DE19528498C1

DE19528498C1 - Insulating core for thermally insulated laminar profile, partic. windows, etc.

Info

Publication number: DE19528498C1
Application number: DE1995128498
Authority: DE
Inventors: Albert Kraemer; Harald Kraemer
Original assignee: Albert Kraemer; Harald Kraemer
Priority date: 1995-02-01
Filing date: 1995-08-03
Publication date: 1996-06-27
Anticipated expiration: 2015-08-04
Also published as: DE29512502U1

Abstract

An insulating core for a thermally insulated laminar profile (2) consists of at least two insulating slats (3, 4) of heat insulating material which join two metal profiles (5, 6). Lateral slats (7, 8) are located on the insulating slats in the chamber formed, and the lateral slats divide the chamber into two sections. The slats overlap to form a gas tight chamber. The lateral slats are pref. made of plastic, e.g. polyamide or PET.

Description

The invention relates to an insulating core according to the features of the preamble of Claim 1.

Such an insulating core is already known from DE 22 65 017 A1. The crossbars of the Insulating webs of this insulating core have anchoring means and corresponding Counter anchoring means with which the crossbars can be locked together. in the individual the anchoring means of the insulation profile consist of strip-like Profile projections, which form with the counter-anchoring means, like pliers cooperate towards directed barbs of the crossbar of the insulating web.

Another insulating core known from DE 20 10 663 A1 has a cross-suspension connecting member snapping into adjacent grooves of the metal profiles. To the Foaming the inner chamber of this connector is a special one Design provided. The connecting link is on both sides in the area of the Snap members made with a resilient overlapping wall so that a Cross suspension of this wall is made possible during the assembly process. Here is the perforated center bar, with which the two insulating bars are connected to each other, as unyielding abutment to look at.

In DE 19 26 879 U there is a between a frame and a wing of a window lip seal formed from two sealing strips. The back ends of this Stripes are held on bends of two legs. The generated by this Insulation wall only forms a closed wall when the window sash is closed. The bisection of the lip seal has a tight seal Cavities between the frame and the window sash result. When rigid to each other arranged profiles, however, the use of a one-piece wall is provided.

From DE 94 11 396 U insulating webs are known which connect a metal profile to one another. An insertion profile can be inserted into the chamber formed by the metal profiles and insulating webs be inserted. Furthermore, it is provided on the insulating bars in the chamber protruding crosspieces to be provided, which are arranged perpendicular to the heat flow and are spaced from each other. The crossbars as well as the insertion profile are with an IR reflective coating.

From DE 42 38 750 A1 is a thermally insulated composite profile with itself in the Isolierstegen limited chamber extending and mutually overlapping cross bars known. Through this comb-like interlocking crossbars convection and Heat radiation in the inner chamber can be reduced. The arrangement of cross bars the chamber-side boundary wall of the insulating webs is also from DE 32 23 343 C2 and DE 94 11 396 U1 known, the crossbars according to the latter document additionally with an infrared-red reflective coating or a corresponding covering are provided to avoid heat radiation.

However, these insulating cores do not meet the requirements of today Thermal protection regulation. Another disadvantage is that for different widths Metal profiles and the composite profile different insulating cores must be used what a considerable manufacturing effort and a corresponding storage at the Processors. After all, there are already insulation cores with one Multi-chamber system between the outer and inner metal profile known, but also insulating cores adapted to the respective profile widths must be used here.

Proceeding from this, the object of the invention is an insulating core at the beginning Specify the type mentioned, which when reducing the heat transfer in the range Isolating bars can be used variably for different widths of the metal profiles.

This object is achieved according to the invention by an insulating core with the features of Claim 1 solved.

The insulating core according to the invention is for different widths of the metal profiles Composite profile can be used, with the crossbars overlapping with different lengths. Since the mutually assigned cross webs of the two insulating webs in the contact position step with each other, closed sub-chambers are formed within the insulating core. This multi-chamber system significantly reduces the heat transfer reached in the area of the insulating bridge. The arrangement results in one Cross bar on the chamber inner boundary wall of each insulating web two and through the arrangement of two crossbars three subchambers. In order to i. w. It is also provided that the crossbars in Mounting position overlap each other and are pressed against each other.

To this extent, it can be recommended according to the invention that the crossbars in their Initial position under tension in the direction of the assigned in the assembly position Crossbar of the opposite insulating web are to the desired To achieve contact pressure of the associated crossbars against each other.

Manufacturing and warehousing technology, it is particularly cheap if the two Insulating bars at least with regard to the arrangement of the cross bars on the inside of the chamber Boundary wall i. w. are identical.

According to the invention, it is recommended that the insulating webs be made of plastic, for example polyamide or Polyethylene terephthalate, to be produced with or without additional glass fiber content Reinforcement.

The crossbars can also be made of plastic, in particular polyamide or Polyethylene terephthalate, are produced and preferably molded onto the insulating webs his.

Alternatively, according to the invention, it is also possible to make the transverse webs from metal, preferably light metal, such as aluminum or an aluminum alloy, to manufacture.

