The invention relates to a ceiling or wall element for fixing to a ceiling or a wall, the ceiling or wall element having a frame with a base plate which can be affixed to the ceiling or the wall, in which a heating or cooling register is disposed. The invention also pertains to the utilization of a composite material consisting of a non-woven fabric and a graphite film as a ceiling or wall element. The invention further relates to a thermally activatable concrete wall or concrete ceiling to which such ceiling or wall elements are affixed.
Ceiling or wall elements which have a frame with a base plate which can be fixed to the ceiling or the wall and a heating or cooling register arranged in the frame are already known from the prior art. Known from DE 20 2007 010 215 U1 for example is a wall or ceiling cladding with a heating or cooling register in the form of pipes which are fixed to heat conducting profiles. The heat conducting profiles rest on a rear side of a cladding surface formed by cladding panels. The cladding panels are fixed to supporting rails having a U-shaped cross-section. The supporting rails and the cladding panels fastened thereon thus form a frame which can be fixed to a ceiling or wall with a base formed by the cladding panels. The heat conducting profiles are arranged in the interior of this frame and abut against the cladding panels. The heat conducting profiles and the pipes fixed thereon form the heating or cooling register. In order to produce good heating conducting contact between the pipes and the cladding surface, binders are provided transversely to the elongate heat conducting profiles which hold at least two adjacent heat conducting profiles on the cladding panel under spring tension.
The heat conducting profiles have an approximately semicircular shoulder on their rear side in which the pipes are arranged. The pipes have heating or cooling medium such as hot or cold water, for example, flowing through them depending on the intended application as a heating or cooling line. The heat conducting profiles are usually made of metal, for example, made of aluminum. The cladding panels can, for example, comprise plasterboard panels.
In such wall or ceiling claddings the efficiency of the heat or cold transmission from the wall or ceiling claddings to the room is very low. This is on the one hand due to the intermediate spaced between the adjacent heat conducting profiles. These intermediate spaces act like an insulating layer and prevent a uniform dissipation of the heat flow over the surface of the wall or ceiling claddings facing the room. On the other hand, the heat or cold transmission from the heating or cooling lines to the cladding panels is very inefficient because the cladding panels comprise poor heat conductors.
It is accordingly an object of the invention to provide a ceiling or wall element which overcomes the above-mentioned disadvantages of the heretofore-known devices and methods of this general type and which provides for a ceiling or wall element so that efficient heat transmission can be ensured between the heating or cooling register and the room to be heated or cooled. Furthermore, the ceiling or wall element should have good sound absorption.
With the foregoing and other objects in view there is provided, in accordance with the invention, a ceiling or wall element for fixing to a ceiling or a wall. The ceiling or wall element comprising:
a frame with a base plate to be affixed to the ceiling or the wall;
a heating or cooling register disposed in said frame; and
a non-woven fabric and a perforated graphite film disposed between said base plate of said frame and said heating or cooling register.
With the above and other objects in view there is also provided, in accordance with the invention, a ceiling or wall element for fixing to a ceiling or a wall, the ceiling or wall element comprising a frame with a base to be affixed to the ceiling or the wall; and a non-woven fabric and a graphite film disposed on said base of said frame.
In accordance with an added feature of the invention, the graphite film comprises a film made of expanded graphite having a perforation. In a preferred embodiment, the graphite film has a hole fraction of between 5% and 20% per unit area, or it has a perforation with a hole fraction greater than 20%.
In accordance with an additional feature of the invention, the frame is made of a thermally conductive material, such as metal sheet or a graphite-modified composite material.
In accordance with another feature of the invention, the non-woven fabric comprises a glass fiber non-woven or a carbon fiber non-woven. In a preferred embodiment, the non-woven fabric comprises a carbon fiber non-woven calendered onto the (perforated) graphite film.
In accordance with a further feature of the invention, the heating or cooling register comprises a fixing profile and heating or cooling pipes affixed thereto, and the perforated graphite film is in thermal contact with a fixing profile.
