DE102021108720A1 - Self-locking bush bearing - Google Patents

Abstract

The invention relates to a bush bearing for a motor vehicle to be accommodated in a bearing receptacle assigned to the bush bearing, comprising a bearing core, an elastomer body at least partially enclosing the bearing core, and a sleeve element which circumferentially surrounds the elastomer body in relation to a bearing axis, the sleeve element having a wall with a Has outer lateral surface, which is designed to rest against a boundary surface of the bearing mount. The bush bearing according to the invention is characterized in that the wall of the sleeve element has a transverse opening through which a latching element embedded in sections in the elastomer body and materially bonded to the elastomer of the elastomer body extends radially beyond the outer lateral surface of the sleeve element, with the bush bearing starting from a first , Operating arrangement is designed to generate a radially outwardly acting elastic reaction force on the locking element in a second operating arrangement in which the bearing core and sleeve element are axially displaced relative to one another. The invention also relates to a bearing arrangement

Description

The invention relates to a bush bearing for a motor vehicle to be accommodated in a bearing receptacle assigned to the bush bearing, comprising a bearing core, an elastomer body at least partially enclosing the bearing core and a sleeve element which encompasses the elastomer body circumferentially in relation to a bearing axis, the sleeve element having a wall with a Has outer lateral surface, which is designed to rest against a boundary surface of the bearing mount.

Bush bearings of this type are used in particular in the area of motor vehicle chassis components, for example in control arms that can be installed in the area of wheel suspensions. Such a control arm can include a force transmission element that has at least one bearing mount into which such a bush bearing is pressed. An essential aspect of the reliability of such a bearing arrangement relates to the provision of a high axial extrusion force which is necessary in order to press the bush bearing out of this bearing seat. In this case, the pressing force that is realized should be much greater than the operating forces that usually occur on the bearing arrangement. This applies in particular to bush bearings which, for example for reasons of weight, have a sleeve element which comprises plastic or is made from a plastic material. However, the use of a sleeve element made of plastic can result in problems in providing a sufficiently high extrusion force, since the bearing mount is usually provided by a metal object. This is because the coefficient of friction between a plastic material and a metal material is generally very much lower than the coefficient of friction in the case of a metal material pairing of the components of such a bearing arrangement which are in contact with one another. The same can apply to bush bearings, in which both the bearing seat and the sleeve element are each made of a plastic material, possibly also of different plastics or composite materials.

The invention is based on the object of further developing a conventional bush bearing in such a way that a higher pressing-out force can be provided for the axial pressing-out of the bearing from an associated bearing mount.

The present invention already solves this problem with a bush bearing with the features of claim 1. The bush bearing according to the invention for a motor vehicle to be accommodated in a bearing receptacle assigned to the bush bearing comprises a bearing core, an elastomer body that encloses the bearing core at least in sections, and a sleeve element that encloses the elastomer body circumferentially encompasses or radially encloses, the sleeve element having a wall, in particular in the form of a hollow cylinder, with an outer lateral surface which is designed to rest against a boundary surface of the bearing mount. The bush bearing according to the invention is characterized in that the wall of the sleeve element has a transverse opening through which a latching element embedded in sections in the elastomer body and materially bonded to the elastomer of the elastomer body extends radially beyond the outer lateral surface of the sleeve element, with the bush bearing starting from a first operating arrangement is designed to generate a radially outwardly acting elastic reaction force from the elastomer onto the locking element in a second operating arrangement, in which the bearing core and sleeve element are axially displaced relative to one another.

The bush bearing according to the invention is based on the fundamental idea of providing at least one locking element which is embedded in the elastomer of the elastomer body and extends radially through an opening, in particular in the manner of a window, through the wall of the sleeve element and, in particular in the installed position, into an associated The locking receptacle of the bearing receptacle can extend, with the arrangement of the bearing core, elastomer body and locking element being designed to provide self-locking in such a way that when an operating force occurs in the axial direction on the bearing, i.e. when the bearing core and sleeve element are axially displaced, a force is exerted in the radial direction can be generated on the latching element in order to prevent the bearing from being pressed out of the associated bearing seat by the acting axial operating forces.

