JP2013516592A - Room temperature controller - Google Patents

Abstract

  The invention relates to a room temperature control device, which device forms a thermal reservoir and has at least one building member (5) having an interior facing surface (11), and said building member (5) And a plurality of conduits (9) that are thermally coupled to the conduit (9). The conduits (9) can be supplied with a heating or cooling medium. In the present invention, the conduit (9) is embedded in a plate (1) containing expanded graphite or made of expanded graphite, the plate (1) being a surface facing the interior of a building member ( 11) is in thermal contact with the surface.

Description

  The present invention relates to a room temperature adjustment device and a room temperature adjustment method of the type described in the superordinate concept of claims 1 and 27.

  Regarding the air conditioning of rooms with concrete ceilings or concrete walls, so-called “concrete core activation systems” are known from the prior art. In this concrete core activation system, a plurality of conduits for guiding heating or cooling media are attached to the interior, lower or upper part of the concrete ceiling or concrete wall. By storing heating or cooling energy in the concrete material of the wall or ceiling and supplying the stored heating or cooling energy later, air-conditioning with high energy efficiency of the room can be obtained. That is, for example, at night, a cooling fluid, such as water, is cooled and guided through a conduit provided in the ceiling or wall where the concrete core is activated, thereby slowly cooling the ceiling or wall. The cooling energy stored in the concrete ceiling or concrete wall in this way can then be slowly supplied indoors, particularly during warm summer days, due to room temperature drops.

  However, such thermally activatable ceiling or wall mounting is limited to new buildings. When rebuilding an old building, the concrete core activation part of the ceiling or the wall as described above cannot be attached later. In the case of a ceiling or wall with a concrete activation part, it also has the disadvantage that a plurality of conduits provided in the concrete ceiling or wall can be inadvertently damaged, for example by drilling. Repair of damaged conduits is almost impossible. This is because it is difficult to access a conduit embedded in concrete for repair. The static state and stability of the ceiling or wall provided with the conduit is also impaired by the conduit embedded in the concrete. Furthermore, the production of such a concrete core activation system is very time consuming and expensive. Another disadvantage is the inactivation of the thermal system based on the subsequent supply of the thermal energy stored in the concrete reservoir body to the room to be temperature controlled.

  In order to eliminate these drawbacks, the temperature control system known from the prior art can also be placed later on a ceiling or wall without a conduit. This known temperature control system generally has a ceiling or wall member with a plurality of conduits within which a heating or cooling medium can be supplied. These ceilings or wall members are fixed to the ceiling or wall. The thermal energy stored in the heating or cooling medium guided through the conduit is supplied to the room to be temperature controlled by thermal radiation and free convection through the frame or lining of the ceiling or wall member. . Such a system is described, for example, in EP 1 371 915, where a plurality of phase change materials are used as heat stores.

  The known temperature control system has the disadvantage that thermal energy is supplied into the room directly and immediately from the heating or cooling medium flowing in the conduit by thermal radiation and convection. In this temperature control system, the surface of the ceiling or wall is further covered by the ceiling or wall member. As a result, the ceiling surface or wall surface is thermally separated from the room where the temperature is to be adjusted, so that the ceiling or wall substrate cannot be used for nighttime storage cooling (or storage heating). .

  The object of the present invention, starting from this, is to provide a thermal storage of the ceiling or wall body without having to provide a conduit in the ceiling or wall to guide the heating or cooling medium for the thermal activation of the reservoir. It is providing the room temperature control apparatus and room temperature control method which can be utilized as a vessel. It is a further object of the present invention to provide a temperature control system that is as energy efficient as possible with a short response time. In addition, we would like to be able to install this temperature control system later in the reconstruction of an old building.

  These problems are solved by a room temperature control apparatus having the features of claim 1 and a room temperature control method having the features of claim 27. Advantageous configurations of the device according to the invention are described in the dependent claims 2-26.

1 is a schematic cross-sectional view of a first embodiment of a room temperature control apparatus according to the present invention. FIG. 6 is a schematic cross-sectional view of a ceiling or wall member for a second embodiment of a temperature control device according to the present invention. FIG. 3 is a schematic cross-sectional view of a second embodiment of the temperature control apparatus according to the present invention including the ceiling or wall member shown in FIG. 2.

