RU147101U1 - INFRARED HEATER - Google Patents

Abstract

1. An infrared heater, comprising a housing with infrared radiation elements fixed therein, made in the form of at least two rectangular radiating plates, fastened together by a curved rail and having a wavy bottom surface, electric heating elements - heating elements. mounted in holders located in the middle part of the radiating plates, a reflector made of a flexible sheet of aluminum alloy with a mirror surface, and two side end caps fastened to the housing along the longitudinal edges of the plates on the back of the plate, the grooves that are fasteners and form with the holder a single design with each radiating plate, characterized in that each of the radiating plates is made of a cylindrical shape with horizontally longitudinal edges; at the same time, a ceramic coating is applied to the outer surface of the study plates; the reflector is made in the form of interconnected two sheets; wherein one sheet is made of hard sheet metal; while another sheet is made of flexible sheet metal with a mirror surface, which is wrapped with a heat-insulating material; while there are partitions for fixing the radiating plates; there are inserts; at the same time, longitudinal grooves for fixing the inner inserts are made on the radiating plate from the back side; grooves for mounting the reflector; while on the radiating plate on the sides there are two longitudinal grooves for attachment to the housing and connection with each other. 2. An infrared heater according to claim 1, characterized in that a thermostat is installed on the heater. 3. Infrared �

Description

The utility model relates to electric heating systems for heating premises of residential or other buildings using infrared radiation.

Known electric radiant heater, comprising a housing with abutment end caps and a central support, made in the form of a plate of variable profile, a heat-emitting element with parallel grooves on its outer surface, a heat-insulating element and a tubular heater (see, for example, certificate for utility model RU 12314 U1, 12/16/1999).

This heater allows you to intensify the heating of the premises, however, design features of the heater have a significant impact on the heating efficiency.

Known infrared heater PION Ceramics, consisting of a housing; Peony heater, suspension element; TENA of low temperature; ceramic radiating plate; ceramic heat insulator; power indicator lamps; clamping plate. PION Ceramic infrared heater gives a larger (120 °). than usual angle of dispersion of thermal radiation, thanks to a curved (semi-cylindrical) ceramic plate. The body of the device is made of aluminum alloy and coated with powder paint (manufactured by Fitting Atelier LLC. Internet: http://www.2294229.ru/kontakty.html).

The disadvantages of the known technical solutions are the complexity of the design and manufacturing and assembly technologies, and insufficiently efficient heating.

The closest to the invention in terms of technical nature and the achieved result is an electric heater, (RF patent No. 50358 U1, IPC ⁷ H05B 3/40. Op. 27.12.2005), comprising a housing with infrared elements fixed in it, in the middle part of which in the holder an electric heating element is installed - a heater, a reflector made of a flexible sheet of aluminum alloy with a mirror surface, characterized in that the infrared elements are made in the form of at least two rectangular radiating plates, with replicated together on the back with a curved rail and having a wavy lower surface with perpendicular protrusions, along the longitudinal edges of the plates on the back there are protrusions with grooves that are fasteners and form a single structure with the holder with each radiating plate and made of the same material with it, housing consists of an upper convex cylindrical surface with perforation along the end edges and with longitudinal edges bent outward, bonded to the radiating plates by a rail with agnutymi inside longitudinal edges, and two lateral end caps fastened to the housing, wherein on the upper convex cylindrical surface of the housing, two hanger secured.

A disadvantage of the known device is the complexity of the design and manufacturing and assembly technology, and insufficiently efficient heating.

The problem, which the real utility model is aimed at, is to develop a heater of simple design, simple technology and assembly, with a high coefficient of performance (COP).

The technical result from the application of the utility model is to increase the operational characteristics of the heater while increasing energy saving in the process of its use due to the design of the radiating element and the design of a flat-shaped reflector with a mirror surface, formed by connecting a rigid sheet metal and a flexible sheet metal with a mirror surface that is wrapped with a heat-insulating material.