In accordance with yet a further feature of the invention, the heating or cooling register comprises a lightweight panel of expanded graphite having heating or cooling pipes embedded therein.
With the above and other objects in view there is also provided, in accordance with the invention, ceiling or wall element for fixing to a thermally activatable concrete wall or concrete ceiling, the ceiling or wall element comprising a frame with a base plate to be affixed to the ceiling or the wall; and a non-woven fabric and a perforated graphite film and a lightweight panel of expanded graphite disposed between said base plate of said frame and the wall or ceiling. The expression “activatable” in the context means that the temperature of the object (i.e., the concrete wall, ceiling) may be actively controlled. This is typically done by way of heat exchange with a heat exchange fluid.
In a preferred embodiment of the invention there is provided a thermally activatable concrete wall or concrete ceiling assembly, comprising: pipelines for conducting a heating or cooling fluid extending through a concrete wall or concrete ceiling, and a plurality of ceiling or wall elements as summarized above disposed mutually adjacent one another and affixed on a surface of said concrete wall or concrete ceiling.
The ceiling or wall elements advantageously include a lightweight panel made of expanded graphite, and a thermal coupling between the surface of the wall or ceiling and the wall or ceiling element is formed extensively over an entire principal surface of each graphite lightweight panel.
In other words, a ceiling or wall element which has a frame with a base which can be fixed to a ceiling or a wall, in which a heating or cooling register is disposed, further includes a non-woven fabric and a perforated graphite film disposed between the base of the frame and the heating or cooling register. The non-woven fabric preferably comprises a carbon fiber non-woven. However, it can also comprise a glass fiber non-woven. The carbon fiber non-woven has a higher thermal conductivity than a glass fiber non-woven but is more expensive. The non-woven brings about good sound absorption of the ceiling or wall element. The graphite film preferably comprises a film of expanded graphite which is provided with a perforation. The perforated graphite film ensures good thermal contact between the heating or cooling register and the base plate of the ceiling or wall element. The base of the ceiling or wall element is preferably made of a thermally conductive material, in particular of a metal sheet or a graphite-modified panel such as a graphite-modified plasterboard panel. The frame is preferably formed as a cassette, where at least the base is made of a punched metal sheet or metal sheet provided with a perforation. The punching or the perforation in the base combined with the non-woven fabric resting on the base in the interior of the frame ensures good sound absorption.
The non-woven fabric and the perforated graphite film disposed thereon preferably comprises a composite which can be produced by calendering. Such a composite can particularly expediently be made from a carbon fiber non-woven and a graphite film made of expanded graphite. The production of expanded graphite (so-called expanded graphite) is known, inter alia, from U.S. Pat. No. 3,404,061. In order to produce expanded graphite, graphite intercalation compounds or graphite salts such as, for example, graphite hydrogen sulfate or graphite nitrate are heated in a shock manner. The volume of the graphite particles is thereby increased by a factor of about 200-400 and at the same time the bulk density decreases to values of 2-20 g/l. The expanded graphite thus obtained consists of worm- or concertina-shaped aggregates. If completely expanded graphite is compacted under the directional action of pressure, the layer planes of the graphite are preferably arranged perpendicular to the direction of action of the pressure, where the individual aggregates become entangled. In this way, self-supporting surface structures such as, for example, webs, plates or molded bodies can be produced from expanded graphite. Thin films (having thicknesses in the range of 50 μm to 3 mm) can be produced by pressing or rolling webs of expanded graphite. When calendering a film of expanded graphite thus produced with a carbon fiber non-woven, the carbon fibers of the non-woven surface and the surface of the graphite film become entangled so that a firm and non-detachable composite is formed between the carbon fiber non-woven and the graphite film.
Perforation of the graphite film increases its flexibility and thereby facilitates the handling of the film. Since graphite is a brittle material, there is a risk that the film will tear or break when handling thin films of expanded graphite. This risk can be reduced significantly by the perforation of the graphite film.