  In the following, embodiments of the invention will be described in detail with reference to the drawings.

  FIG. 1 shows a first embodiment of a temperature control device according to the present invention. This temperature control device has a member 10 arranged on a building member 5 made of concrete or brick. The building member 5 may be the ceiling, wall or floor of the room R to be temperature controlled. The building member 5 may be composed of another conventional building material that can store heat and / or cold, such as clay or rock. Correspondingly, the member 10 is a ceiling member, a wall member or a floor member disposed on the surface 11 of the building member 5 facing the room. The building member 5 forms a thermal reservoir based on its large mass, in which thermal energy is stored (in the form of heat or cold).

  The member 10 is a plate 1 containing expanded graphite or consisting entirely of expanded graphite.

  The production of expanded graphite (expanded graphite) is known, inter alia, from US Pat. No. 3,404,061. In order to produce expanded graphite, for example, a graphite intercalation compound or graphite salt such as graphite hydrogen sulfate or graphite nitrate is heated impactively. In this case, the volume of the graphite particles increases by about 200 to 400 times, while the bulk density decreases to a value of 2 to 20 g / l. The expanded graphite thus obtained is composed of a plurality of aggregates in the form of worms or accordions. When fully expanded graphite is compressed under pressure orientation, the layer planes of the graphite are preferably arranged perpendicular to the direction of pressure action, in which case the individual aggregates are Overlapping and biting. In this way, free-standing planar structures such as webs, plates or molded bodies can be made from expanded graphite.

  In order to reinforce and improve the stability of such a graphite plate or graphite compact, the expanded graphite can be mixed with a curable binder such as, for example, a resin or plastic, in particular an elastomer or a thermosetting resin. In order to improve the stability of the plates made of expanded graphite, a mixture of expanded graphite with thermoplastics and / or thermosetting plastics is particularly suitable, said thermoplastic and / or thermal The curable plastic is introduced into the expanded graphite, for example by impregnation or via a powder process. After the binder mixed with the expanded graphite has been cured, the graphite compact or graphite plate made from the mixture has sufficient stability for the applications envisaged according to the invention. . The graphite plate thus produced is particularly free-standing, and can be easily fixed to a building member such as a ceiling or a wall, for example, by bonding or screw fastening.

  Pure expanded graphite, like a mixture of expanded graphite and binder, has very good thermal conductivity. The thermal conductivity of the mixture of expanded graphite and binder is still very high depending on the type of binder used, even when the amount of binder is 50% by weight. As far as the graphite plate is referred to below, it is understood that this plate consists of pure expanded graphite or consists of a mixture of expanded graphite and a binder.

  It is also possible to make the graphite plate from a mixture of expanded graphite and phase change materials (PCM). For this purpose, for example, general phase change materials based on paraffin, wax or salt may be mixed during the production of the graphite plate. Such a graphite plate having a phase change material can be used as another heat accumulator (latent heat accumulator) other than the building member 5 serving as a thermal accumulator in the temperature control system according to the present invention.

  A plurality of conduits 9 are embedded in the graphite plate 1 shown in FIG. These conduits 9 are preferably arranged in a serpentine manner inside the plate 1. Other arrangement types of the conduits are also conceivable, for example arrangements such as spirals, grids or bends, or arrangements in the edge area of the plate 1 only. The ends of the conduits 9 extending into the plate 1 are connected to a supply device for guiding a heating or cooling medium (for example hot or cold water) through these conduits 9. In order to provide the member 10 on the entire surface 11 facing the room R of the building member 5, a plurality of members 10 may be arranged so as to be positioned side by side or side by side and fixed to the surface 11. it can. In this case, the end of the conduit 9 of each member 10 is connected to the corresponding end of the adjacent member 10 to form a conduit circuit, so that the conduit circuit guides the heating or cooling medium. Combined with feeding device.

  The fixing of the member 10 is preferably effected by a thermally conductive adhesive 4, by which one main surface 12 of the board is bonded to the surface 11 of the building member 5. Due to this adhesion, the main surface 12 of the plate 1 is in thermal contact with the surface 11 of the thermal reservoir formed by the building member 5 and preferably in a heat-conducting manner over the entire main surface 12. .

