DE29803806U1 - Door or window hinge - Google Patents

Description

02.03.1998

Door or window hinge

The invention relates to a door or window hinge, with a frame hinge to be attached to a fixed frame, which axially supports a guide bush, which receives one end of a pivot bearing axis, the other end of which serves to support a sash hinge and with an adjusting screw, by turning which the axial position of the pivot bearing axis can be adjusted relative to the frame hinge.

A hinge with the aforementioned features is generally known. The adjusting screw is adjustable in a threaded hole in the frame hinge and directly supports the guide bush, which in turn supports the pivot bearing axle. As a result, the axial extension or the height of the frame hinge is influenced by the adjustment height of the adjusting screw.

In contrast, the invention is based on the object of improving a door or window hinge with the features mentioned above in such a way that the construction height of the frame hinge is not influenced by the adjustment height of the adjusting screw 5.

This task is solved by arranging the adjusting screw inside the guide bush and from there axially supporting the pivot bearing axle.
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It is important for the invention that the thread into which the adjusting screw engages is not present in the frame band, i.e. in the body of the frame band that supports the guide bush. Rather, the thread for the thread engagement of the adjusting screw is to be designed within the space enclosed by the guide bush in such a way that the frame band or its band body supporting the guide bush is completely free of the components used for height adjustment.

Rather, these components are assigned exclusively to the pivot bearing axis and the guide bush. This results in the further advantage that the belt body can be designed in the same way for different belt types, regardless of whether or not there is a height adjustment and, if necessary, without the disadvantages that would be present with a belt body of conventional design that is actually designed for height adjustment if height adjustment is omitted, for example by omitting the adjusting screw.

The band can be designed so that the adjusting screw is threaded into the pivot bearing axis. With this design, the guide bush can be kept completely free of a thread used for height adjustment. This is particularly advantageous if the guide bush is made of plastic, where load limits and creep behavior would have to be taken into account in particular. A threaded engagement between the metal adjusting screw and the pivot bearing axis, which is usually also made of metal, avoids such problems.

The band can be designed so that the adjusting screw engages in an internal threaded hole that is coaxial with the pivot bearing axis. This results in a very small weakening of the pivot bearing axis while at the same time providing the greatest possible guide surface area, because the pivot bearing axis can be supported on its outer circumference over its entire length by the guide bush.

It is advantageous if the adjusting screw is mounted on a collar of the guide bush which engages under the pivot bearing axis

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is supported. The ring collar of the guide bushing grips the screw so far that it is securely supported vertically. As a result of the ring collar gripping underneath, only a small opening remains on the underside as an access opening for an adjustment tool to turn the adjusting screw. The ring collar gripping under the pivot bearing axis not only serves to securely support this adjusting screw, but also has a positive effect on the attractive appearance of the frame band in this area.

The band described above can be designed in such a way that the adjusting screw is a head screw, the head of which serves as a support on the collar. Instead of the head screw, a headless screw could also be used, such as a cylinder head screw or a grub screw. In all of these cases, the adjusting screws would be mass-produced parts that can be purchased commercially and thus contribute to an inexpensive design of the band. The head screw also has the advantage that its head offers large radii compared to its shaft, with which the head screw can be supported axially, so that large areas with low surface pressures are created on comparatively large diameters. The large radii also make it possible for the adjusting screw to be rotated using internal non-circular recesses that have a comparatively large diameter and are therefore safe to operate. The internal non-circular recesses or the operating tools cannot be over-tightened or deformed so quickly that reliable operation of the adjusting screw would no longer be possible.

A countersunk head screw can be used as a head screw, for example. However, it is very practical if the adjusting screw is a round head screw. It is very small in the head area and in extreme cases can have a head diameter that is the same as the outside diameter of the pivot bearing axis. This creates optimally large support surfaces between the head of the adjusting screw and the ring that grips under the pivot bearing axis and the guide bush.

The band can be designed so that the head of the adjusting screw is fitted into a guide recess in the pivot bearing axis. The adjusting screw and the pivot bearing axis then form an assembly that is very compact and stable. Above all, it is ensured that the pivot bearing axis is guided externally over its greatest possible length in the guide bush, thus achieving a high level of functional reliability of the bearing.

