CH643933A5 - DEVICE FOR TEMPERATURE ROOMS OF A BUILDING WITH FAÇADE WALLS. - Google Patents

Description

The invention relates to a device for temperature control 20 of rooms of a building with facade walls, which comprise a metal frame of supports and bars, on which facade elements are attached essentially free of thermal bridges.

A room is perceived as comfortable when its room and ambient temperature is around 20 ° C with practically still air. Such a room enclosure surface temperature of 20 ° C is not achieved by the previously known metal facade walls and curtain walls. This value is usually significantly below 30, since the mostly undivided metal construction or scaffolding parts made up of mostly vertical posts and horizontal transoms, which form a support for the facade or curtain walls, do not have any thermal resistance influencing the thermal insulation and in this respect 35 are to be equated with simple sheet metal walls. The requirements of DIN 4103 mostly remain unfulfilled.

Accordingly, if people are in the interior of the room in the vicinity of such facade walls, their heat loss to the cold metal construction parts is increased in winter, while the opposite is true in summer. Posts and transoms of the metal scaffolding of a wall are heated up by solar radiation, which in turn heats up the rooms and the comfort of the people in the room is impaired by the heat radiation from the heated facade construction, especially when the metal scaffolding, as in recent times frequently found, anodized in dark color or painted. Summer temperatures of usually more than 36 ° C room temperature are not uncommon.

50 To overcome this problem, temperature control systems, so-called induction air conditioning systems, are known which have a central temperature control system and an induction device in each room. The induction devices are connected to the central temperature control system via pipes, 55 whereby a forward and return flow for a heat-carrying means of transport, a forward and a return flow for a heat-dissipating means of transport as well as a supply line for primary air are required. These lines must be routed separately to each induction device in each room. Induction temperature control systems of this type have the disadvantage that their construction is very complex, that their operation requires a great deal of energy and that dirt in the individual rooms is constantly whirled up in the room. Another disadvantage is that the induction system can hardly influence the temperature of so-called radiation holes. Radiation holes of this type are wall areas whose temperature differs very greatly from the average room temperature. Typical

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Radiation holes can, for example, be profiled in glass window areas or in a box shape. The outer edge lengths of the be, which (in summer) by solar radiation an additional rectangle are advantageously 100 mm x 60 mm. enable heating of the metal wall construction. In particular, it can be provided that the temperature

A device with integrated facades is also known for the temperature control of external rooms of a generating device attached to the associated scaffold part, specifically on the outside of the heat transfer elements, in which a scaffold made of hollow supports and filteil, which the tube containing the heat transfer medium Hollow bolts for facade elements and window surfaces is facing away. Due to the direct installation of the heat transfer, the flow profile part on the associated scaffold section is connected in a defined manner and a heat transfer liquid drive of the temperature control device removes the heat from the inside of the scaffold between a flow and an OK kig with the heat transfer profile part designed return. As a result, cold or warm metal pipes can be transferred directly from it to the scaffolding parts of the wall of a room in a satisfactory manner by heat conduction. The pipe, which in particular has an

Tempered and thus has a comfortable climate with a diameter of 22 mm, and the high-profile warmth

Be created inside the room. In this tempering transmission profile part, especially with outer edge length device, it is disadvantageous that the metal structure of the is of 100 mm x 60 mm, create a good one, especially if aluminum wall is provided for the heat transport medium nium as a material for both parts got to. Such temperature control devices can therefore only be used for heat transfer with a comparatively small amount if they already have a heat transfer medium to be circulated due to the design of the building as a predetermined design factor of a tube with a small inner diameter.

were provided. Subsequent installation in already existing buildings is such that standing buildings without a temperature control device are arranged so that the temperature control device is arranged in a comparatively simple manner on the metal frame without any gaps between the metal wall scaffolding already created, so that the passage of the practically no longer possible. Furthermore, a tight radiation coupling between the scaffold and this temperature control device is disadvantageous in that the flow temperature control device is formed. This device has the advantage that the heat transport medium passes through the 25 in that, due to the fact that the non-contact, hollow-profiled metal frame of the wall is exposed due to the difference between the frame and the temperature control device

Equally large hollow cross-section necessitates a large circulation work of the amount of a heat transport medium pointing to the temperature control device, so there is no scaffold outer surface and also no corrosion damage that the temperature of the rooms of a building can only occur with one due to contact. The building's inertia can be regulated. 30 wall is therefore not subject to damage, and it

