DE102008010343A1 - Water heating device i.e. flow-type heater, for e.g. dishwasher, has metal base for supporting isolation layer, where device at side of base for direct laminar contact with water is provided with single-layer or two-layered enamel layer - Google Patents

Abstract

The heating device (11) has a metal base (13) for supporting an isolation layer (19) and a heat conductor (22) on a side (18) of the metal base. The heating device at another side of the metal base for direct laminar contact with water is provided with a single-layer or two-layered enamel layer (16) as corrosion protection of the metal base, where the latter side is turned away from the heat conductor. The enamel layer completely covers the metal base and/or the latter side, and the isolation layer covers an edge of the metal base.

Description

Field of application and status of the technique

The The invention relates to a particular planar heating device for heating water or similar media by direct Contact with it.

From the DE 4233676 is a trained as a pipe planar heater known in the form of a flow heater. The tube is made of stainless steel to avoid corrosion, for example in dishwashers or coffee machines. Outside is on an insulating layer, which may be formed by an insulating film, wound and fixed a heating tape.

Task and solution

Of the Invention is based on the object, a heating device mentioned above to overcome the problems of the prior art are eliminated can and in particular the best possible corrosion resistance is reached.

Solved This object is achieved by a heating device with the features of claim 1. Advantageous and preferred embodiments of the invention are the subject of the further claims and will become hereafter explained in more detail. The wording of the claims becomes the content of the description by express reference made.

It it is envisaged that the heater is a metal carrier has or is arranged on a metal support. This wears an insulation layer on one of its two sides, on the turn the heating conductors are arranged and run. According to the invention the heater or the metal carrier on the other Side, so on the side facing away from the heating, with a Enamel layer provided as anti-corrosion, so this page easily in direct contact with water or similar May be exposed to media. The enamel layer is two-layered or even applied as a single layer. This is a significant less effort in enamelling possible.

By The coating with enamel becomes such, layer by layer constructed heater a caustic and acid stable Surface reached, which is also stable against corrosive infiltration is. Enamel has a surface similar to that Properties has like an otherwise well-known non-stick coating, For example, under the trade name Teflon known, with the advantage that it is mechanically more stable. In this respect, through the enamel layer, alternatively or in addition to the corrosion properties, also mainly the result of a surface be achieved with non-stick properties. Then store less Dirt and, above all, calcification is much lower. Furthermore, an enamel layer is temperature-stable with respect to others Process steps, such as baking, the further Structure of the heater may be performed need, for example, in thick film heaters.

Advantageous The enamel coating covers the metal carrier on its side over the entire surface or over the entire surface. She can do that in be applied to a single layer or formed in one layer be. But it can also be multilayered, under certain circumstances even with slightly different characteristics, for example Adhesion on the metal carrier or adhesion of further layers thereon. In a special embodiment of the invention can even under the enamel layer first another layer on the metal carrier be applied, for example for better adhesion, and then the enamel layer. As long as the enamel layer is the outermost layer Good corrosion properties are provided.

Of the Metal support can be considered a flat metal plate, as a vaulted Metal support or even be designed as a metal tube. The side or surface provided with the enamel layer should be fully coated, so at least until to the edges. Advantageously, the enamel layer even extends something about the edges for as possible good corrosion protection.

In Another embodiment of the invention, it is possible to Enamel layer also on the side of the metal support provide on which the heating conductors are attached. In this case, the Enamel layer either a part or the entire insulation layer to insulate the heating conductors against the metal carrier. Even with such a two-sided enamel coating of the metal support should the edges are advantageously co-coated. A circulating so to speak or complete enamel coating of the metal carrier can be done in a single step or in two steps, first one side and then the other. The application of several layers of enamel and insulation on top of each other has the great advantage that the whole isolation gets better and further both a larger one Thickness of insulation as well as a greater probability is achieved that the coating of the metal carrier has no holes that occur in a thick film process can. An advantageous layer sequence is a single one Enamel layer directly on the metal carrier and a single Layer of insulation in turn on it.

In one embodiment of the invention, it is possible to make the metal support from steel. This may be a stainless steel such as ferritic steel or austenitic steel. This can be formed and pulled very well due to its mechanical properties. Alternatively, it can be a carbon steel. Even with an inherently corrosion-resistant stainless steel, the enamel coating according to the invention makes it possible to use the heating device also in applications with corrosive media such as alkalis, acids or solvents containing chlorine or other additives without problems with permanent corrosion resistance, anti-calcification and functional safety. If the enamel layer is applied, for example, to a carbon steel, then a layer thickness between 50 μm and 200 μm of all the enamel layers together is considered to be advantageous, particularly advantageously between 60 μm and 150 μm. In a stainless steel, it may be between 20 microns and 200 microns and be particularly advantageous between 30 microns and 120 microns.