This is achieved due to the fact that in an infrared heater containing a housing with infrared radiation elements fixed in it, made in the form of at least two rectangular radiating plates, fastened together by a curved rail and having a wave-like lower surface, electric heating elements - TEN, installed in holders located in the middle of the radiating plates, a reflector made of a flexible sheet of aluminum alloy with a mirror surface, two side end caps, sk replicated with the body, and grooves along the longitudinal edges of the plates on the back side, which are fasteners and form a single structure with a holder with each radiating plate, according to a utility model, each of the radiating plates is cylindrical in shape with horizontally longitudinal edges; at the same time, a ceramic coating is applied to the outer surface of the study plates; the reflector is made in the form of interconnected two sheets; wherein one sheet is made of hard sheet metal; while another sheet is made of flexible sheet metal with a mirror surface, which is wrapped with a heat-insulating material; while there are partitions for fixing the radiating plates; there are inserts; at the same time, longitudinal grooves for fixing the inner inserts are made on the radiating plate from the back side; grooves for mounting the reflector; however, on the radiating plate on the sides there are two longitudinal grooves for attachment to the housing and connection with each other. In this case, a curved rail for connecting two radiating plates is made of bent sheet metal. In this case, the body is made of bent sheet metal. At the same time, a thermal insulation material made of a material with low thermal conductivity is located in the reflector. In this case, the side covers are made of polymer material. At the same time, technological holes are made on the surface of the heater for outputting wires and brackets are provided for fastening the heater to a hook connection to the ceiling.

The utility model is illustrated by drawings.

In FIG. 1 - infrared heater, general view.

In FIG. 2 - the same, rear view;

In FIG. 3 is the same, section A-A in FIG. 2.

In FIG. 4 is the same, section B-B in FIG. 2.

In FIG. 5 is the same, section C-C in FIG. 2.

In FIG. 6 - the same, a fragment of the radiating plate.

In FIG. 7 - the same, a fragment of the radiating plate.

Positions indicate: radiating plate (1); teni (2); holder (3), figured rail (4); side groove (5); temperature controller (6); extreme longitudinal groove (7); reflector (8); partition (9); terminal block (10); longitudinal groove (11); thermal insulation material (12); flexible mirror aluminum sheet (13); case (14); ceramic coating (15); inserts (16); end cap (17); wavy surface (18) of the radiating plate (1).

The utility model consists of radiating plates (1), with horizontally longitudinal edges, the central part has a cylindrical shape, plates made of extruded aluminum alloy. Heating element - TEN (2). A reflector (8) of a flat shape with a mirror surface is formed by connecting a rigid sheet metal and a flexible sheet metal with a mirror surface (13). Partitions (9) for fixing the radiating plates (1) are made of sheet metal. The figured rail (4) for connecting two radiating plates (1) is made of bent sheet metal. Thermal insulation material (12) with a low coefficient of thermal conductivity. The housing (14) is made of bent sheet metal. Insert (16) made of bent sheet metal. Side covers (17) are made of polymer material. Two side grooves (5) for fixing the inner inserts (16); for mounting the reflector (8), the groove (7); for connection with another radiating plate, the central longitudinal groove (11) on the back in the form of a ring is the holder of the heater (2), two longitudinal grooves (7) in the form of open rings serve as the basis for a threaded connection with partitions, and the remaining longitudinal groove ( 7) is used to mount the reflector. A ceramic coating (15) containing oxides of aluminum and alkali metals is applied to the study plate (1).

The device operates as follows.

On the radiating plate (1), on the back there are longitudinal grooves: for attaching the partitions (9), two longitudinal grooves (11); for mounting the reflector (8), the groove (7). On the radiating plate (1) on the sides there are two longitudinal grooves (5) for attachment to the housing and connection with each other. On the front side, the radiating plate (1) has a wavy surface (18). Tens (2) are inserted into the radiating plates (1) into the holder (3), then the radiating plates (1) are connected to each other by a figured rail (4), which is inserted into one of the side grooves (5) of the radiating plate (1). A thermoregulator (6) is mounted on the heating element (2). Then, in the extreme rear longitudinal grooves (7), a reflector (8) is inserted with the mirror side inward. A terminal block (10) is mounted on one of the partitions (9). Next, the radiating plates (1) are fixed on a threaded connection formed by longitudinal grooves (11) on the back side, from both ends by partitions (9). Heat-insulating material (12) wrapped in a flexible mirror aluminum sheet (13) is laid on the reflector (8) from the matte side. The housing (14) is inserted into the groove (5) of the resulting structure, and is fixed to an integral rivet connection, or to a threaded connection. Then, inserts (16) are inserted into the housing (14). The resulting design on both end faces is closed with end caps (17) made of a polymer material.

