EP1656491A1 - Corner joint and method for producing a joint of this type - Google Patents

Abstract

The invention relates to a corner joint (2) consisting of two connecting parts (5, 10), which are fixed to the respective hollow sections (3, 9). The mitred hollow sections (3, 9) and the fixed connecting parts (5, 10) are interconnected with the aid of screws in such a way that said hollow sections (3, 9) can be braced against one another. Recesses (34) and/or distribution channels (38) for receiving and distributing adhesive are provided on at least one lateral surface of a connecting part (5, 10).

Description

Corner connection and method for producing such a corner connection

The invention relates to a corner connection consisting of a corner connector and two metal profiles and a method for producing such a connection with the features of the preamble of the independent claims. The invention further relates to a connecting part from which the corner connector composed of at least two connecting parts consists.

Numerous corner connections or corner connectors are already known and used. For example, EP 0 810 344 B1 describes a corner connection which uses a one-piece, approximately L-shaped corner connector for connecting miter-cut hollow profiles.

EP 0 810 344 B1 itself describes a corner connector and associated, miter-cut hollow profiles, the profiles being pressed together by fastening arrangements which are supported on the corner connector. In addition, the hollow profiles are glued to the corner connector.

DE 86 21 143 U shows an apparatus and a method in which hollow profiles are connected to form a corner connection with the aid of a connecting piece.

In practice, it has been shown that the production of a corner connection with the aid of a one-piece corner connector is comparatively difficult depending on the application. Furthermore, the known methods are not very suitable for reliable and easy to press the profiles against each other.

BESTATIGUNGSKOPIE Two-part corner connectors are known for example from FR 2 477 443. The corner connection of FR 2 477 443 consists of miter-cut hollow profiles, into each of which a corner connector part can be inserted. To connect the corner connector parts with the hollow profiles and the corner connector parts to one another, screw connections are particularly common.

FR 86 645 shows a corner connection in which frame profiles that are open on one side are connected to one another. The corner connecting parts can be arranged offset inwards on the profiles, whereby a distance between the miter surfaces of the corner connector parts is defined.

Furthermore, a corner connection is known from EP 1 333 145 A2 with a corner connector consisting of two connecting elements, two reinforcement profiles and two miter-cut hollow profiles made of plastic. A connecting element can be inserted into a reinforcing profile and this into a cavity of one hollow profile. The connecting elements are connected to the hollow profiles by screws and also to one another by screws. The screws for connecting the connecting elements to the hollow profiles on the one hand and for connecting the connecting elements to one another on the other hand are gradually tightened such that the hollow profiles are pressed against one another. The plastic hollow profiles are then welded together.

FR 2 729 738 AI shows a corner connection with two prism-shaped corner connector parts. The connection arrangement is essentially carried out with the aid of screws, with adhesive points also being provided. There are also known corner connections which only have adhesive connections. For example, DE 101 18 791 AI shows a corner connection for hollow profiles made of aluminum with an L-shaped connecting element, into which adhesive can be filled via channel-forming recesses and chambers.

DE 198 18 632 AI relates to a corner connection of hollow plastic profiles. Appropriate plastic inserts can be inserted into the miter-cut hollow profiles. The insert bodies have an adhesive channel guidance system for connecting the insert bodies to the hollow profiles, adhesive being introduced through an inlet opening in the region of a miter surface of an insert body.

It is therefore an object of the present invention to avoid the disadvantages of the known, in particular to provide a device and a method of the type mentioned at the outset which are distinguished by simple, economical use, high stability and by a wide range of applications. The corner connection is said to be particularly suitable for hollow metal profiles.

According to the invention, these objects are achieved with a corner connection, a connecting part and a kit for this corner connection and a method for producing a corner connection with the features of the characterizing part of the independent claims.

A corner connection for frames of wall elements, doors or windows contains a corner connector and mitred hollow profiles. The corner connector is composed of at least two parts. The connecting parts can each be inserted into a cavity of a hollow profile and have a fastening arrangement for connecting each with a hollow profile. The connecting parts also have a connecting arrangement for connecting the connecting parts which are each fastened to a hollow profile. Since the connecting parts are preassembled in the respective hollow profiles, the hollow profiles (with their associated connecting parts) only have to be positioned relative to one another for the actual connection corners and then joined by connecting the connecting parts. Thus, the comparatively complicated step of inserting the respective legs of a one-piece corner connector of the aforementioned known type is eliminated. The two-part construction of a corner connector thus has great advantages in terms of handling and installing a corner connection. Furthermore, the connecting parts - compared to L-shaped parts - are relatively inexpensive to manufacture.

