DE29613519U1 - Spacers and connectors for insulating glass panes - Google Patents

Abstract

This invention concerns an insertable connecting element (1) which has a small and thin-walled stop (12) at the connection point (5) which has sides (13) which are parallel or at an acute angle. The stop (12) inserts fully into the profile face walls (6) upon pushing the profiles (3, 4) together, so that the side walls (6) tightly abut above the stop (12). With regard to the stop (12), the connecting element (1) has a tolerance compensator (16) which allows the guidance of the lateral walls (10) into the hollow profiles (3, 4) without vertical play.

Description

Spacers and connectors for insulating glass panes

The invention relates to a spacer and a connector for insulating glass panes with the features in the preamble of the main claim.

A straight connector for spacers of insulating glass panes is known from DE-82 27 371 Ul and DE-32 36 110 Al, which is designed as a punched and bent part made of sheet steel with a U-shaped cross-section. The side webs have wide triangular stops for the hollow profiles on the lower edge in the area of the connection point. The stops have flanks on both sides with a large flank angle of significantly more than 90°. The flanks therefore serve as starting bevels on which the attached hollow profiles should run without digging in. Due to the wedge effect of the starting bevels, the connector, which is guided with vertical play, is pushed upwards in the hollow profiles and pressed against the restoring force of spring tongues. The spring tension in turn presses the stops back into the connection point, which can drive the hollow profiles apart. In an alternative design, the hollow profiles have prepared lateral grooves to accommodate the stops. Here, too, the aforementioned sliding occurs. This arrangement requires machining of the hollow profiles, which is costly and time-consuming and is not compatible with automated production of spacers.

Another straight connector is known from DE-94 11 067 Ul, which also has rigid, wide stops with slanted flanks, which partly function as starting bevels like the previously mentioned state of the art and are intended to absorb the height play by sliding on.

EP-O 283 689 Al and DE-90 16 592 Ul disclose alternative designs of connectors made of metal and plastic, which have spring-loaded stops, which elastically deflect when the hollow profiles are pushed on and disappear into the profile interior.

From DE-94 12 570 Ul, DE-38 06 845 Al and EP-133 655 Al, connectors with rigid stops in the form of cylindrical knobs or transverse circumferential webs are also known, against which the hollow profiles abut with their end walls. The stops therefore distance the hollow profiles at the connection point and leave an undesirable gap there.

DE-92 16 955 Ul shows another connector that has a U-shape with angled side bars, whereby spring-loaded terminal strips are arranged on the side bars. In the middle there are wedge-shaped stop lugs that act on one side, against which the hollow profiles abut on the front side.

30

It is the object of the present invention to provide a better possibility for tightly connecting the hollow profiles at the connection point.

The invention solves this problem with the features in the preamble of the two independent claims. The invention has the advantage that the complete

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By digging in the small stops on the profile end walls, a completely tight connection of the profile end walls can be achieved without having to accept any other negative effects.

Due to the parallel or acute-angled flanks and their thin walls, the correspondingly narrow stops can dig particularly well into the profile end walls. In contrast to the previously known wide-angled stops

Î and the run-on slopes, no noticeable restoring forces are created during digging. The strain hardening in the hollow profile material is less. The hollow profiles remain close to one another.

(Continued on page 3 of the original description)

To facilitate complete burying of the stops, it is recommended to make them as small as possible, i.e. particularly narrow and short. In addition, other measures can support the burying.

A height-play-free guide for the connector in the hollow profiles, which preferably fixes the connector side walls, has the advantage that the stops can be very small and still come into safe contact with the profile end walls. They cannot be pushed over when the hollow profiles are plugged in.

In the design according to the invention, the stops do not have to compensate for the height tolerances of the connector in the hollow profiles. Instead, the connector can be guided without any height play via a separate tolerance compensation on the side walls. This also prevents the development of unfavorable restoring forces on the connection point. The connector is guided safely and firmly in the hollow profiles.

Thanks to its solid side walls in the area of the connection point, it is particularly resistant to bending and deformation in this heavily loaded area. The tolerance compensation can also improve the inherent stability of the connector. Notch effects in this area are largely avoided. On the other hand, the high structural strength and bending load capacity allow the wall thickness of the connector to be reduced and costs to be saved.

A two-sided free cut on the stop flanks is also beneficial. The hollow profiles therefore come into contact primarily with the middle and upper area of the stop flank. This is more advantageous for cutting into the profile front wall and avoiding restoring forces than starting at the flank root, which is

its rounding at the transition to the edge of the side wall would encourage the less desirable sliding.

