DE1089092B - Surface-shaped radiation furnace, preferably designed as a wall radiator, consisting of an insulated heating conductor, which emits its heat onto a beam surface, preferably arranged in a frame, and to which a reflector is assigned - Google Patents

Description

GERMAN

The invention relates to a planar radiation furnace, which is preferably used for fastening on the wall, especially in the bathroom. Known embodiments of flat-shaped Radiant ovens generally consist of a bare or insulated heating conductor, which gives off its heat on a radiant surface and behind the Another reflector is arranged, the radiant surface is made in order to distribute the heat as evenly as possible to get as big as possible and surrounds it with a special look for the sake of it Frame. However, the known planar radiant ovens generally have the disadvantage that they are only designed for relatively low temperatures, therefore a relatively high one, in this case give off unwanted part of convection heat. Furthermore, they often have an undesirable size Depth expansion, which gives an unsightly sight.

The present invention has now set itself the task of providing a planar radiation furnace create, whose beam surface temperatures come to over 180 ° C and therefore a relatively low one Has proportion of convection.

According to the invention, the object set is preferably designed as a wall radiator sheet-like radiant furnace, which consists of an insulated heating conductor, which draws its heat emits a beam surface which is preferably arranged in a frame and is assigned a reflector is solved in that the 'radiant surface consists mainly of enamelled sheet metal, the insulated heating conductor arranged directly behind it with good thermal contact and through the reflector against the radiant surface is held. The heating conductor is in recesses, for example beads, in the radiant surface and / or in the Reflector stored.

The further features of the invention and details of the advantages achieved thereby result from the following description of an embodiment shown in the drawing.

1 shows the planar radiation furnace in a view from the front;

FIG. 2 shows a side view of a section through the housing of the radiant furnace from FIG. 1;

Fig. 3 shows the placement of the heating conductor between. see beam surface and reflector;

Fig. 4 shows schematically the circuit of the radiant furnace.

In the figures, 1 is the beam area, with 2 the heating conductor surrounded by the insulation 3, with 4 the reflector and with 5 the one surrounding the radiant surface Labeled frame.

The radiant surface 1 consists of a predominantly enamelled surface-shaped radiant furnace,
preferably as a wall spotlight

educated,

consisting of an insulated heating conductor, which distributes its heat to a,
preferably in a frame
arranged jet area emits
and to which a reflector is assigned

Applicant:
Siemens-Electrogeräte Aktiengesellschaft,

Berlin and Munich,
Munich 2, Oskar-von-Miller-Ring 18

Dipl.-Ing. Hermann Gerds, Traunstein (Obb.),
has been named as the inventor

tem sheet, which receives particularly good radiation properties through the enamelling. The heating conductor 2 is advantageously surrounded with insulating beads 3 and arranged with good thermal contact immediately behind the radiant surface X and is through the reflector 4 held against the jet surface 1. The heating conductor 2 lies in depressions, for example in beads, which are provided in the beam surface 1 and / or in the reflector 4. The beads are in the beam surface 1 designed so that they have a large contact area with the heating conductor 2. the Corrugations in the reflector "on the other hand, are designed so that as far as possible only linear contact between Heat conductor 2 and reflector 4 takes place. The opposing corrugations essentially run horizontally, whereby the heating conductor is also guided horizontally over its greatest length, which is a at vertical guidance possible collapse of the heating conductor is avoided. At the end of each horizontally running bead, the heating conductor must of course be deflected, which is the case with the one shown Embodiment in correspondingly deeper pronounced beads, which are only provided in the reflector, he follows. The heating conductors are laid bifilar. Of course, simple laying is also possible. The beam surface 1 and the reflector 4 consist of

009 607/317

the same material or one with the same coefficient of thermal expansion. This avoids the large thermal expansion occurring at the high temperatures from bending or warping of the radiant furnace. The beam surface 1 can consist of enamelled aluminum, in which case the reflector is made of polished aluminum. In the illustrated embodiment, there is the beam surface 1 made of enamelled sheet steel and the reflector made of an aluminum-plated sheet steel, what the The advantage is that on the one hand the same coefficient of thermal expansion is available, on the other hand also the good reflective properties of aluminum can be used.

