WO2023213947A1 - Composite profile arrangement for doors, windows or facade elements, and door, window or facade element - Google Patents

Abstract

The invention relates to a composite profile arrangement (1) for a door, window or facade element with: a surrounding frame composite profile (2) having a first metal shell (21) and a second metal shell (22) and a surrounding frame insulation zone (23) formed therebetween; a casement frame composite profile (3) which can be moved relative to the surrounding frame (2) into an open position and into a closed position, which casement frame composite profile has a first metal shell (31) and a second metal shell (32) and a casement frame insulation zone (33) formed therebetween and has a glass rebate (G) in which a flat element, preferably an insulation pane (4) can be received; a rebate space (F) between the surrounding frame composite profile (2) and the casement frame composite profile (3); and an overall insulation zone which comprises a series of advantageous insulation sections.

Description

Composite profile arrangement for doors, windows or facade elements as well as door, window or facade elements

The present invention relates to a composite profile arrangement for frames of doors, windows or facade elements and a door, a window or a facade element with a frame made of such composite profile arrangements.

As the requirements for the thermal insulating properties of doors, windows and facade elements continue to increase, there is a need to further optimize their components, i.e. in particular their frames, in this direction.

It is therefore desirable to design the frame profile arrangements of these frames in such a way that they have the lowest possible heat transfer coefficient Uw. If the frames are made from composite profiles with an inner and an outer metal shell and an insulating zone in between, special attention is paid to optimizing this insulating web zone.

Against this background, the invention has the task of further developing the composite profile arrangement of the generic type in such a way that it has a low heat transfer coefficient.

The invention solves this problem through the subject matter of claim 1.

According to claim 1, the following item is created:

A composite profile assembly for a door, a window or a facade element with: a frame composite profile having a first metal shell and a second metal shell and a frame insulation zone formed therebetween; a sash frame composite profile that is movable relative to the frame composite profile into an open position and a closed position, which has a first metal shell and a second metal shell as well as a sash frame insulation zone formed therebetween and a glass rebate in which a surface element, preferably an insulating pane, can be received; a rebate space between the frame composite profile and the sash composite profile. It is provided that the frame insulating zone has at least one insulating web and a combination of a center seal insulation block and a stop means seal that can be moved in sections, with the center seal insulation block and the stop means seal each being arranged on the insulating web of the frame facing the rebate space, wherein in the closed state of the sash composite profile at least in sections there is a gap between the Center seal insulation block and the sectionally movable sling means seal is formed, the sling means seal being moved in the closed state by an element of the sash frame composite profile into the position in which in the closed state of the sash frame composite profile the gap between the center seal insulation block and the sectionally movable sling means seal is formed.

It is therefore provided that a combination of a center seal insulation block and the sling means seal, which is movable in sections, is arranged in the rebate space, with the center seal insulation block and the sling means seal each being arranged entirely or substantially entirely on the insulating web of the frame facing the rebate space.

According to claim 1, a composite profile arrangement is created which has a very low heat transfer coefficient overall and also in its sections.

According to an advantageous optional and very well thermally insulated embodiment, it is provided that in the closed state of the sash composite profile, the sectional, in particular wedge-shaped, gap S1 is formed between the center seal insulation block and the sectionally movable sling means seal.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the sling seal in the closed state is moved by an element of the sash composite profile, in particular by the multi-head insulator, into the position in which, in the closed state of the sash composite profile, the gap between the center seal insulation block and the Sectionally movable sling seal is formed.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the sling seal rests against the center seal insulation block in the open state.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the sling seal comprises areas made of TPE and/or EPDM. According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the center seal insulation block is made entirely or in sections from a foam element, in particular PE foam, and has an X value <0.036 W/(mK).

According to another development, an advantageous overall insulating zone is realized, which comprises at least the following insulating sections: as the first insulating section in the frame insulation zone, at least two insulating webs of the frame composite profile, which are arranged at a distance from one another, and the first metal shell and the second metal shell are connected to one another, the insulating webs of the frame composite profile are made of plastic and have an and completely or substantially fill the space between the two insulating bars and the metal shells; where the X value of the respective foam element made of foamed plastic is X < 0.030 W/(mK); as a third insulating section in the frame insulating zone and in the glass rebate at least one stop seal, which is formed on one of the two insulating webs of the frame composite profile and protrudes into the glass rebate and which rests at least in the closed state on an element of the sash frame insulating zone, this being at least one Sling seal, made of foamed plastic, in particular PE and/or TPE and/or EPDM; as a fourth insulating section in the sash frame insulating zone, at least one or more sash frame insulating webs - preferably or optionally as part of a multi-head insulator with a multi-head web with at least one or more hollow chambers -, these sash frame insulating webs or possibly the multi-head web being made of plastic and having an X value between < 0.3 W/(mK), as the fifth insulating section in the sash frame insulating zone, in particular on one of the sash frame insulating webs, in particular in the one or more of the hollow chambers of the multi-head web, in each case a foam element or a foam filling made of plastic, one or more Xs -Value <0.034 W/(mK), in particular X value <0.028 W/(mK); and as a sixth insulating section in the sash frame insulating zone, a glass rebate insulation element made of foamed plastic, which projects into the glass rebate and is arranged on the multi-head insulator and has an X value <0.03 W/(mK).

According to an advantageous optional and very well thermally insulated embodiment, it is provided that the insulating webs of the composite frame profile and/or possibly the composite sash frame profile, in particular the multi-head insulator of the Sash frame composite profile, are made of a non-foamed ABS and have an X value between 0.3 W/(mK) and 0.1 W/(mK), preferably between 0.22 W/(mK) and 0.14 W/( mK).

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the insulating webs of the composite frame profile and/or possibly the composite sash profile, in particular the multi-head insulator of the composite sash profile, are made of the unfoamed ABS and have an X value less than 0.16 W/ (m K) in particular from an ABS with 0.15 W/(mK) or less.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the insulating webs of the composite frame profile and/or possibly the composite sash profile, in particular the multi-head insulator of the composite sash profile, consist of a foamed plastic, in particular polyamide (PA), and have an X value between 0.3 W/(mK) to 0.1 W/(mK), preferably between 0.29 W/(mK) and 0.10 W/(mK).

