DE202023100415U1 - Corner connector with expansion element - Google Patents

Abstract

Corner connector for connecting two hollow chamber profiles of windows, doors or the like, which are cut to a miter and preferably consist of weldable plastic, the corner connector (1) having:
- a shaft part (2) for insertion into one of the hollow chamber profiles (56), which extends along a longitudinal axis (16) defining an axial direction (12) and has two longitudinal sides (52, 54) and two cover sides (26, 28), a wedge structure (50) being formed on at least one of the longitudinal sides,
- an expanding element (6) for arranging between at least the longitudinal side and the hollow chamber profile (56), the expanding element (6) having a counter wedge structure (48) which interacts with the wedge structure in such a way that the expanding element (6) is displaced on the longitudinal side pushes the spreading element (6) outwards transversely to the longitudinal side and thus braces the shaft part (2) transversely to the longitudinal sides (52, 54) in the hollow chamber profile (56), and
- a clamping body (4) which can be displaced axially on the shaft part (2) and is designed in such a way that the axial displacement of the clamping body (4) displaces the expansion element (6) on the longitudinal side, characterized in that
- The clamping body (4) takes the expansion element (6) in the axial direction (12) during its axial displacement and thus causes an axial displacement of the expansion element (6) and
- The wedge structure (50) and the counter-wedge structure (48) are aligned in such a way that the axial displacement of the expanding element (6) pushes the expanding element (6) outwards transversely to the longitudinal side.

Description

The invention relates to a corner connector for connecting two mitred hollow chamber profiles of windows, doors or the like, the corner connector having: a shaft part for insertion into one of the hollow chamber profiles, which extends along a longitudinal axis defining an axial direction and two longitudinal sides as well has two cover sides, a wedge structure being formed on at least one of the longitudinal sides; a spreading element to be arranged between at least the longitudinal side and the hollow chamber profile, the spreading element having a counter-wedge structure which interacts with the wedge structure in such a way that a displacement of the spreading element on the longitudinal side pushes the spreading element outwards transversely to the longitudinal side and thus the shaft part transversely to the longitudinal sides braced in the hollow chamber profile; and a clamping body which is axially displaceable on the shaft part and is designed in such a way that the axial displacement of the clamping body displaces the expansion element on the longitudinal side.

Corner connectors are used to connect two mitred hollow chamber profiles in which they are fixed. An important condition is to fix the corner connector inserted into a hollow chamber profile particularly firmly within the hollow chamber profile, so that the corner connector can fulfill its intended stiffening and fastening function. Corner connectors are known for this purpose, which are hammered into the associated hollow chamber profile with a slight oversize and are additionally fixed there by screws. An alternative approach, which is advantageous in terms of assembly accuracy, is to use braceable corner connectors that can be pushed into the hollow chamber profile, i.e. have an external dimension that is slightly smaller than the internal dimension of the hollow chamber profile, and are then braced in the hollow chamber profile.

The created a new class of these braceable corner connectors EP 0 698 720 A1 , which has the shaft part mentioned at the outset and the clamping body mentioned at the outset. Its axial displacement raises the clamping body in relation to the shank part and thus clamps the shank part in the hollow chamber profile. For this purpose, the publication mentioned provides inclined surfaces as a wedge structure. Understandably, these wedge structures can also be designed differently, for example by round surfaces, as in FIG DE 10 2007 030 618 B3 intended.

In these configurations, the clamping body ensures reliable clamping of the shaft part in the hollow chamber profile, but this clamping acts only in one direction, namely transversely to the upper cover side, on which the clamping body is lifted during axial displacement.

The DE 10 2007 030 618 A1 represents a further development in this respect by providing a spreading element. It is designed as a U-shaped component that is open at the bottom and is placed over the shaft part. The clamping body lies between the top of the shank element and the base (the dash) of the U. The clamping body lifts the expansion element during its axial displacement. This raises the base of the “U” and pushes it away from the top deck against the hollow section inner wall. As a result, the shaft part is braced transversely to the upper cover side. The spreader element also includes two spreader plates, which form the legs of the "U" and lie on the longitudinal sides of the shaft part. The longitudinal sides of the shaft part and the inner surfaces of the spreader plates pointing to these longitudinal sides are designed with inclined surfaces which press the spreader plates outwards from the longitudinal sides when the spreader element is lifted from the clamping body. In this way, the upper part is also braced transversely to the longitudinal sides.