Further stabilization of the bearing can be achieved by supporting the head of the adjusting screw in a guide recess of the ring collar that engages under the pivot bearing axis or on a flat ring collar surface that is available over the entire area. The guide recess can help to stabilize the bearing in particular if the pivot bearing axis is adjusted to a high position. In this case, the adjusting screw acts as a radial holder at the lower end of the guide bush.

If the entire available flat ring collar surface is used to support the adjusting screw, notch stresses in the transition area between the ring collar and the guide sleeve can be avoided, which serves to ensure the stability of the guide bush.

In order to be able to safely transfer larger forces axially and to ensure a considerable durability of the bearing, the band is designed so that the guide bush is a metal bush or, if necessary, a fiber-reinforced plastic bush. A plastic bush will often not be able to be used for larger loads. It can then be advantageous to reinforce the plastic bush with fibers, for example with carbon fibers, which are preferably arranged in the transition area between the ring collar and the guide bush.

The band can be further developed so that the

The pivot bearing axis is secured against rotation. As a result, twisting the adjusting screw will safely lead to axial displacement of the pivot bearing axis without the risk of

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This means that the pivot bearing axis is rotated by turning the adjusting screw due to frictional forces, so that the predetermined height adjustment does not occur. Also, rotations of the sash hinge cannot affect the axial height adjustment of the hinge.

A particularly simple design of the band is achieved by the fact that the adjusting screw can be rotated in an internal thread of the guide bush and directly supports the pivot bearing axis. No adjustment engagement of any kind is therefore required between the adjusting screw and the pivot bearing axis; instead, the abutting end faces of both components are sufficient for direct support. The pivot bearing axis can basically be adopted unchanged from known designs. The thread engagement between the adjusting screw and the guide bush can be designed to suit the specified loads, e.g. with a correspondingly large engagement diameter.

It is advantageous if the adjusting screw is secured against loss by a collar on the guide bushing and if necessary the adjusting screw is longer than the internal thread of the guide bushing. The adjusting screw can be screwed into the thread of the guide bushing from the end opposite the collar on the guide bushing. In conjunction with this design, the height of the adjusting screw can be dimensioned so that it protrudes from the internal thread of the 0 guide bushing even when the adjusting screw is screwed against the collar. This ensures that the pivot bearing axis must always be supported on the adjusting screw and cannot be supported directly on the guide bushing in a structurally uncontrolled manner.

A further development of the door or window hinge can be characterized in that the adjusting screw, which is in threaded engagement with a pivot bearing axis supported on the frame hinge, supports an adjusting element which enables a height adjustment corresponding to a rotational adjustment of the adjusting screw.

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adjustment of the sash hinge. With the help of the adjustment element, an adjustment movement of the adjusting screw is decoupled from a height adjustment movement of the pivot bearing axis. The adjustment element can instead act on the sash hinge, i.e. cause its height adjustment, without a height adjustment movement of the pivot bearing axis being necessary at the same time. As a result, the structurally predetermined bearing conditions of the guide bush and the pivot bearing axis in the area of the frame hinge remain completely unaffected.

A design of the hinge described above is characterized in that the adjustment element is an adjustment sleeve supported on a head of the adjusting screw, which is arranged in a radially supporting manner between the lower end of the pivot bearing axis and the guide bush. The adjustment sleeve thus surrounds the pivot bearing axis coaxially and is axially loaded by means of the adjustment movement of the adjusting screw, which leads to the sash hinge being adjusted accordingly in height. The arrangement of the adjustment sleeve between the guide bush and the pivot bearing axis reduces the risk of deformation of the adjustment sleeve, so that it can be designed with thin walls. The radial enlargement of the frame hinge due to the adjustment sleeve is therefore small.

