EP1109983A1

EP1109983A1 - Screw-on hinge with blocked position

Info

Publication number: EP1109983A1
Application number: EP99941634A
Authority: EP
Inventors: Dieter Ramsauer
Original assignee: Individual
Current assignee: Individual
Priority date: 1998-09-02
Filing date: 1999-08-17
Publication date: 2001-06-27
Anticipated expiration: 2019-08-17
Also published as: DE29815747U1; US6568032B1; WO2000014371A1; DE59903199D1; EP1109983B1; DE19981699D2

Abstract

The invention relates to a screw-on hinge (10) for a door or shutter (16) which is vertically or horizontally mounted on a frame or wall (12) in a pivoting manner, which removably holds the door or shutter (16) in at least one pivot-angle position (-5°; +85°; +175°). Said screw-on hinge consists of a first hinge part (18) which can, for example, be fixed to the frame, and a second hinge part (24) which can, for example, be fixed to the door or shutter (16). Said hinge parts (18, 24) are both symmetrical about their bisecting line and each have a hole (26, 28) for receiving a hinge pin system (30). The hinge pin system comprises a sleeve (34) which is connected to the one hinge part (18) in a non-rotating manner, a spring detent element being positioned between said sleeve (34) and the other hinge part (24). According to the invention the hinge pin system (30) has two parts. The one end of the one hinge part which faces the other hinge part forms the detent element and said detent element is embodied by a face of the sleeve and comprises a helical compression spring (52) which is axially positioned inside the sleeve.

Description

Screw-on hinge with locking position

Technical field:

The invention relates to a screw hinge for a vertically or horizontally arranged on a frame or wall pivotable door or flap, in which the door or flap is releasably held in at least one pivoting angle position, consisting of a first z. B. hinge part attachable to the frame, and a second z. B. attachable to the door or flap hinge part, the hinge parts are each symmetrical about their bisector and each include a bore for receiving a hinge pin assembly, the hinge pin assembly comprising a sleeve which is rotationally rigidly connected to one hinge part and between which sleeve and the other Hinge part a resilient locking device is arranged.

State of the art:

Such a screw-on hinge is described in US Pat. No. 5,412,842. The known hinge makes it possible to hold a door releasably at a predetermined position relative to the frame when the door is pivoted for the purpose of opening or closing. In the known arrangement, countersunk radial bores are provided on the sleeve, into which spring-loaded balls can enter. With the arrival of the ball, the sleeve and thus the hinge part (hinge flap) connected to this sleeve, and thus in turn the door, is held in the corresponding position with a force which is dependent on the spring tension and depends on the run-up angle of the ball. To accommodate the spring, in one hinge part radially aligned to the hinge axis bore spaces are provided, which open at one end to the sleeve and receive the ball there, while the other end of the bore can be closed by a slide, on which the Supports compression spring. The disadvantage here is that a special configuration of the at least one hinge part (hinge flap) is necessary, which special configuration leads to an increased overall height of the hinge part. There are also a relatively large number of components; in the embodiment shown in the document, there are a total of three balls, three compression springs and an insertable holding plate which are necessary in order to achieve the desired result. There are also difficulties with the assembly, because balls, compression springs and plate can only be installed when the sleeve-shaped hinge pin with the inlet openings for the balls is in place within the two hinge parts. Another disadvantage of the ball is the punctiform pressure point, which leads to high surface pressure and rapid material wear.

From DE 29 41 860 A1, a hinge consisting of two hinge parts is known, in which the hinge pin is formed by a sleeve in which a compression spring is arranged, which protrudes the end of the sleeve which is connected to the one hinge part in a rotationally rigid manner against an in the other hinge part arranged, provided with radial notches presses to obtain an elastic locking at certain angles of rotation. It is disadvantageous that the two hinge parts cannot be axially fixed to one another and the hinge can therefore only be used in conjunction with a second hinge of the same type which is designed in opposite directions (p. 6, lines 16-21).

From DE 24 18 147 a hinge for a motor vehicle door with two hinge parts carrying cooperating seat surfaces centered by a hinge pin is known. To determine in an open position, the seats with notches or protrusions are pressed against each other by the door weight or by springs (p. 2, line 14) which are not explained in more detail. One hinge part encloses the other in a fork shape. DE 23 42 945 also describes a hinge for a motor vehicle door, which has a locking device. A spiral compression spring 10, which can be reinforced by a second coaxially arranged compression spring 9, is provided with radial depressions, with the one hinge part 3 rotationally rigidly connected control plates pressed against pins 11, 12 which are guided transversely through the hinge pin 6, which hinge pins are rotationally rigid with the other Hinge part 1 are connected.

