DE102009055441A1 - Device for controlling temperature in room of building, has thermally coupled pipes embedded in plate, which contains expanded graphite, where plate is thermal-contacted with surface area of structural element - Google Patents

Abstract

The device gas a structural element (5) forming a thermal storage, and a surface area (11) viewed in a room (R). Thermally coupled pipes (9) are enclosed with the element and connected with a heat- or cooling medium. The pipes are embedded in a graphite plate (1), which is made from mixture of expanded graphite and adhesive agent e.g. resin and plastic or phase-change material e.g. salt or wax or paraffin base. The plate is extensively thermal-contacted with the surface area of the element over a thermally controlling adhesive layer, and glued with a frame that is made of sheet metal. An independent claim is also included for a method for temperature controlling a room.

Description

The invention relates to a device and a method for controlling the temperature of a room according to the preambles of claims 1 and 27.

For the air conditioning of rooms with concrete ceilings or concrete walls so-called concrete core activation systems are known from the prior art. In these, heating or cooling media leading pipes are installed in, under or on the concrete floor or the concrete wall. By storing the heating or cooling energy in the concrete mass of the ceiling or the walls and a time-delayed release of the stored heating or cooling energy, an energy-efficient air conditioning of the rooms can be achieved. Thus, for example, a cooling fluid (for example, water) may be cooled down at night and passed through the pipelines in a concrete core-activated ceiling or wall, as a result of which the ceiling or the wall cools down slowly. The cooling energy thus stored in the concrete ceiling or wall can then be released slowly into the room during the day, especially in warm summer months, to lower the room temperature.

However, the installation of such thermally activatable ceilings or walls is limited to new buildings. In the renovation of old buildings such concrete core activation of the ceiling or walls can not be retrofitted. For ceilings or walls with a concrete core activation is also disadvantageous that the laid in the concrete ceiling or wall pipes can be damaged accidentally, for example by drilling holes. A repair of damaged piping is hardly possible, since the cast-in pipes are difficult to access for repair. The statics and stability of the piped ceilings or walls also suffers from the embedded piping. Moreover, the production of such concrete core activation systems is very time consuming and costly. Another disadvantage lies in the inertia of the thermal system, which is based on the time-delayed release of the thermal energy stored in the concrete storage mass to the room to be tempered.

To eliminate these disadvantages, temperature control systems are known from the prior art, which can also be subsequently arranged on pipe-free ceilings or walls. These temperature control systems usually include ceiling or wall elements in which pipelines are arranged, which can be acted upon by a heating or cooling medium. These ceiling or wall elements are attached to the ceiling or wall. The stored in the heating or cooling medium, which is passed through the pipes, stored thermal energy is dissipated via a frame or a panel of the ceiling or wall elements in the room to be tempered by heat radiation and free convection. Such a system is, for example, in the EP 1371915 A1 described, come in the phase change materials as heat storage for use.

These tempering systems have the disadvantage that the thermal energy is released directly and instantaneously into the room by heat radiation and convection from the heating or cooling medium flowing in the pipes. The surfaces of the ceilings or the walls are also covered in these tempering with the ceiling or wall elements. As a result, the ceiling or wall surface is thermally separated from the room to be tempered, which is why the mass of the ceiling or the walls for a storage cooling (or heating) at night can not be used.

Proceeding from this, the present invention seeks to provide a device and a method for controlling the temperature of a room in which the mass of the ceiling or walls can be used as a thermal storage, without piping for the passage of a heating or cooling medium for thermal activation of the memory must be placed in the ceilings or walls. The invention is further based on the object to show a most energy-efficient temperature control with short response times. In addition, it should be possible to retrofit this tempering also in the renovation of old buildings.

These objects are achieved with a device for controlling the temperature of a room with the features of claim 1 and with a method having the features of claim 27. Preferred embodiments of the device according to the invention can be found in the dependent claims 2 to 26.

