SK42799A3 - Building with a heating and a cooling system which includes a floor heating system and a fresh-air heating system - Google Patents

Abstract

The invention concerns a building which, for heating purposes, uses the existing solar energy and the waste heat produced in the building itself. The building comprises a heating and cooling system which includes a floor heating system fed with solar energy and a fresh-air heating system heated by waste heat. The building itself is a post-and-beam house with at least a double-shell.

Description

Technical field

The invention relates to a building with a heating system according to the claims and in particular to energy-saving houses.

BACKGROUND OF THE INVENTION

Energy-saving houses in a variety of designs are already known. For example, DE 29 44 360 A1 discloses an energy-saving house for cold areas having a floor heating unit in an underfloor floor, outer walls and a roof covering comprising thermal insulation material and a piping system that supplies heat from the room heating unit through the floor of each room. heating this room into this room. In addition, a solar energy absorption device is also provided on the sunny side of the building, which is also used to produce warm air. Thus, two complete room heating devices are needed which are alternatively or simultaneously used to heat each room.

DE 31 12 394 A1 discloses the use of main and supplementary heating. The main heating is operated with unspecified means, possibly electric power, and serves to reach the basic temperature. The additional heating serves for individual heating and ventilation of the building and can be at least partially heated by the building's own used air.

Finally, U.S. Pat. No. 4,069,973 discloses a heat distribution and storage system which uses, inter alia, solar energy to heat a room. However, this does not yet make full use of and make available the natural energy resources available to avoid environmental burdens.

The present invention is intended to make it possible to further improve the use of the available energy and to simplify the technical complexity for the necessary heating units. This objective is to be achieved by the specific use and supply of heat transfer media, depending on the construction of the building. At the same time, the burden on nature of CO _X and NO _X and the risks associated with the use of fossil fuels or the use of nuclear energy for heat production are to be substantially reduced.

SUMMARY OF THE INVENTION

The object of the invention is a building with a heating and cooling system, which has underfloor heating and fresh air heating, where at least in a two-layered pillar house the underfloor heating is performed by solar heat and fresh air heating by the heat of the air used.

In this way, not only the available solar energy, but also the warm air used in the house, is optimally used; possibly the necessary heating, preferably by electric energy, during the heating of the floor and / or fresh air can be avoided or reduced to a minimum. For this, the building must be at least two-, preferably three- or multi-layered, pillared houses, preferably of cross-sectional construction, whose heat transfer coefficient for external walls should not be less than 0.15 W / m ² and not more than 0.23 W / m ² . Basically it is assumed for the basement hot-floor heating and for above-ground floors ceiling heating of fresh air. Both heaters can be equipped with heat exchangers. Instead of a heat exchanger, a heat pump can also be integrated into the fresh air heating, as described, for example, in the Brockhaus Naturwissenschaft und Technik, Vol. 5, pages 233, 234, FA Brockhaus, Mannheim 1989; with this, the efficiency can be increased from 75% to 90% over the heat exchanger. It is advantageous if the floor plate of the first floor and the ceilings of the second or above-ground storey are equipped with heating elements as well as the ceilings of all floors with ventilation elements. Heating floor heating with hot-air heating does not cause leakage problems like hot water heating. For indirect production of warm air may be between solar technical

A water circuit so that the air is heated by the circulation of water in the heat exchanger. The floor heating devices are thus hot-air devices, with the warm air of the underfloor heating being in a closed circuit and the warm air of the ceiling heating moving freely across the floors. Suitably, the fresh air required for hot-air heating is sucked through a ground pipe fitted at a non-freezing depth, the length of which, for example, equals the peripheral length of the house. Prior to heating, the suction air is subjected to filtration to remove harmful or unpleasant components. The fresh air thus sucked in can also be used to cool rooms in a building, especially in the warm season.

By way of derogation from the basic structure, the ventilation elements may also be provided in the outer walls and / or near the floorboard and / or ceilings, if necessary. At least one heat exchanger or heat pump is provided for venting the preferably ground floor, by means of which the supplied fresh air is heated. At least one fan is always provided for sufficient circulation of warm air in the closed underfloor heating system and in the open above-ground floor heating system, fresh air heating. A pump can also be prepared to circulate the water in the circuit between the solar utility and the heat exchanger. For heat storage and water supply, the water circuit is routed through a large buffer tank, the volume of which should not be less than 350 liters and which could be equipped with thermal insulation and additional heating; For a single-family house, a buffer tank with a capacity of 350 to 500 liters is considered sufficient. In the latitude of Central Europe, the energy obtained in a solar installation from sunlight or daylight is generally sufficient to heat such a building. However, when hot water is supplied to the building from the buffer tank and / or the latitude of northern Europe, the installation of additional heating is advantageous.

The invention will be explained in more detail below by means of a schematic representation of an exemplary embodiment.

