DE2919647A1 - Radiator heating workpieces and materials - has thermally insulating layer attached to rear by foaming - Google Patents

Abstract

The radiator has an insulating layer (2) on its rear made of material of poor thermal conductivity. The insulating layer is fixed to the radiator (1) by means of foaming. The radiator has projections (5) with undercuts to retain the insulating layer. Alternatively, the insulating layer is bonded to the radiator. The insulating layer may be fixed removably to the radiator by anchorages, e.g. bolts. The radiator has a base with holes or slots. The insulating layer has openings. The insulating layer is only in contact with the surface of the radiator locally. The supply (4) is attached to the electric heating element (3).

Description

1 'A h L E R

The invention relates to a radiator, as it is individually or in groups summarized for the heating of various objects and materials is used. The radiator is preferably heated electrically, it gives the heat in the form of radiation to the object Dz. the material to which he is arranged at a certain distance.

The DT-5N1 72 39 040 shows such a radiator.

If such radiators are used, for example, for heating thermoplastic If plastic foils or plates are used, individual radiators are used entire heater in a grid-like manner according to the required size. A DT-AS 1 604 749 shows such a structure for a heater.

The surface temperature of ceramic infrared emitters can be up to 6000 C. This means that the actual radiator body all around it Assumes temperature and also radiates heat to the rear where it is not used can be.

It is known to arrange a reflector behind the radiator, which reflects part of this heat radiated backwards. This hits then back to the back of the radiator, as these radiators are usually close together stand. This radiation cannot therefore directly heat the plastic can be used.

Despite the reflection, the reflector plate heats up due to the thermal radiation that is passed on to the wiring space next to it by heating and circulating the air behind the reflector.

Another heat transfer from the radiator to the reflector therefore takes place instead, because the base of the spotlight is anchored in the reflector. This finds heat conduction takes place because the base is made of the same or a similar material like the radiator body, mostly made of ceramic or porcelain. These materials guide quite good.

A further loss of heat takes place because the air heats behind the radiators and around the radiators and rises to the top (nonvection). This also causes the reflector plate to heat up.

The consequence of the strong warming of the reflector plate is a high loss of energy the entire heating and thus a poor efficiency. In addition, the wiring space very warm behind the reflector, which is a special wana-proof insulation of the wires requires and which exposes the power supply rails to increased corrosion are.

The object of the invention is to design the radiator so that the Dissipation of heat to the rear of the reflector or

to a retaining plate is largely prevented, namely with respect to it Heat radiation, heat conduction and convection. This should be an energy saving can be achieved, in addition, a lowering of the temperature in the wiring space should be achieved will.

This is achieved according to the invention in that the radiator is on the back is provided with an insulating layer.

This can be directly connected to the radiator, be it through Gluing an insulating material or z.3. by foaming a material with the surface of the emitter is liable. But it is also possible to do this Insulation layer can be anchored detachably with drn spotlights, creating even more Possibilities for the design of the insulating layer result, as will be described below.

Particularly advantageous designs of the insulation layer and the Radiators are described in more detail with reference to the schematic drawings.

It shows: FIG. 1 a radiator with a foamed insulation layer.

2 shows a radiator with a glued-on insulation layer.

3 shows a radiator with a detachably anchored insulation layer.

4 shows a radiator with an insulation layer, the side wall of which is specifically is designed.

5 shows a plan view of a radiator according to FIG. 4, FIG. 1 shows a radiator 1 with a permanently attached insulating layer 2, which is e.g. a material consisting of a mixture of a silicate and aluminum phosphate, is applied. : With the help of a molding box this is possible without any problems. The radiator 1 usually consists of ceramic or porcelain, in it are heating coils 3 embedded. Power is supplied via lines 4.

For better anchoring of the insulating layer 2, projections are preferably grounded 5 molded with undercuts on the radiator 1.

In Fig. 2, a radiator 6 is shown with an insulating layer 7, the latter being firmly connected to the radiator 6, e.g. by gluing. So it is here possible, the insulating layer 7 with a corresponding molding tool rationally to manufacture and then to connect to the radiator 6.

The same is possible with the radiator according to FIG. 3, the insulating layer 8 detachable by anchoring with the radiator 9 connected is. For this purpose, a base 10 is formed on the radiator 9, for example, which at the same time the cable feed is used.

The insulating layer 8 has a corresponding depression.

Via transverse stanchions or grooves in the base 10 and in the insulating layer 8 bolts 11 can be pushed through.

It is possible in this way if the radiator is damaged 9 or insulating layer 8 to use the other part again. There is also a wait in this case not necessary until an adhesive has set.