The invention will be explained in more detail by means of embodiments with reference to the accompanying drawings. The drawings show:

1 : Schematic sectional view of a device according to the invention for controlling the temperature of a room in a first embodiment;

2 : Schematic sectional view of a ceiling or wall element for a tempering device according to the invention in a second embodiment;

3 : Schematic sectional view of the second embodiment of a tempering device according to the invention with the ceiling or wall element of 2 ,

In 1 a first embodiment of a temperature control device according to the invention is shown. This includes a on a component 5 concrete or tile element 10 , In the device 5 it can be a ceiling or a wall or a floor of the room R to be tempered. The component 5 may also be constructed of another conventional building material that is capable of storing heat and / or cold, such as clay or natural stone. At the element 10 then it is accordingly a ceiling, wall or a floor element, which at the surface facing in the room 11 of the component 5 is arranged. Due to its large mass, the component represents 5 a thermal storage in which thermal energy (in the form of heat or cold) can be stored.

At the element 10 it is a plate 1 containing expanded graphite or consisting entirely of graphite expandate.

The production of expanded graphite (graphite expandate) is inter alia from the US 3,404,061-A known. For the production of expanded graphite Graphiteinlagerungsverbindungen or graphite salts such. B. graphite hydrogen sulfate or graphite nitrate shock-heated. The volume of the graphite particles increases by a factor of about 200-400 and at the same time the bulk density drops to values of 2-20 g / l. The graphite expandate thus obtained consists of worm-shaped or accordion-shaped aggregates. If fully expanded graphite is compacted under the direction of a pressure, the layer planes of the graphite arrange preferentially perpendicular to the direction of action of the pressure, whereby the individual aggregates become entangled with one another. In this way, self-supporting fabrics such. B. sheets, plates or moldings made of expanded graphite.

To stiffen and increase the stability of such graphite plates or shaped bodies, the expanded graphite with hardening binders, such as. As resins or plastics, in particular elastomers or duromers, are mixed. To improve the stability of sheets of expanded graphite, the blending of the expanded graphite with thermoplastic and / or thermosetting plastics, which can be introduced into the expanded graphite, for example by impregnation or by a powder method, is particularly suitable. After curing of the binder mixed with the expanded graphite, the graphite moldings or plates produced from these mixtures have sufficient stability for the intended use according to the invention. The graphite plates produced in this way are in particular self-supporting and can easily be fixed, for example, by gluing or screwing to components such as ceilings or walls.

Pure expanded graphite as well as blends of expanded graphite with binders have very good thermal conductivity. The thermal conductivity of a mixture of expanded graphite with a binder is still very high at a 50% by weight binder content, depending on the type of binder used. As far as is referred to in the following graphite plates, these are understood to mean plates which consist either of pure graphite expandate or of a mixture of expanded graphite with a binder.

It is also possible to produce graphite sheets from expanded graphite blends with phase change materials (PCM). For this purpose, common phase change materials, for example, on paraffin, wax or salt, be mixed in the production of graphite plates. Such a graphite plate with a phase change material can in the temperature control according to the invention as a further thermal storage (latent heat storage) in addition to acting as a thermal storage device 5 be used.

In the in 1 represented graphite plate 1 are pipelines 9 embedded. The pipelines 9 are preferably serpentine inside the plate 1 arranged. Other installation forms of piping, such. As a spiral, grid-shaped or meandering arrangement, or an arrangement only in the edge regions of the plate 1 is conceivable. The ends of the in the plate 1 running pipelines 9 are sent to a conveyor for the passage of a heating or cooling medium (such as hot or cold water) through the pipes 9 connected. Around the entire surface facing room R 11 of the component 5 with elements 10 can also provide several such elements 10 behind or next to each other and arranged on the surface 11 be attached. The ends of the pipes 9 every element 10 then be with the associated ends of the adjacent elements 10 connected to form a line circuit and the line circuit is coupled to the conveyor for the passage of the heating or cooling medium.

The attachment of the elements 10 is preferably carried out by a thermally conductive adhesive 4 with which the one main surface 12 the plate on the surface 11 of the component 5 is glued. By gluing the main surface is 12 the plate 1 flat and preferably over the entire main surface 12 in thermal contact with the surface 11 that through the device 5 formed thermal storage.