"Elastic reaction force on the locking element" can mean an elastic constraining force of the elastomer, which is caused by a deformation of the elastomer of the elastomer body and acts on the locking element.

An operating arrangement of the bush bearing according to the invention can mean an operating situation in which the components of the bearing, in particular the bearing core, the elastomer body and the sleeve element, have a predetermined relative arrangement to one another, which can be caused in particular by the occurrence of certain operating forces. For example, a first operating arrangement or operating situation can be set in that no operating forces, e.g. when the vehicle in which the bush bearing is installed, are at a standstill, act on the bush bearing and a different operating arrangement or Operating situation in which operating forces that occur lead to an axial displacement of the bearing core and sleeve element relative to one another in comparison to the first-mentioned operating arrangement or operating situation, which in this example can also be referred to as the relative rest position of the bearing core and sleeve element.

The term elastomeric body is to be understood broadly and can mean a coherent accumulation of elastomeric material arranged radially here between the bearing core and the sleeve element. According to the invention, the specification also includes accumulations of elastomer which are not arranged rotationally symmetrically with respect to the bearing axis. In particular, such an elastomer body for providing a direction-dependent identifier can also be limited to predetermined circumferential volume areas between the bearing core and the sleeve element, so that there can be gaps or cavities between the bearing core and the sleeve element that are not filled with elastomer. Similarly, the elastomeric body may also have circumferentially spaced accumulations of elastomer in the manner of suspension springs. In the bush bearing according to the invention, an elastomer body generally provides a supporting and damping functionality between the bearing core and the sleeve element.

The bush bearing according to the invention with self-locking when axial operating forces occur to increase the axial extrusion force can be designed with basically any material constellations with regard to the material of the bearing core and the sleeve element. For example, one or both of these components may be formed from one metal material, or both may be formed from different metal materials. It is also possible that only one of these two components, in particular the sleeve element, is made of a plastic material, in particular a fiber-reinforced plastic material, it also being possible for both the sleeve element and the bearing core to be made of a plastic material. In a particularly expedient embodiment, the bearing core can be made from a metal material and the sleeve element can be made from a plastic material, with the sleeve element and the locking element preferably being made in a single manufacturing step, in particular by injection molding.

Further features according to the invention and developments of the invention are given in the following general description, the figures, the description of the figures and the patent claims.

It can expediently be provided that the transverse opening in the particularly hollow-cylindrical wall of the sleeve element represents an opening in the transverse direction to the bushing axis, in the manner of a window with a closed boundary surface defining the transverse opening, whereby this opening can have any basic surface, for example round in the design of an at least partially cylindrical locking element or also angular with a cross section of the locking element adapted thereto. In this embodiment, in which the transverse opening is defined by a closed boundary surface, the latching element can be designed and arranged in such a way that there is no material connection between the latching element and the sleeve element, but rather that it, embedded in the elastomer of the elastomer body, extends radially outwards through this window protrudes. Depending on the embodiment and operating arrangement or operating situation, the latching element can have a spacing at least in sections from the boundary surface of the sleeve element that defines the window.

In order to provide the described self-locking functionality of the bearing according to the invention, it can expediently be provided that the elastic reaction force acting radially outwards on the locking element in the second operating arrangement can be generated via compression of elastomer material of the elastomer body caused by the axial displacement of the bearing core relative to the sleeve element, wherein this elastomeric material can preferably be arranged in a volume section of the elastomeric body located between the latching element and the bearing core. This volume section of the elastomeric body can in particular specify a volume section that lies radially inwards with respect to the circumferential and axial extent of the latching element.

Furthermore, the bush bearing according to the invention can be designed in such a way that during the relative displacement of the sleeve element and the bearing core, an axially directed reaction force, mediated by the elastomer, acts between the sleeve element and the bearing core, which counteracts the original operating force for the axial displacement of the bearing core relative to the sleeve element.

