DE4126621C1 - Nut with locking ring - has surfaces on nut and ring forming inclined planes to force ring against flexible tongues which lock onto threads. - Google Patents

Abstract

The ring such as a nut has a basic element (2) with axial projections which have conical surface areas on the outside. At the transition with the projections the basic element has a step contg. a security ring (3). Both the basic element and the security ring have facing support (13, 14) which together form a slanting plane for the axial displacement of the security ring opposite the basic element. Where the nut has an inner thread (7) the pitch of the support faces can be smaller or greater than the pitch of the inner thread. USE/ADVANTAGE - The locking ring on a nut can be securely fixed on an axis of a shaft etc. without the need for special tools.

Description

The invention relates to a ring, in particular to a mother, with a body that closed is annular and essentially axial Incisions divided axial processes that on their Outside surface areas in the axial direction have expanding conical surface, the base body on Transition to the axial processes has a step in the Recording space a locking ring is provided, which with the Area areas of the axial extensions by axial offset in the Meaning of a clamping radial movement of the axial processes cooperates. The invention can be ring-shaped use closed basic bodies with a Are provided with internal threads, i.e. on nuts and the like, threaded fasteners. The invention can also be used with collars, bushings or similar Use elements that do not have a thread, but that are intended to comprise a shaft or a shaft and fixed on it in an axially aligned position to become.

A mother of the type described above is known as a so-called Two-lock mother known. A closed ring The base body faces axially on one side Axial processes on, similar to a crown splint nut, whereby the axial processes through axially guided incisions are divided so that they face each other in the radial direction the base body are elastically resiliently movable. On the Outside of these axial extensions are surface areas formed, which form a conical surface, the tip of which Base body is arranged facing. Between base body and the axial processes a step is formed, the one Recording space for a circlip represents the Axial processes facing a correspondingly conical  designed counter surface. By applying a Axial force on the locking ring in the sense of a movement away from the base body, the locking ring exerts a radial Clamping force on the axial extensions. The internal thread of the Mother extends over the main body and the Axial processes. Such a mother is called Fastener on a corresponding screw or turned a threaded shaft, so that the Basic body with its side facing away from the axial processes comes to rest on the workpiece to be fastened. After this the intended preload is applied, the Circlip with a special tool through application an axial force towards the free end of the Axial extensions pulled, which increases the radial clamping force which adjusts the axial processes. Such screws / nuts Connection is intended to transfer operational forces related to the screw longitudinal axis, act in the axial and transverse directions can. The screw connection depends on the type of load with an operating force in the axial direction predominantly one Loosen and with a cross-directional worker Loosened exposed. In practice, axial and Lateral forces more or less strongly on the Screw connection together, so that the risk of There is loosening and / or loosening. To one unwanted axial displacement of the locking ring from the counteract the clamped position in the release position it is known to use a second special tool and with this a metal cap with extensions so over the free End of the axial processes and the circlip to form that this additionally held in its safety position and is fixed with it. The well-known mother shows that Disadvantage that their use is the use of two Special tools required. The measure of the axial offset of the Circlip and the proper attachment of the cap are highly dependent on the skill and experience of the Fitter dependent.  

From DE-PS 11 70 198 is a disk-shaped Screw or nut lock known, when the essential element a lock washer is used, facing the workpiece between the screw head or the nut and the workpiece surface is clamped. This lock washer has a known smooth Contact surface with high friction torque, matched to the Workpiece surface. On the other hand, between the Circlip and the nut or the screw head inclined support surfaces provided, their frictional torque however less than the frictional torque on the smooth surface the locking washer is formed. Are axial processes not provided and radial clamping is neither intends still possible. The slanted ones Support surfaces must be arranged in their sense of rotation so that sliding the parts onto each other for backup purposes is used. Such security against automatic Twisting has with a nut of the type described above to do nothing in itself.

