DE20308574U1 - Heater unit for generation of infrared radiation for area heating has radiation element consisting filler and strengthening materials and electrically conductive powder mixture - Google Patents

Abstract

The heater unit for generation of infrared radiation for area heating comprises a radiation element consisting filler and strengthening materials (29 - 51 %) and an electrically conductive powder mixture (49 - 71 %). The powder mixture contains graphite, soot, metal oxide compounds and reticulation or dispersion additives.

Description

Service Group GmbH 28 May 2003

Am Kalkhügel 26
99706 Sondershausen

Description

Radiators for electric surface heaters

The invention relates to a radiator for electric surface heaters for generating infrared radiation in closed and partially closed rooms as well as outdoors and their construction designs.

According to DE 100 20 489 C2 (addition to DE 100 08 999), a flat resistance heating element with at least one electrically operated heating resistor for generating heat is known, whereby the or each heating resistor is designed as a heating mat operated with low voltage. This heating mat has carbon atoms linked together in a graphite-like manner. These solutions are designed as heaters for special applications, such as mattress, seat or mobile underfloor heating. This heater gives off heat to the environment.

Furthermore, an electric interior heater for caravans is known from DE 196 47 935 A1. This interior heater essentially comprises a large-area resistance heater covering the interior walls enclosing the room, which has an electrically conductive heating layer as a resistance heating element, which 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 safety extra-low voltage. The resistance heater has a composite construction with at least one thermal insulation layer and an electrically insulating carrier layer with increased strength, which is coated with the heating layer, consisting of a mixture of mixed with a hardenable binding agent.

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Carbon, graphite particles and/or carbon fibers. The components of this heating layer are simply mixed.

The wall is heated, which allows high heat losses to the outside and remains unpredictable on the inside. Heating the wall as a heat carrier is dangerous; regulation/control and safety shutdown are not shown. There is also no information about the temperature hazards when heating the wall. The effect is that of a normal resistance heater, where the wall serves as a heat carrier and convection heat is generated with around 95% pure resistance heat.

According to DE 202 02 810 U1, an electric panel heater with a heatable cover layer is known, which consists of a front plate made of natural stone or similar materials with a flat back. A carrier plate is arranged on this back. Both elements are attached to a wall using a bracket. The carrier plate is made of non-conductive material with a low coefficient of thermal expansion, such as glass and ceramic, and has a heatable cover layer. This cover layer consists of a conductive material or a semiconductor material. When the panel heater is operated, the cover layer heats up when current is applied and releases this heat to the environment, preferably over the entire surface, via the cover layer. This panel heater is a resistance heater consisting of separate layers, which releases its power - through the heated radiator - in the range of approx. 95% as heat.

According to DE 195 38 686 A1, a plate-shaped electrical resistance heater for air conditioning in apartments and buildings is known, the electrically conductive heating layer of which can be heated by electricity and consists of a mixture based on graphite particles and a water glass that can be diluted with water as a binding agent. Metallic strip-shaped current supply electrodes are provided on two parallel opposite sides of the heating layer. The mixture can be applied directly to a moisture-absorbing carrier plate by painting, spraying, screen printing or the like. The carrier plate is formed by a conventional plasterboard suitable for interior construction and provided with a thermal insulation layer on the back. According to DE 196 00 228 A1, a composite building board provided with a thermal insulation material on the back is used instead of a plasterboard.

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Use that is coated on its visible side with a building board made of plaster, cement, ceramic masses, concrete, artificial stone or similar masses commonly used in construction, glass, wood, synthetic resin or plastic masses. These solutions are also resistance heaters that heat themselves and then release the heat into the environment.

Because they generate primarily intensive convection heat, these heaters have a high nominal power consumption of 750 watts to even 3000 watts, which results in very high electricity costs as well as air and dust movements and air drying phenomena in the rooms to be heated.

According to DE 34 37 397 A1, a radiation source for infrared radiation with a surface radiator and an electrically conductive resistance layer is known, whereby the surface radiator and the resistance layer are arranged on a carrier substrate. The heat capacity of the radiation source should be reduced to such an extent that a modulation of the intensity of the radiation sources with sufficiently high frequencies is possible. For this purpose, the resistance layer is applied in a thinned area of the carrier substrate.