Advantageously, in order to provide the elastic reaction force on the latching element, boundary surfaces of the latching element and/or the bearing core which are associated with one another, ie radially opposite one another, can be designed in an optimized manner. This mutually associated boundary surfaces of the locking element and / or the bearing core can be designed such that with a relative axial displacement of Bearing core and sleeve element by external operating forces, in particular caused by a movement of the vehicle, a reaction force can be generated in the elastomer of the elastomer body, which acts with a force component in the radial direction on the locking element to press the locking element radially outwards, possibly in an associated, as a radial Recess formed radial clearance or to increase a frictional connection between the locking element and a bearing mount providing component of the bearing assembly.

For example, it can be provided that the latching element has a substantially convex boundary surface in a longitudinal section of the bearing on a boundary section facing the bearing core. For the same purpose, it can expediently be provided that the bearing core has a substantially concave boundary surface in a longitudinal section of the bearing on a boundary section radially facing the latching element.

In order to optimize the elastically acting reaction force and thus to provide the described functionality of self-locking when axial operating forces occur, it is particularly expedient to provide that radially opposite or mutually associated boundary surfaces of the bearing core and the locking element are designed to correspond to one another in such a way that in the second Operating arrangement in which the bearing core is axially deflected relative to the sleeve element, elastomeric material arranged axially and radially between the locking element and the bearing core can be compressed in order to generate the elastic reaction force with a radial component on the locking element.

It should be noted that the mutually associated and radially opposite boundary surfaces of the bearing core and the latching element do not have to be designed in the manner of a continuous curvature over their entire axial extent. In particular, it can be provided that in an embodiment with non-continuous curvature, these mutually associated boundary surfaces of the bearing core and/or the locking element in the longitudinal section of the bearing can be straight in sections, in particular to form a non-continuous concave or convex curvature. In this respect, the above-described convex boundary surface of the latching element and/or the concave boundary surface of the bearing core can be provided by surfaces running at an angle of 45° or 135° to the axis in the longitudinal section of the bearing, and at least one axial surface. The term "axial surface" means a surface that extends in the axial and circumferential direction, in particular in such a way that a radial vector, starting from the axis of the bearing, is perpendicular to it. This axial surface can in particular be a cylinder surface or a section of a cylinder surface. The specified surface sections of the bearing core, which are straight in longitudinal section, can be provided in particular by respective conical sections of the bearing core extending in the axial direction of the bearing. In a similar way, the surface sections of the latching element that are associated therewith and are straight in longitudinal section can be provided by respective cone sections of the latching element.

In a specific embodiment of the bush bearing according to the invention, the bearing core can be designed in the manner of a double truncated cone in order to provide the respective mating surfaces for the locking element.

In order to provide a predetermined torsional rigidity of the bush bearing according to the invention, it can expediently be provided that the sleeve element and the bearing core are materially connected to the elastomer body, in particular by vulcanization. In a further embodiment, however, it can also be provided that the described components of the bearing core, elastomer body and sleeve element are arranged solely in a frictionally or form-fitting manner with respect to one another.

The arrangement of the latching element relative to the sleeve element can be designed in such a way that the latching element in an operating arrangement is mounted freely floating relative to the transverse opening in the elastomer body without the occurrence of external operating forces, in particular is embedded in the elastomer in a materially bonded manner, i.e. the peripheral boundary surface of the latching element has no contact with the, in particular closed, area Having boundary surface of the transverse opening in the sleeve member. When an axial operating force occurs, such a design can allow free displacement of the locking element to the sleeve element in a purely radial direction due to the constraining force generated in the elastomer.

In order to optimize the flow of forces between the latching element and the sleeve element in order to prevent the bush bearing according to the invention from being pressed out of the associated bearing receptacle when large operating forces occur, it can expediently be provided that the extent of the latching element in the region of the section protruding radially from the sleeve element is at least twice as large in the circumferential direction having the extension of the locking element in the longitudinal direction of the bearing. In particular, can the latching element has an approximately cuboid shape, wherein, as explained above, a delimiting section of the latching element facing the bearing core can be convex in the axial direction of the bearing.