The heating or cooling register can comprises heating or cooling lines fixed to heat conducting profiles. In order to ensure good thermal contact between the heating or cooling register and the base of the frame, the base is in thermal contact with the heat conducting profiles via the composite comprising the non-woven fabric and the perforated graphite film.
The heating or cooling register can also comprise a lightweight panel of expanded graphite in which heating or cooling lines are embedded. In this exemplary embodiment the surface of the graphite lightweight panel is preferably in thermal contact with the perforated graphite film over its entire principal area. Good thermal contact between the heating or cooling lines and the base of the frame is made in this way via the good heat-conducting composite comprising the perforated graphite film and the non-woven fabric. The heat (or cold) carried in the heating or cooling lines can be distributed very efficiently and uniformly over the entire surface of the ceiling or wall element in the room in which the ceiling or wall element is located. The surface of the graphite lightweight panel opposite the graphite film is preferably in thermal contact over its entire principal surface with the surface of the wall or the ceiling to which the ceiling or wall element is fixed. As a result of this thermal contact, the heat coming from the heating or cooling lines can be released partially via the graphite lightweight panel to the wall or ceiling so that the mass of the wall or ceiling can be used as a thermal accumulator for a delayed release of heat.
So-called concrete core activation systems are known from the prior art for the air conditioning of rooms having concrete ceilings or concrete walls. In these systems pipes carrying heating or cooling media are mounted in, below or on the concrete ceiling 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 delivery of the stored heating or cooling energy, an energy-efficient air conditioning of the rooms can be achieved. Thus, for example, at night a cooling fluid (for example, water) is cooled and passed through the pipes in a concrete core activated ceiling or wall, whereby the ceiling or the wall is slowly cooled. The cooling energy stored in the concrete ceiling or wall can then be released into the room during the day in particular in the warm summer months, to slowly lower the room temperature in the room.
For the cladding of such thermally activatable concrete ceilings or walls, the invention provides a ceiling or wall element comprising a frame with a base which can be fixed to the wall or the ceiling, where a non-woven fabric and a perforated graphite film are provided between the base of the frame and the wall or the ceiling. In this exemplary embodiment a lightweight panel of expanded graphite is preferably additionally provided between the graphite film and the wall.
In this exemplary embodiment of the invention the non-woven ensures good sound absorption of the ceiling or wall element. Good thermal contact between the thermally activatable wall or ceiling and the base of the frame is ensured by means of the perforated graphite film and graphite lightweight panel provided between the graphite film and the wall or ceiling surface. This provides efficient heat transmission between the thermally activatable wall or ceiling and the room.
Other features which are considered as characteristic for the invention are set forth in the appended claims.
Although the invention is illustrated and described herein as embodied in a ceiling or wall element with a heating or cooling register, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.
The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
Referring now more specifically to the drawing figures, the exemplary embodiments of the invention described hereinafter are illustrated by reference to the use of ceiling or wall elements according to the invention for fixing to a ceiling 5 extending in the horizontal plane. We therefore talk of ceiling elements in each case. The ceiling or wall elements according to the invention can however also be used in a corresponding manner for fixing to a vertical wall. In the exemplary embodiments shown in the drawings the same or corresponding parts are provided with the same reference numbers.
Insofar as thermally activatable concrete ceilings or walls are mentioned, this is understood as concrete ceilings or walls in which pipes are laid for the passage of a heating or cooling medium. These pipes are used for the thermal activation of the ceiling or the wall.
The frame 2 comprises a base formed by a base plate 2a and side walls 2b disposed thereon or formed integrally with the base plate 2a. A fixing flange 2c is formed on the upper edge of the side walls 2b by which means the frame 2 can be fixed to the ceiling, in particular can be screwed thereon. The frame 2 is preferably formed in a cassette shape with four side walls 2b arranged circumferentially around the base plate 2a. The frame 2 is preferably made of metal, in particular from a metal sheet. The base plate 2a is provided with a perforation. The holes of the perforation in the base plate 2a ensure that sound waves can penetrate into the frame 2 and can be damped there.