In another embodiment of the invention consists of the metal carrier made of aluminium. So can a relatively light and very good heat conducting heater be created. Here, the thickness of the enamel layer in similar Magnitude as mentioned above may be even slightly thinner, advantageously between 20 microns and 200 microns and more preferably between 50 microns and 150 μm.

As previously indicated, it is possible to use the metal carrier in a flat or plate-like training on the one hand or a curved or curved training on the other to use as a wall of the water supply of the heater or in a corresponding opening enforce. This can either be with the function of a water heater or as well Water reservoir.

In a further development of the invention, the metal support may be tube-like and thus particularly well form a water heater, similar to the aforementioned DE 4233676 A1 ,

Becomes the enamel layer only on the water - bearing side of the Applied metal carrier, it is advantageous an insulation layer on the other hand, provided for the heating conductors, the can be applied in thick film technology. Therefor are suitable per se known insulation layers. Alternatively it can an insulating film, for example of polyimide.

The heating conductors can either also be applied by thick film technology and then baked. Alternatively, they may be applied as separate heating conductors, for example by winding a tube. In general, the heating conductors can advantageously be designed to run as smoothly as possible for the greatest possible length and to cover the surface as well as possible. These may be meandering or in a tubular heater also circumferentially in a spiral shape. A power density of the heater or the heating conductor can be by their geometric design between 20 W / cm ² and 70 W / cm ² , ie significantly higher than in known such heaters, such as tubular flow heaters. This is also achieved by the non-stick properties of the enamel coating.

These and other features are excluded from the claims also from the description and the drawings, wherein the individual features in each case alone or to several in the form of subcombinations in one embodiment of the Invention and other fields be realized and advantageous as well as for protectable versions represent protection for which protection is claimed. Restrict the subdivision of the application into sections and intermediate headings the statements made thereunder are not in their generality.

Brief description of the drawings

embodiments The invention are shown schematically in the drawings and will be explained in more detail below. In the drawings shows schematically:

1 an oblique view of a heater according to the invention in tube form as a water heater,

2 a longitudinal section through a portion of the heater 1 with the layer construction and

3 and 4 Variations of the longitudinal section 2 ,

Detailed description the embodiments

In 1 is a heating device according to the invention 11 represented in tubular form, as it can be used for example as a water heater in a dishwasher, washing machine or coffee maker. The heater 11 has a metallic tube 13 on, for example, carbon steel, stainless steel or aluminum. It forms a water channel inside 14 ,

Out 2 with the longitudinal section through a portion of the heater 11 can be seen as an inside 15 of the pipe 13 with an enamel layer 16 is coated. Here is the enamel layer 16 only on the inside 15 provided, but may advantageously also extend a piece around the end edges around. Based on 2 is also good to see how a flat carrier can be formed.

On the outside 18 of the pipe 13 is an insulation layer 19 applied, advantageously in thick-film process or as the aforementioned insulating film. The insulation layer 19 So does not necessarily have to be insoluble with the pipe 13 be connected. On the insulation layer 19 are the heating conductors 22 applied, either by coating or in the case of heating conductors 22 made of metal strip by mechanical winding. This heating conductor 22 form the heater 21 , An electrical connection to the heater 21 or the heating conductors 22 via the on the insulation layer 19 attached connecting brick 24 , which is designed for a plug connection. Furthermore, it is located on the insulation layer 19 another temperature sensor 26 as electrical resistance temperature sensor.

As especially from the sectional view in 2 it can be seen, the heating conductors 22 with a cover layer 23 Mistake. As a result, they are advantageously also electrically insulated from the outside and / or protected against environmental influences such as corrosion. This cover layer 23 can in the area of the connecting block 24 and the temperature sensor 26 omitted.

Thus, therefore, the training shows in accordance 2 a heating device according to the invention with only one of the heating conductors 22 facing away from inside 15 provided enamel layer 16 , The enamel layer may have the aforementioned thickness in the range between 20 microns and 200 microns, preferably about 50 microns. It is advantageously provided as the only enamel layer. The pipe or the carrier 13 may be a few mm thick, for example 1 mm or 2 mm. The insulation layer 19 may have a similar thickness as the enamel layer 16 , So a few microns, and an aforementioned insulating film has a thickness of 20 microns to 100 microns.

