DE29910425U1 - Wall or ceiling structure with integrated space heating or cooling system and holder for it - Google Patents

Description

Manfred Reckzeh
Fürstenbergstr. 25, 63457 Hanau

Wall or ceiling projection with integrated room heating or
Cooling system and bracket for it

The present invention relates to a wall or ceiling projection with an integrated room heating or cooling system, with a substructure which can be fastened to the wall or ceiling, with pipes for the heating or cooling medium which are arranged in cavities of the substructure or below the substructure, optionally with heat-conducting fins which are arranged on the pipes, and with a cover plate which forms the outer surface facing the room.

Known wall or ceiling projections contain a substructure that is attached to the wall or ceiling directly or via a suspension, and on which cover panels are arranged, which form the external surface facing the room. The substructure serves, among other things, to reduce the room height to a desired level, to compensate for unevenness in the wall or ceiling, to provide a mounting base for the cover panels and, if necessary, to accommodate insulation.

It is also known to install a room heating or cooling system between the wall or ceiling and the cover plates. For the sake of simplicity, the following will only refer to a ceiling projection with a heating system, without explicitly mentioning each time that the same

Designs also apply to wall projections and that the heating system can in principle also be used as a cooling system.

The construction of a ceiling projection with a room heating system is carried out in the state of the art by first attaching the substructure to the ceiling. Bends are welded to the pipes to form registers, adapted to the straight pipe sections of the room heating system. The pipe register is then hung under the ceiling using wires and eyelets, and heat-conducting fins are attached to the pipes from below. In the next step, the cover plates are attached to the substructure. Only when these are screwed in can the wires on which the pipe register hangs be cut in order to lower the pipe register with the heat-conducting fins so that it lies on the cover plates. The described state of the art method is very time-consuming and requires a lot of space for the welded pipe registers. Furthermore, only steel pipes can be used. A particular disadvantage is that lowering the pipe register usually involves a jolt and can hardly be done in a controlled manner, since access to the substructure is blocked by the already attached cover plates.

Insulation is also not possible or only possible with great difficulty, since the space between the ceiling and the cover plates is blocked by the suspended pipe registers or wires before the cover plates are attached and by the cover plates themselves after they are attached.

The present invention therefore has the task of avoiding the disadvantages of the prior art and of providing a wall or ceiling extension with an integrated room heating or cooling system and components for this, which is easier and more cost-effective to build and in which conventional materials and systems can be used. Furthermore, better heat transfer should take place and good insulation should be possible.

This object is achieved by a wall or ceiling projection which contains the following elements in a known manner: a substructure which can be fastened to the wall or ceiling; pipes for the heating or cooling medium which are arranged in cavities in the substructure or beneath the substructure; optionally heat-conducting fins which are arranged on the pipes; and a cover plate which forms the outer surface facing the room. According to the invention, the wall or ceiling projection is characterized in that it has brackets which can be fastened to the substructure and/or the wall or ceiling and which can accommodate the pipes and hold them in an adjustable position.

The brackets according to the invention ensure that the pipes can be easily installed in their final position after or together with the substructure. The pipe sections are inserted into the brackets on the ceiling or wall and connected to one another. Hanging them on wires is not necessary. The heat-conducting fins can also be easily attached to the easily accessible pipes. Since the brackets can hold the pipes in an adjustable position, the entire pipe system can be aligned flat. Differences in height in the wall, ceiling or substructure can be easily compensated for. The cover plates can then be attached to the substructure without any subsequent manipulation of the pipes being necessary.

Since the pipes are leveled, they or the heat-conducting lamellas lie well and evenly on the cover plates everywhere, which improves the heat transfer from the pipes to the cover plates and vice versa. A further advantage of the arrangement according to the invention is that the pipes are supported by the brackets and therefore do not rest on the cover plates with their weight. The cover plates can therefore be removed again at a later date in order to maintain the hanging pipes. Furthermore, unforeseen changes to the construction can be reacted to immediately.

by adapting the design, as the system is very flexible.