A further design of the hinge can be made such that the adjustment sleeve ends below a bearing collar of the pivot bearing axis resting on the guide bush, and that the bearing bush of the sash hinge is supported by an adjustment ring which is supported on the adjustment sleeve with support feet through 0 guide recesses in the bearing collar. The adjustment ring is used to pass on an adjustment movement of the adjustment sleeve through the bearing collar of the pivot axis to the sash hinge. The adjustment ring with its support feet is non-rotatably mounted in the guide recesses of the bearing collar. The bearing bush of the sash hinge rests on the adjustment ring, whereby the friction conditions between the adjustment ring and the bearing bush of the sash hinge can be designed as if the bearing bush were supported directly on the bearing collar of the pivot bearing axis.

In order to achieve a symmetrical design of the bearing band in the area of the bearing collar of the pivot bearing axis, the band is designed so that the guide recesses are at least two diametrically opposite slots or holes in the bearing collar. If more than two slots or holes are provided in the bearing collar, this results in better support in the event of tilting loads on the pivot bearing axis caused by the door or window leaf.

An optimal cross-sectional design of the support feet of the adjusting ring is achieved if the band is designed in such a way that the support feet are projections that are adapted to the outer circumference of the pivot bearing axis and fit into the axis receiving hole of the guide bush. In particular, low surface pressures are achieved between the support feet and the outer circumference of the pivot bearing axis and the support feet make optimal use of the given cross-sectional space in the sense of the greatest possible rigidity.

An advantageous design of the belt with regard to the anti-twisting protection of its pivot bearing axis is when the pivot bearing axis is anti-twisting in the guide bush. Such an anti-twisting protection can be designed in a simple manner without having to intervene in the belt body.

The design of the band is simple in the sense described above, especially if the pivot bearing axis 0 has at least one axially parallel guide rib which engages in a guide groove of the guide bush.

A further development of the hinge is characterized by the fact that the guide bush and/or the bearing bush engages in the sash hinge or the frame hinge, bridging a gap between the frame hinge and the sash hinge. This improves the appearance of the hinge. In addition, the bearing area is better protected against dirt and any bearing abrasion from the inside cannot be removed without

8th
further into the visible area of the tape, so that the outside remains correspondingly uncontaminated.

It is advantageous to design the hinge in such a way that the guide bushing surrounds a bearing bushing of the sash hinge on the outside. As a result, the guide bushing can engage in an annular gap between the guide bushing of the sash hinge and its hinge body. The stability of the guide bushing is not impaired and there is enough radial space so that the guide bushing of the sash hinge can support itself over a sufficiently large area on the bearing collar of the pivot bearing axis.

If the bearing bush is supported on the bearing collar with a ring that seals the gap, the window hinge is designed with a wearing part that can be replaced if necessary. The ring can be mounted on the pivot bearing axis so that it cannot rotate, for example by engaging a guide rib on the pivot bearing axis in a guide groove on the ring. The ring can also serve as an optical cover.

The invention is explained using embodiments shown in the drawing. It shows: 25

Fig.l a longitudinal section through a frame band in the

Center plane of the pivot bearing axis, Fig.2 another embodiment of a belt with

modified design of the guide bush, 0 Fig.3 a third embodiment of a band with

modified direct support of the pivot bearing axis with an adjusting screw and Fig.4 a fourth embodiment in a

Illustration similar to Fig.2, with a

5 swivel bearing axle suspended adjustment

direction for height adjustment of the sash hinge,

Fig.4a is a side view of an adjusting ring of the band of Fig.4, and

0 Fig.4b-4d vertical views of pivot bearing axes,

which in embodiments according to Fig.4 for
can be used.

Fig.l essentially shows the lower part of a door hinge, namely a frame hinge 10, which is connected in an articulated manner to a leaf hinge 13 by means of a pivot bearing axis 12. To attach the door hinge, a fastening tab 10' of the frame hinge 10 and a fastening tab 13' of the leaf hinge 13 are each provided with fastening holes 22, compare Fig.2, through which fastening screws (not shown) are screwed into a leaf frame or into a fixed frame. The load of the leaf is transferred to the frame hinge 10 via the leaf hinge 13.

What all embodiments have in common is that the sash hinge 13 has a bearing bush 24 and the frame hinge has a guide bush 12 for supporting an upper end 12'' or for supporting a lower end 12' of the pivot bearing axis 12. The bearing bush 24 and the guide bush 11 are each arranged within a hinge body 10'' or 13'', respectively, and are thus themselves designed like a sleeve and enclose the bushes 11, 24 on their outer circumference in a radially positive fit and also in an axially positive fit to the extent described below.