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the insulating webs of the composite frame profile and/or possibly the composite sash profile, in particular the multi-head insulator of the composite sash profile, consist of a foamed plastic, in particular polyamide (PA), and have an X value less than 0.22 W/(mK) and in particular made of a polyamide with 0.21 W/(mK) or less.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that at least one phenolic resin foam element with an X-value <0.023 W/(mK), particularly preferably X-value 0.022 W/(mK) or = 0.021 W/mK is introduced.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the foam filling of the multi-head insulator is formed from one or more inserts made of foamed plastic or from one or more foams made of plastic.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the glass rebate insulation element is made entirely or essentially from a foamed PE. According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the insulating web of the multi-head web of the multi-head insulator, which is oriented towards the glass rebate, is longer than the insulating web of the multi-head web of the multi-head insulator, which is oriented towards the rebate space.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the transverse webs of the multi-head web are thinner than the insulating webs of the multi-head web of the multi-head insulator.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the longer insulating web of the multi-head web, which is oriented towards the glass rebate, has the glass rebate insulation element which projects into the glass rebate.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the two insulating webs of the multi-head web of the multi-head insulator run parallel or essentially parallel to one another.

According to a further advantageous, optional and very well thermally insulated embodiment, it is provided that the multi-head web has at least two head areas at both ends, with which the multi-head web is attached to the first and second metal shell of the sash composite profile.

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that the head areas with which the multi-head web is fixed to the first metal shell are at a smaller distance from one another than the head areas with which the multi-head web is attached to the second metal shell of the sash frame composite profile .

According to a further advantageous, optional and very well thermally insulated embodiment, it is provided that the multi-head insulator has one or more hollow chambers, with a foam filling being introduced into at least one of the hollow chambers.

According to another development and possibly optionally an aspect to be considered independently, the following object is created, with which very good thermal insulation is achieved: A composite profile arrangement according to one of the related preceding claims with an insulating glass pane section of 190mm of an insulating glass pane, characterized in that it has the following Isotherm progression: at an outside temperature of -10 ° C and an inside temperature of 20 ° C, a 10 ° C isotherm B and preferably a 13 ° C isotherm run C viewed in the Y direction between the interior and the exterior always within the overall insulation zone, which includes the two insulation zones (23, 33).

According to a further advantageous optional and very well thermally insulated embodiment, it is provided that it has the following isotherm profile: the 0° isotherm A, viewed in the Y direction, always runs in the lower half of the composite profile arrangement - both in the frame composite profile (2) and in the Sash frame composite profile - and the 10° isotherm B always runs in the upper half of the overall insulating zone and the upper half of the insulating glass pane (4) or the two insulating zones and the 13° isotherm C always runs - except for the insulating glass pane, completely in the upper one Half of the total isolation zone.

The invention also creates the insulating body of claim 24, i.e. an insulating body for a sash frame composite profile, which has a first metal shell and a second metal shell and a sash frame insulating zone formed therebetween, which has the insulating body, characterized in that the insulating body is designed as a multi-head insulator is formed with a multi-head web, which in turn has two insulating webs, which are designed to connect the two metal profiles of the sash composite profile to one another and which insulating webs are connected to one another by means of transverse webs, one of the insulating webs having an insulating approach.

In this way, an insulating body is created for a sash composite profile that has a very low heat transfer coefficient.

Claim 24 is followed by the advantageous embodiments of claims 25 - 37. These contribute to a very low heat transfer coefficient and each create advantageous constructive developments.

According to an advantageous embodiment, it can be provided that the insulating web of the multi-head web of the multi-head insulator, which is oriented towards a glass rebate in an installed state, is longer than the insulating web of the multi-head web of the multi-head insulator, which is oriented towards the rebate space.

According to an advantageous embodiment, it can also be provided that the transverse webs of the multi-head web of the multi-head insulator are thinner than the insulating webs of the multi-head web of the multi-head insulator. Then, according to an advantageous embodiment, it can be provided that the longer insulating web of the multi-head web that is oriented towards the glass rebate has the glass rebate insulation element that projects into the glass rebate

According to an advantageous embodiment, it can also be provided that the two insulating webs of the multi-head web of the multi-head insulator run parallel or essentially parallel to one another.

According to an advantageous embodiment, it can also be provided that the multi-head web has at least two head regions at each of its two ends, with which the multi-head web is fastened to the first and second metal shell of the sash frame composite profile.

According to an advantageous embodiment, it can also be provided that the head areas with which the multi-head web is fixed to the first metal shell are at a smaller distance from one another than the head areas with which the multi-head web is attached to the second metal shell of the sash composite profile.

According to an advantageous embodiment, it can also be provided that the insulating webs of the multi-head insulator of the sash composite profile are made of a non-foamed ABS and have an X value between 0.3 W/(mK) and 0.1 W/(mK), preferably between 0.22 W/(mK) and 0.14 W/(mK).

According to an advantageous embodiment, it can also be provided that the insulating webs of the multi-head insulator of the sash composite profile are made of the unfoamed ABS and have an (mK) or less.

According to an advantageous embodiment, it can also be provided that the insulating webs of the multi-head insulator of the sash composite profile consist of a foamed plastic, in particular polyamide (PA), and have an X value between 0.3 W/(mK) to 0.1 W /(mK), preferably between 0.29 W/(mK) and 0.10 W/(mK).

According to an advantageous embodiment, it can also be provided that the insulating webs of the multi-head insulator of the sash composite profile consist of a foamed plastic, in particular polyamide, and have an X value less than 0.22 W/(mK) and in particular made of a polyamide with 0.21 W/(mK) or less.

According to an advantageous embodiment, it can also be provided that the multi-head insulator has one or more hollow chambers, with a foam filling being introduced into at least one of the hollow chambers.