To make it easier to press the bush bearing according to the invention into an associated bearing receptacle, in which the locking element has to be moved radially inward, it can expediently be provided that a peripheral edge in the region of the section of the locking element that protrudes radially from the transverse opening of the sleeve element is beveled or rounded . Provision can be made for the bevel to be designed as a ramp, which is designed and set up to interact with a boundary surface of the bearing mount when the bearing is pressed in to generate a force acting radially inward on the latching element. Provision can be made for the locking element to protrude radially inwards towards the rounded area or ramp section with a boundary surface radially over the outer lateral surface of the sleeve element, the surface normal of which runs approximately perpendicular to the bearing axis.

The bush bearing according to the invention can preferably have a plurality of such locking elements, in particular two locking elements offset by about 180° or three locking elements by about 120° circumferentially to the bearing axis, with the wall of the sleeve element having an associated transverse opening for each of these locking elements, through which the respective element extends into the elastomer body The locking element embedded in sections and materially bonded to the elastomer of the elastomer body extends radially beyond the outer lateral surface of the sleeve element, with the bush bearing being designed, starting from a first operating arrangement, to generate an elastic reaction force acting radially outwards on the respective locking element in a second operating arrangement, in which bearing core and sleeve member are axially displaced relative to each other. The plurality of latching elements can preferably be arranged at approximately the same axial height of the bush bearing. In particular, the bush bearing according to the invention can be designed with regard to this plurality of locking elements, as explained above with regard to the developments of the invention for a single locking element. This configuration of the bush bearing according to the invention with at least two latching elements makes it possible to reliably provide a desired self-locking for all operating forces on the bearing.

The sleeve element of the bush bearing according to the invention can be designed in the manner of a hollow cylinder with a peripherally closed lateral surface. In another embodiment of the bush bearing according to the invention, the sleeve element can also be designed as a longitudinally slotted, in particular hollow-cylindrical sleeve element, in which the longitudinal slot is closed when the bearing is pressed into the associated bearing receptacle in order to provide a radial prestress by the radial compression of the elastomer body of the bush bearing caused during pressing . The sleeve element can also be formed by a plurality of circumferentially consecutive and circumferentially spaced shell parts which are each vulcanized onto the elastomeric body.

The invention further relates to a bearing arrangement, comprising a force transmission element with at least one bearing seat, in which an associated bush bearing is accommodated, the bush bearing being designed as a bush bearing according to the invention.

The bearing seat of the force transmission element has a boundary surface that is cylindrical at least in sections and on which the bush bearing is supported via outer lateral surface sections, the boundary surface of the bearing body having a radial clearance assigned to the latching element for receiving at least one radial end section of the latching element. The term "radial clearance" is generally to be understood as a radial lowering of the boundary surface or as a gap in the boundary surface, so that the locking element engages radially in the lowering or the gap in the boundary surface when the bush bearing is assembled in the bearing mount to create an axial form fit between the bush bearing according to the invention and the power transmission element.

It can preferably be provided that the dimensions of the radial clearance are adapted to the dimensions of the latching element, in particular such that after the setting of an engagement state of the latching element in the radial clearance, the latter is essentially filled by the latching element in a plane approximately perpendicular to the radial direction. In another embodiment, it can also be provided that after the setting of an engagement state of the locking element in the radial clearance, the latter is essentially filled by the locking element in a plane approximately perpendicular to the radial direction to such an extent that there is a circumferential spacing between the locking element and the radial clearance.