A heating or cooling register 9 is arranged in the cassette-shaped frame 2. In the exemplary embodiment shown in
The fixing profiles 11 are disposed on a perforated graphite film in thermal contact with the graphite film 1. Expediently, the underside of each fixing profile 11 is adhesively bonded to the graphite film 1 by means of a thermally conducting adhesive. A non-woven fabric 3 is disposed between the perforated graphite film 1 and the inner surface of the base plate 2a. The non-woven fabric 3 can comprises a glass fiber non-woven or preferably a carbon fiber non-woven. The non-woven 3 is adhesively bonded to the inner surface of the base plate 2a by means of a thermally conducting adhesive.
The non-woven fabric 3 and the perforated graphite film 1 expediently comprise a composite material. A composite produced by calendering from a carbon fiber non-woven 3 and the perforated graphite film 1 is particularly suitable.
The graphite film 1 expediently comprises a thin film of expanded graphite with a perforation. A hole fraction of 5% to 20% ensures good handling of the perforated graphite film 1 and prevents breaking or tearing of the graphite film.
In both exemplary embodiments the non-woven expediently has a thickness of 50 μm to 3 mm and the thickness of the perforated graphite film is preferably between 200 μm and 3 mm.
A non-woven fabric 3 lying on the base plate 2a and preferably glued thereon and a perforated graphite film 1 located thereon is again disposed in the interior of the cassette-shaped frame 2. The non-woven fabric 3 and the perforated graphite film 1 expediently again comprise a carbon fiber non-woven and a film of expanded graphite. A lightweight panel 13 of expanded graphite is disposed on the graphite film 1 in flat and thermal contact therewith.
For fixing the ceiling element 10 on the thermally activatable concrete ceiling 5, the frame 2 is fixed in a known manner to the surface 14 of the ceiling 5, for example, by screwing. In order to ensure the best possible thermal contact between the upper side 15 of the graphite lightweight panel 13 and the surface 14 of the ceiling 5, the upper side 15 of the graphite lightweight panel 13 is glued to the ceiling surface 14 with a thermally conducting adhesive 4. However, the use of an adhesive can also be omitted. In particular, the use of an adhesive can be omitted if the surface 15 of the graphite lightweight panel 13 projects over the upper edge of the side walls 2b of the frame 2 when not yet mounted. Then, when screwing the frame 2 to the ceiling surface 14, the lightweight panel 13 made of compressible graphite is slightly compressed. This ensures good thermal contact between the upper side 15 of the graphite lightweight panel 13 and the ceiling surface 14 over the entire area, where slight unevenesses in the ceiling surface 14 can be compensated by compressing.
The material composite used in the exemplary embodiments of
Like the material composite used in
Number | Date | Country | Kind |
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102009055440.8 | Dec 2009 | DE | national |
102009055441.6 | Dec 2009 | DE | national |
102009055442.4 | Dec 2009 | DE | national |
102009055443.2 | Dec 2009 | DE | national |
102009055444.0 | Dec 2009 | DE | national |
102010041085.3 | Sep 2010 | DE | national |
This application is a continuation, under 35 U.S.C. §120, of copending international application No. PCT/EP2010/070977, filed Dec. 31, 2010, which designated the United States; this application also claims the priority, under 35 U.S.C. §119, of German patent application Nos. DE 10 2009 055 441.6, DE 10 2009 055 442.4, DE 10 2009 055 443.2; DE 10 2009 055 444.0; DE 10 2009 055 440.8, each filed on Dec. 31, 2009; and DE 10 2010 041 085.3, filed on Sep. 20, 2010; the prior applications are herewith incorporated by reference in their entirety.
Number | Date | Country | |
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Parent | PCT/EP2010/070977 | Dec 2010 | US |
Child | 13540039 | US |