If the insulating layer 7,8 is made separately and then with the emitter 6,9 is connected, it is possible and advantageous to have chambers 12, 13 in the insulating layer 7,8 to be molded so that there is no full contact between radiator G, 9 and insulating layer 7.3 exists. This improves the insulating effect.

It's also beneficial on top for the same reason to form the insulating layer 2,7,8 chambers 14,15,16, so that no full system between the insulating layer 2,7,8 and the support plate to which they are attached.

A special Formation of the invention vorgescnlagen in the insulating layers 2,7,8 fastening element to mold or request from it. It can be inserts 17 with thread, be bolts 13 or projections 19, which then spring-loaded Xilammern Carry out to be placed through the Halteblectl.

A direct ... prevented.

If radiators are assembled like a grid to form heaters, there is a certain gap between the radiators, which depends on the distance between the radiators. If the gap becomes too large, an air flow takes place here, the warm air from the hot radiator surface leads to the retaining plate. To avoid this, it is suggested that either to make the insulating layer larger than the beam width, so that consequently only a narrow gap is created. But it is also possible for the wall of the insulating layer so that no air flow occurs, in which e.g. another element is introduced.

In Fig. 4 it is shown how by paragraphs 20, 21 a certain overlap the insulating layer 22 is reached. The paragraphs 20 are on two pages, which are at right angles to each other, provided, the paragraphs 21, however, on the other two sides (see Fig. 5). If one keeps the overlap a smaller than the dimension S, emitters with insulating layer can be exchanged individually in a total stimulation by moving them to the side after loosening and before removing them.

Another solution would be to form a groove 23 in the side wall, so that a thin sheet 24 can be inserted between the individual radiators. Any radiator spacing could be bridged with appropriate spacer plates no adaptation of the radiator or the insulating layer is necessary.

The lines 4 are passed through the insulating layers 2, 7, C. If the insulating layers are manufactured separately and not foamed, then appropriate Holes provided therein.

After the cables 4 have passed through, these are preferably covered with an insulating material filled up, for example glass wool, so that no air circulation takes place.

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Claims (14)

P A T E N T A N S P R Ü C H E 1. Radiator for heating objects or materials of any kind, with substantially flat, rectangular or square shape, characterized in that there is an insulating layer on its rear side (2,7,8,20) is applied from material that has poor thermal conductivity. 2. Radiator according to claim 1, characterized in that the insulating layer (2.7) is inextricably linked to the radiator (1.6). 3. Radiator according to claim 2, characterized in that the insulating layer (2) is attached to the radiator (1) by foaming. 4. Radiator according to claim 3, characterized in that the radiator (1) has projections (5) with undercuts for holding the insulating layer (2) in place. 5. Radiator according to claim 2, characterized in that the insulating layer (7) is attached by gluing to the radiator (6). 6. Radiator according to claim 1, characterized in that the insulating layer (3) Detachably connected to the radiator (3) by an anchor, e.g. a bolt (11) is, for which the radiator (9) has a base (10) with holes or grooves, the insulating layer (8) has breakthroughs. 7. Radiator according to claim 5 or 6, characterized in that the Insulating layer (7,3) only locally in contact with the surface of the radiator (5,3) is what is achieved through chambers (12, 13). 3. Radiator according to one of claims 1 - 7, characterized in that that the insulating layer (2,7,3) chambers on the side opposite the radiator (14, 15, 16), so that the insulating layer (2,7,8) when attaching to a flat retaining plate only rests locally. 9. Radiator according to one of claims 1 - 8, characterized in that that in the insulating layer (2,7,8) fastening elements (17,18) are embedded, which are used to attach the unit emitter - insulating layer to retaining plates. 10. Radiator according to one of claims 1 - 8, characterized in that that the insulating layer has projections (19) for leading through a retaining plate, to which clips or halves can be attached for fastening. 11. Radiator according to one of claims 1 - 10, characterized in that that the side wall of the insulating layer (2,7,8) recesses (23) for the introduction of Has metal sheets (24) which provide an air flow between lined up radiators (1) prevent. 12. Radiator according to one of claims 1 - 10, characterized in that that the insulating layer (22) has projections (20, 21) on the side wall, wherein these protrude on two sides standing at right angles to one another, on the other stand back on both sides. 13. Radiator according to claim 12, characterized in that the overlap (a) is smaller than the free space (b) between the projections (20, 21) and the Insulating layer (22) 14. Radiator according to one of claims 4-13 characterized in that the openings in the Isolierscllichten to carry out the cables (4) are filled with an insulating material.