DE19652614A1 - Electric space-heating panel for interior space e.g. rooms - Google Patents

Abstract

The panel has a resistive layer (3) applied to a thermal insulating base (10) via a support layer (12). The resistive layer has a controlled amount of conducting material added to its bulk e.g. graphite, carbon, carbon fibre. The protective layer is bonded by a hydraulic binder to form a moisture resistant cover which transmits infrared energy supplied from the heating layer. Contacts (4) are bonded to the resistive layer. The heating layer has a rating of 1-30 watts per square metre. The thermal insulation (1) can be provided by a foam material on a supporting base (13). The heating panels are applied to the walls and ceiling of a room. The wall heating system can be supplemented by conventional underfloor heating or storage heating.

Description

The invention relates to an electrical low-temperature heating system for interiors, with a resistance heater, the one with electrodes, the room-encompassing Has completely or partially covering, electrically conductive heating layer, which consists of a mixture based on graphite particles, carbon or carbon fibers and a curable binder such as water glass.

Radiation wallpapers or heating foils are connected in series to heat interior rooms arranged strip-shaped heating elements known from a on wallpaper base paper applied dispersion of graphite powder, carbon black, water glass and water are shown.

This in DE 32 13 977 A1 and at H.-D. Fröse, electric heating systems, electric practice, Pflaum Verlag Munich 1995, Table 1.3.3.1-1, described heating wallpapers have a comparatively large heat output based on the area, which is greater than 100 W / m ² .

The high heating power causes an excessive surface temperature as well as special ones Precautions that make the purchase and operation of interior heating more expensive. The strip-shaped heating elements must be protected against overheating and with a Protection circuit and be equipped with an internal temperature controller. With Walls covered with heating wallpaper and the floors to be heated with heating foil must not be adjusted with furniture to ensure heat dissipation. Consequently there is a risk that the available for lining with heating wallpaper Heating surfaces are not large enough to sufficiently heat a room. In addition, at irregular distribution of the heating surfaces an even heat distribution in the heating room not guaranteed. For these reasons there can be wallpaper heaters don't enforce.

In order to air-condition and evenly heat an interior, an older application with the file number DE 195 38 686 proposed a large-area heating system with an electrically conductive heating layer covering the inner walls surrounding the room, which consists of a mixture of graphite particles and a hardenable binder such as water glass, and has an area power of 20 W / m ² to 40 W / m ² . This electrically conductive heating layer, which is additionally characterized in DE 24 20 098 A1, is inexpensive and can be produced on the spot with adaptation to the local conditions. Expensive protective measures can be avoided if the large area heating is operated with protective extra-low voltage and a surface temperature that is only slightly above the temperature of the room to be heated.

The disadvantage of using water glass is that by reacting sodium water glass is obtained with the carbon dioxide contained in the atmosphere sodium carbonate, the is very hygroscopic. Sodium carbonate can contain up to 10% water in bright rooms tie without looking damp. Increased with an increasing moisture content therefore the conductivity between the electrodes and the performance of the electrical conductive heating layer decreases. On cold days and in high humidity as a result, a long flow of heating and a higher current when heating required. Accordingly, the effort for the line cross sections and the Production of the heating layer, which, moreover, is difficult without great performance Heat loss can be regulated and controlled. The provision of a large heating output is reduced the economy because at a higher surface temperature part of the generated Heat can be lost. To low electrical connection values for air conditioning To achieve a room, the heating must be as stable as possible if it is used accordingly lower surface temperatures are required to prevent the heater depending on Heat demand must work in the "Stop and go" mode.

In addition, the operating costs of an electric heater are even more important than that Acquisition price when installing the system. If an electrical heat source than Continuous heating is to be operated, the limits for economy are Comparison with a heating system with fossil fuels with a connected load of approx 4000 watts. For this reason, to keep energy costs low, they are low Connection values and also good thermal insulation are necessary.

In order to generate heat inexpensively, the invention aims at an electrical one Low temperature heating system with a low surface temperature of the electric conductive heating layer, in which the constant on and off depending on the heat demand in Space is avoidable.  

According to the invention, the object is achieved by a covering of the electrical heating layer diatherme or infrared-emitting surface protection layer against Released air humidity, which prevents that existing in a room Humidity can be absorbed by the sodium carbonate or the heating layer. As a result, the conductivity of the electrically conductive heating layer remains constant and can are designed to be lower in accordance with the actually calculated resistance values. As a result, the heater can respond immediately, even in damp or cold weather.

According to a preferred embodiment of the invention, the electrically conductive Heating layer is composed of cement, fiber cement or glass fiber cement Surface protective layer, which is applied in a layer thickness of 1-3 mm and smoothed becomes. The glass fiber cement layer also has a large heat storage capacity with which the heat generated in the heating layer can be stored over a long period of time. In this way, the surface protection layer is particularly good for a low-energy house suitable. In addition, a cement layer has one with respect to infrared heat rays radiation-intensive surface that is comparable to the radiation of a black body is.