The hinge of EP 0 266 490 B1, see FIG. 4, shows two mutually directed plate spring assemblies held by a screw, provided for a lockable vehicle door.

DE-OS 22 35 555 discloses for a hinge with locking hinge straps with coaxial and arranged on the hinge pin (plate) springs (claim 2).

DE 31 26 933 A1 is concerned with a hinge band for doors that enables latching positions. A locking force is exerted by the residual closing pressure (p. 7, line 11).

DE 36 24 649 A1 mentions a bolt 4 with compression and thus discloses the rivet principle for a lockable hinge for motor vehicles.

DE 39 05 351 A1 explains a hinged door and also hinges with a latching device, whereby according to column 2, lines 49-51 hinge parts and latching parts can also be injection molded from plastic, just as it is possible to have a bearing journal made of metal made of plastic to inject.

DE 196 19 473 A1 mentions a plastic glider in connection with a detachable door hinge with structurally combined door retainer in column 3, line 44.

Most of the hinges known from the above publications lack compactness, the spring devices are often also visible and not only have an unaesthetic effect, but also represent a dust catcher US 5 412 842 (mentioned at the outset and selected as the closest prior art (and possibly DE 29 41 880 A1)) does not describe any of the publications a hinge suitable for sheet metal cabinet doors.

Object of the invention:

The object of the invention is to avoid the above disadvantages and to provide a screw-on hinge according to the type mentioned at the outset, which has a simpler construction, is more compact in its outer shape, comprises fewer individual parts, is largely symmetrical and can therefore be assembled more easily, and that has a longer lifespan.

Solutions:

The object is achieved in that the hinge pin device is in two parts and that one end of the one hinge part, which faces the other hinge part, forms the latching device, and that the latching device is formed by a sleeve end side and comprises a spiral compression spring arranged axially inside the sleeve.

These features make it possible to use the space of the hinge pin for the latching device and it is avoided that one of the screw-on hinge parts of the screw-on hinge has to be used, which causes the problems described above. The end face of the sleeve also provides a contour surface which enables a locking device with a relatively low surface pressure, which reduces material wear and increases the life of the hinge.

The symmetry of the hinge and its parts not only makes assembly easier, it also makes it easier to change the door hinge afterwards.

According to a development of the invention, the latching device comprises a shoulder or blind bottom surface formed or arranged at the end of the bore for the hinge pin in the hinge part, in which depressions or elevations are provided which correspond to elevations or depressions of the sleeve end face, the compression spring pressing the sleeve with its elevations or depressions against the shoulder or bottom surface with its depressions and elevations (recesses, projections). This represents a particularly simple measure in order to achieve the desired locking positions without the use of losable balls, which also lead to inconvenience when assembling the hinge.

For reasons of simplified production, it is favorable if the torsionally rigid connection between the one hinge part and the hinge pin is achieved by a tongue and groove device, or alternatively by non-round, for example prismatic cross-sectional shape of the cross section of the hinge pin on the one hand and the bore in the hinge part, in which this hinge pin is to be inserted, on the other hand.

Giving the hinge pin the shape of a sleeve not only has material saving advantages, but also facilitates the production of projections and recesses on the end face of this sleeve-shaped hinge pin. In addition, there are special advantages in further embodiments to be described, such as the possibility of accommodating a spiral compression spring and a screw bolt or rivet.

A particularly stable and nevertheless simple form of a hinge is one in which one hinge part encloses the other hinge part in a fork-like manner, as can also be seen in the prior art. Especially with this shape of the hinge, it is favorable that the sleeve-shaped hinge pin is made in two parts and the one end of the one hinge pin part, which has the end facing the other hinge pin part, carries the latching device. To increase the latching force, it is advantageous if, according to yet another embodiment of the invention, both hinge pin parts of the two-part hinge pin are accordingly provided on their front ends with latching projections or latching recesses which engage in corresponding recesses or projections which are formed by ring shoulders in the hinge part bore, in which the corresponding ends of the Hinge pin parts are included

The other end of the hinge pin parts can then be non-rotatably received in the hinge pin bore of the other hinge part, but may be slidably received in the axial direction. The slidable receptacle ensures that they can dodge in the axial direction during engagement and disengagement

