DE20102640U1 - Ceiling element for climate ceilings - Google Patents

Description

Company emcal Wärmesysteme GmbH,
Hollefeldstr. 23, 48282 Emsdetten

"Ceiling element for climate ceilings"
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The innovation relates to a ceiling element according to the preamble of claim 1.

The installation of air-conditioned ceilings involves a relatively large amount of construction work: Pipes are attached to the panels that are visible from the room, through which the heat transfer medium is fed, for example a medium in the form of a fluid such as water. Several panels with several pipes must be connected to one another and combined to form an overall circuit.

The innovation is based on the task of improving a generic ceiling element so that it enables simple, quick and cost-effective installation of the climate ceiling.

This object is achieved by a ceiling element having the features of claim 1.

Advantageous embodiments are set out in the subclaims

removable.

In other words, the innovation proposes a prefabricated module, with each ceiling element having a single pipe. This can be made up of several sections if necessary.

However, the entire ceiling element can be handled by the user as if it were a single pipe, so that only one connection is provided for the supply line and only one connection for the return of the heat transfer medium. Apart from the fact that the pipe itself is already connected to the plate of the

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ceiling element, installation is simplified by the fact that the leak test for the pipework of this ceiling element can already have been carried out at the factory, so that less effort is required for a leak test on site.

Because the pipe is at least partially immersed in grooves in the panel and is mounted to the panel at the factory, a standardized and qualitatively optimal heat transfer from the pipe to the panel is ensured, so that in this respect assembly errors that could impair the performance of the air-conditioned ceiling are excluded.

In order to ensure optimum heat transfer between the pipe and the plate, the recesses can be designed as holes whose cross-section is completely surrounded by the plate material, whereby such recesses can advantageously be created during plate production or can be introduced into the plates afterwards. However, it can be advantageous from a manufacturing point of view to design the recesses as grooves so that they can be subsequently introduced into any commercially available plate at low cost.

It can be advantageous to dimension the pipe connections long enough so that the connection to a distributor can be made outside the room in which the air-conditioned ceiling is to be installed. In this way, no leak test is required at all within the room in which the air-conditioned ceiling is to be installed, but this can be limited to the room in which the distributor is intended. In this way, a risk of leaks can also be shifted to a room in which the extent of possible damage can be kept particularly low, so that, for example, expensive technical equipment, valuable exhibits or the like are optimally protected in this way.

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In this way, should leaks occur in the area of the distributor, downtime in the room in which the air conditioning ceiling is installed can be avoided or minimized, since the repair work can only be carried out in another room.

In order to achieve good sound insulation, the panel can be designed as a so-called acoustic panel in a conventional manner, i.e. it can be provided with openings. The openings are referred to as "drillings" regardless of how they are manufactured and their cross-sectional shape. In order not to impair the acoustics of the panel and to avoid any visual impairment depending on the installation and structure of the air-conditioned ceiling, the recesses in which the pipe is routed are preferably provided between the holes in the acoustic ceiling, i.e. arranged so that they are invisible from the room.

The panel can advantageously be made of plasterboard. This enables a high heat transfer performance and a building material is selected that is inert in many respects, for example in terms of its expansion when temperatures fluctuate, so that the panel is always optimally positioned on the pipe and thus optimal heat transfer is ensured.

Advantageously, the recesses can have a cross-section that is dimensioned so that the plate material fits tightly against the pipe, i.e. in the case of circular pipe cross-sections, a rounded cross-section. In this way, the heat transfer between the pipe and the plate material is optimized.

In the case of recesses designed as grooves, it can be advantageous to provide the grooves with a &OHgr;-shaped cross-section so that the plate material surrounds the pipeline by

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more than 180° of the pipe cross-section. When using flexible pipe materials, such as plastic, the pipe can be inserted into the groove from above. With stiffer materials, such as copper materials, the pipe can be inserted lengthways

into such a &OHgr;-shaped groove.