DE-PS 4 80 132 shows a screw lock made of two Main parts, namely a core with thread and one Shell part with a hexagonal or other outer shape. The core has that assigned to the screw shaft Internal thread, is axially continuous at a circumferential point slotted and conical on the outside, the Jacket part correspondingly conical on its inner circumference is designed to accommodate the core. The coat part has a support surface for in one end face the system on the workpiece, while the core exclusively with the thread of the screw shaft comes into contact. Core and Sheath parts are over a pin that runs along the generatrix of the cone is connected to one another in a rotationally fixed manner, however guided axially. The pen is relative to the Slot of the core arranged so that the core - in Circumferential direction - divided into two unequal parts is, in such a way that in the area of the smaller part in the Sense of the tightening direction of the jacket part of the pin before Slot of the core is located. So when you start turning it educated mother the effect of a loop brake used, which opposes the loosening of the mother. The Applying the preload on the one hand and the Securing effect on the other hand is with this Threadlocker directly connected to each other. About the Tapered surfaces can have the securing effect and the preload only applied at the same time and also dismantled at the same time will. This is disadvantageous in the event of a loss the bias also lost the securing effect, e.g. B. during a setting process.

The invention has for its object a ring, especially mother, jack or the like. To provide the without using special tools on one axis, one Screw shaft or the like. Attachable and on the intended Is fixable in the sense of a backup.

According to the invention this is achieved in that the Basic body on the one hand and the locking ring on the other have a mutually facing pair of support surfaces which with each other an inclined plane for the axial offset of the Form locking ring against the base body. If the Ring, for example, is designed as a nut, this is with the base body on the associated screw shaft turned up until that also in the area of the axial extensions threads in the area of the screw shank  is coming. After the intended preload is applied has been, the locking ring is now relative to the Base body twisted, forming an inclined plane Support surfaces slide on each other and ensure that the Circlip is moved in the axial direction. These Movement faces away from the surface of the workpiece this directed towards the free end of the mother or the Axial processes. By the provided on the axial extensions Area areas of the expanding conical surface becomes the Axial movement in a radial movement of the axial processes converted, thus in the sense of applying a Protection against loosening and loosening on the screw shaft be pressed. There are no special tools for assembly required; it is enough to use conventional wrenches or use similar twisting tools. The arrangement of the The direction of rotation of the support surfaces of the inclined plane is on possible in both directions. While twisting the locking ring, the base body is either anyway held by a twisting tool or during training as mother z. B. by the friction after applied Preload held. Maybe that makes more sense Arrangement of the inclined plane in the same sense as that Pitch of a thread. If the measure of radial Clamping of the axial processes reproducible is to be kept constant, it is appropriate at Relative rotation of the circlip one Use a torque wrench or a similar tool. Especially in automotive engineering, and there for example at Locking wheel bearings, a preferred application of the present invention, however, such tools are not uncommon.

If the ring is designed as a nut with an internal thread, the slope of the support surfaces can be greater than the slope of the internal thread of the mother. This makes it special high radial locking force reached. On the other hand, it is  but also possible, the slope of the support surfaces smaller to choose as the pitch of the internal thread of the nut. This results in a particularly sensitive Setting option of the securing force.

In both cases, the inclined support surfaces Have self-locking, d. H. the conditions must be like this be trained and coordinated with one another that when performing the stress on the connection a sliding of the parts contrary to the slope increase can take place. Only if the connection is deliberately broken this self-locking can be achieved by using a corresponding loosening torque can be solved. The Reusability of the parts is good.

For the division of the support surfaces result various possibilities. Basically necessary at least a pair of support surfaces, one surface on the ring or the nut and the other surface on the Circlip is provided. It is expedient that To divide support surfaces into three support surface segments, which are regularly distributed over the circumference. The The number of support surface segments can of course also be increased or be humiliated. This will support the Axial force divided locally.

In addition to the inclined support surfaces, you can Flat surfaces on the base body and / or on the locking ring be provided by the geometric arrangement of the measure the axial offset and thus the clamping radial movement the axial processes is fixed. Through such flat areas, which are very easy to manufacture, becomes the measure of Axial misalignment of the locking ring is set so that a Angular range is opened, into which one Relative rotation of the locking ring compared to the Basic body must be done. It is then indifferent to  at which point in this area the rotation is ended. In all cases, the same axial offset and thus the corresponding clamping radial movement. In order to the use of a torque wrench becomes unnecessary. Of course, this training sets a corresponding Tolerant processing of the areas assigned to each other ahead, which, however, seems easily manageable.

The basic body, the locking ring and the axial extensions can be designed so that the sum of the Deformation moments and deformation forces less than that Torque of the nut is. This has the advantage that the nut during the relative rotation of the locking ring does not have to be actively held, but as it were by alone is certain.

The axial extensions can become radial webs for captive Have the retaining ring included. Even without these bars captive recording is possible, which can only be achieved by the Arrangement of the conical conical surface can be effected. The production of such combined elements must be done Base body and locking ring matched to each other that the captive seat is reached.

