DE19819230A1 - Heat installation for room - Google Patents

Abstract

A large part of the walls (2), preferably those limiting adjacent rooms within the building, are provided with a heating device (1). The average wall temperature in relation to the intended room temperature is within a preferable range of plus or minus 2 degrees K. The average wall temperature can equal the intended room temperature. The side of the wall via which no heat is emitted is provided with an insulation coating. The supporting section (3) of the wall is of stone, brick or concrete material or a combination of such materials. The heat transmitting conduits are arranged in the first third of the wall thickness extent on which the room to be heated is located. The conduits are electrical resistance wires, arranged meander-, grid-, or spiral-form in the wall.

Description

The invention relates to a heating device for a room.

Such a heater is for space heating Residential buildings, office buildings, industrial halls, etc. applicable. The heater can also be used to cool rooms be used.

In known heaters for rooms, a distinction is made between selective heating, such as radiator heating, selective warm air supply in a room, and flat Heaters, such as underfloor heating, wall heating or large area radiators. The heat distribution in the too heating room is usually made in a combination Air circulation or convection and heat radiation.

A radiator heater is considered a point-like one Heat source a radiator on the wall, usually under one Window attached with hot water with a relatively high Flow temperature of 70 to 90 ° C is fed. The heat is mainly through heat conduction and via convective Air movement brought into the room. The heat transfer in the space by radiation is except in the immediate vicinity of the Radiators very low. The high flow temperature causes due to the large temperature difference between the Hot water and the target room temperature high losses in entire heating system. If you want to reduce this disadvantage, the flow temperature must be reduced, the Radiator capacity or the radiator area accordingly must be enlarged. A big radiator, however, is on the one hand, expensive, on the other hand, it requires a lot of wall space or space for setting up furniture and the like get lost.

Both low temperature and high temperature  Radiator heaters roll due to the high convective Part of the dust in the room increased by what with People can cause discomfort to the respiratory system. In addition, high temperature radiator heaters have the Disadvantage that dust circulates in the room on the radiators carbonized, or burns, whereupon the Carbonization products due to the air circulation in the room be distributed, which also causes irritation and discomfort to the Respiratory system.

Furthermore, selective heating with high Heat transfer through convection and lower Heat transfer by radiation has the disadvantage that People in the room despite the relatively high air temperature from 23 to 25 ° C, for example, because the Space-limiting, relatively cold walls, radiating cold.

There are underfloor heating and under the surface heating Wall heaters.

Underfloor heating is usually constructed in such a way that over an existing one, for example made of reinforced concrete Ceiling wall an insulation and insulation layer is arranged. Above them are pipes through which warm water flows laid over which the screed is layered. Becomes a room heated exclusively by means of underfloor heating, one must relatively high water inlet temperature of 35 to 45 ° C be used. This leads to the fact that on the floor over the hot water pipes trained relatively hot strips be, so that no uniform heat emission over the Floor space is possible. Furthermore, the choice of Strong flooring when using underfloor heating limited. In this context is a ceramic Flooring more advantageous than carpeting or a Wooden floor. Especially with carpeting there is a risk of increased dust whirling very high. Furthermore, the Temperature unfavorably distributed over the room height. Is on the ground if it is too warm on the ceiling it is too cold. Since people at  floor heating always on a warm surface are generally with such Underfloor heating also has health problems, such as Sweaty feet and varicose veins on the legs connected. Floor heating systems are also relatively slow Room temperature control property. Especially when the outside temperature rises quickly due to the weather, or if the room to be heated is exposed to sunlight if the room is additionally heated, the room overheats, taking the underfloor heating, even if it is turned off immediately is reheated for about a day.

So-called wall heaters are also known, in which on the unplastered wall meandering hot water Pipelines are installed in a relatively thin Layer of plaster can be embedded. This surface heating has the disadvantage that directly above the hot water Form piping hot strips. When operating this Wall heating has the disadvantage that the plaster due to thermal expansion with stresses, cracking or Blowing off the plaster or the tiles is connected. Furthermore, the risk is very great that when hitting Nails or drilling holes water-carrying pipes are injured, leading to failure the heating leads and is connected with repair work.

