AT515858A1 - Infrared radiant heating - Google Patents

Abstract

The invention relates to an infrared radiation heater consisting of a plate-shaped radiator, in which heat carrier lines are arranged, wherein the power supply to the heat carrier lines is controlled by a thermostat circuit. In order to homogenize the radiation over the entire radiation surface, the heat transfer lines (3) in a thermal storage mass (7) include, which forms the radiation surface or is covered by a radiation-conducting plate (1) under full-surface contact, wherein on the side facing away from the radiation surface, the thermal storage mass (7) a cover of a thermal insulation material (11) is provided.

Description

DIPL ING. PETER ITZE 1060 WIEN, AMERLINGSTRASSE 8 CHWALLAGASSE 4

description

The invention relates to an infrared radiation heater consisting of a plate-shaped radiator in which heat carrier lines are arranged, wherein the energy supply to the heat carrier lines is controlled by a thermostat circuit.

Self-regulating infrared radiators are already known which deliver heat to a glass or metal body via heating foils or heating cables. These are glued to the inside of the front and then release the heat through the contact points of the film or cables to the surface. These have a maximum temperature oriented at the ambient temperature, the higher the room temperature is also producing a higher temperature.

A disadvantage of these known systems is that the heating conductors must be adapted to the maximum radiation temperature and can come very slowly to their operating temperature in very cold rooms. Since a temperature difference of 80 ° C to the existing room temperature is prescribed, these heating conductors can only produce a surface temperature of 80 ° C at room temperature of 0 ° C and this temperature is at the lower end of the efficient perceptible infrared radiation. However, this must be taken into account, as e.g. Otherwise, a permissible surface temperature of 120 ° C can be exceeded at a very high room temperature of 40 ° C. Furthermore, systems with a temperature boost function are known, wherein in the starting area, the heating conductors are deliberately overloaded to produce a stronger wattage. This is to be rejected because of the overload and the resulting increased power consumption.

From DE 102009020326 Al a Elektroflachheizkörper with short-wave infrared radiation can be removed, in which on a ceramic support plate heating resistors are mounted serpentine, which are covered on the side facing away from the ceramic plate by a heat reflector. Between the heating resistors are mounted infrared A heating elements, wherein heating elements are provided in a hollow body which forms the outer part of the in-infrared A heating element.

It is in this known training to a conventional ceramic electric heater, in which additional infrared A heating elements are provided, the heat rays predominantly having a wavelength between 0.75 microns and 1.4 microns.

According to EP 0211491 Bl a relatively thin ceramic plate is provided, which is profiled the formation of grooves on the back, wherein in these grooves on the backside heating coil are inserted, wherein the free space are filled around the heating coil with heat-resistant material under cover of the heating coil , The purpose of this design is that due to the thin ceramic plate, the heat of the heating coil can be blasted relatively quickly, with a heat-resistant insulating plate is attached to the back of the ceramic plate. The entire radiator is surrounded on the back by a metal housing to which the suspension organs are attached. In this embodiment, the radiation distribution over the surface is very uneven because the high temperatures mainly in the region of the contacts between the heating coil and the ceramic plate.

The invention is based on the object to produce an infrared heater, which emits the radiation uniformly over its entire radiation surface and has in corresponding storage capacity for a tight timing of the current application.

According to the invention, this object is achieved in that the heat carrier lines are enclosed in a temperature storage mass which forms the radiation surface or is covered by a radiation-conducting plate under full-surface contact, wherein on the side facing away from the radiation surface of the thermal storage mass a cover is provided from a thermal insulation material. This ensures that, on the one hand, the surface temperature of the radiation surface is essentially the same over the entire surface and, on the other hand, heat is stored in the storage mass, which is emitted when the energy supply is switched off via the radiation surface until a predetermined limit value has been reached.

Advantageously, the radiation-conducting plate can be bent back at the edges around the thermo-memory mass to the back in a U-shape, which ensures that an all-sided inclusion of the thermal storage mass is given. In this case, the thermal storage mass in the bent-back region can be curved toward the rear, which ensures that the edge regions of the radiation-conducting plate can also serve for emitting the thermal radiation. For a universally applicable infrared radiation heating plate can be arranged on the side facing away from the radiation surface of the thermal storage mass a cooling unit, which gives the possibility to use the heating plates in summer as cooling elements. In order to prevent unwanted radiation of radiant energy on the side facing away from the radiation surface, the plate-shaped radiator may be covered at its the radiant surface from facing surface with a retroreflective film and / or an infrared return wall. For the control can be arranged on the thermal storage mass or the Inffarotrückstrahlwand a temperature sensor for determining the temperature of the radiation surface. This makes it possible to carry out a brief pulsed application of energy, whereby a substantially uniform temperature of the radiation surface is made possible.

