NO310481B1 - Profile for placement between an inner part and an outer part in a frame structure - Google Patents

Description

The present invention relates to a profile for placement between an inner part and an outer part of a frame construction to ensure a fixed distance between these parts, which profile includes connection areas for cooperation with corresponding connection areas in the inner part, respectively the outer part of the frame construction.

It is known to use a plate-shaped profile for placement between an inner and an outer part in a frame construction. A plate-shaped profile of the known type is produced with a square cross-sectional area, see e.g. DK-B 156 229. However, this is associated with several disadvantages, as the material consumption is considerable, and because the heat transfer between the inner and outer parts of the frame structures becomes relatively large.

From DE 30 26 261 Al, a plate-shaped connection profile is known, made of an elastic, yielding material and with special edge designs, so that the profile can be mounted in the parts of the frame structure.

This complex cross-sectional geometry in the mounting areas means that some material is sometimes required to produce the profile, and that the profile has an inappropriately low compressive strength.

It is also known from German patent document DE 42 38 750 to provide a profile with a thin-walled, cellular structure, which profile is also used for placement in a frame construction for e.g. a route. The profile is made up of two parts that are clamped together and placed between the outer and inner parts of the frame structure. The first part of the cellular structure is a main part, which is fixed to the outer and inner part of the frame structure, while the second part is a removable part, which is mounted to the main part to give the profile a cellular, thin-walled structure. The second part thus does not help to increase the compressive strength of the profile.

However, a profile of this type is rather complicated in structure, and thus difficult to produce, and, as mentioned above, it has an inappropriately low compressive strength. This does not ensure that the outer and inner parts of the frame construction are maintained at a fixed distance from each other, which is a desirable property.

The purpose of the present invention is thus to remedy the disadvantages mentioned above by providing a profile for a frame structure, which is preferably used for doors and windows or the like, where the heat transfer between the outer and inner part of the frame structure is brought down to an optimally low value, due to a reduced cross-sectional area

(material consumption) and a profile, which with reduced material consumption, preserves the strength of the profile, so that the outer and inner parts of the frame construction are maintained at a desirable fixed distance from each other.

This purpose is achieved with a profile which is characterized by the fact that the profile between the connection areas is flat and is designed with a lattice structure, so that at least a first material area is formed surrounded by another material area in the form of a projection with a larger cross-sectional dimension than the first material area.

With a profile of the type mentioned above, it is thus possible to provide a profile which, with a reduced material consumption (cross-sectional area), will largely have the same strength as a profile with a square cross-section. This is achieved by giving the profile a lattice-like structure, which ensures stability in the design, which structure can absorb any pressure forces that are provided between the outer and inner parts of a frame structure. As a result of the reduced material consumption, the material through which the heat transfer will take place will also be reduced, and this will lower the heat flow through the profile, and thus through the construction frame.

Since a profile of the above-mentioned type is often produced as a plastic product, for example from polyamide, preferably polyamide 66 with 25% glass, which is a relatively expensive material, a reduction in material consumption in the profile would also be desirable for economic reasons. However, the profile can be produced in any other material that has the required strength and low heat transfer figures.

The profile's lattice-like construction can be designed in several different ways, but for strength calculation reasons will often be triangular, as a triangular profile will be able to absorb compressive forces as well as tensile forces, which can often occur in a frame construction. To ensure that these compressive and tensile forces are taken up, it will be particularly appropriate to design the first material areas as isosceles triangle areas. Such isosceles triangular areas will suitably be able to absorb both transverse forces and compressive forces.

However, in special designs of the profile, there may be first areas of material that run perpendicular to the fixing areas. However, such a design will primarily occur when the frame structure is exposed to large compressive forces.

The present invention will be explained in more detail below with reference to the drawings, where

fig. 1 shows a profile according to the invention seen from the side,

fig. 2 shows a longitudinal section through that in fig. 1 viewed profile,

fig. 3 shows another embodiment of a profile seen from the side,

fig. 4 shows a longitudinal section through that in fig. 3 displayed profile,

fig. 5 shows a section through a profile according to the present invention, seen in the profile

longitudinal direction,

fig. 6 shows two profiles in a construction consisting of an outer and an inner part,

fig. 7 shows two profiles in a frame construction, where the lower profile is provided with a

protrusion,

fig. 8 shows, as in fig. 6 and 7, two profiles between an outer and an inner part, where both

profiles are formed with protrusions for the reception of a sealing strip, and

fig. 9 shows four profiles according to the present invention, in an openable frame structure.

