RU190093U1 - INFRARED ELECTRICAL HEATER, INCLUDED IN SUSPENDED CEILING - Google Patents

Abstract

The utility model relates to an infrared electric heater used in the Armstrong-type suspended ceiling system for space heating. The technical result of the claimed utility model is to increase the reliability of the device. An infrared electric heater embedded in a suspended ceiling contains a body made of hardened K-glass with a low emissivity conductive coating and a heat-insulating material that is applied to the conductive coating, while metallized conductive tires are applied to the edges of the glass surface.

Description

TECHNICAL FIELD

The utility model relates to an infrared (IR) electric heater used in the Armstrong-type suspended ceiling system for space heating.

BACKGROUND

Known electric heater, disclosed in EN 130374 U1, publ. 07/20/2013. An electric heater contains a thin-layer heating element connected to the power supply, a heat-insulating element and means for fixing the electric heater to a wall, floor or ceiling. At the same time, the electric heater contains monolithically assembled layers including an external metal shell over the entire surface of the electric heater, a heat insulator placed in it sequentially, a previously insulated flexible non-metallic one.

The disadvantage of this electric heater is the use of electrically heated carbon resistive coating, which is difficult to apply, it is difficult to bring energy to it, respectively, respectively, problems arise with reliability, performance, overheating at high specific powers of the electric heater.

In addition, from the prior art known electric heater, disclosed in RU 151643 U1, publ. 04/10/2015, the prototype. The electric heater contains a thin-layer heating element connected to the power supply, thermal insulation, it contains monolithically assembled layers, including an external insulating casing, successively placed thermal insulation and a pre-insulated flexible non-metallic heating element based on carbon resistive. The heater contains an infrared heating element, an electrical input box with a built-in thermal switch and a connecting wire with double insulation. At the same time, the infrared heating element consists of a carrier element, the front part of which is a thermal source of infrared action; moreover, a layer of heat-resistant, thermoplastic glue is applied to the back surface of the carrier element, with which a flexible heating resistive element is fixed. In addition, two electrical contacts are fixed on opposite edges of the flexible heating resistive element, to which a current lead is connected with a solder or conductive carbon-polymer composition, and the entire return surface of the supporting element, the flexible heating resistive element and electrical contacts are electrically insulated to prevent electric shock; wherein the flexible heating resistive element comprises a fabric substrate and a conductive resistive layer formed on the basis of a resistive carbon composite material comprising a conductive phase based on carbon black and a polymeric binder. At the same time, the resistive carbon composite material contains technical carbon with a highly developed specific surface area of 300x600 m ² / g and above, with a particle size of 10 to 50 nm in combination with colloidal graphite preparations with graphite particles less than 4 microns and a solution of heat-resistant polymer binder; at the same time, in the flexible heating resistive element, the fabric substrate is impregnated with resistive carbon composite material; at the same time, the thermal insulation is fixed in place by an external insulating sheath, which is glued to the supporting element along the contour.

The disadvantage of this electric heater is the use of electrically heated carbon resistive coating, which is difficult to apply, it is difficult to bring energy to it, respectively, respectively, problems arise with reliability, performance, overheating at high specific powers of the electric heater.

DISCLOSURE OF USEFUL MODEL

The objective of the claimed utility model is the development of an infrared electric heater having a high reliability of operation with high heating efficiency.

The technical result of the claimed utility model is to increase the service life of the device.

This technical result is achieved due to the fact that the IR electric heater that is embedded in the suspended ceiling, contains a case made of hardened K-glass with low emissivity conductive coating and insulating material that is applied to the conductive coating. At the same time along the edges of the glass surface on the conductive coating applied metallized conductive tires.

The low-emissivity conductive coating (hereinafter the conductive coating) is made structured in the form of a conductive path and / or a structured pattern.

On one edge of the glass, two metallized busbars are applied on the conductive coating, and on the other, an intermediate metallized busbar.

The case of an infrared electric heater is housed in a metal frame-casing made of steel.

BRIEF DESCRIPTION OF THE DRAWINGS

The utility model will be more understandable from the description, which is not restrictive, and is given with reference to the accompanying drawings, which depict:

FIG. 1 - cross section of the declared IR electric heater

FIG. 2 is a top view of the claimed IR electric heater with a conductive coating made structured.

1 - K-glass; 2 - conductive coating; 3 - heat insulating material; 4 - metallized busbar; 5 - metallized intermediate conductor bus; 6 - dividing track; 7 - structured pattern; 8 - electrical leads.

IMPLEMENTATION OF THE USEFUL MODEL

The claimed IR electric heater comprises a housing made of hardened K-glass (1) containing a conductive coating (2) and a heat-insulating material (3) that is applied to the conductive coating (2). In this case, the conductive coating (2) can be made structured - a dividing path (6) and / or a structured pattern (7), and on the edges of the glass surface on the conductive coating (2) metallized current-carrying tires (4) are applied

The separating track (6) is a strip 0.5–1 mm wide along the entire surface of K-glass, formed by the laser removing a specified width of the conductive coating (2). The separating track (6) does not conduct electric current and ensures the separation of the conductive coating into two series-connected sections.

