AT16209U1 - CEILING AND / OR WALL COVERING AND MANUFACTURING METHOD THEREFOR - Google Patents

Abstract

Ceiling and / or wall cladding (100), comprising at least one lamella (110; 110a; 110b), wherein a temperature control system (120) for controlling the temperature of the at least one lamella (110; 110a; 110b) is provided, and wherein the temperature control system (120 ) has at least one fluid line (122), which is designed for transporting a fluid (122a) which can be used for temperature control, and which is in thermal contact with the at least one lamella (110; 110a; 110b).

Description

Description: The invention relates to a ceiling and / or wall covering comprising at least one lamella. The invention further relates to a building with at least one such ceiling and / or wall covering. The invention further relates to a production method for such ceiling and / or wall cladding.

It is an object of the present invention, a ceiling and / or wall paneling and a building of the type mentioned above and a manufacturing method of the type mentioned above to improve the effect that greater flexibility and increased utility is given.

This object is achieved in the ceiling and / or wall cladding of the type mentioned by the combination of features according to claim 1. According to the invention, a tempering system is provided for controlling the temperature of the at least one fin. This advantageously provides the opportunity to temper the blade, so to cool and / or to heat, which allows a corresponding cooling or heating of a room in which the ceiling and / or wall panel according to the invention is arranged. Particularly advantageous ceiling and / or wall cladding invention thus fulfills at least one dual function, namely the temperature control according to the invention in addition to an optical or acoustic function.

In a preferred embodiment, the blade made of aluminum, in particular aluminum sheet. Other thermally well conductive materials are also usable.

Further according to the invention it is provided that the temperature control system has at least one fluid line, which is designed for transporting a fluid suitable for temperature control, and which is in thermal contact with the at least one lamella. By using a fluid for tempering a comparatively large heating power or cooling capacity can be introduced so that comparatively large ceiling and wall surfaces having ceiling and / or wall cladding according to the invention can be efficiently supplied.

In a further preferred embodiment it is provided that the at least one lamella has a profile body, wherein the profile body has a substantially egg-shaped cross-section with three wall sections delimiting an interior space, wherein the fluid line is arranged in the interior, that they in thermal Contact with at least two different wall sections of the profile body, wherein preferably the fluid line touches the at least two different wall sections of the profile body. As a result, advantageously large surface portions of the profile body of the blade for the exchange of heat energy, ie for cooling or heating, can be used.

Particularly advantageous in preferred embodiments, the at least one lamella at the same time for temperature control (cooling or heating) by way of convection and the radiation (or recording) of thermal energy to be formed, resulting in an efficient temperature control. In other words, the mode of operation results convectively by air movement (buoyancy or downforce) of tempered air, in cooling downforce, in heating buoyancy, especially by a chimney effect between adjacent lamellae, due to the fin spacing according to the embodiments. In addition, the embodiments act by emitting heat radiation (infrared radiation) through the heated fins in each direction. Infrared radiation is characterized by electromagnetic waves that move at the speed of light u. when hitting a e.g. solid body (skin or floor, etc.) to be converted into heat.

In a further preferred embodiment it is provided that at least one lamella has a profile body, wherein the profile body has a substantially V-shaped cross-section with two wall sections delimiting an interior space, wherein the fluid line is arranged in the interior, that in thermal contact with at least two different wall portions of the profile body, wherein preferably the

Fluid line contacts the at least two different wall sections of the profile body. In a further preferred embodiment it is provided that the Temperierungssystem has at least one fluid conduit for controlling the temperature of at least one lamella, wherein the Temperierungssystem comprises at least one flow line for supplying the at least one fluid line with a or the fluid, and wherein the Temperierungssystem least a return line for returning fluid which has flowed through the at least one fluid line. The flow line, the at least one fluid line, and the return line in this case advantageously together form a tempering module. It is understood that the respective components must be fluid-tightly interconnected.

Preferably, in further embodiments, a plurality of fluid lines are provided, each associated with a common flow line and a common return line. In these embodiments, a tempering module thus has a flow line, a return line and a plurality of fluid lines, wherein one or more fluid lines can each be assigned a lamella.

In a further preferred embodiment, fluid lines and their associated flow line and return line can be made of the same material, in particular in one piece. For example, an entire tempering module can be obtained as an injection molded part, and / or by welding the fluid lines with their associated feed line and return line.

In further embodiments, all fluid lines of a Temperiermoduls and their associated flow line and return line material of uniform design, in particular integrally formed.

In further embodiments, all fluid lines of the entire ceiling and / or wall paneling and their associated flow line and return line are formed of the same material, in particular integrally formed.

In a further preferred embodiment it is provided that a plurality of fluid conduits are provided and fluidly connected in parallel between the flow line and the return line, whereby each of the fluid lines is advantageously supplied with "fresh", that is, set temperature, fluid.

In further embodiments, all fluid lines directly from one or their associated flow line with fluid, in particular with fresh (ie set temperature of a flow having) fluid, can be supplied. This is equivalent to the fact that all fluid lines are connected in parallel with respect to their associated flow line.

In further embodiments, all fluid lines are connected to one or their associated return line, that the fluid is directly fed to the return line after flowing through a respective fluid line. This is equivalent to the fact that all fluid lines are connected in parallel with respect to their associated return line.

In a further preferred embodiment it is provided that the at least one lamella in at least one first axial end region has a mounting opening for attachment to a mounting rail, preferably in both axial end regions. As a result, the slat can be connected to the support rail in a particularly preferred manner, which ensures easy assembly and disassembly of the slat. Particularly advantageous may be provided that the mounting opening of the blade is brought into engagement with a hook-shaped portion of the support rail, so that there is a reliable positive connection. Further details on mounting options of the slats on mounting rails are shown in the Utility Model 20 2014 009 761 of the Applicant.

In further embodiments, the lamella is generally releasably connectable to the mounting rail, resulting in a good revisionability.

In further embodiments, the lamella by means of its mounting opening (s) is positively connected to the mounting rail. This results in a stable attachment of

Slat on the mounting rail. Particularly advantageously, the lamella can thereby at least partially accommodate the weight of possibly further existing components of the ceiling and / or wall cladding.

In further embodiments, the mounting opening of the lamella is engageable with a hook-shaped portion of the support rail, which allows a simple to produce and again releasable connection.

In a further preferred embodiment it is provided that the at least one lamella has a recess in at least a first axial end region, whereby a space is created for a connection area between a flow line and one of the lamella associated fluid line or a return line and one of Slat associated fluid line.

In further embodiments, the at least one lamella in each case has a recess in two opposite axial end regions. As a result, a corresponding space is advantageously created in the two axial end regions. In particular, this makes it possible that an overall height of the ceiling and / or wall cladding according to the invention is comparatively low, although the ceiling and / or wall cladding advantageously several functions (optics and acoustics (especially sound absorption) and temperature (heating and / or cooling)) provides ,

In further embodiments, the recess creates a space for a connection area between a flow line and a fluid line associated with the lamella.

In further embodiments, the recess creates a space for a connection area between a return line and one of the lamella associated fluid line.

In further embodiments, the recess has substantially approximately rectangular shape, which is particularly inexpensive to produce. In further embodiments, the rectangular shape has a first length along a longitudinal axis of the sipe and a first height perpendicular to the longitudinal axis of the sipe. In further embodiments, the first length is between about 50 millimeters and about 60 millimeters. In further embodiments, the first height is between about 10 millimeters and about 60 millimeters. In further embodiments, the first height is between about 10 millimeters and about 20 millimeters.

In a further preferred embodiment it is provided that a plurality of Temperiermodule are provided, each of which has at least one supply line for supplying at least one fluid line of the Temperiermoduls with one or the fluid, and wherein each Temperiermodul at least one return line for the return of the at least one fluid line of the tempering has flowed fluid. The provision of one or more tempering modules enables efficient installation of the ceiling and / or wall cladding according to the invention. In further embodiments, an inner width of the at least one fin is between about 6 millimeters and about 20 millimeters. In further embodiments, the internal width of the at least one fin is between about 9 millimeters and about 10 millimeters.

In further embodiments, the inner width of the at least one lamella is between about 9.1 millimeters and about 9.3 millimeters, preferably about 9.14 millimeters. Investigations by the Applicant According to this measure allows a particularly efficient tempering of the surrounding space by means of convection and radiation of heat energy at the same time excellent sound absorption properties.

In further embodiments, the at least one blade has a material thickness of about 0.4 millimeters to about 0.6 millimeters.

In further embodiments, the at least one blade has a material thickness of about 0.43 millimeters. Investigations by the applicant according to this allows a comparatively stable formation of individual slats at a comparatively low weight.

In further embodiments, the at least one blade has a height of about 40 mm to about 120 mm. In further embodiments, the at least one sipe has a height of about 40 mm to about 80 mm. In further embodiments, the at least one blade has a height of about 60 mm. As a result, investigations by the Applicant show that the construction height of the entire ceiling and / or wall cladding is particularly low and, at the same time, very efficient in tempering.

In further embodiments, the at least one blade has an outer width of about 8 mm to about 30 mm.

In further embodiments, the at least one blade has an outer width of about 10 mm. According to Applicant's investigations, this enables efficient integration of one or more fluid conduits for said temperature control and, at the same time, degrees of freedom with regard to a spacing between mutually adjacent fins, which favors the convection effects.

In further embodiments, the at least one blade has an outer width of about 10 mm and a height of about 60 mm. According to the applicant, this combination results in a particularly low construction height with simultaneously optimized temperature control and sound absorption.

In further embodiments, the at least one blade has an outer width of about 10 mm, a height of about 60 mm and an inner width of about 9.14 millimeters. In this configuration, a comparatively high stability of the at least one lamella is additionally given, and one or more fluid lines for the temperature control can advantageously be frictionally arranged in an interior of the at least one lamella, whereby an efficient heat transfer between the fluid lines and the lamella results.

In a further preferred embodiment it is provided that an inner width of the at least one lamella is less than or equal to an outer dimension of the at least one fluid line, in particular an outer diameter at a substantially circular fluid line, preferably smaller by about 2 millimeters, thereby advantageously ensured in that the wall sections defining the inner width of the lamella bear resiliently on the corresponding outer surface areas of the fluid line, resulting in good thermal contact between the outer surface of the fluid line and the respective wall sections of the lamella.

