DE19923937C2 - Module plate for electrical surface heating of floors or walls - Google Patents

Description

The invention relates to a module plate for electrical surface heating of Floors or walls with a support plate, a thermal barrier coating and one possibly embedded in a heat-conducting contact and binding layer current-conducting materials that can be operated as electrical resistance heating, containing heating layer.

From DE 196 47 935 A1 an electric interior heater for caravans is known, which is designed as a large-area resistance heater covering the inner walls in a composite construction. This known resistance heater comprises at least one thermal insulation layer and an electrically insulating carrier layer with increased strength, which is coated with a heating layer which is coated from a mixture of a carbon, graphite particles and / or carbon fibers mixed with hardenable binder. This resistance heater has a heating output of 50 to 200 W / m ² and can be connected to an output voltage of 12 to 50 V or protective extra-low voltage.

From DE-AS 12 50 573 is already a heated plate for clothing or Manufacture of floors, ceilings or walls known using a stream very low voltage can be heated. This is a Detachably connected plate with its base, for example for heating of piglet stalls and chicken stalls or as an additional floor covering for cold Floors can be used in winter. The plate is a composite of two Chipboard with a heat insulating layer in between Rigid plastic foam built up and points to a free surface of one Chipboard on a wire mesh grill that works with a mechanical  and thermally resistant screed is covered. The used All materials are combustible and not for high resistance to treading Designed for loads.

Known floor heating systems are integrated into the floors of the buildings, preferably equipped with a heat-conducting medium flowed pipe system.

Movable radiators are also known which contain heat insulating bodies and heated by electric current in the form of, for example, rolls mounted mobile storage heater. However, these represent a larger one Room only represent selective heat sources and can only have one room via one heat for a very long period of time, being from a radiator amount of heat to be released is usually limited by the size of the same and a plurality of such radiators are required for a large space.

The invention has for its object a device for electrical Heating floors and / or walls in buildings, households, Conservatories, industrial plants, exhibition stands to create the mechanically stable and is heavy-duty, for permanent installation as the only heater or for temporary installation and transportable and effective in the shortest possible time heats.

According to the invention, a module plate for electrical surface heating of floors or walls is proposed to achieve the object, in which the carrier plate and the heat insulation layer are designed in the form of a vacuum heat insulation plate as a self-supporting structural element and applied to the vacuum heat insulation plate on or in the adhesive and electrically insulating contact and bonding layer as a current-conducting material, a flexible sheet containing carbon fibers is applied, and a covering layer made of a good heat-conducting covering is applied thereon. According to the invention, a defined carbon fiber sheet is used as a heating conductor. A vacuum thermal insulation panel is proposed as the carrier panel, which has a very low thermal conductivity of up to <0.003 W / mK, which preferably has mineral, non-combustible material as a thermal insulation layer and can be fire-insulating up to 800 ° C. In particular, the module plate according to the invention is based on the vacuum heat insulation plate used, which is characterized by a high load-bearing capacity and resistance to treading, which, depending on the design, permits a load-bearing capacity of up to 6.5 t / m ² .

The module plates according to the invention are suitable both for permanent installation as well as for a temporary installation, that is, easy to install and removable and also portable. The sizes of the module plates are like this chosen that they are still easy to handle, on the other hand as little as possible Assembly work.

Advantageous and inventive developments of the module plate for floor or wall heating are the characteristic features of the subclaims removable.

According to the invention, the vacuum heat insulation plate is more resilient and walkable floor a vacuum-tight covering made of stainless steel or plastic or glass fiber reinforced plastic and is filled with a thermal insulation material and vacuumed. Vacuum heat insulation plates are for example in DE 42 14 002 A1 described. Such vacuum thermal insulation panels have so far been used usually used in refrigeration, namely for refrigerated containers, cold rooms, Tank containers, blast freezers, household refrigerators and freezers u. a ..

The carrier plates are filled with a highly heat-insulating material, which has a thermal conductivity according to DIN 52612, preferably of 0.03 W / mK or smaller, has. Micro glass fibers, for example, come as thermal insulation material, Vermiculite, pearlite, minerals, plastics, powdered inorganic oxides, Microsilica and / or diatomaceous earth in question. Thermal insulation materials are preferred used in compressed form for filling the carrier plate. After filling the Stainless steel sheet casing, the plate thus formed is evacuated, whereby the Thermal conductivity is reduced to a value of 0.01 W / mK to 0.003 W / mK. A microporous silica material is preferably used as the thermal insulation material, a mineral, inorganic material that is non-flammable. From the Combination of the microporous silica material, which is already an extraordinary high thermal insulation of 0.02 W / mK results in connection with the vacuumed plate a very low thermal conductivity of the vacuum Thermal insulation plate of up to 0.003 W / mK. The microporous silica material fills completely remove the vacuum plate. This will also make it a very high one Impact resistance of the vacuum plate is achieved because it is not hollow.  

