DE8900041U1 - Block for fixing glass panes or similar in door or window frames - Google Patents

Description

DR.-ING. DIPL-PHYS. H. STURIES PATENT ATTORNEYS

DIPL-ING. P. EICHLER

Hans Dieter Niemann, Am Hügel 17, 5014 Kerpen-Horrem

Block for fixing glass panes or similar in door— or Window frame

The invention relates to a block for securing glass panes or the like in door or window frames, with a supporting part that can be secured to the frame and with a spacer arranged thereon that supports the glass pane.

Such a block is known from DE-GM 86 29 093. Its carrier part is firmly connected to the frame at the factory. This carrier part is positively engaged with the spacer on the narrow edges of both to prevent longitudinal displacement. This ensures that the spacer on the carrier part cannot slip or even fall out completely.

However, such blocks are also used when the glass panes or similar are very large in size.

PO Box 20 12 42 TELEPHONE (0202) 62 17 95 Pottglroamt Cologne Deutsche Bank Wuppertal B?«hüis«»rsS« 29 TBlJOt 5591 !72 «ep« d (BLZ 370 100 50) (BLZ 330 7QQ 90)

5600 WupjMrtal2 FAX (0202) 62 17*96 ACCOUNT NO. 1608 23-502 ACCOUNT NO! 8*871 675

In such cases, larger relative movements can occur between the glass panes and the frame parts, which can be attributed, for example, to greater thermal expansion, comparatively large instability of the frame construction or higher stresses due to wind pressure or adjustment of the sash frame.

The invention is therefore based on the object of improving a block of the type mentioned at the outset in such a way that its spacer, in conjunction with the support part, is able to control larger relative movements between the glass pane and the frame.

This task is solved by the spacer being assembled with the support part so that it can move longitudinally and/or to a limited extent transversely.

It is important for the invention that the spacer and the support part are assembled so that they are relatively movable. A block of this type therefore creates a point of relative movement between the pane of glass and the window frame, so that the block is designed and used in a completely new way for its components. The longitudinal mobility between the spacer and the support part allows for greater length expansions of the frame parts, for example due to temperature fluctuations, to be taken into account. The limited transverse mobility means that, for example, the components involved can be twisted without mechanical stresses being transferred from the frame to the pane of glass, for example. The risk of glass breakage is therefore practically eliminated.

The block is advantageously designed in such a way that the spacer has sliding projections on its outer surface facing the carrier part and the carrier part has a smooth support surface supporting the sliding projections, or vice versa. One of the two block components, i.e. either the spacer or the carrier part, has sliding projections that are supported on a smooth support surface of the other component. Sliding projections and

The support surface together form a sliding pair, the resistance of which during relative movements of the two components of the block can be influenced to the desired extent by shaping. If the material is selected in such a way that the material for the sliding projections is primarily tailored to load-bearing capacity and the soft material for the smooth support surface is primarily tailored to optimal sliding behavior, then a further optimization or reduction of the resistance during relative movements of the block parts can be achieved.

In the above sense, it is particularly advantageous that the sliding projections are spherical caps evenly distributed over the outer surface facing the other block part at the same distance from neighboring sliding projections. This results in a dense distribution of the sliding projections on an outer surface or on the underside of the support part with the greatest possible support capacity for a maximum permissible specific load depending on the choice of material.

It is advantageous if the spacer is T-shaped and its roof legs overlap or rest on the U-shaped projections of the support part with a small vertical distance. The result is an overall cuboid-shaped block, which is conventional in this respect and can be used in the conventional way at the required points between the frame and the pane by appropriate dimensioning. In particular, the T-shape of the spacer makes it possible to use practically the entire width of the support part to support the glass pane.

In an embodiment of the invention, between the roof legs of the spacer and the U-shaped projections of the support part, there is an outwardly sloping slot, which, if required, has an extension channel parallel to the leg. ^ The outwardly sloping slot ensures that rainwater or condensate that penetrates through leaky seals on the long sides of the block cannot get between the two block parts. The formation of the outwardly sloping slot is particularly important when

Significance if the U-shaped support part protrudes slightly transversely to the block's longitudinal axis, namely approximately corresponding to the transverse play that must be present to limit transverse mobility between the spacer and the support part. If the slot is so narrow that there is a risk of liquid penetrating the slot as a result of capillary action, it is advisable to install an expansion channel parallel to the leg, which excludes capillary action.

The invention is further explained using an embodiment shown in the drawing. It shows:

Fig. 1 is a perspective view of one end of a lower window frame spar with a glass pane supported by a block,

Fig. 2 is an enlarged view of a block corresponding to Fig. 1,

Fig. 3 is a view of the spacer of Fig. 2 in direction A,

Fig. 4 shows detail D of Fig. 2 in an enlarged view, and

Fig. 5 is a front view similar to Fig.2.

