DE102019125966A1 - Heating apparatus and method of making the same - Google Patents

Abstract

Disclosed is first of all a heating device (1) with a visible surface made of natural stone, a support (2) which has electrodes (10) and is covered with a heating means (4) on a heating surface (3) parallel to the visible surface, which is located under a between the electrodes (10) flowing current is heated. A method for producing such a heating device (1) is also disclosed. As an inexpensive heating means (4) it is proposed that the heating means (4) essentially consist of nanoparticles and that the electrodes (10) are attached to opposite edges of the heating surface (3) will.

Description

The invention initially relates to a heating device with a visible surface made of natural stone, a carrier which has electrodes and is covered on a heating surface parallel to the visible surface with a heating means which heats up under a current flowing between the electrodes. The invention also relates to a method for producing such a heating device.

DE 10 2004 025 033 A1 suggests using a graphite foil or laminate plate made of natural graphite as the heating means in such a heating device.

In the background of the invention is off DE 199 09 642 C1 a stone veneer made of natural stone is known.

task

The invention is based on the object of using an inexpensive heating means.

solution

Based on the known heating device, it is proposed according to the invention that the heating means consist essentially of nanoparticles and that the electrodes are attached to opposite edges of the heating surface.

In particular, carbon nanotubes (CNT), graphene or graphite, soot and copper or silver particles are used as nanoparticles. These inexpensive heating means have an electrical conductivity of typically more than 10 ⁶ S / m (for example graphite: 3, graphene: 100 and CNT: 232 × 10 ⁶ S / m).

The electrodes can in particular consist of copper, silver or gold and be glued to the heating means by means of an adhesive. The adhesive preferably has a conductivity of at least 10 ³ , more preferably at least 10 ⁴ S / m. Particularly suitable adhesives are intrinsically conductive polymers with conductivities of up to 10 ⁵ S / m.

Alternatively, the carrier of a heating device according to the invention is preferably a step or a pavement slab. The heating device then prevents the stone slab from icing over, particularly in the outside area.

Alternatively, the heating device according to the invention is preferably part of a kitchen worktop. The heating device can be integrated seamlessly and invisibly into the worktop as a cooking and / or warming surface.

Alternatively, the heating device according to the invention is preferably a mobile hotplate and / or hotplate, for example a so-called “hot stone”. The heating device is then easily transportable.

The visible surface of a heating device according to the invention is preferably a stone veneer. The heating device is then, on the one hand, particularly light and, on the other hand, the temperature of the heating device can be changed particularly quickly.

Based on the known method, it is proposed according to the invention that the heating means consists essentially of nanoparticles and that the electrodes are attached to mutually opposite edges of the heating surface. The method according to the invention allows the production of one of the above-described heating devices according to the invention and is also distinguished by the advantages mentioned above.

In a method according to the invention, the nanoparticles are preferably applied to the heating surface in an aqueous dispersion and moisture contained in the dispersion is evaporated. In such a process, the nanoparticles are deposited in a solid and even layer on the heating surface.

Alternatively, in a heating device according to the invention, the heating means has a polymer matrix in which the carbon nanotubes are embedded. Such heating means are generally known, for example under the product name “Carbo e-Therm” from the manufacturer FutureCarbon GmbH, Bayreuth / DE. Polyacrylates, epoxy resins and silicone resins in particular come into consideration as the polymer matrix.

In a method according to the invention, the heating medium is preferably sprayed onto the heating surface and onto the electrodes. In such a method according to the invention, a particularly uniform layer of the heating medium can be applied to the heating surface. Alternatively, the heating medium can be brushed or trowelled onto the heating surface.

In the context of a method according to the invention, the heating device is preferably attached to a floor or a wall of a building. The heating device according to the invention is then used to heat the adjoining interior space of the building, in particular a living, office, business, production or storage room or a wet room.

