DE29918219U1 - Facade for a low-energy house - Google Patents

Description

PFISTER & PFISTER PATENT ATTORNEYS Dipl.-Ing. Helmut Pfister

European Patent Attorney

Dipl.-Phys. Stefan Pfister

D-87700 Memmingen/Bavaria Office: Herrenstraße 11

Telephone 0 83 31 / 2412 Fax 08331/2407 Office 2: Buxacher Straße 9

Telephone 0 83 31 / 6 51 83 Fax 0 8331/65185 Postgiroamt Munich
1343 39-805 (bank code 700 100 80) Bayer. Vereinsbank Memmingen 2 303 396 (bank code 731 200 75) VAT ID No. ■ VAT Reg. No. ■ N° CEE DE 129 066 032

15 OCT. 1999

Company Raico Bautechnik GmbH
Dorfstrasse la, 87746 Erkheim-Schlegelsberg

"Facade for a low-energy house"

The invention relates to a facade consisting of a support structure with several supports which accommodate facade parts such as panels, glass panes, etc. between them, wherein a pressure strip is provided which presses the facade part against the support, as well as thermal insulation in the area of the pressure strip.

DE-OS 44 09 872 describes a facade construction whose covering elements, for example in the edge area of insulating glass panes, are covered to provide thermal insulation on the outside.

However, there is no detailed description of how this thermal insulation is designed.

With known facades of this type, a K value of approx. 1.5 - 2.5 w/mK is currently achieved. The K value is the heat transfer coefficient and indicates the amount of heat that is transferred through 1 m of a certain component within one second at a temperature difference of one Kelvin.
the K-value, the better the thermal insulation.

1 m of a specific component. The lower the

It is now the object of the invention to create a facade whose heat transfer coefficient is as low as possible in order to realize a low-energy house with such a facade.

This task is solved by the fact that the thermal insulation consists of at least two insulating bodies.

The pressure strip is used to press facade parts such as glass or a pane of glass or other panels against the support of the support structure. In particular, the support structure in such houses consists of a post and beam construction, which has the advantage that the facade parts can be kept relatively short, thus allowing a more flexible design of the facade.

The first thermal or cold bridge is, for example, the fastening means used to attach the pressure strip to the support. In the post-and-beam construction, for example, this fastening means is arranged at a distance of approximately 30 cm from the next one and, due to its small cross-section, only contributes minimally to heat conduction.

However, it is important to provide thermal insulation underneath the pressure bar, which may be made of aluminum or another material.

-» VVVV VVVVVVVWWW

— J — φ·· vvv ν ·

VVVVV VVVVV VV VV

According to the invention, it is proposed that the thermal insulation be designed from at least two insulating bodies. The combination of the two insulating bodies, which can also be made of identical materials, has the advantage that they can be adapted to different requirements. With a small set of insulating bodies, it is therefore possible to create a large number of different thermal insulations. The various insulating bodies can be adapted in each case, in particular due to the different dimensions of the gap between the adjacent panels, or also with regard to the different design of the pressure strip or a cover strip located on it. It is also possible to optimize the insulating bodies with regard to their physical properties (hardness or thermal insulation). With regard to the invention, it is equally important whether the two insulating bodies are connected to one another or arranged individually in the facade. The insulating bodies are glued to one another, for example. Alternatively, it is also intended to connect the two insulating bodies to their associated structural elements of the facade, for example by gluing them or inserting them loosely.

According to the invention, insulating bodies made of materials of varying hardness are used. The first insulating body, towards the outside of the facade parts, is relatively hard, as this is ultimately responsible for transferring the holding force of the fastening to the glass, the facade part or the panels. A material is selected for this insulating body whose mechanical properties are sufficient to transfer this holding force and at the same time has a sufficiently low heat transfer coefficient (approx. 0.06 W/mK) to ensure optimal thermal insulation. Materials are preferably used whose compressive stress (according to DIN 53421) is relatively high (for example
extremely low heat conduction.

is relatively high (for example greater than 5 N/mm ), with possible

Alternatively, the insulation body can be designed in such a way that it is not possible to transfer the holding forces, for example because the insulation body is relatively soft. In this case, other or additional means are provided on the pressure strip to safely transfer the holding forces to the facade part for holding the facade part.