The structure after DE 10 2007 030 618 A1 however, has the problem that on the one hand the spreader plates are intended to move outwards parallel to the long sides of the shaft part, but on the other hand they are attached to the base of the "U" which is pushed upwards. The one considered in the preamble DE 20 2008 008 250 U1 therefore forms the spreading element, which has the same effect as in the DE 10 2007 030 618 A1 has, as two L-shaped bodies, between which the clamping body is located. The vertical line of the "L" forms the spreader plates. The cross line of the "L" forms a short leg and is located on the top side of the stock part. Opposite of DE 10 2007 030 618 A1 So the base of the "U" is severed. The clamping body reaches under the short leg in order to lift it. As a result, each L-shaped body can be designed with a flexible connection as a solid joint between the short leg and the spreader plate.

However, the realization of this solid joint leads to problems: On the one hand, the connection must be flexible so that the spreader plates can move slightly outwards in the area of the connection and the lifting and thus the bracing in the direction transverse to the cover sides is not hindered. On the one hand, the connection must be stiff in order to pull the spreader plates up and achieve good bracing in the direction transverse to the long sides. One is thus faced with a design conflict for the two directions of stress.

The invention is therefore based on the object of further developing a generic corner connector in such a way that the bracing in both bracing directions is improved.

The object is achieved according to the invention by a corner connector according to claim 1. The dependent claims relate to preferred developments.

Generic is the corner connector for connecting two mitred hollow chamber profiles of windows, doors or the like. Formed. Such hollow chamber profiles preferably have weldable plastic. Most hollow chamber profiles also contain a metal profile to achieve greater rigidity. The corner connector has a shank part for insertion into one of the hollow chamber profiles. The shank portion extends along a longitudinal axis that defines an axial direction. It has two long sides and two top sides. A wedge structure is formed on at least one of the longitudinal sides. Arranged between this long side and the hollow chamber profile is a spreader element which has a counter wedge structure which interacts with the wedge structure in such a way that a displacement of the spreader element on the long side pushes the spreader element outwards transversely to the long side. Due to this displacement, the shaft part is braced transversely to the longitudinal sides in the hollow chamber profile. The axial displacement of the expansion element is effected by a clamping body which can be displaced axially on the shaft part. Its axial displacement moves the expansion element on the long side.

According to the invention, the axial displacement of the clamping body takes the expansion element with it in the axial direction. The displacement of the expanding element, which pushes the expanding element outwards transversely to the longitudinal side, is therefore an axial displacement and not a lifting, as in the generic prior art. The cooperating wedge and counter-wedge structures are understandably aligned in such a way that the axial displacement of the spreader element pushes the spreader element outwards transversely to the longitudinal side.

Since the spreading element does not have to be raised and causes the spreading transversely to the longitudinal sides due to its axial movement, the design conflict is avoided. It is no longer necessary to have a flexible and thus ultimately also fragile solid-state joint on the expansion element.

In contrast to the prior art, the wedge structures do not act through inclined surfaces parallel to the axial direction, but rather through cooperating wedge structures that bring about a movement essentially perpendicular to the axial direction. For example, wedge or inclined surfaces are used, which are inclined with respect to the axial direction.

Because the spreading element is pressed outwards when it is axially displaced, the spreading element essentially does not change its position relative to the cover sides, so that it is not only in the area of the cover side on which the shaft part is arranged, but also in the area of the opposite and thus lower cover side reliably clamps the shaft part transversely to the longitudinal side. Reliable clamping transversely to the longitudinal sides is thus also achieved in this area of the lower cover side of the shaft part.

It was also shown that play on the lower cover side of the shaft part, which is opposite the cover side, can now also be ruled out simply because the expansion element can essentially retain its position relative to the lower cover side of the shaft part. This is impossible with the generic spreader plates because they are raised, so that the bracing effect in the area of the lower cover side of the shaft part decreases.