According to the invention, the module is obtained as a load-bearing component by the design of the support plate as a vacuum heat insulation plate, which can be connected to a base as well as used as a self-supporting element. The module according to the invention can be used as a construction element with high mechanical, thermal, corrosive stability. Even vacuum thermal insulation panels with a thickness of 10 to 18 mm and a thickness of the stainless steel sheet of 0.6 to 1.0 mm are able to withstand the stresses as a floor and have excellent thermal conductivity figures. For heavily loaded underfloor heating, which should be accessible, for example, by forklift truck or truck, panels with a thickness of 40 mm or more with a thickness of the stainless steel sheet cover of 3 mm and more can be used, whereby crush resistance of up to 6.5 t / m ² can be achieved. Vacuum thermal insulation panels, which can be used for the portable floor and wall heating according to the invention, can already be produced in large-format panels from 0.6 m × 0.6 m up to 2.80 m × 5.00 m in length. Dimensions up to 5 m × 8 m are possible. The total thickness of the heatable module plate is 20 to 55 mm.

According to the invention, the modules are in the form of a current-conducting material of a defined fabric made of carbon fibers with such a performance equipped that they are suitable for the sole heating of buildings, apartments are and not only usable as additional heating.

According to a further proposal of the invention, a is used as the current-conducting material Flat structures made of glass fibers and carbon fibers are used. The invention flexibly trained current-conducting material can be used in the manufacture of the Prefabricated module plate as a mat and simply on the contact and binding layer, which is applied to the vacuum heat insulation plate, placed or embedded become. This handling facilitates the economical production of the module plate according to the invention essential. Can also be used as a current-conducting material a carbon fiber fabric can be used in which as many carbon fibers as possible in one Axis are arranged, making the power line and high efficiency so that the thermal energy that can be generated can be achieved. Likewise, as current-conducting material a carbon fiber felt can be used. according to the invention also uses the fact that carbon fibers have a negative effect on heating Have expansion coefficients, so that when heated, the material does not breaks because no voltage is generated.

A dense sheet of carbon fiber is preferably used because the Carbon fibers have a negative coefficient of expansion when heated and therefore no stresses in the contact and bonding layer during heating  produce. There can be the carbon fibers or carbon fiber structures on one Glass fiber fabric or glass fiber fabric applied and together with this the contact and bonding layer are applied. The connections of the Electrically conductive material are led out of the module plate and are with connected to an electrical energy source, for example Power supply via thyristor-controlled transformers at a voltage of 24 volts transformed mains voltage of 220 volts.

According to a proposal of the invention, the connections of the current-carrying Materials designed as a galvanic system and with a low voltage and DC powered power source connected.

The applied in, or on the contact and bonding layer of the module plate Electrically conductive materials enable high thermal energy to be applied across the surface produce. In particular, this energy is generated through the use of carbon fiber structures, such as carbon fiber fabrics, carbon fiber felts or carbon fiber rods that are if necessary, have it flexibly adapted to the contact and mortar layer, realized. Those used according to the invention to generate the heat Carbon fiber structures are therefore used to work on the principle of large Surface as an electrical resistance heater a controllable high Generate energy density and heat in the module plate. According to the Construction of the module plate according to the invention, this amount of heat Insulated on the floor side by the vacuum thermal insulation plate and thus migrates exclusively to the cover layer and through this in the to be heated Room.

The carbon fiber structures that can be used, for example, according to the invention are in the Space industry developed and commercially available, for example under the trade names Sigrabond® and Sigratherm® from SGL Carbon AG distributed.

The module plate according to the invention for use as underfloor heating or Wall heating not only has a very low overall height, it also requires it only a minimum of energy to be used, d. H. as a result of extremely heat-insulating carrier plate made of a vacuum heat insulation plate Significant energy savings by reducing heat loss in the wrong direction possible.  

Vacuum thermal insulation panels where the outer panels are made of plastic or fiber-reinforced plastic, e.g. B. consist of glass fiber reinforced polyester fibers, have a not quite as high step resistance as those with plates Stainless steel. Other sets are lighter and therefore easier to handle, For example, it can also be attached to walls.