In Fig. 1, a frame profile 10 is shown, namely the frame profile of a lower window frame beam, which carries an insulating glass pane 11, which is supported vertically on a profile wall or on a groove base 13 via a block 12. A profile strip 14 on one side of the insulating glass pane 11 and a glass retaining strip 15 on the other side of the insulating glass pane 11 serve to hold the glass pane 11 laterally. The glass retaining strip 15 is locked into the profile wall 10' of the window frame 10 with a connecting rib 16. The insulating glass pane 11 is sealed laterally using elastic sealing strips 17, which are attached to the profile strip 14 and the glass retaining strip 15 via connecting ribs 18 by locking into corresponding connecting grooves.

Despite the sealing strips 17, condensation can occur in the space between the insulating glass pane 11 and the window frame 10 below the sealing strips 17, or accumulation of leakage water due to defective or incorrectly installed sealing strips 17. Drainage holes 19 are therefore provided in the frame 10, which allow the water to be drained from the groove base 13 that collects the accumulating water. It goes without saying that the supporting block 12 must be newly formed so that the accumulating water can flow to the drainage holes 19 on the groove base 13. For this purpose, the block is designed in the conventional manner as a block bridge, i.e. with a longitudinal flow.

The block 12 consists of two parts, namely a spacer 21 for supporting the glass pane 11 and a support part 20 for supporting the spacer 21 on the groove base 13. The support part 20 is a U-shaped body which extends in the groove shown in Fig. 1 or on a profile wall of a frame profile in the longitudinal direction, e.g. 10 cm. It rests with its bottom surface 29 on the groove base 13. Fastening to the frame 10 is possible in a conventional manner, for example by clamping or gluing. On the longitudinal edges of the support part 20 there are vertical projections 25 which are strip-shaped, so that the support part 20 is consequently U-shaped. Between the U-projections 25 the support part 20 has a smooth support surface 23 for supporting the spacer 21.

The space between the U-shaped projections 25 and the support surface 23 is essentially filled by the spacer 21, which rests on the support surface 23. Sliding projections 24 serve to provide support, so that a point-shaped or small-area contact surface is created between each sliding projection 24 and the support surface 23. This small area of the contact surface or all contact surfaces between the spacer 21 and the support part 20 results in a correspondingly low resistance to movement between the two block parts. It must be ensured that a permissible surface pressure in the area of the contact surfaces is not exceeded.

This is done by selecting suitable materials for the Xlotz parts.

Fig. 3 shows the distribution of a plurality of sliding projections 24 on the outer surface 22 of the spacer 21 facing the carrier part 20. Each sliding projection 24 is arranged at the same distance from its neighboring sliding projections. This distance tends to be

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evenly distributed over the outer surface 22. As a result, a dense packing or arrangement of the sliding projections 24 occurs, which are designed as spherical caps as shown in Fig. 2. The spherical cap-shaped design of the sliding projections 24 has the advantage that the resistance to movement is the same in all directions of movement of the steerable relative movements between the carrier part 20 and the spacer 21.

It is understood that the spacer 21 and its carrier part 20 are relatively movable in the longitudinal direction and can also be so to a large extent. In this case, it is usually sufficient if both parts are the same length; however, it is also possible to make the lower block part, i.e. the carrier part 20, longer so that, for example, the row of sliding projections on the front side does not remain unsupported in the event of a larger longitudinal displacement of the spacer 21.

The transverse mobility of the spacer 21 is determined by the fact that its width b between the U-projections 25 is slightly smaller than the distance a between the legs of these U-projections. The difference between the above dimensions is the play of movement that the block 12 can provide to compensate for relative movements transversely between the glass pane 11 and the frame 10.

The spacer 21 is T-shaped and its roof legs 26 overlap the projections 25 of the support part 20. Between the underside of the support part 20 or the roof legs 26 and the projections 25 or their front

surface 30 is a slot 27 corresponding to the distance c. The distance c is so small that a contact-free relative movement between the spacer and the support part 20 can usually take place in this area. On the other hand, this distance c or the slot 27 is not large enough to not be able to serve as additional support in an emergency, namely if the glass pane 11 is supported with a pane plate directly above the roof leg 26, if this roof leg 26 is not designed for the load described above,

In Fig. 4, detail D is shown enlarged and shows the design of the slot 27. It can be seen that the U-shaped projection 25 projects further horizontally than the roof leg 26, so that the aforementioned projection 30 is created. If water collects here, there is a risk that it will get through the slot 27 into the area between the spacer 21 and the support part 20, which is undesirable because it affects the sliding resistance between the two block parts and because of the soiling effect. De: Slot 27 is therefore designed to slope outwards, which counteracts the penetration of water. However, since the slot 27 is only small and bending of the roof leg 26, e.g. under excessive load from the glass pane 11, cannot be ruled out, capillary action must be expected, so that the risk of water penetrating even through a very narrow gap is to be feared. As a result, an expansion groove 28 is present, which expands the slot 27 and thus interrupts the capillary effect

The material of the spacer 21 can be, for example, a polyamide, which is processed into its final form by injection molding. The carrier part 20 is, for example, a polyoxymethylene, which is characterized by a low coefficient of friction in addition to good mechanical properties.