The visible surface of a heating device according to the invention can - at least on its visible surface - consist in particular of natural stone, for example of slate, granite or marble

Figure list

• 1a im Querschnitt eine erste erfindungsgemäße Heizvorrichtung, und
• 1b ein Detail der ersten Heizvorrichtung,
• 2a im Querschnitt eine zweite erfindungsgemäße Heizvorrichtung und
• 2b eine Draufsicht der zweiten Heizvorrichtung sowie
• 3a im Querschnitt eine dritte erfindungsgemäße Heizvorrichtung und
• 3b eine Draufsicht der dritten Heizvorrichtung.

The invention is explained below on the basis of exemplary embodiments. It show in schematic, not to scale representations

• 1a in cross section a first heating device according to the invention, and
• 1b a detail of the first heating device,
• 2a in cross section a second heating device according to the invention and
• 2 B a plan view of the second heater and
• 3a in cross section a third heating device according to the invention and
• 3b a top view of the third heater.

In the 1a and in a detail in 1b shown first heating device according to the invention 1 has a carrier 2 on with a heating surface 3 that with a heating medium 4th is covered. The carrier 2 is a step made of natural stone with a length 5 of 100 cm and with a depth of 34 cm, not shown, and with a thickness 6th of 30 mm. The heating surface 3 takes up the entire bottom 7th of the wearer 2 a.

On the heating surface 3 were carbon nanotubes (product name Aquacyl from Nanocyl, Sambreville / BE) in aqueous dispersion, which can be used as heating means 4th with a thickness 8th less than 10 µm on the heating surface 3 have deposited. On the heating medium 4th are two electrodes 10 from one with a conductive adhesive 9 self-adhesive copper foil (product designation 1181 tape from 3M Electrical Products, Austin, TX / US)) with a thickness 11 from 30 to 50 µm and a width 12th glued on from 5 mm.

The opposite edge areas 13th of the electrodes 10 and the adjacent areas of the heating surface 3 were after sticking the electrodes 10 again with the heating medium 4th sprayed to one with the heating surface 3 connected contact layer 14th train the the edge areas 13th covered and from there onto the heating surface 3 overlaps. The contact layer 14th again has a thickness 15th of less than 10 µm.

On the contact layer 14th is a top layer 16 made of copper with a thickness 17th also applied by electroplating of less than 10 µm. In order to improve the electroplating, the contact layer was applied 14th a conductive copper lacquer (product name TIFOO from Marawe GmbH, Regensburg / DE) was applied beforehand.

The first heater 1 is on a leveling layer 18th from a silicate airgel with a thickness 19th of 5 mm stored, which in turn is on a base step 20th with a thickness 21 30 mm is in contact. The first heater 1 has an electrical power consumption of up to 500 W with a supply voltage of 42 V.

In a further exemplary embodiment (not shown), instead of electroplating, a polymer with low conductivity is sprayed onto the contact layer as a cover layer for electrical insulation.

The ones in the 2a and 2 B shown second heating device according to the invention 22nd is a heating or cooking plate (so-called "hot stone") for a large kitchen with a width 23 and a depth 24 of 100 cm each.

The second heater 22nd has a carrier 25th made of silicate airgel with a thickness 26th of 5 mm, its heating surface 27 with a thickness 28 , 29 of less than 10 µm each with the spray adhesive 30th and then in two heating zones 31 , 32 with the heating medium 33 from the first heater 1 is covered. In the first heating zone 31 became the heating medium 33 easy, in the second heating zone 32 applied twice.

On the heating medium 33 are parallel to each other on the outer edges 34 the second heater 22nd and between the heating zones 31 , 32 three electrodes 35 from a double-sided self-adhesive copper foil (product designation 1182 tape from 3M Electrical Products, Austin, TX / US) with the one from the first heating device 1 known dimensions attached and in the opposite edge areas 36 with the heating medium 33 covered.

On the double-sided adhesive electrodes 35 does it stick to the edge areas 36 applied heating means 33 even without electroplating.