For the design, function and cost-effectiveness of the connector, it is advantageous to manufacture it from metal, especially steel. The metal stops dig in easier and better than plastic stops.

The smaller the stops, the more important the dimensional accuracy of the connector is. For this purpose, it is advisable to provide a centering device that ensures precise bending of the connector and uniform dimensions of the side walls and stops. The smaller the bending tolerances, the smaller the stops can be, while still being functionally reliable.

In a metallic version, it is advantageous to manufacture the connector from a pre-finished material that does not require any subsequent post-treatment. This ensures that the tiny stops retain their shape and are not broken off or otherwise deformed during post-treatment. During pre-treatment, the metal, in particular a so-called cold-rolled steel strip, is preferably made rust-proof. This can be done by galvanizing and/or chromating before punching and bending the material. There is no need for subsequent tempering or other post-treatment of the connectors. This reduces tolerance problems and the number of control dimensions, which ultimately also results in more cost-effective production.

Further advantageous embodiments of the invention are specified in the subclaims.

The invention is illustrated by way of example and schematically in the drawings. In detail:

Figure 1 and 2

a connector in bottom view and folded side view,

10

Figure 3

an enlarged view of the middle section of the connector of Figure 2 with the stop,

Figure 4

a front view of the connector according to arrow IV of Figure 1,

15 Figure 5

a spacer with inserted connector in broken and cut side view according to Figure 2 and

20

Figure 6

a sectional front view of the connector of Figure 5 at the connection point.

Figures 1 to 4 show a straight connector (1) for use in the spacer (2) for insulating glass panes shown in Figures 5 and 6. The spacer (2) consists of one or more curved and/or straight hollow profiles (3, 4) which are butt-jointed at the connection point (5) and are held together by the straight connector (1) inserted there.

The connector (1) is preferably made as a stamped and bent part from metal, in particular from sheet steel. It has a substantially U-shaped cross-section and is preferably open at the end faces (21). This allows the

Granulated drying agents located in hollow profiles (3,4) flow through the inner cavity (22) of the connector (1) over the connection point (5).

The connector (1) preferably has two rigid stops (12) in the middle, which are at the same height and act on both sides. The stops (12) are arranged on the edges (11) of the side walls (10) of the connector (1) and protrude beyond them. The stops (12) are in the wall plane and have the small wall thickness of the side walls (10), which is less than 1 mm and in the preferred embodiment is approximately 0.5 mm.

The stops (12) have a substantially triangular shape with oblique flanks (13) which have an acute flank angle α of less than 90°, preferably 'approx. 45°. At the tips, the stops can

(12) be rounded.

In an alternative embodiment, the flanks

(13) can also be straight and parallel. They are then at right angles to the longitudinal axis of the connector (20).

In this case the flank angle α is 0°. 25

As Figure 3 in particular shows in detail, the rigid stops (12) are very small. At the height of the side wall edges (11) they have a width (b) of less than 0.5 mm, preferably about 0.3 to 0.15 mm. Their height (h) is also less than 0.5 mm, preferably 0.3 mm or less.

In the embodiment shown in Figure 3, the edges (11) of the side walls (10) on both sides of the stops (12) can have cutouts or recesses (14) into which the flanks (13) run with a notch-favorable rounding. The stop height (h) can in this case

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from the base of the cutouts (14). In the embodiment shown, the cutouts (14) protrude approx. 0.15 mm from the side wall edges (11). As a result, the tips of the stops (12) protrude 0.15 mm beyond the edges (11) at a stop height (h) of 0.3 mm. This protrusion can be approximately in the order of magnitude of the tolerance range of the hollow profile dimensions.

The connector (1) has a tolerance compensation (16) at the connection point (5) opposite the stops (12). It serves to guide the connector (1) in the hollow profiles (3, 4) precisely and without any vertical play, at least in the area of the connection point (5). The guide preferably acts on the side walls (10). This ensures that the edges (11) of the side walls (10) rest against the facing hollow profile inner wall (8) and the tiny stops (12) come into secure contact with the end walls (6) of the hollow profiles (3, 4) and cannot be pushed over.