The wall or ceiling projection can advantageously have an insulating layer, which can be arranged in particular between the wall or ceiling and the substructure. Such an insulating layer prevents heat loss from the pipes to the ceiling or wall. The insulating layer can be attached without any problems within the scope of the construction according to the invention, since it can be integrated into the substructure in the usual way. Unlike with the prior art, no space has to be kept free for hanging pipe registers on wires, which later have to be cut again. Instead, the pipe system is mounted on the substructure from below and therefore does not conflict with the insulating layer. All known common insulating materials can be used as insulating materials and installed in the usual way.

The insulation layers mentioned can advantageously be designed in such a way that they have elevations on the side facing the cover plate. The heat-conducting fins can then be placed on these elevations so that they are pressed tightly against the cover plate and form a good heat transfer to it. At the same time, the contact area with the insulation layer is small so that the heat flow in this direction is minimal.

According to a preferred development of the invention, the pipes between two heat-conducting lamellas are surrounded by elastic thickenings. These thickenings can be designed in the shape of sleeves, for example. They can ensure that the pipe cannot bend even over long distances between two supports, since the thickenings provide a resilient support. This ensures that the lamellas are evenly supported.

The substructure is preferably designed in such a way that it has parallel spaced base rails and transverse

•c ·

This includes support rails that are parallel to and spaced apart. Grid-shaped substructures of this type are known in various designs and are used in particular in office buildings. They can be made of metal, plastic and/or wood. Due to their construction, they contain hollow spaces in which the heating or cooling pipes can be laid without having to create a separate space. The room heating or cooling system can therefore be integrated into such common substructures particularly cost-effectively.

Since the support rails preferably extend to the side walls (in ceiling heating systems) or to the ceiling or floor (in wall heating systems), through-openings are preferably provided near the front sides of the support rails in order to be able to guide the meandering heating pipes through the support rails.

Preferably, separate end parts are provided for this purpose, which are inserted into the front sides of the support rail body.

These end pieces can also have an opening for a cable feedthrough.

The invention further comprises a stud wall with an integrated room heating or cooling system, which is characterized in that a first wall projection is connected to a second wall projection that is a mirror image of the first wall projection and the wall projections are designed in the manner described above. Mirror image does not mean that the wall projections are constructed and dimensioned exactly the same, but that the sequence of the layer structure is the same. A support wall can be located between the two wall projections. However, one wall projection can also be attached directly to the other, with the projections being back to back and supporting each other. In this way, a stud wall can be easily constructed.

which has heating or cooling on both outer surfaces.

The invention further comprises a holder for pipes of a space heating or cooling system. This is essentially U-shaped, with at least one outer leg of the U being elastic and at least one outer leg having an inwardly directed thickening at its free end. The two outer legs are preferably designed symmetrically with these two properties. Such a holder is suitable for the wall or ceiling projections described above in order to accommodate the pipes there. The outer diameter of the pipes corresponds to the inner distance between the outer legs of the U. Since at least one outer leg has an inwardly directed thickening at its free end, the distance between the outer legs is somewhat narrower at this point. The pipe therefore only gets into the interior between the two outer legs of the U if at least one of the outer legs gives way by the amount of the thickening and then springs back into its old position. In this way, the pipe can be inserted into the holder and is then held in place. Furthermore, the depth at which the pipe sits in the holder is variable. To achieve this, the length of the outer legs is greater than the inner distance between them, preferably by 10 to 100%. A certain position of the pipe between the legs of the U can be fixed by static friction of the pipe with the outer legs, for which purpose the outer legs have a roughened surface or a surface covered with a coating (e.g. rubber). Alternatively, the outer legs can also have a toothing on which the pipes can snap into place in stages. An important advantage of the holders according to the invention is that they are accessible for inserting the pipes from below (the opening of the U) and that these can be easily attached there by "clipping".

The middle leg of the bracket should have means for attachment to a surface. This can be an adhesive surface, for example. However, it is preferable to have at least one through hole in the middle leg through which

-7

the bracket can be screwed (or nailed, riveted, etc.) in place. This type of fastening is easy to carry out and results in high stability.