If, for example, the bearing mount is provided by sheet metal sections, for example in the design of the power transmission element as a shaped sheet metal link, the radial clearance can be produced by a punching in the sheet metal in the area of the boundary surface of the bearing mount. If the power transmission element is made from a solid material, for example, as in the case of an aluminum link, the radial relief can be produced, for example, by milling in the area of the boundary surface that fixes the bearing mount, for example, as a groove with a predetermined groove length in the circumferential direction of the bearing axis, with the groove length being adapted to the circumferential extension of the associated locking element can be adjusted. In one embodiment, it can also be provided that the radial clearance runs at a predetermined axial height of the bush bearing and over a predetermined circumferential extent, or over the entire circumferential extent, so that the radial clearance is closed circumferentially. With such an embodiment, the construction of the bearing arrangement according to the invention can be simplified, in particular in the case of a bush bearing according to the invention constructed rotationally symmetrically about the bearing axis or a bush bearing according to the invention which has a plurality of latching elements designed as described and spaced circumferentially with respect to the bearing axis.

In particular in those embodiments of the bearing arrangement according to the invention in which the radial clearance is designed as a radial step in the boundary surface of the bearing mount and the bottom of the clearance, in particular the bottom of a groove, can therefore act as a stop surface for an associated radial stop surface of the locking element an application-specific selection of the radial depth of the relief, the radial stiffness of the bearing can be set or adjusted to a certain extent. The radial rigidity of the bearing used in the bearing arrangement according to the invention can depend on how far the locking element is moved radially inward from the state when it is not installed in the associated bearing receptacle due to the stop with the stop surface described, which is determined by adjusting the radial depth of the clearance the boundary surface of the bearing seat can be fixed, in particular by defining a groove depth. Furthermore, this variability with regard to the radial rigidity of the bearing in a radial direction through the respective locking element can also be used to achieve a predetermined ratio between the radial rigidity in this predetermined direction and the rigidity in another direction of the bearing, in particular in a direction around 90 ° circumferentially offset to the specified direction. Such a ratio is known in the art as a spread.

• 1a eine Ausführungsform eines erfindungsgemäß gestalteten Buchsenlagers in einer perspektivischen Ansicht,
• 1b die in 1a gezeigte Ausführungsform eines erfindungsgemäßen Buchsenlagers in einer Stirnseitenansicht,
• 2a das Buchsenlager der 1a, b in einer Seitenansicht,
• 2b die Ausführungsform des erfindungsgemäßen Buchsenlagers der 2a in einer Längsschnittdarstellung,
• 3 das in 2b gezeigte erfindungsgemäße Buchsenlager in Einbaulage in einem Blechlenker,
• 4 das in 2b angegebene erfindungsgemäße Buchsenlager im eingebauten Zustand in einem Schmiedelenker,
• 5 das in 2b gezeigte Lager in einem eingebauten Zustand in einen Schmiedelenker mit eingearbeiteter Nut in der die Lageraufnahme festlegenden Begrenzungsfläche, und
• 6 das Lager der 5 in einem axial ausgelenkten Zustand

zeigt.The invention is explained below by describing an embodiment together with modifications with reference to the accompanying figures, wherein

• 1a an embodiment of a bush bearing designed according to the invention in a perspective view,
• 1b in the 1a shown embodiment of a bush bearing according to the invention in an end view,
• 2a the bush bearing of the 1a, b in a side view,
• 2 B the embodiment of the bush bearing according to the invention 2a in a longitudinal section,
• 3 this in 2 B bush bearing according to the invention shown in the installation position in a metal handlebar,
• 4 this in 2 B specified bush bearings according to the invention in the installed state in a forged link,
• 5 this in 2 B bearing shown in an installed state in a forged link with incorporated groove in the boundary surface defining the bearing seat, and
• 6 the camp of 5 in an axially deflected state

indicates.

1a, b show an embodiment of a bush bearing 1 designed according to the invention, as can be used, for example, in connection with a control arm in the area of the wheel suspension of a motor vehicle. In the embodiment described, the bearing has a bearing core, also referred to as an inner part, and a sleeve element 6, here in the form of a hollow cylinder, which radially encloses the bearing core 2, with an elastomer body 4 being arranged radially between the bearing core 2 and sleeve element 6, which in the embodiment described designed in one lane and vulcanized both to the bearing core 2 and to the sleeve element 6, ie is connected to each of these in a materially bonded manner. How from the 1a, b As can be seen, the elastomer body in the described embodiment has substantial accumulations of elastomer in the form of elastomer suspension springs in the radial direction R1, while the elastomer body has an elastomer gap in a radial direction offset by 90°.