If the ring is without an internal thread, for example as a collar, the base body has one smooth passage that extends even into the area of Axial processes extends. Here, too, they are each other facing inner surfaces of the ring and that of the Ring enclosed shaft coordinated.

The height of the body can be the height of the locking ring be about 2: 1. A division of this magnitude seems sensible for the application of the preload.  

The basic body, the locking ring and the axial extensions can also be designed so that Securing torque of the clamping radial movement is equal to or greater than the internal torque of the nut, based on the Preload is. This will be the one you want Securing effect achieved and loosening or loosening does not occur under operating conditions.

The invention will be more preferred based on several Exemplary embodiments further explained and described. It demonstrate:

Fig. 1 is a side view of a nut, partially in section,

Fig. 2 is an axial view of the nut according to Fig. 1,

Fig. 3 is a developed view of the support surfaces of the nut according to Fig. 1 and 2, in the plane

Fig. 4 shows another embodiment of the mother in a representation similar to Fig. 1 and

Fig. 5 is a development of the support surfaces in a second embodiment.

In Fig. 1, a nut 1 is shown, which consists of a base body 2 and a locking ring 3 .

The base body 2 is formed in a ring-shaped manner in the usual way. It has one or more contact surfaces 4 with which it comes to rest on the workpiece. On the side facing away from the support surface 4, axial extensions 5 are formed on the base body 2 , which are formed by incisions 6 which extend from the free end of the axial extensions 5 in the direction of the base body to the apparent depth. The incisions 6 make the axial extensions 5 radially resilient. An internal thread 7 extends over the inner surface of the base body 2 as well as the axial extensions 5 . The axial extensions 5 have on their outer surface areas 8 a conical surface 10 that widens in the axial direction. The tip of the conical surface 10 lies on the side of the base body 2 . The cone widens towards the free ends of the axial extensions 5 . The extent of the expansion is illustrated by the entered angle of, for example, 5 °.

The locking ring 3 faces the surface area 8 of the axial extensions 5 and corresponds to corresponding surface areas 9 , so that when the base body 2 and the locking ring 3 move axially apart, the axial extensions 5 can deflect radially inwards. By appropriately dimensioning the surface areas 8 and 9 , the retaining ring 3 is movable, but is held captively on the base body 2 .

The base body 2 faces away from the bearing surface 4 and faces the retaining ring 3 , a circumferential recess 11 , while the retaining ring 3 has a circumferential projection 12 which is matched to the recess 11 and projects into it. The base body 2 has, as it were, a support surface 13 on the bottom of the recess 11 , while a coordinated support surface 14 is provided on the projection 12 of the locking ring 3 . The pair of these support surfaces 13 , 14 is arranged obliquely, in the sense of an inclined plane, as is illustrated by FIG. 3. A single pair of support surfaces 13 , 14 is sufficient. However, it is also possible to subdivide the support surfaces into separate support surface segments, as can be seen in FIG. 3. It can be seen, in particular with reference to FIG. 3, that a relative rotation of the locking ring 3 relative to the base body 2 leads to the support surfaces 13 and 14 sliding on one another in the sense of the inclined plane, so that the locking ring 3 and the base body 2 move axially relative to one another Remove the direction and in this respect compress the axial extensions 5 radially inwards over the surface areas 8 , 9 . If the nut 1 is screwed onto a screw shank, a radial pressure in the area of the axial extensions 5 is thereby achieved, by means of which the nut is secured. The locking effect is applied by relatively rotating the locking ring 3 in the direction of an arrow 15 , relative to the stationary base body 2 . The connection can be released again by a relative rotation opposite to arrow 15 and can be reused.

Fig. 4 shows a second embodiment of a nut 1 with a base 2 and securing ring 3. Instead of the recess 11 , a step 16 is formed here at the transition of the base body 2 into the axial extensions 5 . In this stage 16 , the locking ring 3 is received. The support surfaces 13 can extend over the entire radial width of the step 16 . The support surfaces 14 on the locking ring 3 can also be made wider here. It goes without saying that the conical surface areas 8 and 9 are also provided here. The axial extensions 5 can have radial webs 17 which can provide additional protection for the captive locking ring 3 . In general, however, this is not necessary. The angle of the surface areas 8 and 9 is sufficient to ensure the captivity.

