DE10038454A1 - Door hinge; has pivot locking unit with engaging profiles on hinge bolt and hinge lugs, where one profile is nose and other profile is sliding face that forms friction lock with nose - Google Patents

Abstract

The hinge has a pivot locking unit, which has profiles on the hinge bolt (4) and the hinge lugs (9,12) that engage with each other. The profiles are formed by at least one nose (11) on one of the hinge parts (2-4) and at least one sliding face on another part that forms a friction lock with the nose. The pivot angle of a sliding area before the pivoting is blocked may be selected according to the width of the nose.

Description

The invention relates to a hinge with hinge pin and hinge eye and with Swivel locking device, on the hinge pin and in the hinge eye mutually engaging profiles are provided.

Hinges, in particular those for doors or flaps, for example on motor vehicles, are in usually provided with a device that inhibits the pivoting movement. This is supposed to to ensure that the door or the flap does not accidentally open or close, but remains in the position into which it has been swiveled, or hers Pivoting movement is at least braked.

Such swivel locking devices are already an imaginary one Cylindrical surface gradually increasing and steeply falling cylindrical Wedge surfaces have been proposed on the hinge pin and in the hinge eye. At the Swiveling the hinge, the backs of the wedge surfaces slide against one another in frictional engagement and thereby inhibit the swiveling movement (DE 44 06 824 A1, DE 196 25 557 A1, DE 197 26 536 A1).

The production of such wedge profiles with a low slope and close tolerance has proven to be proven sophisticated. This is especially true if for the course of the Inhibitory effect over the swivel range certain courses are to be achieved.

The object of the invention was therefore to provide a simpler solution for a hinge to provide integrated devices for inhibiting the swiveling movement. It solves them Task with the characteristics mentioned in the characterizing part of the main claim.

Lugs and sliding surfaces can with respect to their width in the circumferential direction, their height in Axis direction, its radius from the pivot axis and also in the course, d. H. in Zu- or Acceptance of these parameters in the circumferential direction and in the axial direction within very wide limits  be varied so that very different requirements for the course of the Inhibitory effect can be met over the swivel range.

For example, the lugs can be wider or narrower in the circumferential direction. Narrow noses after passing through the joining gap that is always required for joining, their width in the circumferential direction corresponding pivot angle achieve the inhibitory effect and keep it moving as you pan. With a wide nose, the rise the inhibitory effect be flatter. If the width of the nose in the axial direction and in Swiveling direction increases, the increase in inhibitory effect can occur all over Swivel range can be expanded. Conversely, in the axial direction decreasing width of the nose the inhibitory effect with increasing swivel angle can be reduced. The same effects can be achieved if the amount of Nose increases or decreases in width in the circumferential direction.

If the groove-like gaps between the sliding surfaces are required to the To be able to push hinge parts into each other, are much wider than the lugs an initial swivel range can be kept free of inhibitory effects. Even the height of the sliding surfaces, i.e. their radius in relation to the pivot axis of the hinge in The circumferential direction can increase or decrease. The inhibitory effect increases accordingly increasing swivel angle to or from. The same effect can occur in the axial direction or decreasing width of the sliding surfaces can be achieved.

Exemplary embodiments of the invention are schematic in the figures of the drawing shown. Show it

Figure 1 is a partially sectioned view of a hinge equipped with the invention.

FIG. 2a to 5b and 8a and 8b different embodiments of the invention in cross section through the bearing region (a) (b) of the articles and the torque / swivel angle diagrams shown;

FIG. 6 shows a further embodiment as shown in FIG. 2a;

Fig. 7 shows another embodiment in development of the inner surface of the eye of one of the hinge shields;

9 to 11 show further embodiments of the invention, in representation as in FIG. 1.

Fig. 12 is a plan view of the object of Fig. 11.

As can be seen from FIG. 1, the hinge 1 consists of two hinge plates 2 and 3 , which are pivotally connected to one another by a hinge pin 4 . The hinge pin 4 has a collar 5 which is conical on the underside and a threaded shoulder 6 at its lower end. The hinge pin 4 can be fastened in the eye 9 of the hinge plate 2 , which is likewise conical in its end regions, by means of a nut 7 which can also be screwed onto the threaded extension 6 and also has a conical extension 8 . Since the hinge pin 4 must sit in the hinge plate 2 in a rotationally fixed manner for reasons that result from the following description, it can also be provided with a toothing 10 which engages in a corresponding toothing in the eye 9 of the hinge plate 2 .