In a further preferred embodiment it is provided that in an interior of the lamella at least partially a, preferably flame-retardant or non-flammable, textile material is arranged, thereby improving the sound-absorbing properties of the lamella. At the same time advantageous Temperierungsmöglichkeit the invention remains.

In a further preferred embodiment it is provided that the lamella has openings, in particular a perforation characterized by a plurality of openings, in particular a micro-perforation, whereby further improve the sound-absorbing properties of the lamella. At the same time advantageous Temperierungsmöglichkeit the invention remains.

In further embodiments, the at least one fluid line has at least one tube. In preferred embodiments, the at least one tube is made of polypropylene. In other embodiments, other materials for forming the tube are conceivable. In further embodiments, the at least one tube has an outer diameter of about 10 mm. In further embodiments, the at least one tube has a wall thickness of about 1 mm. In further embodiments, the at least one tube is non-positively inserted into a lamella. This results in a good thermal contact with easy installation. In the case of a plurality of fluid lines, the lamella, in further embodiments, a plurality of tubes can be frictionally inserted into a lamella.

In further embodiments, the at least one fluid line is continuously applied to the at least one lamella, resulting in a particularly good thermal contact between the fluid line and the lamella and thus an efficient temperature.

In further embodiments, the at least one fluid line is in the axial direction of the at least one blade along at least about 80 percent of a length of the lamella.

In further embodiments, a plurality of fins are provided. As a result, the sound absorption and the power with respect to the temperature of the surrounding space can be advantageously increased.

In preferred embodiments, the plurality of fins are arranged substantially parallel to one another, resulting in a particularly uniform sound absorption and in particular even tempering.

In further embodiments, a fin spacing between two adjacent fins is between about 20 mm and about 120 mm. In the case of a plurality of lamellae, a constant lamellar spacing between respectively adjacent lamellae is particularly preferably provided. In further embodiments, a fin spacing between two adjacent fins is about 38 mm. In further embodiments, a fin spacing between two adjacent fins is about 86 mm. In other embodiments, a center distance (center-to-center distance) between adjacent slats is about 50 mm or about 70 mm or about 100 mm or about 140 mm.

In further embodiments, the fluid line contacts the at least two different wall sections of the profile body.

In further embodiments, the profile body has a first wall portion and a second wall portion arranged substantially parallel to the first wall portion, and a third wall portion connecting the first wall portion with the second wall portion. Such a configuration is given, for example, with substantially egg-shaped cross-section having fins, wherein the first wall portion and the second wall portion corresponds to a long leg of the U-shape, and wherein the third wall portion corresponds to the short leg of the U-shape.

In further embodiments, the first wall portion and the second wall portion and the third wall portion (each) are formed substantially flat. In other embodiments, it is also possible that at least one of the three wall sections is substantially not flat, but curved, for example.

In further embodiments, the fluid line limited together with areas of the first and second wall portion of the profile body and together with the third wall portion of the profile body limits the interior of the profile body. As a result, a substantially closed volume in the region of the interior of the profile body is advantageously defined, which can be tempered particularly efficiently by the fluid line (s) in order to contribute to the temperature control of the lamella.

In further embodiments, the fluid line delimits, together with regions of the first and second wall section of the profile body and together with the third wall section of the profile body, a first cross-sectional partial surface of the profile body.

In preferred embodiments, the first cross-sectional sub-area is about 60 percent or more of a total cross-sectional area of the profile body. In further preferred embodiments, the first cross-sectional sub-area is about 80 percent or more of a total cross-sectional area of the profile body.

In further embodiments, the at least one fin is arranged such that an opening of the U-shaped cross section is oriented approximately antiparallel to the gravitational vector of the earth. In these embodiments, the at least one lamella is thus aligned with its opening upwards. This allows easy mounting and mounting of the

Fluid line (s) in the lamella, in particular, the fluid line (s) from below the lamella are visually imperceptible. At the same time this results in a particularly efficient temperature control by means of convection and thermal radiation.

In further embodiments, at least one support rail for holding the at least one blade is provided.

For example, in some embodiments, the support rail may have a substantially U-shaped profile, e.g. comparable to some of the aforementioned embodiments of the lamella.

In further embodiments, the at least one support rail and the at least one lamella are arranged substantially within the same virtual plane. This can preferably be achieved in that corresponding areas of the lamella of the support rail engage in each other and / or have corresponding recesses for this purpose. This advantageously ensures that results in a comparatively low height for the entire structure of mounting rails and slats.

In further embodiments it is provided that an overall height of the ceiling and / or wall cladding in a direction perpendicular to the virtual plane is less than or equal to about 200 millimeters. As a result, the ceiling and / or wall cladding according to the invention can be used in particular in comparatively low rooms or creates degrees of freedom for the arrangement of other ceiling systems such as lighting and the like.

In further embodiments it is provided that an overall height of the ceiling and / or wall cladding in a direction perpendicular to the virtual plane is less than or equal to about 90 millimeters.

In still other embodiments, it is contemplated that an overall height of the ceiling and / or wall panel in a direction perpendicular to the virtual plane is about 85 millimeters.

In further embodiments, it is provided that at least one outer surface of the at least one lamella is painted. This results in a particularly efficient radiation of heat energy. In some embodiments, the fins are preferably painted to have one of the following colors: RAL 9003 and / or RAL 9006 and / or RAL 9005.

In further preferred embodiments, the ceiling and / or wall paneling at room temperature and at a temperature difference of about 10 Kelvin between the fluid and the room temperature has a cooling capacity of about 105 watts per square meter.

In further embodiments, the ceiling and / or wall paneling at room temperature and at a temperature difference of about 15 Kelvin between the fluid and the room temperature on a thermal output of about 90 watts per square meter.

In further embodiments, the at least one lamella are associated with two or more fluid lines, whereby the heat output for the temperature control (heating or cooling) which can be supplied to the lamella concerned increases accordingly. By way of example, a doubling of the number of fluid lines per lamella may in some embodiments essentially result in a corresponding doubling of the temperature control performance.

In further embodiments, the two or more fluid lines are arranged substantially completely in the U-shaped cross-section of the profile body of the at least one lamella.

In further embodiments, the temperature control system comprises at least one flow line for supplying the two or more fluid lines with a fluid, wherein the temperature control system has at least one return line for returning fluid having flowed through the two or more fluid lines.

In further embodiments, the two or more fluid lines are fluidically interposed between the flow line and the return line in parallel.

In further embodiments, all fluid lines that are associated with the same flow line and the same return line (ie, in the case of Temperiermodulen example, the same Temperiermodul belong), with respect to the flow line and the return line fluidly connected in parallel.

In further embodiments, the flow line and the return line of a Temperiermoduls and all of the flow line and the return line of the same Temperiermoduls associated fluid lines are connected to each other, in particular further embodiment according to undetachably connected. In still further embodiments, these components are preferably connected to one another in a material-locking manner, which can be achieved, for example, by adhesive methods or welding methods.

In other preferred embodiments, the flow line and the return line of a Temperiermoduls and all of the flow line and the return line of the same Temperiermoduls associated fluid lines are integrally formed.

In further embodiments, the flow line and the return line and the at least one fluid line are permanently connected to each other. In further embodiments, the supply line and the return line and the at least one fluid line are connected to one another in a material-locking manner. In further embodiments, the flow line and the return line and the at least one fluid line are integrally formed.

In further embodiments, the ceiling and / or wall cladding is adapted to allow a free convection of a fluid surrounding the at least one blade, in particular ambient air. In further embodiments, the ceiling and / or wall cladding is adapted to emit heat radiation to a surrounding space.

In further embodiments, the ceiling and / or wall cladding is adapted to emit heat radiation by means of the at least one lamella to the surrounding space.

Due to the comparatively large area of the at least one lamella, this results in a particularly efficient emission of heat radiation. At the same time, convection can also result in a particularly efficient flow of air between the adjacent lamellae.

In further embodiments, the at least two tempering modules are hydraulically connected in series.

In further embodiments, an output of a first temperature-control module of the at least two temperature-control modules is connected to an input of a second temperature-control module of the at least two temperature-control modules. This results in a particularly simple structure using multiple Temperiermodule, which comparatively large areas can be equipped with Temperiermodulen. The parallel flow through the plurality of fluid lines assigned to the lamellae in the case of preferred embodiments results in a particularly low flow resistance per temperature control module, which likewise advantageously contributes to the fact that a plurality of temperature control modules can be connected in series.

In further embodiments, at least four tempering modules are hydraulically connected in series.

In further embodiments, the temperature control system is adapted to temper the fluid to a temperature between about 16 degrees Celsius and about 20 degrees Celsius and to pressurize the at least one fluid line with the fluid. This results in an efficient temperature control of the fins and the surrounding space in the respective temperature range. Based on a standard room temperature of 20 degrees Celsius, this is preferably an efficient cooling operation possible.

In further embodiments, the tempering system is configured to temper the fluid to a temperature between about 25 degrees Celsius to about 28 degrees Celsius and to pressurize the at least one fluid line with the fluid. Based on the standard room temperature of 20 degrees Celsius this is preferably an efficient heating operation possible.

In further embodiments, the at least one lamella in at least one first axial end region on a receiving area on which the flow line and / or the return line can be supported.

In further embodiments, at least one first support rail and a second support rail for holding the at least one fin are provided, wherein the supply line and the return line between the first support rail and the second support rail are arranged.

In further embodiments, the first support rail and the second support rail and the flow line and the return line are arranged approximately parallel to each other.

In further embodiments, the flow line has at least one first tube, wherein the return line has at least one second tube. In further embodiments, the first tube and / or the second tube is made of polypropylene. In further embodiments, the first tube and / or the second tube has an outer diameter of about 20 mm. In further embodiments, the first tube and / or the second tube has a wall thickness of about 2 mm.

Further embodiments of the present invention relate to a building with at least one ceiling and / or wall cladding according to at least one embodiment. The building may, for example, be an office building and / or a residential building and / or another building in which an efficient temperature control with simultaneous absorption of sound is desirable.