The other main area 13 the plate 1 can, as in the 1 shown embodiment, with a stiffening layer 6 be provided. At the stiffening layer 6 it may be, for example, a plaster layer or a pasted hard cardboard or plasterboard layer. Also combinations of plaster layers and embedded textile fabrics, such as. As nets, fabrics, knitted, knitted or the like is possible. Through the stiffening layer 6 On the one hand, the stability of the graphite plate 1 can be increased and on the other hand, the pointing in the space R main surface 13 the plate 1 be dressed visually appealing. The application of a stiffening layer 6 especially suitable for plates 1 on, which are made of pure graphite expander (without the addition of binder).

The in the plate 1 running pipelines 9 Already in the production of graphite plate 1 be introduced. At the pipelines 9 These are preferably pipes made of metal, for example copper, or plastic pipes, for example made of polypropylene or crosslinked polyethylene. However, because of the better heat transfer tubes made of metal are preferable. The pipelines 9 can - as in the embodiment of 1 shown - completely in the plate 1 be embedded. However, it is also possible to use the piping 9 Arrange so that they are flush with a major surface 12 or 13 the plate 1 to lock.

For embedding the pipelines 9 in the plate 1 can the piping 9 in the plate production in the landfill of the worm or accordion-shaped graphite aggregates inserted and this composition then in a known manner by pressure (for example by means of rollers or printing plates) to a dimensionally stable graphite plate 1 be pressed. In order to increase the stability of the plates, one of the already mentioned binders can be added during the manufacturing process. The graphite plates thus produced 1 with piping embedded in it 9 typically have thicknesses between 8 and 50 mm. The density of graphite plates 1 is regularly in the range of 0.01 to 0.5 g / cm ³ (depending on the proportion of added binder). The graphite plates 1 have a thermal conductivity of 3 to 6 W / mK.

Due to the good thermal conductivity of the graphite plate 1 can be in a through the piping 9 guided heating or cooling medium stored thermal energy to a certain extent, initially by heat conduction from the pipes 9 to the free main surface 13 the plate 1 directed and discharged from there by heat radiation and free convection to be tempered room R. This heat dissipation (or cooling release when passing a cooling medium through the pipes) takes place very rapidly, as a result of which the space can be heated up very rapidly (or cooled down). Another part of the thermal energy stored in the heating or cooling medium is by conduction of heat from the pipelines 9 over the thermally conductive plate 1 to the of the device 5 transferred formed thermal storage. This heats the thermal store (or cools it down when piping through a cooling medium). The thermal storage can then release the so temporarily stored thermal energy with a time delay to the room, wherein the good thermal conductivity of the plate 1 ensures that this is largely lossless. The heating (or cooling) of the room R taking place in this way takes place over a longer time scale (of a few hours). The tempering system according to the invention is therefore able to bring the room to be tempered R both rapidly and by utilizing the thermal storage in a slow manner to a desired room temperature. For example, in the summer at night, the thermal storage by passing a cooling medium (for example, cold water) through the pipes 9 be cooled. During the day, the thermal storage can then be used to cool the room via a time-delayed release of the cold to the room.

In a corresponding manner, the tempering system according to the invention can be heated in the winter during the day initially for instantaneous heating of the room by passing a heating medium through the pipes. At the same time, the thermal store is charged with heat. At night, the flow of the heating medium can be turned off, as the time-delayed release of heat from the loaded thermal storage is sufficient to keep the room at a (lower) room temperature during the night.

In the 2 and 3 a further embodiment of a tempering system according to the invention is shown. Same or corresponding parts are in the 2 and 3 provided with the same reference numerals as in 1 ,

At the in 3 shown embodiment of an inventive device for Temperature control of a room R is a ceiling element 10 on a component designed as a concrete floor 5 attached. The component 5 forms a thermal store with the concrete mass of the ceiling as storage mass. The ceiling element 10 has a frame 2 on, on the surface facing R in the room 11 of the component 5 attached, in particular screwed. The frame 2 is formed as a cassette which is open on one side (namely its top). The frame 2 is preferably made of a thermally conductive material, such as. B. made of a metal sheet. The frame 2 has a base plate 2a and four or with the bottom plate 2a integrally formed side walls 2 B , At least the bottom plate 2a (and possibly also the side walls 2 B ) is formed of a perforated plate (ie a metal sheet with a perforation). In the frame 2 is a graphite plate 1 inserted. The composition of the graphite plate 1 corresponds to the plate 1 of the embodiment of 1 , As in this embodiment, pipes are also here 9 in the graphite plate 1 embedded and run there snake, lattice, spiral or meandering. The graphite plate 1 is preferably via a thermally conductive adhesive 4 on the surface 11 of the component 5 glued flat. The main area 12 the graphite plate 1 is thus expediently in thermal contact with the surface over its entire surface 11 of the component 5 , On the adhesive layer 4 However, it can also be waived (see below).

