EP4103805A1 - Two-part hinge device, method for adjusting a hinge device, and use of the hinge device - Google Patents

Abstract

The invention relates to a two-part hinge device for a door or a window, said hinge device comprising: a first housing part (20) and a second housing part (30) which, when assembled, form a door hinge housing (19); and a rod (15) which runs in the first housing part (20) and second housing part (30) along the axial direction (60) of the rod, wherein the rod (15) has at least three successive rod sections (16, 17, 18) - a first, a second, and a third. The first rod section (16) is supported in the first housing part (20) by a fixture (50) and the third rod section (18) supports the second housing part (30). In the region of the second rod section (17), the rod (15) can be adjusted relative to the first housing part (20) in two directions at an angle to each other, independently of one another, and the two directions at an angle to each other extend perpendicularly to the axial direction (60) of the rod (15).

Description

Two-part belt device and method for adjusting a belt device and how to use the belt device

The invention relates to a two-part belt device and a method for adjusting the two-part belt device and a use of the belt device according to the independent claims.

EP 0962616 B1 discloses a two-part door hinge consisting of two housings, which is designed for heavy or wide doors. An adjustment, i.e. adjustment of the door relative to the door frame by manipulating the door hinge, is achieved by eccentric bearing sleeves or eccentric bolts. Furthermore, the weight of the door is applied to the bolt by a pressure washer. EP 0 271 053 A2 discloses a generic, two-part hinge for a door or for a window, consisting of two housing parts.

The disadvantage of this known solution is that the setting of the door is complex and by no means intuitive. In addition, the construction of the door hinge is complex and therefore expensive. In particular, the formation of an eccentric bolt is difficult.

It is the object of the present invention to remedy one or more disadvantages of the prior art. In particular, a two-part hinge device is to be created for a door, a gate or a window, which allows an intuitive, quick and thus cost-saving alignment of the door or the window relative to the frame. Furthermore, a method is to be created with which an intuitive, fast and thus cost-saving alignment of the door or the window relative to the frame is made possible. Furthermore, the belt device should be used in such a way that the number of movement cycles with the belt device is increased.

The object is achieved by the device and the method as well as the use defined in the independent claims. Advantageous further developments are presented in the figures and in the dependent claims.

A two-part hinge device according to the invention for a door, a gate or a window comprising a first housing part and a second housing part which form a hinge housing in the assembled state, a rod which runs in the first housing part and the second housing part along their axis direction, the rod at least three consecutive - a first, a second and a third rod sections. The first rod section is supported by a clamp in the first housing part and the third rod section carries it the second housing part. The rod can be adjusted independently of one another in the region of the second rod section in two directions at an angle to one another relative to the first housing part, and the two directions at an angle to one another are arranged transversely to the axial direction of the rod.

Due to the special adjustment option, the two-part hinge device is particularly easy and can be adjusted in a few simple steps by just one person / fitter so that the door or window that is arranged on the hinge device can be opened and closed over hundreds of thousands of cycles without resistance and reproducibly . This considerably simplifies the assembly conditions of a fitter on a construction site or in a workshop and leads to significant cost savings, since any maintenance of the two-part door hinge can also be carried out by a caretaker or an unskilled (no specialist) person. The rod can be inserted into a first housing opening in the first housing part. The second housing part is in operative connection with the rod in that it carries the second housing part, as described above. For this purpose, the third rod section can be inserted into a second housing opening of the second housing part, so that the second housing part is simply rotatably mounted in the second housing opening with respect to the first housing part.

The first housing part and / or the second housing part advantageously contain at least one adjusting device for adjusting the height as an extension of the rod. The adjustment device for height adjustment is arranged in one of the two housing parts, so that the height adjustment takes place with only one adjustment mechanism. Alternatively, an adjusting device for height adjustment can be provided in each of the two housing parts, so that the two housing parts can be easily adjusted relative to one another. The at least one adjusting device is in operative connection with the rod, so that the distance between the first housing part and the second housing part can be adjusted based on the movement of the rod in the hinge housing.

In particular, the first housing part and / or the second housing part are teardrop-shaped and have a flat fastening section for the door tabs or door frame tabs. The hinge device can thus be attached to the door or to the door frame in a simpler and more stable manner.

Alternatively, other actuators are suitable, such as screws, pins, bolts, and others. The pole is in a defined area, the second Rod section, in two directions at an angle to each other relative to the first housing part, independently of each other, adjustable so that the two-part hinge device can only be adjusted intuitively and easily in two spatial directions with the aid of the rod. This means that there is no need for a trained fitter on the construction site to adjust the two-part hinge device. The respective spindles can be secured in the rod with a chemical locking agent, for example by using Tuflok® or Nytemp® as a chemical locking agent. Chemical locking agents for spindles have a high locking effect, even at high temperatures.

The rod is preferably designed as a pendulum rod or as a bolt. A bolt has, for example, a cylindrical outer surface so that it can be easily and symmetrically inserted into the respective openings of the first housing part and the second housing part and these can simply rotate about the axis direction of the rod. A pendulum rod is a movably mounted rod which is mounted at least at one point in the hinge housing and thereby efficiently carries the second housing part, so that the two-part hinge device can be easily adjusted at least around this point.

The pendulum rod preferably has at least one polygon-shaped section on the second rod section. The polygonal section, for example a cuboid section, has at least one polygonal cross section which is formed symmetrically about the axis device of the rod. The rod is adjusted relative to the first housing part on the second rod section, the polygonal section comprising an actuator, for example a screw. This actuator holds the rod stationary and enables the rod to be adjusted relative to one of the housing parts. Alternatively, the second rod section of the pendulum rod has a spherical section or a cylindrical section, the respective section comprising at least one actuator, as described here, so that the pendulum rod can be easily inserted and adjusted into the first housing part. Alternatively, the second rod section of the pendulum rod has a section with a cross-section that is enlarged compared to the first rod section. Such pendulum rods are easy to manufacture and have a high degree of strength.

The pendulum rod advantageously has at least one cylindrical section as the first rod section. The cylindrical section has a cylindrical jacket surface which is formed symmetrically about the axis direction of the rod. That The second housing part can easily be rotated around the first rod section, which is designed as a cylindrical section.

The first rod section of the pendulum rod advantageously has a polygonal section. The polygonal section on the first rod section of the pendulum rod can serve as an anti-twist device in order to hold the pendulum rod in the first housing part in a rotationally fixed manner about the axis direction.

The pendulum rod advantageously has at least two removal notches along its longitudinal extension. This gives the pendulum rod a bone profile so that material savings are made possible and the mass-to-rigidity ratio of the pendulum rod is improved. The at least two removal notches extend at least partially into the first and third rod sections and along the entire second rod section, so that maximum material savings are possible.

The rod is preferably designed in one piece. A one-piece rod is easy to manufacture and has an intrinsically high strength, so that any wear or deformation of the rod when the band device is in use is reduced.