The tolerance compensation (16) can be designed in any suitable way, e.g. as a cut-out and bent spring nose(s) on the middle wall (9). In the preferred embodiment shown in detail in Figure 3, the tolerance compensation (16) can consist of hump-like run-on bevels (16) on both sides, which are designed as a bend or bulge on the middle wall (9) and/or on the adjacent edges or edge beads (18) of the side walls (10). The bent run-on bevels (16) also have the effect of strengthening the connector (1) and stabilizing it by increasing the bending cross-section. The bends also have the advantage that there are no cuts on the middle or side walls (10, 9) at the connection point (5) and thus no wall weakening or notch effects.

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available.

The apex is located at the connection point (5), whereby the width of the run-on bevels (16) is several millimetres, e.g.

approx. 10 mm. The hollow profiles (3,4) slide on the run-on slopes (16). This takes up the internal dimension tolerances of the hollow profiles (3,4) and the connector (1) is guided in the hollow profiles (3,4) free of height play, at least in the area of the connection point (5). The height of the tolerance compensation or the run-on slopes (16) is a few tenths of a millimeter, e.g. 0.15 mm.

The stops (12) serve to limit the depth of insertion of the connector (1) into the hollow profiles (3,4) when plugging it in and for centering in the hollow profiles (3,4). As Figures 5 and 6 show, the hollow profiles (3,4) are pushed simultaneously or one after the other from the end faces (21) onto the connector (1) and meet at the connection point (5) in the middle of the connector.

The rigid stops (12) dig into the end walls (6) of the hollow profiles (3,4), which is facilitated by the tiny size and thin walls of the stops (12) as well as the steep flank shape. Sliding is preferably prevented in favor of digging in. The stop height (h) is smaller than the wall thickness of the hollow profiles, which also supports digging in. The stops (12) are completely immersed in the end walls (6). This means that the hollow profiles (3,4) or the end walls (6) can fit tightly together at the connection point (5).

The precise guidance of the connector (1) without any play in height is advantageous in order to prevent the stops (12) from running into each other and sliding over. It also ensures that

» ♦·■* *« * · StT* 1

that the hollow profiles {3,4) meet exactly and are flush with one another without offset, tilting or twisting. The flat design means that the connection point (5) is sealed so that no drying agent can escape and sealing problems when filling the insulating glass panes with insulating glass are avoided.

The connector (1) can otherwise be designed in any way. In the embodiment shown, the middle wall (9) is essentially solid and has no wall openings. For stabilization and improved positioning in the hollow profiles (3, 4), it can have flat projections (17) with an essentially cuboid shape in places. In the embodiment shown, there are three projections (17) evenly distributed over the length, the middle one of which is arranged at the connection point (5) and can be designed as a run-on slope (16).

&igr; ■ The base (19) of the central wall (9) is lowered between the projections {17). The projections (17) are flush with the longitudinal edge beads (18) at the transition of the central wall (9) into the side walls (10).

As a result, they lie tightly against the facing inner profile wall (7). Between the projections (17) and the edge beads (18) there can be a longitudinal groove for receiving rows of perforations on the hollow profiles (3, 4) as shown in Fig. 6.

The connector (1) designed as a punched and bent part does not have a centering device (23) for the exact bending of the U-shape. As a result, the side walls (10) and their stops (12) are the same height. The centering device (23) can be designed in any suitable manner. In the embodiment shown, it is two axially centered punched-out

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Centering holes (23) on the connector ends, through which locating pins grip during bending and center the board and guide it in a form-fitting manner relative to the bending tool. The centering holes (23) are preferably located on projections (17).

The retention of the connector (1) in the hollow profiles (3, 4) can be ensured in various ways. In the preferred embodiment, retaining elements (15) are located on both sides and at a distance from the connection point (5) on the side walls (10). These can be, for example, spring noses that are cut free and angled downwards and outwards. The retaining elements (15) can also be designed completely differently, e.g. as spring noses that are flared out on the middle wall (9), corrugations, etc. It is also possible to secure the position by caulking the walls, in which the hollow profile walls are deformed from the outside into corresponding recesses on the middle wall (9) and/or the side walls (10). This creates a positive engagement.

The cross-sectional design and dimensions of the connector (1) are adapted to the interior of the hollow profiles (3, 4). As Figure 6 shows, it is preferably installed in a position in which its middle wall (9) rests against the profile base (7). The profile base (7) is located on the inner wall of the spacer (2) and faces the interior between the insulating glass panes (not shown). The side walls (10) face the profile roof (8) and can be slightly angled in order to press themselves against the profile side walls in a spring-loaded manner. For precise height guidance of the connector (1) over the side walls

(10) it is advantageous to fold the profile roof (8) and to support the side walls (10) on a horizontally projecting attachment to the outside.