-4Overview of drawings

Fig. 1 is a cross-sectional view of a building.

Fig. 2 is an enlarged section of the exterior wall of FIG. First

Fig. 3 is an enlarged section of the roof of the building of FIG. First

Fig. 4 is an enlarged section of the floorboard of the building of FIG. First

Fig. 5 is a part of a heater for a floorboard; and

Fig. 6 is a part of a heating device for a ceiling tile.

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 1 shows a house 1 with a transverse structure, whose three-layer outer walls 2 are provided with windows or doors closed by openings 3,4 and are placed on the floorboard 5. House 1 has two ceilings 7, 8 under the gable roof 6 which together with a partition 9 A buffer tank 12 is arranged in the top space H above the above-ground floor 10. On the south side of the roof 6 there is a solar technology 13. The floor plate 5 comprises a heat exchanger 14 with air channels 15 through which the fans 16 (FIG. 5) in the heat exchanger 14 they press the heating air 17. The cooled heating air 18 is returned via the air channels 19 to the heat exchanger 14.

To heat the heating air 17 to about 40 ° C there is a solar device 13 from which the heated water is routed through a thermally insulated conduit 20, a thermally insulated buffer tank 12 to a heating coil 22 or the like in a heat exchanger 14 and cooled water through conduits 21 Back to the solar plant 13. By means of the air channels 15, the floorboard 5 is heated almost uniformly to, for example, 24 ° C. Instead of locally separated ducts 15, 19 for heated air 17 and cooled heating air 18, the ducts may also be coaxial to one another.

The ceilings 7, 8 have outlet openings 23 for the warm air used, which are connected to the duct system 24 (FIG. 6). They are also formed in the ceiling 8

The inlet openings 25 for warm fresh air, which are connected to the duct system 26 and the associated heat exchanger 29, the function of which will be described in FIG. 6, to which inter alia the ground conduit 34 leads. they can also be located in other places of the above-ground floor 10, resp. floor slab 5, ceiling 7 and walls 2 surrounded by ground floor 27.

The arrangement is chosen so that, for example, in a 250 m ³ enclosure, a heat transfer coefficient K * of 0.2 W / m ² for the exterior shell of house 1, an outdoor temperature of -15 ° C can achieve heating air in duct J5 to 45 ° C and in the pipe system 24 to 28 ° C, so that the ground floor is set to an internal temperature of 24 ° C and the ground floor to an internal temperature of 18 ° C. For diameters of 100 mm for ducts consisting, for example, of folded corrugated tubes, respectively. of air heating system piping systems, without opening the doors and windows, the air in the whole house is exchanged only within 2 to 4 hours without opening the doors and windows 1.

In FIG. 2 consists, for example, of a 34 cm thick outer wall 2 of three layers 36, 3Z, 38. Layer 37 is a self-supporting layer (crossbar) with pillars 39, crossbars 40 and a mineral wool layer 41 filling the interspaces with the pillars arranged below the right. at an angle to the crossbars 40, vertically and parallel to the plane of the drawing of FIG. 2. FIG. 2, only one pillar 39 is partially depicted for reasons of illustration. In order to keep the mineral wool 41 between the pillars and the crossbars 40, the layer 37 is provided on one side (externally) with a chipboard 42 and on the other side with a foil 43 forming a vapor barrier. for air, but impermeable to steam. The layer 36, extending externally to the layer 37, comprises an outer plaster 45 applied to the heraclitic plates 44. Heraclitic plates 44 are nailed to transverse battens 46, which in turn are nailed to the transverse battens 40, wherein between the transverse battens 40 and transverse battens 46 are so-called water strips 68 are arranged to provide sufficient air circulation in the outer layer 36. The inner layer 38 has a partition frame 47 whose cross members extend substantially parallel to the strips 46 of the transverse slat 46

-6a the crossbars 40 of the layers 36, 37 and are connected to the crossbars 40. The intermediate spaces of the crossbeam 47 are also filled with mineral wool 48; the partition frame 47 is a carrier of a layer of thick sheet piling 49 with which plasterboard boards 50 are beaten or bolted. The layer 38 serves to attach furniture, paintings and other objects.

The roof cutout of FIG. 3 has a roof covering externally consisting of roof tiles 51 which are suspended on roof battens 52. The roof battens 52 lie on the antibody layer 53 and these over a layer of bituminized cardboard 54 on a layer of rough sheet pile whose plates are substantially parallel to the roof tiles. battens 52. Roof battens 52, battens 53, and thick sheet pile layer 55 with bitumen board 54 are connected to rafters 56 (of which only one is partially shown for reasons of illustration). The interspaces between FIG. 3, parallel to the drawing planks 56, which are oriented one after the other, are filled with a mineral wool layer 57 in such a way that there is an air space, respectively between the mats 53 and the mineral wool layer. an air layer 58 for improved air circulation. In this case too, a vapor barrier 59 is formed which separates the thicker mineral wool layer 57 from the thinner mineral wool layer 60, which is located in the plane of the economical formwork 61 and has a plasterboard layer 62 as the bottom closure. a three-layered roof structure 6 having a thickness of about 33.5 cm.