A second insulating body is provided between the front sides of the adjacent facade parts, which fills the gap as much as possible. The material of this second insulating body is chosen so that it can accommodate any manufacturing tolerances or length differences in the glass panes or other panels caused by thermal expansion. However, this is only possible to a limited extent, because the material of the second insulating body must still be sufficiently hard to achieve blocking between the panels or glass panes. The second insulating body is preferably optimized for optimal thermal insulation, which, due to the higher intake of air or gas, usually leads to materials that are less mechanically resilient and can be used. In this case, for example, the blocking or other mechanical tasks are not carried out by the second insulating body, but by other means.

The combination of both insulating bodies made of different materials, or similar materials with different physical properties (e.g. density, thermal conductivity, compressive stress), offers a high level of thermal insulation of the facade while at the same time providing high mechanical stability in this area. These insulating bodies are advantageously made of different hard materials.

Since the insulation body does not have to transfer any forces in the area between the front sides of the facades, a

softer material is provided, the heat transfer coefficient of which is lower than that of the material of the first insulating body. In order to be able to use the insulating bodies more easily when building the facade, one embodiment of the invention provides for both insulating bodies to be connected to one another. This can be done by gluing, for example, whereby the outer contour of both insulating bodies then has a T-shape, for example.

Furthermore, the task is solved by a facade as described at the beginning, whereby the thermal insulation consists of an insulating body that extends between the pressure strip and the support structure and between the front sides of the adjacent facade parts. This essentially one-piece body is located in the gap between two adjacent panels. It has been found that when optimizing the thermal insulation in such facades, the thermal insulation is at its worst, particularly in the area below the pressure strips, which regularly attack the edge of the panels or window elements. In order to improve the thermal insulation and in particular to achieve low K values, it is also part of the invention to fill this gap with a corresponding insulating body. To attach this insulating body, it is also possible to glue it to the elements of the facade, for example by gluing it to the support structure. However, it is also possible to press the insulating bodies into the gap using the pressure strip.

It is also possible to design the insulation body in a T-shape, for example, whereby the web of the "T", similar to the first insulation body in the two-part solution, is pressed against the panel by the pressure strip and thus held. It is advisable to choose a hardness of the insulation body that is sufficient to safely transmit the holding forces. Alternatively, it is possible to

It is also possible to use softer materials, which usually achieve better thermal insulation, whereby the mechanical task or other elements on the pressure bar, for example the seal, are then taken over.

In a further advantageous embodiment of the invention, in addition to the (second) insulation body, which is located between adjacent facade parts, an insulation strip is arranged between the insulation body and the front side of the facade part. It flanks the second insulation body on both sides and rests at least partially on the front sides of the facade parts. The use of the insulation strip also prevents the air circulation, which is still possible in the side areas. The air circulation also represents a part of the internal exchange, which is prevented by the design. The use of the insulation strip is possible with one- or multi-part thermal insulation according to the invention, i.e. the insulation strip is integrally formed onto the insulation body, or as a separate component with the second insulation body or the part of the insulation body that is arranged between the two facade elements, for example glued or loosely attached. The one-piece design in particular offers advantages in production, since corresponding insulation bodies can be adjusted in a single cutting or milling process.

This insulation strip is made of a relatively soft material and has a good insulating effect. It has elongated recesses that prevent air from circulating from the cold outside to the warm inside and vice versa. At the same time, this material also serves as a flexible buffer to accommodate tolerances in the facade parts. This material lies against the glass.