The bore 25 for receiving the guide bush 11 is formed on the sash hinge side with a central extension 26, within which an annular bearing bead 27 of the guide bush 12 is arranged. The bearing bead 27 is supported according to Fig. 1, 2 with a truncated cone surface on a corresponding truncated cone surface 28 of the guide bush 11, whereby both cone angles are the same size and the truncated cones taper vertically downwards. As a result, vertical loads on the guide bush 11, 5 that originate from the sash hinge 13 are transferred to the frame hinge body 10" at this point.

Below the bead 27 is the guide bush 11

circular-cylindrical. At its lower end 11', the guide bush 11 is surrounded by an annular extension of the

10
band body 10'', into which, for example, a

A clamping part made of plastic can be used to secure the guide bush 11 against twisting within the hinge body 10''.
5

In Fig.2, the design of the guide bush 11 with regard to the load transfer to the belt body 13'' is the same as in Fig.1. However, on its outer circumference located under the bead 27, the guide bush 11 is provided with longitudinal grooves 29 evenly distributed over the circumference in order to save material, the lower ends 29' of which can be used to force-fit locking projections, which are arranged on a ring surrounding the lower end of the guide bush 11 and, after being inserted, ensure that the guide bush 11 cannot rotate relative to the belt body 13''.

The load from the sash hinge 13 is transferred by the bearing bush 24 of the sash hinge 13, which is supported with its hinge body 13'' by means of a conical bearing surface 13 ''' on a bearing ring surface 24'' of the bearing bush 24. Both surfaces have the same cone angle. The bearing bush 24 is supported with an end face 24''' on a bearing collar 30 of the pivot bearing axis 12. The bearing collar 30 projects beyond the 5 outer circumference of the pivot bearing axis 12 to such an extent that a sufficiently large support surface is created for the bearing bush 24, namely an annular surface on which the specific surface pressure is small enough to transfer the loads resulting from the load on the sash hinge 13 without causing unacceptable abrasion when the sash hinge 13 pivots. The coefficient of friction between the bearing bush 24 and the bearing collar 30 is so low that only minimal wear occurs and the forces required to move the door leaf remain small.

The bearing collar 30 engages in a corresponding ring-shaped recess 31 of the bearing bush 11, whereby the former is so high that even the lowest position of the height-adjustable pivot bearing axis 12 does not lead to the bearing collar 30 coming to rest on the guide bush 11. Also in the

11
lowest position of the pivot bearing axis 12, the

Bearing collar 30 the upper edge of the guide bush 11 so that the predetermined support of the bearing bush 24 on the bearing collar 30 is always ensured.
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In all relative positions of the bearing bush 24 or the sash hinge 13 to the frame hinge 11, an annular gap 23 is formed between the two, which is larger or smaller depending on the axial position of the pivot bearing axis 12.

Fig.2 shows an embodiment in which the annular gap 23 is closed with the guide bush 11. For this purpose, the guide bush 11 has an annular projection YS.''' which engages between the band body 13 '' and the bearing bush 24. To accommodate the annular projection H''' , the bearing bush 24 is provided with an annular recess so that its outer circumference from the adjacent inner circumference of the band body 13'' is at the distance required to accommodate the annular projection 11'''. The annular projection YS.''' surrounds the bearing collar 30 on the outside so that the latter can have the same outer diameter as the bearing bush 24, whereby the support conditions or the friction conditions between the bearing bush 24 and the bearing collar 30 are not impaired. Any abrasion that occurs in this area cannot penetrate outwards through the gap 23 because it is prevented from doing so by the annular projection YS.''' .

In order to prevent the pivot bearing axis 12 from being twisted due to friction during pivoting movements of the sash hinge 13, the pivot bearing axis 12 is secured against relative rotation within its guide bushing 11. Guide ribs 20 serve to prevent rotation. There are two diametrically opposed guide ribs 20, each of which engages in a guide groove 21 formed in the guide bushing 11. The vertical engagement of the guide ribs 20 in the guide grooves 21 is just as large as the vertical engagement of the bearing collar 30 in the recess 31 of the guide bushing 11.