The object of the present invention is a To provide heater for a room that works economically, the usable living space does not reduced, which receives the walls as a mounting surface, the avoids overheating of space and a healthy and creates a pleasant indoor climate for people.

This object is achieved by the features of patent claim 1 solved.

Because one or all of the side walls and possibly additionally the ceiling wall itself using a  Heating device is heated, act the one room surrounding walls as a kind of tiled stove. By heating of the masonry itself, can be even Heat distribution achieved on the wall surface of the wall become. Most of the heat is given off to the room (80 up to 90%) about heat radiation what humans find very pleasant and feels comfortable. The actual target Room temperature can be kept relatively low (preferably at 17 to 21 ° C).

Furthermore, the building material of the heating device Side and / or ceiling wall used as heat storage, which contributes to economical energy consumption.

Because of the large usable heating surface, the wall needs only at target temperature or slightly above target To be heated to room temperature, where as T preferably a range between 0 to 4 ° K is sufficient. There with this room heating mainly by means of Heat radiation can be transmitted into the room Wall temperature is even below the target room temperature.

In other words, when the wall is heated using fluid-carrying Lines can have a very low flow temperature be worked, which means that the heater overall can work very economically, with residual heat and Waste heat from other areas is still effective Space heating purposes can be used.

Furthermore, by using a relatively small T Avoid overheating a room because sudden weather-related increase in outside temperature and / or in the event of sudden strong sunlight Space heating device automatically emits heat to the room sets because even with a slight increase in room temperature the temperature gradient between room temperature and masonry approaches zero and the room heating is therefore automatic turns off.  

Since only side and ceiling walls are heated, they are Health problems on people's feet and legs eliminated. Furthermore, you are free to choose the Flooring.

Since the wall itself is heated, the wall surface stands available for driving in nails and screws. Furthermore, the use of the space is not by any Radiators Restricted Radiators Restricted.

In addition, when heating the wall by means of fluid-carrying lines the system also for room cooling be used when appropriately cooled fluid through the lines are routed.

Further advantageous developments and refinements of The heating device can be found in the subclaims.

The invention is illustrated below using an example preferred embodiment with reference to the drawing explained where

Fig. 1 shows a sectional view through a side wall for the simultaneous heating of two adjacent areas;

Fig. 2 shows a sectional view through a side wall for heating a room along the line AA according to Fig. 1;

Figure 3 shows an oblique view of a brick;

Figure 4 shows a front view of a wall provided with the heater;

Figure 5 shows a front view of a wall provided with the heater;

Fig. 6 to 9 show sectional views of a modified, provided with a heater side walls;

Fig. 10 shows a sectional view through a side wall to the individual heating of two adjacent spaces;

Fig. 11 is a sectional view through a ceiling wall to heat the room lying below the ceiling wall;

According to Fig. 1 and 2 is a sectional view through a wall 2, which is provided in a middle in thickness direction of the wall portion with a heating device 1. The wall 2 with a thickness D consists mainly of a load-bearing layer 3 , which is provided on both sides with a plaster layer 4 and 5 having a thickness d, which in turn is delimited by a wall surface 4 a and 5 a.

In this embodiment, the heating device 1 for heating the wall 2 is arranged centrally in the supporting layer 3 . The heating device 1 consists of a large number of pipelines 6 through which hot water flows and which are laid in the wall. The pipes 6 are preferably made of plastic. However, they can be made from any other suitable material such as aluminum, copper, stainless steel or steel. The load-bearing layer 3 is preferably made of brick. However, it can also be made of sheet clay, concrete or a combination of bricks with sheet clay or concrete or gas concrete.

The wall 2 is provided with horizontally and, or vertically arranged, in the extent or at right angles to the surface 4 a, 5 a of the wall 2 slots 7 . The slots 7 can extend in the thickness extension of the wall 2 through the entire wall 2 to the opposite plaster layer 4 . The width of the slots 7 is designed according to the width of the pipes 6 used . The slots 7 , into which other structural installations, such as electrical service water and wastewater installations, can be laid, are filled with bläton or another suitable, heat-conducting and heat-storing, hardening casting material.