The means of the current-conducting materials as a thermal energy source in the Temperatures generated by the module plate can be controlled by means of a control device Control of the applied voltage can be regulated. By means of the current conducting in the contact and bonding layer embedded materials, such as the dense fabrics made of carbon fibers, the necessary Heating temperatures of up to about 50 ° C can be generated in the shortest possible time. The desired temperature curve is controlled by controlling the voltage of the Regulated energy source. The heating system according to the invention thus enables the module plates have a special control characteristic, according to which the module plates in a few minutes from z. B. 20 ° C to 40 ° C temperature of the surface of the Let the cover layer run up. In comparison need conventional Underfloor heating with piping and water as a heating medium is essential longer times.

The regulation of the temperature profile and the amount of heat to be released can by placing thermometer elements and sensors on the surfaces of the Module plates are detected and the measured values are fed to a control device.

The current-conducting used in the contact and bonding layer according to the invention Materials thus form one in connection with the applied voltage electrical resistance heating and generate a corresponding thermal Energy.

Essential for a good efficiency in the contact and binding layer embedded current-conducting materials, their embedding is particularly that Carbon fiber structures, in the absence of air, so that oxidation is prevented.

In addition, it is possible for the carbon fibers to provide a protective coating against Receive oxidation, for example a glaze coating based on silicon Carbide or a protective layer against erosion.  

According to the invention, the module plate with a low voltage is preferred a maximum of 30 volts or less applied for heating.

Since a high density of the current-conducting material, in particular the Carbon fiber structure, increases the efficiency of the power line, it is preferred and important that carbon fiber structures and carbon fibers with a high Purity level over 98% should be used if possible.

The carbon fiber structures that can be used according to the invention should preferably have fibers oriented in an axial direction and a high density. The specific electrical resistance at 20 ° C. can range from 24 to 32 ohms / μm, these bulk densities being between 1.0 and 1.5 g / cm ³ .

As a contact and binding layer is a layer of a heat-conducting and electrically insulating material, such as mortar, proposed. There are but also contact and bonding layers made of thermally conductive plastics, Adhesion promoters or adhesives possible. If necessary, additional Adhesion promoter layers on the contact and binding layer to produce a sufficient adhesive bond to the cover layer and / or vacuum Thermal insulation plate are provided. In particular, it is also possible to Use of a vacuum heat insulation plate with an outer jacket made of steel plates to be provided with an electrically insulating layer which at the same time and bonding layer on which the electrically conductive heating materials - conductive materials - to be applied. In addition, it is possible after the application of the current-conducting materials on the surface Contract and binding layer, on top of the electrically conductive materials Apply cover layer from a hard-wearing plastic layer. At the same time however, this protective layer can also be colored and serve as a surface, for example when using the module plate as wall heating. It is preferred here as a covering layer, a laminated laminate, for example based on epoxy resin or polyester.

In particular for underfloor heating, the module panels are equipped with a Covering layer made of heat-conducting materials that are suitable for inspection, such as commercially available ceramic tiles, stone slabs, marble slabs or others provide suitable flooring materials. It is also possible to get one continuous covering made of a suitable and heat-conducting material Insert cover layer. The cover layer is preferably adherent to the  Contact and bonding layer connected, so that a stable module plate as a complete Assembly unit is present.

In particular, it is provided that the vacuum thermal insulation panels are large in size and a large number of small-format tiles as a covering layer exhibit. So it is possible to create large format module plates, whereby the Use of flexible electricity-conducting materials that make up the electric heating system form a certain flexibility of portable underfloor heating or Wall heating is guaranteed to avoid damage to the Heating system.

According to the floor heating or wall heating in the form of prefabricated elements, the module plates that are put together or also in the form of larger module plates as prefabricated heating in households, Conservatories, industrial plants, exhibition stands are used. The invention also enables a transportable electrically heated and resilient Underfloor heating. The module plates are a prefabricated heater, comprehensive both the floor insulation, the heating system and the walk-on cover layer. An additional layer of thermal insulation or insulation against the There is no need for a surface on which the module plates are applied.

According to a further proposal of the invention, it is possible in the floor Current-conducting materials installed as heating also for an alarm system or to use an alarm signal. For this it is proposed to use an electrical one Inductance and capacitance of the current-conducting materials To provide a measuring device which is connected to an alarm system, as a result Entering the module plate causes pressure-related changes in the inductance / capacitance record and feed as alarm signal to the alarm system. This measuring device can be activated, for example, when leaving the building, so that at unauthorized access to the floor, the alarm signal can be triggered.