The thermal conductivity of the material of the insulation body or the insulation strip is between approximately 0.020 and 0.080,

•a* ··« «t*a

but preferably between 0.035 and 0.06 W/mK. By using materials in this range, a facade is obtained that achieves a very favorable K value overall and enables the realization of a low-energy house. Plastics of varying hardness are advantageously provided as materials for this insulating body or insulating strip. In one example, this material is polyurethane foam. However, all other materials whose heat transfer coefficients are better than 0.08 W/mK are also suitable.

The use of rigid polyurethane foam, known on the market as Puren or Purenit, for example, offers advantages in terms of processing. The material can be processed in a similar way to wood and offers adjustable holding forces with adjustable thermal insulation values. In addition to the use of polyurethane, it is also planned to use polyethylene foam, polystyrene or other synthetic or foam materials as the material for the insulating body (single or multi-part).

When using an insulating body that is designed in several parts according to the invention, the complete insulating body may consist of several parts that are homogeneous in themselves, but overall optimized with regard to the tasks and are therefore heterogeneous as a whole. For fastening (web of the T), harder materials are preferably used that have a correspondingly higher compressive stress (greater than 5 N/mm ). For the part of the insulating body that is arranged in the gap between the two facade parts, a material with lower thermal conductivity and therefore also lower hardness or compressive stress is preferred. These different properties are of course also possible with a one-piece insulating body that is co-extruded from heterogeneous material, such that the web is made of harder and the stem of softer, heat-insulating material.

In all cases, it is also possible to form the insulation strip in one piece during the manufacturing process.

A seal is provided between the pressure strip and the facade or between the facade and the support. This seal prevents moisture from penetrating the gaps between the facade parts due to weather conditions.

In a preferred embodiment, the first insulating body has dovetail-like grooves in which this seal engages. It is flat towards the facade parts. The seal is made of ethylene-propylene rubber (EPDM rubber), for example, which is relatively weather and ozone resistant. Another rubber seal is provided on the opposite side of the facade part and seals the gap between the facade and the support.

Silicone is also suitable as a seal, as it has an even higher heat and cold resistance than EPDM rubber, but its tear resistance is somewhat lower.

As already mentioned at the beginning, the pressure bar is pressed against the support by means of a fastening device. This is done, for example, by the fastening device interacting directly with the support; this is particularly advantageous if the support itself is made of wood and therefore no separate elements are provided that are intended to interact with the fastening device.

In a further advantageous embodiment, an element is provided on the carrier, in particular when the carrier is made of metal or another hard material with which the fastening means interacts. In the event that the fastening means is a screw, the element provided is, for example, a screw channel which is fastened to the carrier.

This screw channel extends at least partially into the space between the front sides of the facade parts.

In order to fill the gap as well as possible with insulation material, the second insulation body or the part of the insulation body that is arranged between the facade parts is placed like a hat over the element or the screw channel.

A screw is provided as a fastening means, which works together with the screw channel or, for example, with the wooden support. However, it is also conceivable to create a bayonet-like connection between the pressure strip and the support or to use rivets, a snap connection or other fastening options familiar to the expert.

As already described, a post-and-beam construction is preferably used as the supporting structure for the facade, as this offers the facades a high level of stability. However, it would also be conceivable to provide only one frame to which the facade parts are attached, which means that the invention can also be used at the edges of the facade. In addition to using a post-and-beam construction as the facade construction, the arrangement of parallel supports without cross connections etc. is also possible.

In a further variant of the invention, a cover strip can be placed on the pressure strip, which covers the pressure strip on the outside. The cover strip is designed, for example, in such a way that it covers the part of the insulation body that protrudes above the facade level. The cover strip is essentially U-shaped, with the material thickness being approximately 1.5 mm in order to provide the poorest possible heat conduction. This cover strip also has the advantage that it can be coated or painted as desired to achieve the corresponding effects. The cover strip is also made of metal, for example aluminum.

- 10 -

• · ♦ ··

The advantage of using aluminum as a material for the pressure bar is that it has a high heat reflection, which in turn impairs heat conduction.