For the spreading effect according to the invention, it is sufficient to arrange a spreading plate on a longitudinal side of the shaft part. For reasons of symmetry, however, it is particularly preferred to design the spreader element as two spreader plates, one of which is arranged on each longitudinal side. Insofar as reference is made below to such a spreader element, which has two spreader plates, which can each be separate components or are connected to one another in the form of a bracket, this is to be understood merely as an example.

The principle of the expansion element can be particularly preferably combined with the fact that the clamping body carries out the clamping in the orthogonal direction, i. H. across the cover pages or lengthwise to the long sides. Then the clamping body is arranged on an upper one of the cover sides of the shaft part. It has a wedge structure on its underside facing the shaft part, and the shaft part has a corresponding counter-wedge structure on the upper cover side. These two structures are designed in such a way that the clamping body is pushed away from the upper cover side by its axial displacement and thus clamps the shaft part transversely to the cover sides or longitudinally to the longitudinal sides in the hollow chamber profile. In this way, the bracing across the cover sides is taken over by the tensioning body, and the bracing across the long sides is taken over by the expansion element. This functional separation is particularly preferred.

The displacement of the expanding element is effected by the axial displacement of the clamping body. For axial entrainment, the clamping body and expansion element are preferably coupled in such a way that there is play transversely to the axial direction to the extent that the expansion element moves outward. As a result, the conflict of interpretation mentioned is additionally avoided.

So that the clamping body can take the expansion element with it during its axial displacement in the axial direction, it is particularly preferred that the expansion element and the clamping body engage in one another by at least one projection and at least one recess. Here, said game can be easily provided. For example, the projection can be arranged on the expanding element, and the recess on the clamping body. It is particularly preferred here to shape the expansion element in an L-shape, with a long leg of the “L” extending along the longitudinal side and the short leg overlapping the upper cover side and having the projection which engages in the recess on the clamping body. Of course, the arrangement of projection and recess can also be inverted, so that the clamping body has a projection which engages in a recess in the short leg of the L-shaped expansion element. Equally, it is also possible that the clamping body has a side surface which interacts with an end face of the short leg of the L-shaped expansion element in such a way that the axial displacement of the clamping body takes the expansion element with it axially.

Since the clamping body in the configuration in which it clamps the shaft part transversely to the cover sides in the hollow chamber profile moves parallel to the longitudinal side by an amount that is necessary for this clamping, i.e. is raised relative to the upper cover side, it is preferred that Form the spreader element so that it engages over the upper cover side and is provided with a lifting structure, which also raises the spreader element by essentially this amount by which the clamping body is raised, so that the recess and projection reliably engage with one another. It should be emphasized that this lifting of the spreader element is not related to the fact that the spreader element is pressed outwards transversely to the longitudinal side. The axial displacement of the expanding element is still decisive for this. The slight lifting only serves to ensure that the expansion element is reliably carried along by the clamping body in the axial direction. The lifting of the expansion element by the lifting structure therefore does not have to keep the distance between the clamping body and the expansion element completely constant. Rather, a constancy is sufficient which is such that the entrainment of the expanding element is ensured by the clamping body. It is therefore sufficient that the distance, in particular the distance measured transversely axially, remains essentially constant. "Substantially" refers here, for example, to a length of a projection which engages in a recess in order to achieve entrainment. This projection must not slip out of the recess despite the lifting of the clamping body, which occurs e.g. for clamping across the cover sides.

In order to ensure a particularly reliable bracing transversely to the longitudinal sides (the height represents the dimension transverse to the cover sides), it is preferred that the expanding element extends along the longitudinal side both over the upper third, which is closer to the clamping body, and up to extends into the lower third of the long side. Preferably, the lower edge of the spreader element remains within a band that makes up the lower 10% of the longitudinal side during the axial displacement.

The wedge structure on the shank part can be implemented in a particularly simple manner in that the shank part tapers along the longitudinal axis in a wedge section that forms the wedge structure. The spreading element can slide onto this wedge structure with a corresponding counter-wedge when it is moved axially.