  A reinforcing layer 6 can be provided on the other main surface 13 of the plate 1 as in the embodiment shown in FIG. This reinforcing layer 6 may be, for example, a painted wall layer or a bonded cardboard or gypsum board layer. Moreover, it is also possible to combine a coating wall layer and fiber materials, such as a net | network, a woven fabric, a knitted fabric, and a knit, embedded in this coating wall layer. By means of the reinforcing layer 6, the stability of the graphite plate 1 is improved on the one hand, and on the other hand, the main surface 13 of the plate 1 facing the room R can be lined with a good appearance. The reinforcing layer 6 is applied to the plate 1 made in particular from pure expanded graphite (without the addition of a binder).

  The conduit 9 extending into the plate 1 can already be introduced during the production of the graphite plate 1. These conduits 9 are preferably tubes made of metal, for example copper, or plastic tubes, for example made of polypropylene or cross-linked polyethylene. However, for better heat transfer, metal tubes are preferred. As in the embodiment shown in FIG. 1, the conduit 9 may be completely embedded in the plate 1. However, it is also possible to arrange the conduit 9 so that it is flush with one major surface 12; 13 of the plate 1.

In order to embed the conduit 9 in the plate 1, the conduit 9 is embedded in the deposited portion of the worm-like or accordion-like graphite aggregate during the production of the plate and the composition is then used in a known manner (for example using rollers or pressure plates). The graphite plate 1 having a stable shape based on the pressure action is obtained by pressing. In order to increase the stability of the plate, one of the binders already mentioned can be added during the production process. The graphite plate 1 with the conduit 9 embedded in this way typically has a thickness of 8 to 50 mm. The density of the graphite plate 1 is usually 0.01 to 0.5 g / cm ³ (depending on the amount of binder added). The graphite plate 1 has a thermal conductivity of 3 to 6 W / mK.

  Based on the good thermal conductivity of the graphite plate 1, some portion of the thermal energy stored in the heating or cooling medium guided through the conduit 9 is first exposed from the conduit 9 to the exposure of the plate 1 by heat conduction. The main surface 13 can be guided to the room R where the temperature is to be adjusted by thermal radiation and free convection. Since this heat supply (or cold air supply when the cooling medium is guided through a conduit) is performed very quickly, it is possible to warm (or cool) the room very quickly. The other part of the thermal energy stored in the heating or cooling medium is transferred by heat conduction from the conduit 9 through the thermally conductive plate 1 to the thermal reservoir formed by the building member 5. This heats up the thermal reservoir (or cools when the cooling medium is guided through the conduit). The thermal reservoir then supplies the intermediate stored thermal energy to the room later, in which case the good thermal conductivity of the plate 1 is approximately the thermal energy supply to the room. Help to be done without loss. The heating (or cooling) of the room R performed in this way is performed over a relatively long time (several hours). Therefore, the temperature control system according to the present invention can quickly bring the room R to be temperature-controlled to a desired room temperature, or slowly using a thermal reservoir. That is, for example, by guiding a cooling medium (for example, cold water) through the conduit 9 at night in summer, the thermal reservoir can be cooled. The thermal reservoir can then be used to cool the room during the day by supplying cool air later to the room.

  Similarly, the temperature control system according to the invention is heated during the winter day by first guiding the heating medium through a conduit in order to rapidly heat the room first. At the same time, heat is supplied to the thermal reservoir. The flow of the heating medium may be stopped at night. This is because, in order to keep the room at room temperature at the required height at night (which is relatively lower than the daytime temperature), it is necessary to keep the room from after the heat from the thermal reservoir supplied with the heat. The release is enough.

  2 and 3 show another embodiment of the temperature control system according to the present invention. 2 and 3, the same or corresponding components as those in FIG. 1 are denoted by the same reference numerals.