The assembled finished infrared heater is installed, in a convenient place for heating, in the working hanging position, using two suspensions for this, which are fixed by fastening elements to a supporting horizontal surface, for example, to the ceiling (not shown).

When connected to the mains, heating elements (TEN) (2) heat up the radiating plates (1), which begin to emit infrared rays into the room. Moreover, the wavy bottom surface (18) of the plates (1) allows to increase the radiating heat flux, and the implementation of the cylindrical plates allows to increase the heating sector, thereby increasing the heating efficiency.

Infrared rays heat the room according to the principle of sunlight, they pass through the air almost unhindered, but heat the surface of objects in their area of action: walls, floors, furniture, etc. By choosing the required number of electric heaters of the appropriate power, they achieve a comfortable temperature in the room.

Maintenance of electric heaters does not require special training of users and consists in keeping the electric heater clean and safe.

The inventive electric heater used for primary or secondary heating of premises is made of environmentally friendly materials, fireproof, resistant to mechanical damage, does not contribute to the accumulation of household dust. Its design is easy to manufacture and assemble, provides simplicity and ease of use.

Samples of the inventive device are made and tested in operation. During manufacture and operation, their advantages were confirmed.

The use of such a heater design allows the fulfillment of the task of the invention to increase the efficiency of the heater by optimizing the performance of the heat-emitting element and the heater body:

1. reduce energy consumption by increasing the dissipating ability (the direction of radiation is not only in one direction, which allows you to heat a uniformly larger volume).

2. increase the emissivity, increase the heating sector due to the cylindrical shape of the radiating plate.

3. increase the wear resistance due to ceramic coating.

5. The use of a flat-shaped reflector with a mirror surface in the design, formed by connecting a rigid sheet metal and a flexible sheet metal with a mirror surface and a heat-insulating material, can increase the heat resistance.

Claims (9)

1. An infrared heater, comprising a housing with infrared radiation elements fixed therein, made in the form of at least two rectangular radiating plates, fastened together by a curved rail and having a wavy bottom surface, electric heating elements - heating elements. mounted in holders located in the middle part of the radiating plates, a reflector made of a flexible sheet of aluminum alloy with a mirror surface, and two side end caps fastened to the housing along the longitudinal edges of the plates on the back of the plate, the grooves that are fasteners and form with the holder a single design with each radiating plate, characterized in that each of the radiating plates is made of a cylindrical shape with horizontally longitudinal edges; at the same time, a ceramic coating is applied to the outer surface of the study plates; the reflector is made in the form of interconnected two sheets; wherein one sheet is made of hard sheet metal; while another sheet is made of flexible sheet metal with a mirror surface, which is wrapped with a heat-insulating material; while there are partitions for fixing the radiating plates; there are inserts; at the same time, longitudinal grooves for fixing the inner inserts are made on the radiating plate from the back side; grooves for mounting the reflector; however, on the radiating plate on the sides there are two longitudinal grooves for attachment to the housing and connection with each other. 2. An infrared heater according to claim 1, characterized in that a temperature regulator is installed on the heater. 3. The infrared heater according to claim 1, characterized in that a terminal block is installed on one of the partitions. 4. The infrared heater according to claim 1, characterized in that the figured rail for connecting two radiating plates is made of bent sheet metal. 5. The infrared heater according to claim 1, characterized in that the housing is made of bent sheet metal. 6. The infrared heater according to claim 1, characterized in that a heat-insulating material made of a material with low thermal conductivity is located in the reflector. 7. The infrared heater according to claim 1, characterized in that the side covers are made of polymer material. 8. The infrared heater according to claim 1, characterized in that the ceramic coating contains oxides of aluminum and alkali metals. 9. The infrared heater according to claim 1, characterized in that technological holes are made on the surface of the heater for outputting wires, brackets are provided for mounting the heater on a hook connection to the ceiling.

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