DE2104677A1 - Electric heater - Google Patents

Description

Electric heater The invention relates to an electric heater Heating device, with a heating plate on which a linearly laid heating conductor is upset.

In a known heating device designed as a hotplate In this way, the heating conductor is embedded in an insulating compound. To achieve a good Heat transfer from the heating conductor to the heating plate is the surface of the side of the Heating plate, on which the heating conductor is attached, enlarged by heat conducting ribs, which protrude into the 1 solid measure between the heating conductors. Such a heater is expensive to manufacture and has a disadvantageously large heat capacity.

The invention is based on the object of a heating device create, which are easy to manufacture due to a good heat transfer from Distinguishes the heating conductor on the heating plate.

According to the invention, this object is achieved in an electrical heating device solved with linearly laid heating conductor in that the heating conductor in a its lines following graphite mass is embedded. The graphite mass is an excellent heat conductor, so that the heat capacity of the heating device according to the invention is very low. The production of the heating device is particularly simple. the Graphite mass and the heating conductor make a composite radiator dard in general the resistance wires used for the heating conductor have a positive temperature coefficient on, which adversely affect the thermal control behavior of the heating device can. By using the composite radiator there are possibilities that Temperature resistance coefficients served at least in a certain temperature range to neutralize by the positive temperature resistance coefficient of the Resistance wire offset by the negative temperature resistance coefficient of the graphite mass The ohmic resistance of the composite heater is determined by the conductivity of the Heat conductor determined. As a rule, this is 1.0-0.8 Siemens; the conductivity of graphite, on the other hand, is 0.3.10-2 to 0.25.10 Siemens, so that with regard to the conductivity of the composite radiator of the heating conductor is dominant.

For fastening the graphite mass with the heating conductor to the heating plate there are several possibilities.

First there is the possibility of using the graphite mass with the heating conductor to be pressed by a counter plate on the heating plate, the counter plate and the heating plate are preferably connected to one another at their edges.

For connecting the graphite mass with an inorganic heating plate It is an insulating material such as glass, glass ceramic, fused quartz or the like expedient, the graphite mass phosphorous constituents, æ e z.3. Phosphoric acid, nonoaluminum phosphate or to add magnesium dihydrogen phosphate. The phosphorous ingredients go with the inorganic material of the heating plate one by the acidity of the phosphoric Chemical bonding caused by debris.

In this way, the graphite mass surrounding the heating conductor is also included the heating plate intimately and inextricably connected after appropriate curing.

The heating conductor embedded in the graphite mass can in principle also on a metallic heating plate made of sheet steel or the like be applied. In this case it is necessary to face the heating conductor to electrically isolate the graphite compound or the graphite compound from the heating plate. The insulation is to be dimensioned in such a way that the requirements of the dielectric strength This is taken into account and at the same time the heat transfer from the heating conductor to the heating plate is sufficient. To produce the insulation, it has proven to be advantageous to glimmer the heat conductor or with a coating of magnesium oxide, To provide corundum or the like, the glass-forming binder, e.g. on phosphate, Borate or silica based are added. The insulation can also be made of glass or Be formed glass ceramic.

It is advantageous if the graphite mass is called flake graphite contains. This type of graphite shows a very low level of graphite in relation to its layer level thermal expansion coefficient. Especially when using the graphite compound on a heating plate made of inorganic material, which also has a has very low thermal expansion coefficients, are also at large temperature differences between the heating plate and the graphite mass significant thermal stresses to be expected. It is also advantageous to use the heating conductor to absorb differences in thermal expansion compared to the heating plate by means of suitable Adapt shape, e.g. helix or corrugation. In this regard it is the formation of the heating conductor as a thin layer is also advantageous.

In the case of a metallic heating plate, granular graphite is advantageous or fine graphite with ceramic material of great thermal expansion such as quartz sand or magnesia is used for the thermal conductivity material.

Based on the drawing, embodiments of the refinement in schematic representation described.

Figures 1 to 3 each show a section in cross section a heating device designed as an electric hotplate with different Arrangements of graphite mass and heating conductors, with a heating plate made of inorganic Material.

FIG. 4 shows the top view of the arrangement according to FIG. 3.

Figures 5 to 8 each show a section in cross section a heating device designed as an electric perforated plate with different Arrangements of graphite mass and heating conductors, with a metal heating plate.