  In the embodiment shown in FIG. 3 of the room temperature adjusting device according to the invention for adjusting the temperature of the room R, the ceiling member 10 is fixed to a building member 5 formed as a concrete ceiling. The building member 5 forms a thermal reservoir, and has a ceiling concrete material as a base of the reservoir. The ceiling member 10 has a frame 2, which is fixed to the surface 11 of the building member 5 facing the room R, in particular by screwing. The frame 2 is formed as a cassette whose one side (that is, the upper surface) is open. The frame 2 is preferably made from a thermally conductive material, such as a thin metal plate. The frame 2 includes a bottom plate 2a and four side walls 2b disposed on the bottom plate 2a or integrally formed with the bottom plate 2a. At least the bottom plate 2a (and possibly the side wall 2b) is formed from a perforated plate (that is, a metal thin plate having a perforated portion). A graphite plate 1 is placed in the frame 2. The composition of this graphite plate 1 is equal to the composition of the plate 1 of the embodiment shown in FIG. Also in this embodiment, a plurality of conduits 9 are embedded in the graphite plate 1 and extend in a meandering shape, a lattice shape, a spiral shape, or a bent shape. The graphite plate 1 is preferably bonded in a planar manner to the surface 11 of the building member 5 via a thermally conductive adhesive 4. Thereby, the main surface 12 of the graphite plate 1 is preferably in thermal contact with the surface 11 of the building member 5 over its entire surface. However, the adhesive layer 4 can also be omitted (see below).

  A fleece 3 and a graphite sheet 15 are preferably arranged between the bottom plate 2 a of the frame 2 and the graphite plate 1. The fleece 3 may be, for example, a glass fiber fleece or a carbon fiber fleece. In connection with the perforated part of the bottom plate 2a, the fleece 3 ensures good sound absorption of the ceiling member 10. The graphite sheet 15 is a thin sheet made of expanded graphite. The thickness of the graphite sheet 15 is preferably 0.05 mm to 3 mm, in particular 0.2 to 3 mm.

  Advantageously, the fleece 3 and the graphite sheet 15 disposed thereon are one non-dissociable composite that can be produced, for example, by calendering. Such a composite can be made particularly advantageously from a carbon fiber fleece and a graphite sheet 15 made of expanded graphite. When calendering the expanded graphite thin sheet together with the carbon fiber fleece, the carbon particles on the surface of the fleece and the carbon particles on the surface of the graphite sheet mesh with each other, so that there is a gap between the carbon fiber fleece 3 and the graphite sheet 15. Thus, a strong bond that cannot be dissociated is formed. In this case, a perforated graphite sheet 15 is particularly preferably used. That is, the perforated portion of the graphite sheet 15 increases the flexibility of the graphite sheet 15, thereby simplifying the handling of the sheet. Since graphite is a brittle material, when handling thin sheets of expanded graphite, there is a risk of the sheet breaking or breaking. This risk can be significantly reduced by the perforations in the graphite sheet 15.

  FIG. 2 shows a cross-sectional view of a ceiling member 10 that can be used in the embodiment of the temperature control apparatus according to the present invention shown in FIG. As can be seen from FIG. 2, the upper main surface 12 of the graphite plate 1 protrudes beyond the upper edge 2 c of the side wall 2 b of the frame 2. When such a ceiling member 10 is used, the adhesion of the graphite plate 1 to the surface 11 of the building member 5 may be omitted. That is, the frame 2 is screwed to the building member 5 in order to fix the ceiling member 10 to the building member 5. When the frame 2 is screwed to the surface 11 of the building member 5, the graphite plate 1 is crushed until the main surface 12 of the plate 1 is flush with the upper edge 2c of the side wall 2b of the frame. In this case, the graphite plate 1 can be crushed based on the deformability of the expanded graphite. The graphite material of the plate 1 crushed in the direction perpendicular to the surface 11 is preferably in thermal contact with the surface 11 over the main surface 12 after fixing the ceiling member 10 to the building member 5. In this case, undulations and protrusions on the surface 11 of the building member 5 can also be compensated based on the good deformability of the graphite material of the plate 1.

  The arrangement of one ceiling member 10 on the surface 11 of the building member 5 or the arrangement of a plurality of ceiling members arranged side by side corresponds to the embodiment of FIG. 1 described above. The functional form of the temperature control device shown in FIG. 3 is also the same as that of the embodiment shown in FIG.