12
The vertical adjustability of the pivot bearing axis 12

is achieved in the embodiments of Fig. 1, 2 with an adjusting screw 14. The adjusting screw 14 engages with its screw shaft in an internal threaded hole 15, which is arranged coaxially with the pivot bearing axis 12. The internal threaded hole 15 is so deep that the adjusting screw 14 can be screwed in completely and even when unscrewed to the maximum extent has a sufficiently deep thread engagement in order to be able to transfer the forces arising from the pivot bearing axis 12 to the adjusting screw 14.

The adjusting screw 14 is designed as a cap screw with a head 16 that is supported on the guide bush 11. The support is provided by an annular collar 17 of the guide bush 11, which engages under the pivot bearing axis 12. The head 16 is supported in a guide recess 19, whereby the guide recess 19 is designed in such a way that the head 16 is guided radially, so that lateral displacements are excluded. As a result, the head 16 can also serve to stabilize the radial position of the pivot bearing axis 19. This is advantageous, for example, in the case of Fig. 2, where the outer diameter of the head 16 is smaller than the inner diameter of the bore 32 of the guide bush 11. With this design of the adjustment device of the pivot bearing axis 12, the outer diameter of the head 16 could also be selected so that it is equal to the inner diameter of the bore 32, so that the adjusting screw 14 is guided radially over the entire height of its head 16.

Fig. 1 shows a special feature with regard to the interaction of the pivot bearing axis 12 and the adjusting screw 14 in that it has a guide recess 18 into which the head 16 of the adjusting screw 14 is fitted. As a result, the end 12' of the pivot bearing axis 12 extends into the immediate vicinity of the annular collar 17 of the guide bush 11.

The collar 17 of the guide bush 11 is provided with an insertion opening 33 into which an adjusting key can be inserted with one end until it engages in a non-circular recess 34 of the adjusting screw 14, which in

whose head 16 is present. The non-circular recess 3 4 is, for example, a hexagon socket recess. Depending on the direction of rotation of the adjustment key and the direction of the thread engagement of the adjusting screw 14 in the internal threaded hole 15, the pivot bearing axis 12 is raised or lowered. A left-hand thread engagement is preferred so that the pivot bearing axis 12 is raised when the adjusting screw 14 is adjusted clockwise.

In Fig. 3, 4 different embodiments of the invention are shown, in which, however, the design of the sash hinge 13 is or can be identical to that of Fig. 1, 2. Accordingly, the same reference numerals are used for corresponding components. This also applies to the frame hinges 10 of Fig. 3, 4. The advantages that were described for the hinges of Fig. 1, 2 also apply to the hinges of Fig. 3, 4. With regard to Fig. 3, it should be noted that its guide bush 11 has an anti-twist device in the hinge body 10'', as was described for Fig. 1, 2, i.e. with axially parallel guide ribs 20 that engage in corresponding guide grooves 21 of the guide bush 11.

With regard to the height adjustment, the embodiment of Fig. 3 differs from that of Fig. 1, 2 by 5 an adjusting screw 14, which is designed as a headless screw. It is screwed with an external thread 40 into an internal thread 3 5 of the guide bush 11. The internal thread 3 5 is located in an annular collar 17 that engages under the pivot bearing axis 12 and is provided with an insertion opening 33 for an adjustment key that can engage in an internal non-circular recess 34 of the adjusting screw 14. The adjusting screw 14 can be screwed axially with its end face 41 against the annular collar 17. The pivot bearing axis 12 and thus the sash hinge 13 then have the lowest possible position. In this position too, the opposite end face 42 protrudes into the receiving space 3 9 for the pivot bearing axis 12. As a result, the front surface 42 can support the pivot bearing axis 12 over its entire surface, with an insertion chamfer 43 of the pivot bearing axis 12 being designed such that

that the size of the front surface 44 approximately corresponds to the size of the front surface 42 of the adjusting screw 14.