The rod is preferably designed in two parts, the rod consisting of a first rod element and a second rod element. Two-part rods enable simpler production, in particular if the shapes and / or the materials of the two rod elements are designed differently. The two rod elements have connecting sections with which the two rod elements can be mechanically, for example screwed, connected to form a rod. Furthermore, the tilt angle can easily be compensated for with a two-part rod, so that the joint of the door, window or gate remains movable and tilting of the joint can thus be prevented.

The first rod section is advantageously arranged on the first rod element and the third rod section is arranged on the second rod element, the second rod section including sections of the first and second rod elements. The rod can thus be clamped on the first rod element in the first housing part. Furthermore, the second housing part is in a load-bearing force-operative connection with the second rod element, so that it can be rotated easily and largely without play. The adjustment of the rod, as described here, on both rod elements leads to increased flexibility when adjusting the belt device. The second rod element preferably comprises a sleeve for introducing the force from the second housing part, the second rod section being arranged at least in sections on the sleeve. The bushing is arranged in a stationary manner on the second rod element and is arranged in a rotationally fixed manner in the axial direction of the rod and thus additionally forms the rod. The bushing typically consists of a material that differs from the first rod element, in particular a material with a higher wear resistance or strength behavior than the first rod element. With the appropriate material pairing, the service life of the belt device is significantly increased because the tribological properties in the two-part belt device can be optimized.

The pendulum rod is advantageously a three-axis ellipsoid. In this way, the load peaks are better distributed when the band device is in use at the neuralgic sections of the pendulum rod, in particular at the second rod section, since the load syringes are intercepted at these sections with an increase in material. In addition, the first rod section and the second rod section have a smaller material thickness, so that at least the first rod section can be easily inserted into the sleeve and the outer diameter of the sleeve is reduced. A hinge device with such a pendulum rod enables use for window, gate or door systems according to DIN EN1935: 2002 for load cases with a door weight of up to 350kg, for example.

The rod is preferably adjustable in the region of the second rod section by means of actuators, which are advantageously spindles. The actuators effect a reproducible adjustment of the rod along the directions at an angle to one another. An actuator can be present for each of the two directions at an angle to one another. Spindles can be designed as screws, such as worm screws, for example, which are arranged movably along a longitudinal extent of a threaded hole on the second rod section in the rod. The spindles are easily and independently adjustable to adjust the rod in the belt housing. For this purpose, the second rod section has at least two threaded bores, which run along these mutually facing directions and are offset along the axial direction.

The at least two removal notches on the second rod section advantageously each have a flat point. The actuators can thus be easily inserted into the threaded hole, so that the adjustment of the hinge device is simplified. The rod is preferably secured with an anti-twist device against undesired axis rotation about the axis direction. This means that the rod can be held in the hinge housing in a rotationally fixed manner. For example, a polygonal plate, which is preferably square or octagonal, and a locking ring can be designed as an anti-twist device. The locking ring, for example a shaft locking ring, can serve as a pull-out lock, so that an undesired removal of the rod from the hinge housing can be prevented.

The first rod section of the pendulum rod advantageously has a polygonal section. The polygonal section on the first rod section of the pendulum rod can serve as an anti-twist device in order to hold the pendulum rod in the first housing part in a rotationally fixed manner about the axis direction.

The rod is preferably clamped on the first rod section opposite the first housing part in the radial and advantageously in the axial direction. In this way, the rod on the first rod section is held stationary in the first housing part, which simplifies the alignment of the second housing part and thus the door or window on the frame during assembly.

At least one first adjustment opening and one further adjustment opening are preferably present. The actuators are thus easily accessible, so that the rod can be easily adjusted relative to the first housing part. The first adjustment opening and the further adjustment openings are preferably arranged offset in two directions which are at an angle to one another.

The first rod section of the rod preferably has a spherical head which is precisely fitting for clamping, the clamping comprising a spherical shell-shaped bearing. The rod is thus clamped at points in the spherical shell-shaped bearing and thus in the first housing part, so that an effective adjustment can take place around this point in the spherical shell-shaped bearing.

The precisely fitting spherical head advantageously has polygonal surfaces arranged radially, a prism-shaped plate being arranged on the spherical-shell-shaped bearing. As a result, the load distribution in the first housing part is improved and an anti-twist device is implemented.

The precisely fitting ball head advantageously has polygonal surfaces which are arranged radially and which engage in a polygon-shaped bearing, for example a prism-shaped bearing. This provides an effective anti-twist device, while at the same time reducing the number of components. A rotation lock is advantageously arranged in the ball head in order to hold the rod in the first housing part in a rotationally fixed manner about the axis direction. The anti-rotation device can be designed as a first bolt, which extends at least in sections through the ball head and in sections protrudes from the ball head. The protruding section of the first bolt is in an operative connection with the first housing part, for example in an elongated hole or in a groove in the first housing part, so that the rod is held in a rotationally fixed manner. In addition, the first bolt can serve as a pull-out protection so that an undesired removal of the rod from the first housing part can be prevented.

The first bolt is advantageously arranged parallel to at least one of the two mutually standing directions, transverse to the axial direction of the rod. This provides a pull-out safety device which is easy to manufacture.

As an alternative to this, the first rod section of the rod has a precisely fitting polygon head for clamping, the clamping comprising a polygonal bearing. The rod is thus clamped on several sides in the polygonal bearing and thus in the first housing part, so that the rod is securely held. The polygon head can serve as an anti-twist device in order to hold the rod in the first housing part in a rotationally fixed manner about the axis direction.

The rod is preferably adjustable by means of at least four spindles, one spindle each being arranged in the first rod section and in the third rod section, which have two directions at an angle to one another, and two spindles are arranged in the second rod section, the first spindle being parallel in the second rod section is aligned with the spindle of the first rod section and the second spindle in the second rod section is aligned parallel to the spindle of the third rod section. The rod can thus be adjusted in such a way that the first housing part can only be adjusted in a first spatial direction and the second housing part can only be adjusted in a further spatial direction. This results in a simple adjustment of the belt device, whereby only one person, for example a fitter or a non-specialist, is required.

In an alternative embodiment of the two-part belt device according to the invention, the rod is adjustable by means of at least four spindles, one spindle each being arranged in the first rod section and in the third rod section, which have two directions at an angle to one another and two spindles are arranged in the second rod section , the first spindle in the second rod section perpendicular to the spindle of the first Rod portion is aligned and the second spindle in the second rod portion is aligned perpendicular to the spindle of the third rod portion. The rod can thus be adjusted in such a way that the housing parts can each be adjusted both in a first spatial direction and in a further spatial direction. This results in increased flexibility in the adjustment of the belt device, with only one person, for example a fitter, being required.

The third rod section of the rod is preferably designed as a spherical head bolt on which the bushing rests. A spherical head bolt has a spherical end on one end face of the rod, the diameter of which can be larger than the diameter of the rod, for example the first rod section. The spherical end can be easily positioned in the sleeve.