The manufacture of a wall 2 is described below with reference to FIGS. 1 to 5.

Bricks 8 are used, as shown in FIG. 3. Such a cuboid or cube-shaped brick 8 has a lower surface 8 a, an upper surface 8 b and four side surfaces 8 c, 8 d, 8 e and 8 f. In extension of the side surfaces 8 e and 8 f and the upper surface 8 b and the lower surface 8 a, a circumferential wedge-shaped projection 9 is formed. Furthermore, the bricks 8 are provided with a plurality of air chambers 10 extending through the bricks 8 from the lower surface 8 a to the upper surface 8 b, which run parallel to one another through the bricks 8 and extend to the lower surface 8 a and to the upper surface 8 b open.

The bricks 8 , which are available in various sizes forming a system grid, are lined up with the side surface 8 f on a horizontally lying formwork platform (not shown) in such a way that the edges 9 a of the projections 9 abut one another and over the projections 9 horizontally and Form vertical slots 7 . In this way, a complete wall 2 is formed, into which, for example, a window 11 with a roller shutter box 11 a arranged above it or a door (not shown) can be integrated ( FIGS. 4 and 5). The slots 7 also serve, for example, to accommodate reinforcement made of structural steel and electrical and water installations. In particular, the hot water-carrying pipes 6 used to heat the wall 2 are installed in the slots 7 in a central section of the thickness extension of the wall 2 . After all installations have been made, the slots are filled with Bläton 12 . After the hardening of the clay 12 , the wall is finished. It can now be provided on the side surfaces 8 d and 8 f of the brick 8 with the relatively thin plaster layer 4 , 5 . The finished wall 2 is placed vertically after curing and joined together with other side walls and ceiling walls to form a building (not shown) enclosing rooms. The finished building is provided with full thermal insulation on its outer surfaces in accordance with the Thermal Protection Ordinance. Such insulation layers have a heat-conduction layer, such as styrofoam and / or a heat radiation-inhibition layer, such as an aluminum foil.

Instead of leaf tone, any other can be used as the casting material suitable concrete or gas concrete can be used.

According to FIG. 4 is an installation method of the hot-water-carrying tubes 6 is shown in the slits 7. Here, a multiplicity of parallel-spaced pipelines 6 are arranged, which are fluidically connected at their end sides to distributors or manifolds 6 a, 6 b running transversely to the multiplicity of pipelines 6 , so that a type of grid arrangement is created. In this arrangement, the hot water is fed in via the distribution lines 6 a (arrow), flows through the multiplicity of parallel pipes 6 and flows off via the collecting line 6 b (arrow). This lattice-shaped arrangement of the pipes 6 , 6 a, 6 b is laid according to FIGS. 1 and 2 in a central section of the wall 2 with vertical alignment of the plurality of pipes 6 . The hot water preferably flows in through the distributor line 6 a arranged at the bottom. The grid-shaped arrangement of the pipes 6 , 6 a, 6 b can also be installed in the wall 2 with the plurality of pipes 6 aligned horizontally.

Referring to FIG. 5, a further cable installation is a hot-water-carrying tube illustrated in the slots 7 of the wall 2 6. Here, a pipeline 6 is laid in a meandering shape to correspond to the course of the slots 7 in the wall. The hot water is fed in at one end of the pipeline and flows out over the other end (arrow).

According to Figs. 4 and 5 is provided, only a part of the respective wall 2 with pipe lines 6, however, the entire wall 2 can be provided with conduits 6, if necessary, so that there are provided also to the window 11 around pipes 6.

According to FIG. 6, a pipe arrangement according to FIG. 4 or 5 is laid in the wall 2 in the thickness extension of the wall 2 in two different levels. The laying plane of the pipelines 6 is preferably laid in the first quarter or in the first third in the thickness dimension of the wall 2 measured from the respective wall surface 4 a or 5 a. The longitudinal pipes 6 of the one pipe arrangement are arranged crosswise to the longitudinal pipes 6 of the other pipe arrangement, in particular to ensure a more uniform heating of the wall.