According to a further proposal of the invention, the crossbars can also be made from one Hollow profile made of metal, in particular light metal, the hollow profile in seen a longitudinal section, one arranged between two outer plate elements has wavy spacer.

The metallic crossbars can be molded or molded into the plastic insulating bars Coextrusion may be appropriate.

It is also within the scope of the invention that the crossbars are infrared reflecting Have coating or a corresponding covering, so that the heat transfer in this area is reduced again.

With an insulating core, in which the ends of the insulating webs in the grooves Metal profiles are held, it is provided according to the invention that the insulating webs in Connection area are angled outwards at their insertion ends in the mounting position. This bridge shape of the insulating bars ensures their stability and hold in the Recording grooves significantly improved.

It is particularly advantageous if, according to one embodiment of the invention Insulating webs in the area between the bends have a reduced wall thickness. This further reduces the heat transfer between the insulating bars.

To use the same insulating cores or insulating bars with cross bars also with metal profiles To be able to use excess width, it is provided according to the invention that between the An adapter can be used for the transverse webs of the opposite insulating webs. The or the For example, adapters can be held at the ends of the crossbars by means of a snap-in connection his.

It is also within the scope of the invention that on the chamber outer boundary wall an insulating web at least one cross web, a rib, a wall extension or the like. Projection is formed, on which a seal arranged on the composite profile for Formation of a chamber comes to the plant. This is the thermal insulation of the Composite profile further improved.

Furthermore, especially with large profile cross sections, it can be according to the invention recommend that the transverse webs run approximately in the longitudinal direction of the insulating webs Wall sections are formed to reduce the convection flow in the or to improve the thermal insulation of the subchambers.

Further objects, advantages, features and possible uses of the present invention result from the following description of exemplary embodiments with reference to FIG Drawings.

Show it:

Fig. 1 shows a cross section of a composite profile with a sash and frame and

Fig. 2 shows a possible embodiment of an insulating web according to the invention with a cross bar.

The window frame according to FIG. 1 has a casement frame 23 with a pane 25 and a frame 24 fixed in the building soffit. Both the sash 23 and the frame 24 consist of a composite profile 2 , each with an outer metal profile 5 and an inner metal profile 6 . The outer and inner metal profiles 5 , 6 are connected to one another by means of plastic insulating webs 3 , 4 and are kept at a distance from one another to form chambers 9 , 10 , 11 . Cross webs 7 , 8 are arranged on the inner boundary walls of the insulating webs 3 , 4 , which overlap one another in the assembly position and are pressed against one another by a prestress. As a result, three closed partial chambers 9 , 10 , 11 are formed, as a result of which the heat transfer in the region of the insulating webs 3 , 4 is considerably reduced.

The design of the crossbars 7 , 8 also has the advantage that the same web elements can be used for different widths of the metal profiles 5 , 6 , which are then in contact position depending on the profile width with different lengths of the mutually assigned crossbars 7 , 8 . This has a favorable effect on the manufacture and storage of the web elements. For wide widths of the metal profiles 5 , 6 , it is possible to use an adapter (not shown) between the transverse webs 7 , 8 of the opposite insulating webs 4 , 5 .

The insulating webs 3 , 4 are held in receiving grooves 16 of the metal profiles 5 , 6 . As can be seen from Fig. 1, the insulating webs 3 , 4 are angled outwards in the connection area at their insertion ends 15 . In the wall section 18 extending between the bends 17 , the insulating webs 3 , 4 are reduced in their wall thickness. Due to the bends 17 of the insulating webs in the region of their insertion ends 15 , the stability of the insulating webs or the static securing of the composite profile 1 against tilting of the two metal profiles 5 , 6 is significantly improved. By reducing the wall thickness in the area between the bends 17 , the heat transfer in the area of the insulating core 1 is further reduced.

The transverse webs 7 , 8 , like preferably also the insulating webs 3 , 4, are made of plastic, in particular polyamide. But shown in FIG. 2, it is also possible that the transverse webs of a hollow profile made of metal, in particular aluminum or an aluminum alloy, are made with, seen in longitudinal section between two outer plate elements 12, 13 arranged wave-shaped spacing element 14. These cross bars 7 , 8 made of metal can, for example, be injection molded onto the insulating bars 3 , 4 made of plastic by coextrusion.

As can be seen from FIG. 2, particularly in the case of wide composite profiles, a wall section 31 extending in the longitudinal direction of the respective insulating web 3 or 4 , for example projecting into the partial chamber 10 according to FIG. 1, can be provided on at least one transverse web 7 or 8 to improve thermal insulation by reducing convection and heat radiation.

A further reduction in the heat transfer in the region of the insulating core 1 is the measure known per se of providing the crossbars 7 , 8 with an infrared-reflecting coating or a corresponding covering.