As a heat-insulating material (3), in the claimed IR heater, any heat-insulating materials that can withstand high temperature and low weight are used, for example, pressed mineral wool with paper fraction, gypsum-fiber sheet, mineral wool, etc. 2) using a heat-resistant electrically neutral silicone sealant applied to the conductive coating (2), the specified sealant is also applied to the ends of the K-glass (1). Thus, an IR electric heater body is formed in the form of a single safe panel.

A structured pattern (7) is made on the conductive coating (2), which forms non-conductive participants on the conductive coating (2). The structured pattern (7) is formed due to the removal by the laser of the necessary sections of the conductive coating (2), forming the necessary pattern in the conductive coating (2).

When the conductive coating is structured, on one edge of the glass two conductive metallized tires (4) are applied on the conductive coating (3), and on the other - an intermediate metallized conductor bus (5) that provides a consistent connection of two sections of the conductive coating (2), separated by separating track (6). Electrical leads (8) are soldered to the metallized busbars (4).

Metallized current-carrying tires (4, 5) are applied by gas-dynamic method, which is based on the effect of fixing solid particles on the surface, moving at supersonic speed. The technology of applying tires includes heating compressed air, the formation of a supersonic air flow, the supply of powder material, the acceleration of supersonic air flow and its direction to the surface of the workpiece. Powders of metals (copper, aluminum, zinc), alloys or their mechanical mixtures with abrasive fractions can be used as powder materials for forming current-carrying tires.

This ensures the required reliability of the electrical connection between the conductive coating and conductive tires at high operating temperature.

If necessary, the case of an infrared electric heater can be placed in a frame-casing made of steel. In this case, the casing is fixed with rivets, which are fixed through the holes in the connecting elements of the frame-casing in the heat-insulating material (3).

In the case of using conventional mineral wool as a thermal insulation material (3), the declared IR heater is assembled as follows. K-glass (1) is placed in a frame-casing made of steel, then mineral wool is placed tightly in the space between the ends and the inner wall of the frame-casing, ensuring rigid placement of glass (1) in the frame-casing, and then on the surface of the conductive coating (2 ) and the space between the surface of the conductive coating (2) and the inner wall of the frame-case is tightly packed with mineral wool, after which the surface of the mineral wool is covered with a metal cover, which is fastened with fastening elements to the frame-frame su.

In addition, on the front surface (glass surface that does not contain a conductive coating) of the infrared electric heater glass, a baked coating of the desired color, in most cases, white, can be applied.

Also on the front surface of the glass (1) can be applied silicone heat-resistant coating, which allows to give the product a coarse, rough matte tint and at the same time provide additional protection in cases of glass breakage.

On the front surface of the glass (1) IR electric heater using laser engraving by removing the coating on the front surface of the IR electric heater, various signs and logos can be formed. Thus, for example, with the help of a miniature neon indicator and the corresponding image, it is possible to easily form an on sign and the like, especially since the supply leads are in close proximity to each other.

Declared IR heater works as follows.

Through electrical leads (8) and metallized current-carrying buses (4), AC or DC electric power is supplied to the conductive coating (2) of the IR electric heater. With the passage of electric current through the conductive coating (2), it releases thermal energy, heating the K-glass (1) across its surface to a temperature of not more than 170 ° C, while the glass (1), as a material with a high coefficient Radiation effectively emits infrared radiation through the front surface of the glass (1) IR electric heater, resulting in heating, for example, the room. In addition, K-glass (1) emits IR radiation in the direction of the insulating material (3), which reflects IR radiation in the direction of the front surface of the glass (1) IR electric heater, while the reflected IR radiation is also emitted through the front surface of the glass (1) IR electric heater.

The use of tempered K-glass with a conductive coating compared to a resistive carbon coating can improve reliability, since the conductive K-glass coating provides a uniform electrical surface resistance (no overheating), is mechanically durable, with the ability to provide different power of the IR electric heater due to remove the necessary sections of conductive coating

The execution on the conductive coating of the separating track or structured pattern provides for heating the glass to a temperature below 170 ⁰ С (corresponds to the required specific power of the IR electric heater), which ensures reliability due to the absence of overheating of the IR electric heater, which may cause the heated room to ignite building. When the width of the dividing track is less than the declared interval, there is a breakdown in the dividing path, which leads to overheating of the infrared heater, and increasing the width of the more declared is impractical.

The implementation of a structured pattern together with a dividing path on a conductive coating can further reduce the temperature of heating the glass.

The utility model was disclosed above with reference to a specific version of its implementation. For specialists may be obvious and other embodiments of the utility model, not changing its essence, as it is disclosed in the present description. Accordingly, the utility model should be considered limited in scope only by the following claims.

Claims (1)

An infrared electric heater embedded in a suspended ceiling made of tempered glass with a low emissivity conductive coating and a heat insulating material applied to the conductive coating, while current-carrying tires are applied to the edges of the glass surface and the low emission conductive coating is structured as a split.

Images