The axial movement of the clamping body as well as the axial movement of the expansion element usually take place out of the hollow chamber profile, i. H. toward the miter surface formed on the shank portion. To drive the axial movement, the clamping body can be provided with a detachable pull strap, a pull eye etc. or a thread into which a screw engages.

It goes without saying that the features mentioned above and those still to be explained below can be used not only in the specified combinations, but also in other combinations or on their own, without departing from the scope of the present invention.

• 1 eine Explosionsdarstellung eines Eckverbinders in einer ersten Ausführungsform,
• 2 und 4 den Eckverbinder der 1 im zusammengebauten Zustand in zwei unterschiedlichen Spreizstellungen,
• 3 und 5 den Eckverbinder der 1 in Schnittdarstellung in diesen zwei Spreizstellungen,
• 6 und 7 eine Längsschnittdarstellung des Eckverbinders der 1 in diesen zwei Spreizstellungen,
• 8 eine Abwandlung des Eckverbinders der 1 hinsichtlich der Ausgestaltung eines Spreizelementes und
• 9 und 10 Weiterbildungen der Eckverbinder gemäß 1 und 2 hinsichtlich einer einteiligen Ausführung des Spreizelementes.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the accompanying drawings, which also disclose features that are essential to the invention. These embodiments are provided for illustration only and are not to be construed as limiting. For example, a description of an embodiment having a plurality of elements or components should not be construed as implying that all of those elements or components are necessary for implementation. Rather, other embodiments can also contain alternative elements and components, fewer elements or components, or additional elements or components. Elements or components of different exemplary embodiments can be combined with one another unless otherwise stated. Modifications and variations that are described for one of the embodiments can also be applicable to other embodiments. To avoid repetition, the same or corresponding elements in different figures are denoted by the same reference symbols and are not explained more than once. From the figures show:

• 1 an exploded view of a corner connector in a first embodiment,
• 2 and 4 the corner connector 1 when assembled in two different spread positions,
• 3 and 5 the corner connector 1 in a sectional view in these two spread positions,
• 6 and 7 a longitudinal sectional view of the corner connector 1 in these two spread positions,
• 8th a modification of the corner connector 1 with regard to the design of a spreading element and
• 9 and 10 Further developments of the corner connectors according to 1 and 2 with regard to a one-piece design of the expansion element.

1 shows a corner connector 1, which comprises a shank part 2, which is divided into a (in 1 not shown) Interior of a hollow chamber profile is inserted, which is to be connected to another hollow chamber profile mitred. A clamping body 4 serves to clamp the shaft part 2 in a vertical direction in the hollow chamber profile. In addition, a spreader element 6 is provided for bracing in the transverse direction, which is made in two parts here and includes two spreader plates 8 , 10 .

2 shows the assembled state of the corner connector 1. In this state, the corner connector 1 is first inserted into the hollow chamber profile (in 1 and 2 not shown) inserted. The clamping body 4 is then pulled out along an axial direction 12 opposite a miter surface 14 of the shank part 2 and thus parallel to the axial longitudinal extension 16 of the clamping body 4 . The pull tab shown, which protrudes from the miter surface 14, is used for this purpose. In the process, the clamping body 4 rises in the vertical direction 27 due to a wedge structure formed on the underside of the clamping body 4 . In the exemplary embodiment shown, the wedge structure has two inclined surfaces 18 , 20 , which are formed on the upper cover side 26 of the shaft part 2 with a counter-wedge structure comprising inclined surfaces 22 , 24 . The displacement of the clamping body 4 along the axial direction 12 thus clamps the shaft part 2 between the upper cover side 26 and a lower cover side 28, since the upper side 30 of the clamping body 4 is pushed away from the upper cover side 26 and is pressed against the inner wall of the hollow chamber profile.

During this axial movement, the clamping body 4 entrains the expanding element 6 in the axial direction. For this purpose, the spreader plates 8, 10 are each L-shaped and enclose the upper cover side 26 with the short legs 32, 34, which is formed here with corresponding recesses 36, 38. Furthermore, projections 40 , 42 are formed on the upper legs 32 , 34 and are inserted into corresponding recesses 44 , 46 on the clamping body 4 . As a result, the clamping body 4 carries the spreader plates 8, 10 with it during the axial displacement in the axial direction.

