DE2953533C2 - Facade flap for building facades - Google Patents

Description

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The invention relates to a pivotable on a building facade, in particular on the edge of a window area hinged facade flap with a solar energy collector integrated into the flap, which has an absorber plate and a pipeline system in thermal contact with it for the heat transport medium with pipe connections at both ends that are rigidly connected to the flap Pipe sockets are formed and arranged coaxially to the pivot axis of the flap, each pivot bearing the flap from one of the pipe sockets rigidly connected to the flap, a connecting pipe coaxial therewith and sealing means is formed between these parts.

Through the CH-PS 6 09 142 a sun protection lamella that can be arranged horizontally on the axis is designed Façade flap known, provided in the case of the bearing journals drilled through on the cover plates, that is to say pipe sockets which engage in associated coaxial bearing bushes. These bearing bushes, which serve as connecting pipes are connected to an inlet or outlet line via a borehole. Sealing the The pipe socket in the bearing bushes is made using sealing rings that are embedded in annular grooves in the pipe socket.

When the sun protection slats are positioned vertically, the sealing rings are subjected to relatively little stress. At a Horizontal arrangement of the sun protection slats can f> 5 sealing problems occur. Any shifts in Axial direction and as a result of the uneven loading of the sealing rings, which occurs in the horizontal arrangement absorbing the entire weight of the lamella, damage to the same can occur, leading to Leaks. In particular, the sunshade dams can already be used when inserting the pipe socket the sealing rings in the bearing bushes will be damaged. Replacing a damaged or destroyed sealing ring requires the removal of the lamella.

The invention is based on the object of designing pipe connections designed as pivot bearings in such a way that that with a horizontal swivel axis the seal is more secure and permanent.

This object is achieved according to the invention in that the connecting pipe engages in the pipe socket which with a surrounding it, protruding over its end pipe section is firmly connected that between the protruding area of the pipe section and the connecting pipe, a sealing ring is arranged, and that a clamping sleeve over the free end region of the pipe section and engages around the connecting pipe.

Since the sealing device is provided in front of the end face of the pipe socket, they do not have to be together be introduced with the pipe socket serving as a bearing bush, because it is on the connecting pipe like this can be pushed back a long way so that they can also be pushed back from his when pushing the pipe stub onto the connecting pipe Pipe section is not touched. After assembling the flap, the sealing ring is attached to the face of the pipe socket and clamped with the help of the clamping sleeve. This is already during the Assembly eliminates the risk of damage. The sealing device is also then from the outside still accessible when the facade flap is installed. This makes it possible to use the sealing ring re-tensioning if, for example, it experiences a change in volume due to fatigue. Because the sealing ring is arranged in front of the end face of the pipe socket, it is not caused by bearing forces loaded, which are introduced directly into the connecting pipe via the pipe socket. This will get over long line ensures a secure seal.

In an embodiment of the invention, an annular ring can be placed between the sealing ring and the clamping sleeve An intermediate element is provided and the clamping sleeve can be screwed onto the outer end of the pipe section be.

Embodiments of the invention are explained with reference to the drawing. It shows

1 shows a vertical section of part of a building facade with facade flaps,

F i g. Figure 2 is a plan view of a number of facade flaps shown in their horizontal position are,

3 shows a schematic representation of the line system provided in the facade flaps,

F i g. 4 shows a partially sectioned pivot bearing of a facade flap,

F i g. 5 shows another embodiment of a pivot bearing of a facade flap and

6 is a schematic, partially shown in section Bearing between a facade flap and a vertical pull rod.

The building facade shown in Fig. 1 in vertical section, of which only the top two floors are shown, contains vertical, spaced-apart profile supports 10, horizontal, im Spaced bolt 12 which

are also designed as profile parts, a framed by the profile supports 10 and bolts 12 glazing 14 and wall panels 16, which form the non-glazed part of the facade. The profile supports 10 and transoms 12 preferably form an integrated facade system in DE-AS 2132 921 or Dt-AS 26 21 186 described type. So is in F i g. 1 indicated schematically by an arrow 18 that the under the glazing 14 located bar 12 is provided with an Austritisöffnu ^ g, from the conditioned air for temperature control the room exits. Similarly, the profile supports 10 are hollow, and in them a heat transport medium flows to control the temperature of the room.

The profile supports 10 carry an outwardly at the upper edge of the glazing 14 at the level of the bolt 12 protruding bearing plate 20, on which one side of a facade flap 22 is pivotably articulated. On theirs The free end is the facade flap 22 via a bracket 24 attached to it on a vertical pull rod 26 hinged. The articulation of the facade flap 22 on the building facade is described in detail with reference on the F i g. 4 to 6 explained.

The pull rod 26 is attached to a cable 30 at the point indicated by 28, which is via a cable guide roller 32 out and can be rolled up onto and from a pulley 34. By rolling up the rope 30 on the Pulley 34, which can be driven by an electric motor, the pull rod 26 is raised so that the facade flaps 22 are moved in the direction of their horizontal end position. To lower the Façade flaps 22 can be used by pulling the pulley 34 while maintaining the force of gravity required braking force is released so that the pull rod 26 is lowered and with her the Swivel the facade flaps 22 up to the system on the building facade.