The object of the invention is to provide a device for tempering a device according to the invention for tempering rooms in a building which can be easily and quickly connected to many different scaffolding parts, in particular the type described, which not only in vertical structures and in new buildings Horizontal bolts, designed with this in mind, but also in the case of existing ones, whereby inaccuracies in the scaffolding parts of the buildings are very simple and cost-effective. Only a few fastenings can be installed cheaply, and a simple and easy point of the temperature control device on the wall, the rapid control of the room temperature is possible. especially when feeding and returning the pipe performance system

The solution to this problem according to the invention can be provided in the temperature control device,

characterizing part of claim 1 specified, while the temperature control device according to the invention can be found in advantageous further developments of this solution, the patent claims 40 to 18 can be found harmoniously in the design of existing rooms. insert, since practically only an existing pattern of

The invention advantageously enables an indi-wall due to the scaffold configuration in the contouring, direct heat transfer from the warm to the cold side, thus being utilized and possibly underlined. Due to the fact that in the case of cooling, for example, the heat transfer frame, which is insulated from the outside and out of the room, from supports and locking from a facade construction to a cooling cone, and the arrangement of the temperature control device in the construction through the circulation of the cooling medium in the right equipment to the frame in Interior increases

Tempering device from the sunny side to the shadow - the radiation intensity of the scaffolding part to the side, i.e. can be used in the thermal side. The temperature is a plane parallel to the wall, in which mostly window surfaces, which are aligned with respect to the scaffolding, are located. People who, for example, in winter can lie more or less directly on scaffolding parts. The 50 near the window next to a tempered scaffolding part, heat can thus be a pleasant heat radiation in the operation of the inventive temperatures despite the perperating device by heat conduction and / or cold window surfaces, and thereby the comfort coupling between the active parts is transmitted. Maintaining the feeling of people even then or he- It has been shown that they are very simple and cost-effective if they are close to the wall. The previous way, a satisfactory temperature control can be achieved even with the above-described, winter effect of the elevation buildings, in which the temperature control of the comfort also applies to the summer, especially if the device has been installed retrospectively . especially when the solar radiation under one

An expedient embodiment of the invention provides that angle acts through the window wall on the scaffolding parts, that the tempering device consists of a single one and this consists of the incident radiant heat together with the tube, which is in one piece with a heat transfer heat that is emitted by people near the window. profile part is formed. The pipe can have a round cross-section through the temperature control system according to the invention, and it has the inside diameter of the pipe. It has been shown that due to the rapid removal, in particular 22 mm. sportes the heat through the heat transfer fluid in the

Pipe system of the tempering device no pipe and heat transfer profile part can be made of aluminum for the purpose of radiation effect on the side of the tempering device-good heat conduction. tion occurs that points into the interior of the room. Undesirable

Advantageously, the heat transfer profile part has radiation side effects which affect the indoor climate and a hollow cross section and is in particular rectangular, are thus practically excluded.

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In a preferred embodiment, the temperature control device is located at a distance of approximately 50 mm from the associated scaffolding part in rooms of normal dimensions. As a result, the advantages of the freedom of contact described above are achieved with an optimum radiation coupling between the functional parts.

Another development of the invention provides that the piping system of the temperature control device has at least partially a double or multiple pipe with parallel flow between the flow and return. As a result, particularly good temperature control values can be achieved even if the framework part to be temperature-controlled is designed to be particularly wide or generally of large area. The individual pipe sections can have the same diameter, so that their manufacture is simplified.

A particularly advantageous development is characterized in that the pipeline system has an additional radiation / reflector part formed integrally with the tube between the flow and return along the areas of heat transfer. In this way, with a particularly simple manufacture of the temperature control device and a minimum of required heat transport fluid in the system, an even better temperature control effect is achieved which is surprisingly established.

The radiation / reflector part can have a U-shape in cross-section, the free ends of the U-legs being directed essentially towards the associated frame part.

However, the radiation / reflector part can also have a parabolic shape in cross-section, the line pipe or pipes lying or lying in the region of the radiation center or focal point and the free longitudinal edges of the radiation / reflector part being directed essentially towards the scaffolding part. The temperature control device according to the latter embodiment is thus designed in a channel-shaped manner with optimal use of thermal engineering aspects, the concave wall of the temperature control device pointing into the interior of the room. Regardless of the thermal advantages of this embodiment, architectural aspects can be taken into account practically without major manufacturing costs, and the further advantage of reducing the risk of injury to people inside the room is also achieved.