An anti-rotation device is advantageously arranged in the ball head bolt in order to hold the rod in the second housing part in a rotationally fixed manner about the axis direction. The anti-rotation device can be designed as a second bolt, which extends at least in sections through the ball head bolt and in sections protrudes from the ball head bolt. The protruding section of the second bolt is in an operative connection with the second housing part, so that the rod is held in a rotationally fixed manner. In addition, the second bolt can serve as a pull-out protection so that an undesired removal of the rod from the second housing part can be prevented.

The second bolt is advantageously arranged parallel to at least one of the two mutually related directions, transverse to the axial direction of the rod. This provides a pull-out safety device which is easy to manufacture.

As an alternative or in addition, the ball head bolt comprises facets in order to form an anti-twist device so that the rod can be fixed in the second housing part in a rotationally fixed manner about the axis direction. Alternatively, the ball head bolt has polygonal surfaces in order to form an anti-twist device so that the rod is held in the second housing part in a rotationally fixed manner about the axis direction.

An axial bearing is advantageously introduced between the second housing part and the bushing, so that there is a simple axial bearing of the rod.

The axial bearing is advantageously arranged in a non-positive manner in a housing part so that it is held securely in the hinge device.

Alternatively, the axial bearing has a shoulder and is arranged in a form-fitting manner with the aid of a securing device in the second housing part in order to prevent undesired displacement in the hinge device. A method according to the invention for setting a hinge device for a door or a window, in particular a two-part hinge device as described here for a door, a gate or a window, wherein a rod is present in the hinge device, which comprises at least three rod sections, comprises at least the following steps:

Joining a first housing part with a second housing part to form a door hinge housing, a first rod section being arranged in the first housing part and a third rod section of the rod being inserted at least in sections into an opening in the second housing part;

Adjusting the first housing part relative to the second housing part, the distance between the housing parts being adjusted in the process;

Adjusting the rod perpendicular to the axial direction, the adjustment taking place in a second rod section of the rod, which is arranged between the first rod section and the third rod section and wherein the rod can be adjusted independently of one another in two directions at an angle to one another.

This method enables an intuitive, quick and thus cost-saving alignment of the door or the window relative to the frame.

The adjustment of the rod in the second rod section is preferably effected by actuating at least two actuators.

A use according to the invention of the two-part hinge device described here takes place when the first housing part is arranged on a pivotable door or gate or window frame or door leaf and the second housing part is arranged on a stationary door or gate or window frame.

The first rod section of the rod in the first housing part is supported by the clamping and the third rod section of the rod is supported in the second housing part, so that the load in the two-part belt device is much more favorable. The two-part belt device is thus more cost-effective and can be dimensioned smaller in terms of its dimensions, and the number of movement cycles is increased. When the door or gate or window frame or door leaf is pivoted, the rod is only exposed to a static load through the door, gate or window, regardless of the opening angle of the door, gate or window. Further advantages, features and details of the invention emerge from the following description, in which exemplary embodiments of the invention are described with reference to the drawings.

Like the technical content of the claims and figures, the list of reference symbols is part of the disclosure. The figures are described coherently and comprehensively. The same reference symbols denote the same components, reference symbols with different indices indicate functionally identical or similar components.

1 shows a first embodiment of a two-part belt device according to the invention in an exploded view;

FIG. 2 shows the rod of the two-part belt device according to FIG. 1 in a perspective illustration; FIG.

3 shows the two-part belt device according to FIG. 1 in a first one

Sectional view;

4 shows the two-part belt device according to FIG. 1 in a second sectional illustration;

5 shows a second embodiment of a two-part belt device according to the invention in an exploded view; 6 shows the rod of the two-part belt device according to FIG. 5 in a perspective illustration;

7 shows the two-part belt device according to FIG. 5 in a first one

Sectional view;

8 shows the two-part belt device according to FIG. 5 in a second

Sectional view;

9 shows a third embodiment of a two-part belt device according to the invention in an exploded view;

10 shows the rod of the two-part belt device according to FIG. 9 in a perspective illustration; 11 shows the two-part belt device according to FIG. 9 in a first one

Sectional view; FIG. 12 shows the two-part belt device according to FIG. 9 in a second sectional illustration; FIG.

13 shows a fourth embodiment of a two-part belt device according to the invention in an exploded view; 14 shows the rod of the two-part belt device according to FIG. 13 in a perspective illustration;

15 shows the two-part belt device according to FIG. 13 in a first one

Sectional view;

16 shows the two-part belt device according to FIG. 13 in a second sectional illustration;

17 shows a further embodiment of the two-part belt device according to the invention in an exploded view;

18 shows the rod of the two-part belt device according to FIG. 17 in a perspective illustration; 19 shows the two-part belt device according to FIG. 17 in a first one

Sectional view, and

FIG. 20 shows the two-part belt device according to FIG. 17 in a second

Sectional view.

21 shows a further embodiment of the two-part belt device according to the invention in an exploded view;

22 shows the rod of the two-part belt device according to FIG. 21 in a perspective illustration;

23 shows the two-part belt device according to FIG. 21 in a first one

Sectional view, FIG. 24, the two-part belt device according to FIG. 21 in a second

Sectional view,

25 shows a further embodiment of a two-part belt device according to the invention in an exploded view;

FIG. 26 shows the rod of the two-part belt device according to FIG. 25 in a perspective illustration; FIG.

27 shows the two-part belt device according to FIG. 25 in a first sectional illustration; 28 shows the two-part belt device according to FIG. 25 in a second sectional illustration;

29 shows the embodiment of the two-part belt device according to the invention according to FIG. 13 in an exploded view in a preferred use;

30 shows the embodiment of the two-part belt device according to the invention according to FIG. 25 in an exploded view in a preferred use;

31 shows the two-part belt device according to FIG. 30 in a first sectional view,

32 shows the two-part belt device according to FIG. 30 in a second sectional view,

33 shows an axial bearing for one of the aforementioned hinge devices in a perspective view, and FIG. 34 shows the axial bearing according to FIG. 30 in one of the aforementioned hinge devices in a perspective sectional view.

1 to 4 show a two-part hinge device 11 for a door, a gate or a window. The two-part hinge device 11 comprises a first housing part 20 and a second housing part 30, which form a hinge housing 12 in the assembled state. A first flange 13 with openings 14 is arranged on the first housing part 20, the first housing part 20 being fastened to the frame R of a door, a window or a gate with the aid of the first flange 13. A second flange 31 with openings 34 is arranged on the second housing part 30, the second housing part 30 being fastened to a door, a window or a gate with the aid of the second flange 31. The two-part belt device 11 comprises a rod 15 which runs in the first housing part 20 and second housing part 30 along its axis direction 60. For this purpose, the first housing part 20 has a first housing opening 21 into which the rod 15 can be inserted. The second housing part 30 has a second housing opening 33 into which the rod 15 can be inserted.

