heating panel, characterized in that the cellular concrete is lined on both sides with a material having high thermal conductivity, low electrical conductivity and high moisture resistance.