The hollow profiles usually consist of metallic material, in particular steel, from which relatively complicated profile cross sections can also be produced. The metal is rolled or drawn, for example. The extrusion process can also be used. In its simplest form, the hollow profile is basically rectangular in cross section. Of course, hollow profiles can also have other shapes or geometries. In particular, the connecting parts are also suitable for use in profiles which, instead of only one cavity, have a plurality of cavities which are separated from one another and which run in parallel. The respective associated connecting parts are designed in cross section in such a way that they can be inserted into a cavity of the profile with a precise fit without (or at least only with little play). The connecting parts themselves generally also consist of metallic material, preferably steel, stainless steel or aluminum. The connecting arrangement for connecting the connecting parts, each fastened to a hollow profile, and / or the connecting parts are designed such that, during the connecting process, the miter-cut hollow profiles can be pressed against one another under prestress. This ensures that any manufacturing-related bumps or inaccuracies in the miter-cut profiles are compensated for in the area of the miter. Furthermore, the stability of the corner connection is improved by the frictional connection. Another advantage is that by avoiding any gaps, the corners meet higher aesthetic requirements.

Recesses and distribution channels for receiving injectable adhesive are provided on at least one interface of a connecting part. An interface is a surface of the connecting part that bears on the hollow profile inner wall. It can be used to apply adhesive in precisely defined areas. This also has the advantage that adhesive can be saved since the entire area is not intended for the reception of adhesive. With the help of the distribution channels, an injectable adhesive can be effectively distributed.

The connecting parts are particularly advantageously provided with a miter, the miter angle roughly corresponding to that of the respectively assigned hollow profiles. Consequently, the miter surfaces of a hollow profile and the miter surface of the respective connecting part run parallel to one another. This has the advantage that the connecting parts or hollow profiles are pressed uniformly against each other and thus no stress peaks can arise. At least one of the connecting parts is particularly advantageously fastened at a distance from the miter surface of a hollow profile. When connecting the hollow profiles or the connecting parts attached to them, the distance between the miter surfaces of the connecting parts is reduced, as a result of which the hollow profiles are pressed against one another in the region of the miter. This arrangement of the connecting parts in the hollow profiles has the advantage that the hollow profiles can be pressed against one another in a simple manner under prestress. By choosing the distance, it is conceivable to be able to set the desired pressing force or pretension to a certain degree. Preferably, however, the connecting parts are inserted into the respective hollow profiles at the same distance.

In a further exemplary embodiment, the respective hollow profile and the respective connecting part are screwed together and / or glued. The connection between the hollow profile and the respective connecting part can thus be achieved relatively easily. In order to keep the assembly effort as low as possible, only a few, for example two screws per hollow profile are advantageously used, which are in particular embedded on the same surface of the hollow profile. A screw connection also has the advantage that the aforementioned distance can be set in a simple manner by positioning the screw connection. Adhesive bonding, on the other hand, has the advantage that the profile does not have to be provided with several "unsightly" holes: A combination of the adhesive and screw connection types results in a particularly firm connection. Gluing can also only be used to additionally secure the screw connection.

The connecting part is particularly advantageously fastened to the hollow profile by self-tapping screws. This has the advantage partly that the connecting part does not have to have a screw thread, simple drill holes are sufficient. This means that the comparatively complex work step of attaching a thread, for example thread cutting, can be dispensed with when producing a connecting part. This makes it easier and cheaper to produce a connecting part.

In a next embodiment, connecting parts are screwed together and / or glued. This makes the corner connection easy to install. The gluing takes place, for example, by wetting the connecting parts on their miter surface with adhesive. A combination of an adhesive bond with a screw connection also has the advantage that, compared to an adhesive bond alone, additional holding or positioning means for precisely positioning the connecting parts or the hollow profiles connected to one another can be dispensed with.

Particularly advantageously, the connecting parts have at least one through hole running at right angles to the miter for connecting the connecting parts. With the help of this through hole, the connecting parts can be easily screwed together with fastening screws. The screws are inserted into the through hole from one side and then tightened using a nut or a corresponding thread in the opposite connecting part. This has the advantage that the hollow profiles can be pressed against one another simply by tightening the screw connection.