Essential feature of the module plate according to the invention for use as Surface heating for floors and / or walls is the creation of a directed heat only in the rooms to be heated, as the The side of the module plates facing the substrate is very well stripped. The Module plate according to the invention enables the installation of surface heating with very low height, space-saving, it is just as suitable for renovating old buildings, as well as temporary heating as well as for continuous operation. The  Module panels according to the invention can be installed easily and quickly. The Heating by means of the module plates according to the invention is not sluggish, but rather responsive, it starts in a reaction time of 5 minutes Heat emission. The module plates according to the invention can also be ideal in the Use the transitional period temporarily. Due to low heat loss for They save energy underground and as floor, wall and ceiling heating applicable. High mechanical stability of the modules and resistance to corruption enable versatile use.

The invention is explained below using the drawing as an example.

In Fig. 1, a module plate M is shown, comprising the vacuum heat insulation plate 1 , which is also a carrier plate, the contact and bonding layer 2 adhered to the plate 1 with the electrically conductive materials embedded therein as an electrical heating system and with the contact and Binding layer 2 bonded covering layer made of ceramic tiles 5 The connections 4 are provided for the power supply.

In FIG. 2 is a schematic cross-section through the module plate M. The carrier plate 1 is formed by a vacuum heat insulation plate which has a coefficient of thermal conductivity of, for example, 0.007 W / mK. This vacuum heat insulation plate consists, for example, of a stainless steel double plate 1 a, 1 b, into which a highly heat-insulating material 1 c is introduced, for example a product based on microsilica. However, other thermal insulation materials such as vermiculite or perlite or the like can also be used. The stainless steel plates 1 a, 1 b are also provided on their end faces 1 e with a stainless steel frame and are welded together to form an airtight body, in the cavity of which the thermal insulation material 1 c is located. This cavity is then evacuated after filling with thermal insulation material, whereby the thermal conductivity of the entire vacuum thermal insulation plate is extremely low. In particular, the thermal conductivity of the thermal insulation material used, for example compressed microsilica, which is 0.02 W / mK at 30 ° C., is further reduced by the evacuation.

The carrier plate 1 thus fulfills both the load-bearing requirements of a floor in terms of resistance to treading and resilience as well as those of excellent thermal insulation. A contact and bonding layer 2 , for example mortar, is applied to this carrier plate 1 and an electrical heating system 3 with current-conducting materials, in particular a glass fiber fabric with carbon fibers as electrical resistance heating, is embedded therein. The current-conducting materials are completely embedded in the contact and binding layer 3 , so that they are air-sealed therein and only the strands 4 lead out of the contact and binding layer 2 to a voltage source, for example the module plate M with a low voltage of 24 volts acted upon. On the contact and bonding layer 2 , the walkable cover layer 5 facing the room to be heated is applied for the transfer of the thermal energy, for example in the form of ceramic tiles, marble slabs, stone slabs or other suitable heat-conducting coverings 5 , which are bonded to the contract and bonding layer 2 are.

The current-conducting materials 3 are used to generate a controllable high energy density in the form of a quantity of heat according to the principle of the large surface area as electrical resistance heating and to deliver this via the contact mortar layer to the covering layer 5 and from there further into the room.

For the heating of one square meter of floor to 40 ° C floor temperature of the covering layer 5 made of ceramic tiles with a thickness of 10 mm, 100 watts are required, with an applied voltage of 12 volts, a thickness of the carrier plate of 10 mm, with a stainless steel sheet thickness of 1.5 mm, a thickness of the mortar layer of 2 mm and a carbon fiber fabric with a total weight of 120 g, a length of 6 m and a width of 20 mm and a thickness of 1.5 mm. The measured current was 8.3 amps.

The module plate according to the invention took 5 minutes to heat the temperature of the covering layer 5 from 20 ° C. to 40 ° C. Usually, however, only a general floor temperature in closed rooms of a maximum of 28 ° C is aimed for.

In Fig. 3, a module plate is shown in cross section, which has a low overall height of 21 mm and is sufficient as a floor heating for normal conditions. A 10 mm thick vacuum heat insulation plate with a stainless steel outer jacket and microsilica filling is provided as the carrier plate 1 , and the current-conducting material 3 in the form of a flat structure made of a glass fiber fabric with carbon fibers is embedded in a thin electrically insulating plastic layer 2 . Decorative plates with a thickness of 10 mm made of ceramic are provided as the covering layer 5 . The substrate 6 has, for example, a temperature of 15 ° C. When the heating layer 3 is heated to 28 ° C., the carrier plate 1 heats up by approximately 1 ° C., while the decorative plate on its upper side likewise reaches 28 ° C.

The invention is characterized by transportable module plates, which as Prefabricated components, depending on their size, can be used as underfloor heating can be used or several module plates have a larger area Floor heating result. The module plates can easily be placed next to each other and electrically connectable. Due to the high quality insulation of the used Carrier plate, an energy-saving electrical heating is possible, which also Saves costs. The extremely short heating-up times are also special Advantage.