According to an advantageous embodiment, it can also be provided that the foam filling of the multi-head insulator is formed from one or more inserts made of foamed plastic or from one or more foams made of plastic.

According to an advantageous embodiment, it can also be provided that the glass rebate insulation element (336) is made entirely or essentially from a foamed PE.

According to another further development and possibly optionally an aspect to be considered independently, the following object is created with which very good thermal insulation is achieved: A window or door or facade element with at least one or more composite frame arrangements assembled into a frame and a sash frame that is movable relative to it one of the preceding claims.

The invention also creates a window or door or facade element with at least one or more composite frame arrangements assembled into a frame and a sash frame that is movable relative thereto, according to one of the related claims, which accordingly has very good thermal insulation.

Further advantageous embodiments of the invention can be found in the subclaims, which can be combined with each of the main claims.

Embodiments of the object according to the invention are shown in the drawings and are described in more detail below. The invention is not limited to these exemplary embodiments. It is also conceivable to combine features of the exemplary embodiments shown into other exemplary embodiments in a manner other than that shown. Show it:

Figure 1: a sectional view of a first composite profile arrangement with a

Edge of an insulating glass pane;

Figure 2: a sectional view of the first composite profile arrangement with a

Edge of an insulating glass pane and with an isothermal curve supplemented in the section;

Figure 3: a sectional view of a second composite profile arrangement with an edge of an insulating glass pane;

Figure 4: a sectional view of the second composite profile arrangement with a

Edge of an insulating glass pane and with an isothermal curve supplemented in the section;

Figure 5: a sectional view of a third composite profile arrangement with a

Edge of an insulating glass pane;

Figure 6: a sectional view of a fourth composite profile arrangement with a

Edge of an insulating glass pane;

Figures 7 -12: Sectional views of variants of various sash composite profiles for composite profile arrangements;

Figure 13: a sectional view of a glass rebate insulation element; and

Figures 14, 15: Sectional views of variants of different frame composite profiles for composite profile arrangements.

Some elements that are common to the exemplary embodiments shown will first be explained below.

Figure 1 shows a section through a composite profile arrangement 1 for doors, windows or facade elements (the latter is not completely shown here). A circumferentially closed frame (not shown here) or, for example, a three-sided non-circumferentially closed frame for a window, a door or a facade can be made from several sections of such a composite profile arrangement 1, this frame having a frame and a sash frame. The sash frame is part a wing that is movable relative to the frame on a joint element such as a rotating and/or folding hinge or the like, which surrounds a surface element such as an insulating glass pane 4 on several, so on three (door) or four (particularly window or facade element) sides. Below, the term “window” is also used synonymously for doors and facade elements. The frame is used to insert into a wall opening.

The composite profile arrangement 1 of Figure 1 has a frame composite profile 2 and a sash frame composite profile 3. The frame that runs around on three or four sides can be assembled from several of the frame composite profiles 2 and from several of the sash composite profiles the sash frame, which is generally completely circumferential, can be assembled.

The frame composite profile 2 has a first metal shell 21 - in particular designed as an extruded profile made of aluminum - and a second metal shell 22 - in particular designed as an extruded profile made of aluminum. A frame insulating zone 23 is formed between these two metal shells 21, 22.

It is preferred that the first and second metal shells 21, 22 of the frame composite profile 2 each have at least one hollow chamber 211, 221. Alternatively, you can have several hollow chambers.

The sash frame composite profile 3 has a first metal shell 31 - in particular designed as an extruded profile made of aluminum - and a second metal shell 32 - in particular designed as an extruded profile made of aluminum. A sash frame insulation zone 33 is formed between these two metal shells 31, 32.

It is preferred that the first and second metal shells 31, 32 of the sash composite profile each have at least one hollow chamber 311, 321. Alternatively, you can have several hollow chambers.

The frame composite profile 2 is designed for installation in an opening in a wall of a building. In this respect, it has a connection side 2A that faces this wall opening when installed. It also has a rebate side 2B, in which it points to the sash composite profile 3 or to the rebate space F between the frame composite profile 2 and the sash composite profile 3.

The sash frame composite profile 3 is designed to accommodate a surface element such as an insulating glass pane 4. In this respect it points to this opening pointing glass rebate side 3A. It also has a folded side 3B, in which it faces the sash composite profile 3. As shown, the insulating glass pane can be held in the sash frame or here the sash frame composite profile 3 by means of sealing strips 34, 35. For this purpose, a glass retaining strip 36 can also be provided.

A rebate space or rebate gap F is formed between the fold sides 2B of the frame composite profile and 3B of the sash composite profile.

The second metal shell 21 of the frame composite profile 2 and the metal shell 31 of the sash composite profile 3 can each have webs 222, 312 (here extending in the of the frame composite profile 3 overlap in areas so that the rebate space F is covered laterally. In order to close any remaining gap between the first metal shell 21 and the web 312 or the second metal shell 32 and the web 222, one or more stop sealing strips 37 can optionally be formed on the webs 221 and/or 311.

The sash frame composite profile 3 can be movable in and against a direction The type of movement depends on how the sash and frame are coupled and on which side of the frame the frame composite profile and the sash composite profile are arranged relative to the joint elements.

The surface element - here the insulating glass pane 4, preferably in triple glazing - extends essentially perpendicular to it in a Y-Z Z plane, the direction Z here being the direction perpendicular to the sectional plane of Figure 1. When calculating the heat transfer coefficients, a pane edge of 90 mm is usually included in the calculation.

The overall insulation zone of the frame profile arrangement has the frame insulation zone 23 and the sash frame insulation zone 33, which complement each other to form a type of overall insulation zone, which essentially completely covers the composite profile arrangement like a thermal insulation barrier between the two metal shell levels of the frame composite profile 2 and the sash composite profile 3 in the Y direction from the first insulating web 231 over the rebate space to the glass edge rebate G. This overall insulating zone has several - preferably six or more - insulating sections which are arranged between the side 2A and the side 3A of the frame composite profile 2 and the sash composite profile.