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The connector (1) consists of a pre-treated or pre-finished material. The pre-treatment can, for example, serve to protect against corrosion, in particular rust, and can consist of galvanizing and/or chromating. Low-carbon steels, e.g. STK2, are suitable as base materials. The so-called cold strip pre-treated in this way is then punched and bent into the required shape during connector production. The pre-treatment means that the connector (1) does not need to be reworked or treated. This means that subsequent tempering or the like is not necessary. The connector (1) is ready for use after punching and bending. This is particularly beneficial for the small and sensitive stops (12).

The embodiment shown can be modified in various ways. Instead of a U-shape, the connector (1) can also have a completely or partially closed box shape. The stops (12) can also be located elsewhere. Their number can also vary. The tolerance compensation (16) can be implemented in a different way or can be omitted. The same applies to the cutouts (14). Closed front sides (21) of the connector (1) are possible. The choice of material, e.g. plastic, and the type of pretreatment can also be varied.

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LIST OF REFERENCE SYMBOLS

1 connector

2 Spacers 3 Hollow profile

4 Hollow profile

5 Connection point, joint

6 Front wall

7 Profile floor 8 Profile roof

9 Middle wall

10 Side wall

11 Edge, bottom edge

12 Stop 13 Flank

14 Free cut, recess

15 Retaining element, spring nose

16 Tolerance compensation, starting bevel

17 projection 20■ 18 edge bead

19 Floor

20 Connector longitudinal axis

21 Front side

22 Cavity

23 Centering device, centering hole

α flank angle

b Stop width

h Stop height

Claims (13)

- 13 CLAIMS FOR PROTECTION 1.) Spacer for insulating glass panes, consisting of one or more hollow profiles (3,4) with a straight connector (1) inserted at the connection point (5), which is guided in the hollow profile(s) (3,4) and has at least one small, thin-walled, rigid and double-acting stop (12) with parallel or acute-angled flanks (13), whereby the end walls (6) of the hollow profile(s) (3,4) meet tightly at the connection point (5) above the stop (12) and the stop (12) is completely buried in the end walls (6). 2.) Spacer according to claim 1, characterized in that the connector (1) is guided via its side walls (10) with a tolerance compensation (16) in the hollow profile(s) (3,4) without any vertical play. 3.) Straight connector for spacers of insulating glass panes, with at least one protruding, rigid and bilaterally acting stop for the end walls of one or more hollow profiles at the connection point, characterized in that the stop (12) is small, thin-walled and designed with parallel or acute-angled flanks (13) for complete digging into the profile end walls (6). 4.) Connector according to claim 3, characterized in that the connector (1) has a tolerance compensation (16) relative to the stop (12) for the height-free guidance of the side walls (10) in the hollow profile(s) - 14 (3.4)
having. 5.) Connector according to claim 3 or 4, characterized in that the flanks (13) "■■ have a flank angle α between 0° and 60°. 6.) Connector according to claim 3, 4 or 5, characterized in that the stop (12) has a width (b) and a height (h) of less than 0.3 mm each, preferably of approximately 0.15-0.25 mm. 7.) Connector according to claim 3 or one of the following, characterized in that the stop (12) has cutouts (14) on both sides in the foot area. 8.) Connector according to claim 3 or one of the following, characterized in that the connector (1) has a substantially U-shaped cross-section, with a stop (12) protruding in the wall plane being arranged at the same height on the edges (11) of the side walls (10). 9.) Connector according to claim 3 or one of the following, characterized in that the tolerance compensation (16) is designed as hump-like starting slopes (16) on the side walls (10) and/or the middle wall (9) of the connector (1). 10.) Connector according to claim 3 or one of the following, characterized in that the middle wall (9) has longitudinal edge beads (18) on both sides and a lowered base (19) relative to them, with one or more 15 - several flat projections (17) are arranged at the level of the edge beads (18). 11.) Connector according to claim 3 or one of the following, characterized in that the connector (1) designed as a stamped and bent part consists of a rust-proof pre-finished metal. 12.) Connector according to claim 11, characterized in that the connector (1) consists of a pre-galvanized and pre-chromated cold-rolled steel strip. 13.) Connector according to claim 3 or one of the following, characterized in that the connector (1) has a centering device (23) for precise bending.