In preferred embodiments, the building has at least one room, wherein the ceiling and / or wall covering is arranged in the region of a ceiling of the room. Alternatively or additionally, in other embodiments at least one wall of the building may also be provided with a ceiling and / or wall cladding according to the embodiments. In further embodiments, it is also conceivable to provide the ceiling and / or wall cladding in the region of a floor.

In further embodiments, the ceiling and / or wall cladding has a plurality of fins and at least one support rail for holding the plurality of fins.

In further embodiments, the at least one support rail is attached directly to the ceiling of the room, resulting in a secure installation and at the same time a low overall height.

In further embodiments, the at least one support rail is attached by means of a suspension device to the ceiling of the room. This advantageously results in further degrees of freedom for the vertical arrangement of the ceiling and / or wall cladding, whereby in particular the degree of convection and / or sound absorption can be influenced.

In further embodiments, the plurality of slats are releasably connected to the at least one support rail, whereby a good auditability is given. In further embodiments, the fins are spaced from the ceiling by at least about 25 millimeters. In further embodiments, the fins are spaced from the ceiling by at least about 100 millimeters.

In further embodiments, the at least one lamella is adapted to carry the weight of at least one fluid line associated therewith. As a result, at least part of the temperature control system or its components can advantageously be carried by the at least one lamella, so that, if appropriate, no separate attachment or

Mounting the Temperierungssystems in the field of ceiling and / or wall cladding is required.

Further embodiments relate to a method for producing a ceiling and / or wall paneling comprising at least one blade, wherein a Temperierungssystem is provided for controlling the temperature of the at least one blade, wherein the Temperierungssystem has at least one fluid line, for transporting a for temperature control usable fluid is formed, and which can be brought in thermal contact with the at least one lamella or stands.

In further embodiments, it is provided that at least one tempering is provided by at least one of the at least one lamella associated fluid line is connected to a flow line for supplying the at least one fluid line with a fluid, wherein the at least one lamella associated fluid line with at least a return line for returning fluid flowed through the fluid line, and wherein the at least one temperature module is mechanically connected to the at least one fin so that the at least one fluid line is brought into thermal contact with the at least one fin.

In further embodiments, the following steps are further provided: attaching at least two mounting rails to a wall or ceiling, at least temporarily fixing at least one Temperiermoduls in the region of at least two support rails, in particular between the at least two support rails, attaching at least one blade, preferably several fins, on the at least two mounting rails. Due to the fact that the at least one tempering module is fastened at least temporarily in the region of the mounting rails, individual disks or a plurality of disks can advantageously be fastened very precisely to the mounting rails without having to take into account or maintain the at least one temperature control module.

In further embodiments, it is provided that the tempering has at least one flow line for supplying at least one fluid line of Temperiermoduls with a or the fluid and at least one return line for returning fluid having flowed through the at least one fluid line of the Temperiermoduls, said at least one Fluid line between the flow line and the return line is connected.

In further embodiments, it is provided that at least temporarily fixing at least one tempering module in the region of the at least two mounting rails comprises: at least temporarily fixing at least one Temperiermoduls to the support rails and / or at least temporarily attaching at least one Temperiermoduls to a wall and / or ceiling in the area of the mounting rails. As a result, the at least one tempering module can be reliably arranged at least temporarily in the respective areas, thereby enabling precise assembly of the lamellae.

In further embodiments, it is provided that the method further comprises: arranging the at least one tempering module on at least one, preferably a plurality of lamellae already fastened to the mounting rails, in particular depositing the at least one temperature control module on or already attached to the mounting rails Slats, wherein in particular the weight of the at least one tempering is supported by the already attached to the support rails slats. As a result, the fastening means for the at least temporary attachment of the at least one tempering module in the region of the mounting rails can be removed again, resulting in a configuration with low complexity. In particularly preferred embodiments, the temperature control modules can be completely obtained by the lamellae already fastened to the mounting rails.

In a further advantageous embodiment, it is provided that the at least one lamella is brought into thermal contact with the at least one fluid line.

In a further advantageous embodiment, it is provided that the method further comprises: after arranging or depositing the at least one Temperiermoduls, releasing the at least one Temperiermoduls of the support rails and / or the wall and / or ceiling in the region of the support rails.

Further advantageous embodiments are given by the subclaims.

Other features, applications and advantages of the invention will become apparent from the following description of embodiments of the invention, which are illustrated in the figures. All features described or illustrated alone or in any combination form the subject matter of the invention, regardless of their summary in the claims or their dependency and regardless of their formulation or representation in the description or in the drawing.

Hereinafter, exemplary embodiments of the invention will be explained with reference to the drawings. 1 schematically shows a side view of a ceiling cladding according to an embodiment, FIG. 2A schematically shows a substantially U-shaped slat with fluid line according to an embodiment, FIG. 2B schematically shows a substantially U-shaped one Fig. 2C schematically shows a substantially V-shaped fin with fluid conduit according to an embodiment; Fig. 3 shows schematically a perspective view of a fin according to a further embodiment; Fig. 4 schematically shows a frontal view 5A schematically shows a side view of an axial end portion of a fin with fluid line disposed therein according to an embodiment. FIG. 5B schematically shows a side view of both axial end portions of a fin with fluid conduit disposed therein 6 shows schematically a plan view of a ceiling and / or wall cladding according to a further embodiment, [00107] FIG. 7 shows schematically a tempering module according to an embodiment, [00108] FIG. 8 schematically shows a plan view of a ceiling and / or floor covering FIG. 9A schematically shows a flow chart of a method according to an embodiment, [00110] FIG. 9B schematically shows a flow chart of a method according to a further embodiment, FIG. 9C schematically shows a flow chart of a method according to a further embodiment, FIG. 11 schematically shows a hydraulic series connection of two temperature control modules according to an embodiment, FIG. 12 shows schematically a detail from FIG. 5B according to further embodiments, [00115] FIG 13 schematically shows a substantially U-shaped louver with fluid conduit according to an embodiment; FIG. 14 schematically shows a ceiling panel with frontal view of two lamellas according to an embodiment; FIG. 15 schematically shows a substantially U-shaped lamella with two fluid conduits according to an embodiment FIG. 16 schematically shows a detail of FIG. 5B according to further embodiments, FIG. 17 schematically shows a top view of a ceiling and / or wall covering according to a further embodiment, and [00120] FIG. 18 shows schematically a side view of a building according to an embodiment ,

FIG. 1 schematically shows a side view of a ceiling panel 100 according to an embodiment. Although the following remarks are made by way of example with reference to a ceiling cladding, it will be understood that all of the invention aspects described below may be used with corresponding wall claddings or even in the floor area.

The ceiling panel 100 has a plurality of fins 110, which are preferably detachably connected to one or more support rails 102, wherein the support rails 102, of which only one is shown in Figure 1, for example, attached to a ceiling (not shown) of a room are, for example by means of screw or suspension or the like.

According to the invention, a temperature control system 120 for controlling the temperature of the slats 110 is provided. In this case, a temperature of the fins 110 can be reduced, for example (cooling operation) or, optionally, also increased (heating operation). In some embodiments, only one cooling operation or one heating operation may be provided in each case. The temperature control system 120 has a plurality of fluid lines 122, of which at least one of each corresponding lamella 110 is associated.

The temperature control system 120 further has a central unit 124, which supplies the fluid lines 122 with a fluid, which may preferably be, for example, a liquid, and which has a predefinable setpoint temperature. As soon as the fluid flows through the fluid lines 122, it releases part of its heat energy to the louvers 110, which are in thermal contact with the fluid lines 122 (heating operation) or absorbs heat energy from the louvers 110 (cooling operation). In this way, the ceiling panel according to the invention is simultaneously advantageous as "surface heating" or "surface cooling" available.

[00125] FIG. 2A schematically shows a substantially U-shaped louver 110 with fluid line 122 according to an embodiment. In the present case, the lamella 110 has a profile body 112 with a substantially U-shaped geometry, which has three wall sections 112a, 112b, 112c. As can be seen in FIG. 2A, the fluid line 122 is arranged in an inner space I of the profile body 112 in such a way that it contacts and thus makes thermal contact with inner surfaces of the opposing wall sections 112a, 112c of the profile body 112.

In the fluid line 122, a fluid 122a is transported, which is used for temperature control of the profile body 112, and which is provided for example by the central processing unit 124 of Figure 1. Particularly preferably, in one embodiment, a closed fluid circuit can be formed with the elements 122, 124, resulting in a particularly low-maintenance operation.

In further embodiments, the at least one fluid line 122 is arranged substantially completely in the U-shaped cross-section of the profile body 112, resulting in an efficient temperature control of the blade 110.

In further embodiments, the at least one fluid line 122 has at least one tube R, wherein preferably the at least one tube R consists of polypropylene. In further embodiments, the at least one tube R has an outer diameter of about 10 mm and / or a wall thickness of about 1 mm.

In further embodiments, the at least one tube R is frictionally inserted into the lamella 110, wherein preferably the at least one fluid line 122 is continuously applied to the at least one lamella 110, see Figure 3. Preferably, the at least one fluid line 122 is in further embodiments axial direction L (FIG. 3) of the at least one fin 110 along at least about 80 percent of a length L of the fin 110.

FIG. 2B schematically shows a substantially U-shaped lamella 110a with a fluid line 122 according to a further embodiment. In contrast to the configuration depicted in FIG. 2A, in the embodiment according to FIG. 2B the fluid line 122 is arranged in the interior I of the profile body 112 so that it contacts all three wall sections 112a, 112b, 112c of the profile body 112.

FIG. 2C schematically shows a substantially V-shaped lamination 110b with fluid line 122 according to a further embodiment. In the present case, the profile body 112 of the lamella 110b has two wall sections or legs 112a, 112b, which both make thermal contact with the fluid line 122, for example touching them.

In further embodiments it can be provided that in the interior I of the lamella 110; 110a; 110b at least partially a, preferably flame retardant or non-combustible, textile material (not shown) is arranged, which further increases sound-absorbing properties of the blade according to the invention.

In further embodiments it can be provided that the lamella 110; 110a; 110b openings (not shown), in particular characterized by a plurality of openings perforation, which further increases the sound-absorbing properties of the blade according to the invention.