In addition, the insulating glass pane 4 can be held in the sash frame or here the sash frame composite profile 3 by means of the seals 34, 35 (or in another way), as shown. These seals 34, 35 can be designed as glass seals which are arranged between the insulating glass pane 4 and the glass retaining strip 36 and the second metal shell 32 of the sash composite profile. These seals 34, 35 can consist of an insulating material or a composite of materials, in particular consist entirely or partially of an EPDM.

The frame insulation zone 23 here initially has two insulating webs 231, 232 of the frame composite profile 2. These preferably consist entirely or essentially (e.g. except for wire elements or the like) of an ABS (acrylonitrile-butadiene-styrene copolymer) or a polyamide - in particular polythermide (trademark of the applicant Schüco International KG). If a polyamide is used, it is used in foamed form.

The insulating webs 231 - made of non-foamed plastic - preferably have an X value of 0.3 to 0.1, particularly preferably between 0.22 and 0.14, in particular less than 0.16 W/(m K). In particular, an ABS with an X value <0 0.15 W/(mK) can be used.

If an ABS is used, it preferably has an X value (lambda value) of 0.16 W/(mK) or.

If foamed plastic, in particular foamed polyamide, is used as the material of the insulating webs 231, 232, it preferably has an X value of 0.3 to 0.1, particularly preferably between 0.29 to 0.10 and in particular less than 0.22 W /(mK) or less.

The two insulating webs 231, 232 can also - in particular - consist of various of the materials mentioned above.

1, these two insulating webs 231, 232 form the first insulating section of the insulating zone 23 of the overall insulating zone 2. The two insulating webs 231, 232 of the frame composite profile 2 can be designed at a distance from one another. They can also be aligned parallel. These insulating webs 231, 232 can also each have one or more hollow chambers 2311, 2321 - here three hollow chambers. They can also be the same length. They can also have head areas 2312 and 2322 at their ends; 2322, 2323, with which they engage in corresponding grooves of the first and second metal shells 231, 232, in which they can be fixed in a shear-resistant manner, preferably by rolling.

The space between the two spaced insulating webs 231, 232 of the frame composite profile 2 and the first and second metal shells 21, 22 can be completely or essentially (i.e. more than 80%) filled by a foam element, in particular a phenolic resin foam element 233. This can be co-extruded with one of the two insulating webs 231, 232, here with the insulating web 232 lying on the fold side 2B. A narrow gap can remain between the first insulating web 221 and this foam element, in particular a triangular or wedge-shaped gap in cross section, which widens away from the insulating web in the rebate space F.

The foam element, in particular the phenolic resin foam element 233, forms the second insulating section of the overall insulating zone according to FIG. 1 (see also FIGS. 13 and 14).

The X value of the phenolic resin foam member 233 is preferably:

X value = 0.022 W/(mK) or less (see Figures 13 and 14).

The insulating web 232 lying on the fold side 2B has a center seal insulation block 234 on the fold side 2B. This is preferably made from a TPE and/or an EPDM. According to FIG. 1, the center seal insulation block 234 forms the third insulating section of the overall insulating zone. It can preferably extend from the insulating web 232 of the frame composite profile over more than half the width of the rebate space F in the Y direction and over more than half the length of the insulating web 232 in the X direction. It can be glued to the insulating web 232 or attached to foot elements or extruded together with it.

According to FIG. 1, the center seal insulation block 234 forms the third insulating section of the overall insulating zone. In addition to the center seal insulation block 234 (preferably PE foam with an

This stop center seal 235 can have a base 2351 in the manner of an A and a sealing stop head 2352 on the side facing away from a locking foot 23511. The base 2351 engages with the locking foot 23511 of the A in a receiving groove 2324 of the insulating web 232, which fixes the locking foot 23511 on the insulating web 232. The other web 23512 of the A is supported on the second metal shell 22.

The locking foot 23511 can be made of TPE. The base 2351 and the sealing stop head 2352 can be made of EPDM.

In this way, this stop center seal 235 is securely fastened in the rebate space F on the composite frame profile 2 and still has good heat-insulating properties. These are preferably further improved by the following embodiment.

Nut

According to this advantageous embodiment, which can also be viewed as a separate invention, the base 2351 can rest against the center seal insulation block 234 when the wing 3 is open. If the sash 3 is closed, the base 2352, in particular the sealing stop head 2352, lifts off the center seal insulation block 234, since the sash frame 3 abuts against it with an element of the sash frame and the base 2351 lifts a few mm from the center seal insulation block 234 when closing, preferably by 1 to 2 mm. Then the gap in the closed state of the sash composite profile 3 is the gap S1 preferably > 0.01 mm and < 2 mm, so that it interrupts the direct heat transfer between the elements 234 and 235 at this point.

Starting from the gap S1, a chamber (towards the insulating web 232), for example or preferably wedge-shaped, can be formed in sections or completely between the center seal insulation block 234 and the base 2351. Starting from the gap S1, the chamber can also be designed differently, for example rectangular, in particular as a parallelogram. The gap S1 formed in this way optimizes the thermal insulation. When the sash is opened again or the sash frame composite profile 3 is lifted off, the sealing stop head 2352 preferably moves back slightly due to a resilient effect. If necessary, it can also rest against the center seal insulation block 234. The stop center seal 235 can be made of TPE (especially the foot) and/or EPDM (foam, especially in the area protruding into the fold).

According to FIG. 1, the stop center seal 235 can form a further section of the third insulating section of the overall insulating zone.

The sash insulating zone 33 then preferably has two insulating webs 332, 333, preferably designed as a region of a multi-head web of a multi-head insulator 331, wherein the multi-head web can consist of a plastic material.

The multi-head web can preferably have one, two or more hollow chambers 3311, 3312 and here have the two insulating webs 332, 333, which are preferably aligned completely or essentially parallel to one another (see also FIGS. 7 to 12). The multi-head web can preferably consist entirely or essentially (e.g. except for wire elements or the like) of plastic, in particular an ABS such as Polytherm id (Schüco) or of polyamide. The multi-head web is a hollow plastic body.