According to the present invention, a profile 1 is to be provided, whose primary task is to separate an outer part 5 from an inner part 4 in a frame structure 2, see fig. 1-9. With such a profile 1, it is thus possible that a frame construction 2 does not achieve a high heat transfer in case of large temperature differences, when the frame construction 2 is used for example for glass facades and the like. Therefore, a profile 1 is placed between the outer and the inner part 5, which profile will act as an insulator in the frame construction 2.

In order to reduce the heat transfer in the frame structure 2, it is desirable that the cross-sectional dimension of the profile 1 is reduced without the strength of the profile 1 being reduced. Thereby, it is achieved that the heat transfer in the frame construction 2 is reduced, and that the material consumption for the profile 1 is reduced, which is desirable as the acquisition costs for the profile 1 are relatively high. They are normally greater than the material costs for the outer and inner parts 5, 4 of the frame structure 2.

Fig. 1 shows the profile 1 according to the present invention. The profile 1 has two connection areas 12 that extend along the profile's outer edges 15. Between the connection areas 12, two material areas 7, 8 are formed. The first material area 7 has a smaller cross-sectional dimension than the second material area 8. With this design, the profile 1 achieves at least a page 9 a lattice-like structure which will give the profile 1 a relatively large strength with a smaller cross-sectional area than a profile 1 with a constant cross-sectional thickness.

The other material areas 8, which are formed at least on one side 9 of the profile 1, preferably run in a straight line, in order, as mentioned above, to give the profile 1 the desired/necessary strength. It should thus be noted that the number of these other material areas 8, which surround several of the first material areas 7, varies from profile to profile, as any frame construction varies with respect to the frame construction's area of application.

The first material areas 7, which are placed between the connection areas 12, are all surrounded by the other material areas 8, which have the larger cross-sectional dimension. The other material areas 8 are thereby part of the connection areas 12.

In fig. 2 shows a longitudinal section through it in fig. 1 showed an embodiment of a profile 1 according to the invention. There it is clear that the connection areas 12 have a larger cross-sectional area than the material areas 8, which in turn have a larger cross-sectional dimension than the material areas 7. A bead 14 is also provided at the outer edges 15 of the profile 1.

In fig. 3 shows another embodiment of profile 1 according to the invention. The embodiment of the profile 1 here provides a different lattice structure, where some of the other material areas 8 with the larger cross-sectional dimension run perpendicular to the connection areas 12. The intermediate lattice structure is formed by non-isosceles triangles, see fig. 1 and 2.

Fig. 4 shows a cross-section of a profile 1 as shown in fig. 3. From fig. 4, it clearly proceeds, in the same way as in fig. 2, that the connection areas 12 have a larger cross-sectional area than the material areas 8, which in turn have a larger material dimension than the material areas 9.

From the above described, it will appear from fig. 1 - 4, that the first material areas 7 can have any design. In the examples shown, we are only talking about triangular designs of the material areas 7. The triangles formed in the first material areas 7 will preferably have an angle of between 30 and 60° in relation to the outer edges 15 of the profile, without this needing to be limiting for the design of the profile 1.

Thus, the profile 1 could be designed with the other material areas 8 exclusively running perpendicular to the connection areas 12, thereby forming the first material area 7 with a square design. However, this will not be an optimal embodiment, as the length (the distance through the profile 1's other material areas 8 from the first part 4 to the second part 5) of the material through which the heat transfer takes place will be reduced.

A profile 1 according to the invention will preferably be made of plastic material, which can be, for example, polyamide. It could be, for example, polyamide 66 with glass, preferably 25%, PVC or the like. Since the insulation material, from which the profile 1 is made, has a relatively high acquisition and production value compared to e.g. the outer and inner parts 5, 4 of the frame construction 2, which are normally made of aluminium, it is desired that the profile 1 has a relatively small extent.

Fig. 5 shows a profile 1 according to the present invention, seen from the end. It is clear from this how the areas between the connection areas 12 form a continuous piece. This is an important prerequisite for a profile 1 according to the invention to be used. Profile 1 must be airtight to achieve good insulation. Such good insulation is achieved with a frame construction 2, where the different cavities of the frame construction are separated physically ("hermetically") from each other, see fig. 6-9.