The floorboard 5 according to FIG. 4 on a waxed floor 63, for example, a coarse sand layer 64 with a thickness of 10 cm, a hard foam layer 65 with a thickness of 20 cm, a layer 66 of 22 cm thick reinforced concrete and a screed layer 67, usually 4 cm. Wrapped pleated pipes 15 are placed in the reinforced concrete layer 66 to guide the air of the floor heating. Due to the three-layer construction of house 1, the annual heat consumption is only 46 kW / m ² .

Fig. 5 serves to explain the principle of operation of the heating in the floorboard, for which the solar system 13, buffer tank 12, heat exchanger 14 and air ducts 15, 19 are essential. Small heating of the air in the air ducts 15 and thus the ground floor air 27 and the heating air of the above-ground storey 10, respectively.

This can be done automatically by means of temperature sensors and thermostats (not shown) on the ground floor 27, respectively. In addition, a pump may be provided in the lines 20, 21 to provide water circulation.

In FIG. 6, a counter-current heat exchanger 29 (waste gas heat exchanger) can be seen in which hot used air 30 flows from the outlet openings 23 through the duct system 24 and leaves it as cold used air 31 through the duct 32 '. The hot spent air 30 transfers its heat to the cold fresh air 33, which passes through a conduit 34 and filter 35 to a heat exchanger 29, which flushes the specially conducted hot used air 30, receives its heat and passes through the duct system 26 to the heating inlets 25 The waste gas heat exchanger 29 can be equipped with additional heating as well as the water tank 12.

The invention is not tied to building 1 with a certain number of floors 10, 27 or rooms. A heat pump can also be used instead of the waste gas heat exchanger 29. Cold fresh air 33 can be conveyed through a duct located in the ground next to the house (building) 1 over a sufficiently long path, for example around the perimeter of the house, to a heat exchanger 29 or to a heat pump. Preferably, this line will not be laid in a possible frost area. This will cool the fresh air and can be used for cooling in summer; the heat exchange is then not carried out either for fresh air heating or for underfloor heating. All of the features set forth in the description, in the following claims and figures, may be singularly or in any combination with one another essential to the invention.

Claims (15)

PATENT CLAIMS A building with a heating and cooling system having underfloor heating and fresh air heating, characterized in that in at least a two-layer pillar house the underfloor heating is performed by solar heat and the heating of fresh air (33) by the heat of the used air (30, 31). Building according to claim 1, characterized in that the outer walls (2) of the building have a coefficient of heat transfer Km of 0.15 to 0.23 W / m ² . The building according to claim 2, characterized in that the pillared house is a house with a partition structure (1). Building according to claim 1, characterized in that the floor heating and / or the fresh air heating (33) are equipped with heat exchangers (14, 29). The building according to claim 1, characterized in that the underfloor heating has a closed air circulation which is heated in the respective heat exchanger (14, 29) by a closed water circuit heated by the solar installation (13). Building according to claim 1, characterized in that the underfloor heating is located in the floor slab (5) of the building or in the cellar ceiling. Building according to claim 4, characterized in that the heat exchanger (14) belonging to the floor heating is arranged in the floor plate (5) or in the basement of the building. -98. The building according to claim 1, characterized in that it comprises a large-volume hot water storage tank (12) which is heated by the solar system (13) via a heat exchanger (14). The building according to claim 1, characterized in that the fresh air heating (33) is equipped with a heat pump. The building according to claim 4, characterized in that the fresh air sucked in (33) is passed through a filter (35) before heating. The building according to claim 1 or 4, characterized in that the inlet openings (25) of the fresh air heating (33) are located in the ceiling (7, 8) of the respective floor of the building (1). The building according to claim 1 or 4, characterized in that the outlet openings (23) for used air are located in the ceiling (7, 8) of the respective floor of the building (1). A building according to claim 1, characterized in that in addition to the house (1), a duct (34) is laid in the ground through which fresh air (33) is sucked. A building according to claim 13, characterized in that fresh air (33) is used for cooling. A building according to claim 4 or 7, characterized in that additional heating is associated with the heat transfer floor heating circuits and / or the fresh air heating circuits (33) and / or the hot water storage tank. A building according to claim 5, characterized in that a pump is provided in the underfloor heating circuit. Building according to claim 5 or 11 or 12, characterized in that fans (16) are arranged in the air circuit for underfloor heating and / or in fresh air ducts and / or in used air ducts.