The multi-head insulator 331 can be designed as a four-head insulator. The multi-head bridge is then a four-head bridge. This is particularly advantageous because it achieves good statics of the sash composite profile, which is accompanied by good thermal insulation.

The four-head insulator 331 has the multi-head web, which can preferably consist entirely or essentially (e.g. except for wire elements or the like) of polythermide or polyamide. The two insulating webs 332, 333 can be designed at a distance from one another. They can be connected in the area of their ends by crossbars 334, 335. The two transverse webs 334, 335 can be thinner than the insulating webs 332, 333 of the four-head web. Thin-walled bars have the ability to expand better when foaming occurs. In this way, an expansion space is advantageously created in the multi-head web in a simple manner for any expansion during foaming. Outside the crossbars, heat-insulating chambers are created for the metal shells.

The two insulating webs 332, 333 can be of different lengths. In particular, it can be provided that the insulating web 333 oriented towards the glass rebate F is longer than the other insulating web 332 oriented towards the rebate space F, in particular more than 10%, preferably more than 20% longer. This has the advantage that it is close to the Insulating glass pane 4 further improves the thermal insulation. The first metal shell 31 can be made correspondingly narrower here. This contributes to an optimized, uniform isothermal progression. This will be explained in more detail below with reference to FIG. 2.

The four-head insulator 331 can also have one or more, here two, hollow chambers 3311, 3312. The insulating webs 332, 333 can also have head regions 3321, 3331 or 3322, 3323 at their ends, with which they engage in grooves in the first and second metal shells, in which they can be fixed in a shear-resistant manner, preferably by rolling.

At least one of the hollow chambers 3311, 3312 can be formed inside an insulating attachment 3323. This insulation approach 3323 can be attached to the first insulating bar

332 of the four-head insulator 331 and extend from here into the rebate space F. It can extend up to 50% of its width. It can touch the sling seal 235 when closed. It can also have the hollow chamber 3312. It can be filled with foam or have an insert. The hollow chamber 3311 can also not be made of foam.

The insulation approach 3323 can have a boundary wall, which is the element which lifts the sealing stop head 2352 from the center seal insulation block 234 when closed or in the closed state. The other of the hollow chambers 3322 can be between the transverse webs 334, 335 and the parallel insulating webs 332,

333 be trained.

The hollow chambers 3311 and 3312 can be completely or partially filled with foam as shown.

This foam can be designed as an insulating plastic foam (Figure 1, Fog.2, Figure 7). It can be formed by foaming the hollow chambers 3311, 3312 (see also Figure 8). Alternatively, inserts 33111, 33121 in the form of webs made of foam can have been inserted into the hollow chambers 3311, 3312 at this point (see, for example, Figures 1 and 3 and 7).

The inserts 33111, 33121 can be designed as PU inserts 33111, 33121. For example, they can have an X value of the following size:

X < 0.027 W/(mK). The foam can be designed as a PE injection foam. The hollow chambers

3311 and 3312 can have an X-value of the following size: large chamber 3311 X-value < 0.028 W/(mK); and small chamber 3312 X-value < 0.034 W/(mK).

The advantageous multi-head insulator 331, in particular four-head insulator, forms the fourth and fifth insulating sections of the overall insulating zone according to FIG. 1 with the insulation approach 3323.

The multi-head insulator 331 - made from unfoamed or foamed plastic - preferably has an X value of 0.1 W/(mK) to 0.3 W/(mK), particularly preferably between W/(mK) 0.14 and W/(mK ) 0.22, in particular X value <0.16 W/(mK). In particular, an unfoamed ABS with an 0.1 to 0.3, particularly preferably between 0.10 to 0.29, in particular as 0.22 W/(mK) or less, particularly preferably foamed PA (polyamide) with an X value <0.21 W/( mK).

It is also conceivable to fill the hollow chambers 3311 and 3312 with injection foam (PUR) or insulation inserts (PUR/PE/PF/MF/XPS/PET/EPS) with the mentioned X values: large chamber 3311 X value < 0.028 W /(mK) and small chamber 3312 X value < 0.034 W/(mK).

The multi-head insulator 331 can in turn be made in particular from Polythermid PT (an ABS, brand name of Schüco International KG). It can then, for example, have an X value of the following size: X < 0.022 W/(mK).

The insulating webs 332, 333 of the sash composite profile can run parallel or only essentially parallel to one another, so that the distance between the head regions 3321, 3331 or 3322, 3331 on the first metal shell 332 is smaller than the distance between the fastening heads on the second metal shell. 333. The angle between the insulating webs 332, 333 is less than 30° (Figure 9, Figure 10).

Only one of the hollow chambers 3321, 3322 of the four-head insulator 331 can also be provided with a foam filling. In the glass rebate G, a glass rebate insulation element 336 can be arranged and/or formed on the four-head insulator 331, in particular on its second insulating web 332.

This glass rebate insulation element 336, possibly supplemented by a seal, can cross the entire glass rebate in a strip-like manner in the transverse direction - preferably always at a slight distance from the edge of the pane. It can be made or consist of PE or PET.

According to FIG. 1, the glass rebate insulation element 336 forms the sixth insulating section of the overall insulating zone, possibly supplemented by a seal. The glass rebate insulation element 336 can consist of foamed material, in particular foamed PE and particularly preferably XPET.

For example, it can have a lambda value as follows: X value < 0.03 W/(mK), in particular X value = 0.029 W/(mK).

Overall, the six insulating sections, possibly supplemented by a further section of the third insulating section in the illustrated and explained embodiment, result in particularly good thermal insulation.

The two sealing strips 34, 35 can each have a base 341, 351 made of a stronger material and a sealing area 342, 352 made of a foam such as EPDM. They can also have a flag 343, 353 with which they can further divide the glass rebate into several chamber-like areas, which can optionally optimize the overall insulation effect like an eighth insulation zone.