According to a further exemplary embodiment, the connecting parts have a cutout in the inlet area of the through hole for receiving a nut. This arrangement allows it is easy to insert receiving nuts in it. This allows a user to choose from which side or from which of the hollow profiles of a corner connection a fastening screw is to be inserted. The assembly of a corner connection can be designed flexibly. In particular, this makes it possible to fit frames for wall elements, doors or windows that are adapted to the structural conditions, for example. The receiving nuts can already be inserted before the first manufacturing step, the fastening of the connecting parts with the respective hollow profiles. These nuts are secured against rotation, for example, by gluing the nut in the blind hole or by positive and / or non-positive locking.

It is particularly advantageous if the hollow profile has at least one opening for injecting adhesive into the distribution channels. This makes it possible to introduce adhesive from a few injection openings between the hollow profile and the connecting profile. This makes it possible to first assemble the corner connection completely mechanically, for example with the aid of screw connections, and only then to add additional adhesive. The handling and use of adhesives is simplified. The process of making a glued and screwed corner connection can be made much more efficient.

According to a further exemplary embodiment, the connecting part has webs and cutouts running in the longitudinal direction in the region of the outside and in the region of the inside. The inside is understood to mean the inner face of a frame corner. Consequently, the outside is understood to mean the opposite, outer end face or that side of a hollow profile cut with a miter, which has the greatest length as a result of the miter. The connecting part is created by machining, for example in a milling system. However, the design of the connecting part as a cast part is also conceivable. The design of the connecting parts results in a weight reduction without the connecting parts losing their functional and static properties.

In an embodiment which is particularly advantageous for this purpose, the connecting part has a central recess in the area of the outside and, accordingly, two webs on the side and at least one web in the area of the inside. The space created by the central recess can be used, for example, to allow electrical lines and a lock locking rod to be routed inside the corner connection. It is also conceivable that sealing or insulation material can be introduced into the cutouts.

The corner connection can be produced by the following steps: one connecting part each is connected to a respective hollow profile with the aid of a fastening arrangement, then the connecting parts each fastened to a hollow profile are connected to one another with the aid of a connecting arrangement. The manufacturing process therefore essentially consists of two steps.

In the second step, when connecting the connecting parts each fastened to a hollow profile, the mitered hollow profiles are pressed against one another particularly advantageously.

This pressure can result from the fact that the connecting parts are inserted and fastened into the hollow profiles in such a way that there is a distance between the mitred surfaces of a hollow profile and the respective connecting part. If the connecting parts are then connected to one another for the connection of the hollow profiles, the connection manure parts of the gap due to the mentioned distance is reduced, so that the hollow profiles are pressed against each other in the area of the miter.

Further individual features and advantages of the invention result from the following description of the exemplary embodiments and from the drawings. Show it:

FIG. 1: schematic side view of a first exemplary embodiment of a corner connection according to the invention,

FIG. 2: an exploded perspective view of a corner connection,

FIG. 3: longitudinal section through two connecting parts, each of which is connected to a hollow profile before assembly,

FIG. 4: longitudinal section through a corner connection, the corner connection being created by assembling the connecting parts with the hollow profile attached to them according to FIG. 3,

FIG. 5: longitudinal section through a corner connection according to a further exemplary embodiment,

FIG. 6: section through a connecting part and a hollow profile from FIG. 5 (section B-B),

FIG. 7: top view from the outside of a connecting part according to the exemplary embodiment from FIG. 5, FIG. 8 top view from the inside of a connecting part according to the exemplary embodiment from FIG. 5,

FIG. 9: side view of a connecting part according to a further exemplary embodiment, which is fastened in a hollow profile,

FIG. 10 section through a connecting part according to the exemplary embodiment from FIG. 9 (section D-D),

FIG. 11 longitudinal section through the connecting part according to the exemplary embodiment from FIG. 9,

FIG. 12 side view of a connecting part according to a further exemplary embodiment,

As can be seen from FIG. 1, a corner connection essentially consists of a corner connector 2 and two hollow profiles 3, 9 in each case. The corner connector 2 is formed in two parts and consists of the connecting parts 5 and 10. In the present schematic representation (and in all the following figures) ) the angle of the miter surface 8 of the miter cut hollow profiles 3, 9 to the longitudinal axis should be 45 °. However, other angles are also conceivable, for example one of the hollow profiles is cut at an angle of 60 ° and the other at an angle of 30 °. However, this then requires hollow profiles with different profile cross sections. The miter angle of the respectively associated connecting parts 2, 5 is adjusted accordingly.