A further optimization of the heat transfer can be achieved by making the groove deeper than the diameter of the pipe, so that the pipe can be fully

can be immersed in the groove at all times. In these cases, the remaining free space can then be filled with a heat transfer compound or filler, so that a flat plate top is achieved and the pipeline is completely surrounded by plate material or filler material

which has a better thermal conductivity than air, so that an optimal heat transfer between the plate and the pipe can be achieved. This may make it possible to manufacture the modules more cost-effectively than when using plates with recesses that

enclose the cable all around.

If several sections of the pipeline are laid in parallel, this may result in an undesirable weakening of the plate in terms of its buckling strength. To avoid damage to the plate

To prevent this, reinforcement strips can be provided which are arranged above the pipeline and run transversely or diagonally to the pipeline, and accordingly also transversely or diagonally to the grooves weakening the panel material, so that sufficient stability of the ceiling

element can be ensured with the help of such reinforcement strips.

Advantageously, quick couplings can be provided at the connections of the pipeline so that the assembly

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of the ceiling element can be further accelerated and simplified in this way.

An embodiment of the innovation is explained in more detail below using the drawing, which is purely schematic and

A ceiling element is shown in perspective as a factory-ready module.

The ceiling element has a pipe 1, which can be designed, for example, as a heating pipe or cooling pipe with a diameter of 10 mm and a wall thickness of 1 mm. 2 designates a plate made of plasterboard and provided as a perforated plate with a large number of holes 8 for the production of an acoustic ceiling. On the visible side of the plate 1, i.e. facing the room, an acoustically permeable fleece 4 is provided, which is provided with an acoustically permeable acoustic plaster on the bottom, i.e. facing the room. The pipe is laid in such a way that it runs between the holes 8 and in this way the acoustic properties

properties of the ceiling element are not impaired.

Above the pipeline 1, so-called support profiles 6 are provided, which can be firmly attached to the plate 2 to serve as reinforcement strips.

However, deviating from the embodiment shown, separate reinforcement strips can also be provided.

The support profiles 6 are attached to base profiles 5, which in turn are attached to the ceiling via so-called nonius hangers 7.

are suspended and ultimately enable the fastening of the ceiling element designated 9 in total.

The plate 2 is provided with the pipe 1 at the factory, whereby the pipe 1 has two connections 10 as supply and return for

the heat transfer medium. Between the connections

* • * ·
• • • • * • ·· • ··· • · •
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-β &iacgr;&ogr; the pipeline 1 can consist of several individual elements which are connected to one another and leak-tested at the factory. If necessary, the pipeline 1 can also consist of a single element, for example a flexible, bendable pipe.

Claims (8)

1. Ceiling element for climate ceilings,
with a plate,
and with a pipeline in which a heat transfer medium can be carried,
characterized ,
that recesses are provided in the plate ( 2 ) in which the pipeline ( 1 ) is laid,
wherein the pipeline ( 1 ) has a connection ( 10 ) for the flow and return of the heat carrier,
and wherein the plate ( 2 ) is factory-fitted with the pipe ( 1 ). 2. Ceiling element according to claim 1, characterized in that the recesses are designed as grooves. 3. Ceiling element according to claim 1 or 2, characterized in that the connections ( 10 ) are dimensioned to be long enough to adapt to the room in which the air-conditioned ceiling is to be installed, that they can be led out of the room and connected to a distributor located outside the room. 4. Ceiling element according to one of the preceding claims, characterized in that the plate ( 2 ) is provided with bores ( 8 ), wherein the recesses for receiving the pipes ( 1 ) run between the bores ( 8 ). 5. Ceiling element according to one of the preceding claims, characterized in that the panel ( 2 ) is designed as a plasterboard. 6. Ceiling element according to one of the preceding claims, characterized in that the plate ( 2 ) fits tightly against the pipeline ( 1 ). 7. Ceiling element according to claim 2, characterized in that the grooves have a Q-shaped cross-section and the plate ( 2 ) surrounds the pipeline ( 1 ) by more than 180°. 8. Ceiling element according to one of the preceding claims, characterized by reinforcing strips which are provided above the pipeline ( 1 ) and run transversely or obliquely to the pipeline ( 1 ).