In the exemplary embodiment according to FIG. 1, webs 19 pointing outwards are formed on the insulating web 3 closest to the frame 24 , against which a center web seal 20 of the frame 24 with its sealing lip 27 bears in the closed position of the window. This creates additional chambers 21 , 22 , which likewise reduces heat transfer between the cold and warm zones of the composite profile 2 or the entire frame structure. In the same way, the sealing lug 30 of the glass-side seal 28 held in the glass strip 29 acts, which nestles against the outer boundary wall of the insulating web 4 and, with the formation of partial chambers between the metal profiles 5 , 6 and the glass strip 30, brings about thermal insulation. In addition, outer seals 26 can be attached to the outer metal profiles 5 of the sash 23 and the frame 24 .

Reference list

1 insulating core 2 composite profile
3 insulating web
4 insulating web
5 metal profile
6 metal profile
7 crossbar
8 crossbar
9 partial chamber
10 partial chamber
11 partial chamber
12 plate element
13 plate element
14 spacer
15 insertion ends
16 receiving groove
17 Angling
18 wall section
19 bridge
20 seal, center bar seal
21 chamber
22 chamber
23 casement
24 frames
25 disc
26 outer seal
27 sealing lip
28 seal inside the glass
29 glazing bead
30 sealing lug
31 wall section

Claims

1. Insulating core for a thermally insulated composite profile ( 2 ), in particular for windows, doors, facade structures or the like, with at least two insulating webs ( 3 , 4 ) made of heat-insulating material, which two metal profiles ( 5 , 6 ) of the composite profile ( 2 ) with each other Connect and keep a distance from each other to form a chamber, with transverse webs ( 7 , 8 ) projecting into the interior of the chamber being provided on the insulating webs ( 3 , 4 ), each insulating web ( 3 , 4 ) with an associated transverse web ( 7 , 8 ) as a single piece Component is formed and the crossbars ( 7 , 8 ) in the assembly position divide the chamber into at least two closed subchambers ( 9 , 10 , 11 ), characterized in that in the assembly position the crossbars ( 7 , 8 ) opposite insulating webs ( 3 , 4 ) accordingly the respective width of the metal profiles ( 5 , 6 ) overlap each other to a greater or lesser extent and are pressed against one another, so that the partial chambers ( 9 , 10 , 11 ) i w are sealed gas-tight against each other.

2. Insulating core according to claim 1, characterized in that the transverse webs ( 7 , 8 ) are in their initial position under tension in the direction of the transverse web assigned in the mounting position ( 8 or 7 ) of the opposite insulating web ( 4 or 3 ).

3. Insulating core according to one of the preceding claims, characterized in that the two insulating webs ( 3 , 4 ) at least with respect to the arrangement of the transverse webs ( 7 , 8 ) are of identical design.

4. Insulating core according to one of the preceding claims, characterized in that the crossbars ( 3 , 4 ) made of plastic, for example. Polyamide or polyethylene terephthalate, with or without glass fiber content.

5. Insulating core according to one of the preceding claims, characterized in that the transverse webs ( 7 , 8 ) made of plastic, for example. Polyamide or polyethylene terephthalate, and are preferably molded or molded onto the insulating webs ( 3 , 4 ).

6. Insulating core according to one of claims 1 to 3 or 5, characterized in that the transverse webs ( 7 , 8 ) consist of metal, preferably light metal, in particular aluminum or aluminum alloy.

7. Insulating core according to one of claims 1 to 4, characterized in that the transverse webs ( 7 , 8 ) consist of a hollow profile made of metal, preferably light metal, in particular aluminum or an aluminum alloy.

8. Insulating core according to claim 7, characterized in that the hollow profile has, in a longitudinal section, a corrugated spacer element ( 14 ) arranged between two outer plate elements ( 12, 13 ).

9. Insulating core according to one of claims 6 to 8, characterized in that the metallic transverse webs ( 7 , 8 ) in the insulating webs ( 3 , 4 ) are injection molded from plastic or attached by coextrusion.

10. Insulating core according to one or more of the preceding claims, characterized in that the transverse webs ( 7 , 8 ) have an infrared-reflective coating or covering.

11. Insulating core according to one of the preceding claims, characterized in that the insulating webs ( 3 , 4 ) in the connection area to their insertion ends ( 15 ) with respect to their mounting position on the metal profiles ( 5 , 6 ) are angled outwards.

12. Insulating core according to claim 11, characterized in that the insulating webs ( 3 , 4 ) in the wall section ( 18 ) between the bends ( 17 ) are reduced in their wall thickness.

13. Insulating core according to one of the preceding claims, characterized in that an adapter between the transverse webs ( 7 , 8 ) of the insulating webs ( 3 , 4 ) can be used.

14. Insulating core according to one of the preceding claims, characterized in that on the chamber outer wall of an insulating web ( 3 , 4 ), at least one transverse web ( 19 ), a rib, a wall extension or the like. A projection is formed, on which one at the Composite profile ( 2 ) arranged seal ( 20 ) to form chambers ( 20 , 21 ) comes to rest.

15. Insulating core according to one of the preceding claims, characterized in that on the transverse webs ( 7 , 8 ) approximately in the longitudinal direction of the insulating webs ( 3 , 4 ) extending wall sections ( 31 ) are formed.

16. Thermally insulated composite profile, in particular for windows, doors, facade constructions or the like, with at least one insulating core ( 1 ) according to one of claims 1 to 15.