In fig. 6 shows a frame construction 2 where two profiles 1 are placed between an inner part 4 and an outer part 5 in the frame construction. The profiles 1 are placed so that they face each other with the sides 9 where the material areas 7, 8 are formed. One can thus not see the lattice-like construction of the profile in the frame structure 2.

It will thus be possible to provide one side 16 of the profile with a projection 10. Such a projection 10 can be formed in several different ways and will preferably serve as a mounting plate for a sealing strip 11 or for recording an edge area of the sealing strip II (see fig. 7, 8 and 9).

Fig. 7, 8 and 9 show, as fig. 6, different embodiments and applications of a profile 1 in a frame construction 2 according to the invention. It thus appears, also as mentioned above, that the profile 1 on the outer side 16, opposite the one side 9, where the profile 1 has the

different material areas 7, 8 can be provided with different protrusions 10. The shown embodiments of the protrusions 10 are here only intended as examples, as it will be obvious to a person skilled in the art that these protrusions 10 can have a largely which

preferably design. The design of the protrusions 10 will, as mentioned, vary according to the purpose of application of the protrusions 10.

A profile 1 according to the invention, which is preferably, as mentioned above, made of plastic, will usually have a material thickness in the second material area 8 of between 3 and 8 mm, and a material thickness in the first material area 7 of between 0.1 and 2 mm, preferably 0.3 mm, and a height (width from one outer edge 15 to the other outer edge 15 of the profile 1) of between 15 and 40 mm, preferably 22 mm. It is obvious, however, that an increase in the height (width) of the profile 1 will result in an increased material thickness of preferably the second material area 8.

As shown in fig. 1-9, the profile 1 according to the invention is provided with beads 14 at the connection area 12. The bead 14 is intended for inclusion in a cut-out 17 in the inner part 4 and outer part 5 of the frame construction 2, respectively. The cut-out 17 will normally be designed with an undercut for that to ensure that the outer and inner parts 4, 5 of the frame structure 2 cannot be moved in relation to each other. This ensures that e.g. a route 3 in the frame construction 2 (see fig. 9) is retained. The construction thus remains stable and thus does not expose the route 3 to unnecessary influences such as twisting or compression.

Claims (10)

1. Profile (1) for placement between an inner part (4) and an outer part (5) of a frame structure (2) for securing a fixed distance between these parts (4, 5), which profile (1) includes connection areas (12) ) for cooperation with corresponding connection areas in the inner part (4) and the outer part (5) of the frame structure (2), characterized in that the profile (1) between the connection areas (12) is flat and designed with a lattice structure, whereby the comes at least a first material area (7) surrounded by another material area (8) in the form of a projection with a larger cross-sectional dimension than the first material area (7). 2. Profile according to claim 1, characterized in that the second material area (8) is continuous and surrounds several of the first material areas (7). 3. Profile according to claim 1 or 2, characterized in that the second material area (8) extends along the connection areas (12) at the outer edges (15) of the profile (1), and that between these outer edges (15) extend rectilinear sub-areas of the other material area (8). 4. Profile according to claim 3, characterized in that the rectilinear partial areas of the second material area (8) have an angle of between 30° and 90° in relation to the outer edges (15) of the profile (1). 5. Profile according to claims 1-4, characterized in that the second material area (8) has a material thickness of between 3 and 8 mm, and that the first material area (7) has a material thickness of between 0.1 and 2 mm, preferably 0.3 etc. 6. Profile according to claims 1-5, characterized in that one side (16) of the profile (1) is flat. 7. Profile according to claims 1-6, characterized in that projections (10) are provided on the flat side (16) of the profile (1) for receiving sealing strips (11) or for installing sealing strips (11). 8. Profile according to claims 1-7, characterized in that the profile (1) at the outer edges is formed with a bead (14), which bead (14) largely corresponds to an undercut (17) in the inner part (4) and the outer part respectively (5) of the frame structure (2), in which the profile (1) is placed. 9. Profile according to claims 1-8, characterized in that the profile (1) is made of a plastic material, such as for example polyamide, for example polyamide 66 with glass, preferably 25%, PVC or the like. 10. Profile according to claims 1-9, characterized in that the first material areas (7) preferably have a triangular design and that the angle in the first material areas (7) is 60°.