The radiation / reflector part can be coated on the inside with a reflecting medium, namely on its wall, which is directed towards the associated scaffolding part.

The width of the radiation / reflector part advantageously corresponds to the width of the associated frame part.

The invention is described below using exemplary embodiments with reference to the drawing; show it:

La a detail of a temperature control device according to the invention in a horizontal section through a building wall,

1b shows a further detail of a temperature control device according to the invention with a wall fastening in a horizontal section through a building wall,

1c shows a further embodiment of the heat transfer profile shown in FIGS. 1a and 1b,

1d shows a further embodiment of the heat transfer profiles shown in FIGS. 1a and 1b,

Fig. Le shows a detail of a temperature control device according to the invention including wall mounting in a horizontal section through a building wall.

In Fig. La 2 denotes a building wall or facade and 1 a temperature control device consisting of a single tube which is integrally formed with a heat transfer profile 51. The area of the heat transfer profile 51 which is furthest away from the tube area of the temperature control device 1 is in the vicinity of the associated framework part 3 which is to be temperature-controlled. This area can more or less abut or be attached to the associated scaffold part 3, so that the 5 heat is transmitted during operation by heat conduction and / or by radiation coupling. The heat transfer from the facade structure 2 to the temperature control device 1 can in this case by circulation of the Heizbzw. Cooling water from the sunny side to the shady side would be used technically. This causes indirect heat transfer from the warm to the cold side.

In Fig. Lb 2 denotes the building wall or facade and 5 the glass panes fastened therein. The former has a temperature control device I similar to FIG. La, which i5 likewise has a heat transfer profile 51 which is located at a close distance from the associated scaffolding part 3 or which can be abutted or fastened to this scaffolding part. According to this embodiment, essentially the same advantages are achieved as with a construction according to FIG.

According to FIG. 1c, the aluminum tube formed in one piece with the heat transfer profile 51 and containing the heat transport medium does not completely fill the corresponding inner box cross-section of the heat transfer profile 51, but instead has additional cutouts 52 on the side inside the box profile. With sufficient stability of the temperature control device and good heat transfer from the tube to the associated scaffolding part 3, these cutouts create the advantage of considerable material savings.

The embodiment of a heat transfer profile 51 shown in FIG. 1d has only an inner recess 54 between the pipe and the inner wall of the box-shaped closed heat transfer profile 51, so that the pipe is arranged in a corner of the heat transfer profile 51.

It is characteristic of the embodiments of a temperature control device 1 with a single pipeline formed integrally with the heat transfer profile 51 shown in FIGS. 1a to 1d that comparatively little heat transport fluid flows through the temperature control device during operation, i.e. The majority of the hollow-profiled temperature control device in the area of the heat transfer profile 51 remains unflowed, and nevertheless a good and effective heat transfer is guaranteed. Due to the small amount of circulating heat transfer fluid, there is advantageously a simple and quickly responsive regulation of the room temperature of a building, so that large and rapid temperature fluctuations 5 ° of the outside environment can be compensated for very effectively.

According to FIG. 1, the temperature control device 1 has two double tubes, which are arranged at a distance a from the vertical supports of the frame 3 to be temperature-controlled and are aligned with respect to the parts of the frame to be temperature-controlled in such a way that during operation there is a radiation coupling between the temperature control device 1 and the associated scaffolding parts 3 is formed.

The tempering device 1 is constructed in the form of a pipe 60 pipe system which is attached to the building facade 2 at 10 in the area of the flow 14 and return pipe 15 of the pipe system of the tempering device 1. In the exemplary embodiment illustrated in FIG. 1e, the building facade consists of vertical supports of a metal frame 3 consisting of supports and 65 horizontal bars, which fastens double glass panes 5, insulation profiles 6 being provided between the glass panes 5 and the vertical supports. The vertical support in the area of the fastening

Parts 10 of the temperature control device can be an integral part of the building facade 2, as shown in Fig. Le, and also attach facade elements or glass panels 5 via insulation 12.