Instead of a spacer 21 with a specific height, spacers with different desired heights can be used.

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the, e.g. in order to be able to take into account distances that deviate from those expected due to tolerances.

Fig.5 shows a spacer 21 in a front view, which is plate-shaped and has a projection 25 in the middle on its long and long sides, for example a circular pin. The spacer 21, which can also be considered T-shaped in the broader sense, is supported with its roof legs 26 on U-projections 25 of a support part 20 and its projection 25 engages in a recess 31 of this support part 20. The recess 31 is dimensioned so large that play 32 is present. As a result, the spacer 21 can move to the right and left in the plane of the illustration, i.e. can move transversely to the support part 20. Since the recess 31 is circular in accordance with the cross section of the projection 25, there is equal relative mobility in all directions of a plane perpendicular to the plane of the illustration. If, however, the recess 31 is designed as a slot that extends perpendicular to the plane of the illustration, the mobility of the spacer is determined by the dimensioning of this slot, thus achieving greater longitudinal mobility of the spacer relative to the carrier part 20.

The support of the spacer 21 on the carrier part 20 or its projections 25 can be carried out via domes corresponding to Figures 2, 3 and the limitations of the mobility of the carrier part 20 in the middle of the central projection 25 described for Figure 5 can also be used in the embodiments of Figures 2, 3. In the case of Figure 5, however, there is the advantage that there is a cavity 33 between the spacer 21 and the carrier part 20 through which air and/or water can flow, so that the block does not hinder the ventilation between the frame and the pane.

All blocks shown in the figures can also be designed in the form of a block bridge. In this case, the support part 20 has parallel webs supported on the groove base 13 and running in the longitudinal direction of the groove, which

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Claims (8)

DR.-ING. DIPL-PHYS. H. STURIES ; PATENT ATTORNEYS DiPL-ING. P. EiCHLER Claims 1. Block for securing glass panes or the like in door or window frames, with a support part that can be secured to the frame and with a spacer piece arranged thereon that supports the glass pane, characterized in that the spacer piece (21) is assembled with the support part (20) so that it can move longitudinally and/or to a limited extent transversely. 2. Block according to claim 1, characterized in that the spacer (21) has sliding projections (24) on its outer surface (22) facing the carrier part (20) and the carrier part (20) has a smooth support surface (23) supporting the sliding projections (24), or vice versa. 3. Block according to claim 2, characterized in that the sliding projections (24) are spherical caps distributed at the same distance from adjacent sliding projections evenly over the outer surface (22) facing the other block part (support part 20). 4. Kloti. according to one or more of claims 1 to 3, characterized in that the limitation of the transverse mobility of the spacer < 21) is achieved by means of at least one vertical projection (25) of the carrier part (20) or of the spacer (21). PO Box 20 12 42 TELEPHONE (0202) 62 17 95 Postgiroamt Köln Deutsche Bank Wuppertal BrahmsstraB« 29 TELEX 8 591 172 wp»d (bank code 370 100 50) (bank code 330 700 90) Wuppertal 2 FAX (0202) 62 17 i>6 ACCOUNT NO. 1608 23-502 ACCOUNT NO. 8 871 675 5. Block according to one of claims 1 to 4, characterized in that the projection (25) limiting the transverse movement of the spacer (21) is a pin of the spacer (21) which engages with play (32) in a recess (31) profiled according to its cross section or in a longitudinal slot of the carrier part (20) provided with transverse play. 6. Block according to one of claims 1 to 5, characterized gGrvGnn ZS xCiiHG u, uaij tj33 &khgr; l?c3yGl?LG il \ c \j) \j ~ shaped and has a leg spacing (a) which exceeds the width (b) of the spacer (21) present between the U-legs as projections (25) limiting the transverse mobility of the spacer (21). 7. Block according to one of claims 1 to 6, characterized in that the spacer (21) is T-shaped and its roof legs (26) overlap or rest on the U-projections (25) of the support part (20) with a small vertical distance (c). 8. Block according to claim 7, characterized in that between the roof legs '26' of the spacer (21) and the U-projections (25) of the support part (20) there is an outwardly sloping slot (27) which, if required, has an extension groove (28) parallel to the leg.