The facade according to the invention achieves a K value that is approximately 20 percent below the required K value of 0.8 w/mK. The design according to the invention thus creates a facade, in particular the shape of a winter garden or the like, that is suitable for integration into a low-energy house concept and enables considerable savings in resources and fuel when implementing such types of construction.

The invention is described in more detail with reference to the drawing.

Fig. 1 to 3 each show a section of an inventive

facade in accordance with the requirements.

The facade 1 shown in Figure 1 consists of an element 2 which is placed on the support 12, or a bar of a post-and-beam construction, in particular of low-energy houses, and a pressure strip 3, which are held together by means of a screw 4 as a fastening means and between them receive and hold edges of facade parts 5, such as panels, glass panes, etc.

The screw can also be screwed directly into the latch, which is made of wood, for example, thus eliminating the need for element 2.

At this point on the facade, thermal or cold bridges occur, which should be prevented if possible.

- 11 -

The thermal bridge at the screw can be neglected, since the distance between the screws is usually about 30 cm or more and the cross-section of the screw is so small that the heat transfer coefficient is relatively low in relation to the length.

A larger thermal bridge would be created if the pressure strip 3 were to press directly onto the facade parts. Therefore, an insulating body 6 is provided between the pressure strip and the facade part 5, the material of which is relatively hard, however, since it has to transfer the force of the pressure strip to the facade parts 5. A hard material has the disadvantage that the heat transfer coefficient is relatively poor, but when using certain plastics such as polyurethane, a heat transfer coefficient of approximately 0.06 W/mK is also possible here.

In the area between the front sides of the facade parts 5, a further insulating body 7 is provided, which largely fills the space between the front sides of the facade parts 5. It is put over the screw channel 13 of the element 2 in a hat-like manner in order to fill as much of the free space as possible.

In order to facilitate the installation of the insulation bodies when producing the facade, it is possible to connect both insulation bodies to one another, in particular by gluing. In a further embodiment according to the invention, however, it is also possible to use a one-piece insulation body that fills the space between the facade parts and covers part of the outer edges of the facade parts. A one-piece insulation body can be produced, for example, from homogeneous insulation material or from a material with different physical properties (insulation, mechanical stability).

Due to manufacturing tolerances of the facade parts or

- 12 -

Due to differences in the length of the facade parts caused by thermal expansion, there is a gap between the insulating body 7 and the front sides of the facade parts, which allows air to circulate from the cold outside to the warm inside and vice versa. However, this again forms a heat or cold bridge, which should be prevented as far as possible. For this purpose, an insulating strip 8 is provided, which at least partially rests on the front sides of the facade parts. It is made of very soft material, for example, with a heat transfer coefficient of only around 0.035, and at the same time compensates for the distance between the facade part and the insulating body 7, for example due to manufacturing tolerances.

Elongated recesses 9 increase the flexibility of this insulation strip. Between the first insulation body 6 and the facade part 5 and between the support 12 or element 2, which carries the screw channel 13, and the facade part 5, a sealing material is also provided which prevents rainwater from penetrating into the gaps.

In an advantageous embodiment, this sealing material can be ethylene propylene rubber (EPDM rubber) with good weather and ozone resistance and high elasticity or silicone, which in addition to good weather and ozone resistance is insensitive to temperature fluctuations.

A cover strip 11 is applied to the pressure strip 3, which covers the facade on the outside. In a further variant of the invention, the entire outside of the facade is covered by these cover strips, whereby the entire insulation is concealed.

The cover strip 11, for example, has a thickness of about 1.5 millimeters in order to provide the poorest possible heat conduction. At the same time, this cover strip II has the advantage that

- 13 -

that it can be coated or painted as desired to achieve certain effects.