It is advantageous if the spring device for the latching device is designed in two parts, in particular the spring ends directed away from one another can be held by a screw penetrating the spring parts, one spring being on the head of the screw and the other spring being on the screw screwed nut could support This has the great advantage that the force with which the locking devices exert the holding force does not have to be absorbed by parts of the hinge and thereby stress these hinge parts, but can be applied by the screw, which otherwise does not perform a holding function The measure thus greatly increases the stability of the overall arrangement. At the same time, the two fork tines of the fork-shaped hinge part are relieved of bending forces

It has proven to be advantageous if the end face of the sleeve has four lugs (or elevations) or depressions, which are at a distance of 90 degrees from each other.This results in particularly favorable conditions for hinges which allow an opening angle of 180 ° in this arrangement namely, a function is possible in which both in the closed position, as well as in the 180 ° open position as well as at a half opening angle of 90 °, there is a lock.This is also an inexpensive compromise between the number of locking lugs on the one hand and the width of the lugs (Projection) on the other hand, which leads to a favorable compromise between stability on the one hand and holding force on the other

The depressions or noses (projections) formed by the shoulder should also be provided four times in this case and have a distance of 90 degrees. The coordination of these noses (projections) or depressions with one another leads to a particularly stable hinge shape and a particularly high holding force in the various locking positions

Most of the time, it will be beneficial to align the locking points in such a way that a locking position has just been reached when the door or flap reaches the closed position. Alternatively, the locking device can also be designed so that the spring pressure of the coil spring is within a small range Latching point lying around the angle of rotation leads to a torque in the direction of the latching point, and that the orientation of the one latching point for the closed position is such that when the door or flap is closed the latching point has not yet been fully reached and therefore a torque acting in the closing direction is present that the door is held in its closed position with a certain pressure, so that no rattling or play movement occurs, as could be the case when the door is in the closed position exactly in the zero position of the latching position

It will usually be favorable if the hinge parts are designed in such a way that they can be screwed onto mutually aligned fastening surfaces of the frame on the one hand and the door or flap on the other

Brief description of the invention

The invention is explained in more detail below with the aid of exemplary embodiments which are illustrated in the drawings

It shows

1 is a cross-sectional view of a thin wall with an opening which can be closed by a flap, which flap is held on the thin wall by a hinge designed according to the invention,

Fig. 2 in a reduced representation the flap shown in Fig. 1 in 90 ° open, in this position locked stop position;

Figure 3 is a plan view of the hinge with a cut axial pin.

Fig. 4 is a top view of the hinge of Fig. 3;

5 shows an enlarged view of the locking area according to a first position (zero position);

6 shows the corresponding area in a second position (deviating from the zero position) for generating a torque in the closing direction;

Fig. 7 in a single part representation, the one hinge part which encompasses the other hinge part shown in Fig. 9 with two fork prongs;

FIG. 8 is a view from above of the encompassing one hinge part shown in FIG. 7;

9 the encompassed other hinge part in a top view;

FIG. 10 the encompassed hinge part according to FIG. 9 in a view from above;

11 shows the side view of a sleeve-like hinge pin part of a two-part hinge pin arrangement, as is used according to FIG. 3; 12 is a bottom view of the hinge pin part of FIG. 11,

13 is a top view of the hinge pin part shown in FIG. 11,

Fig. 14 is a side view of the associated compression spring that can be received in the sleeve-shaped hinge pin part, and

Fig. 15 is a side view of the associated cylinder screw with nut, which compresses the springs of the two hinge pin parts

Best ways of carrying out the invention

1 shows a screw-on hinge 10 for a door or flap 16 which can be pivoted vertically or horizontally on a frame or a wall 12 about an axis 14 and which can be detachably held in at least one pivoting angle position, for example in one of the positions shown in FIG The screw-on hinge 10 consists of a first hinge part 18, which can be fastened, for example, to the frame or to the wall 12, the fastening being able to be carried out, for example, by means of two axially offset countersunk screws 20, see corresponding countersunk head openings 22 in FIGS. 3 and 4 a second hinge part 24, which can be screwed onto the door or flap 16, for example. Both hinge parts 18, 24 each have a bore 26, 28, see FIGS. 7 and 9, into which a hinge pin device 30 can be received

