EP0006440A2 - Adjustable pivot bearing for windows, doors and the like able both to pivot about a vertical axis and tilt about a horizontal one - Google Patents

Abstract

1. Adjustable corner mounting for side and top hung window or door units and the like with a bracket (11) which fits into a drill hole of the fixed frame designed to be screwed or bolted on the fixed frame by means of a bracket plate (1) and with at least one threaded member (8) projecting backwards through the bracket plate (1), which has a joint bolt pin (18) which can be tilted about the horizontal axis and which engages as a support into a link arranged on the unit in alignment with its lateral vertical axis (6-6) in such a manner that the bracket (11) can be adjusted using the threaded member (8) relative to the bracket plate (1) and at right angles to the plane of the fixed frame, characterised by the fact that the bracket plate (1) is fitted across the front with rigid projecting guide cams (5) which the bracket (11) embraces in a lock with guiding rocker arms (12) moulded on the back, that the threaded member (8) on the one hand only pivots in the bracket plate (1 ; Fig. 3), but cannot be adjusted, whilst on the other hand it engages axially relatively adjustably by rotation (11 ; Fig. 3), that the guide cams (5) are formed by two parallel pivots which project extend into the appropriate guide holes (12) in the bracket (11) whilst the threaded member (8) swivels between these pivots (5) in the bracket plate (1) and engages into the drill hole in the fixed frame (Figs. 2 and 3) by means of a projecting smooth one-piece extension shaft (9), and that the bracket plate (1) and bracket (11) above the guide holes (12) and guide cams (5) each have fastening holes (4, 13) through which the fastening bolts can be passed into the fixed frame (Fig. 4).

Description

b) Teelin area

The innovation relates to a corner bearing for turn-tilt sashes of windows, doors or the like with a screwable to the fixed frame via a support plate and with at least one support pin or pin projecting from the rear of the support plate and engaging in a bore of the fixed frame, the one about a horizontal axis pivotable hinge pin, which engages supportingly in an articulated band aligned on the wing with its lateral vertical axis of rotation, the bearing block being adjustable relative to the support plate and transversely to the plane of the fixed frame via a threaded member.

Corner bearings of this type are regularly used in tilt-and-turn windows and doors when it is important to be able to regulate the seal contact pressure of the closed wing relative to the fixed frame at any time - even retrospectively - as required.

In practical use of the tilt-and-turn windows and doors, it often happens that the construction material used to build the sash and frame, especially wood and plastic, works due to the effects of the weather and inevitably follows undesirable changes in the sealing relationship between sash and frame pulls itself. These must be balanced out if the windows and doors are to function optimally at all times.

A permanently perfect function of the windows and doors also requires that the corner bearing maintains a permanently secure fit on the fixed frame even under the influence of heavy-duty sashes. To ensure this, the corner bearings are therefore not only screwed to the fixed frame via a support plate, but the support plate is also provided with at least one support pin or pin projecting from the rear, which fits into a hole in the fixed frame.

c) State of the art

From DE-Gbm 17 83 611 a corner bearing is already known, which can be screwed onto the fixed frame via a support plate and the like the bearing bracket, which can be tilted about a horizontal axis, is adjustable relative to the support plate and transversely to the plane of the fixed frame by means of a threaded member.

The desirable adjustment of the bearing block can, however, only be carried out here after the hinge band, which is aligned with the lateral, vertical axis of rotation of the wing, has previously been disengaged from the hinge pin supported by the bearing block.

A structurally similar corner bearing is also known from DE-Gbm 18 65 421.

By DE-OS 25 27 348 but also corner bearings are already part of the prior art, in which the bearing bracket held by a support plate and the pivot pin pivotable about a horizontal axis adjust relative to the support plate and transversely to the level of the fixed frame via a threaded member lets without having to unhook the hinge hinge aligned with the lateral, vertical axis of rotation of the wing for this purpose from the hinge pin.

In this case, however, the support plate cannot simply be screwed onto the end face of the fixed frame on the room side. Rather, it must be let into a relatively large and deep recess, which at the relevant corner of the fixed frame, for. B. is to be produced by a milling process.

Such a corner bearing version has a high load-bearing capacity. speed and can also be easily manipulated for the purpose of regulating the sealing contact pressure for the wing. The work involved in milling the recess on the corner of the frame is, however, relatively high and such a milling can not be provided regularly in the corner area of the fixed frame, even in the case of windows made of hollow plastic profiles.