The perspective exploded view according to FIG. 2 shows details for a corner connection 1. Manure parts 5, 10 are inserted into the respective hollow profiles 3, 9. In its simplest form, the shape and dimensions of the connecting parts 5, 10 correspond to those of the cavity 4 of the hollow profiles 3, 9, and in the present case they are rectangular. The connecting parts 5, 10 can be inserted approximately precisely into the hollow profiles 3, 9. The hollow profiles are usually produced in an extrusion process. The manufacturing accuracy of the hollow profiles plays a role insofar as this must be taken into account when designing a connecting part. A play-free insertion is only ensured if the profiles are of high quality. Instead of a rectangular cross-section, of course, more complicated geometries are also conceivable; all that is required is that the connecting part 5, 10 can be inserted into the hollow profile 3, 9 in a form-fitting manner. After insertion, the connecting parts 5, 10 are fastened with the respective hollow profile 3, 9, for example with the aid of fastening screws. Other fastening means, such as rivets, gluing or welding, are also conceivable.

FIGS. 3 and 4 show how the hollow profiles 3, 10 are connected to one another with the connecting parts 5, 10 attached to them. For this purpose, the respective connecting parts 5, 10 are inserted into the respective hollow profiles 3, 9 in the x-direction in a position that has been pre-determined. The connecting part 5, 10 has a bevel 23, which ensures that the connecting part 5, 10 can be inserted more easily into the cavity 4 of a hollow profile. In the present exemplary embodiment, the connecting parts 5, 10 are pushed in so far that there is a distance a, a ^Λ between the miter surface 13, 15 of the respective connecting parts and the miter surface 8, 14 of the hollow profiles. The distance a or a ^λ is approximately 0 to 2 mm, preferably 0.5 mm to 1 mm. The distance to be selected depends in particular on the dimensions of the hollow profiles. As a rule, the distances a and a ^{λ are the} same. For a uniform force distribution, the respective miter surfaces 8, 13 and 14, 15 of the hollow profiles and connecting parts must be parallel to each other. At the predefined position, the connecting parts 5, 10 are fastened to the respective hollow profile 3, 9, for example, as in the present case by means of fastening screws 16, for example a slotted screw 16. The fastening screw 16 is particularly advantageously designed as a self-tapping screw, so that the connecting part 5, 10 no thread needs to be cut. A simple through hole 17 is sufficient. This has the advantage that one work step is omitted for producing a connecting part 5, 10. Other types of fastening are also conceivable, for example with the aid of nails or pins, in particular the connecting part 5, 10 can be glued into the respective hollow profile 3, 9, for example with a PU or silicone adhesive. It is particularly advantageous if the miter surfaces are glued in addition to the screw connection. The miter surfaces can be wetted before screwing. However, it is also conceivable that after the screws have been inserted, but preferably before the screws have been tightened, injectable adhesive into the cavity 37 created by the distances a, a 'via a single opening (not shown in the drawing) in the area of the miter is introduced. It is also conceivable that at least one miter surface 13, 15 of a connecting part 5, 10 has cutouts for the reception of adhesive.

FIG. 4 shows the final assembled corner connection 1. The hollow profiles 3, 9 and the connecting parts 5, 10 attached to them are positioned relative to one another in such a way that a corner is created. The two parts are then joined together using a screw connection. The central axis 18 of the screw connection is perpendicular to the miter surface 13 or 15 of a connecting part 5, 10. In the exemplary embodiment in FIG. 4, the screw 19 is a screw designed with a hexagon socket (Allen screw) for better accessibility for a tool for tightening the screw. A nut 21, which forms the counterpart to the screw 19, is let into an inlet opening 20 in the area of the through bore 17. The nut 21 can be glued in the corresponding blind hole. The nut 21 can also be designed as a rivet nut. The nut 21 is thus secured against rotation. Other arrangements are also conceivable. But it is also conceivable that a corresponding thread has in the respective connecting part. In addition to the screw connection, it can be advantageous if the corner connection is glued. For this purpose, the miter surfaces 13, 15 of the connecting parts 5, 10 are wetted with adhesive. This also has the advantage that, by moving the connecting parts 5, 10 back at a distance a or a ^λ to the respective hollow profiles 3, 9, no adhesive can penetrate to the outside. It is also conceivable that the respective connecting parts 5, 10 are merely glued to the associated hollow profiles 3, 9 instead of using a screw connection, the connecting parts 5, 10 being pressed against one another with the aid of a pressing device (not described here), as a result of which their miter surfaces 13, 15 make an adhesive bond. For the assembly or insertion of the fasteners 19, 21 there is a recess 22 on the outside of the hollow profile 3, 9, which ensures that these fasteners can be inserted. As shown in FIG. 5, the two connecting parts 5, 10 are of identical design, in particular the bores provided for the screw connection for connecting the connecting parts to one another. This has the advantage that, depending on the application, it can be chosen from which side a screw 19 is to be inserted; the user therefore has the choice of either inserting a screw 19 from the inlet opening 20 of the “right” or via the inlet opening 20 of the “left” connecting part 10. Lie difficult space conditions before, insert the receiving nut 21, before connecting the connecting parts with the respective hollow profiles in the connecting part that is considered difficult to access due to the space conditions. This ensures that corner connections can be assembled even in tight spaces, which increases the flexibility and the area of application of the corner connection.