The hinge pin 4 , which is cylindrical above the collar 5, has at least one axially parallel nose 11 there on its circumference. In the following it is assumed that three lugs are arranged at the same mutual distance, that is to say offset by 120 ° around the circumference of the hinge pin 4 . Three lugs offer the advantage of safely centering and evenly carrying all lugs. However, embodiments with only two or with four or more lugs are also possible and in some cases advantageous.

In order to be able to easily slide the hinge plate 3 onto the hinge pin 4 , the eye 12 of the hinge plate 3 is provided with three grooves 13 assigned to the lugs 11 , as can be seen from FIG. 2a, wherein between the mutually opposing surfaces of the hinge pin and the eye of the Hinge plate there is a narrow joint gap. Otherwise, the clear diameter of the eye 12 is smaller than an imaginary cylinder enveloping the lugs 11 . The difference between the radii of the lugs 11 , the grooves 13 and the sliding surfaces 14 between the grooves are shown in Fig. 2a to 5a, 6 and 8a greatly exaggerated for the sake of visibility. The amount by which the diameter of an imaginary cylinder enveloping the lugs 11 exceeds the diameter of the sliding surfaces 14 is in the range of fractions of a mm.

So that the hinge plate 3 is supported on the hinge pin 4 without play, even in the joining position or before the lugs 11 slide onto the sliding surfaces 14, the hinge plate and hinge pin have cylindrical bearing surfaces 4 on at least one side next to the area provided with lugs 11 'or 4 ". It goes without saying that the lower bearing surface 4 ' must protrude radially from the nose (s) 11 and that the upper bearing surface 4 " should correspond to the largest cylinder to be inscribed in the hinge pin 4 .

When the hinge plate 3 pushed onto the hinge pin 4 in the joining position shown in FIG. 2a is rotated, the lugs 11 slide out of the grooves 13 onto the areas of the eye 12 with a smaller diameter and come into frictional connection with the sliding surfaces 14 . This friction connection leads to the desired inhibitory effect. To facilitate this sliding, the edges of the lugs and grooves are chamfered. During this sliding and also when pivoting the hinge 1 further, considerable torques occur on the hinge pin 4 , under the effect of which it must not twist in the hinge plate 2 . To prevent this, the toothing 10 mentioned is provided. It goes without saying that this securing against twisting can also take place in another way, for example by means of tongue and groove, spin pin, key surfaces etc.

When the lugs 11 slide onto the sliding surfaces 14 , the eye 12 of the hinge plate 3 is elastically deformed. So that the lugs 11 and sliding surfaces 14 do not wear too much under the considerable friction stress and the inhibiting effect remains the same as far as possible, the surfaces of the components mentioned which come into active connection with one another are advantageously nitrided.

The friction surface between lugs 11 and sliding surfaces 14 gradually increases in a sliding area 15 , which is, for example, approximately 20 °. The associated increase in the frictional force and the inhibiting effect can be seen from the diagram in FIG. 2b, in which the swivel angle is plotted on the abscissa and the frictional force / inhibiting effect is plotted on the ordinate. When the lugs 11 have slid completely onto the sliding surfaces 14 , the frictional force and thus the inhibiting effect remain the same in a constant region 16 . As can be seen, the frictional force and the inhibiting effect would drop again if the door approached a pivoting angle of approximately 120 °, in which the lugs 11 would move into the area of the next grooves 13 . The pivoting range of about 90 ° that can be used here is rarely reached - so a pivoting angle of about 70 ° is not exceeded for car doors. If a swivel angle of 120 ° and more is actually desired, only two diametrically opposed lugs 11 and grooves 13 should be arranged, for example.

As can be seen from FIGS . 3a and 3b, the sliding area 15 extends over a larger swivel angle of, for example, 40 ° when the lugs 11 are broadened to about twice. The friction force and thus the inhibiting effect is also greater due to the increased friction surface. It is obvious that the level of the frictional force and thus the inhibiting effect can be influenced by choosing a different diameter difference between the tops of the lugs 11 and the sliding surfaces 14 .