Investigations by the applicant according to the above-mentioned textile material or the perforations can be combined as desired with the temperature control system according to the invention.

FIG. 3 schematically shows a perspective view of a lamella 110 according to a further embodiment. In a preferred variant, the blade 110 has a height H of about 40 mm (millimeters) to about 80 mm, more preferably about 55 mm. In a further preferred variant, the lamella 110 has a length L of about 3000 mm to about 8000 mm, in particular about 5200 mm. In a further preferred variant, the lamella 110 has an outer width B of about 8 mm to about 30 mm, preferably about 20 mm or about 10 mm. Particularly preferably, an inner width Bi of the lamella 110 is matched to an outer dimension of the fluid line 122 such that a good thermal contact results in the lamella 110 in the arrangement of the fluid line 122 (FIG. 2A), for example in that the wall sections or legs 112a , 112c resiliently abut with their respective inner surface on an outer surface of the fluid line 122.

FIG. 4 schematically shows a frontal view of two slats 110 according to a further embodiment. The slats 110 are detachably connected with hook-shaped mounting elements of a mounting rail 102 mounted on the ceiling D. To release the slats 110 from the mounting region 102a, for example, the two legs 112a, 112c (see FIG. 2A) can be moved towards one another in order to disengage them from the hook-shaped mounting elements of the support rail 102.

The fluid lines according to the invention are not shown in FIG. 4, but run essentially perpendicular to the plane of the drawing in an interior of the lamellae 110.

FIG. 5A schematically shows a side view of a first axial end section 110 'of a lamella 110 with fluid line 122 arranged therein according to an embodiment. FIG. 5A also shows the central unit 124 of the temperature control system 120 according to the invention (FIG. 1), which supplies a supply line 126a with fluid provided for acting on the fluid line 122. A fluid connection between the central unit 124 and the supply line 126a is indicated in Figure 5A only schematically by a non-designated line. A flow direction of the fluid in the fluid line 122 is indicated by the arrow F1 in FIG. 5A.

Furthermore, from FIG. 5A, a mounting opening 113 for detachably fastening the lamella 110 to a mounting rail 102 (FIG. 4) can be seen. In further embodiments, the lamella 110 can be positively connected to the mounting rail 102 by means of its mounting opening 113, wherein in particular the mounting opening 113 of the lamella 110 can be brought into engagement with a hook-shaped section 102a '(FIG. 4) of the mounting rail 102.

5B schematically shows a side view of both axial end sections 110 ', 110 "of the lamella 110 with fluid line 122 arranged therein, in addition to the flow line 126a, a return line 126b is illustrated in FIG As the fluid flows through the fluid line 122 from left to right in Figure 5B, it absorbs heat energy from the fin 110 in thermal contact with it, or transfers heat energy to it.

In further embodiments, the flow line 126a and the return line 126b and the at least one fluid line 122 inextricably connected to each other, in particular materially connected to each other, further in particular integrally formed.

In further embodiments, the feed line 126a at least a first tube R1, wherein the return line 126b has at least one second tube R2, wherein in particular the first tube R1 and / or the second tube R2 is made of polypropylene, more particularly the first Tube R1 and / or the second tube R2 has an outer diameter of about 20 mm, further more particularly the first tube R1 and / or the second tube R2 has a wall thickness of about 2 mm.

In a further preferred embodiment, the lamella 110 has a recess 114 in at least one first axial end region 110 ", 100". In the present case, corresponding recesses 114 are provided in both axial end regions 110 ', 100 "of the lamella 110, whereby a construction space for coupling sections or connecting regions between the flow line 126a and the fluid line 122 or between the fluid line 122 and the return line 126b is created.

Advantageously, in the axially central region 110 '", the fluid conduit 122 abuts the interior surfaces of the legs 112a, 112c (FIG. 2A) of the fin 110, thereby providing efficient transfer of heat energy between the components 110, 122 ,

A difference of the first height H1 and second height H2 depicted in FIG. 5B is preferably selected in one embodiment so that the difference corresponds essentially to at least 50% of a vertical extent of the feed line 126a or the return line 126b in FIG. 5B.

In preferred embodiments, the at least one recess 114 has a substantially approximately rectangular shape, cf. the schematic detail view of Figure 12, wherein the rectangular shape has a first length LA1 along a longitudinal axis LA of the blade 110 and a first height HA1 perpendicular to the longitudinal axis LA of the blade 110. In preferred embodiments, the first length LA1 is between about 50 millimeters and about 60 millimeters, and the first height HA1 is between about 10 millimeters and about 60 millimeters. In further embodiments, the first height HA1 is between about 10 millimeters and about 20 millimeters.

FIG. 6 schematically shows a plan view of a ceiling and / or wall covering 100 according to a further embodiment. On a plurality of mounting rails 102, which may be attached, for example, in a conventional manner to a wall or ceiling, a plurality of fins 110 are arranged, each having its own fluid line (not shown) for temperature control. The fluid lines are supplied by the central unit 124 with the fluid. This is present only schematically by the connecting lines between the

Central unit 124 and exemplified two slats 110 indicated. Similarly, a fluid that has flowed through the fluid conduits may be returned to the central processing unit 124. For this purpose, in an advantageous embodiment, the feed line 126a and the return line 126b already described above with reference to FIG. 5B can be used.

FIG. 7 schematically shows a tempering module of the system 120 according to an embodiment. The tempering module has a plurality of fluid lines 122 1, 122 2, .., 122 3, which are arranged substantially parallel to each other. All fluid lines are fluidically connected in parallel (and not in series) between the flow line 126a and the return line 126b. As a result, each fluid line 122 1, 122 2,..., 122 3 is supplied with fresh fluid directly from the supply line 126 a, and that "used up" fluid becomes, after the corresponding fluid line 122 1, 122 2, flows through and has completed a corresponding exchange of heat energy, returned centrally via the common return line 126b, for example, to the central unit 124.

The fluid circuit of the configuration according to FIG. 7 therefore comprises the following elements 124, 126a, 1221 and 122 2,..., 122 3, each in parallel, 126b, 124. A supply of "fresh" fluid from the central unit 124 to the supply line 126a is designated by reference numeral 126a 'in FIG. 7, and a recirculation of "spent" fluid from the return line 126b to the central processing unit 124 is designated by reference numeral 126b' in FIG.

The arrow F2 indicates the flow direction of the fluid in the fluid lines 122 1, 122 2,..., 122 3, which are arranged hydraulically parallel to one another.

According to one embodiment, the central unit 124 may, for example, have its own temperature control unit (not shown) for conditioning a desired temperature of the fluid, for example via a refrigeration unit and / or a heating unit. In other embodiments, it is conceivable that the central unit 124 is connected to a heating circuit or cooling circuit of a building technology of a building, in whose premises the ceiling and / or wall covering 100 according to the invention is arranged.

In a further advantageous embodiment, which is shown schematically in Figure 8, several tempering modules M1, M2 (indicated in each case by dashed rounded rectangles) in the region of the ceiling and / or wall cladding 100 according to the invention are provided so that comparatively large Ceiling surfaces or wall surfaces or their slats can be efficiently tempered.

In further embodiments, the wall or ceiling to be covered is particularly preferably first provided with a holding structure, for example with an arrangement of a plurality of mounting rails 102 (see FIG. 6). Then, according to the number of lamellae to be provided, one or more fluid lines are arranged in the region of the mounting rails, and then the lamellae can be thermally conductively connected to the fluid lines in question, for example, clamped to them.

Figure 9A shows schematically a flow diagram of an embodiment of a method for producing a ceiling and / or wall covering according to the invention. In a first step 200, at least one tempering module is provided. This can be done, for example, by at least one of the at least one lamella 110; 110a; 110b associated fluid line 122; 122 1, 122 2, .., 122 3 (Figure 7) with a flow line 126a for supplying the at least one fluid line 122; 122 1, 122 2, .., 122 3 is connected to a fluid 122a, wherein the at least one blade 110; 110a; 110b associated fluid line 122; 122 1, 122 2, .., 122 3 with at least one return line 126b (Figure 7) for returning from the fluid line 122; 122 1, 122 2, .., 122 3 flowed fluid 122a is connected.

In a second step 202 (FIG. 9A), the at least one tempering module is thus mechanically connected to the at least one blade 110; 110a; 110b, that the at least one fluid line 122; 122 1, 122 2, .., 122 3 in thermal contact with the at least one fin 110; 110a; 110b is brought. It is understood that if several fins and several fluid lines as possible all fins are brought into a correspondingly good thermal contact with their associated fluid lines, see. e.g. Fig. 2A.

FIG. 9B schematically shows a flow chart of a further embodiment of a method for producing a ceiling and / or wall covering according to the invention. In a first step 210, at least two mounting rails 102 are attached to a wall or ceiling. In a subsequent step 212, at least one tempering module M1, M2 is fastened in the region of the at least two support rails 102, in particular on the at least two support rails 102. The tempering module can be, for example, the configuration 126a, 122 1, 122 2,..., 122 3 126b according to FIG. 7, cf. also the reference symbols M1, M2 from FIG. 8. Alternatively or additionally, the at least one tempering module can also be a tempering module according to at least one of the configurations described with reference to FIGS. 8, 10, 11, 17 or any combinations thereof.

It should be noted that in other embodiments, the steps of the aforementioned method variants can also be reversed. For example, the step 212 of attaching the at least one tempering module can also take place before the step 210 of attaching the at least two carrier rails 102. In further embodiments, it is also conceivable first to attach at least one mounting rail to the ceiling or wall, then to attach at least one tempering module in this area, and then to fasten at least one further mounting rail in this area, and so forth.

In a third step 214, at least one lamella 110 is attached; 110a; 110 b on the at least two support rails 102 so that the at least one blade 110; 110a; 110b in thermal contact with at least one fluid conduit 122; 122 1, 122 2, .., 122 3 of the at least one tempering module M1, M2 is brought. Particularly advantageously, the at least one lamella 110 can be fixed in a form-fitting manner to the at least two carrier rails 102 in step 214, resulting in a stable connection.