Fig. 2 shows a further variant of the facade according to the invention. In this example, the insulating body 6 is used as a one-piece insulating body 15, which is essentially T-shaped. Fastening grooves 16 are provided on the sides of the pressure strip 3, into which the seal 10, 14 is inserted and held. The holding force that is to be transferred to the facade parts 5 by the fastening means 4, a screw, via the pressure strip 3 is guided via the seals 10, 14. The seals 10, 14 are sufficiently stiff to reliably transfer these forces. Alternatively, it is also possible for the one-piece insulating body 15 to also rest on the outside of the facade part 5 in the web area 17 and, if sufficiently hard, also to transfer holding forces. Depending on which functionality is desired, the hardness or thermal conductivity or thermal insulation of the insulating body 15 must be selected. As described, it is possible to create this one-piece insulation body from homogeneous or heterogeneous material. The arrangement shown can also be used for multi-piece insulation bodies.

In particular, a sealing strip 8 is integrally formed on the stem 18 of the T-shaped insulating body 15. The stem 18 of the T-shaped, one-piece insulating body 15 at least partially fills the space between the two adjacent facade parts 5, with the hat-like design additionally insulating and insulating the metal screw channel 13 in particular. It is of course possible to arrange this hat-like design not only in the upper area of the screw channel, but also to design it to extend as far inwards as possible on both sides.

- 14 -

·

·

•♦· ··

Similar to Fig. 1, in the design according to Fig. 3 the seal 10 (on the outside of the facade part 5) is held in a groove 19 in the insulation body. In contrast to the design in Fig. 1, however, the insulation body 6, 15 here essentially consists of a one-piece element. The groove 19 is located in the web area 17, arranged essentially symmetrically with respect to the screw channel 2. Since in the design according to Fig. 3 the holding force is transferred to the facade part 5 by the insulation body 6, 15 itself or flanked by the seals 10, a relatively hard material is preferably used here, which has a relatively high compressive stress. In contrast, in Fig. 2, the modified arrangement of the seal made it possible to optimize the insulating body 15 here with regard to its thermal insulation, whereby, for example, polyethylene foam (type LD 15) is preferably used here, which is characterized by a density of 15 kg/m and a thermal conductivity of less than 0.037 w/mK.

In particular, by introducing the insulating body into the gap between the two facade parts 5 and combining this post 18 standing in the gap with the insulating strips 8 formed on it, an optimal insulating effect or thermal insulation was achieved. The proposal according to the invention consistently insulates or suppresses all physical transport mechanisms for heat, which ultimately makes it possible to create a facade that can be equipped in particular with insulating glass panes 5 that achieve the required low thermal conductivity coefficient of less than 0.8.

The claims filed now with the application and subsequently are attempts to formulate without prejudice to achieve more extensive protection.

- 15 -

The references cited in the dependent claims indicate the further development of the subject matter of the main claim through the features of the respective subclaim. However, these are not to be understood as a waiver of the achievement of independent, objective protection for the features of the referenced subclaims.

Features that have so far only been disclosed in the description can be claimed in the course of the procedure as being of essential importance to the invention, for example to distinguish it from the prior art.

Claims (28)