In Fig. 2 the situation can be seen again in a reduced representation, the solid line showing the closed door or the closed flap within the wall or frame 12 and dashed through 90 ° pivoted to this shows a further position, which may be a detachably held position The arrangement according to FIG. 2 may be a machine cover 12, and the hinge 10 hold a flap 16 which can be pivoted about a horizontal axis and which is opened in the horizontal direction in the broken line and for example, access to the engine room allowed for maintenance purposes

In contrast, FIG. 1 may represent a door 16 that can be opened and closed about a vertical axis 14, here also sealing strips 32 are indicated, which are placed on edges of the frame or wall 12 and when the door 16 is closed together with edges in the door enable a tight closure of the openings closed by the door 16

In order to obtain this sealing effect reliably, it is important that the hinge 30 generates a certain contact pressure, which is possible with the hinge arrangement according to the invention, as will be described below

According to FIG. 3, the hinge pin arrangement 30 is formed by two sleeve parts 34 ′, 34 ″, which are expediently constructed identically and are shown in FIG. 11 in a side view, in FIG. 12 in a view from below and in FIG. 13 in a view from above The sleeve part 34 has at its lower end 36 in FIG. 11 an axially oriented, radially projecting strip or tongue 38 which can be received in a corresponding groove 40 which springs back in the area of the hinge pin bore 26 formed by the first hinge part 18 in the region of the fastening tab 42 Due to this arrangement, groove 40 weakens the first hinge part only insignificantly, this tongue and groove connection serving to hold sleeve 34 in the bore 26 of the two ends of hinge part 18 in a rotationally rigid but axially displaceable manner. The other end 44 has one circular-shaped end face in which four indentations 46 offset by 90 ° are arranged Lse 34 forms an axial bore 48 which narrows near the end 44 to a bore 50 of smaller diameter. A spiral compression spring 52 can be received in the bore 48 of larger diameter, which is shown in FIG. 14 and is formed on the constriction from the bore 50 Shoulder 54 can be supported. The narrower bore 50 can in turn be used in FIG. 15 WHERE 0

Pass 1 1 shown bolt 56, as will be described in more detail below.

The upper end of the sleeve 34 with the end face having the depressions 46 can be received in a bore 28 which is shown in FIG. 9 with respect to the second hinge part 24. This bore also forms a first bore region with a larger diameter, which can receive the sleeve 34 rotatably and axially displaceably, and a second bore region 60 of smaller diameter, forming an annular shoulder 58, the diameter of which is sufficient to in turn be able to pass the shaft of the bolt 56. According to FIG. 10, a view from below of the part according to FIG. 9, the annular shoulder 58 carries four axially projecting lugs or projections 62, which are arranged radially with respect to the hinge axis and are offset by 90 ° to one another, and their 90 ° coordinates with respect to the fastening plane 64 are slightly offset, for example by -5 °, as is clear from the angle in FIG. 10.

The first hinge part 18 is designed such that it encompasses the inner part 68 of the second hinge part 24 with its two legs 66, with the bores 26 of the two legs 66 of the first hinge part 18 being symmetrical about the two existing, symmetrical to the hinge part center 67 after corresponding alignment arranged bores 28 of the second hinge part 24 are aligned. In this position, a sleeve part 34 can be inserted from the outside into the bores 26 of the first hinge part 18 with its side 44, which has the narrower bore 50, until this side 44 has penetrated and fills in the bore 28 of the second hinge part 24, at the same time the component 34 is aligned with its spring part 38 so that this spring 38 moves into the groove 40. This assembled position can be seen in Fig. 3. Subsequently, a compression spring 52 can be introduced into the two outwardly open sleeves, whereupon the screw bolt 56 shown in FIG. B. is first passed through the lower compression spring and thus through the bore 26 of the hinge part 18 and the (lower) bore 28 of the hinge part 24, then through the bore 50 of the sleeve 34 arranged below, then through the bore 60 of the hinge part 24, then through the bore 50 of a second sleeve part 34, the is inserted in the opposite direction into the upper bore 28 of the hinge part 24, is passed through a second compression spring 52 and thus through the bore 28 of the second hinge part and through the larger part of the bore 26 of the hinge part 18. In this position, the head 70 of the bolt 56 rests against the lower end of the lower compression spring 52 shown in FIG. 3, and a nut 72 now screwed onto the upper thread of the bolt 56 forms a support for the upper end in FIG. 3 shown upper compression spring 52. The cylinder screw or the bolt 56 preferably has such an extent that the two compression springs 52 come under a certain tension and thereby the two sleeve parts 34 'and 34 "according to FIG. 3 with their depressions 46 having end faces moved to one another and thus pressed onto the shoulders of the inner part 61 of the second hinge part 24 which have the projections 62. In the position shifted by, for example, 5 °, as shown in Fig. 10, the projection 62 and recess 46 fit together exactly as it does 5, and the hinge has reached a locking position is shifted in the arrangement shown in FIG. 1 with respect to the hinge part 24 by 5 ° in the clockwise direction, as a result of which a certain pressure is exerted on the door leaf 16. Since the door frame does not allow this 5 ° displacement, the semicircular projection surface 62 according to FIG. 5, for example, migrates upwards on an inclined side surface of the trough-shaped recess 46 and thus increases the distance between the two components, as can be seen in FIG. 6 . This leads to a compression of the corresponding compression spring 52. The compression spring 52 tries to reverse this movement and in doing so presses the hinge part 24 in the clockwise direction and thus the door according to FIG. 1 into the closed position, see arrow 74.