In further embodiments, after attaching the at least one lamella to the at least two mounting rails, the at least one temperature control module can advantageously be arranged on the lamella previously fastened to the mounting rails so that at least a part of the weighting force of the temperature control module is carried by the lamella. In particular, in further embodiments, the at least one tempering module can be placed on the lamella previously fastened to the mounting rails so that at least part of the weight of the temperature control module is supported by the lamella. In further embodiments, preferably at least two or even more than two lamellae are fastened to the mounting rails, in particular positively connected therewith, before the temperature-control module is arranged or deposited on the lamellae fastened in this way.

Subsequently, the tempering module M1 can optionally be connected to the central unit 124 in order to close a fluid circuit.

[00161] Further embodiments of the present invention will be described below, which may be combined individually or in combination with one or more further aspects described below with one or more aspects of the embodiments described above.

In further embodiments, at least one blade 110, 110a, 110b made of aluminum, in particular aluminum sheet. In other embodiments, it is also possible to provide another metallic material or a non-metallic material with comparable heat-conducting properties to aluminum.

In further embodiments, the at least one fluid line 122 1, 122 2, .., 122 3 (Fig. 5B) and its associated flow line 126a and return line 126b are formed of the same material, in particular integrally formed. More preferably, a plurality or even all of the fluid lines 122 1, 122 2, .., 122 3 and their associated flow line 126 a and return line 126 b formed of the same material, in particular integrally formed.

In further embodiments, all fluid lines 122 1, 122 2, .., 122 3 directly from one or their associated flow line 126a with, in particular fresh (ie, target temperature of a flow having), fluid 122a (Fig. 2A) can be supplied , This means in some embodiments, in particular, that the fluid for supplying a relevant fluid line is provided directly from the associated flow line 126a and has not previously passed through one or more fluid lines (the same temperature control module).

In further embodiments, all the fluid lines 122 1, 122 2, .., 122 3 are connected to one or their associated return line 126b such that the fluid, after flowing through a respective fluid line 122 1, 122 2, .., 122 3 directly to the return line 126b can be fed (and not previously through at least one further fluid line (the same temperature control) flows).

FIG. 10 schematically shows components of a temperature control system 120 according to a further embodiment. In the present case, the tempering system has, by way of example, a tempering module M1, which has, similar to the configuration shown in FIG. 5B, a supply line 126a and a return line 126b and a multiplicity of fluid lines 122 1, 122 2,..., 122 3, which are preferably all connected in fluidic parallel are between the flow line 126a and the return line 126b. In contrast to the configuration shown in FIG. 5B, an input E1 of the first tempering module M1 is provided in FIG. 10, bottom left, and an output A1 of the tempering module M1 in FIG. 10, top right. Via the input E1, the supply line 126a can be supplied with fresh fluid, compare the arrow 126a ', and via the outlet A1, the fluid exits from the return line 126b, see. Arrow 126b '. In the configuration shown in FIG. 10, all the hydraulic paths (E1 -> 122_1 -> A1, E1 -> 122_2 -> A1, ..) from the input E1 to the output A1 have substantially the same length (comparable to a hydraulic one) Calibration), which ensures a particularly efficient operation.

Generally, in other embodiments, a tempering M1 may be formed so that all its individual fluid lines 122 1, 122 2, .., 122 3, in particular plus the flow line 126a and the return line 126b, associated hydraulic paths (E1-> 1221 -> A1, E1-> 122_2-> A1, .., E1-> 122_3-> A1) each about the same length (maximum deviation with respect to the longest hydraulic path is less than or equal to approximately 10%, preferably less than or equal to approximately 5%. ) are.

FIG. 11 schematically shows a hydraulic series connection of two tempering modules M1, M2 by way of example according to an embodiment, wherein an output A1 of the first temperature control module M1 (output of its return line 126b) is connected to the input E2 of the second temperature control module M2 (input 126a of its feed line) is, cf. the arrow A1E2.

In further embodiments (not shown), at least four or even six tempering modules M1, M2,... Are hydraulically connected in series.

In further embodiments, the temperature control system 120 is adapted to a) to control the temperature for the supply of the tempering M1, M2 fluid to a temperature between about 16 degrees Celsius (° C) and about 20 ° C and the at least one fluid line 122 1, 122 2, .., 122 3 to pressurize the fluid (cooling operation based on room temperature) and / or b) to temper the fluid to a temperature between about 25 degrees Celsius to about 28 degrees Celsius and the at least one fluid line with to pressurize the fluid (heating operation based on room temperature).

Generally it can be provided in further embodiments, that the at least one blade 110, 110a, 110b has a profile body 112 (Fig. 2A, 3), wherein the profile body 112 has a substantially U-shaped cross-section with three an interior I limiting Wall sections 112a, 112b, 112c has. Preferably, in further embodiments, an internal width Bi (FIG. 3) of the at least one fin 110 is between about 6 millimeters and about 20 millimeters, more preferably between about 9 millimeters and about 10 millimeters, even more preferably between about 9 according to further embodiments , 1 millimeter and about 9.3 millimeters, most preferably about 9.14 millimeters.

In further embodiments, the at least one slat 110 has an outer width B of about 10 mm and a height H of about 60 mm. In still other embodiments, the at least one fin 110 has an outer width B of about 10 mm and a height H of about 60 mm and an inner width Bi of about 9.14 mm.

In further embodiments, the at least one fin 110 (FIG. 3) has a material thickness S of about 0.4 millimeters to about 0.6 millimeters, in other embodiments preferably of about 0.43 millimeters.

In further embodiments, compare FIG. 6, a plurality of lamellae 110 are provided, wherein the plurality of louvers 110 are preferably arranged substantially parallel to each other, more preferably a louver distance DL1 between two adjacent louvers 110 (measured from outside to outside of the relevant lamellae ) is between about 20 mm and about 120 mm. In further preferred embodiments, the fin spacing DL1 is about 38 mm or about 86 mm.

In further embodiments, a center distance DA1 (measured from center to center of the respective lamellae) between adjacent lamellae is about 50 mm or about 70 mm or about 100 mm or about 140 mm.

FIG. 13 schematically shows a substantially U-shaped louver 110 with fluid line 122 according to an embodiment, wherein the fluid line 122 contacts the at least two different wall sections 112a, 112c of the profile body 112, wherein the profile body 112 has a first wall section 112a and an interior wall Substantially parallel to the first wall portion 112a arranged second wall portion 112c, and a third wall portion 112b, which connects the first wall portion 112a with the second wall portion 112c.

In preferred embodiments, the first wall portion 112a and the second wall portion 112c and the third wall portion 112b are formed substantially flat, but in other embodiments, non-planar, such as curved, may be formed.

In further preferred embodiments, the fluid line 122, together with areas B1, B2 of the first and second wall sections 112a, 112c and together with the third wall section 112b, delimits the interior I of the profile body 112 of the louver 110.

In further preferred embodiments, the fluid line 122, together with the areas B1, B2 of the first and second wall sections 112a, 112c and together with the third wall section 112b, defines a first cross-sectional subarea AQ1 of the profiled body 112, wherein preferably the first cross-sectional subarea AQ1 is approximately 60 percent or more of an overall cross-sectional area (in this case corresponding to the sum of the first cross-sectional partial area AQ1 and the second cross-sectional partial area AQ2 and the cross-sectional area of the fluid conduit 122) of the profiled body 112. The total cross-sectional area of the lamella 110 or its profile body 112 is given here by the product of its width B and its height H, see also FIG. 3.

In further embodiments, it is provided that an opening OE of the U-shaped cross section, see FIG. 3, is aligned approximately antiparallel to the gravitational vector G of the earth.

In further embodiments, it is provided that at least one support rail 102 is provided for holding the at least one lamella 110, cf. FIG. 14. In the present case, the support rail 102 is fastened to a ceiling D of a room. The at least one support rail 102 and the at least one lamella 110 are arranged substantially within the same virtual plane VE and thus enable a comparatively small total height HGES for the construction comprising the support rails 102 and the louvers 110. Particularly preferred is an overall height HGES of the ceilings - and / or wall cladding in a direction perpendicular to the virtual plane VE (that is, substantially parallel to the gravity vector of the earth) is less than or equal to about 200 millimeters.

In further preferred embodiments, the total height HGES of the ceiling and / or wall cladding in a direction perpendicular to the virtual plane VE is less than or equal to about 90 millimeters, as indicated in Figure 14, inter alia, by the partially vertical nesting of the slats 110 and the support rails 102 can be reached. Very particularly preferred embodiments, the total height HGES the ceiling and / or wall cladding is only about 85 millimeters.

In further embodiments, at least one outer surface AO of the at least one fin 110 is painted, which allows a particularly efficient radiation of heat energy.

In further embodiments, the ceiling and / or wall cladding 100 is adapted to allow free convection of a fluid surrounding the at least one fin 110, in particular ambient air, compare the arrows UL.

In further embodiments, the ceiling and / or wall cladding 100 is adapted to emit heat radiation to a surrounding space, compare the arrows WS, which according to preferred embodiments, in particular by means of the at least one slat 110 success, in turn, by the temperature control system 120 according to the invention (Fig. 1) is appropriately tempered.

In further preferred embodiments, the ceiling and / or wall cladding at room temperature and at a temperature difference of about 10 Kelvin between the fluid 122a (Fig. 2A) and the room temperature, a cooling power of about 105 watts per square meter and / or at Room temperature and at a temperature difference of about 15 Kelvin between the fluid 122a and the room temperature, a thermal output of about 90 watts per square meter.

[00187] In further preferred embodiments, the at least one fin 110 is associated with two or more fluid conduits 1220, 1221, see FIG. 15. Preferably, both (or in the case of more than two fluid conduits all) fluid conduits 1220, 1221 are substantially completely in the U-channel. shaped cross section of the profile body 112 is arranged.

Analogous to the embodiments described above with reference to FIGS. 5A, 5B, 7, 10, in the case of configurations in which a lamination as shown in FIG. 15 is assigned two or more fluid lines, the temperature control system 120 (FIG. 1) comprise at least one flow line 126a (FIG. 10) for supplying the two or more fluid lines 1220, 1221 (FIG. 15) with fluid 122a, and the temperature control system 120 may include at least one return line 126b (FIG Return of flowed through the two or more fluid lines 1220, 1221 fluid. In that regard, the same applies to the embodiments described above with a fluid line per slat. In particular, in preferred embodiments, it may also be provided that the two or more fluid lines 1220, 1221 of louver 110 (FIG. 15) are fluidly connected in parallel between the flow line and the return line, as well as all other pairs of fluid lines (not shown) optionally provided and assigned in pairs to other slats.