If the effect of the heating is to be achieved immediately after switching on, a infrared-emitting paint can be used as a surface protective layer. After a a further embodiment of the invention, the surface protective layer can be provided by a diatherme, water-resistant Keimsche mineral paint are formed, which as a binder contains aqueous potassium water glass solution. The water glass reacts with formation water-insoluble silicates, which gives a hard, light-fast coating. For The mineral paint is made exclusively from potash water glass with water glass-fastness Pigments such as titanium dioxide, chromium dioxide, iron oxide or cobalt pigments are used. The Layer thickness of the surface protective layer can be carried out in the micrometer range and for transparent infrared rays. The heat storage capacity is low, so the heat when the heater is switched off, it can cease as quickly as it occurred. Thereby the period of use can be determined carefully and a lot of energy saved.

It is particularly advantageous that the ambient air temperature in the heat waves from the electrically conductive heating layer outgoing, 3 ° C higher than with a  different kind of heat effect, so that the room temperature and the surface temperature of the Heating layer can be kept lower, without the well-being is restricted.

The heating capacity can be operated in the short or long term with a lower heating capacity depending on the needs and the use of the room. In order to increase the economy of the heating system, it is provided according to a further embodiment of the invention that the electrically conductive heating layer has a heating power of 1 W / m ² to 30 watts / m ² and thermal insulation made of polyurethane foam on the back of the heating layer.

A further increase in profitability can be achieved in that the Low-temperature heating system on at least two parallel to each other Wall surfaces an electrically conductive heating layer with connection electrodes and at least a wall or Floor surface has a storage heater, which with a special agreement of the EVU for Storage of heat with inexpensive nighttime electricity is rechargeable.

The EVU grant a cheap heating of a storage heater for a certain Release period predominantly in the low-load period, i.e. predominantly at night, one Night electricity tariff for more even utilization of the energy supply systems when the Connection cross sections in a local network are provided for this. The prerequisite is that the Storage heater is attached to the structure and firmly connected. For storing As a result, according to a further embodiment of the invention, heat is a Underfloor heating or a flat one, in an alcove of an outer wall with a Heat insulation built-in storage heater useful, which is in the following in one Embodiment and will be explained in more detail with reference to drawings. Further expedient embodiments of the invention result from the subclaims of Invention.

In the drawings belonging to the embodiment shows

Fig. 1 shows the inside view of a to be heated inside the room,

Fig. 2 shows a cross section through an electrically conductive heating layer on a side wall with insulation,

Fig. 3 shows a cross section through a storage floor heating with a heated screed,

Fig. 4 shows a cross section through an outer wall at the level of a niche with a storage heater and

Fig. 5 shows a cross section through a latent heat accumulator that can be heated with an electrically conductive heating layer.

Fig. 1 shows a highly schematic view of the inside of a room to be heated with a solid side wall 1 and a side wall 2 arranged parallel to it, which is partially recognizable and completely like the side wall 1 with an electrically conductive heating layer 3 between two current supply electrodes 4 at the level of the ceiling edge 5 and the floor edge 6 is covered. From the power supply electrodes 4 , connecting lines 7 go to a power supply circuit 8 , which is known per se and is not shown in detail. The electrically conductive heating layer 3 belonging to the low-temperature heating system covers the side wall 1 over a large area or is formed from individual plate-shaped heating segments 9 indicated by dash-dotted lines, which are cut according to the height of the side wall 1 and connected in parallel in a horizontal or vertical arrangement and connected to a power supply circuit 8 are. In addition, the electrically conductive heating layer 3 can be provided for heating the floor 10 .

The heating layer 3 can be seen in cross section in FIG. 2. It comprises thermal insulation and, furthermore, a multilayer composite building board with a heat-insulating core layer 11 made of rigid foam, preferably made of polyurethane, which has 30% higher thermal insulation than a comparable foam, and for reinforcement at least one front panel 12 reinforced with fibers and optionally one Back plate 13 made of an inorganic hydraulic binder composition, preferably glass fiber cement. The wall thickness of the core layer 11 is 1 to 5 cm and that of the front plate 12 and the back plate 13 1-5 mm. The front of the front plate 12 is smoothed and provided for the application of the electrically conductive heating layer 3 . Glass fiber cement is preferably used to reinforce the core layer 11, which can penetrate into the pore-containing surface of the foam structure when applied in the moist state and can firmly join with the thermal insulation layer in the background during curing. This creates a durable layered composite that can meet the thermal stresses of heating.