The heater according to the invention can in the form of the prefabricated module plates can be put together, including pre-made heating Floor insulation, heating element and walk-in tiles for permanent installation or as transportable equipment can be used and wherever temporarily and rooms must be temporarily heated, built and used become. It can also be easily dismantled and moved to another location erectable.

Claims (22)

1. Module plate for electrical surface heating of floors or walls with a support plate, a heat insulation layer and a possibly embedded in a heat-conductive contact and bonding layer current-conducting materials that can be operated as electrical resistance heating, containing heating layer, characterized in that the support plate and the heat insulation layer in the form of a vacuum heat insulation plate ( 1 ) are designed as a self-supporting, unified structural element and a flexible sheet containing carbon fibers is applied to the vacuum heat insulation plate onto or into the adherently applied and electrically insulating contact and bonding layer ( 2 ) as the current-conducting material, and thereupon a covering layer ( 5 ) made of a good heat-conducting covering is applied in an adherent manner. 2. module plate according to claim 1, characterized in that the vacuum heat insulating plate a has a vacuum-tight envelope made of stainless steel sheet and with a Thermal insulation is filled and vacuumed. 3. Module plate according to claim 1, characterized in that the vacuum heat insulating plate a vacuum-tight casing made of plastic or glass fiber reinforced Has plastic plates and filled with a thermal insulation material and is vacuumed. 4. module plate according to claim 1 to 3, characterized in that the vacuum heat insulating plate a Thermal conductivity according to DIN 52612 less than 0.01 W / mK. 5. Module plate according to one of claims 1 to 4, characterized in that vacuum thermal insulation panels of a thickness of 10 to 40 mm are provided.   6. Module plate according to one of claims 1 to 5, characterized in that as thermal insulation material microglass fibers, powdery inorganic oxides, vermiculite, pearlite, mineral substances, Plastics, microsilica and / or diatomaceous earth are provided. 7. module plate according to claim 6, characterized in that thermal insulation materials with a low Thermal conductivity of 0.03 W / mK or less are used. 8. Module plate according to one of claims 1 to 7, characterized in that it has an impact resistance of at least 4 t / m ² for use as underfloor heating. 9. Module plate according to one of claims 1 to 8, characterized in that a flat structure is used as the current-conducting material made of glass fibers and carbon fibers. 10. Module plate according to one of claims 1 to 9, characterized in that carbon fiber fabric as the current-conducting material are used in which as many carbon fibers as possible in one axis are arranged, which means a high efficiency of the power line and thus of the thermal energy that can be generated. 11. Module plate according to one of claims 1 to 9, characterized in that a carbon fiber felt as the current-conducting material is provided. 12. Module plate according to one of claims 1 to 11, characterized in that the connections of the current-conducting material are designed as a galvanic system and with an electrical Low voltage and direct current operated energy source are connectable. 13. Module plate according to one of claims 1 to 12, characterized in that the desired surface temperature of the Module plate can be reached by controlling the voltage of the energy source.   14. Module plate according to one of claims 1 to 13, characterized in that as a covering layer on the current-carrying Material a plastic layer, or a laminate based on laminate curable resins, such as epoxy resin, polyester is applied. 15. Module plate according to one of claims 1 to 13, characterized in that as a cover layer on the in the contact and Binding layer embedded current-conducting material is a good heat conductor plate-shaped covering is applied firmly. 16. Module plate according to one of claims 1 to 15, characterized in that the electrical inductance and capacitance of the current-conducting materials measuring device is provided, the is connected to an alarm system in order to enter the module plate to record pressure-related changes and as an alarm signal from the alarm system feed. 17. Module plate according to one of claims 1 to 16, characterized in that it takes a few minutes, especially less than eight minutes, starting from room temperature, can be heated, so that the surface of the cover layer has a temperature 20 ° C higher than that Corresponds to the initial room temperature, can be reached. 18. Module plate according to one of claims 1 to 17, characterized in that as a contact and bonding layer mortar and as Covering layer ceramic tiles, stone slabs, marble slabs provided are. 19. Module plate according to one of claims 1 to 18, characterized in that an electrical as a contact and bonding layer insulating and thermally conductive adhesive is provided. 20. Module plate according to one of claims 1 to 19, characterized in that large-format vacuum thermal insulation panels Are provided as a variety of small-sized tiles or plates Have cover layer.   21. Module plate according to one of claims 1 to 20, characterized in that they have a thickness of 20 to 25 mm. 22. Module plate according to one of claims 1 to 21, characterized, that it is designed in such a way that an area-wide one Floor or wall heating can be plugged together.