In the hinge of Fig.4, the pivot bearing axle 12 is supported with its bearing collar 30 on an end face 24''' of the bearing bush 11 facing the leaf hinge 13. The loads on the pivot bearing axle 12 result from a screw adjustment engagement of an adjustment screw 14 in an internal threaded bore 15 of the pivot bearing axle and in this engagement the internal threaded bore 15 and the adjusting screw 14 are essentially designed as described for Fig.1. The head 16 of the adjusting screw 14 is, however, designed as a round head with a radius such that its outer circumference 16' fits into the axle receiving bore 39 and is radially supported by it. The lower end 12' of the pivot bearing axis 12 is therefore extended by the adjusting screw 14 with respect to the guide of the pivot bearing axis 12 within the guide bush 11. The adjusting screw 14 is adjusted by means of a non-circular recess 34 as described above, for which purpose the pivot bearing axis 12 can also have a non-circular recess 45 at its upper end 12'' in order to hold the pivot bearing axis 12 in place or to also influence the adjustment.

The special feature of the height adjustment shown in Fig.4 is that an adjustment sleeve 36 is present as an adjustment element, which radially surrounds the lower end 12' of the pivot bearing axis 12 and is arranged between this and the guide bush 11 and is supported radially. Only its lower sleeve end 36', which projects beyond the end 12', is supported radially exclusively by the guide bush 11. The sleeve end 36' is supported on the head surface of the head 16 of the adjusting screw 14 on the pivot bearing axis side, so that the adjustment sleeve 3 6 is raised when the adjusting screw 14 is screwed into the internal thread 15 and is lowered as a result of its load by the sash hinge 13 when the adjusting screw 14 is unscrewed from the internal thread 15.

15
The upper sleeve end 36'' is below the bearing collar

30 and serves to support an adjusting ring 37, which is shown separately in Fig. 4a. The adjusting ring 37 therefore has a bore 47 with which it surrounds the upper end 12'' of the pivot bearing axis 12. Furthermore, there are support feet 38 that project vertically to the adjusting ring 37 and that protrude through guide recesses 46 of the bearing collar 30 to the upper end 36'' of the adjusting sleeve 36. In Fig. 4a, two diametrically opposed support feet 38 are arranged.

Fig. 4b-4d show different designs of the pivot bearing axis 12 in the area of its bearing collar 30. Fig. 4b shows a bearing collar 30 provided with slots 46, so that the bearing collar 30 consists of only two segments arranged diametrically opposite one another. The bearing collars 30 of Fig. 4c, 4d show holes 48. The holes 48 of the bearing collar 30 of Fig. 4c extend over approximately 90 degrees of the total circumference, the holes 48 of the bearing collar 30 of Fig. 4d over approximately 45 degrees. Accordingly, only two holes 48 are shown in Fig. 4c, whereas four are shown in Fig. 4d. From the design of the holes 48 it can be seen that the support feet 38 are adapted to the outer circumference of the pivot bearing axis 12. In addition, the support feet 38 are designed in such a way that they fit radially into the axle receiving bore 39 of the guide bushing 11, so that the adjusting ring 37 is guided radially in the guide bushing 11 and also in the guide recesses formed by the slots 46 or holes 48.

Any adjustment movements of the adjustment sleeve 3 6 thus cause, via the support feet 3 8, corresponding height adjustments of the adjustment ring 37, which rests on the bearing bush 24 of the sash hinge 13, so that the latter is adjusted accordingly in height.

Claims (22)