In order to increase the load-bearing capacity of corner bearings of the two known embodiments mentioned first, their support plate has already been provided with at least one, but preferably two, rear projecting support bolts or journals which can be inserted into simple bores in the fixed frame. Such holes can be made not only on fixed frames made of wood but also on those that are composed of hollow plastic profiles, easily and safely.

d) Description of the innovation

There is now a need to have corner bearings for turn-tilt sashes for windows, doors or the like available, which do not adhere to the shortcomings of the various known embodiments, but which combine their respective advantages. The innovation is therefore based on the task of creating a spatial shape for a corner bearing of the type explained in the introduction, which can easily be attached to the fixed frame with a high load-bearing capacity but an adjustment of the sealing system between the sash and the fixed frame enables the hinged hinge of the sash to be removed from the tiltable hinge pin of the corner bearing.

The solution to this problem is guaranteed by the innovation by the characterizing features of claim 1.

This also has the advantage that the bearing block can be regulated practically continuously relative to the support plate and thus a very sensitive influence on the sealing system between the sash and the fixed frame can be achieved.

A structurally particularly simple embodiment for a corner bearing of high load-bearing capacity can be created by using the features of one or more of claims 2 to 5.

An even more sophisticated design for a corner bearing according to the invention can be created by using the features of claim 6. It is recommended to also use the features indicated in claim 7.

Any right and left stop for these corner bearings can be realized by the features of claims 8 and 9.

A two-dimensional adjustability of the corner bearing, that is additional possibility of regulating the position of the wing relative to the fixed frame parallel to its main plane can be achieved with practically no appreciable increase in size if the features of one of claims 10 and 11 before. be seen. Through simultaneous use of the features shown in claims 10 and 11, there is even a three-dimensional adjustability for the corner bearing.

e) Description of the drawing figures

• Fig. 1 shows a preferred embodiment of a corner bearing for turn-tilt sashes of windows, doors or the like in front view.
• 2 shows the corner bearing according to FIG. 1 in a side view,
• 3 shows a section of the corner bearing according to FIG. 1 along the line III-III,
• Fig. 4 shows a section through the corner bearing along the line IV-IV in Fig. 1 and
• Fig. 5 shows the corner bearing according to Figures 1 to 4 in plan view.
• 6 shows another advantageous corner bearing design in a view from the front,
• Fig. 7 shows the corner bearing of Fig. 6 in section along the line VII - VII and
• Fig. 8 shows a top view of the corner bearing according to FIGS. 6 and 7 again.

f) Ways to implement the innovation

The corner bearing shown in FIGS. 1 to 5 has a flat support plate 1 stamped from sheet metal with a vertical screw-on tab 1 'and two adjoining it in one piece to its lower end. screwing tabs 1 "directed on opposite sides, in such a way that this support plate 1 has approximately the outline shape of an inverted T ..

The screw-on tab 1 'of the support plate 1 has two overlying valleys 2, one above the other, by means of which it can be fastened by means of countersunk screws on the frame-side visible surface. On the rear, a support bolt or pin 3 is rigidly attached to the screw-on tab 1 'in the area between the two countersunk holes 2 and can be inserted into a suitable hole in the fixed frame.

Each of the two screw-on tabs 1 ″ of the support plate 1 is provided with a punched-out hole 4 near its upper boundary edge, while it carries a guide pin 5 projecting forward in the vicinity of its lower edge.

At the intersection of the normal symmetry plane 6-6 of the screw-on tab 1 'normal to the main plane of the support plate 1 with the horizontal plane of symmetry 7-7 of the two screw-on tabs 1 ", which is also normal to the main plane of the support plate 1, is rotatable in the support plate 1, but axially immovable mounted in the same direction as the two guide pins 5 via this protruding threaded member 8, which has a smooth extension shaft 9 integrally molded on backwards. The transverse shape and length of this extension shaft 9 correspond to the supporting bolt or pin 3, whereby it also fits into a suitable bore on the fixed one Frame is inserted.

With the threaded member 8 of the support plate 1, a bearing block 11 is in adjusting engagement via a corresponding internal thread 10, which is supported by the guide pins 5 of the support plate 1 in a rotationally fixed but slidable manner by means of two guide holes 12.

Above the guide holes 12, the bearing block 11 is also provided with a countersunk hole 13, said countersunk hole 13 being aligned with the through holes 4 of the support plate 1 and together with these serving to receive countersunk screws which can be screwed into the fixed frame.

The bearing block 11 is provided with two upwardly directed, mutually parallel fork legs 14, which form bearing eyes for a rotatable but axially immovable threaded member 15 which extends in the horizontal direction and parallel to the plane of the fixed frame or the support plate 1.

This threaded member is in permanent engagement via an adapted internal thread 16 with the bearing tab 17 of an upwardly directed hinge pin 18, in such a way that the hinge pin 18 on the one hand can be tilted forward at least by a limited angle relative to the threaded member 15, while on the other hand by corresponding rotation of the Threaded member 15 can be adjusted continuously to the right or to the left by a limited amount between the fork legs 14.

The hinge pin 18 engages from below in an articulated band arranged on the wing with its lateral vertical axis of rotation in a supporting manner (not shown).