Furthermore, the middle leg of the bracket preferably has an inwardly curved shape. This means that the curvature runs counter to the "normal" curvature of the U. The bracket therefore rests on a flat surface at two points, between which the middle leg forms a bridge. This shape has the advantage that when the bracket is fixed to the surface, with the middle leg pressed onto the surface and the curvature thus flattened, the bracket is pre-tensioned. This reduces the distance between the two outer legs.

In the following, the invention is explained by way of example with reference to the figures.

Fig. 1 shows a perspective view of a ceiling projection with integrated heating.

Fig. 2 shows a section along the line A-A of Figure 1.

Fig. 3 shows a bracket in front and side view.

Fig. 4 shows a section through a sloping roof extension.

Fig. 5a and 5b show sections through a wall projection.
30

Fig. 6 shows a section through a stud wall heated on two sides.

Fig. 7 shows schematically the arrangement of through-openings in the support rails.

Fig. 8 shows the structure of a closure part in a sectional view along the section plane AA in Fig. 7.
40

Figure 1 shows the structure of a typical ceiling substructure 1 (hereinafter referred to as "ceiling projection ¹¹ "). A section through this ceiling projection 1 along the line AA is shown enlarged in Figure 2.

The ceiling projection is attached to the ceiling of a room (not shown) with hangers 2. It consists of the base profiles 4 arranged parallel to one another at a distance from one another, to which the support profiles 3 running perpendicular to them and also arranged parallel at a distance are attached from below. The ceiling projection is closed off towards the room by cover plates 8, of which only a small section is indicated in Figure 1.

The ceiling projection described so far can be made from commercially available systems. Suppliers of such systems include Knauf (Neuss, DE) and Rigips (Düsseldorf, DE). The hangers, base profiles and support profiles can be made from metal. All common materials can be used for the cover panels, in particular plasterboard, wood panels, metal cassettes, etc.

Between the base profiles 4 and the cover plates 8 there are construction-related cavities, the height of which corresponds to the thickness of the support profiles 3 and is typically about 30 mm. In the context of the invention, these cavities are used to accommodate the pipes 5 of a room heating system. The following description is limited to a heating system, since a room cooling system would not differ from a heating system in terms of construction, but only in terms of operation. The system described can therefore also be used for room cooling, which is of particular interest in work spaces such as offices.

The pipe system runs in a meandering shape in the lower part of the ceiling projection with straight sections that are parallel to the support profiles 3 and connected by bends. All common pipe types can be used for the heating pipes.

, especially so-called Pex pipes (high-pressure pressed pipes made of cross-linked polyethylene), multi-layer composite pipes or metal pipes (steel, copper, etc.)

To improve heat dissipation, heat conducting fins 6 are arranged on the pipes 5, which dissipate the heat over a large area downwards into the room. Aluminum is a particularly suitable material for the heat conducting fins 6, as it allows high heating and cooling performance to be achieved with low weight. The use of the fins ensures that the entire surface of the wall is evenly warmed (or cold). In ceiling projections with integrated room heating according to the state of the art, the entire pipe register including the heat conducting fins rests loosely on the cover plates after a suspension of the pipe register on wires made for assembly has been cut. This not only results in a high weight load for the cover plates, but also an uncontrollable and often inadequate support of the heat conducting fins and thus poor heat transfer. In addition, conventional assembly is very complex and does not allow additional insulation to be introduced into the ceiling projection.