In some embodiments, all the fluid lines 1220, 1221 that are assigned to the same supply line 126a (FIG. 10) and the same return line 126b are particularly advantageously fluidly connected in parallel with respect to the supply line 126a and the return line 126b.

In further embodiments, cf. FIG. 10, the supply line 126a and the return line 126b of a temperature control module M1 and all the fluid lines 122 associated with the flow line 126a and the return line 126b of the same temperature control module M1; 1221, 122 2, .., 122 3; 1220, 1221 (ie in particular also those fluid lines, which are where appropriate pairwise associated with a respective lamella or pairs of mutually adjacent lamellae) connected to each other, in particular inseparably connected to each other further in particular materially connected to each other, even more particularly in one piece.

In further embodiments, cf. FIG. 16, the at least one lamella 110 has a receiving region 1140 in at least one first axial end region 110 '(but preferably in both axial end regions 110', 110 ", compare FIG. 5B, respectively) In particular, in some embodiments, the receiving area 1140 is thus suitable for at least partially accommodating a weight force, for example, of the supply line 126a and / or the return line 126b.

Figure 17 schematically shows a plan view of a ceiling and / or wall covering according to another embodiment, wherein at least a first support rail 102 'and a second support rail 102 "are provided for holding a plurality of fins 110, wherein the flow line 126a and the Return line 126b between the first support rail 102 'and the second support rail 102 "are arranged. Preferably, the first support rail 102 'and the second support rail 102 "and the supply line 126a and the return line 126b are arranged approximately parallel to one another It should be noted that, for reasons of clarity, only one of the plurality of fins is designated by the reference numeral 110 in FIG and that also for reasons of clarity, the fluid lines associated with the louvers 110, which are all connected in fluidic parallel connection between the flow line 126a and the return line 126b (and which are respectively inserted into the fins 110), are not shown.

Further embodiments of the present invention relate to a building 1000 having at least one ceiling and / or wall covering 100 according to at least one embodiment, cf. FIG. 18. The building 1000 may be, for example, an office building and / or a residential building and / or another building in which an efficient temperature control with simultaneous absorption of sound is desirable.

In preferred embodiments, the building 1000 has at least one space 1002, wherein the ceiling and / or wall cladding 100 is presently arranged in the area of a ceiling 1004 of the room 1002, in particular in FIG. 18, attached to the ceiling 1004 from below , Alternatively or additionally, in other embodiments at least one wall 1005 of the building 1000 may be provided with a ceiling and / or wall cladding according to the embodiments.

In further embodiments, the ceiling and / or wall cladding 100 comprises a plurality of fins 110, 110a, 110b and at least one support rail 102 for supporting the plurality of fins, also compare the embodiments described above with reference to the figures 1-17.

In further embodiments, the at least one support rail 102 (see also Fig. 14) is attached directly to the ceiling 1004 of the room 1002, resulting in a secure installation and at the same time a low construction height.

In further embodiments, the at least one support rail is attached to the ceiling 1004 of the room 1002 by means of a suspension device (not shown). This results in advantageous further degrees of freedom for the vertical arrangement of the ceiling and / or wall covering 100, which in particular the degree of convection and / or sound absorption can be influenced.

In further embodiments, the sipes (not shown) of the ceiling and / or wall covering 100 have a distance to the ceiling 1004 (FIG. 18) of at least about 25 millimeters.

In further embodiments, the fins are spaced from the ceiling 1004 by at least about 100 millimeters.

In further embodiments, the at least one fin 110 (FIG. 1) is designed to carry the weight of at least one fluid line 122, 1220, 1221 associated therewith and / or a feed line 126a and / or a return line 126b. As a result, at least one part of the temperature control system or its components can advantageously be carried by the at least one lamella 110, so that no separate or additional fastening or mounting of the temperature control system in the area of the ceiling and / or wall cladding 100 or on the ceiling 1004 may occur or on the wall 1005 is required.

Overall, the ceiling and / or wall covering 100 according to the invention advantageously allows an energy saving at the same temperature sensation due to the efficient temperature control, a uniform temperature distribution over the entire ceiling and / or wall cladding 100 and advantageously also a short heating or cooling time. Furthermore, a very simple installation, excellent overhaul and a very good sound absorption is given. In addition, the ceiling and / or wall covering 100 of the invention has a timeless, elegant design and advantageously also allows the integration of other components such as lights.

Other embodiments relate to a method for producing a ceiling and / or wall cladding 100 comprising at least one blade 110, wherein a Temperierungssystem is provided for controlling the temperature of the at least one blade, wherein the Temperierungssystem has at least one fluid line 122, which for transport is formed of a suitable temperature control fluid 122a, and which is in thermal contact with the at least one fin 110th

In further embodiments it is provided that at least one tempering M1, M2 (Fig. 10, 11) is provided by at least one of the at least one blade 110 associated fluid line 1221 with a flow line 126a for supplying the at least one fluid line 1221 with a Fluid is connected, wherein the at least one blade 110 associated fluid line 1221 is connected to at least one return line 126b for returning fluid having flowed through the fluid line 1221, and wherein the at least one tempering M1, M2 is mechanically connected to the at least one blade 110 in that the at least one fluid line 1221 is brought into thermal contact with the at least one fin 110.

In further embodiments, the following steps are further provided: attaching at least two support rails 102, 102 ', 102 "to a wall 1005 (FIG. 18) or ceiling 1004, at least temporarily fixing at least one tempering module M1 in the region of at least two Support rails, in particular between the at least two support rails (Fig. 17), attaching at least one blade 110, preferably a plurality of fins 110, to the at least two support rails 102 ', 102 ". Because the at least one tempering module M1, M2 is fastened at least temporarily in the region of the mounting rails, individual laminations or several laminations can advantageously be fastened very precisely to the mounting rails without the at least one temperature control module having to be considered or held.

In further embodiments, it is provided that the tempering module M1, M2 has at least one feed line 126a for supplying at least one fluid line of the temperature control module with one or the fluid and at least one return line 126b for returning fluid that has flowed through the at least one fluid line of the temperature control module wherein the at least one fluid line is connected between the flow line and the return line.

In further embodiments, it is provided that the at least temporary fastening of at least one tempering module M1, M2 in the region of the at least two support rails 102 ', 102 "(FIG. 17) comprises: at least temporary fixing of at least one tempering module M1 to the support rails 102'. , 102 "and / or at least temporarily affixing at least one tempering module M1 to a wall 1005 and / or ceiling 1004 in the region of the mounting rails 102 ', 102", whereby the at least one temperature control module M1 can be reliably arranged at least temporarily in the respective areas a precise assembly of the slats 110 is made possible.

In further embodiments, it is provided that the method further comprises: arranging the at least one tempering module M1 on at least one, preferably a plurality, already attached to the support rails 102 ', 102' 'fins 110, in particular laying down the at least one tempering M1 the lamellae 110 already fastened to the support rails 102 ', 102 ", wherein in particular the weight of the at least one temperature control module M1 is supported by the louvers 110 already fastened to the support rails 102', 102". As a result, the fastening means for the at least temporary fixing of the at least one tempering module M1 in the region of the support rails 102 ', 102 "(in particular after the at least one tempering module M1 has been loosened) can be removed again, resulting in a configuration of low complexity in preferred embodiments, the tempering modules M1, M2 are completely held by the blades 110 already fastened to the support rails 102 ', 102 ".

In further advantageous embodiments, it is provided that the at least one lamella 110 is brought into thermal contact with the at least one fluid line 122.

In further advantageous embodiments, it is provided that the method further comprises: before or after arranging or depositing the at least one tempering module M1, M2, detaching the at least one tempering module M1 from the support rails 102 ', 102 "and / or the Wall 1005 and / or ceiling 1004 in the area of the mounting rails.

In further advantageous embodiments, it is provided that the method has the following steps, cf. 9C: providing 302 at least one tempering module M1, M2 for tempering the at least one fin 110, attaching 304 of at least two mounting rails 102 to a wall 1005 and / or ceiling 1004, attaching 306 the provided at least one tempering module M1, M2, in particular in the region of the support rails 102, in particular between the support rails 102, attaching 308 the at least one blade 110 to the at least two support rails 102, attaching 310 of the at least one tempering M1, M2 to the at least one blade 110th

In further embodiments, the aforementioned steps 302, 304, 306, 308, 310 (in whole or in part) may also be carried out in a different order to one another.

In further advantageous embodiments, it is provided that the provision 302 of the at least one tempering module M1, M2 comprises the provision 302a of at least one prefabricated tempering module M1, M2, wherein in particular the prefabricated tempering module M1, M2 at least one feed line 126a for the fluid 122a and at least one return line 126b for the fluid and at least one, but preferably a plurality of fluid lines 122; 122 1, 122 2, .., 122 3; 1220, 1221, wherein in particular the at least one, but preferably a plurality of fluid conduits 122; 122 1, 122 2, .., 122 3; 1220, 1221, fluidly connected in parallel between the flow line 126a and the return line 126b are connected, in particular permanently connected to the flow line and the return line, further in particular cohesively the flow line and return line are connected, in particular integrally with the flow line and the return line are formed.

In further advantageous embodiments it is provided that the attachment 304 of the at least two mounting rails 102 to a wall 1005 and / or ceiling 1004 comprises: attaching 304a of the at least two mounting rails 102 directly to the ceiling 1004 and / or the wall 1005 or hanging 304 b of the at least two mounting rails 102 from the ceiling 1004 and / or the wall 1005.

In further advantageous embodiments it is provided that the attachment 306 of the provided at least one tempering module M1, M2 comprises: at least temporary attachment 306a of the at least one tempering module M1, M2 to the support rails 102 and / or at least temporary attachment 306b of the at least one tempering module M1, M2 on the wall 1005 and / or ceiling 1004, in particular in the region of the mounting rails.