A modified embodiment of a heater 11 in representation accordingly 2 is out 3 to see. Here is on a metal carrier 13 an enamel layer 16 not just on its inner side 15 provided, but also on its outside 18 below the heating conductor 22 , So it can be seen that the enamel layer 16 the metal carrier 13 completely or completely covered. About the heating conductors 22 is again a covering layer 23 intended. This training is especially useful when the metal carrier 13 good on both sides with the enamel layer 16 can be provided, especially with respect to the coating method in terms of the shape of the metal support. The step of applying the insulation layer 19 according to 2 can then be omitted.

In a further embodiment of the invention according to 4 is, so to speak, a heating device according to 3 with complete coating with the enamel layer 16 before applying the heating conductor 22 another insulation layer 19 applied to the outside. Also this isolation layer 19 according to 4 can be formed as mentioned above. Also on it are again the heating conductors 22 and a cover layer 23 applied. The advantage of the training of 4 compared to 3 is that through the extra insulation layer 19 an even better electrical insulation of the heating conductors 22 opposite the metal carrier 13 is ensured, especially by the greater total thickness of the coating. This allows the heating conductors 22 operate with higher voltage or the enamel layer 16 even thinner to design, especially on the outside 18 ,

As has been mentioned, the sectional representations of 2 to 4 both for tubular support according to 1 as well as for arched, channel-like beams or very flat beams.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 4233676 [0002]
• - DE 4233676 A1 [0013]

Claims (16)

Heating device ( 11 ) for heating water by direct surface contact with the water, the heating device ( 11 ) a metal support ( 13 ) on one side ( 18 ) an insulation layer ( 19 ) and then heating conductor ( 22 ), characterized in that the heating device ( 11 ) at the of the heating conductors ( 22 ) facing away ( 15 ) for direct surface contact with the water with a single-layer or two-layer enamel layer ( 16 ) as corrosion protection on the metal support ( 13 ) is provided. Heating device according to claim 1, characterized in that the enamel layer ( 16 ) the metal carrier ( 13 ) or its page ( 15 ) over the entire surface. Heating device according to claim 1 or 2, characterized in that the enamel layer ( 16 ) is monolayered or applied. Heating device according to one of the preceding claims, characterized in that the enamel layer ( 16 ) also on the page ( 18 ) of the metal carrier ( 13 ) with the heating conductors ( 22 ), wherein it preferably forms the insulating layer and in particular also the edges of the metal carrier ( 13 ) covered. Heating device according to one of the preceding claims, characterized in that the metal carrier ( 13 ) consists of steel, preferably made of carbon steel. Heating device according to claim 5, characterized in that the enamel layer ( 16 ) on a metal support ( 13 ) Carbon steel has a layer thickness of 50 microns to 200 microns, preferably 60 microns to 150 microns. Heating device according to one of claims 1 to 5, characterized in that the metal carrier ( 13 ) is made of stainless steel, preferably of ferritic stainless steel or austenitic stainless steel. Heating device according to claim 7, characterized in that the enamel layer ( 16 ) on a metal support ( 13 ) of stainless steel has a layer thickness of 20 microns to 200 microns, preferably 30 microns to 120 microns. Heating device according to one of claims 1 to 4, characterized in that the metal carrier ( 13 ) consists of aluminum. Heating device according to claim 9, characterized in that the enamel layer ( 16 ) on a metal support ( 13 ) of aluminum has a layer thickness of 20 microns to 200 microns, preferably 50 microns to 150 microns. Heating device according to one of the preceding claims, characterized in that the metal carrier ( 13 ) is formed flat or plate-like, preferably in a correspondingly formed opening a water supply of the heater ( 11 ) can be used liquid-tight. Heating device according to one of claims 1 to 10, characterized in that the metal carrier ( 13 ) is curved or arched, wherein it is preferably channel-like and in particular designed as a tube with the heating conductors ( 22 ) on the outside ( 18 ) and the enamel layer ( 16 ) on the inside ( 15 ). Heating device according to one of the preceding claims, characterized in that the enamel layer ( 16 ) at least a part of the insulating layer of the heating conductor ( 22 ) against the metal carrier ( 13 ). Heating device according to one of the preceding claims, characterized in that the insulating layer ( 19 ) is applied in thick film technology. Heating device according to one of the preceding claims, characterized in that the insulating layer ( 19 ) in addition to the enamel layer ( 16 ) on the metal support ( 13 ) or on the enamel layer ( 16 ) himself is upset. Heating device according to one of the preceding claims, characterized in that the heating conductors ( 22 ) are formed in tracks or meandering, wherein they are preferably applied in thick film technology.