In some applications, latching positions are desired in the swivel range, in which, for example, a door is held. This can be achieved in that - as shown in FIGS. 4a and 4b - additional (locking) grooves 13 'are arranged in the desired locking positions. When the lugs 11 fall into these locking grooves 13 ', the frictional force drops and to move the lugs out of these locking grooves in both pivoting directions, increasing frictional force is required, which acts as an inhibition of the pivoting of the door from this locking position 17 .

If, as not shown in more detail, the grooves 13 are significantly wider than the lugs 11 , the sliding area 15 only begins at a larger swivel angle. The door can then be moved over a certain swivel angle without inhibition.

The radius of the sliding surfaces 14 to the pivot axis can remain the same over their entire course. In FIGS. 5a and 5b, a solution is shown, this radius is reduced when extending from a first portion 18 in a second region 19. This results in a pivoting of the hinge plate 3 in the arrow direction on the fixed under consideration hinge pin 4 to the recognizable in Fig. 5b stepped increase of the frictional force and thus the inhibitory effect initially to a first level 16, and then to a second level 16 '.

This gradual increase in inhibition can also be achieved in other ways. In FIG. 6 illustrates an embodiment in which four distributed around the circumference of tabs 11 and grooves 13, 13 are provided. "Two of the diametrically opposed grooves 13 are opposite the lugs 11 extends only to the joining gap, while the other two grooves 13 "are much wider. When the hinge plate 3 is rotated in the direction of the arrow, the lugs 11 immediately run out of the narrow grooves 13 onto the sliding surfaces 14 and cause the level 16 to have an inhibiting effect. When the hinge plate 3 is pivoted further, the other two lugs run out of the wider grooves 13 ″ onto the sliding surfaces 14 and bring about an increase in the frictional and inhibiting action to the level 16 ′. The pivoting angle at which this increase occurs can be caused by the The angular position of the rising flank of the groove 13 ″ on the sliding surface 14 can be determined in relation to the angle of rotation of the hinge plate 3 . This embodiment is evidently tied to the paired arrangement of lugs 11 and grooves 13 , 13 ".

FIG. 7 shows a further embodiment for achieving the stepped increase in the inhibitory effect according to FIG. 5b. As can be seen from the development of the inner surface of the eye 12 of the hinge plate 3 , the rise of the sliding surfaces 14 from the grooves 13 is shifted in the circumferential direction in two regions 20 and 21 offset in the axial direction. When the hinge plate 3 is rotated, the three lugs 11 provided here immediately run onto the sliding surfaces 14 in the direction of the arrow in the upper region 20 and cause the level 16 to be inhibited. When the hinge plate 3 is pivoted further, the lugs 11 also run onto the sliding surfaces 14 in the lower region 21 and cause the friction and inhibiting action to be increased to the level 16 ′.

The difference in the levels 10 , 16 'of the inhibitory effect can be selected by the width ratio of the areas 20 , 21 . It goes without saying that if the design is functional, a decreasing gradation of the inhibitory effect can also be achieved.

In the embodiment of FIG. 8a, the radius of the sliding surfaces 14 is decreased continuously. As shown in FIG. 8b, when the hinge plate 3 is pivoted in the direction of the arrow, the frictional force and thus the inhibiting effect increases continuously over the entire pivoting angle. As not shown in detail, this effect can also be achieved in that the width of the lugs 11 increases in the axial direction. With increasing pivoting angle, an increasingly greater length of the lugs 11 comes into frictional engagement with the sliding surfaces 14 and thus increases the inhibiting effect.

It goes without saying that the interaction of lugs 11 , grooves 13 and sliding surfaces 14 can also be reversed kinematically, ie the sliding surfaces 14 can be narrowed to such an extent that they act as inwardly pointing lugs in the eye 11 of the hinge plate 3 while the lugs 11 on the hinge pin 4 can be widened to slide surfaces.

As already mentioned, the amount by which the diameter of an imaginary cylinder enveloping the lugs 11 exceeds the diameter of the sliding surfaces 14 is very small. In order to avoid extremely tight manufacturing tolerances and / or to be able to set the inhibiting effect, adjustment options can be provided by means of which the frictional force can be adjusted.

In the embodiment of FIG. 9, the area of the hinge pin 4 provided with the lugs 11 and, accordingly, the eye 12 of the hinge plate 3 is slightly conical with a cone angle between more than 0 ° to 1 °. By means of the nut 7 , the hinge pin 4 can be drawn increasingly deeper into the eye 12 of the hinge plate 3 and thus the diameter excess with which an imaginary cone enveloping the lugs 11 exceeds the diameter of the sliding surfaces 14 in the eye 12 of the hinge plate 3 . This increases the frictional force and thus the inhibitory effect.