Between the bottom plate 2a of the frame 2 and the graphite plate 1 is preferably a nonwoven 3 and a graphite foil 15 arranged. At the fleece 3 it may be, for example, a glass fiber or a carbon fiber fleece. In connection with the hole perforation of the bottom plate 2 represents the fleece 3 a good sound absorption of the ceiling element 10 for sure. At the graphite foil 15 it is a thin sheet of expanded graphite. The thickness of the graphite foil 15 is preferably between 0.05 mm and 3 mm, in particular between 0.2 and 3 mm.

Preferably, it is the nonwoven 3 and the graphite foil disposed thereon 15 a non-detachable composite, which can be produced for example by calendering. Such a composite can be particularly useful from a carbon fiber fleece and a graphite foil 15 be made of expanded graphite. When calendering a thin sheet of expanded graphite with a carbon fiber nonwoven, the carbon particles of the nonwoven surface and the surface of the graphite sheet interlock with each other to form a strong and non-releasable bond between the carbon fiber nonwoven fabric 3 and the graphite foil 15 arises. Particularly useful is the use of a perforated graphite foil 15 , A perforation of the graphite foil 15 namely increases their flexibility and thereby facilitates the handling of the film. Since graphite is a brittle material, there is a risk that the film will crack or break when handling thin sheets of expanded graphite. This danger can be caused by a perforation of the graphite foil 15 be significantly reduced.

In 2 is a sectional view of a ceiling element 10 shown as it is in the 3 illustrated embodiment of the temperature control device according to the invention can be used. As it turned out 2 results, the upper main surface stands 12 the graphite plate 1 over the top edge 2c the side walls 2 B of the frame 2 out. When using such a ceiling element 10 may be due to the sticking of the graphite plate 1 on the surface 11 of the component 5 be waived. For fastening the ceiling element 10 on the device 5 will be the frame 2 on the device 5 screwed. When screwing on the frame 2 on the surface 11 of the component 5 becomes the graphite plate 1 squeezed until the main surface 12 the plate 1 flush with the top edge 2c the side walls 2 B completes the frame. Compressing the graphite plate 1 is made possible by the deformability of the expanded graphite. The perpendicular to the surface 11 compressed graphite material of the plate 1 is after the attachment of the ceiling element 10 on the device 5 expedient over the entire main surface 12 in thermal contact with the surface 11 , Due to the good deformability of the graphite material of the plate 1 can also be unevenness and protrusions in the surface 11 of the component 5 be compensated.

The arrangement of the ceiling element 10 or more adjacent ceiling elements on the surface 11 of the component 5 corresponds to the embodiment described above the 1 , Also, the operation of the temperature of the 3 is the same as in the embodiment of 1 ,

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1371915 A1 [0004]
• US Pat. No. 3,440,061 A [0014]

Claims (27)