The rod 15 has three consecutive - a first, a second and a third - rod sections 16, 17, 18. In the assembled state of the two-part belt device 11, the first rod section 16 is in the first Housing part 20 supported by a clamp 50. The third rod section 18 carries a bush 25 and thus the second housing part 30, the third rod section 18 being arranged in sections in the bush 25. An axial bearing 45 is arranged between the second housing part 30 and the bush 25. The rod 15 is adjustable in the area of the second rod section 17 in two directions X, Y at an angle ß to each other relative to the first housing part 20, the two directions X, Y at an angle ß to each other being arranged transversely to the axis direction 60 of the rod 15. The rod 15 can be adjusted in the X direction and, independently thereof, can be adjusted in the Y direction. The two-part belt device 11 comprises actuators for adjusting the rod 15. The actuators shown are spindles 22 and 32, which each have a thread and which can be screwed into two threaded bores 19, 19a for adjusting the rod 15. For this purpose, the threaded bores 19, 19a have corresponding threads on the inside. The two threaded bores 19, 19a extend in two directions X, Y in the second rod section 17 at an angle β to one another. The rod 15 is clamped in the radial direction on the first rod section 16 opposite the first housing part 20.

The first housing part 20 has a first adjusting opening 23 and a second adjusting opening 24, which are arranged offset in two directions X, Y which are at the angle β to one another. In the assembled state, the rod 15 of the two-part belt device 11 can be adjusted with the aid of the spindles 22 and 32 and with a tool, the tool being inserted into the respective adjustment opening 23, 24 in order to rotate or actuate the spindles 22, 32 (not shown ). Alternatively, other actuators are suitable, such as screws, pins, bolts, and others.

2 shows the one-piece rod 15, which is designed as a pendulum rod, the pendulum rod having at least one polygonal section 17a on the second rod section 17. The polygonal section 17a has at least one polygonal cross section which is formed symmetrically about the axis device 60 of the rod 15. The rod 15 is adjusted on the second rod section 17, the polygonal section 17a having surfaces on which the threaded bores 19, 19a are arranged. The threaded bores 19, 19a are spaced apart from one another along the axial direction 60 of the rod 15.

The first rod section 16 of the rod 15 has an essentially cylindrical section 16a and a spherical head 52 which is precisely fitting for the clamping 50, the clamping 50 being a spherical shell-shaped bearing 53 includes. Furthermore, there is a pull-out safeguard 35 which fixes the rod 15 in the first housing part 20. The spherical shell-shaped bearing 53 is inserted into a bearing opening 26 of the first housing part 20 and fixed there. The rod 15 is thus clamped at points in the spherical shell-shaped bearing 53 and thus in the first housing part 20. The rod 15 is secured with an anti-rotation lock 51 against undesired axis rotation about the axis direction 60, the anti-rotation lock 51 being arranged between the first housing part 20 and the spherical-shell-shaped bearing 53. For this purpose, the first rod section 16 of the rod 15 has a polygonal section 50a. The polygonal section 50a on the first rod section 16 holds the rod 15 in the first housing part 20 in a rotationally fixed manner about the axis direction 60 by interacting with the anti-rotation lock 51. The third rod section 18 of the rod 15 is designed as a ball head bolt 18a on which the bush 25 is supported.

Alternatively, the second rod section of the pendulum rod 15 has a spherical section or a cylindrical section, the respective section comprising at least one actuator, as described here (not shown). Alternatively, the second rod section of the pendulum rod 15 has a section with a cross-section that is enlarged compared to the first rod section (not shown).

In Fig. 3 and Fig. 4, the previously mentioned two-part belt device 11 is shown, an adjusting device 40 for height adjustment being arranged in the second housing part. The adjusting device 40 is arranged as an extension of the rod 15. The adjusting device 40 comprises an adjusting member 41 and an adjusting threaded bore 43 in which the adjusting member 41 is rotatably arranged. By actuating the adjusting member 41 with a tool (not shown), the adjusting member 41 is rotated into the adjusting threaded bore 43 and presses on the axial bearing 45 and thus on the sleeve 25, so that the two housing parts 20, 30 can be adjusted relative to one another by the height of the To adjust the door or the window to the frame. The adjustment device 40 is in operative connection with the rod 15, so that the distance between the first housing part 20 and the second housing part 30 can be adjusted based on the movement of the rod 15 in the hinge housing 12. The threaded adjustment bore 43 can be closed with a cover 42 which, in the closed state, presses on the adjustment member 41 so that the adjustment member 41 is fixed because it is locked with the cover 42.

FIGS. 5 to 8 show a further embodiment of a two-part belt device. The two-part belt device 111 essentially has the same components as the two-part belt device 11 according to FIGS. 1 to 4, the two-part belt device 111 having an alternative rod 115 and an alternative clamp 150, an alternative pull-out lock 155, 156 and an alternative rotation lock 151, 151a.

6 shows the rod 115 with the three consecutive rod sections 116, 117, 118 - a first, a second and a third and the third rod section 118 carries the bush 25 and thus the second housing part 30, the third rod section 118 being arranged in sections in the bush 25. The third rod section 118 of the rod 115 is designed as a ball head bolt 118a on which the bush 25 rests. The ball head bolt 118a comprises facets 118b in order to form an anti-twist device 151a, so that the rod is held in the second housing part 30 in a rotationally fixed manner about the axis direction 160. A securing ring is arranged on the third rod section 118 as a first pull-out safeguard 155, so that the rod 115 cannot be pulled out of the sleeve 25. The rod 115 is adjusted on the second rod section 117, the polygonal section 117a having surfaces on which the threaded bores 119, 119a are arranged, as previously described in FIGS. 1 to 4.

The first rod section 116 of the rod 115 has an essentially cylindrical section 116a and a polygon head 152 which is precisely fitting for clamping 150. The precisely fitting polygon head 152 has radially arranged polygonal surfaces 152a which, in the assembled state, grip precisely into a polygonal bearing 153 and thus form the further anti-rotation device 151. The clamping device 150 is held in the first housing part 20 by the cover 154. A securing ring is arranged on the first rod section 116 as a second pull-out safeguard 156.

9 to 12 show a further embodiment of a two-part belt device. The two-part belt device 211 has essentially the same components as the two-part belt device 11, according to FIGS. 1 to 4, and / or as the two-part belt device 111, according to FIGS. 5 to 8, this having an alternative rod 215 and an alternative clamping 250 has.

The rod 215 has three consecutive - a first, a second and a third - rod sections 216, 217, 218. The rod 215 differs from the rod 115 of FIGS. 5 to 8 in that an alternative, more precisely fitting Ball head 252 is present on the first housing section 16. The precisely fitting ball head 252 has radially arranged polygonal surfaces 252a which, when assembled, fit precisely into a prism-shaped plate 254 as a counterpart, so that the precisely fitting ball head 252 is fixed by the spherical shell-shaped bearing 253 and form the anti-rotation device 251. The rod 215 is adjusted on the second rod section 217, the polygonal section 217a having surfaces on which the threaded bores 219, 219a are arranged, as previously described in FIGS. 1 to 4.