In a particularly advantageous embodiment, the heat carrier lines may be formed as electrical resistance heating cable, which can be acted upon in response to the determined temperature of the radiation surface via a thermostat with power. For a very accurate control of the temperature of the radiation surface is possible.

Alternatively, the heat carrier lines may be formed as hot water lines, which can be acted upon by hot water according to the determined temperature of the radiation surface via a thermostatic valve. It is thus possible to connect the infrared radiation heating plate according to the invention to conventional heating systems which operate with a correspondingly higher temperature.

Particularly preferably, the temperature range of the radiation surface can be set in operation between 80 ° C and 120 ° C, in which area the best radiation effect is achieved. For plate-shaped radiators equipped with a cooling unit, condensate collecting devices can be provided, which ensures that, when the plate is operating in cooling mode, the condensate forming thereon can be specifically discharged.

In the drawing, exemplary embodiments of the subject invention are shown. Figure 1 shows partially pulled apart the structure of the application according to the invention infrared heater. FIG. 2 is a rear view in the diagram. FIG. 3 shows a vertical section through the heating plate according to the invention. Figure 4 is a representation analogous to Figure 3, but with additional cooling means. FIG. 5 likewise shows a view analogous to FIG. 3, but with differently arranged thermal insulation on the rear side. Figure 6 shows diagrammatically the structure of such a plate with collecting means for condensate. Figure 7 shows a cross section again, in which the plate is formed entirely of heat storage material, in which the heating cables are cast directly. FIG. 8 shows the temperature control in the form of a block diagram. Finally, FIG. 9 shows a dynamic temperature curve, as occurs on the surface of the radiation plate in the case of a heating plate controlled according to the invention.

The structure of the infrared radiation heating is first explained fundamentally on the basis of the schematic illustration in FIG. 1 denotes a radiation-conducting plate, on whose rear side heat carrier lines 2 are arranged, which are cast in a thermosensitive material 7. On the inside of the radiation-conducting plate 1, a thermocouple 4 is arranged, which is connected to a thermodynamic electronics 5 on the outside of the plate. At the rear of the infrared radiation heating system, an infrared return wall 8 is provided which covers the infrared radiation heating at the rear. The thermodynamic electronics 5 is disposed on the outside of the infrared return wall and enclosed by a housing cover 9. The current is applied via line 6, wherein the thermodynamic electronics is interposed between the line 6 and the heat carrier lines 3 and the power supply in response to the measured temperature of the temperature sensor 4 of the radiation-conducting plate 1 is controlled.

With 2 arranged on the outside of the infrared return wall suspension members are provided, which is as indicated in Figure 2, parallel to the plane of

Infrared Rückstrahlwand are rotatable. The suspension members 2 are formed by U-shaped bent tabs, which are rotatably mounted with a Schenkelwandung to the infrared return wall 8 and in the free leg wall 2 '.

Slits 2 ", which emanate from the free edge of the leg wall 24 and reach over the axis of rotation of the suspension member 2. To attach the infrared radiation heating plate this is pushed with the holding members 2 on suspension organs, the slots 2 "are pushed over the suspension organs. When all hangers are properly pushed onto the fasteners, the fasteners 2 of a row are rotated by 180 °, which then the slots 2 "facing each other and thus the brackets are enclosed in the mounting members 2 so that a sliding of the radiant heater 1 from the holding organs is prevented.

FIG. 3 shows a vertical section which shows the structure of the plate in detail. In the embodiment according to FIG. 3, the heat-conducting lines 3 are provided on the rear side of the radiation-conducting plate 1, which are completely cast in the thermal storage mass, wherein the thermal storage mass also in the edge region, in which the radiation-conducting plate 1 in a U-shape bent back in, is pulled in. Thus, a lateral radiation of heat energy is possible, as indicated by the arrows 13. At the back of the thermal storage mass 7, a plate of insulating material 11 is provided, which prevents the heat radiation to the back of the infrared radiation heating plate. The infrared return wall 8 is fastened to the U-shaped bent-back region of the radiation-conducting plate 1 by means of rivets 10. In the illustrated embodiment, in addition to the insulating material 11 on the infrared return wall also a return film 12 is provided, which does not heat radiation at the back of the infrared radiation heater according to the invention.

FIG. 4 shows an alternative embodiment analogous to FIG. 3, in which cooling units 14 are additionally provided on the rear side of the thermal storage mass 7 and in front of the panel of thermal insulation material 11, which allows the radiation-conducting panel to be switched off when the energy supply to the heat carrier lines 1 is switched off 1 to supply from the back with cooling energy, so that the infrared radiation heater according to the invention can also be used as an air conditioner in the summer.