On the inside of the spreader plates 8, 10 wedge surfaces are formed, of which in the perspective view of 1 only the wedge surface 48 of the spreader plate 10 can be seen. During the axial movement, they slide on corresponding wedge surfaces, of which only the wedge surface 50 can be seen, which are provided on the longitudinal sides 52, 54 of the shaft part 2. Thus, during the axial entrainment by the clamping body 4, the spreader plates 8, 10 are pressed outwards by the wedge surfaces in relation to the longitudinal sides 52, 54 and clamp the shaft part 2 transversely to the longitudinal sides 52, 54 (and parallel to the vertical direction 26 and the cover sides 26, 28). As a result, the expansion element develops a transverse effect.

3 shows a sectional view perpendicular to the longitudinal axis 16 in the region of the end of the shaft part 2 in the state of FIG 2, i.e . H. with clamping body 4 not yet axially displaced. It can be seen that between the outer surfaces of the spreader plates 8, 10 and the inner surfaces of the hollow chamber profile 56, of which only an internal and stiffening metal tube is shown here, in which the shaft part 2 is clamped, a gap exists.

4 shows a display similar to that 2 , but here the clamping body 4 is already shifted axially. You can see the axial displacement of the spreader plate 8 and the clamping body 4 compared to 2 clearly. This can also be seen in the sectional view of the 5 , which in their view of 3 is equivalent to. The spreader plates 8 , 10 are now in contact with their outer sides on the inner sides of the hollow chamber profile 56 . The same applies to the top 3 of the clamping body 4. The Shaft part 2 is consequently braced in two orthogonal directions in space in the hollow chamber profile 56, namely over the entire extent of the longitudinal sides as well as over the entire extent of the top sides.

The 6 and 7 show the unbraced or braced state in a sectional view transverse to the longitudinal sides 52, 54 at the height of the longitudinal axis 16. 6 shows the unstressed, 7 the clamped state in which the spreader plate 8, 10 has slid onto the corresponding wedge surface on the longitudinal side 54, 52 of the shaft part 2 and is correspondingly pressed outwards.

Since the clamping body 4 in accordance with the embodiment 1 increases during the axial displacement, the short legs 34, 32 of the expanding element 6 are provided on their undersides with inclined surfaces, of which in the perspective view of 1 only the inclined surface 58 on the short leg 34 can be seen. They slide on corresponding inclined surfaces 60, 62, which are formed on the upper side of the shaft part 2, and ensure that the projections 40, 42 lie reliably in the recesses 44, 46 during the axial displacement.

These inclined surfaces are an example of a lifting structure which ensures that the transverse axial distance (height) between the spreader plates 8, 10, namely their short legs 32, 34, and the clamping body 4 remains essentially the same during the axial displacement.

This measure is not necessary in accordance with the embodiment 8th , in which the spreading element 6 is modified in such a way that the short legs 32, 34 engage around the clamping body 4 from above, so that the projections 40, 42 are inserted into the recesses 44, 46 from above. For this purpose, the clamping body 4 has corresponding recesses 64 , 66 , so that the short legs 32 , 34 do not protrude in relation to the upper side 30 of the clamping body 4 . The spreader element 6 thus still does not take part in the bracing transversely to the cover pages. However, the spreader plates 8, 10 are also raised by the corresponding amount during the axial displacement of the clamping body 4, so that the projections 40, 42 reliably remain in the recesses 44, 46. Otherwise the construction corresponds to the 8th the based on the 1 ff described.

9 shows a modification with regard to the configuration of the spreading element 6, which is now formed in one piece by the spreading plates 8, 10 being connected via a bracket 68, on the upper side of which the projections 40, 42 are arranged. 10 shows this configuration for the variant with projections 40, 42 engaging from above.

All wedge structures described herein are preferably latching in the embodiments; H. with a suitable microstructure, e.g. This applies in particular to the wedge surfaces (including 48 and 50) which act for the transverse action of the spreader element 6. Thus, the axial position of the spreader element 6 can be fixed without having to use the wedge structures that push the spreader plates 8, 10 away from the longitudinal sides.