13 to 16 show a further embodiment of a two-part belt device. The two-part hinge device 311 has essentially the same components as the two-part hinge device 11 according to FIGS. Otherwise, the functional and structural properties of the components of the two-part belt device 311 are constructed as described for the two-part belt device 11 and can be used if necessary in order to create an advantageous combination of the two embodiments.

The rod 315 has three consecutive - a first, a second and a third - rod sections 316, 317, 318. In the assembled state of the two-part hinge device 311, the first rod section 316 is supported in the first housing part 20 by a clamp 350. The first rod section 316 of the rod 315 has a precisely fitting spherical head 352 for clamping 350, which is fixed by the spherical shell-shaped bearing 353. The rod 315 is adjusted on the second rod section 317, the polygonal section 317a having surfaces on which the threaded bores 319, 319a are arranged, as previously described in FIGS. 1 to 4.

A rotation lock 351 is arranged in the ball head 352 in order to hold the rod 315 in the first housing part 20 in a rotationally fixed manner about the axis direction 360. The anti-rotation device 351 is designed as a first bolt 351a, which extends at least in sections through the spherical head 352 and in sections protrudes from the spherical head 352. The protruding section of the first bolt 351a is in an operative connection with the first housing part 20 in that it extends in an elongated hole or a groove in the first housing part 20, so that the rod 315 is held in a rotationally fixed manner. In addition, the first bolt 351a serves as a pull-out protection.

The third rod section 318 of the rod 315 is designed as a ball head bolt 318a on which the bush 325 rests. The ball head bolt 318a has a Anti-rotation lock 351, which is designed as a second bolt 318b, which extends at least in sections through the ball head bolt 318a and in sections protrudes from the ball head bolt 318a. The protruding section of the second bolt 318b is in an operative connection with the bushing 325 in that it extends in an elongated hole or a groove, so that the rod 315 is held in a rotationally fixed manner.

FIGS. 17 to 20 show a further embodiment of a two-part hinge device 411 for a door, a gate or a window. The two-part hinge device 411 comprises a first housing part 420 and a second housing part 430, which when joined together form a hinge housing 412. A first flange 413 with openings 414 is arranged on the first housing part 420, the first housing part 420 being fastened to the frame R of a door, a window or a gate with the aid of the first flange 413. A second flange 431 with openings 434 is arranged on the second housing part 430, the second housing part 430 being fastened to a door, a window or a gate with the aid of the second flange 431.

The two-part belt device 411 comprises a rod 415 which runs in the first housing part 420 and second housing part 430 along its axis direction 460. For this purpose, the first housing part 420 has a first housing opening 421, into which the rod 415 can be inserted in sections. The second housing part 430 has a second housing opening 433, into which the rod 415 can be inserted in sections. A bushing, as described in the aforementioned embodiments, can be dispensed with.

The rod 415 has three consecutive - a first, a second and a third - rod sections 416, 417, 418. In the assembled state of the two-part belt device 411, the first rod section 416 is supported in the first housing part 420 by means of a clamp 450. The restraint 450 comprises a cover 452 on which the first rod section 416 rests. The third rod section 418 carries the second housing part 430. An axial bearing 445 is arranged between the second housing part 430 and the third rod section 418. The rod 415 is adjustable in the area of the second rod section 417 in two directions X, Y at an angle β to one another relative to the first housing part 420, the two directions X, Y at an angle β to one another being arranged transversely to the axial direction 460 of the rod 415. The rod 415 can be adjusted in the X direction and, independently thereof, can be adjusted in the Y direction. The two-part belt device 411 comprises actuators for adjusting the rod 415. The actuators shown are four spindles 422, 427 and 432, 435, each of which has a thread. The spindles 422, 427 and 432, 435 can be screwed in and out of the threaded bores 419, 419a, 419b, 419c to adjust the rod 415. For this purpose, the threaded bores 419, 419a, 419b, 419c of the rod 415 have corresponding threads on the inside. The threaded bores 419, 419a extend in two directions X, Y in the second rod section 417 at an angle ß to one another and the threaded bores 419b, 419c extend in two directions X, Y at the angle ß to one another in the first rod section 416 and in the third rod section 418 A spindle 435, 427 is arranged in the first rod section 416 and in the third rod section 418, which have two directions X, Y at an angle β to one another and two spindles 422 and 432 are arranged in the second rod section 417, the first The spindle 432 in the second rod section 417 is oriented perpendicular to the spindle 435 of the first rod section 416 and the second spindle 422 in the second rod section 417 is oriented perpendicular to the spindle 427 of the third rod section 418.

The first housing part 420 has four adjusting openings 423, 424, 428, 429, the first and second adjusting openings 423, 428 being offset from the third and fourth adjusting openings 424, 429 in two directions X, Y at an angle β to one another. In the assembled state, the rod 415 of the two-part belt device 411 can be adjusted with the aid of the spindles 422, 427 and 432, 435 and with a tool, the tool being inserted into the respective adjustment opening 423, 424, 428, 429 to adjust the spindles 422, 427 and 432, 435 to rotate or operate (not shown). Alternatively, other actuators are suitable, such as screws, pins, bolts, and others.

Fig. 18 shows the one-piece rod 415, which is designed as a bolt. The rod 415 is secured with an anti-rotation device 451 against undesired axis rotation about the axis direction 460, the anti-rotation device 451 being designed as polygonal sections 416a, 417a, 418a on the rod 415, which are arranged in the first housing part 420 in a rotationally fixed manner.

In FIG. 19 and FIG. 20, the previously mentioned two-part belt device 411 is shown in the assembled state, with an adjusting device 440 for height adjustment being arranged in the second housing part 430. The adjustment device 440 is arranged as an extension of the rod 415. The adjusting device 440 comprises an adjusting member 441 and an adjusting threaded bore 443 in which the adjusting member 441 is rotatably arranged. By actuating the adjusting member 441 With a tool (not shown) the adjusting member 441 is rotated into the adjusting threaded bore 443 and presses on the axial bearing 445 and thus on the rod 418 in the area of the third rod section 418, so that the two housing parts 420, 430 can be adjusted relative to one another by the height of the To adjust the door or the window to the frame. The adjustment device 440 is in operative connection with the rod 415, so that the distance between the first housing part 420 and the second housing part 430 can be adjusted based on the movement of the rod 415 in the hinge housing 412. The threaded adjustment bore 443 can be closed with a cover 442 which, in the closed state, presses on the adjustment member 441 so that the adjustment member 441 is fixed.