As can be seen from Fig. 2, are in a preferred Embodiment several facade flaps 22a, 226, 22c ... arranged next to one another. Three at a time Façade flaps 22a, 226, 22c form a group, the dashed lines of which are indicated as coiled pipes Line systems 36a, 36b, 36c are connected in series. The flow line of the facade flap group 22a, 226, 22c, like the return line, is arranged in a profile cavity 38 of a profile support 10. the Flow and return lines are included in the primary circuit of a heat pump system, not shown and feed it. The façade flaps through the pipe system and the flowing through it Energy removed from the transport medium can also, if it has a suitable temperature, can be used directly for heating purposes.

FIG. 3 shows a schematic plan view of the structure of the facade flaps 22. That of each facade flap 22 Associated line system 36 is formed by a coil 40, the main direction of which is parallel to The longitudinal direction of the facade flaps 22 runs. The pipe coil 40 is guided on the facade flap in such a way that that their connecting ends 40a, 406 are aligned with one another. These connection ends 40a, 406 are at the points of Arranged side edges of the facade flap 22, on which this is pivotably articulated, namely coaxially with the pivot axis. The pivot bearing shown schematically at the connection end 40a has a coaxial one Passage for the Leiti'ngssystem 36 so that a direct series connection with the adjacent facade flap is made possible. The one at the end of the connection 406 shown, pivot bearing has a through connection both to the adjacent facade flap and to a connecting line: device 42, which is from

a cavity 38 of the profile support 10 is received. The connection line 42 can, depending on the location Be a flow line or a return line.

4 shows in detail a preferred embodiment the pivoting mounting of the facade

fold 22 on the bearing plate 20, which is rigidly connected to the facade structure. These pivotable mounting serves at the same time to connect the line system 36 of the facade flap 22 to a Connection pipe 42 in the profile support 10 (Fig. 3). The Schwcnklager contains one on each side with the Flap 22 rigidly connected pipe socket 84, which forms the end of the pipe coil 40, one in the pipe socket 84 insertable and rotatable connection pipe 86 therein, a cylindrical sealing ring 88, which the Pipe socket 84 extended, a pushed over the pipe socket 84 and with this z. B. by welding firmly connected pipe section 90, which protrudes beyond the pipe socket 84 also to the outside and the Sealing ring 88 and an annular intermediate element 88a encloses, as well as a sleeve 92, which on the The outer end of the pipe section 90 is screwed on and the sealing ring 88 clamps. That way will a pivot bearing is formed in which the pipe socket 84 is rotatable around the connecting pipe 86, this Rotary connection is sealed against the outlet of the heat transport medium.

The connecting pipe 86 merges at its outer end in a flange 94, which on the bearing plate 20 by means Bolt% is screwed with nut 98. The liquid seal takes place via an intermediate Sealing washer 100.

In Figure 4 it is indicated schematically that the Connection pipe 86 opens into a cavity within the bearing plate 20, which in turn has a

Connecting channel 102 is connected to a connecting pipe 42 (FIG. 3) serving as a flow line. Arrows 104 indicate the direction of flow of the heat transport medium.
In the embodiment of the pivot bearing shown in FIG. 5, it is used only to connect the line systems of two adjacent facade panels 22. In this way, the line systems of the adjacent facade flaps 22 can easily be connected in series. The bearing plate 20 has a

Through channel 106 which connects the passages formed by each connecting tube 86 with one another. The direction of flow is indicated by arrows 108, 110.

Fig. 6 shows the articulation of two adjacent facade flaps 22 on a pull rod 26, which in the The embodiment shown is an aluminum hollow profile with a rectangular cross-section. On both of them wider sides of the tie rod 26 are flanges 112, 114 screwed on by means of bolts 116 with nuts 118, which continue in hollow nozzles 120, 122. The hollow nozzles 120, 122 each have an axial bore 124, in which both the free end of a cylindrical pin 126 is rotatably mounted. This pin 126 is identical to the one already shown in FIG. 1 bracket 24 shown rigidly connected. This bracket 24 establishes the connection with the facade flap 22.

In addition 6 sheets of drawings

Claims (3)

Patent claims: 1. Pivotable articulated on a building facade, in particular on the edge of a window area Façade flap with a solar energy collector integrated into the flap, which is an absorber plate and a pipeline system in thermal contact with it for the heat transport medium having pipe connections at both ends, which are designed as pipe sockets rigidly connected to the flap and are coaxial with the Pivot axis of the flap are arranged, each pivot bearing of the flap of one of the with the flap rigidly connected pipe socket, a coaxial connection pipe and a sealing device is formed between these parts, characterized in that the connecting pipe (86) engages in the pipe socket (84), which with a surrounding it, over its end protruding pipe section (90) is firmly connected that between the protruding area of the Pipe section (90) and the connecting pipe (86) a sealing ring (88) is arranged, and that one Clamping sleeve (92) over the free end area of the pipe section (90) and the connecting pipe (86) encompasses. 2. Facade flap according to claim 1, characterized in that between the sealing ring (88) and the clamping sleeve (92) an annular intermediate element (8SaJ is provided. 3. Facade flap according to claim I or 2, characterized in that the clamping sleeve (92) the outer end of the pipe section (90) can be screwed on. 10