According to Fig. 7 and 8, an installation method of the pipes 6 is illustrated. The supporting layer 3 of the wall 2 consists approximately of half 3 a of a plurality of bricks 8 , as shown for example in Fig. 3, and the other half 3 b of sheet clay. The pipes 6 for heating the wall 6 are laid adjacent to the side faces 8 d of the brick 8 in a central section of the wall. This arrangement of the pipelines 6 has the advantage that it can take place regardless of the presence of slots 7 . The conduits 6 may in the embodiment of Fig. 7 and 8, a meander shape, as shown in Fig. 4, or lattice-shaped as shown in FIG. 5, or even be laid spirally or in any other suitable type.

As an alternative to the embodiment shown in FIGS. 7 and 8, the load-bearing layer 3 of the wall 2 can be produced entirely from a casting material such as sheet clay, concrete or gas concrete, with a layer of brick being dispensed with.

A wall with a cross-sectional structure according to FIGS. 1 to 8 is suitable to give off heat equally over both surfaces 4 a and 5 a, and is thus able to heat the two rooms separated by this wall at the same time. However, it is also possible to move the heating device 1 not absolutely in the middle of the wall 2 , but in the first third adjacent to the wall surface 4 a, so with this structure more heat can be transferred into the room to which the wall surface 4 a borders in the room to which the other surface 5 a borders. In this way, for example, be less heated on the wall surface 5 a bordering bedroom, as a bordering example to the surface 4 a living room.

According to the Fig. 9 a modification is shown to the above described wall cross-sectional constructions. The wall structure differs from the wall structures shown above only in that an insulation layer 13 with a thickness Id is provided between the plaster layer 4 and the load-bearing wall layer 3 . The insulation layer 13 consists of a material with a very low thermal conductivity value, such as, for example, polystyrene with 89% air or mineral fiber plates. Such a wall structure is chosen if heat is to be transferred only over one wall surface 5 a of the wall 2 , with almost no heat being transferred over the other wall surface 5 a. In this embodiment, the heating device 1 is arranged within the wall 2 closer to the heat-emitting wall surface 5 a, preferably in the first third of the thickness of the wall 2 measured from the wall surface 5 a. Such a wall structure is used as an outer wall or as an intermediate wall. This wall structure is used as an intermediate wall, in particular when the space adjoining the wall surface 4 a is not to be heated via the wall 2 .

Referring to FIG. 10, a further wall structure is shown. In the wall 2 according to FIG. 10, the supporting layer 3 c of the wall 2 into two sub-layers 3, divided c 3, each of which is about half of the thickness D of the walls has described above. An insulation layer 13 is provided between the two sub-layers 3 c and 3 c, as has already been described with regard to the embodiment of FIG. 9. In a central section of a respective sub-layer 3 c, a heating device 1 is provided in the form of a pipeline structure that carries hot water. The wall is in turn delimited by the plaster layers 4 and 5 on both sides. In this version, it is possible to heat the rooms adjacent to the respective wall surfaces 4 a and 5 a individually, that is to say with different temperatures.

Referring to FIG. 11, a top wall arrangement. This ceiling wall arrangement has a load-bearing layer 3 with a thickness D, below which the plaster layer 5 serving as a ceiling is applied. Above the load-bearing layer 3 is an insulation layer 13 with the thickness Id and above it a layer 14 that supports the floor covering (not shown). Layer 14 can be a screed, a bitumen layer or a layer of wooden laying boards. In the middle of the load-bearing layer 3 and preferably in the first third of the load-bearing layer, measured from the plaster layer 5 , the heating device 1 is provided in the form of pipelines 6 carrying hot water. Here, too, it is possible to use the pipes not only as a heating device 1 for the ceiling wall 2 but also as a test when using pipes 6 made of steel, with appropriate dimensioning of the pipes 6 .