Overall, the overall insulation zone achieves extensive thermal separation between the metal shells and overall between the rooms I and II to be separated.

This is illustrated very well in FIG. 2, which shows an isothermal profile of the composite profile arrangement from FIG. 1.

This is calculated according to DIN EN ISO 10077-2 - Thermal behavior of windows, doors and shutters - Calculation of the heat transfer coefficient - Part 2: Numerical method for frames. The depth in Y direction is 75 mm. But it is not limited to this value. In preferred embodiments, it can advantageously be between 50 mm and 125 mm.

The isothermal curve is shown in Figure 2 at an outside temperature of -10 ° C (in outside room I). A temperature of 20° is assumed in interior II.

Particularly visible are the 0°C isotherm A, the 10°C isotherm B and the 13°C isotherm C.

It can be seen that the 0° isotherm A, viewed in the Y direction, always runs advantageously in the lower half of the composite profile arrangement - both in the frame composite profile 2 and in the sash composite profile 3. Viewed in the Y direction, the 0° isotherm A always runs advantageously within the lower half of the overall insulating zone, which includes the two insulating zones 23, 33. It also runs in the lower half of the insulating pane 4 (here, for example, triple glazing with two chambers). The 10° isotherm B, on the other hand, always runs in the upper half of the overall insulating zone and the upper half of the insulating glass pane 4 or the two insulating zones 23, 33 and the 13° isotherm C always advantageously runs completely in the upper half of the overall insulating zone 23, 33 It can only run along the upper edge of the insulating glass 4 itself (towards the interior).

The calculation takes into account a 190 mm pane edge of an insulating glass pane 4, which has three spaced individual panes. The 0° and 10° isotherms also always run through this disk. The 13° isotherms B and C run in sections along the edge of the insulating glass pane 4. The insulating glass pane 4 can be designed as triple glazing with a central pane and two outer panes and hollow chambers in between.

According to Figure 3, a particularly wide frame is formed. Therefore, the frame composite profile 2 can be designed to be correspondingly wide.

The composite profile arrangement 1 can have a width in the X direction of more than 130 mm, in particular more than 150 mm, particularly preferably more than 175 mm.

The overall depth in the Y direction is again 75 mm. But it is not limited to this value. In preferred embodiments, it can advantageously be between 50 mm and 100 mm. In particular, it is intended that the composite frame profile 2 be designed to be very wide. For this purpose, it can be provided that both insulating webs 231, 232 each have a phenolic resin foam element 2331, 2332 on the two sides facing each other. These can extend close to each other, preferably leaving a gap of less than 2 mm.

In this way, very good thermal insulation is achieved even with such a wide composite frame profile. The isothermal curve 4 according to Figure 4 has the same advantageous features as discussed above in relation to Figure 2 (in Figure 3, foam is used in the hollow chambers of the multi-head web and in Figure 4, inserts are used, which but leads to essentially equally good results).

The exemplary embodiment of FIG. 5 differs from FIG. 1 in particular in that the sling seal 235' is designed somewhat differently. It has a slightly different base area. The sling seal 235′ can have one or more hollow chambers 2351 here and also in other embodiments. The hollow chamber 2351 here has two partial chambers that are connected via a narrow channel, which also leads to thermal insulation. This 235" sling seal can preferably be made of TPE and/or EPDM. The entire sling seal 235′ can have one or more hollow chambers 2351. The insulating webs 232 facing the rebate space F also have no hollow chambers (Figure 5, Figure 15).

The exemplary embodiment of Figure 6 differs from Figure 1 in particular in that a slightly modified sling seal 235″ also takes over the function of the center seal insulation block 234. An enlarged and here one-piece center seal 235" is therefore created, which also abuts the multi-head insulator 331 with a shoulder that forms a seal stop head similar to the seal stop head 2352 when the wing is closed. This 235" sling seal extends over the entire length of the insulating web 232 of the frame composite profile on the side of the rebate space F to the sash composite profile 3. It can preferably be made of TPE and/or EPDM. The entire sling seal 235" can have hollow chambers 2351.

According to Figure 3, the hollow chambers 3311, 3321 of the four-head insulator 331 can be filled with foam. Alternatively, inserts 33112, 33212 made of foamed material can also be inserted into them, for example in the manner of FIG. 1. Otherwise, the advantages discussed with regard to Figurl apply.

In the combination of the elements, according to the arrangement of FIGS. 1 and 2, a thermal insulation of llf < 0.95 W / (m ² K) for a construction depth > 75 mm (Y direction) and a width of the profile arrangement in the X direction preferably <125 mm, in particular <117 mm.

In the combination of the elements, according to the arrangement of FIGS. 3 and 4, a thermal insulation of llf < 0.80 W / (m ² K) for a construction depth > 75 mm (Y direction) and a width of the profile arrangement in the X direction preferably <190 mm, in particular <178 mm). In the combination of the elements, according to the arrangement of FIG. 5, a thermal insulation of llf <0.80 W/(m ² K) is preferred for a construction depth of > 90 mm (Y direction) and a width of the profile arrangement in the X direction < 125 mm, in particular <117 mm.

In the combination of the elements, according to the arrangement of FIG. 6, a thermal insulation of llf < 1.00 W/(m ² K) for a construction depth > 75 mm (Y direction) and a

Width of the profile arrangement in the X direction is preferably <125 mm, in particular <117 mm.