FIG. 6, which shows a section through the connecting part 5 and the hollow profile 3 in the region of the fastening device for connecting the connecting part 5 to the hollow profile 3 (section BB), again clearly shows that there is a positive connection between the connecting part 5 and the hollow profile 3. It can also be seen that the connecting part 5 does not have to be fully formed in cross section, but can contain recesses and cutouts. The geometry is chosen so that the static properties of a corner connection 1 are not (significantly) influenced. In the area of the outside 11, the connecting part 5 has webs 24 which rest on the inside side surfaces 25, 26 of the hollow profile 3. Between the webs 24 there is an inner space 27, which can also accommodate lines or other accessories. In approximately its central region 28, the connecting part 5 is of solid construction or over its entire width (subject to the bores provided for the fastening means). In the area of the side facing the inside 12, the connecting part has a central web 29 and, in the area adjacent to a side surface 26 of the hollow profile, a further web 30 and correspondingly two cavities 30, 31. The webs 24, 29, 30 are of this type configured that the dimensions correspond to the cavity 4 of the hollow profile 3. FIG. 6 also shows that this also shows that the connecting part 5, 10 has two through bores 17 for receiving a screw. Depending on the application and area of application, a different number is also conceivable. The through hole serves to receive a self-tapping screw corresponding in diameter. Of course, push-through screws (and nuts) can also be used. In this case, the hollow profile would have to have a corresponding bore on its inside 12.

As FIG. 7 shows, the webs 24 run over the entire length of the connecting part 5. For reasons of weight, they are made narrower in an approximately central region 33 than in the lateral regions in which fastening arrangements are provided. FIG. 7 further shows cutouts 34 located on the side surfaces, which are provided for the reception of adhesives. The side surfaces on which the recesses (34) are arranged form boundary surfaces which abut a hollow profile inner wall, for example the inner side surfaces 25, 26 of the hollow profile (cf. FIG. 6). In particular, it is provided that the cutouts 34 can be filled with injectable adhesive.

It can be seen from FIG. 8 that the connecting webs 29, 30 extend from the miter surface 13 over the entire length of the connecting part 5. In addition to the side bevels 23, the connecting part 5 also has bevels 35.

FIGS. 9 to 11 show a further exemplary embodiment of a connecting part 5. This has in particular a recess 34 for receiving adhesive in the region of its side surface. The connecting part 5 has a cross section in contrast to the previous exemplary embodiment (see FIG. 6) via a single central web 29. This cross section corresponds to a particularly weight-reduced design without sacrificing stability and statics of the corner connection. The fastening screws 16 are attached in the present exemplary embodiment, in contrast to previous exemplary embodiments.

As FIG. 11 shows, the design of the interior 27 also makes it possible to insert screws for the connection of the two connecting elements 5, 10 from the inside 12.

FIG. 12 shows that instead of a straight miter surface, the miter surface can be designed in the form of a step or staircase. Of course, the miter surfaces 13, 15 of the respective connecting parts 5, 10 which belong to one another are to be designed in such a way that they correspond to one another. Such a configuration of a connecting part 5, 10 brings additional advantages with regard to the stability and robustness of the corner connection 1.

FIG. 12 also shows a type of configuration of cutouts and distribution channels for receiving adhesive. In the present exemplary embodiment, adhesive can be injected into the cutout 34 through the opening 39 via the distribution channels 36 and 40. By arranging the distribution channel in the immediate vicinity of the miter, it is also possible to introduce adhesive onto the miter surface (13) of the connecting parts or into the cavity (37) between them.

