GB2051193A - Frame Members for Windows and Other Panels - Google Patents

Abstract

A composite member for making up window frames and the like comprises interengaging metal (1) and plastics (6) portions with at least two spaced-apart pairs of interengaging hook formations (4, 8 and 5, 9) forced into tight engagement by the insertion of a wedging strip (10) the spacing apart of the formations ensuring stability against tilting. There are furthermore abutment surfaces (9a, 15) on at least one (9) of the hook formations on the plastics portion and on the metal portion to define accurately their relative positions. The purpose is primarily to ensure the front and back faces (3, 7) of the composite member are truly parallel and correctly spaced apart. <IMAGE>

Description

SPECIFICATION Frames for Windows and Other Panels This invention relates to frames, primarily for windows, although such frames may be applied also to other forms of panel used in building construction.

A known drawback of extruded aluminium alloy or other metal frames is their high thermal conductivity, the effect of which partially negates the value of using double glazing to restrict loss of heat. Frames made of extruded plastics material are known, especially in continental Europe, but in order to have adequate rigidity they have to be of relatively heavy section, making then expensive in terms of material cost, and anyway there can be a danger of distortion that may create problems when the corners are mitred.

Composite frames are also known, comprising inner and outer extruded metal sections separated by a so-called 'thermal break' in the form of a section of plastics material that is either bonded to the metal, or mechanically keyed to it, or both.

Finally, it is known to have simply two extrusions, one of plastics and one of metal, keyed together.

In both these composite forms of frame, the keying together of the rigid metal section and the less rigid plastics extrusion can be a problem and despite the use of relatively complex interlocking sections with various ribs, flanges and rebates, there is the danger that the frames may come apart, especially when subjected to the very rough handling that they may receive during delivery and erection.

In particular, proposals have been made involving hook-like projections on the metal section and on the extruded plastics sections, which interengage, and then the two parts are held together by the insertion of a series of spaced apart wedges held in by friction, or in some cases a single continuous wedge section held in place by screws. However, these known arrangements do not allow for any tolerances in the dimensions of the parts.

There are two important factors to be taken into account in practice in the assembly of rectangular frames from composite sections of combined metal and plastics section. In the formation of such frames, lengths of the composite section are cut to the required length, with mitred ends, and then joined together at the corners by special L-shaped connecting pieces. If the front and back surfaces of the composite section are not truly parallel the corner joint is distorted, so that the two sides of the rectangle that meet at that corner fail to lie in a common plane, and the whole frame takes on a twisted state. Secondly, if the front and back faces are, due to tolerance variations, not exactly the right distance apart, the result is likewise an overall distortion of the frame. These two factors are not adequately dealt with in the known constructions.

The aim of the invention is to provide a composite section for use in the formation of frames, which section takes the above-mentioned factors into account and ensures truly parallel and correctly spaced front and back faces despite possible tolerance variations in the metal and plastics section that go to make up the composite section.

According to the invention, in a composite section suitable for forming rectangular frames and made up of at least one rigid metal section and at least one less rigid plastics section mechanically keyed together by the use of interengaging hook formations on the two sections, in co-operation with wedging means to hold them together, there are at least two separate spaced-apart hook formations on each of the two interengaging sections, both hook formations facing in the sume direction and at least one of the hook formations is of tapering profile to provide a wedging action and at least one of the hook formations (it may be the same one) has an abutment surface engaging a cooperating abutment surface on the other section to define accurately the relative positions of the interengaging hook formations, the two spaced sets of hook formations being simultaneously locked in position by the insertion of a continuous wedge profile that is held locked in place by cooperation of its own shape with one of the sections.

By the provision of two spaced sets of hook formations we ensure that there can be no relative tilting of the metal section on the one hand and the plastics section on the other hand, so that their external faces remain truly parallel, and the provision of the abutment surfaces on one of the sets of hook formations ensured that those faces are the correct distance apart.

The invention will now be described by way of example with reference to the accompanying drawings, in which Figures 1 and 2 are crosssections through two examples of composite sections made in accordance with the invention.

Referring first to Figure 1, an extruded metal section 1 of aluminium alloy is basically in the form of a rectangular hollow box section but with an extended front flange 2 having a flat front face 3. On one side of the box section there are two Lshaped hook formations 4 and 5, widely spaced apart in a direction perpendicular to the plane of the face 3. Both hook formations point in the same direction, i.e. towards the face 3. One limb of each hook is parallel to that face and the other limb, which points towards it, has a rounded nose and has one side, 4a, 5a, perpendicular to the face 3 and the other side 4b, 5b inclined at 1 50 to that perpendicular. This inclined side has a step or shoulder, 4c, 5c, directed away from the face 3.

Co-operating with the metal section 1 is a section 6 of plastics material, preferably unplasticised PVC. It is of complex form, comprising two linked hollow box sections, and a flat face 7 which defines the rear face of the overall composite section that is formed by the sections 1 and 6. The section 6 has two spaced apart L-shaped hook formations 8 and 9, both facing in the same direction, i.e. towards the face 7, and co-operating respectively with the hook formations 4 and 5 on the metal section 1. The free limb 8a, 9a of each hook formation 8, 9 tapers towards its free end (for example with its inner face inclined at 50 to a line perpendicular to the face 7) and terminates in a rounded nose.