The heating medium 33 and the electrodes 35 are finally with a decorative panel 37 with a stone veneer (product name Slate-Lite from R&D GmbH, Rheinbach / DE) and a thickness 38 covered by 3 mm. The carrier 25th is on a base plate 39 from a natural stone with a thickness 40 of 10 mm attached.

With a connected load of around 500 W and a voltage of 230 V between the electrodes 35 indicates the first heating zone 31 a temperature of 50 ° C and the second heating zone 32 a Temperature of 80 ° C. By reducing the respective voltage, the heating output of the two heating zones is increased 31 , 32 regulated independently of the other.

The ones in the 3a and 3b shown third heating device according to the invention 41 corresponds essentially to the second heating device 22nd .

There are only two electrodes that differ 42 at the edges 43 the third heater 41 appropriate. The heating zones 44 with different heating outputs as with the second heating device 22nd run transversely between the electrodes 42 . By reducing the voltage between the electrodes 42 becomes the heating output of the two heating zones 44 regulated at the same time.

In a further exemplary embodiment, not shown, the carrier is a different heat insulator, in particular a different airgel or expanded polystyrene (EPS, trade name Styrofoam).

List of reference symbols

1

Heater

2

carrier

3

Heating surface

4th

Heating means

5

length

6th

thickness

7th

bottom

8th

thickness

9

Glue

10

electrode

11

thickness

12th

width

13th

Edge area

14th

Contact layer

15th

thickness

16

Top layer

17th

thickness

18th

Leveling layer

19th

thickness

20th

Basic level

21

thickness

22nd

Heater

23

width

24

depth

25th

carrier

26th

thickness

27

Heating surface

28

thickness

29

thickness

30th

Spray adhesive

31

first heating zone

32

second heating zone

33

Heating means

34

edge

35

electrode

36

Edge area

37

Decorative panel

38

thickness

39

Base plate

40

thickness

41

Heater

42

electrode

43

edge

44

Heating zone

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102004025033 A1 [0002]
• DE 19909642 C1 [0003]

Claims (10)

Heating device (1, 22, 41) with a visible surface made of natural stone, a carrier (2, 25) which has electrodes (10, 35, 42) and on a heating surface (3, 27) parallel to the visible surface with a heating means (4 , 33), which heats up under a current flowing between the electrodes (10, 35, 42), characterized in that the heating means (4, 33) consists essentially of nanoparticles and the electrodes (10, 35, 42) are mounted on opposite edges of the heating surface (3, 27). Heating device (1, 22, 41) according to the preceding claim, characterized in that the electrodes (10, 35, 42) are glued to the heating means (4, 33) by means of an adhesive. Heating device (1) according to one of the preceding claims, characterized in that the carrier (2) is a step. Heating device according to one of the Claims 1 to 3 , characterized in that the heating device is part of a kitchen worktop. Heating device (22, 41) according to one of the Claims 1 to 3 , characterized in that the heating device is a hot plate. Heating device (1, 22, 41) according to one of the preceding claims, characterized in that the visible surface is a stone veneer. Method for producing a heating device (1, 22, 41) with a visible surface made of natural stone, electrodes (10, 35, 42) being attached to a carrier (2, 25) and a heating surface (3, 27) parallel to the visible surface The support (2, 25) is covered with a heating means (4, 33) which heats up under a current flowing between the electrodes (10, 35, 42), and the stone slab with its back on the support (2, 25) is applied, characterized in that the heating means (4, 33) consists essentially of nanoparticles and the electrodes (10, 35, 42) are attached to opposite edges of the heating surface (3, 27). Method according to the preceding claim, characterized in that the nanoparticles are applied to the heating surface (3, 27) in aqueous dispersion and moisture contained in the dispersion is evaporated. Method according to one of the Claims 7 or 8th , characterized in that the heating medium (4, 33) is sprayed onto the heating surface (3, 27) and onto the electrodes (10, 35). Method according to one of the Claims 7 to 9 , characterized in that the heating device is mounted on a floor or a wall of a building.

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