By rotating the threaded member 15 relative to the fork legs ln 14 of the bearing block 11 forming the bearing eyes for this purpose, the lateral, vertical axis of rotation of the wing can thus be displaced parallel to the plane of the fixed frame. On the other hand, by rotating the threaded member 8 relative to the bearing block 11, this bearing block 11 can be adjusted transversely to the plane of the fixed frame relative to the support plate 1 and thus cause a corresponding displacement of the lateral, perpendicular axis of rotation for the wing relative to the fixed frame.

So that the resulting from the sash weight and the Ge steering pin 18 introduced into the corner bearing force effects not only have to be absorbed or intercepted by the guide pin 5 and the threaded member 8, the two fork legs 14 of the bearing Bockes 11 each provided with rearward-facing strips 19, which support overlap with their lower end surface 20, the upward-facing edge surfaces 21 of the two screw-on flaps 1 ", while their longitudinal surfaces 22 also abut the side-facing edge surfaces 23 of the screw-on flap 1".

The high load-bearing capacity of the corner bearing design according to FIGS. 1 to 5 is achieved in that it can be anchored on the one hand by means of four screws to the fixed frame, while in addition the support bolt or pin 3 and the extension shaft 9 are inserted into the same in relatively deep holes are. Due to the structurally symmetrical design of the corner bearing relative to the vertical normal plane (6-6, this is easily suitable for optional right and left hinging. It is also important that all the elements of the corner bearing necessary for positional adjustment of the sash lie in front of the end face of the fixed frame on the room side and require no installation space within the frame profile.

The corner bearing design shown in FIGS. 6 to 8 has - seen in principle - the same functional parts as the corner bearing according to FIGS. 1 to 5. Only with regard to the active connection between the bearing block 11 and the support plate 1, on the one hand, and with regard to Active connection of the threaded member 8 with the bearing block 11 and the support plate 1 on the other hand, there are structural differences.

In the corner bearing according to FIGS. 6 to 8, the support plate 1 with the supporting bolt or pin 3 and the extension shaft 9 is in one piece Molded part made of die-cast. Coaxial to the extension shaft 9, a polygonal projection 25 protruding from its front, for example of a square outline, is molded onto the support plate 1 as a guide cam for the bearing block 11. This polygonal extension 25 contains a bore 26, to which an internal thread 27 is connected within the extension shaft 9.

From the rear, a polygonal recess 28, which is adapted to the cross-section 25 in cross-section, is formed in the bearing block 11 and is concentric with it. Bearing bracket 11 a neck 29. By means of the polygonal recess 28, the bearing bracket 11 is rotatably but axially displaceably guided on the polygonal extension 25 of the support plate 1, while its neck 29 fits into the bore 26 of the multi-sided extension 25.

The threaded member 8 is formed by a cylinder head screw, the head part 30 of which is received in a cylindrical extension 31 of the extension shaft 9. The threaded section 32 of the threaded member 8 adjoining the cylinder head 30 is in permanent engagement with the internal thread 27 of the extension shaft 9, while a smooth shaft section 33 of the same passes through the neck 29 of the bearing block 11 so that it can rotate but cannot be axially displaced. A support ring 34 connected to the free end of the smooth shaft section 33 is received flush in a recess 35 on the end face of the bearing block 11. This support ring 34 is preferably firmly riveted to the smooth shaft portion 33 of the threaded member 8, a polygonal recess 36, for example an internal hexagon, of the thread in the region of the riveting member 8 opens into which an adjusting tool can be brought into engagement. When the threaded member 8 is actuated by the adjusting tool, it moves together with the bearing block 11 relative to the support plate 1 or to the extension shaft 9 thereof in the axial direction.

In Fig. 7 is also indicated how the hinge attached to the wing 37 can interact with the hinge pin 18 of the corner bearing. It is supported by a bearing shell 38 on the upper end of the hinge pin 18. Here is the. Bearing shell 38 rotatably, but supported axially adjustable by an adjusting screw 39 in the bearing bore 40 of the hinge 37, such that the hinge 37 is displaced in the axial direction relative to the hinge pin 18 by rotating the adjusting screw 39. In this way, a three-dimensional adjustability of the wing can be realized via the corner bearing.

g) The commercial area of use

The corner bearing designs described above can be used in conjunction with tilt-and-turn sashes of windows, doors or the like wherever an easy-to-manipulate adjustability of the installed sash is important, but at the same time a high load-bearing capacity of the corner bearing must be ensured without Excessively large recesses must be provided in the fixed frame.