With the ceiling wall arrangement according to FIG. 11, the space beneath the wall surface 5 a can be heated. Due to the insulation layer 13 , however, the floor above is not heated.

Instead of water as the heat-carrying medium, anyone else can liquid or gaseous, a certain heat capacity medium is pumped through the pipes. In the case of a medium with a low heat capacity, the Volume flow can be increased accordingly by a predetermined To transfer heat. In addition, the Pipe cross-section enlarged or according to Heat capacity of the medium can be adjusted.

Instead of using pipes for a heat-carrying medium also electrical heating cables, such as. B. electrically Resistance wires inserted in the ceiling or side wall become. The resistance wires are good with one sheathed heat-conducting and electrically insulating layer.

The wall can also be heated in that the Wall itself made of a material with relatively high resistance is produced, to which a voltage is applied to a Training heating device.

In a variation of the wall construction according to Fig. 1 and 2 b and on the lower surface 8 a to which the air chambers 10 open without the wedge-shaped protrusion 9 is provided unlike this embodiment, the bricks 8 at least at the upper surface 8, so that the bricks abut against one another during assembly with the open air chambers 10 , which results in a multitude of continuous air ducts in the wall horizontally or vertically, depending on the orientation of the bricks. A transverse distributor air line (not shown) is formed on each of the two end sides of the plurality of air lines and is in fluid communication with the plurality of air lines. The pipes 6 are not available. In this arrangement, the wall is heated with warm air, which is supplied via a distribution line, flows through the wall via the large number of air lines integrally formed in the bricks, and flows out again via the opposite distribution line.

Instead of the central load-bearing brick layer, a load-bearing layer made of concrete, lightweight concrete, gas concrete, stone, sandstone or the like can be used. The load-bearing layer 3 should be made of a material with a specific heat capacity c in kJkg ^-1 K ^-1 of c = 0.3 to 1.0, preferably of c = 0.8 ± 0.2 and with a thermal conductivity (at 20 ° C) l in W m ^-1 K ^-1 of l = 0.2 to 10, preferably of l = 0.8 ± 0.3.

The total thickness D of the wall 2 shown in the drawing is D = 120 to 350 mm. The thickness D of a wall is preferably D = 200 to 300 mm. The thickness d of a plaster layer 4 , 5 is preferably not more than d = 5 to 10 mm. The thickness of an insulation layer 13 is between 50 mm and 100 mm, preferably 70 mm. An insulation layer 13 is constructed on the basis of the thermal insulation regulation.

The pipes 6 are preferably at a depth t of 30 to 200 mm and a preferred distance a of 150 to 400 mm with respect to the heat-emitting wall surface.

The regulation of the target room temperature of rooms with the side and or ceiling walls described above are limited, takes place via a control device that the Heating device for the wall depending on the information controlled by sensors. Different sensors can be used as sensors serve in different positions. For example, a Temperature sensor for recording the room air temperature, on Temperature sensor for recording the wall surface temperature or a temperature sensor to record the Internal wall temperature or a sensor to record the in heat radiation prevailing in a room (e.g. infrared sensor) be used. It can also be a combination of these Sensors are used, e.g. B. a heat radiation sensor can be used with a wall surface sensor.  

Each of the types of installation of the heating device 1 for the wall 2 described above, each type of heating 1 for the wall 2 described above and each wall structure described above can be freely combined with one another to form a ceiling wall or a side wall, which in turn can be combined to form a building.

Heater for a room where one is the room delimiting side and / or ceiling wall with an in the wall arranged heater is provided. A such a heater is for space heating Residential buildings, office buildings, industrial halls, etc. applicable. The heating device arranged in the wall can also be used as Cooling device may be designed to cool the room.