FIG. 5 shows a modification of the embodiment according to FIG. 4 again, and thermal insulation material 11 is not arranged in front of the re-radiation film 12, but the infrared reverberation wall 8 is much more double-walled, with the thermal insulation material 11 being arranged between the two layers of the infrared reverberation wall 8. The return film 12 is attached directly to the inner wall of the infrared return wall 8.

FIG. 6 shows schematically a trough-shaped arrangement of two infrared radiation heating plates, the connecting edge between the two plates representing the lower region of the arrangement. The structure of the individual plates is analogous to those according to the above-described Ausföhrungsformen, wherein only the suspension is changed in that the suspension members 2 are mounted on supports 19. For each of the two sides separate thermodynamic electronics 5 are provided, which are covered by the housings 17 and 18. With 20 is designated a gutter, which serves to collect the condensate. In this gutter 20, a highly water-absorbing material may be provided, which can regenerate when drying back into the original shape or almost original shape.

In the embodiment according to FIG. 7, instead of the radiation-conducting plate 1, the thermal storage mass is selected such that it forms a self-supporting plate 15. Within this self-supporting plate 15 of thermal storage mass, a reinforcement 16 is provided, on which the heat carrier lines 3 are mounted. This reinforcement serves on the one hand for holding the heat carrier lines 3 during the pouring into the thermal storage material to obtain the plate 15 and on the other hand also to reinforce the plate 15 made of thermal storage material.

The radiation of the infrared radiation is again indicated by the arrows 13.

In the embodiment variants described above, the heat carrier lines 3 are designed as resistance heating wires, but hot water lines can also be provided in the same way, in which hot water circulates between 80 ° C and 120 ° C. The electrical resistance heating wires have the advantage that they are directly controllable via the thermodynamic electronics, whereas in the treated with hot water lines corresponding control valves, which are controlled via the thermodynamic electronics, must be provided.

In Figure 8, the schematic representation of the cooling and heating element control is shown as a block diagram. As can be seen in addition to the conventional room temperature sensor and the associated thermostat nor the controller 5 is provided which either cools or heats depending on the temperature. When cooling, the control is carried out in a conventional manner to the effect that via the room thermostat, the power supply and the switching of the cooling unit via the room thermostat.

In the heating circuit, in addition to the room thermostat even the thermodynamic electronics interposed, by means of which after obtaining the temperature sensor 4 detected temperature at the radiation transmitting plate 1 is a tightly timed temperature control, to the effect that when heat demand through the room thermostat, the power remains on, whereas thermodynamics takes over the switching cycles and switches them in relatively narrow temperature ranges. A typical thermodynamic temperature curve is shown in FIG. 9. This clocked in a narrow temperature range circuit is made possible by the use of the thermal storage mass 7, which slows down the heating somewhat but also slows down the cooling, whereby a more uniform temperature of the radiation surface is achieved and facilitates appropriate control.

Claims (10)

1.) Infrared radiation heating consisting of a plate-shaped radiator, in which heat carrier lines are arranged, wherein the energy supply to the heat carrier lines is controlled by a thermostat circuit, characterized in that the heat carrier lines (3) in a thermal storage mass (7) are included, which the radiation surface is formed or covered by a radiation-conducting plate (1) under full-surface contact, wherein on the side facing away from the radiation surface, the thermal storage mass (7) a cover of a thermal insulation material (11) is provided. 2.) Infrared radiation heater according to claim 1, characterized in that the radiation-conducting plate (1) is bent back at the edges around the thermal storage mass (7) to the rear in a U-shape. 3.) Infrared radiation heater according to claim 2, characterized in that the thermal storage mass (7) is curved in the rückgebogenem area towards the rear. 4.) Infrared radiation heater according to one of claims 1-3, characterized in that on the side facing away from the radiation surface of the thermal storage mass (7), a cooling unit (14) is arranged. 5.) Infrared radiation heater according to one of claims 1-4, characterized in that the plate-shaped heating element is covered on its surface facing away from the radiation surface with a return film (12) and / or an infrared return wall (8). 6.) infrared radiation heater according to any one of claims 1-5, characterized in that on the thermal storage mass (7) or the return wall (8), a thermal sensor for determining the temperature of the radiation surface is arranged. 7.) Infrared radiation heater according to claim 6, characterized in that the heat carrier lines (3) are designed as electrical Widerstandsheizkabel which are acted upon in dependence on the determined temperature of the radiation surface via a thermostat with power bar. 8.) infrared radiation heater according to claim 6, characterized in that the heat carrier lines (3) are designed as hot water lines, which are acted upon in response to the determined temperature of the radiation surface via a thermostatic valve with hot water bar. 9.) Infrared radiation heater according to one of claims 7 or 8, characterized in that the Temperarturbereich the radiation surface is set in operation between 80 ° and 120 ° C. 10.) infrared radiation heater according to any one of claims 4-9, characterized in that provided with a cooling unit (14) equipped plate-shaped radiator condensate collecting devices.