Reference symbol list

Composite profile arrangement 1

Frame composite profile 2 sides 3A, 3B first metal shell 21 second metal shell 22 hollow chamber 211, 221 web 222

Frame insulating zone 23 stop sealing strip 24 two insulating webs 231, 232 hollow chambers 2311, 2321 head areas 2312, 2313 or 2322, 2323

Phenolic resin foam element 233 Center seal insulation block 234 Sling seal 235, 235' base 2351

Foot 23511

Sealing stop head 2352

Sash frame composite profile 3 sides 3A, 3B first metal shell 31 hollow chamber 311, 321 web 312 second metal shell 32 sash frame insulation zone 33 four-head insulator 331 insulating webs 332, 333 sealing strips 34, 35 glass retaining strip 36

Stop sealing strip 37 Four-head insulator 331 Hollow chambers 3311, 3312 Insulating webs 332, 333 Head areas 3321, 3331 or 3322, 3332 Insulation attachment 3323 Crossbars 334, 335

Glass rebate insulation element 336 hollow chambers 3311, 3321

Inserts 33112, 33212

Rebate space F

Glass rebate G directions X, Y, Z

Claims

Claims Composite profile arrangement (1) for a door, a window or a facade element with: a) a frame composite profile (2) which has a first metal shell (21) and a second metal shell (22) and a frame insulation zone (23) formed between them; b) a sash frame composite profile (3) which is movable relative to the frame composite profile (2) into an open position and a closed position and which has a first metal shell (31) and a second metal shell (32) as well as a sash frame insulation zone (33) formed between them and a glass rebate ( G), in which a surface element, preferably an insulating disk (4), can be received; c) a rebate space between the frame composite profile (2) and the sash frame composite profile (3), characterized in that d) the frame insulation zone (23) has at least one insulating web (231, 232) and a combination of a center seal insulation block (234) and one to it sectionally movable stop means seal (235, 235'), the center seal insulation block (234) and the stop means seal (235, 235') each being arranged entirely or partially on the insulating web (233) of the frame directed towards the rebate space (232), in the closed state of the sash composite profile (3) a gap S1 is formed at least in sections between the center seal insulation block (234) and the sectionally movable stop means seal (235, 235'), the stop means seal (235, 235') being in the closed state by an element of the sash composite profile, into which Position is moved in which the gap between the center seal insulation block (234) and the partially movable stop means seal (235, 235 ') is formed in the closed state of the sash frame composite profile (3). Composite profile arrangement according to claim 1, characterized in that in the closed state of the sash frame composite profile (3) a sectional, in particular wedge-shaped gap S1 is formed between the center seal insulation block (234) and the sectionally movable stop means seal (235, 235 '), the gap S1 preferably < is 2 mm.

3. Composite profile arrangement according to claim 1, characterized in that in the closed state of the sash composite profile (3) the gap S1 is preferably > 0.01 mm and <2 mm.

4. Composite profile arrangement according to one of the preceding claims, characterized in that the stop seal (235, 235 ') is moved in the closed state by an element of the sash composite profile, in particular by the multi-head insulator (231), into the position in which in the closed state of the Sash frame composite profile (3) the gap S1 is formed between the center seal insulation block (234) and the partially movable stop means seal (235, 235 ').

5. Composite profile arrangement according to one of the preceding claims, characterized in that the stop seal (235, 235 ') rests on the center seal insulation block (234) in the open state.

6. Composite profile arrangement according to one of the preceding claims, characterized in that the sling seal (235, 235 ', 235") comprises areas made of TPE and / or EPDM.

7. Composite profile arrangement according to one of the preceding claims, characterized in that the center seal insulation block (234) is made entirely or in sections from a foam element, in particular PE foam, and has an X value <0.036 W/(mK).

8. Composite profile arrangement according to one of the preceding claims, characterized in that the insulating webs (231, 232) of the frame composite profile (2) and / or possibly the sash composite profile, in particular the multi-head insulator of the sash composite profile (3), are made of a non-foamed ABS and one X value between 0.3 W/(mK) and 0.1 W/(mK), preferably between 0.22 W/(mK) and 0.14 W/(mK).

9. Composite profile arrangement according to one of the preceding claims, characterized in that the insulating webs (231, 232) of the frame composite profile (2) and / or possibly the sash composite profile, in particular the multi-head insulator of the sash composite profile (3), are made of the unfoamed ABS and one X value less than 0.16 W/(mK) in particular from an ABS with 0.15 W/(mK) or less. Composite profile arrangement according to one of the preceding claims, characterized in that the insulating webs (231, 232) of the frame composite profile (2) and / or possibly the sash composite profile, in particular the multi-head insulator of the sash composite profile (3), made of a foamed plastic, in particular polyamide (PA ), exist and have an X value between 0.3 W/(mK) to 0.1 W/(mK), preferably between 0.29 W/(mK) and 0.10 W/(mK). Composite profile arrangement according to one of the preceding claims, characterized in that the insulating webs (231, 232) of the frame composite profile (2) and / or possibly the sash composite profile, in particular the multi-head insulator of the sash composite profile (3), made of a foamed plastic, in particular polyamide (PA ), and have an X value less than 0.22 W/(mK) and in particular made of a polyamide with 0.21 W/(mK) or less. Composite profile arrangement according to one of the preceding claims, characterized in that between the insulating webs (231, 232) of the frame composite profile (2) there is at least one phenolic resin foam element (233) with an /(mK) or X value = 0.021 W/mK or smaller is introduced. Composite profile arrangement according to one of the preceding claims, characterized in that the foam filling of the multi-head insulator is formed from one or more inserts made of foamed plastic or from one or more foams made of plastic. Composite profile arrangement according to one of the preceding claims, characterized in that the glass rebate insulation element (336) is made entirely or essentially from a foamed PE. Composite profile arrangement according to one of the preceding claims, characterized in that the insulating web (333) of the multi-head web of the multi-head insulator (331) oriented towards the glass rebate (G) is longer than the insulating web (332) of the multi-head web of the multi-head insulator (331) which is oriented towards the rebate space (F). ). Composite profile arrangement according to one of the preceding claims, characterized in that the transverse webs (334, 335) of the multi-head web of the T.I

Multi-head insulator (331) are thinner than the insulating webs (332, 333) of the multi-head web of the multi-head insulator (331).

17. Composite profile arrangement according to one of the preceding claims, characterized in that the longer insulating web (333) of the multi-head web oriented towards the glass rebate (G) has the glass rebate insulation element (336) projecting into the glass rebate (G).

