DE29805579U1 - Insulated composite profile - Google Patents

Description

Thermally insulated composite profile

Thermally insulated composite profiles, such as those required in particular for the manufacture of windows, doors, facade constructions or the like, essentially consist of two metal profiles that are connected to one another via at least two insulating bars made of non-heat-conducting material, for example plastic material. Both the metal profiles and the insulating bars are manufactured as extruded profiles, whereby the insulating bars are then anchored in the metal profiles by rolling them into corresponding receiving grooves. In a window made from such composite profiles, heat flow from the metal profile on the warm inside to the metal profile on the cold outside is prevented by heat conduction.

However, with such profiles, a residual heat flow occurs through heat radiation from the warm metal profile to the cold metal profile and, if the cross section of the chamber enclosed between the metal profiles and the insulating bars is large enough, also through convection. To avoid this, it was proposed in accordance with DE 29512502 to provide the two insulating bars with crossbars that are directed towards each other and overlap one another, thus forming at least two mutually closed partial chambers. These crossbars made of insulating material, which run parallel to the metal profiles, practically prevent heat flow through radiation and, at the same time, prevent convection by reducing the chamber cross section. In addition, this arrangement enables the production of composite profiles with different width dimensions, whereby the width range that can be covered is very limited by the width of the possible overlap area of the 5 crossbars in the direction of very narrow profile widths.

These disadvantages are avoided according to the invention with a thermally insulated composite profile, in particular for windows, doors, facade constructions and the like, with two insulating webs made of non-heat-conducting material, which connect two metal profiles of the composite profile to one another and keep them at a distance from one another to form a chamber, with at least one insulating web being provided with at least one cross web which projects into the interior of the chamber and runs over the length of the insulating web and is connected to the insulating web via a film hinge, so that the cross web extends to the other insulating web in the assembled position, forming at least two partial chambers which are closed off from one another. By arranging a film hinge, it is thus possible to arrange the insulating webs at a smaller distance from one another, starting from the maximum width of the composite profile specified by the width of the insulating web, with the cross web which rests against the other insulating web with its free edge then being pivoted accordingly about the film hinge, which runs more or less diagonally between the two insulating webs depending on the reduction in the distance between the insulating webs. It is possible to divide the space between the two metal profiles into two sub-chambers with just one crossbar.
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In a particularly useful embodiment of the invention, it is provided that the crossbar is arranged off-center in relation to the cross section of the insulating bar. This makes it possible to arrange the two insulating bars running parallel to each other very close to each other.

both insulating bars are provided with such crossbars, then the insulating bars can be arranged offset from each other "on the envelope" so that the space between the two metal profiles is divided into three sub-chambers. 35

In a particularly expedient embodiment of the invention, it is further provided that the crossbar is divided at least once in the longitudinal direction and that the partial webs each have a

are connected to each other with a film hinge. This measure makes it possible to cover an even larger width range for the composite profile, since when the two insulating webs are "pushed together" the cross web no longer runs diagonally according to the division but can bend, so that the two insulating webs can be brought much closer together. If the webs are divided into more than two partial webs, the cross web has a zigzag shape in cross section if the insulating webs have to be arranged very close to each other.

In a further advantageous embodiment of the invention, the crossbar is hinged to two insulating webs running parallel to one another, each via a film hinge. This arrangement offers the advantage that the partial chambers divided by the crossbar are sealed and no crossflows can occur. The further advantage is that, with different widths of the composite profile and correspondingly different distances between the insulating webs, the crossbar divided into at least two partial webs can bend in a precisely predetermined manner.

In a further advantageous embodiment of the invention, it is provided that at least one insulating bar is provided on its side facing away from the cross bar with projections and/or recesses and/or undercuts for fastening additional components. This measure makes it possible, if necessary in conjunction with corresponding projections on the metal profile, to use a corresponding projection or a corresponding undercut on the insulating bar to grip clamping grooves for fittings, transom connectors, rung connectors, locking bar guides or the like on the one hand via the metal profile and on the other hand via the insulating bar, so that it is possible to produce insulated metal structures, in particular aluminum structures with low construction depths.

The invention is explained in more detail using schematic drawings of embodiments.

Show it:

Fig. 1 shows a cross-section through a metal composite profile provided with insulating bars in a wide version.

Fig. 2 shows the application of the insulating bars according to Fig. 1 for a metal composite profile in a narrow design.
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Fig. 3 shows a modification of the insulating bars according to Fig. in a positioning for a wide composite profile.

Fig. 4 shows the insulating bars according to Fig. 3 in a positioning for a narrow composite profile.

Fig. 5 Modifications of the insulating bars according to Fig. 1 and

Fig.3.
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Fig. 6 a cross section through a profile arrangement

for a thermally insulated window.

As can be seen in Fig. 1, the composite profile shown in cross section has two metal profiles 1, 2, which are formed, for example, by extruded aluminum profiles. The two metal profiles 1, 2 are connected to one another via insulating webs 3, 4, which are made, for example, from an extruded plastic material such as polyamide, PVC or from other plastic materials with comparable strength and comparable poor heat conduction. The insulating webs 3, 4 each have dovetail-shaped heads at their ends 5, which are inserted into correspondingly formed grooves in the metal profiles 1, 2 and 5 are fixed to the metal profile by rolling the respective outer groove edge 6.