Fig. 10 shows an embodiment in which the lugs 11 are arranged on a slotted sleeve 22 whose inner surface 23 is conical and is located on the upper correspondingly conical region of the hinge pin 4. When the hinge pin 4 is pulled downwards by means of the nut 7 , the bush 22 is expanded in the manner of a collet and, as in the embodiment described above, the frictional engagement between the lugs 11 and the sliding surfaces 14 is increased. Since the bushing 22 must be connected to the hinge pin 4 in a rotationally fixed manner, a rotation lock, for example in the form of tongue and groove 24 , is provided between these two parts. It is understood that this rotation lock can also be designed in the form of a corrugation pressed into the complementary part on one of the parts or as a toothing of both parts.

FIGS. 11 and 12 finally show a solution in which the eye is slit 12 'of the hinge plate 3 and can be narrowed by means of two screws 25, to adjust the frictional engagement, and thus the inhibitory effect.

The rotation lock of the hinge pin 4 and the cylindrical bearing surfaces on the hinge pin and in the eye 12 of the hinge plate 3 are not shown in FIGS. 9 to 12 because of the simpler illustration.

LIST OF REFERENCE NUMBERS

1

hinge

2

.

3

hinge shields

4

hinge pin

4

'

4

"cylindrical storage areas

5

Collar on the hinge pin

6

threaded extension

7

mother

8th

tapered approach

9

Eye of the hinge shield

2

10

gearing

11

nose

12

.

12

'Eye of the hinge shield

3

13

.

13

'

13

"Grooves

14

sliding surfaces

15

Aufgleitbereich

16

.

16

'' Constant range

17

detent position

18

.

19

Areas of the sliding surface in the circumferential direction

20

.

21

Areas of the sliding surface in the axial direction

22

rifle

23

Inner surface of the rifle

24

Tongue and groove

25

screw

Claims (9)

1. Hinge with hinge pin and hinge eye and with swivel locking device, in which on the hinge pin and in the hinge eye engaging profiles are provided, characterized in that the profiles by at least one nose ( 11 ) on one of the hinge parts ( 4 , 2 or 3rd ) and at least one sliding surface ( 14 ) engaging with the nose on the other hinge part. 2. Door hinge according to claim 1, characterized in that the pivot angle of a Aufgleitbereiches ( 15 ) of the inhibitory effect by the width of the at least one nose ( 11 ) is selectable in the circumferential direction. ( Fig. 2a / 2b, 3a / 3b) 3. Door hinge according to claim 1, characterized in that an increase in the inhibiting effect extending over a large part of the intended pivoting range is achieved by lugs ( 11 ), the width of which corresponds to the pivoting range. 4. Door hinge according to claim 1, characterized in that an increase over a large part of the intended swivel range of the inhibiting effect is achieved by sliding surfaces ( 14 ) whose distance from the swivel axis decreases over the swivel range in the swivel direction. ( Fig. 8a / 8b) 5. Door hinge according to claim 1, characterized in that a gradual increase in the inhibiting force is achieved by increasing the sliding surfaces ( 14 ) in the direction of the pivoting. ( Fig. 5a / 5b, 6, 7) 6. Door hinge according to one of the preceding claims, characterized in that the height of the inhibiting effect is achieved by the choice of the difference between the distances between the peripheral surfaces of the lugs ( 11 ) and the sliding surfaces ( 14 ) to the pivot axis. 7. Door hinge according to claim 1, characterized in that locking positions ( 17 ) with lowering the inhibiting effect by additional grooves ( 13 ') in the sliding surfaces ( 14 ) can be achieved. ( Fig. 4a / 4b) 8. Door hinge according to one of the preceding claims, characterized in that the inhibitory effect by conical formation of the lugs ( 11 ) having the area of the hinge pin ( 4 ) and the eye ( 12 ) on it hinged hinge plate ( 3 ) and axial adjustability of the hinge pin is adjustable , ( Fig. 9) 9. Door hinge according to one of the preceding claims, characterized in that the inhibiting effect is adjustable in that the eye ( 12 ') of the hinge pin ( 4 ) pivotable hinge plate ( 3 ) is slit in the axial direction and its clear width is adjustable. ( Fig. 11, 12)