FIG. 5 shows a representation similar to FIG. 3. However, the secured, that is to say the relatively rotated, position between base body 2 and locking ring 3 is shown here. In addition, not only support surfaces 13 and 14 , but these additional plane surfaces 18 and 19 are provided, so that an axial dimension 20 is thereby defined, by which the locking ring 3 is axially displaced by twisting, so that it causes a reproducible radial clamping of the axial extensions 5 . It can be seen that it is only necessary to rotate the locking ring 3 relative to the base body 2 until the end position is in an angular range determined in accordance with the extent of the plane surfaces 18 , 19 . Then the axial dimension 20 is fulfilled and it does not matter at which point of this surface area the relative rotation is ended. The use of a torque wrench for the relative rotation of the locking ring 3 is therefore unnecessary. The flat surface 18 can also be provided with a local depression 21 , which is only indicated by dots here in order to achieve a certain locking effect. This can also mean additional protection against loosening. It is understood that the recess 21 takes on a very small extent. The design of FIG. 5 can be used both in the embodiment of FIGS. 1 and 2 as well as in that of FIG. 4 find application.

Although the invention has been set forth in several embodiments, each relating to a nut 1 , it is understood that the internal thread 7 is in itself unnecessary for bringing about the radial jamming of the axial extensions 5 , so that smooth parts, e.g. B. collars, bushings or the like., The invention is applicable.

Reference symbol list:

1 mother
2 basic bodies
3 circlip
4 contact surface
5 axial process
6 incision
7 internal threads
8 surface area
9 surface area
10 cone surface
11 deepening
12 head start
13 support surface
14 support surface
15 arrow
16 level
17 bridge
18 flat surface
19 flat surface
20 measure
21 deepening

Claims (11)

1. Ring, in particular nut, with a base body, which is formed in a closed, ring-shaped manner and has axial projections designed by essentially axial incisions, which on the outside have surface areas of a conical surface that widens in the axial direction, the base body at the transition to the axial extensions A locking ring is provided in the receiving space, which interacts with the surface areas of the axial extensions by axial offset in the sense of a clamping radial movement of the axial extensions, characterized in that the base body ( 2 ) on the one hand and the locking ring ( 3 ) have a pair of supporting surfaces ( 13 , 14 ), which together form an inclined plane for the axial offset of the locking ring ( 3 ) relative to the base body ( 2 ). 2. Ring according to claim 1, which is designed as a nut ( 1 ) with an internal thread ( 7 ), characterized in that the slope of the support surfaces ( 13 , 14 ) is greater than the slope of the internal thread ( 7 ) of the nut. 3. Ring according to claim 1, which is designed as a nut ( 1 ) with an internal thread ( 7 ), characterized in that the slope of the support surfaces ( 13 , 14 ) is smaller than the slope of the internal thread ( 7 ) of the nut. 4. Ring according to claim 2 or 2, characterized in that the inclined support surfaces ( 13 , 14 ) have self-locking. 5. Ring according to one or more of claims 1 to 4, characterized in that the support surfaces ( 13 , 14 ) are preferably divided into three support surface segments, which are arranged regularly distributed over the circumference. 6. Ring according to one or more of claims 1 to 5, characterized in that in addition to the inclined support surfaces ( 13 , 14 ) plane surfaces ( 18 , 19 ) on the base body and / or the locking ring ( 3 ) are provided by their geometric Arrangement the dimension ( 20 ) of the axial offset and thus the clamping radial movement of the axial extensions ( 5 ) is fixed. 7. Ring according to one or more of claims 1 to 6, characterized in that the base body ( 2 ), the locking ring ( 3 ) and the axial extensions ( 5 ) are designed such that the sum of the moments of deformation less than the tightening torque of the nut ( 1 ) is. 8. Ring according to one or more of claims 1 to 7, characterized in that the axial extensions ( 5 ) have axial webs ( 17 ) for captively receiving the retaining ring ( 3 ). 9. Ring according to claim 1, which is designed as an adjusting ring, characterized in that the base body ( 2 ) has a smooth passage which extends into the region of the axial extensions ( 5 ). 10. Ring according to claim 1 or 8, characterized in that the height of the base body ( 2 ) to the height of the locking ring ( 3 ) is approximately 2: 1. 11. Ring according to claim 10, characterized in that the base body ( 2 ), the locking ring ( 3 ) and the axial extensions ( 5 ) is designed such that the locking torque of the clamping radial movement is equal to or greater than the inner loosening torque of the nut ( 1 ) , based on the preload.