Since this pressure or torque is generated simultaneously by two springs 52, the pressing force is doubled.

The length of the cheese head screw 56 is expediently chosen such that it disappears within the hinge parts. This gives the hinge an aesthetic appearance because the built-in locking device is not visible. In the embodiment shown, a hinge according to FIG. 4 is designed such that it shows latching points at -5 °, at 85 ° and at 175 °. In the -5 ° position, the frame or the wall pushes the door into the 0 ° position, creating contact pressure. At the 85 ° position, the door remains in the open position, the door leaf projecting essentially perpendicularly from the fastening surface. Finally, there is a further opening position, which has a latching point at 175 °, the hinge shown here making this large opening angle possible (see the broken line in FIG. 4), since it is a 180 ° hinge.

The cylinder screw 56 compressing the springs 52 enables the pressure force and thus the locking force to be adjusted by tightening or loosening the nut 72. If one can dispense with this adjustability, a rivet of suitable length and suitable diameter can also be used instead of the socket head screw 56, for example in the form of a hollow rivet, one of which has the function of the screw head and the other of which the rivet head acts as the nut of the socket head screw.

The hinge parts can be injection molded from metal or preferably from plastic. The locking surfaces, if made of plastic, result in low friction values. For higher resilience, however, it can also be favorable to form the latching surfaces from a metal part which is inserted or injected into the plastic.

It is also possible to construct the hinge pin device from two sleeves inserted one into the other, the outer, first sleeve being firmly connected to the one hinge part (e.g. pressed, glued), so that this sleeve does not axially relate to the hinge in the assembled state is movable. The inner second sleeve is arranged axially displaceably and rotatably within this first outer sleeve. One outer sleeve may then form a latching surface with a radially inwardly projecting annular shoulder, while the other, inner sleeve forms the corresponding second latching surface rotating thereon, this sleeve being connected in a suitable manner in a rotationally rigid but axially displaceable manner to the other hinge part is. The inner sleeve then contains the spring, which is the locking surfaces of the press the two sleeves together. The spring is penetrated by a retaining bolt or rivet, the latter possibly also in the form of a sleeve. This arrangement is particularly stable and enables a hinge with hinge tabs made of plastic, in which the z. B. existing sleeves made of metal, of particularly great strength.

Commercial evaluability:

The invention can be evaluated commercially in control cabinet construction.

Claims

P a t e n t a n s r u c h e:

Screw-on hinge (10) for a door or flap (16) pivotably arranged vertically or horizontally on a frame or wall (12), in which the door or flap (16) is in at least one pivoting angle position (-5 °; + 85 °; +175 °) is held releasably, consisting of a first example hinge part (18) attachable to the frame, and a second e.g. second hinge part (24) which can be fastened to the door or flap (16), the hinge parts (18, 24) are each symmetrical about their median bisector (67) and each comprise a bore (26, 28) for receiving a hinge pin arrangement (30), wherein the hinge pin arrangement comprises a sleeve (34) which is rotationally rigidly connected to one hinge part (18) and between which sleeve (34) and the other hinge part (24) a resilient latching device is arranged, characterized in that the hinge pin device (30) is in two parts and that the one end (44) of the one hinge part, which points to the other hinge part, forms the latching device, and that the latching device is each formed by a sleeve end face and each comprises a spiral compression spring (52) arranged axially inside the sleeve.