These disadvantages are avoided by the present invention by using special brackets 7 for the pipes 5, which are attached to the base profiles 4 in the middle between the support profiles 3. The pipes can be inserted into these brackets from below and fixed in a position that can be selected (within limits). This allows the pipes to be mounted in their final position after the base profiles 4 and support profiles 3 have been assembled. In particular, they can be leveled so that the pipe system runs in one plane. Unevenness caused by the ceiling or the substructure can be compensated for with the help of the brackets according to the invention. The heat-conducting fins 6 can then be attached to the pre-assembled pipes. It is advantageous here that the pipes are freely accessible from below. Furthermore, a gap can be created between the ceiling and the upper edge of the suspended substructure.

tion. This is also easily possible since the space required for this is not blocked by wires on which the pipes are suspended and which would have to be cut after the cover plates have been attached. The insulating layer 16 towards the ceiling also significantly improves the heating effectiveness of the ceiling projection according to the invention compared to conventional ceilings. The heat-conducting slats 6 are designed in such a way that they rest on the cover plates under a slight pre-tension and therefore ensure good contact with good heat transfer to the plates. The desired heat transfer performance can also be adjusted as required by the number of pipes and slats. Good heat transfer is particularly important in cooling applications where the applicable temperature difference must be kept low to avoid condensation. With regard to the design of the slats, it should also be noted that they run in a V-shape towards the pipe, i.e. that the connecting legs bend at an obtuse angle towards the pipe 5. In known slats, the connection to the pipe is U-shaped, i.e. bends at a right angle. This has the disadvantage that the distance between the pipe and the cover plate must adhere to very narrow tolerances. The V-shape, on the other hand, has the advantage that the entire slat becomes springy and therefore adapts better under pressure.

In Figure 2 it can also be seen that the ends 20 of the slats 6 rest on the support profiles 3 by a few millimeters. This clamps them between the support profiles and the cover plate 8, which ensures that when the cover plates are attached, the slats rest snugly and that the slats are well positioned on the cover plate 8. This slat arrangement is preferably used when the slats do not lie directly on the profiles of the insulation, as described below.

A preferred embodiment of the bracket with which the pipes 5 are attached under the substructure is shown in Figure 3 in the front and side view.

The holder 7 is U-shaped in plan view with a central leg 10, at each end of which an outer leg 13 is arranged. The outer legs 13 have nose-shaped thickenings 14 on their free ends, directed towards the inside of the U. The inner distance between the two outer legs 13 corresponds to the outer diameter of the pipes 5. Due to the thickening at the entrance to the U, a pipe 5 that is to be clamped into the holder must first push the outer legs 13 apart slightly. The outer legs 13 are designed to be elastically resilient so that they allow the necessary yielding. When the pipe 5 is inside the U, the thickenings 14 prevent it from falling out again on its own.

Furthermore, the height of the outer legs 13 is greater than the outer diameter of the pipe 5. The pipe can therefore be arranged in a variable position range 9 within the holder. This clearance makes it possible to level the entire pipe system so that it lies in one plane. In order to hold the pipe in the set position, the inner sides of the outer legs 13 are preferably rough so that a high level of static friction is created with the pipe. The inner sides can also have a sawtooth structure so that the pipe can lock between two teeth at different heights.

In the middle leg 10 of the bracket there is a drill hole 11 through which the bracket can be fastened with a screw to the substrate, e.g. to the base profiles 4 or the support profiles 3.

Furthermore, in Figure 3, an important feature of the holder can be seen that the middle leg 10 has a curvature directed towards the inside of the U, which leads to a distance 12 between a flat surface and the center of the middle leg 10. When the holder is screwed onto a surface, the curvature is pressed flat against the surface. This causes the outer legs 13 to move towards each other and the holder is given a pre-

tension, which leads to a firmer hold of the inserted pipe.

The holder according to the invention can be made from various materials. Plastics that have sufficient stability and elasticity are preferred. Metals (brass, aluminum, etc.) can also be used.

Figure 4 shows a cross-section through a projection in front of a wall or roof slope. In principle, the structure is the same as for the ceiling projection explained above. The substructure can be made of wood or metal. The rafters 4a, which run parallel to one another at a distance, are part of the wall (slope) to which the projection is attached. The wooden slats 3a are attached at a distance and parallel to one another across the rafters 4a, between which the pipes 5 with the heat-conducting fins 6 run. The room-side closure is again formed by cover plates 8, which can be plasterboard, for example. Conventional insulation (e.g. glass wool) can be arranged between the rafters 4a (not shown). The brackets according to the invention (not shown) are attached to the rafters 4a, into which the pipes 5 can be inserted and aligned from below.