As far as wedge structures and counter-wedge structures are mentioned here, these are to be understood as meaning structures arranged on two bodies and cooperating with one another, which convert a displacement of one body relative to the other body in a displacement direction into a movement of one body transverse to the displacement direction. In the embodiments, cooperating inclined surfaces are used as wedge or counter wedge structures. However, this is not the only possible implementation. Equally, rounded surfaces, uneven slopes or structures with levers etc. can be used as cooperating wedge and counter-wedge structures.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• EP 0698720 A1 [0003]
• DE 102007030618 B3 [0003]
• DE 102007030618 A1 [0005, 0006]
• DE 202008008250 U1 [0006]

Claims (8)

Corner connector for connecting two mitred hollow chamber profiles, preferably made of weldable plastic, of windows, doors or the like, the corner connector (1) having: - a shaft part (2) for insertion into one of the hollow chamber profiles (56), which extends longitudinally a longitudinal axis (16) that defines an axial direction (12) and has two longitudinal sides (52, 54) and two cover sides (26, 28), a wedge structure (50) being formed on at least one of the longitudinal sides, - an expanding element (6 ) for arranging between at least the longitudinal side and the hollow chamber profile (56), the expanding element (6) having a counter-wedge structure (48) which interacts with the wedge structure in such a way that a displacement of the expanding element (6) on the longitudinal side causes the expanding element (6) pushes outwards transversely to the longitudinal side and thus clamps the shaft part (2) transversely to the longitudinal sides (52, 54) in the hollow chamber profile (56), and - a clamping body (4) which is axi al is displaceable and is designed such that the axial displacement of the clamping body (4) displaces the expanding element (6) on the longitudinal side, characterized in that - the clamping body (4) during its axial displacement expands the expanding element (6) in the axial direction (12) and thus brings about an axial displacement of the spreading element (6) and - the wedge structure (50) and the counter-wedge structure (48) are aligned in such a way that the axial displacement of the spreading element (6) moves the spreading element (6) transversely to the longitudinal side pushes outside. corner connector claim 1 , characterized in that the clamping body (4) is arranged on an upper (26) of the cover sides (26, 28) of the shaft part (2) and has at least one wedge structure c on its underside (28) facing the shaft part (2), wherein the shaft part (2) has a counter-wedge structure (22, 24) on the upper cover side (26) and the wedge structure (18, 20) and counter-wedge structure (22, 24) are designed in such a way that the clamping body (4) can be displaced from the upper cover side (26) is pushed away and the shaft part (2) is braced transversely to the cover sides (26, 28) in the hollow chamber profile (56). Corner connector according to one of the above claims, characterized in that the spreading element (6) and the clamping body (4) engage in one another by at least one projection (40, 42) and at least one recess (36, 38), via which the clamping body (4) Spreading element (6) in the axial direction (12) entrains. Corner connector according to a combination of claims 2 and 3 , characterized in that the spreading element (6) overlaps the shaft part (2) on the upper cover side (26) and is provided with a lifting structure, preferably designed as a wedge structure (58), which during the axial movement of the clamping body (4) Spreading element (6) relative to the upper cover side (26) lifts and keeps the transverse axial distance between the clamping body (4) and spreading element (6) substantially constant. Corner connector according to one of the above claims, characterized in that the spreading element (6) extends along the longitudinal side (52, 54) both over the upper third of the longitudinal side (52, 54) closer to the clamping body (4) and into the the lower third of the longitudinal side (52, 54) further away from the clamping body (4). Corner connector according to one of the above claims, characterized in that the spreading element (6) comprises two spreading plates (8, 10) which are each arranged on one of the longitudinal sides (52, 54) of the shaft part (2), each spreading plate (8, 10) has the wedge structure (48) on its surface facing the longitudinal side and each longitudinal side of the shaft part (2) has the counter-wedge structure (50). corner connector claim 6 , characterized in that the two spreader plates (8, 10) are separate components which the clamping body (4) entrains in each case during its axial displacement in the axial direction (12). Corner connector according to one of the above claims, characterized in that the shaft part (2) tapers along the longitudinal axis (16) on the longitudinal side (52, 54) in a wedge section which forms the counter-wedge structure (50).

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