FIGS. 21 to 24 show a further embodiment of a two-part hinge device 511 for a door, a gate or a window. The two-part hinge device 511 comprises a first housing part 520 and a second housing part 530, which form a hinge housing 512 in the assembled state. A first flange 513 with openings 514 is arranged on the first housing part 520, the first housing part 520 being fastened to the frame R of a door, a window or a gate with the aid of the first flange 513. A second flange 531 with openings 534 is arranged on the second housing part 530, the second housing part 530 being fastened to a door, a window or a gate with the aid of the second flange 531.

The two-part belt device 511 comprises a rod 515 which is designed in two parts. The rod 515 consists of a first rod element 515a and a second rod element 515b. The two rod elements 515a, 515b have connecting sections 515c, 515d, at which the two rod elements 515a and 515b are joined together to form a rod 515. An axial bearing 545 is arranged between the first rod element 515a and the second rod element 515b. In the assembled state, the rod 515 runs in the first housing part 520 and in the second housing part 530 along its axis direction 560. The first housing part 520 has a first housing opening 521 into which the first rod element 515a can be inserted and the second housing part 530 has a second housing opening 533 , in which the second rod element 515b can be inserted.

The two-part rod 515 has three consecutive - a first, a second and a third - rod sections 516, 517, 518. The first rod section 516 is arranged on the first rod element 515a and the third rod section 518 is arranged on the second rod element 515b, the second rod section 517 in sections, the first and the second Rod element 515a, 515b includes (see Fig. 22). The first rod element 515a is designed as a bushing 525 for introducing the force from the second housing part 530, the second rod section 517 being arranged in sections on the bushing 525.

The rod elements 515a, 515b each have two threaded bores 519a, 519b and 519, 519c, respectively. The threaded bores 519, 519a, 519b, 519c have corresponding threads on the inside. The threaded bores 519, 519a extend in two directions X, Y in the second rod section 517 at an angle ß to one another and the threaded bores 519b, 519c extend in two directions X, Y at the angle ß to one another in the first rod section 516 and in the third rod section 518 .

In the assembled state of the two-part belt device 511, the first rod section 516 is supported in the first housing part 520 by means of a clamp 550. The restraint 550 comprises a cover 552 on which the first rod section 516 rests. The third rod section 518 carries the second housing part 530. The rod 515 is adjustable in the area of the second rod section 517 in two directions X, Y relative to one another at an angle β relative to the first housing part 520, the two directions X, Y at an angle β to one another are arranged transversely to the axial direction 560 of the rod 515. The rod 515 can be adjusted in the X direction and, independently thereof, can be adjusted in the Y direction. The two-part belt device 511 comprises actuators for adjusting the rod 515. The actuators shown are four spindles 522, 527 and 532, 535 which each have a thread and which can be screwed in and out for adjusting the rod 515 in threaded bores 519, 519a, 519b, 519c are. A spindle 527, 535 is arranged in the first rod section 516 and in the third rod section 518, which have two directions X, Y at an angle β to one another and two spindles 522 and 532 are arranged in the second rod section 517, the first The spindle 532 in the second rod section 517 is aligned parallel to the spindle 535 of the first rod section 516 and the second spindle 522 in the second rod section 517 is aligned parallel to the spindle 527 of the third rod section 518.

The first housing part 520 has two adjusting openings 523, 524 and the second housing part 530 has two adjusting openings 528, 529, the first and third adjusting openings 523, 528 to the second and fourth adjusting openings 524, 529 in two directions X at an angle ß to one another , Y are staggered. In the assembled state, the rod 515 is the two-part belt device 511 adjustable with the aid of the spindles 522, 527 and 532, 535 and with a tool, the tool being inserted into the respective adjustment opening 523, 524, 528, 529 in order to rotate or actuate the spindles 522, 527 and 532, 535 (not shown). Alternatively, other actuators are suitable, such as screws, pins, bolts, and others.

22 shows the joined two-part rod 515, which is designed as a bolt. The rod 515 is secured against undesired axis rotation about the axis direction 560 with an anti-rotation lock 551, the anti-rotation lock 551 being formed on the first rod section 516 and the third rod section 518 as polygonal sections 516a and 518a.

In FIGS. 23 and 24, the previously mentioned two-part belt device 511 is shown, which has an adjusting device 540 on the second housing part 530, as shown in the previously shown embodiments according to FIGS. 1 to 4 or FIGS. 17 to 20.

FIGS. 25 to 28 show a further embodiment of a two-part belt device. The two-part band device 611 has essentially the same components as the two-part band device 311 according to FIGS. 13 to 16, with an alternative rod 615, alternative housing parts 622, 630 and an alternative clamping being present. Otherwise, the functional and structural properties of the components of the two-part belt device 611 are set up as described for the two-part belt device 311 and can be used if necessary in order to create an advantageous combination of the two embodiments.

The rod 615 is a three-axis ellipsoid and has three consecutive - a first, a second and a third - rod sections 616, 617, 618. In the assembled state of the two-part hinge device 611, the first rod section 616 is supported in the first housing part 620 in the spherical shell-shaped housing bearing 653. The first rod section 616 of the rod 615 has a spherical head 652 that fits the spherical shell-shaped housing bearing 653. The spherical shell-shaped housing bearing 653 serves as a clamp 650. The rod 615 is adjusted on the second rod section 617, the polygonal section 617a having surfaces on which the threaded bores 619, 619a are arranged, as previously described in FIGS. The rod 615 has two removal notches 627, 627a along its longitudinal extension. This gives the pendulum rod a bone profile so that material savings are made possible. The two removal notches 627, 627a extend at least partially into the first and third rod sections 616, 618 and along the entire second rod section 617. The two removal notches 627, 627a each have a flat point on the second rod section, where the spindles 622, 632 into the Engage threaded holes 619, 619a. The spindles 622, 632 each engage in sections in adjusting disks 622a, 632a for adjustment. Alternatively, the respective spindles 622, 632 can be secured in the rod with the aid of a chemical locking agent, for example by using Tuflok® or Nytemp® as the chemical locking agent.

The third rod section 618 of the rod 615 is designed as a precisely fitting (half) ball head 652a on which the bush 625 rests. A rotationally secured axial bearing 645 is arranged between the second housing part 630 and the bush 625. The ball head 652a has an anti-rotation lock 351, which is designed as a second bolt 318b, which extends at least in sections through the precisely fitting ball head 652a and in sections protrudes from the precisely fitting ball head 652a. The protruding section of the second bolt 318b is in an operative connection with the bush 625 in that it extends in an elongated hole or a groove, so that the rod 615 is held in a rotationally fixed manner.