In further advantageous embodiments, it is provided that the attachment 308 of the at least one lamella 110 to the at least two carrier rails 102 comprises: positively connecting the at least one lamination 110 to the at least two carrier rails 102.

In further advantageous embodiments, it is provided that the attachment 310 of the at least one tempering module M1, M2 to the at least one fin 110 comprises placing the tempering module M1, M2 on the at least one fin 110, in particular such that the weight of the at least a Temperiermoduls M1, M2 at least partially, preferably approximately completely, is supported by the at least one fin 110 (or in the case of several fins 110 through the plurality of fins 110), in particular the laying of the tempering M1, M2 on the at least one fin 110th further comprising: inserting the at least one fluid conduit 122; 122 1, 122 2, .., 122 3; 1220, 1221 in the at least one blade 110, in particular so that a thermal contact between the at least one fluid line 122; 122 1, 122 2, .., 122 3; 1220, 1221 and the at least one blade 110 is produced.

It is understood that in embodiments in which a respective fluid line 122 of the temperature control module M1 is assigned to a lamella 110 (FIG. 2A), the corresponding fluid line is inserted into the lamella associated therewith. Furthermore, in embodiments in which in each case two or more fluid lines of the temperature control module are assigned to a single lamella (FIG. 15), the two or more fluid lumens 1220, 1221 associated with the lamella 110 can accordingly be inserted into the relevant lamella 110.

In further embodiments in which a plurality of fluid lines and a plurality of fins are provided, the insertion of all fluid lines of a Temperiermoduls in their respective associated fins can be carried out substantially simultaneously, because the Temperiermodul M1 is a monolithic component. For example, the tempering module M1 may in some embodiments initially be released from its temporary attachment point in the region of the mounting rails and then be inserted into the disks previously fastened to the mounting rails.

In further embodiments, after the abovementioned steps, a fluidic connection can also be established between the one or more temperature control modules M1, M2 and the central unit 124 (FIG. 1) (in particular now arranged in or on the relevant lamellae).

Claims (48)