Claims (27)

1. A heating device for a room, characterized in that a portion of a wall ( 2 ) delimiting the space is provided with a heating device ( 1 ) arranged in the wall ( 2 ). 2. Device according to claim 1, characterized in that the wall ( 2 ) is a side wall and / or a ceiling wall. 3. Device according to claim 1 or 2, characterized in that a large part, preferably all the walls delimiting the space ( 2 ), preferably the walls ( 2 ) bordering adjacent rooms within the building are provided with the heating device ( 1 ). 4. Device according to one of claims 1 to 3, characterized featured, that the mean wall temperature in relation to the target Room temperature in a range of ± 5 ° K, preferably from ± 2 ° K. 5. Device according to one of claims 1 to 4, characterized featured, that the mean wall temperature is equal to the target Room temperature. 6. Device according to one of claims 1 to 5, characterized in that the side of the wall ( 2 ), via which no heat is to be emitted, is provided with an insulation layer ( 13 ). 7. The device according to claim 6, characterized in that the insulation layer ( 13 ) comprises a heat-conduction layer and / or a heat radiation-inhibiting layer. 8. Device according to one of claims 6 or 7, characterized in that the insulation layer ( 13 ) is formed according to the thermal insulation regulation. 9. Device according to one of claims 1 to 8, characterized in that the wall ( 2 ) made of heat-storing material with a specific heat capacity c in kJkg ^-1 K ^-1 of c = 0, 3 to 1.0, preferably of c = 0.8 ± 0.2 and with a thermal conductivity (at 20 ° C) l in W m ^-1 K ^-1 of l = 0.2 to 10, preferably of l = 0.8 ± 0.3. 10. Device according to one of claims 1 to 9, characterized in that the supporting section ( 3 ) of the wall ( 2 ) consists of stone, brick or concrete material or a combination of these materials. 11. Device according to one of claims 1 to 10, characterized in that the heating device ( 1 ) for the wall ( 2 ) is formed by spaced apart, laid in a central region of the wall thickness extension, heat-transferring lines. 12. The apparatus according to claim 11, characterized in that the heat transfer lines are arranged centrally with respect to the wall thickness extension when both adjacent to the wall ( 2 ) rooms are heated at the same time. 13. Device according to one of claims 11 or 12, characterized featured,  that the heat transfer pipes in the first third of the Wall thickness extension are arranged on which the heating room. 14. Device according to one of claims 11 to 13, characterized in that the heat-transmitting lines are arranged on both sides in the first third of the wall thickness extension and in the central section of the wall is an insulation layer ( 13 ). 15. The device according to one of claims 11 to 14, characterized featured, that the lines as electrical resistance wires are trained. 16. The device according to one of claims 11 to 15, characterized in that the lines are laid in a meandering, lattice or spiral shape in the wall ( 2 ). 17. Device according to one of claims 11 to 16, characterized in that the lines are laid in slots provided in the wall ( 7 ). 18. The apparatus according to claim 17, characterized in that the slots ( 7 ) are poured with concrete or sheet clay or the like. 19. Device according to one of claims 11 to 18, characterized in that the lines are designed as pipes ( 6 ) for guiding fluids. 20. The apparatus according to claim 19, characterized in that the pipes ( 6 ) can be flowed through with a cooled fluid, wherein the space can be cooled via the heating device. 21. Device according to one of claims 19 or 20, characterized in that the pipes ( 10 ) are integrated in the wall material and preferably can be flowed through with air. 22. The device according to one of claims 19 to 21, characterized featured, that as fluids preferably liquids and preferably a Liquid mixture with a high water content is used. 23. The device according to one of claims 19 to 22, characterized in that the pipes ( 6 ) are designed as a plurality of pipes ( 6 ) which are evenly spaced from one another and which are connected to the respective end sides via distributor or collecting lines ( 6 a, 6 b ) are fluidly connected. 24. Device according to one of claims 19 to 23, characterized in that the pipes ( 6 ) preferably consist of a plastic, steel, stainless steel, copper or aluminum. 25. Device according to one of claims 19 to 24, characterized featured, that with steel pipelines, the fluid lines at the same time serve as reinforcement. 26. The device according to one of claims 1 to 25, characterized in that the temperature of the heating device ( 1 ) for the wall can be controlled via a heat radiation sensor arranged in the room. 27. The apparatus according to claim 1, characterized in that the heating device ( 1 ) is designed as a cooling device, whereby the room can be cooled.