The method for setting a hinge device for a door or a window, in particular one of the two-part hinge devices 11, 111, 211, 311 as described here for a door, a gate or a window, is described by way of example with reference to FIGS. 1 to 4. The two-part belt device 11 comprises the rod 15 which is arranged in the belt device 11. The method comprises at least the following steps:

Joining a first housing part 20 with a second housing part 30 to form a door hinge housing 12, a first rod section 16 being arranged in the first housing part 20 and a third rod section 18 of the rod being inserted at least in sections into an opening in the second housing part 30;

Adjusting the first housing part 20 relative to the second housing part 30, the distance between the housing parts 20, 30 being adjusted;

Adjusting the rod 15 perpendicular to the axial direction 60, the adjustment taking place in a second rod section 17 of the rod 15, which is arranged between the first rod section 16 and the third rod section 18 and wherein the rod 15 can be adjusted independently of one another in two directions X, Y which are at an angle β to one another.

The rod 15 is adjusted in the second rod section 17 by actuating at least two actuators 22, 32.

29 shows the preferred use of the two-part hinge devices described here using the example of the two-part hinge device 311 according to FIGS Window frame (or casement) or door leaf R arranged and the second housing part 30 arranged on a stationary door, - or gate, or window frame RI (or frame). The first rod section 316 of the rod 315 is supported or supported in the first housing part 20 by the clamping 350 and the third rod section 318 of the rod 315 is supported or supported in the second housing part 30, so that the loads in the two-part hinge device 311 are much more favorable as shown, for example, in FIGS. 13 to 16.

30 to 32 show a further preferred use of the two-part hinge devices described here using the example of the two-part hinge device 611 according to FIGS. 25 to 28. In this preferred use, the first housing part 620 is on a pivotable door, or gate or window frame (or sash frame) or door leaf R and the second housing part 630 is arranged on a stationary door or gate or window frame RI (or window frame). The first rod section 616 of the rod 615 is supported or supported in the first housing part 620 by the spherical shell-shaped housing bearing 653 and the third rod section 618 of the rod 615 is supported or supported with the aid of the bush 625 in the second housing part 630, so that the loads in the two-part hinge device 611 are much cheaper than shown, for example, in FIGS. 25 to 28.

33 to 34 show an axial bearing 745 as an alternative embodiment to the previously shown axial bearings 45, 445, 545, 645, which can each be introduced into the second housing part 30, 330, 430, 530, 630 in a force-locking manner. For example, the axial bearing 745 is arranged in a form-fitting manner in the second housing part 630 of the hinge device 611 and has a shoulder 746. The axial bearing 745 is fixed to the cover 642 in the hinge device 611 with the aid of a securing ring 747. List of reference symbols

11 two-part belt device

12 tape case

13 first flange

14 openings from 13

15 rod

16 first rod section of 15 16a cylindrical section

17 second rod section of 15 17a polygonal section

18 third rod section of 15 18a ball head bolt

19 threaded hole 19a threaded hole

20 first housing part 21 first housing opening 22 spindle

23 first position opening

24 second opening

25 rifle

26 Opening of the warehouse

30 second housing part

31 second flange

32 spindle

33 second housing opening

34 openings from 31

35 Pull-out protection

40 adjustment device

41 adjusting member

42 cover

43 adjustable threaded hole 45 thrust bearing

50 restraint 50a polygonal section

51 Anti-twist device

52 ball head spherical shell-shaped bearing axis direction two-piece belt device rod first rod sectiona cylindrical section second rod sectiona polygonal section third rod sectiona spherical head bolt b facets clamping further anti-rotation devicea anti-rotation device polygon head a polygonal surfaces polygonal bearing cover first pull-out device second pull-out device axis direction two-piece band device a rod section, first rod section, threaded boring, threaded rod section Anti-rotation lock ball head a polygonal surfaces spherical shell-shaped bearing prism-shaped plate Axial direction two-part belt device rod first rod section second rod section a polygonal section third rod section a spherical head bolt b second bolt

Threaded hole a Threaded hole

rifle

Restraint

Anti-twist device a first bolt

Spherical head spherical socket-shaped bearing axis direction two-piece belt device belt housing first flange openings of 413 rod first rod section of 415a polygonal section second rod section of 415a polygonal section third rod section of 415a polygonal section

Threaded hole a threaded hole b threaded hole c threaded hole first housing part first housing opening

spindle first adjusting opening third adjusting opening bushing third housing opening spindle second adjusting opening fourth adjusting opening second housing part second flange spindle second housing opening openings of 431 spindle

Adjusting device

Adjusting member

cover

Adjustable threaded hole

Thrust bearings

Restraint

Anti-twist device

cover

Axis direction two-part band device band housing first flange openings of 413 rod a first rod element b second rod element c connecting section d connecting section first rod section of 515a polygonal section second rod section of 515 third rod section of 515a polygonal section Threaded hole a threaded hole b threaded hole c threaded hole first housing part first housing opening

Spindle first adjustment opening third adjustment opening bushing third housing opening spindle second adjustment opening fourth adjustment opening second housing part second flange spindle second housing opening openings of 531 spindle

Adjusting device

Adjusting member

cover

Adjustable threaded hole

Thrust bearings

Restraint

Anti-twist device

cover

Axial direction two-part belt device rod, first rod section, second rod section, a polygon-shaped section, third rod section 619 threaded hole

619a threaded hole

620 first housing part

622 spindle

622a adjusting disc

625 rifle

627 removal notches

627a removal notches

630 second housing part

632 spindle

632a adjusting disk

642 cover

645 thrust bearings

650 restraint

652 ball head

653 spherical shell-shaped housing bearing

652a ball head

660 axis direction

745 thrust bearings

746 shoulder of 745

747 retaining ring

X direction

Y direction ß angle between X and Y

R frame

RI framework

Claims

Claims

1. Two-part hinge device (11; 111; 211; 311; 411; 511; 611) for a door, gate or window, comprising a first housing part (20; 420; 520; 620) and a second housing part (30; 430; 530; 630), which in the assembled state is a tape housing

Form (12; 412; 512); a rod (15; 115; 215; 315; 415; 515) in the first housing part (20; 420; 520; 620) and second housing part (30; 430; 530; 630) along their axial direction (60; 160; 260 ; 360; 460; 560; 660), the rod (15; 115; 215; 315; 415; 515; 615) at least three consecutive - a first, a second and a third rod sections (16, 17, 18; 116, 117, 117; 216, 217, 218; 316, 317, 318; 416, 417, 418; 516, 517, 518; 616,617,618), the first rod section (16; 116; 216; 316; 416; 516 ; 616) is supported in the first housing part (20; 420; 520; 620) by a clamp (50; 150; 250; 350; 450; 550; 650) and the third rod section (18; 118; 218; 318; 418; 518; 618) carries the second housing part (30; 430; 530; 630), characterized in that the rod (15; 115; 215; 315; 415; 515; 615) in the area of the second rod section (17; 117; 217 ; 317; 417; 517; 617) in two at an angle (ß) to each other

Directions (X, Y) relative to the first housing part (20; 420; 520; 620) can be adjusted independently of one another, and the two directions (X, Y) at an angle (β) to one another transverse to the axial direction (60; 160; 260; 360; 460; 560; 660) of the rod (15; 115; 215; 315; 415; 515; 615) are arranged.