claims 1. Ceiling and / or wall cladding (100) comprising at least one lamella (110; 110a; 110b), wherein a temperature control system (120) for controlling the temperature of the at least one lamella (110; 110a; 110b) is provided, and wherein the Temperierungssystem (120) has at least one fluid line (122) which is designed to transport a fluid (122a) which can be used for temperature control and which is in thermal contact with the at least one lamella (110; 110a; 110b), the at least one lamella (122) 110, 110a) has a profiled body (112), wherein the profiled body (112) has a substantially U-shaped cross section with three wall sections (112a, 112b, 112c) delimiting an interior space (I), and wherein the fluid conduit (122) is such in the interior space (I) is arranged so that it is in thermal contact with at least two different wall portions (112a, 112c) of the profile body (112), wherein preferably the fluid conduit (122) the at least two different Wandabsc Nuten (112a, 112c) of the profile body (112) touches, wherein the temperature control system (120) at least one flow line (126a) for supplying the at least one fluid line (122; 122 1, 122 2, 122 3) with one or the fluid (122a), and wherein the tempering system (120) comprises at least one return line (126b) for returning through the at least one fluid line (122; 122 1, 122 2, 122; .., 122 3) has flowed fluid (122a), wherein a plurality of fluid conduits (122; 122 1, 122 2, .., 122 3) are provided and fluidly connected in parallel between the flow line (126a) and the return line (126b). 2. ceiling and / or wall cladding (100) according to claim 1, wherein at least one lamella (110b) has a profile body (112), wherein the profile body (112) has a substantially V-shaped cross-section with two an interior (I) limiting Wall portions (112a, 112b), and wherein the fluid line (122) is arranged in the inner space (I) in that it is in thermal contact with at least two different wall portions (112a, 112b) of the profile body (112), preferably Fluid line (122) which contacts at least two different wall portions (112a, 112b) of the profile body (112). The ceiling and / or wall cladding (100) of any one of the preceding claims, wherein the at least one fin (110; 110a; 110b) has a recess (114) in at least a first axial end portion (110 ', 110 ") in particular, the at least one lamella (110, 110a, 110b) in each case has a recess (114) in two opposite axial end regions (110 ', 110 "). 4. Ceiling and / or wall cladding (100) according to any one of the preceding claims, wherein one or more tempering (M1, M2) are provided, each of which at least one flow line (126a) for supplying at least one fluid line (122, 1221, 122 2, .., 122 3) of the tempering module (M1, M2) with one or the fluid (122a), and wherein each tempering module (M1, M2) has at least one return line (126b) for returning it through the at least one fluid line ( 122, 122 1, 122 2, .., 122 3) of the tempering module (M1, M2) has fluid (122a) that has flowed through. 5. A ceiling and / or wall cladding (100) according to any one of the preceding claims, wherein an internal width (Bi) of the at least one fin (110; 110a) is less than or equal to an outside dimension of the at least one fluid conduit (122), preferably about 2 Millimeters smaller. 6. ceiling and / or wall cladding (100) according to any one of the preceding claims, wherein in an interior (I) of the lamella (110; 110a; 110b) at least partially a, preferably flame-retardant or non-combustible, textile material is arranged, and / or wherein the lamella (110; 110a; 110b) has openings, in particular a perforation characterized by a plurality of openings. 7. ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein at least one lamella (110; 110a; 110b) made of aluminum, in particular aluminum sheet. 8. ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the at least one fluid line (122 1, 122 2, ..) and its associated flow line (126a) and return line (126b) are formed of the same material, in particular a plurality of fluid lines (122 1, 122 2, ..) and their associated flow line (126 a) and return line (126 b) are formed of the same material, in particular integrally formed, wherein further in particular all fluid lines (122 1, 122 2, ..) and their associated flow line (126 a) and return line (126 b) are formed of the same material, in particular are integrally formed. 9. ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein all fluid lines (122 1, 122 2, ..) directly from one or their associated flow line (126a) with fluid (122a), in particular fresh fluid, are supplied. 10. ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein at least one support rail (102) is provided and wherein the lamella (110; 110a; 110b) is detachably connectable to the at least one support rail (102), wherein, in particular, the lamella (110; 110a; 110b) can be connected in a form-fitting manner to the support rail (102) by means of a mounting opening (113). 11. ceiling and / or wall cladding (100) according to at least one of claims 3 to 10, wherein the recess (114) has substantially approximately rectangular shape, in particular the rectangular shape a first length (LA1) along a longitudinal axis of the blade (110; 110a, 110b) and a first height (HA1) perpendicular to the longitudinal axis of the blade (110; 110a; 110b), wherein in particular the first length (LA1) is between about 50 millimeters and about 60 millimeters, in particular the first height (HA1). HA1) is between about 10 millimeters and about 60 millimeters, more particularly the first height (HA1) being between about 10 millimeters and about 20 millimeters. 12. ceiling and / or wall cladding (100) according to any one of the preceding claims, wherein the at least one lamella (110; 110a; 110b) has a profile body (112), wherein the profile body (112) has a substantially U-shaped cross-section with three an interior space (I) defining wall portions (112a, 112b, 112c). 13. Ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein an inner width (Bi) of the at least one lamella (110; 110a) is between about 6 millimeters and about 20 millimeters, wherein in particular an inner width (Bi) the at least one fin (110; 110a) is between about 9 millimeters and about 10 millimeters. 14. A ceiling and / or wall covering (100) according to at least one of the preceding claims, wherein the at least one lamella (110; 110a; 110b) has a height (H) of about 40 mm to about 80 mm. 15. Ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the at least one lamella (110; 110a; 110b) has an outer width (B) of about 8 mm to about 30 mm, in particular of about 10 mm , 16. ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the at least one fluid line (122; 122; 122 1, 122 2, .., 122 3) at least one tube (R), in particular the at least one tube (R) consists of polypropylene, wherein in particular the at least one tube (R) has an outer diameter of about 10 mm, wherein in particular the at least one tube (R) has a wall thickness of about 1 mm, wherein in particular the at least one Pipe (R) non-positively in a blade (110, 110a) is inserted. 17. The ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the at least one fluid line (122; 122; 122 1, 122 2, .., 122 3) is continuous to the at least one fin (110; 11 Ob) is present. 18. Ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the at least one fluid line (122; 122; 122 1, 122 2, .., 122 3) in the axial direction of the at least one blade (110; 110a, 110b) abuts along at least about 80 percent of a length of the fin (110; 110a; 110b). 19. A ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein a plurality of fins (110; 110a; 110b) are provided, wherein the plurality of fins (110; 110a; 110b) are arranged substantially parallel to each other, wherein a finned spacing (DL1) between two adjacent fins (110) is between about 20 mm and about 120 mm. 20. Ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the fluid line (122) contacts the at least two different wall sections (112a, 112c) of the profile body (112). 21. The ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the at least one lamella (110; 110a) has a profile body (112) and the profile body (112) has a first wall portion (112a) and a substantially a second wall section (112c) arranged parallel to the first wall section (112a), and a third wall section (112b) connecting the first wall section (112a) to the second wall section (112c), wherein in particular the first wall section (112a) and the second wall portion (112c) and the third wall portion (112b) are formed substantially flat. 22. ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the fluid line (122) together with areas (B1, B2) of the first and second wall portion (112a, 112c) of the profile body (112) and together with the third wall section (112b) of the profile body defines a first cross-sectional partial area (AQ1) of the profile body (112), wherein in particular the first cross-sectional partial area (AQ1) amounts to approximately 60 percent or more of an overall cross-sectional area of the profile body (112). The ceiling and / or wall panel (100) according to at least one of the preceding claims, wherein the at least one fin (110; Earth is aligned. 24. Ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the at least one fluid line (122) is substantially completely in the U-shaped cross section of the profile body (112) of the at least one lamella (110; 110a; 110b ) is arranged. 25. Ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the at least one lamella (110; 110a; 110b) are associated with two or more fluid lines (1220, 1221). 26. The ceiling and / or wall cladding (100) of claim 25, wherein the temperature control system (120) has at least one flow line (126a) for supplying the two or more fluid lines (1220, 1221) with a fluid (122a), and wherein the tempering system (120) has at least one return line (126b) for returning fluid (122a) having flowed through the two or more fluid lines (1220, 1221). 27. ceiling and / or wall cladding (100) according to claim 26, wherein the two or more fluid lines (1220, 1221) are fluidly connected in parallel between the flow line (126a) and the return line (126b), wherein in particular all the fluid lines (1221, 122 2, .., 122 3; 1220, 1221) associated with the same flow line (126a) and the same return flow line (126b) are fluidically connected in parallel to each other with respect to the flow line (126a) and the return line (126b). 28. ceiling and / or wall cladding (100) according to at least one of claims 4 to 27, wherein the flow line (126a) and the return line (126b) of a temperature control module (M1) and all of the flow line (126a) and the return line (126b) The same temperature control module (M1) associated fluid lines (122; 122 1, 122__2, .., 122 3; 1220, 1221) are interconnected, in particular inseparably connected to each other, in particular materially connected to each other, further in particular are integrally formed. 29. Ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the flow line (126a) and the return line (126b) and the at least one fluid line (122; 122 1, 122 2, .., 122 3) are inseparably connected to each other, in particular materially connected to each other, further in particular are integrally formed. 30. Ceiling and / or wall cladding (100) according to at least one of the preceding claims 4 to 29, wherein at least two Temperiermodule (M1, M2) are hydraulically hinterei-nandergeschaltet, wherein in particular an output (A1) of a first tempering (M1) of at least two tempering modules (M1, M2) are connected to one input (E2) of a second tempering module (M2) of the at least two tempering modules (M1, M2), more particularly at least four tempering modules (M1, M2, ..) being connected in series hydraulically. 31. A ceiling and / or wall covering (100) according to at least one of the preceding claims, wherein the at least one lamella (110; 110a; 110b) has a receiving region (1140) in at least one first axial end region (110 ', 110' '), on which one or the flow line (126a) and / or one or the return line (126b) can be supported. 32. Building (1000) having at least one ceiling and / or wall cladding (100) according to at least one of the preceding claims, wherein the building (1000) has at least one space (1002), and wherein the ceiling and / or wall cladding (100 ) is arranged in particular in the region of a ceiling (1004) of the space (1002). 33. The building (1000) of claim 32, wherein the fins (110; 110a; 110b) are at least about 25 millimeters from the ceiling (1004). 34. A building (1000) according to at least one of claims 32 to 33, wherein the lamellae (110; 110a; 110b) have a distance to the ceiling (1004) of at least about 100 millimeters. 35. A method for producing a ceiling and / or wall covering (100), in particular for producing a ceiling and / or wall covering (100) according to at least one of claims 1 to 31, comprising at least one lamella (110), wherein a Temperierungssystem ( 120) for temperature control of the at least one lamella (110; 110a; 110b) is provided (200), wherein the Temperierungssystem (120) has at least one fluid line (122), which is adapted to transport a suitable for temperature control fluid (122a), and which is in thermal contact with the at least one blade (110; 110a; 11 Ob), the at least one blade (110; 110a) having a profile body (112), the profile body (112) having a substantially U-shaped cross-section three wall sections (112a, 112b, 112c) delimiting an interior space (I), and wherein the fluid line (122) is arranged in the interior space (I) in thermal contact with at least two different ones Wall sections (112a, 112c) of the profile body (112) is, wherein preferably the fluid line (122) contacts the at least two different wall portions (112a, 112c) of the profile body (112), wherein the temperature control system (120) at least one flow line (126a) for Supplying the at least one fluid line (122; 122 1, 122 2, .., 122 3) with one or the fluid (122a), and wherein the temperature control system (120) at least one return line (126b) for returning from the at least one fluid line (122, 1221, 122 2, .., 122 3) has flowed fluid (122a), wherein a plurality of fluid lines (122; 122 1, 122 2, .., 122 3) are provided and fluidly connected in parallel between the flow line (126a) and the return line (126b) are. 36. The method of claim 35, wherein at least one tempering module (M1, M2) is provided (200) by at least one of the at least one blade (110; 110a; 110b) associated fluid line (122; 122 1, 122 2, .., 122 3) is connected to the supply line (126a) for supplying the at least one fluid line (122; 122 1, 122 2, .., 122 3) with a fluid (122a), wherein the at least one lamella (110; 110a; 110b) to the at least one return line (126b) for returning fluid having flowed through the fluid line (122; 122 1, 122 2, ..., 122 3) (122a), and wherein the at least one tempering module (M1, M2) is mechanically connected (202) to the at least one fin (110; 110a; 110b) such that the at least one fluid conduit (122; 122 1, 122 2 3, 3) is brought into thermal contact with the at least one blade (110; 110a; 11 Ob). 37. Method according to one of claims 35 to 36, comprising the following steps: attaching (210) at least two mounting rails (102, 102 ', 102') to a wall (1005) or ceiling (1004), in particular a building (1000 ), at least temporary fixing (212) of at least one tempering module (M1, M2) in the region of the at least two carrier rails (102, 102 ', 102 "), in particular between the at least two carrier rails (102, 102', 102"), fastening (FIG. 214) of at least one lamella (110; 110a; 110b), preferably a plurality of lamellae (110; 110a; 110b), on the at least two carrier rails (102; 102 ', 102 "). 38. Method according to claim 37, wherein the tempering module (M1, M2) has at least one feed line (126a) for supplying at least one fluid line (122; 122 1, 122 2, .., 122 3) of the tempering module (M1, M2) with a or the fluid (122a) and at least one return line (126b) for returning fluid (122a) which has flowed through the at least one fluid line (122; 122 1, 122 2, .., 122 3) of the temperature control module (M1, M2). and wherein the at least one fluid line (122; 122 1, 122 2, .., 122 3) is connected between the flow line (126a) and the return line (126b), wherein in particular the at least one fluid line (122; 122 1, 122 2, .., 122 3) is materially connected to the flow line (126a) and the return line (126b) is connected, in particular integrally with the flow line (126a) and the return line (126b) is formed. 39. The method according to claim 37, wherein the at least temporarily fixing (212) of at least one tempering module (M1, M2) in the region of the at least two carrier rails (102, 102 ', 102 ") comprises: at least temporarily fixing at least one Temperature control module (M1, M2) on the mounting rails (102, 102 ', 102 ") and / or at least temporarily fixing at least one tempering module (M1, M2) to the wall (1005) and / or ceiling (1004), in particular in the area of Support rails (102, 102 ', 102 "). 40. Method according to claim 37, wherein the method further comprises: arranging the at least one tempering module (M1, M2) on at least one, preferably a plurality of lamellae already fastened to the support rails (102, 102 ', 102' ') (110), in particular laying down of the at least one tempering module (M1, M2) on the lamination (110) already attached to the support rails (102, 102 ', 102 "), in particular such that the weight of the at least one temperature control module ( M1, M2) is supported at least partially, preferably approximately completely, by the lamellae (110) already fastened to the support rails (102, 102 ', 102 "). 41. The method of claim 35, wherein the at least one fin is brought into thermal contact with the at least one fluid conduit. 42. The method according to claim 40, wherein the method further comprises: after arranging or depositing the at least one temperature control module, releasing the at least one temperature control module from the mounting rails and / or the wall and / or ceiling in the area of the mounting rails. 43. The method according to at least one of claims 35 to 42, comprising the following steps: providing (302) at least one tempering module (M1, M2) for tempering the at least one blade (110; 110a; 110b) attaching (304) at least two Mounting rails (102) on a wall (1005) and / or ceiling (1004), attachment (306) of the provided at least one tempering module (M1, M2), in particular in the region of the mounting rails (102; 102 ', 102 "), attachment ( 308) of the at least one lamella (110; 110a; 110b) on the at least two support rails (102; 102 ', 102 "), affixing (310) the at least one temperature control module (M1, M2) to the at least one lamination (110; 110a 110b). 44. The method of claim 43, wherein providing (302) of the at least one tempering module (M1, M2) comprises providing at least one prefabricated tempering module (M1, M2), wherein in particular the prefabricated tempering module (M1, M2) at least one feed line (126a ) for the fluid (122a) and at least one return line (126b) for the fluid and at least one, but preferably a plurality of fluid conduits (122; 122 1, 122 2, .., 122 3; 1220, 1221), wherein in particular at least one, but preferably a plurality, fluid lines (122; 122 1, 122 2, .., 122 3; 1220, 1221), is connected in fluidic parallel between the flow line (126a) and the return line (126b), in particular undetachably connected to the flow line (126a) and the return line (126b) are further in particular materially connected to the flow line (126a) and the return line (126b) are connected, in particular integrally with the Vorlauflei Device (126a) and the return line (126b) are formed. 45. The method of claim 43, wherein attaching the at least two mounting rails to a wall and / or ceiling comprises: attaching the at least two Support rails (102, 102 ', 102 ") directly on the ceiling (1004) and / or the wall (1005) and / or suspension of the at least two support rails (102, 102', 102") from the ceiling (1004) and / or the wall (1000). 46. Method according to claim 43, wherein attaching (306) of the provided at least one tempering module (M1, M2) comprises: attaching the at least one tempering module (M1, M2) to the carrier rails (102, 102 ') at least temporarily. , 102 ") and / or at least temporarily attaching the at least one tempering module (M1, M2) to the wall (1005) and / or ceiling (1004), in particular in the region of the mounting rails (102, 102 ', 102"). 47. The method of claim 43, wherein attaching the at least one lamella to the at least two carrier rails comprises: at least one of the at least one lamination Lamella (110; 110a; 110b) with the at least two carrier rails (102; 102 ', 102 "). 48. The method according to claim 43, wherein attaching the at least one tempering module to the at least one fin comprises: placing the tempering module on the at least one lamella (110; 110a; 110b), in particular such that the weight of the at least one tempering module (M1, M2) is at least partially, preferably approximately completely, carried by the at least one lamella (110; 110a; 110b) In particular, placing the tempering module (M1, M2) on the at least one fin (110; 110a; 110b) further comprises: inserting the at least one fluid line (122; 122 1, 122 2, 122 3; 1220, 1221) into the at least one Lamella (110; 110a; 110b), in particular such that a thermal contact between the at least one fluid line (122; 122 1, 122 2, .., 122 3; 1220, 1221) and the at least one lamella (110; 110a; 110b) is produced. For this 12 sheets of drawings