With this solution, heat radiation occurs primarily as direct radiation. Room heating only occurs during operation. This means that no heat is stored.

No electrically conductive resistance layer is disclosed in this solution. The room heating only occurs in the operating state. No surrounding materials are heated as storage.

The object of the invention is to create a radiator for infrared radiant heating which, in relation to one another, predominantly generates direct heat radiation as infrared radiation, heats up less than previous radiators and radiates the entire surface onto the bodies and objects in the room and achieves sustainable heating.

According to the invention, this is achieved by the features described in claim 1. Advantageous embodiments of the invention are described in claims 2 to 11.

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The core idea of the invention is that the radiation mass consists of 29 to 51% filler and solidifying agent and 49 to 71% of an electrically conductive powder mixture. The filler and solidifying agent is composed of PU glue and/or melamine glue and/or bone glue and/or water glass and/or alkyd resin emulsion and/or gypsum and/or cement and/or clay and/or loam and/or epoxy resin and/or PVC and/or wood sawdust, sawdust and/or silica and/or quartz powder in the grain size range of 1 μm to 100 μm . The electrically conductive powder mixture consists of 60 to 90% graphite, 3.3 to 39.99% carbon black, 0.01 to 23.7% metal oxide compounds and 0.1 to 5% of a wetting or dispersing additive. In the fluid stage, the radiation mass can be aligned in a dipole-like manner by means of ultrasound, tempering and in an electric and/or magnetic field. Due to its composition, the radiation mass has the ability to generate infrared radiation in the spectral range from 800 nm to 10,000 nm.
The infrared radiation reaches at least 25% and the thermal radiation a maximum of 75%.

The heat is generated primarily on the carrier material and in the electrically conductive coating, the radiant mass. This creates convection heat and thermal radiation. The infrared radiation is generated and emitted exclusively by the electrically conductive radiant mass.
This so-called suppression of convection heat by increasing the infrared efficiency creates an allergy-friendly room climate, which is created by the infrared heat waves heating up the objects in the room, such as furniture and walls. These become heat stores and in turn heat the air in the room in question evenly without a high convection effect. The effect on humans and animals is analogous to the sunlamp without the UV component.

The lasting effect is created by the mass charge in the objects and in the walls.

The heater operates in the voltage ranges of 1 to 500 V (volts) direct and alternating current and the current ranges of 0.001 to 50 A (amperes), phase control and section control, packet control, square waves from 50 Hz to 50 kHz with pulse widths of 10 to 90%. It has the size of 1 cm ² to 4 m ² arranged in series and/or in parallel.

The control is done via an electronic manual and/or remote control. The heater can be manufactured with or without a frame.

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It is advantageous that radiation bodies emit infrared radiation in different spectral ranges, for example in the range from 800 nm to 1200 nm or 800 nm to 2500 nm (10,000 nm), depending on requirements. This is achieved by changes in the configuration of the radiation mass and/or by structural arrangement of the radiation bodies and their components in relation to one another.

The segment arrangement enables the individual adjustment of different area-related infrared radiation ranges.

The invention is explained in more detail below using exemplary embodiments. The accompanying drawings show:

Figure 1: Basic structure of a radiator according to a first embodiment in exploded view

Figure 2: Radiator view with stand
Figure 3: Arrangement variant of radiators, rear sides arranged to each other

Figure 4: Arrangement variant of radiators, front sides arranged to each other

Figure 5: Sectional view of a radiator according to a second embodiment

Figure 6: Sectional view of a radiator according to a variant of the second embodiment

Figure 7: Sectional view of a radiator according to a variant of the second embodiment

Figure 8: Sectional view of a radiator according to a variant of the second embodiment

Figure 9: Basic structure of a radiator according to Figures 6 and 8 in exploded view

Figure 10: Individual representation of the radiation body

The radiator for electric surface heaters for generating infrared radiation in closed and partially closed rooms as well as outdoors consists, according to a first embodiment, of a carrier material 2 coated with radiation mass 5 with a phase connection 6, an insulating material 3 and a rear cover plate 4, which can be surrounded by a frame 1 and are provided with at least one suspension device 10. The radiation mass 5 is

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applied to a carrier material 2 with a layer thickness of one micrometer to five mm by vapor deposition, gluing or by spraying onto the back and/or front of the carrier material 2.