When the two sections 1 and 6 have been caused to interengage, with the hook formations 4 and 5 engaging the hook formations 8 and 9, a continuous resilient wedge section 10 of unplasticised PVC is forced into the gap between a face 1 1 on the back of the hook 9 and a face 12 on the inside of the front flange 2. A rebate 13 on the wedge section 10 engages under a shoulder defined by a head 14 on the flange 2, so as to hold the wedge permanently and virtually irremovably in place.

The insertion of the wedge 10 causes the respective hook formations to become tightly engaged and the lateral dimensions of the free limbs of the hooks 4 and 5 are such, in relation to the width of the channels defined by the free limbs of the hooks 8 and 9, that they distort these hooks 8 and 9 at least to some extent, and so ensure complete freedom from play in both sets of hook formations, despite possible tolerance variations in the plastics section or the metal section, or both. Moreover the nose of at least the hook 9 engages a face 15 on the one limb of the hook 5 to define the degree of engagement of the hook formations, the face 1 5 being in a plane parallel to the faces 3 and 7.

Thus the spacing apart of the pairs of hook formations, combined with the wedging action, ensures freedom from play or tilt between the sections 1 and 6, and so the faces 3 and 7 are truly parallel. Secondly, the abutment of the nose of the hook 9 against the face 15 on the hook 5 defines accurately the relative positions of the sections 1 and 6 in a direction perpendicular to the planes of the faces 3 and 7, and so the spacing apart of those faces, i.e. the overall frontto-back thickness of the composite section, is accurately determined. These two factors ensure that a frame built up from lengths of this composite section, is free from distortion and that its front and back faces are flat.

It will be understood that the flanges, undercuts and rebates that are visible in Figure 1 but have not been described are for the purpose of receiving glazing, and other mounting and sealing strips, not shown.

Figure 2 illustrates a symmetrical composite section, suitable for forming mullions within a rectangular frame made from the section of Figure 1. An aluminium alloy extrusion 16 comprises a box section with a front face 17, and with two hook formations 18 and 19, spaced apart and lying on opposite sides of the box but both pointing towards the plane of the face 17.

An extrusion 20 of unplasticised PVC is based on a combination of two back-to-back mirror image versions of the extrusion 6 of Figure 1, but with one hook formation from each omitted, so there is a total of only two hook formations 21 and 22, co-operating respectively with the hook formations 18 and 19 of the section 16. The plastics extrusion has a flat rear face 23. The wedge section 10 that holds the two extrusions together is substantially the same as that of Figure 1 but in this case two lengths of this wedge sections are used. In the version of Figure 2 there are shallow beads 24 and 25 on the plastics extrusion to engage the backs of the hook formations 18 and 19. These beads help to define accurately the effective widths of the channels which the hooks 18 and 19 enter, and ensure that they become wedged, distorting the plastics and free from play. Like the hook 9, the nose of each hook 21 and 22 engages an abutment face 26 and 27 on the co-operating hook of the metal section to define accurately the spacing between the faces 17 and 23. The parallelism of these faces is ensured by the wide lateral spacing of the two pairs of co-operating hookformations, in combination with their wedging action.

Additional stability is provided by beads 28 and 29 on the plastics section, engaging opposite sides of the inner end of the metal section 16.

Claims (10)

Claims

1. A composite section suitable for forming rectangular frames and made up of at least one rigid metal section and at least one less rigid plastics section mechanically keyed together by the use of interengaging hook formations on the two sections, in co-operation with wedging means to hold them together, in which there are at least two separate spaced-apart hook formations on each of the two interengaging sections, both hook formations facing in the same direction and at least one of the hook formations is of tapering profile to provide a wedging action and at least one of the hook formations (it may be the same one) has an abutment surface engaging a co-operating abutment surface on the other section to define accurately the relative positions of the interengaging hook formations, the two spaced sets of hook formations being simultaneously locked in position by the insertion of a continuous wedge profile that is held locked in place by co-operation of its own shape with one of the sections.

2. A composite section according to claim 1 in which the rigid metal section and the plastics section have respective mutually parallel faces, and in which the hook formations point in a direction perpendicular to the planes of these faces.

3. A composite section according to claim 2 in which the two sets of hook formations are spaced apart in a direction perpendicular to the planes of the faces.

4. A composite section according to claim 2 in which the two sets of hook formations are spaced apart in a direction parallel to the planes of the faces.

5. A composite section according to claim 6 including a second wedge profile, one wedge profile being adjacent to each of the pairs of hook formations.

6. A composite section according to claim 4 or claim 5 including abutment beads on the plastics section, abutting against the metal section at points spaced away from the pairs of hook formations in a direction perpendicular to the planes of the faces.

7. A composite section according to any one of claims 1 to 6 in which at least one of the hook formations on the metal section has an undercut step.

8. A composite section according to any one of claims 1 to 7 in which the said abutment surfaces comprise respectively a nose on the free end of one of the hook formations on the plastics section and a flat abutment surface, extending perpendicular to the direction in which the hook formations point, on the co-operating hook formation on the metal section.

9. A composite section suitable for forming rectangular frames substantially as described with reference to Figure 1 of the accompanying drawings.

10. A composite section suitable for forming rectangular frames substantially as described with reference to Figure 2 of the accompanying drawings.