Device for controlling the temperature of a room, the device comprising at least one component ( 5 ), which forms a thermal store and a surface facing the room ( 11 ), as well as with the component ( 5 ) thermally coupled pipelines ( 9 ), which can be acted upon by a heating or cooling medium, characterized in that the pipelines ( 9 ) into a plate ( 1 ), which contains expanded graphite or consists of graphite expandate, embedded and the plate ( 1 ) flat with the surface facing the room ( 11 ) of the device is in thermal contact. Device according to claim 1, characterized in that the plate ( 1 ) of expanded graphite via a thermally conductive adhesive layer ( 4 ) on the surface ( 11 ) of the component ( 5 ) is attached. Device according to claim 1 or 2, characterized in that the pipelines ( 9 ) serpentine, latticed, spiral or meandering in the plate ( 1 ). Device according to one of the preceding claims, characterized in that the plate ( 1 ) over its entire surface 11 facing main surface ( 12 ) with the surface ( 11 ) of the component ( 5 ) is in thermally conductive connection. Device according to one of the preceding claims, characterized in that the density of the plate ( 1 ) is between 0.04 and 0.10 g / cm ³ . Device according to one of the preceding claims, characterized in that the plate ( 1 ) has a thermal conductivity of more than 2 W / mK. Device according to one of the preceding claims, characterized in that the plate ( 1 ) is made of a mixture of expanded graphite and a binder, in particular a resin or a plastic. Device according to claim 7, characterized in that the proportion of the binder is from 5 to 50% by weight and preferably from 8 to 12% by weight. Device according to one of claims 1 to 6, characterized in that the plate ( 1 ) is made of a mixture of expanded graphite and a latent heat storage material (PCM), in particular on a salt, wax or paraffin basis. Device according to one of the preceding claims, characterized in that it is in the device ( 5 ) is a concrete or concrete wall. Device according to one of the preceding claims, characterized in that on the surface ( 11 ) of the component ( 5 ) several plates ( 1 ) with piping embedded therein ( 9 ) are mounted side by side. Device according to claim 11, characterized in that the pipelines ( 9 ) of adjacent plates ( 1 ) are connected to one another to form a line circuit and that the line circuit to a conveyor for the passage of a heating or cooling medium through the pipes ( 9 ) is coupled. Device according to one of the preceding claims, characterized in that on the said component ( 5 ) facing away from the surface ( 13 ) of the plate ( 1 ) a stiffening layer ( 6 ) is applied. Device according to one of the preceding claims, characterized in that on both surfaces ( 12 . 13 ) of the plate ( 1 ) a stiffening layer ( 6 ) is applied. Device according to one of the preceding claims, characterized in that the plate ( 1 ) in one at the component ( 1 ) fixed frame ( 2 ) is arranged. Device according to claim 15, characterized in that the frame ( 2 ) is made of a thermally conductive material, in particular of a metal sheet. Device according to claim 15 or 16, characterized in that the plate ( 1 ) in the framework ( 2 ) is glued. Device according to one of claims 15 to 17, characterized in that the frame as a cassette ( 2 ) is formed, which is open on one side. Device according to one of claims 15 to 18, characterized in that the plate arranged in the cassette ( 1 ) on the open side of the cassette over its edge ( 2c ) protrudes. Device according to one of claims 15 to 19, characterized in that the frame ( 2 ) as a cassette with a perforated bottom plate ( 2a ) is trained. Device according to claim 20, characterized in that between the bottom plate ( 2a ) of the frame ( 2 ) and the plate ( 1 ) a fleece ( 3 ) and a perforated graphite foil ( 15 ) are arranged. Device according to one of claims 20 or 21, characterized in that it is in the graphite foil ( 15 ) is a sheet of expanded graphite with a hole perforation. Device according to one of claims 20 to 22, characterized in that the perforated graphite foil ( 15 ) firmly with the fleece ( 3 ) connected is. Device according to one of claims 20 to 23, characterized in that it is in the nonwoven ( 3 ) is a glass fiber fleece or a carbon fiber fleece. Device according to one of claims 20 to 24, characterized in that it is in the nonwoven ( 3 ) is a carbon fiber nonwoven, which by calendering with the perforated graphite foil ( 15 ) connected is. Device according to one of the preceding claims, characterized in that the plate ( 1 ) with the piping embedded therein ( 9 ) is self-supporting. Method for controlling the temperature of at least one side of a component ( 5 ) limited space, wherein the device ( 5 ) a surface facing the room ( 11 ) and the mass of the component ( 5 ) forms a thermal storage, which with pipelines ( 9 ), through which a heating or cooling medium is passed, is thermally coupled, characterized in that the pipelines ( 9 ) in a thermally conductive plate ( 1 ), which contains expanded graphite or consists of graphite expandate, embedded and the plate ( 1 ) flat with the surface facing the room ( 11 ) of the component ( 5 ) is in thermal contact, so that at least a portion of the thermal energy stored in the heating or cooling medium by heat conduction from the pipelines ( 9 ) over the thermally conductive plate ( 1 ) is transferred to the thermal storage for temporary storage and is delivered there from the time delay to the room.

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