The smooth front side of the carrier material 2 is preferably laminated with foils, photos or images.

The carrier material 2 for the radiation mass 5 (coating material) for generating infrared radiation consists of glass, single or multiple pane safety glass, in a smooth design or with an ornamental pattern, or of a non-combustible fiberboard, made of ceramic or stoneware on whose back and/or front side and/or between two identical or different materials mentioned above (e.g. ceramic coating material-glass) is applied or inserted.

According to a second embodiment, the radiator consists of a front plate 9, a radiator body 8 consisting solely of the radiant mass 5, an insulating material 3 and a rear cover plate 4, which can be surrounded by a frame 1 and have at least one suspension device 10.

The radiation mass 5 consists of 29 to 51% filler and solidifying agent and 49 to 71% of an electrically conductive powder mixture. The filler and solidifying agent is composed of PU glue and/or melamine glue and/or bone glue and/or water glass and/or alkyd resin emulsion and/or gypsum and/or cement and/or clay and/or loam and/or epoxy resin and/or PVC and/or wood sawdust, sawdust and/or silica and/or quartz powder in the grain size range of 1 pm to 100 pm. The electrically conductive powder mixture consists of 60 to 90% graphite, 3.3 to 39.99% carbon black, 0.01 to 23.7% metal oxide compounds and 0.1 to 5% of a wetting or dispersing additive. The radiation mass 5 can be aligned in a dipole-like manner in the fluid stage by ultrasound, tempering and in the electric and/or magnetic field.
The radiation panels have an area of 1 cm ² to 4 m ² and a thickness of 0.32 [im to 10.6 mm.

Due to its composition, the radiation mass 5 has the ability to generate infrared radiation in the spectral range from 800 nm to 10,000 nm.

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The infrared radiation should be at least 25% and the thermal radiation a maximum of 75%. The heat is generated primarily on the carrier material 2 and in the electrically conductive coating, the radiation mass 5. This creates convection heat and thermal radiation. The infrared radiation is generated and emitted exclusively by the electrically conductive radiation mass 5.

This so-called suppression of convection heat by increasing the infrared efficiency creates an allergy-friendly room climate, which is created by the infrared heat waves heating the objects in the room, such as furniture and walls. These become heat stores and in turn heat the air in the room in question evenly without a high convection effect. The effect on humans and animals is similar to the sun lamp without the UV component. The lasting effect is created by the mass charge in the objects and in the walls.

Furthermore, the radiation mass 5 can be formed in the radiation body 8 or on the carrier layer 2 in an entire surface, in the same or different geometric arrangements, individually or in several different or identical segments. The phase connections 6 for the surfaces or segments during the production of the carrier material 2 or radiation body 8 are rolled on, glued on, sprayed on, printed on or vapor-deposited.

If a frame is provided, it is made of an aluminum alloy, wood, glass, plaster, plastic, wood fiber or laminated materials. The insulating material 3 is made of non-combustible insulating materials. The seal 4 on the rear side is made of a non-combustible metallic or non-metallic material.

For radiation on both sides, the radiator consists, as shown in Figures 6 and 8, of a radiation body 8 on which front panels 9 are arranged on both sides, which are preferably surrounded by a frame 1 and have a mounting device 7 and/or suspension device 10.

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Also according to Figure 7, the front plate 9, the radiation body 8, the insulating material 3 and the rear cover plate 4 are arranged at a distance from each other by a flat gap of 0.1 cm to 400 cm.

Likewise, the radiation body 8 and the front plate 9 according to the second embodiment can be arranged at a distance from each other by a flat gap of 0.1 cm to 400 cm.

According to the invention, the heater operates in the voltage ranges of 1 to 500 V (volts) direct and alternating current and the current ranges of 0.001 to 50 A (amperes), phase control and section control, packet control, square waves from 50 Hz to 50 kHz with pulse widths of 10 to 90%. It has the size of 1 cm ² to 4 m ² arranged in series and/or in parallel.

The control is carried out via an electronic manual and/or remote control. The heater can be manufactured with or without frame 1.