The radiation surface 1 and the frame 5 are formed from one piece in the everting process, then cut apart, and the radiation surface 1 is inserted in the frame 5 in opposite directions.

This configuration brings a large savings in production on the one hand, and on the other hand can Radiant surface 1 and the frame 5 shaped in the simplest way on the opposite edges be that the thermal expansion of the radiant surface can compensate without bending the radiant surface. In the event that the radiant furnace according to the invention for otherwise unheated rooms, for example Toilets, to be used, a frost protection switch 7 can be installed, which at a certain Temperature turns on a heating switch 8 and only after reaching a certain higher room temperature turns off again. Because the frost protection switch 7 can be housed within the radiant furnace should, but cannot be completely protected against the effects of heat from the heatsealing band, there is a risk that the frost protection switch 7 will switch off again before due to heat transfer the room to be heated has a certain temperature that is higher than freezing point.

In order to counteract this disadvantage, the frost protection switch 7 is arranged in the lower part of the frame and the heating conductor 8 switched by it is provided at the opposite upper end of the radiant surface 1. This ensures that the room receives sufficient heat before the heating conductor 8 has a disruptive effect on the frost protection switch 7. Around the wall on which the radiant furnace is mounted is to protect against the harmful effects of heat, can be placed behind the reflector with the interposition one or more shield plates can be arranged in an air gap that enables convection. in the Frames are then provided above and below corresponding convection openings. Are expedient Provide protective grille or protective bars 6 to prevent contact with the hot jet surface.

Claims (12)

55 claims: 1. Planar radiation furnace, preferably designed as a wall radiator, consisting of a insulated heating conductor, which transfers its heat to a radiant surface, preferably arranged in a frame emits and to which a reflector is assigned, characterized in that the beam surface (1) from mainly enamelled sheet metal, the insulated heating conductor (2) with good thermal contact directly arranged behind it and held against the beam surface by the reflector (4). 2. Radiation furnace according to claim 1, characterized in that the heating conductor (2) in depressions, for example, beads, is mounted in the beam surface (1) and / or in the reflector (4). 3. Radiation furnace according to claim 1 and 2, characterized in that the heating conductor (2) in on the same height opposite beads of the beam surface (1) and the reflector (4) in his for the most part horizontally and deflected alone in correspondingly deeper beads of the reflector (4) is. 4. Radiation furnace according to claim 1 to 3, characterized by a bifilar installation of the Heating conductor (2). 5. Radiation furnace according to claim 1 to 4, characterized by a contact between the heating conductor (2) and reflector (4) that is as linear as possible. 6. Radiation furnace according to claim 1, characterized in that the beam surface (1) and the reflector (4) consist of the same material or material with the same coefficient of thermal expansion. 7. Radiation furnace according to claim 1 and 6, characterized in that the beam surface (1) from preferably enamelled aluminum, the reflector (4) consists of polished aluminum. 8. Radiation furnace according to claim 1 and 6, characterized in that the beam surface (1) from preferably enamelled sheet steel, the reflector (4) consists of aluminum-plated sheet steel. 9. Radiation furnace according to claim 1, characterized in that the beam surface (1) and the Frame (5) formed from one piece in everting and then separated and the Beam surface (1) is inserted in opposite directions in the frame (5). 10. Radiation furnace according to claim 1, characterized by a frost protection switch (7), which is arranged in the lower part of the frame and the one in the upper part of the jet surface (1) provided heating coil is assigned. 11. Radiation furnace according to claim 1, characterized in that behind the reflector (4), below Interposition of an air gap that enables convection, one or more shield plates arranged and provided in or on the frame convection openings. 12. Radiation furnace according to claim 1, characterized in that protective grille in front of the beam surface or rods (6) are provided to avoid contact with the beam surface (1). 1 sheet of drawings © 009 607/317 9.