The electrically conductive heating layer 3 , which is applied to the side walls 1 , 2 , requires a current supply electrode 4 on the upper ceiling edge 5 , which is made depending on the expected current strength from a metal strip, from a metal foil or from a strip of a metal paint if the surface heating output should be chosen lower. A second power supply electrode 4 is arranged at the level of the floor edge 6 parallel to the upper power supply electrode 4 . Both power supply electrodes 4 are provided at the ends with connecting lines 7 , which are led to a transformer 8 with protective low voltage.

An electrically conductive heating layer 3 , which is composed of a mixture based on carbon, graphite particles or carbon fibers with a water-dilutable binder in the form of water glass, is applied to the enclosed area between the parallel-spaced power supply electrodes 4 . Alkali silicates, namely sodium water glasses or potassium water glass, can be used as the water glass. Based on the initial volume, the mixing ratio of graphite particles to water glass is 1: 1 to 3: 1, in which a very easily spreadable mass is formed, with which the front of the front plate 12 can be coated with a single application.

After curing, the outside of the heating layer 3 is completely coated with a diathermic or infrared-emitting surface protection layer 14 against atmospheric moisture. For this purpose, a surface protective layer 14 made of cement or glass fiber cement is provided, which is applied in a layer thickness of 1-3 mm. Instead of the cement layer or in addition to it, an infrared-emitting paint can be used as the surface protective layer 14 . In addition, the cement layer can be replaced by a diathermy water-resistant Keim mineral paint, which contains an aqueous potassium water glass solution as a binder. The water glass reacts to form water-insoluble silicates, which gives a hard, light-fast coating. For the production of the mineral color, only potash water glass with pigments suitable for water glass such as titanium dioxide, chromium dioxide, iron oxide or cobalt pigments is used.

In this way, a heat radiation field in the infrared range can be produced between the side walls 1 , 2 , in which ventilation heat losses can only occur to a small extent. In continuous operation, the heating power of the electrically conductive heating layer 3 can consequently be reduced to a heating power of 1 W / m ² to 30 W / m ² .

Furthermore, the heating layer 3 provided on the wall surfaces can be designed as additional heating and can interact with a radiation or convection heating in the form of a storage heating 15 , which can be charged with a special agreement of the power supply company for storing heat with inexpensive night-time electricity. The storage heater 15 is preferably arranged in a plane perpendicular to the side walls 1 , 2 in order to optimize the heat radiation. Radiant heating can be implemented as a floor storage heater 16 , which is shown in cross section in FIG. 3.

The floor storage heater 16 comprises, analogously to the arrangement of the heating layer 3 on the side walls 1 , 2, a multi-layer composite building board with a core layer 11 of rigid polyurethane foam for thermal and impact sound insulation, and optionally for reinforcement, a fiber-reinforced backing plate 13 and a supporting plate 17 made of glass fiber cement. The electrically conductive heating layer 3 or any resistance heating is embedded in a screed layer 18 . The wall thickness of the core layer 11 is 1 to 5 cm and that of the back plate 13 and the support plate 17 1-5 mm. When designing the underfloor heating 16 , it should be noted that a specific room heating output of maximum 70 W / m ^{2 is} maintained. This value results from the temperature difference between the room temperature and the surface temperature of the floor, which must not exceed 24 ° C. By using rigid polyurethane foam in combination with glass fiber cement, it can also be ensured that the heat transfer coefficient downwards is significantly smaller than upwards. The thickness of the insulation layer is thereby reduced, in favor of a thicker screed layer 18 or heat storage layer in which the heating layer 3 is embedded. The heating power of the screed layer 18 can thereby be increased to the room height without any negative consequences.

Instead of or in addition to a floor storage heater 16 , a fixed storage heater 15 can be used on the front side 20 of the room according to FIG. 4, which can be inserted into a recess 22 of an outer wall 23 with space gain. Known commercially available storage heaters or plate-shaped storage elements with an intermediate resistance heater can be used for the storage heater 15 . These can have storage plates made of concrete, magnesite, soapstone, olefin or the like, which are provided with a heat-insulating jacket 24 and with a controllable air outlet opening 25 for regulating the heating of the room. These components are customary in the trade and for this reason are not described further.

A particularly inexpensive embodiment of a plate-shaped storage heater 15 consists of two concrete plates 23 with an electrically conductive heating layer 3 between them made of carbon or graphite particles and water glass as a binder. The storage heater 15 can be made on the spot and fitted into the outer wall 21 . However, the storage heater 15 should not be restricted to plate-shaped storage elements. In their place, flowable heat storage masses in the form of salts or latent heat storage means or liquids such as water or oil can likewise be used in a storage container 27 . Suitable latent heat storage means have a higher heat capacity if they use the enthalpy of conversion between the reversible phase transitions between solid-liquid-solid.