Figures 5a and 5b show two similar cross-sections through a wall projection, whereby Figure 5a is cut in the area of a heat-conducting lamella 6, while the section in Figure 5b is between two lamellas. Figure 5a is described first. The wall 15 can be designed as a solid masonry wall or also in a lightweight construction, e.g. as a plasterboard. The first layer in front of the wall 15 is an insulating layer 16 as thermal insulation. This is held at intervals by U-profiles 17. The support rails 3, which can be made of wood, plastic or metal, run parallel to and at a distance from one another on the insulating layer 16 (two variants are shown simultaneously in the figure). There can be other elements and rails of a substructure that are not shown in detail. The room-side closure is again formed by

in turn, cover plates 8, e.g. plasterboard. In the cavities between the support rails 3, the pipes 5, on which the heat-conducting fins 6 are attached, run parallel to the support rails. The pipes 5 are fixed in front of the wall by brackets (not shown in detail), whereby the pipes can be inserted into the brackets from the front to an adjustable depth. This makes it possible to construct a wall projection much easier than with the prior art.

Figure 5b shows a measure which ensures that the slats 6 fit tightly against the cover plate 8 even when the pipe 5 is not resting directly on the insulating layer 16. In this case, there is a risk that the pipe will bend between the brackets, which are typically 1 m apart, and the slats will therefore not fit tightly in these areas. To prevent this, narrow foam sleeves 18 are placed on the pipe 5. The foam sleeves 18 are slit lengthwise so that they can be placed on. Due to their elasticity, the foam sleeves 18 cause the pipe 5 or the slats 6 to be pressed resiliently against the cover plate 8.

The system according to Figure 5 can be used to create a stud wall if a lightweight construction element such as plasterboard is used as wall 15. Figure 6 shows another type of stud wall. The special feature here is that the two outer surfaces of the wall can be heated (or cooled) because a heating (or cooling) system is integrated in both. The structure of the wall is similar to that described above, but instead of a wall, a wall projection constructed in a mirror image is used. Accordingly, two insulating layers 16, 16' (which can also be made in one piece) form the core of the stud wall. The insulating layers are held at intervals by U-profiles 17. These U-profiles preferably run vertically from the floor to the ceiling of the room, with the outer legs each lying parallel to an outer wall of the stud wall. These outer legs also form a fastening option for the cover.

plates 8, 8', which close off the stud wall towards the sides of the room. The pipes 5, 5' with the heat-conducting fins 6, 6' are arranged between the insulating layers 16, 16' and the cover plates 8, 8 ^1. The insulating layers 16, 16' are designed in the example shown as system plates with recesses for the pipes 5 and heat-conducting fins 6 as well as with holders for the pipes. The thickness of the stud wall is therefore not increased by the heating. Furthermore, on the side of the insulating layers 16, 16' facing the heat-conducting fins 6, a profile can be seen, which can consist of knobs or pointed elevations 19 or the like running parallel to the pipe 5. These elevations 19 cause the fins to be pressed against the cover plates 8, 8' in a springy manner at specific points, so that optimal contact for heat transfer is guaranteed.

These elevations 19 can be molded onto the insulation panel or subsequently applied in the form of, for example, foam strips.

A high-quality material, preferably with a high fire protection class, can be selected for the insulating layers.

Figure 7 shows an alternative embodiment of the substructure (preferably for wall heating). Base rails 4' are attached to the floor and ceiling in parallel. Support rails 3' extend across them (bracket not shown). End pieces 22 are inserted into the front sides of the support rails on one side each (see Figure 8). These have a through-opening 24 for the meandering heating pipe 5 to pass through. The through-opening 24 is designed as a cylindrical recess open to one side across the support rail in such a way that the heating pipe 5 snaps into place like a clip when the diameter is adjusted accordingly and is thus additionally held. The end piece 22 is preferably made of a plastic, whereas the body of the support rail 3' is preferably made of sheet metal.