1. Facade, consisting of a support structure with several supports, which accommodate façade parts, such as panels, glass panes, etc., between them, wherein a pressure strip is provided which presses the façade part against the support, and thermal insulation in the area of the pressure strip, characterized in that the thermal insulation consists of at least two insulating bodies ( 6 , 7 ). 2. Facade according to claim 1, characterized in that a first insulating body ( 6 ) is arranged between the pressure strip ( 3 ) and the facade part ( 5 ) and transfers the holding force of the pressure strip ( 3 ) to the facade part ( 5 ). 3. Facade according to one or both of the preceding claims, characterized in that a second insulating body ( 7 ) is arranged between the end faces of the adjacent facade parts ( 5 ) and largely fills the intermediate space. 4. Facade according to one or more of the preceding claims, characterized in that the insulating bodies ( 6 , 7 ) consist of different materials. 5. Facade according to one or more of the preceding claims, characterized in that the materials of the insulating bodies ( 6 , 7 ) have different hardnesses. 6. Facade, consisting of a support structure with several supports, which accommodate façade parts, such as panels, glass panes, etc., between them, wherein a pressure strip is provided which presses the façade part against the support, and thermal insulation in the area of the pressure strip, characterized in that the thermal insulation consists of an insulating body which extends between the pressure strip and the support structure and between the end faces of the adjacently arranged façade parts. 7. Facade according to claim 6, characterized in that the one-piece insulating body is T-shaped and is pressed against the facade part by the pressure strip. 8. Facade according to one or more of the preceding claims, characterized in that the part of the insulating body which rests against the facade part has sufficient hardness to transmit the holding forces. 9. Facade according to one or more of the preceding claims, characterized in that an insulating strip ( 8 ) is arranged laterally next to the (second) insulating body ( 7 ), which is located between adjacent facade parts, between the insulating body ( 7 ) and the front side of the facade part ( 5 ). 10. Facade according to one or more of the preceding claims, characterized in that the insulating strip ( 8 ) in the area between the facade parts ( 5 ) rests at least in sections on the front sides of the facade parts ( 5 ). 11. Facade according to one or more of the preceding claims, characterized in that the insulating strip ( 8 ) adjacent to the end faces of the facade parts ( 5 ) has elongated recesses ( 9 ). 12. Facade according to one or more of the preceding claims, characterized in that the thermal conductivity of the material of the insulating body ( 6 , 7 ) or the insulating strip ( 8 ) is between approximately 0.020 and 0.080 W/mK. 13. Facade according to one or more of the preceding claims, characterized in that the compressive stress of the material of the insulating body ( 6 , 7 ) is between approximately 0.25 and 10 N/mm ² . 14. Facade according to one or more of the preceding claims, characterized in that the (one-piece) insulating body consists of homogeneous or heterogeneous material, in particular with regard to its density, conductivity or compressive stress. 15. Facade according to one or more of the preceding claims, characterized in that the material for the insulating body ( 6 , 7 , 15 ) or the insulating strip ( 8 ) is plastic, polyurethane foam, polyethylene foam, polystyrene. 16. Facade according to one or more of the preceding claims, characterized in that a seal ( 10 ) is provided between the pressure strip ( 3 ) and the facade or between the facade and the support ( 12 ). 17. Facade according to one or more of the preceding claims, characterized in that the insulating body ( 6 ) carries a fastening means, in particular a fastening groove for the seal ( 10 ). 18. Facade according to one or more of the preceding claims, characterized in that the pressure strip ( 3 ) carries the seal ( 10 ). 19. Facade according to one or more of the preceding claims, characterized in that the sealing body ( 6 ) extends between the seal ( 10 ) on the pressure bar ( 3 ) and under the pressure bar ( 3 ). 20. Facade according to one or more of the preceding claims, characterized in that the insulating body ( 6 ) is fastened to the pressure strip, in particular glued thereto. 21. Facade according to one or more of the preceding claims, characterized in that the seal ( 10 ) consists of ethylene-propylene rubber (EPDM rubber) or silicone. 22. Facade according to one or more of the preceding claims, characterized in that the pressure strip ( 3 ) is pressed against the support ( 12 ) by means of a fastening means ( 4 ). 23. Facade according to one or more of the preceding claims, characterized in that an element ( 2 ) is provided on the support ( 12 ) which cooperates with the fastening means ( 4 ). 24. Facade according to one or more of the preceding claims, characterized in that the fastening means ( 4 ) is a screw. 25. Facade according to one or more of the preceding claims, characterized in that a screw channel ( 13 ) is provided as the element ( 2 ). 26. Facade according to one or more of the preceding claims, characterized in that the second insulating body ( 7 ) or the part of the insulating body which is arranged between the facade parts is placed like a hat over the element ( 2 ) or the screw channel ( 13 ). 27. Facade according to one or more of the preceding claims, characterized in that a post-and-beam construction is provided as the supporting structure for the facade. 28. Facade according to one or more of the preceding claims, characterized in that a cover strip ( 11 ) can be placed on the pressure strip ( 3 ).