02.03.1998 Claims: 1. Door or window hinge, with a frame hinge (10) to be attached to a fixed frame, which axially supports a guide bush (11) which receives one end (12') of a pivot bearing axis (12), the other end (12'') of which serves to support a sash hinge (13), and with an adjusting screw (14), by turning which the axial position of the pivot bearing axis (12) relative to the frame hinge (10) can be adjusted, characterized in that the adjusting screw (14) is arranged within the guide bush (11) and from there axially supports the pivot bearing axis (12). 2. Door or window hinge according to claim 1, characterized in that the adjusting screw (14) is in threaded engagement with the pivot bearing axis (12). 3. Door or window hinge according to claim 1 or 2, characterized in that the adjusting screw (14) engages in an internally threaded bore (15) coaxial with the pivot bearing axis (12). 4. Door or window hinge according to one or more of claims 1 to 3, characterized in that the Adjusting screw (14) is supported on an annular collar (17) of the guide bush (11) which engages under the pivot bearing axis (12).
40 5. Door or window hinge according to one or more of claims 1 to 4, characterized in that the adjusting screw (14) is a head screw, the head (16) of which serves to support the annular collar (17). 6. Door or window hinge according to one or more of claims 1 to 5, characterized in that the adjusting screw (14) is a round-head screw. 7. Door or window hinge according to one or more of claims 1 to 6, characterized in that the head (16) of the adjusting screw (14) is fitted into a guide recess (18) of the pivot bearing axis (12). 8. Door or window hinge according to one or more of claims 1 to 7, characterized in that the adjusting screw (14) is supported, if necessary, with its head (16) in a guide recess (19) of the annular collar (17) engaging under the pivot bearing axis (12) or on a 0 over the entire available flat annular collar surface. 9. Door or window hinge according to one or more of claims 1 to 8, characterized in that the guide bushing (11) is a metal bushing or, if required, a fiber-reinforced plastic bushing. 10. Door or window hinge according to one or more of claims 1 to 9, characterized in that the pivot bearing axis (12) is secured against rotation. 11. Door or window hinge according to one or more of claims 1 to 10, characterized in that the adjusting screw (14) is rotatably adjustable in an internal thread (35) of the guide bush (11) and directly supports the pivot bearing axis (12). 12. Door or window hinge according to one or more of claims 1 to 11, characterized in that the adjusting screw (14) is supported by a ring collar (17) of the guide 3
bushing (11) is secured against loss and the adjusting screw (14) is longer, if necessary, than the internal thread (35) of the guide bushing (11). 13. Door or window hinge according to one or more of claims 1 to 12, characterized in that the pivot bearing axis supported on the frame hinge (10) (12) threadedly engaged adjusting screw (14) supports an adjustment element which causes a height adjustment of the sash hinge (13) corresponding to a rotational adjustment of the adjusting screw (14). 14. Door or window hinge according to one or more of claims 1 to 13, characterized in that the adjusting element is an adjusting sleeve (36) supported on a head (16) of the adjusting screw (14) and arranged in a radially supporting manner between the lower end (12') of the pivot bearing axis (12) and the guide bush (11). 15. Door or window hinge according to one or more of claims 1 to 14, characterized in that the adjusting sleeve (36) ends below a bearing collar (30) of the pivot bearing axis (12) resting on the guide bush (11), and that the bearing bush (24) of the sash hinge (13) is supported by an adjusting ring (37) which is supported on the adjusting sleeve (36) by support feet (38) through guide recesses in the bearing collar (30). 16. Door or window hinge according to one or more of claims 1 to 15, characterized in that the guide recesses (39) have at least two diametrically opposite slots (46) or holes (48) of the Camp Federation (30). 17. Door or window hinge according to one or more of claims 1 to 16, characterized in that the support feet (38) are aligned with the outer circumference of the pivot bearing axis 4
(12) are projections which fit into the axle receiving bore (39) of the guide bush (11). 18. Door or window hinge according to one or more of claims 1 to 17, characterized in that the pivot bearing axis (12) is secured against rotation in the guide bush (11). 19. Door or window hinge according to one or more of claims 1 to 18, characterized in that the pivot bearing axis (12) has at least one axially parallel guide rib (20) which engages in a guide groove (21) of the guide bush (11). 20. Door or window hinge according to one or more of claims 1 to 19, characterized in that the guide bush (11) and/or the bearing bush (24) engages in the sash hinge (13) or in the frame hinge (10) bridging a gap (23) present between the frame hinge (10) and the sash hinge (13). 21. Door or window hinge according to one or more of claims 1 to 20, characterized in that the guide bush (11) engages around a bearing bush (24) of the sash hinge (13) on the outside. 22. Door or window hinge according to one or more of claims 1 to 21, characterized in that the bearing bush (24) is supported on the bearing collar (30) by a ring sealing the gap (23).