A storage container 27 with a latent heat storage means 28 can be covered according to FIG. 5 by an electrically conductive heating layer 3 , which consists of a mixture based on carbon-graphite particles or carbon fibers and water glass as a binder. The heat storage element can have a container-shaped or shell-shaped construction, in which the container wall 26 consists of glass fiber concrete. This is correspondingly coated on the inside or outside with the electrically conductive heating layer 3 and provided with current supply electrodes 4 . The advantage of a built-in storage heater 15 in the proposed manner, which can be produced over a large area and can be operated in combination with a low-temperature heater on the side walls 1 , 2 , consists in addition to the low energy costs when utilizing the night power in the second place, that for the Storage heater 15 lower connection values with longer release times are required. As a result, there is the possibility that an area-wide supply with cheap night-time electricity can be achieved without increasing the cross-sections of the supply lines in a local network.

Claims (10)

1.Electric low-temperature heating system for interiors, with a resistance heater which has an electrically conductive heating layer which is provided with electrodes and which completely or partially covers the interior surfaces surrounding the room and which consists of a mixture based on graphite particles, carbon or carbon fibers and a hardenable binder such as Water glass is composed, characterized in that the electrically conductive heating layer ( 3 ) is covered on the outside with a diathermic or infrared-emitting surface protection layer ( 14 ) against atmospheric moisture and on the back with thermal insulation. 2. Electric low-temperature heating system for interiors according to claim 1, characterized in that the surface protective layer ( 14 ) has a fiber-reinforced hydraulic binder composition, such as cement, fiber cement or glass fiber cement, which is applied and smoothed in a layer thickness of 1-3 mm. 3. Electric low-temperature heating system for interiors according to claim 1 to 2, characterized in that an infrared-emitting paint, a diathermic or water-resistant Keim's mineral paint is used as the surface protective layer ( 14 ) as an binder, an aqueous potassium water glass solution with water glass pigments such as titanium dioxide, Contains chromium dioxide, iron oxide or cobalt pigments. 4. Electrical low-temperature heating system for interiors, characterized in that the electrically conductive heating layer ( 3 ) has a heating power of 1 W / m ² to 30 watts / m ² and thermal insulation on the back. 5. Electrical low-temperature heating system for interiors according to one or more of claims 1 to 4, characterized in that the thermal insulation in composite construction comprises a multilayer composite building board with a 1 to 5 cm thick, heat-insulating core layer ( 11 ) made of rigid foam, preferably made of polyurethane , and for reinforcement at least one fiber-reinforced front plate ( 12 ) and optionally a back plate ( 13 ) made of an inorganic hydraulic binder composition, such as preferably fiber cement or glass fiber cement, which is applied wet in a layer thickness of 1-5 mm and on the front of the front plate ( 12 ) is smoothed. 6. Electrical low-temperature heating system for interiors according to one or more of claims 1 to 5, characterized in that at least one electrically conductive, the room-encompassing inner walls ( 1 , 2 ) or a floor ( 10 ) covering heating layer ( 3 ) formed as additional heating and is combined with a storage heater ( 15 ) which can be charged with a special agreement of the utility company for storing heat with inexpensive night-time electricity. 7. Electrical low-temperature heating system for interiors according to one or more of claims 1 to 6, characterized in that on two mutually parallel wall surfaces ( 1 , 2 ) each have an electrically conductive heating layer ( 3 ) with separate connection electrodes ( 4 ) and at least a storage heater ( 15 ) or underfloor storage heater ( 16 ) is provided on a wall or floor surface standing at right angles or in between; 8. Electrical low-temperature heating system for interiors according to one or more of claims 1 to 7, characterized in that the underfloor heating ( 16 ) has a screed layer ( 18 ) which can be heated with an embedded resistance heater and has a specific space heating capacity of at most 70 W / m ² , where For heat and sound insulation, a multi-layer composite building board with a 1-5 cm thick core layer ( 11 ) made of rigid polyurethane foam is provided, which for reinforcement with a fiber-reinforced back plate ( 13 ) and support plate ( 17 ) with a thickness of 1-5 mm and is provided with a hydraulic binder composition such as cement or glass fiber cement. 9. Electrical low-temperature heating system for interiors according to one or more of claims 1 to 8, characterized in that the storage heater ( 15 ) plate-shaped, on the front side ( 20 ) of a room with space gain in a recess ( 22 ) of an outer wall ( 21 ) insertable storage elements ( 23 ) made of concrete, magnesite, soapstone, Olevin or the like with an intermediate resistance heater, in particular an electrically conductive heating layer ( 3 ). 10. Electric low-temperature heating system for interiors according to one or more of claims 1 to 9, characterized in that the storage heater ( 15 ) flowable heat storage means in the form of salts or latent wall storage means ( 28 ) or liquids such as water or oil in a storage tank made with glass fiber cement ( 27 ), which is coated with an electrically conductive heating layer ( 3 ) based on carbon-graphite particles or carbon fibers and water glass as a binder.