Second

Screw-on hinge according to claim 1, characterized in that the latching device has a shoulder or blind hole bottom surface (58) formed or arranged at the end of the respective bore (28) for the respective hinge pin (30) in the hinge part (58), in which depressions or elevations (recesses) or projections) (46; 62) are provided, the elevations or depressions (62, 46) of the sleeve end face (46) are assigned, and that the spring (52) the sleeve (34) with its elevations or depressions against the shoulder or floor surface with their depressions or elevations.

Third

Screw-on hinge according to claim 1 or 2, characterized in that the torsionally rigid connection between the one hinge part (e.g. 18) and the hinge pin (e.g. 34) by a tongue and groove device (38, 40) or by a prismatic or non-round cross-sectional shape is reached.

4th

Screw-on hinge according to one of claims 1 to 3, characterized in that one hinge part (z. B. 18) encloses the other hinge part (z. B. 24) in a fork shape.

Screw-on hinge according to one of claims 1-4, characterized in that both facing end faces (40) of the hinge parts (34) are provided with projections or recesses (62, 46) which engage in corresponding recesses / projections (46, 62), which are formed by annular shoulders (58) in the hinge part bore, in which the corresponding end faces (44) are received.

6th

Screw-on hinge according to claim 5, characterized in that the other end (36) of the hinge pin parts (34) is received in the hinge pin bore (26) of the other hinge part (18) in a rotationally rigid but axially sliding manner.

7th

Screw-on hinge according to one of claims 1 to 6, characterized in that the spring is in two parts and consists of two compression springs (52).

8th.

Screw-on hinge according to one of claims 1 to 7, characterized in that the spring ends of the compression spring (s) (52) which are directed away from one another are pressed together by a screw (56) penetrating the spring parts, one spring being pressed onto the head (70) of the screw and supports the other spring on a screwed nut (72).

9th

Screw-on hinge according to one of claims 1 to 8, characterized in that the end face (44) of the sleeve has four projections-recesses (62, 46) which are at a distance of 90 degrees from one another.

10th

Screw-on hinge according to one of claims 1 to 9, characterized in that the recessed projections (46, 62) formed by the shoulder (58) are provided four times and are at a distance of 90 degrees from one another, the 0 ° orientation of the recesses -Projections with respect to the mounting surface of the hinge (12) a shift of a few degrees, for. B. 5 °.

11th

Screw-on hinge according to claim 10, characterized in that the orientation of the locking points is such that this locking position has just been reached when the door or flap is in the closed position.

12th

Screw-on hinge according to claim 10, characterized in that the latching device is designed so that the spring pressure of the spiral spring inside of a rotation angle around the locking point leads to a torque in the direction of the locking point, and that the orientation of the one locking point for the closed position is such that when the door or flap is closed, a torque acting in the closing direction occurs on this door or flap.

13th

Screw-on hinge according to one of claims 1 to 12, characterized in that the hinge parts (18, 24) are designed such that they can be screwed onto fastening surfaces (12, 16) of the frame and door or flap which are aligned with one another.

14th

Screw-on hinge according to one of claims 8 to 13, characterized in that a rivet, such as a hollow rivet, compresses the compression springs instead of the screw bolt.

15th

Screw-on hinge according to one of claims 1 to 14, characterized in that the hinge parts (18, 24) are injection molded from plastic.

16th

Screw-on hinge according to claim 15, characterized in that the latching surfaces (58, 60) of one hinge part (24) is formed by a metal part which is inserted into the plastic, in particular is injected.

17th

Screw-on hinge according to one of claims 1 to 16, characterized in that the hinge pin device is fixed by one to the one hinge part connected first sleeve and a rotationally rigid but axially displaceably connected second sleeve is formed with the other hinge part, wherein the second sleeve is arranged in the first sleeve and the first sleeve forms an inwardly radially projecting annular shoulder with locking devices on which the end face of the second Sleeve rests with an analog locking device under spring force, which spring force is generated by a spiral compression spring arranged within the second sleeve.

18th

Screw-on hinge according to claim 17, characterized in that the two sleeves are made of different materials, such as metal and plastic.

19th

Screw-on hinge according to claim 17 or 18, characterized in that the spiral compression spring (s) is held under tension by a screw bolt or rivet, in particular a hollow rivet, which passes through the spiral spring (s).