18. Composite profile arrangement according to one of the preceding claims, characterized in that the two insulating webs (232, 233) of the multi-head web of the multi-head insulator (331) run parallel or substantially parallel to one another.

19. Composite profile arrangement according to one of the preceding claims, characterized in that the multi-head web (331) has at least two head regions (3321, 3331 or 3322, 3323) at each of its two ends, with which the multi-head web is attached to the first or second metal shell (31, 32) of the sash composite profile (3) are attached.

20. Composite profile arrangement according to one of the preceding claims, characterized in that the head regions (3321, 3331), with which the multi-head web is fixed to the first metal shell (31), are at a smaller distance from one another than the head regions (3322, 3323), with which the multi-head web is attached to the second metal shell (31, 32) of the sash composite profile (3).

21. Composite profile arrangement according to one of the preceding claims, characterized in that the multi-head insulator (331) has one or more hollow chambers (3311, 3312), with a foam filling being introduced into at least one of the hollow chambers (3311, 3312).

22. Composite profile arrangement according to one of the preceding claims with an insulating glass pane section of 190 mm of an insulating glass pane, characterized in that it has the following isotherm curve: at an outside temperature of -10 ° C and an inside temperature of 20 ° C, a 10 ° C isotherm B and preferably a 13 ° C isothermal C in the Y direction between the interior and the exterior, always viewed within the overall insulation zone, which includes the two insulation zones (23, 33). Composite profile arrangement according to one of the preceding claims with an insulating glass pane section of 190mm of an insulating glass pane, characterized in that it has the following isotherm profile: the 0 ° isotherm A, viewed in the Y direction, always runs in the lower half of the composite profile arrangement - both in the frame composite profile (2) and also in the sash composite profile (3) - and the 10° isothermal B always runs in the upper half of the overall insulating zone and the upper half of the insulating glass pane (4) or the two insulating zones (23, 33) and the 13° isotherm C also runs always - except for the insulating glass pane (4) completely in the upper half of the overall insulating zone (23, 33). Insulating body for a sash frame composite profile (3), which has a first metal shell (31) and a second metal shell (32) and a sash frame insulation zone (33) formed therebetween, which has the insulating body, characterized in that the insulating body is designed as a multi-head insulator with a Multi-head web is formed, which in turn has two insulating webs (332, 333), which are designed to connect the two metal profiles (31, 32) of the sash composite profile (3) to one another and which insulating webs (332, 333) by means of transverse webs (334, 335 ) are connected to each other, one of the insulating webs (332) having an insulating attachment (3323). Insulating body according to claim 24, characterized in that the insulating web (333) of the multi-head web of the multi-head insulator (331) which is oriented towards a glass rebate (G) in an installed state is longer than the insulating web (332) of the multi-head web of the multi-head insulator (331) which is oriented towards the rebate space (F). 331). Insulating body according to one of the preceding claims 24 or 25, characterized in that the transverse webs (334, 335) of the multi-head web of the multi-head insulator (331) are thinner than the insulating webs (332, 333) of the multi-head web of the multi-head insulator (331). Insulating body according to one of the preceding claims 24 to 26, characterized in that the longer insulating web (333) of the multi-head web oriented towards the glass rebate (G) has the glass rebate insulation element (336) which projects into the glass rebate (G). Insulating body according to one of the preceding claims 24 to 27, characterized in that the two insulating webs (232, 233) of the multi-head web of the Multi-head insulator (331) run parallel or substantially parallel to one another.

29. Insulating body according to one of the preceding claims 24 to 28, characterized in that the multi-head web (331) has at least two head regions (3321, 3331 or 3322, 3323) at both ends, with which the multi-head web on the first or the second metal shell (31, 32) of the sash composite profile (3) are attached.

30. Insulating body according to one of the preceding claims 24 to 29, characterized in that the head regions (3321, 3331), with which the multi-head web is fixed to the first metal shell (31), are at a smaller distance from one another than the head regions (3322, 3323), with which the multi-head web is attached to the second metal shell (31, 32) of the sash composite profile (3).

31. Insulating body according to one of the preceding claims 24 to 30, characterized in that the insulating webs (231, 232) of the multi-head insulator of the sash composite profile (3) are made of a non-foamed ABS and have an X value between 0.3 W/(mK) and 0 .1 W/(mK), preferably between 0.22 W/(mK) and 0.14 W/(mK).

32. Insulating body according to one of the preceding claims 24 to 31, characterized in that the insulating webs (231, 232) of the multi-head insulator of the sash composite profile (3) are made from the unfoamed ABS and have an X value less than 0.16 W/( mK) in particular from an ABS with 0.15 W/(mK) or less.

33. Insulating body according to one of the preceding claims 24 to 32, characterized in that the insulating webs (231, 232) of the multi-head insulator of the sash composite profile (3) consist of a foamed plastic, in particular polyamide (PA), and have an X value between 0.3 W/(mK) to 0.1 W/(mK), preferably between 0.29 W/(mK) and 0.10 W/(mK).

34. Insulating body according to one of the preceding claims 24 to 33, characterized in that the insulating webs (231, 232 multi-head insulator of the sash composite profile (3), made of a foamed plastic, in particular Polyamide (PA), and have an X value less than 0.22 W/(mK) and in particular made of a polyamide with 0.21 W/(mK) or less. Insulating body according to one of the preceding claims 24 to 34, characterized in that the multi-head insulator (331) has one or more hollow chambers (3311, 3312), with a foam filling being introduced into at least one of the hollow chambers (3311, 3312). Insulating body according to one of the preceding claims 24 to 35, characterized in that the foam filling of the multi-head insulator is formed from one or more inserts made of foamed plastic or from one or more foams made of plastic. Insulating body according to one of the preceding claims 24 to 36, characterized in that the glass rebate insulation element (336) is made entirely or essentially from a foamed PE. Window or door or facade element with at least one or more composite frame arrangements assembled into a frame and a sash frame movable relative thereto according to one of the preceding claims.