To allow the insertion of a closing part, the support rail 3 ¹ is U-shaped. To ensure that the closing parts fit securely, the U-profile has recesses on the long sides of the legs.

5 or folded edges (not shown) which prevent the end pieces from sliding out of the free side of the U-profile. In addition, the end pieces can be connected to the support rail, for example by means of a screw. The end pieces ensure that the heating pipe can be guided over the entire heating surface without recesses being required in the substructure for the heating pipes to be guided through, so that the substructure can extend continuously to the edges of the heating surface. Through openings in the support rails themselves (which are preferably made of thin sheet metal) would also be possible for this purpose, but would have the disadvantage compared to the proposed end pieces that very sharp edges would be formed and additional clip-like mounting of the heating pipes would not be possible. In order to also enable cables laid in the substructure to be guided through, the end pieces 22 have cable ducts 26 at their front ends.

Reference number:

1 Wall or ceiling projection 2 Hanger OJOJ Support rails 4
4" Base rails 5 Pipelines 6 Heat conducting fins 7 Brackets 8th Cover plate 9 Position range 10 Middle thigh 11 Through hole 12 Distance 13 Outer thigh 14 thickening 16
16· Insulation layer 17 U-profiles 18 Foam sleeve 19 Survey 20 Slat ends 22 Final part 24 Through opening 26 Cable entry

Claims (12)

1. Wall or ceiling projection ( 1 ) with integrated room heating or cooling system, with a) a substructure which can be attached to the wall or ceiling, b) pipes ( 5 ) for the heating or cooling medium, which are arranged in cavities of the substructure or below the substructure, c) if necessary, heat-conducting fins ( 6 ) arranged on the pipes, d) a cover plate ( 8 ) which forms the outer surface facing the room, characterized in that it comprises brackets ( 7 ) which can be fastened to the substructure and/or the wall or ceiling and which can receive the pipes ( 5 ) and hold them in an adjustable position. 2. Wall or ceiling projection according to claim 1, characterized in that it has an insulating layer ( 16 ) which is preferably arranged between the wall or ceiling and the substructure. 3. Wall or ceiling projection according to claim 2, characterized in that the insulation layer ( 16 ) has elevations ( 19 ) on the side facing the cover plate ( 8 ). 4. Wall or ceiling projection according to one of claims 1 to 3, characterized in that the pipes ( 5 ) are surrounded by elastic thickenings ( 18 ) between heat-conducting lamellas ( 6 ). 5. Wall or ceiling projection according to one of claims 1 to 4, characterized in that the substructure contains base rails ( 4 ) running parallel and spaced apart and transversely thereto, parallel and spaced apart support rails ( 3 ). 6. Wall or ceiling projection according to claim 5, characterized in that at least one support rail ( 3 ') has, in the vicinity of at least one front end, a through-opening ( 24 ) extending transversely to the support rail through the latter for the passage of a pipeline ( 5 ). 7. Wall or ceiling projection according to claim 6, characterized in that at least one support rail ( 3 ') is formed in several parts from a rail body and one or two end parts ( 22 ) which can be inserted into the rail body at the front and which have the through opening ( 24 ). 8. Wall or ceiling projection according to claim 7, characterized in that the closing part ( 22 ) has a recess ( 26 ) at its front end for the passage of a cable. 9. Stud wall with integrated room heating or cooling system, characterized in that a first wall projection according to one of claims 1 to 8 is connected to a second wall projection according to one of claims 1 to 8 arranged in mirror image thereto. 10. Holder ( 7 ) for pipes ( 5 ) of a space heating or cooling system, characterized in that it is substantially U-shaped, wherein at least one outer leg ( 13 ) is elastic and at least one outer leg ( 13 ) has an inwardly directed thickening ( 14 ) at its free end. 11. Holder according to claim 10, characterized in that the middle leg ( 10 ) of the holder has means for fastening to a substrate, preferably in the form of a through hole ( 11 ). 12. Holder according to one of claims 10 or 11, characterized in that the middle leg ( 10 ) of the holder has an inwardly curved shape.