The temperature control device 1 according to FIG. Le lies in a contact-free manner opposite the assigned frame parts at a distance a, preferably 50 mm, so that there is an optimal radiation coupling between the active parts.

The radiation coupling between the active parts in the temperature control device according to FIG. Le is further supported by the design of the line system in the form of double tubes 20 and 21 and a radiation / reflector part 23 which is formed in one piece with each double tube 20 and 21 and in Cross-section has a U-shape. The free legs of the U-shaped radiation / reflector part

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23 point in the installed state of the tempering device 1 in the direction of the framework parts 3 to be tempered.

The width of the radiation / reflector part 23 is preferably dimensioned such that it corresponds to the width of the associated frame part 3 to be tempered.

Instead of the cross-sectionally U-shaped configuration of the radiation / reflector part 23, the latter can also have a parabolic shape in cross-section, wherein according to an advantageous embodiment of the invention the single tube or tubes 20, io 21 is or lie in the region of the focal point of the parabola.

The inner surface of the radiation / reflector part 23 pointing to the scaffolding part 3 to be tempered can be coated in a suitable manner in order to achieve an even greater heat exchange between the scaffolding part 3 and the tempering device 1 during operation of the temperature control device.

C.

1 sheet of drawings

Claims (15)

643 933 PATENT CLAIMS 1.Device for tempering rooms of a building with facade walls, which comprise a metal frame (3) made of supports and bars, on which facade elements are attached essentially free of thermal bridges, with a temperature control device (1) arranged in the interior of the frame (3) ), which contains at least one pipeline (20, 21) assigned to the supports and / or bars, with a heat transport liquid flowing therein, and with heat transfer profiles (51, 23), which are connected to the pipeline in a heat-transferring manner, characterized by the following features: a) the tempering device (1) is arranged on the inside of the room in front of the frame (3); b) the heat transfer profiles (51, 23) essentially follow the contours of the frame (3). 2. Device according to claim 1, characterized in that the temperature control device (1) is arranged at a distance (a) on the metal frame (3), so that a direct radiation coupling between the frame (3) and the temperature control device (1) is formed. 3. Device according to claim 2, characterized in that the temperature control device is arranged at a distance of about 50 mm on the metal frame (3). 4. Device according to claim 1, characterized in that the temperature control device (1) consists of a single pipe which is formed in one piece with a heat transfer profile (51). 5. The device according to claim 4, characterized in that the pipeline has a round cross-section. 6. The device according to claim 1, characterized in that the pipeline and heat transfer profile (51) consist of aluminum. 7. The device according to claim 1, characterized in that the temperature control device (1) is attached to the associated part of the frame (3). 8. The device according to claim 1, characterized in that the pipes (20, 21) of the temperature control device (1) between the flow and return (14, 15) are at least partially constructed as a parallel or double pipe. 9. The device according to claim 1, characterized in that the pipes (20, 21) between the flow and return (14, 15) are formed in one piece with the radiation / reflector part (23) serving as a heat transfer profile. 10. The device according to claim 9, characterized in that the radiation / reflector part (23) has a cross-section IJ shape, the free ends of the U-legs are directed essentially towards the associated part of the frame (3) (Fig. le). 11. The device according to claim 9, characterized in that the radiation / reflector part (23) has a parabolic shape in cross section, the at least one pipe (20, 21) lying in the region of the radiation center or focal point and the free longitudinal edges of the radiation / reflector part (23) are essentially directed towards the assigned part of the frame (3). 12. The device according to claim 11, characterized in that the radiation / reflector part (23) is coated on the inside with a reflecting medium. 13. The device according to claim 11, characterized in that the width of the radiation / reflector part (23) corresponds to the width of the associated part of the frame (3). 14. The device according to claim 1, characterized in that the heat transfer profile (51) with the frame (3) is in direct contact. 15. The device according to claim 1, characterized in that the heat transfer profiles (51) are integrally connected to the associated pipes and consist of aluminum. 16. Device according to claim 15, characterized in that the pipelines in the associated, box-shaped closed heat transfer profiles (51) leave recesses (52, 54) laterally in the interior thereof. 17. The device according to claim 16, characterized ge-io that the recesses (52) are arranged on both sides of the pipes (Fig. Lc). 18. The device according to claim 16, characterized in that the pipes are arranged laterally in the associated heat transfer profiles and 15 leave a single recess (54) (Fig. Ld).