h) List of reference symbols

• 1 support plate
• 1 ', 1 "screw-on tab
• 2 countersinks r
• 3 support bolts or pins
• 4 holes
• 5 guide pins
• 6 vertical planes of symmetry
• 7 horizontal planes of symmetry
• 8 threaded link
• 9 extension shaft
• 10 internal threads
• 11 bearing block
• 12 pilot holes
• 13 sinkholes r
• 14 fork legs
• 15 threaded link
• 16 internal threads
• 17 bearing rags
• 18 hinge pin
• 19 lasts
• 20 end face
• 21 edge surfaces
• 22 longitudinal surfaces
• 23 edge surfaces
• 25 polygonal approach
• 26 hole
• 27 internal thread
• 28 polygonal recess
• 29 neck
• 30 head
• 31 extension
• 32 threaded section
• 33 shaft section
• 34 support ring
• 35 deepening
• 36 Chamber of Commerce deepening
• 37 wrist band
• 38 bearing shell
• 39 adjusting screw
• 40 bearing bore

Claims (11)

1 . Corner bearing for turn-and-tilt sashes of windows, doors or the like with a screwable to the fixed frame via a support plate and with at least one support pin or pin protruding from the rear of the support plate into a bore of the fixed frame, which engages one by one horizontal axis tiltable hinge pin, which in a on the wing with its side. articulated ligament, which is aligned on the right, intervenes in a supporting manner. wherein the bearing block can be hidden relative to the support plate and transversely to the level of the fixed frame via a threaded member,
characterized,
that the support plate (1) with parallel to the axial direction of the threaded member (8) on its front, rigid guide cams (5 and 25) is provided, which the bearing block (11) with rear-molded guide links (12 and 28), form-fitting , and that the threaded link (8) on the one hand either rotatably but immovably in the bearing block (11; Fig. 7) or in the support plate (1; Fig. 3), while on the other hand it is axially relatively adjustable by rotation either in the support plate (1; Fig. 7) or in the bearing block ( 11, Fig. ₃ ) engages. 2. corner bearing according to claim 1,
characterized,
that the guide cams are formed by two parallel pins (5) which protrude into matching guide holes (12) of the bearing block (11), while the threaded member (8) between these pins (5) in the support plate (1) only rotatably and with a smooth extension shaft (9) integrally molded to the rear engages in the bore of the fixed frame (FIGS. 2 and 3). 3. corner bearing according to claims 1 and 2,
characterized,
that the support plate (1) above the two guide pins (5) and the bearing block (11) above the guide holes (12) each have through holes (4 and 13) through which the fastening screws can be screwed into the fixed frame (Fig. 4). 4. corner bearing according to claims 1 to 3,
characterized,
that the bearing block (11) on its the hinge pin (18) can be tilted Bearing fork legs (14) are each provided with rearward-facing strips (19) which support overlap with their lower end surface (20) upward-facing edge surfaces (21) of the support plate (1), while their longitudinal surfaces (22) on side-facing edge surfaces (23) of the support plate (1). 5. corner bearing according to claims 1 to 4,
characterized,
that the support plate consists of a sheet metal stamped part. on which the two guide pins (5) are fixed in a rotationally fixed manner, while the threaded member (8) and its extension shaft (9) are rotatably riveted therein. (6. corner bearing according to claim 1,
characterized,
that the guide cam is formed by a polygonal projection (25) of the support plate (1) which engages in a corresponding polygonal recess (28) of the bearing block (11) and has a coaxial bore (26) into which a neck (29) of the bearing block ( 11) protrudes, wherein in the neck (29) of the bearing block (11) the threaded member (8) with a smooth shaft section (33) is only rotatably supported, while it engages with its threaded section (32) in a threaded bore (27) which is in is in the bore of the fixed frame protruding extension (9) of the support plate (1). 7. corner bearing according to claims 1 and 6,
characterized,
that the support plate (1) with the guide cam (25) and the extension shaft (9) forms a one-piece molding made of die-cast. 8. corner bearing according to claims 1 to 7,
characterized,
that the support plate (1) and the bearing block (11) to a normal to the plane of the fixed frame and vertical plane (6-6-) are symmetrical (Fig. 1 and 6). 9. corner bearing according to claims 1 to 8,
characterized,
that the support plate (1) has approximately the outline shape of an inverted T and the bearing block (11) is held in the region of the two screw-on tabs (1 ") forming T-legs. 10. corner bearing according to claims 1 to 9,
characterized,
that the horizontal hinge axis holding the hinge pin (18) tiltably in the bearing block (11) is formed by a second threaded member (15) which is only rotatably seated in the bearing block (11) and which has a counter thread (16) in a bore of the hinge pin (18) is in positive engagement. 11. corner bearing according to claims 1 to 10,
characterized,
that the articulated hinge (37) on the wing contains in its bearing bore (40) comprising the pivot pin (18) a non-rotatable but axially displaceable bearing socket (38) which can be adjusted and locked axially parallel to the bearing bore (40) by means of a set screw (39) .

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