2. Belt device according to claim 1, characterized in that the rod (15; 115; 215; 315; 415; 515; 615) is designed as a pendulum rod or as a bolt, the pendulum rod preferably having at least one polygonal section (17a; 117a; 217a) ; 317a; 417a; 517a; 617a) on the second rod section (17; 117; 217; 317; 417; 517; 617) and advantageously has at least one cylindrical section (16a; 416a; 516a) as the first rod section (16; 116; 216; 316; 416; 516; 616).

3. Belt device according to claim 2, characterized in that the pendulum rod has at least two removal notches along its longitudinal extension.

4. Belt device according to claim 2 or 3, characterized in that the pendulum rod is a three-axis ellipsoid.

5. Belt device according to one of the preceding claims, characterized in that the rod (15; 115; 215; 315; 415; 515; 615) is formed in one piece, or is formed in two parts, wherein the rod (515) consists of a first rod element ( 515a) and a second rod element (515b).

6. Belt device according to claim 5, characterized in that the second rod element (515b) comprises a sleeve (525) for introducing the force from the second housing part (530), the second rod section (517) at least in sections on the sleeve (525) is arranged.

7. Belt device according to one of the preceding claims, characterized in that the rod (15; 115; 215; 315; 415; 515; 615) in the area of the second rod section (17; 117; 217; 317; 417; 517; 617) is adjustable by means of actuators, which are advantageously spindles (22, 32; 422, 432; 522, 532; 622, 632).

8. Belt device according to one of the preceding claims, characterized in that the rod (15; 115; 215; 315; 415; 515; 615) with an anti-twist device (51; 151; 251; 351; 451; 551) against unwanted axis rotation the axis direction (60; 160; 260; 360; 460; 560; 660) is secured.

9. Belt device according to one of the preceding claims, characterized in that the rod (15; 115; 215; 315; 415; 515; 615) on the first rod section (16; 116; 216; 316; 416; 516; 616) opposite the first housing part (20; 420; 520; 620) is clamped in the radial direction.

10. Belt device according to one of the preceding claims, characterized in that at least one first adjustment opening (23; 423; 523) and a further adjustment opening (24; 424; 524) are present, which are preferably arranged offset in two directions (X, Y) at an angle (β) to one another.

11. Belt device according to one of the preceding claims, characterized in that the first rod section (16; 216; 316) of the rod (15; 215; 315) has a spherical head (52 ; 252; 352; 652), the

Clamping (50; 150; 250; 350) comprises a spherical shell-shaped bearing (53; 253; 353) or a spherical shell-shaped housing bearing (653) and advantageously the spherical head (52; 252; 352; 652) is the anti-rotation device (51; 251; 351) ) having.

12. Belt device according to one of claims 1 to 10, characterized in that the first rod section (116) of the rod (115) has a precisely fitting polygon head (152) for clamping (150;), the clamping (150) being a polygon-shaped bearing ( 153) and advantageously the polygon head (152) has the anti-rotation device (151).

13. Belt device according to one of the preceding claims, characterized in that the rod (415; 515) is adjustable by means of at least four spindles (422, 427, 432, 435; 522, 527, 532, 535), one spindle (435 ; 535) is arranged in the first rod section (416; 516) and in the third rod section (418; 518), which have two directions (X, Y) which are at an angle to one another and wherein in the second rod section (417; 517) two spindles ( 422, 432; 522, 532), the first spindle (422; 522) being aligned in the second rod section (417; 517) parallel to the spindle (435; 535) of the first rod section (416; 516) and the second spindle (432; 532) in the second rod section (417; 517) is aligned parallel to the spindle (427; 527) of the third rod section (418; 518).

14. Belt device according to one of claims 1 to 12, characterized in that the rod (415; 515) is adjustable by means of at least four spindles (422, 427, 432, 435; 522, 527, 532, 535), one spindle in each case (435; 535) is arranged in the first rod section (416; 516) and in the third rod section (418; 518), which have two directions (X, Y) which are at an angle to one another and where im second rod section (417; 517) two spindles (422, 432; 522, 532) are arranged, the first spindle (422; 522) in the second rod section (417; 517) perpendicular to the spindle (435; 535) of the first rod section ( 416; 516) and the second spindle (432; 532) in the second rod section (417; 517) is oriented perpendicular to the spindle (427; 527) of the third rod section (418; 518).

15. Belt device according to one of the preceding claims, characterized in that the third rod section (18; 118; 318; 618) of the rod (15; 115; 315; 615) is designed as a ball head bolt (18a; 118a; 318a; 652a), on which the bush (25; 125; 325; 625) rests.

16. A method for adjusting a hinge device for a door, a gate or a window, in particular a two-part hinge device (11; 111; 211; 311; 411; 511; 611) according to one of the preceding claims, wherein a rod (15; 115; 215; 315; 415; 515; 615) is present in the belt device, which has at least three rod sections (16, 17, 18; 116, 117, 117; 216, 217, 218; 316, 317, 318; 416, 417, 418 ; 516, 517, 518; 616, 617, 618), the method comprising at least the following steps:

- Joining a first housing part (20; 420; 520; 620) with a second housing part (30; 430; 530; 630) to form a band housing (12; 412; 512), wherein a first rod section (16; 116; 216; 316 ; 416; 516; 616) is arranged in the first housing part (20; 420; 520; 620) and a third rod section (18; 118; 218; 318; 418; 518; 618) of the rod (15; 115; 215; 315 ; 415; 515; 615) is introduced at least in sections into a second housing opening (33) of the second housing part (30; 430; 530; 630);

- Adjusting the first housing part (20; 420; 520; 620) relative to the second housing part (30; 430; 530; 630), the distance between the housing parts (20, 30) being adjusted in the process;

- Adjustment of the rod (15; 115; 215; 315; 415; 515; 615) perpendicular to the axial direction (60; 160; 260; 360; 460; 560), the adjustment in a second rod section (17; 117; 217; 317; 417; 517; 617) of the rod (15; 115; 215; 315; 415; 515; 615) between the first rod section (16; 116; 216; 316; 416; 516; 616) and the third Rod section (18; 118; 218; 318; 418; 518; 618) arranged and the rod (15; 115; 215; 315; 415; 515; 615) being adjusted independently of one another in two directions (X, Y) at an angle (β) to one another.

17. The method according to claim 16, characterized in that the adjustment of the rod (15; 115; 215; 315; 415; 515; 615) in the second

Rod section (18; 118; 218; 318; 418; 518; 618) is effected by actuating at least two actuators (22, 32; 422, 432; 522, 532; 622, 632).

18. Use of the two-part belt device (11; 111; 211; 311; 411; 511: 611) according to one of claims 1 to 15, wherein the first housing part

(20; 420; 520; 620) is arranged on a pivotable door, or gate, or window frame (R) or door leaf and the second housing part (30; 430; 530; 630) on a stationary door, - or gate , or window frame (RI) is arranged.