The heater is mounted on walls, ceilings and in or on the floor. Installation on a flat surface is made possible with a mounting device 7.

The panel radiators can be installed individually or in multiples next to each other or one behind the other with radiation in the same direction and/or to each other or opposite to each other, as shown in Figures 3 and 4.
The segment arrangement enables the individual adjustment of different area-related infrared radiation ranges.

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List of reference symbols used:

1 frame

2 Carrier material 3 Insulating material

4 Cover plate

5 Radiation mass

6 phase connection

7 Installation device 8 Radiation body

9 Front panel

10 Suspension device

Claims (11)

1. Radiator for electric surface heaters for generating infrared radiation in closed and partially closed rooms as well as outdoors, which consists of several plate-shaped layers of different materials and has a heating layer consisting of a mixture with graphite particles and provided with phase connections, characterized in that instead of the heating layer a radiation mass ( 5 ) is used which consists of 29 to 51% filler and solidifying agent and 49 to 71% of an electrically conductive powder mixture, wherein the filler and solidifying agent consists of PU glue and/or melamine glue and/or bone glue and/or water glass and/or alkyd resin emulsion and/or gypsum and/or cement and/or clay and/or loam and/or epoxy resin and/or PVC and/or wood sawdust, sawdust and/or silica and/or quartz powder in the grain size range from 1 µm to 100 µm and the electrically conductive powder mixture consists of 60 to 90% graphite, 3.3 to 39.99% carbon black, 0.01 to 23.7% metal oxide compounds and 0.1 to 5% of a wetting or dispersing additive. 2. Radiator for electric surface heaters according to claim 1, characterized in that the radiant mass ( 5 ) can be aligned in a dipole-like manner in the fluid stage by ultrasound, tempering and in the electric and/or magnetic field. 3. Radiator for electric surface heaters according to claims 1 and 2, characterized in that the radiant mass ( 5 ) is simultaneously designed as a radiant body ( 8 ). 4. Radiator for electric surface heaters according to claims 1 and 2, characterized in that the radiant mass ( 5 ) is applied to a carrier material ( 2 ) with a layer thickness of one micrometer to five millimeters by vapor deposition, gluing or by spraying onto the back and/or front of the carrier material ( 2 ). 5. Radiator for electric surface heaters according to one or more of the preceding claims, characterized in that the radiant mass ( 5 ) can be formed in a whole surface, in identical or different arrangements, individually or in several different or identical segments. 6. Radiator for electric surface heaters according to one or more of the preceding claims, characterized in that the phase connections ( 6 ) for the surfaces or segments can be rolled on, glued on, sprayed on, printed on or vapor-deposited during the manufacture of the carrier material ( 2 ) and/or radiation body ( 5 ). 7. Radiator for electric surface heaters according to one or more of the preceding claims, characterized in that the radiator consists of a carrier material ( 2 ) coated with the radiant mass ( 5 ), preferably a glass pane, an insulating material ( 3 ) and a rear cover plate ( 4 ), which can be surrounded by a frame ( 1 ) and has at least one suspension device ( 10 ). 8. Radiator for electric surface heaters according to one or more of the preceding claims, characterized in that the radiator consists of a front plate ( 9 ), a radiation body ( 8 ), an insulating material ( 3 ) and a rear cover plate ( 4 ), which can be surrounded by a frame ( 1 ) and has at least one suspension device ( 10 ). 9. Radiator for electric surface heaters according to one or more of the preceding claims, characterized in that the radiator for radiation on both sides consists of a radiation body ( 8 ) on which front panels ( 9 ) are arranged on both sides, which can be surrounded by a frame ( 1 ) and has a mounting ( 7 ) and/or suspension device ( 10 ). 10. Radiator for electric surface heaters according to one or more of the preceding claims, characterized in that the front plate ( 9 ), the radiation body ( 8 ), the insulating material ( 3 ) and the rear cover plate ( 4 ) are arranged at a distance from one another by a flat gap of 0.1 cm to 400 cm. 11. Radiator for electric surface heaters according to one or more of the preceding claims, characterized in that the radiation body ( 8 ) and the front plate ( 9 ) are arranged at a distance from one another by a flat gap of 0.1 cm to 400 cm.