According to FIG. 1, a strip-shaped composite heating element is attached to the heating plate 1 4 applied, which consists of a graphite mass 3 and an embedded in the graphite mass, coiled heating wire 2 consists. The heating plate 1 is made of an inorganic material manufactured.

The turns of the composite radiator shown in cross section 4 are with a sufficient for the electrical insulation of the windings against each other Spaced. To produce the composite heater 4 is advantageous Prepare the template according to the desired shape of the composite radiator Has grooves. In these grooves the heating wire 2 and those with phosphorous components applied graphite mass 3 inserted. The template filled in this way is attached to the heating plate 1 created. After pre-hardening, the template is removed and the graphite mass 3 completely cured, this with the heating plate 1 in an undetachable and permanent connection occurs.

In an analogous manner, the heating devices according to FIGS. 2 and 3 manufactured. Instead of the coiled heating wire 2, a heating conductor can also be used Corrugated tape 5 (Fig. 2) or a flat tape 6 (Fig. 3) can be used, which are also shown in a graphite mass 7 and 8 are embedded. The current flow goes with the designs according to FIGS. 1 and 3 vertically through the plane of the drawing and in the design according to Fig. 2 parallel to the plane of the drawing.

Instead of the heating wire or tape, it is also possible to use known methods such as screen printing, spraying, chemical or galvanic application, a conductive one Metal band 6 be applied in the graphite mass 8. To absorb differences in thermal expansion it is useful to lay the metal strip 6 in a meander shape. In itself are through Such manufacturing processes only thin metal layers that are thermally weak are resilient, applicable. By embedding the metal strip 6 in the graphite mass however, they are thermal loads, such as those for hotplates, irons and the like are common, easily accessible.

Figures 5 to 8 show heating devices designed as a hotplate with a heating plate 11 made of sheet steel. A wire coil 12 is used as the heating conductor. To isolate it from the graphite mass 13, the heating conductor is provided with an insulating coating 14 provided (Figs. 5 and 7). The graphite mass can also be in the form of a heating conductor 12 covering layer 15 be formed (Figure 6). With one opposite the graphite mass 13 non-insulated heating conductor 12 is the graphite mass 13 opposite the heating plate 11 separated by an insulating layer 16 (Figure 7).

It is advantageous to use the insulated or non-insulated wire helix 12 to be filled in the prefabrication with doughy graphite mass: and until the gel state to harden. The wire coil 12 can be given the final shape in this case which it is then applied to the heating plate 11. When an electrical shunt between the wire helix 12 and the graphite mass 13 located in its interior should be avoided, the wire helix 12 is previously also on its inside the insulation 14 to be provided (Fig. 5 and 6).

The insulation 14 is produced, for example, by mica coating with silicone bond, through magnesium oxide, corundum or the like, that with glass-forming Binder is bound or by glass, or glass ceramic. If the graphite mass 13 acidic binders are added, the heating plate 11 made of metal is useful against the attack of the acidic binder by nickel-plating or basic enamelling protection.

11 claims 7 figures

Claims (11)

Claims 1. Electrical heating device, with a heating plate, on which a linearly laid heating conductor is applied, d a d u r c h g e it is not indicated that the heating conductor follows one of its lines Graphite mass (3,7,8,13,15) is embedded. 2. Heating device according to claim 1, characterized in that the Graphite mass (3,7,8,13,15) phosphorous components are added. 3. Heating device according to claim 1 or 2, characterized in that that the graphite mass (-13.15) added quartz sand, magnesium oxide or the like is. 4. Heating device according to claim 1 or 2, characterized in that that the graphite mass (3,7,8) contains flake graphite. 5. Heating device according to one of claims 1 to 4, characterized in that that the heating conductor is provided with insulation (14). 6. Heating device according to claim 5, characterized in that the Insulation (14) consists of a glow joint with a silicone bond. 7. Heating device according to claim 5, characterized in that the Insulation (14) 'consists of fine mica and / or magnesium oxide and by glass formers, such as z.R. Borate, phosphate, silicate or vanadate is bound. <1 8. Heating device according to claim 5, characterized in that that the insulation consists of glass or glass ceramic. 9. Heating device according to one of claims 1 to 8, characterized in that that the heating conductor is designed as a corrugated tape (5). 10. Heating device according to one of claims 1 to 8, characterized in that that the heating conductor is layered as a meandering metallic strip (6) is formed. 11. Heating device according to one of claims 1 to 8, characterized in that that the heating conductor is designed as a wire coil (2, 12). Lee r? E 1 te