Claims (27)

At least one building member (5) which forms a thermal reservoir and has a surface (11) facing the room, and is thermally applied to the building member (5). In the form of a plurality of conduits (9) coupled to be able to supply a heating or cooling medium to these conduits (9),
A conduit (9) is embedded in a plate (1) containing expanded graphite or made of expanded graphite, the plate (1) facing the surface (11) facing the interior of the building component A room temperature control device characterized by being in thermal contact with each other.   2. The device according to claim 1, wherein the expanded graphite plate (1) is fixed to the surface (11) of the building element (5) via a thermally conductive adhesive layer (4).   Device according to claim 1 or 2, wherein the conduit (9) extends in a serpentine, lattice, spiral or bend in the plate (1).   The plate (1) according to any one of claims 1 to 3, wherein the plate (1) is thermally conductively coupled over the surface (11) of the building member (5) and over the main surface (12) facing the surface (11). The device according to item. The device according to claim 1 ^, wherein the density of the plate (1) is 0.04 to 0.10 g / cm ³ .   6. The device according to claim 1, wherein the plate (1) has a thermal conductivity higher than 2 W / mK.   7. A device according to claim 1, wherein the plate (1) is made from a mixture of expanded graphite and a binder, in particular a resin or plastic.   8. A device according to claim 7, wherein the amount of binder is 5 to 50% by weight, preferably 8 to 12% by weight.   The plate (1) is made from a mixture of expanded graphite and a latent heat storage material (PCM), in particular based on salt, wax or paraffin. Equipment.   10. The device according to claim 1, wherein the building member (5) is a concrete ceiling or a concrete wall.   11. The structure according to claim 1, wherein a plurality of plates (1) in which a plurality of conduits (9) are embedded are fixed to the surface (11) of the building member (5). The apparatus of claim 1.   A plurality of conduits (9) of the side-by-side plates (1) are connected to each other to form a conduit circuit, which guides the heating or cooling medium through the conduit (9). The apparatus of claim 11, wherein the apparatus is coupled to a supply apparatus.   Device according to any one of the preceding claims, wherein a reinforcing layer (6) is applied to the surface (13) of the plate (1) opposite the building member (5).   14. The device according to claim 1, wherein a reinforcing layer (6) is applied to both surfaces (12, 13) of the plate (1).   15. The device according to claim 1, wherein the plate (1) is arranged in a frame (2) fixed to the building member (5).   16. Device according to claim 15, wherein the frame (2) is made of a thermally conductive material, in particular a sheet metal.   17. Device according to claim 15 or 16, wherein the plate (1) is glued in the frame (2).   18. A device according to any one of claims 15 to 17, wherein the frame is formed as a cassette (2) open on one side.   19. The device according to claim 15, wherein the plate (1) arranged in the cassette projects beyond the frame edge (2c) on the open side of the cassette.   20. A device according to any one of claims 15 to 19, wherein the frame (2) is formed as a cassette with a perforated bottom plate (2a).   Device according to claim 20, wherein a fleece (3) and a perforated graphite sheet (15) are arranged between the bottom plate (2a) and the plate (1) of the frame (2).   Device according to claim 20 or 21, wherein the graphite sheet (15) is a sheet made of expanded graphite with perforations.   23. A device according to any one of claims 20 to 22, wherein the perforated graphite sheet (15) is firmly bonded to the fleece (3).   24. Apparatus according to any one of claims 20 to 23, wherein the fleece (3) is a glass fiber fleece or a carbon fiber fleece.   25. Apparatus according to any one of claims 20 to 24, wherein the fleece (3) is a carbon fiber fleece bonded to the perforated graphite sheet (15) by calendering.   26. Device according to any one of claims 1 to 25, wherein the plate (1) in which a plurality of conduits (9) are embedded is self-supporting. A room temperature control method for a room restricted at least on one side by a building member (5), wherein the building member (5) has a surface (11) facing the interior of the building member (5) In the form in which the substrate forms a thermal reservoir thermally coupled with a plurality of conduits (9) for guiding heating or cooling media,
The conduit (9) is embedded in a thermally conductive plate (1) containing expanded graphite or made of expanded graphite, the plate (1) being surfaced (11) facing the interior of the building component (5). ) In the form of a thermal contact, so that at least a part of the thermal energy stored in the heating or cooling medium is stored intermediately from the conduit (9) via the heat conductive plate (1) by heat conduction Room temperature control, characterized in that it is transmitted to a thermal reservoir in the room and then supplied to the room later.

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