In the embodiment shown here, each insulating web 3, 4 is provided with a cross web 7, which is hinged to the insulating web 3 or 4 via a first film hinge 8. In the embodiment shown here, the cross web 7 is divided into two partial webs 7.1 and 7.2, both of which are connected to one another via a film hinge 9. The free edge 10 of the partial web 7.2 is curved.

The two film hinges 8, 9 are now set so that when not installed, the crossbar 7 protrudes essentially vertically from the associated insulating bar 3 or 4. The greatest possible width of the composite profile is essentially determined by the width of the crossbar 7, whereby the width of the composite profile, i.e. the distance between the two insulating bars 3, 4, is expediently made somewhat smaller than the width of the crossbar 7, so that the free edge 10 reaches up to the inner surface of the opposite insulating bar. The film hinges 8, 9 are set elastically so that due to the resulting deformation, the free edge 10 rests against the associated insulating bar 3 or 4 with slight pressure.

As the cross-section according to Fig. 2 shows, a much narrower composite profile can be created with the same insulating web profile, since the cross webs can buckle due to the division into two partial webs 7.1 and 7.2 and thus the distance between the two insulating webs 3, 4 can be set much smaller.

0 In both embodiments, three transversely closed partial chambers are formed between the two metal profiles 1, 2.

From Fig. 1 and 2 it is also clear that it may be sufficient to provide only one insulating web, for example the insulating web 3, with a cross web 7, while the other insulating web, for example the insulating web 4, is designed without a cross web. This may be necessary, for example,

and/or be useful if the insulating web 4 has structurally determined projections or recesses on its outside or is provided with a co-extruded sealing profile, for example. In this case, only two partial chambers are formed between the two metal profiles 1, 2.

Fig. 1 and 2 also show that it may also be sufficient to form the crossbar 7 undivided and to fasten it directly to the insulating bar with only one film hinge 8.

This can be accepted if the specific shape of the insulating bar requires a smaller range of variation for the composite profiles to be created.

In Fig. 3 and 4, only the insulating webs for creating a composite profile are shown in cross-section. As can be seen from the comparison with Fig. 1, 2, this is a modification in that the two insulating webs 3, 4 are each connected to one another in a material-locking manner via two cross webs 7, which are each divided into two partial webs 7.1 and 7.2. Both cross webs 7 are each connected to the insulating webs via film hinges, whereby the partial webs 7.1 and 7.2 have the same stitch width and are connected to one another in the middle plane with a film hinge 9.

As the comparison between Fig. 3 and 4 shows, it is also possible to vary the width of the composite profile to be produced within wide ranges.

Fig. 5.1 shows a modification of the embodiment according to Fig. 1, in which the crossbar 7 is attached to only one insulating bar 3 but is divided into four partial bars, each of which is connected to one another via film hinges, so that here depending on the dimensioning of the extended length for the crossbar 7 and the number of subdivisions, an even greater variation in width is possible, since the zigzag-shaped bending option in a smaller space between the two

Insulating webs 3, 4 can accommodate a longer web length. Fig. 5.2 shows this principle for the embodiment according to Fig. 3, in which the cross web 7 is attached to both insulating webs 3 and 4 at the end. 5

In Fig. 6, a window post 11 with the associated window frame part 12 is shown in a cross section as an application example.

The window post 11 has an inner metal profile 1.1 and an outer metal profile 1.2. The two metal profiles are firmly connected to one another via an insulating bar arrangement 3/4 in accordance with the design according to Fig. 3. The insulating bars 3, 4 are provided with corresponding projections 13 on their outer sides, whereby only the projections facing the frame profile 12 are required for fastening a soft sealing profile 14.

On the window frame profile 12, the inner metal profile 1.1 and the outer metal profile 1.2 are firmly connected to one another via an insulating bar arrangement 3/4, which corresponds in its structure to the arrangement according to Fig. 3. In the embodiment shown here, the insulating bar 3 facing the post profile 11 is provided on its outside with a projection 15, which serves as a stop for the insulating profile 14.

As the cross-section according to Fig. 6 also shows, with the appropriate choice of material for the insulating web arrangement 0 3, 4, it is possible to attach additional fittings 16 and 17 to the metal profiles 1.1 using appropriate lugs, here lugs 13 and 15 in conjunction with corresponding counter profiles 13.1 and 15.1. For example, transom post connectors or a locking bar guide.

Claims (5)

···♦ ft »« Claims 1. Thermally insulated composite profile, in particular for windows, doors, facade constructions or the like, with at least two insulating webs (3, 4) made of non-heat-conducting material, which connect two metal profiles (1, 2) of the composite profile to one another and keep them at a distance from one another to form a chamber, wherein at least one insulating web (3, 4) is provided with at least one transverse web (7) which projects into the interior of the chamber and runs over the length of the insulating web and is connected to at least one insulating web (3, 4) via a film hinge (8, 9). 2. Composite profile according to claim 1, characterized in that the transverse web (7) is arranged off-center with respect to the cross section of the insulating web (3, 4). 3. Composite profile according to claim 1 or, characterized in that the transverse web (7) is divided at least once in the longitudinal direction and the partial webs (7.1, 7.2) are each connected to one another via a film hinge (9). 4. Composite profile according to one of claims 1 to 3, characterized in that the crossbar (7) is hinged to two insulating bars (3, 4) running parallel to one another, each via a film hinge (8). 5. Composite profile according to one of claims 1 to 4, characterized in that at least one insulating web (3, 4) is provided on its side facing away from the cross web (7) with projections and/or recesses and/or undercuts (13, 15) for fastening additional components (14, 16, 17).