Claims

claims

[I. Corner connection (1) for frames of wall elements, doors or windows, containing a corner connector (2) and two miter cut hollow profiles (3, 9), characterized in that the corner connector (2) has at least two in a cavity (4) of a hollow profile (3, 9) has insertable connecting parts (5, 10), each of which is designed with a fastening arrangement (6) for connection to a respective hollow profile (3, 9), with recesses (5, 10) on at least one interface of a connecting part (5, 10). 34) and / or distribution channels (38) for receiving and distributing adhesive and that a connection arrangement (7) is provided for connecting the connection parts (5, 10) each fastened to a hollow profile (3, 9), connection arrangement ( 7) and / or connecting parts (5, 10) are designed such that the miter-cut hollow profiles (3, 9) can be pressed against one another under prestress during the connecting process.

2. corner connection (1) according to claim 1, characterized in that the connecting parts (5, 10) are provided with a miter, the miter angle corresponding to that of the respective associated hollow profiles (3, 9).

3. Corner connection according to claim 2, characterized in that at least one of the connecting parts (5, 10) at a distance (a, a ^λ ) to the miter surface (8) of a hollow profile in the hollow profile (3, 9) is attached.

4. Corner connection according to one of claims 1 to 3, characterized in that the respective hollow profile (3, 9) and that respective connecting part (5, 10) are screwed together and / or glued.

5. Corner connection according to one of claims 1 to 4, characterized in that the hollow profile (3, 9) is fastened by self-tapping screws (16) with the connecting part (5, 10).

6. Corner connection according to one of claims 1 to 5, characterized in that the connecting parts (5, 10) are screwed together and / or glued.

7. Corner connection according to one of claims 1 to 6, characterized in that the connecting parts (5, 10) have at least one through hole (36) running at approximately right angles to the miter, in particular a bore, for connecting the connecting parts (5, 10) ,

8. corner connection according to one of claims 1 to 7, characterized in that the connecting parts (5, 10) in the region of the through hole (36) are provided with a nut (21).

9. corner connection according to one of claims 1 to 8, characterized in that the hollow profile (3, 9) has at least one opening (39) for injecting adhesive into the distribution channels (38, 40).

10. Corner connection according to one of claims 1 to 9, characterized in that the connecting part (5, 10) in the region of the outside (11) and in the region of the inside (12) in the longitudinal direction webs (24, 29, 30) and recesses (27, 31, 32).

11. Corner connection according to one of claims 1 to 10, characterized in that the connecting part (5, 10) in the region of the outside (11) has a central recess (27) and correspondingly on the side two webs (24) and in the region of the inside has at least one web (29).

12.ι connecting part for the production of a corner connection according to one of claims 1 to 11 for frames of wall elements, doors or windows made of two miter cut hollow profiles (3, 9) and with at least two in a cavity (4) of a hollow profile (3rd , 9) insertable connecting parts (5, 10), characterized in that the connecting part (5, 10) has a miter which corresponds to that of the hollow profile with which the connecting part (5, 10) can be connected and a connecting arrangement (7) is provided through which two connecting parts (5, 10) can be connected to the hollow profiles (3, 9) attached to them, the connecting arrangement (7) being designed such that the miter cut hollow profiles (3, 9) underneath during the connecting process Preload can be pressed against one another and that recesses (34) and / or distribution channels (38, 40) on at least one interface of the connecting part (5, 10) for receiving adhesive are provided.

13. Connecting part according to claim 12, characterized in that the connecting part (5, 10) as a connection arrangement (7) have at least one through hole (36), in particular a bore, for receiving a fastening element, in particular a screw (19), and that one of the Connecting parts (5, 10) has a complementary fastening element, in particular a nut (21).

14 .; Method for producing a corner connection (1) for frames of wall elements, doors or windows from a corner connector (2) and at least two miter-cut hollow profiles (3, 9), the corner connector having at least two connecting parts (5, 10), characterized that each connecting part (5, 10) is connected to the respective hollow profile (3, 9) with the aid of a fastening arrangement (6), and that then the connecting parts (5, 10) each fastened to a hollow profile (3, 9) Are connected to one another with the aid of a connecting arrangement (7), when connecting the connecting parts (5, 10) each fastened to a hollow profile (3, 9) the miter-cut hollow profiles (3, 9) are pressed against one another under prestress and that the respective hollow profile (3, 9) and the respective connecting part (5, 10) are screwed together and glued.

15. A method for producing a corner connection according to claim 14, characterized in that at least one connecting part (5, 10) is connected to the respective hollow profile (3, 9), that a connecting part is at a distance (a, a) from the miter surface (8, 14) of a hollow profile (3, 9).

16. A method for producing a corner connection according to one of claims 14 or 15, characterized in that the hollow profile (3, 9) is fastened to the connecting part (5, 10) by self-tapping screws (16).