In contrast to a conventional bush bearing, the bush bearing 1 according to the invention has two latching elements 8 which are circumferentially offset by 180° and which here are embedded in sections in the elastomer of the elastomer body 4 and are materially connected to it, with the respective latching element 8 extending radially over the outer lateral surface 60 of the sleeve element 6 extends beyond. For this purpose, the sleeve element 6 has a transverse opening, referred to as a window 64, through which the respective latching element 8 extends radially outwards.

The bush bearing 1 of 1a, b is used in particular for the elastic damping of vehicle components and is fastened to a first component via the contact surface 20 of the bearing core 2 and to a second component in relation to the outer lateral surface 60 of the sleeve 6 in a non-positive or positive manner.

the 2a, b show the camp of 1a, b in a side view and in a sectional view, the sectional plane comprising the longitudinal axis A of the bearing and a preferred radial direction, such that the sectional plane runs through the two latching elements offset by 180° in the bearing. As in particular from the 1a , 2a As can be seen, the locking elements 8 have a bevel 81 in the form of a ramp in the press-in direction for inserting the bush bearing 1 into the associated bearing receptacle, via which the locking element can be moved radially inward when it is brought into engagement with the bearing receptacle.

Depending on the embodiment, the bearing core 2 can be made of a metallic material or a plastic material. However, it is also within the scope of the invention to mold an inner area of the bearing core 2 made of metal and an outer section made of plastic that defines the outer lateral surface of the entire bearing core, for example by means of an injection molding process. Depending on the embodiment, the elastomer body 4 can be single-track, i.e. solely comprising elastomer, but also multi-track, i.e. using an intermediate shell to determine in particular the radial rigidity of the bearing.

As can be seen from the described embodiment, the bush bearing according to the invention can be non-rotationally symmetrical, in particular for setting predetermined radial identifiers in different radial directions. However, it is also within the scope of the invention to design a rotationally symmetrical bearing in relation to the bearing core and the elastomer body. The number of circumferentially spaced latching elements is also not specified. A bush bearing according to the invention has at least one latching element embedded in the elastomer of the elastomeric body as described and extending radially through an associated window in the sleeve element.

The in the 2a, b The situation given shows the bush bearing designed according to the invention without the action of an external force, possibly caused by operating forces and/or by elastic restoring forces, which can be generated by pressing the bearing into the associated bearing mount, in particular because the locking element or elements 8 are Insertion of the camp are pressed radially inward in the bearing seat. The design of the outer boundary surface of the bearing core 2 and the boundary surface of the latching elements 8 facing it, as well as the elastomer of the elastomer body 4 arranged radially between the latter, is essential for the mode of operation of the self-locking bush bearing according to the invention, as explained below. This design is such that, starting from a first operating arrangement , in particular an operating arrangement without operating forces occurring in the axial direction on the bearing, which is designed to generate a radially outward-acting elastic reaction force on the locking element in a second operating arrangement, in which the bearing core and sleeve element are axially displaced relative to one another in relation to the first operating arrangement .

In addition, the arrangement can be designed in such a way that during the relative displacement of sleeve element 6 and bearing core 2, an axially directed reaction force, mediated by the elastomer, acts between sleeve element 6 and bearing core 2, which counteracts the causal operating force for shifting the bearing core to the sleeve element. According to the invention it can be provided that the detent element 8 facing boundary surface 23a, b, c of the bearing core 2 concave form, wherein in the embodiment described in the section shown 2 the concave formation can be approximated by sections of straight surfaces (surface section). As can be seen, the boundary surface of the bearing core 2 facing the locking element 8 in the described embodiment initially has a straight section 23a axially on the outside in the longitudinal section shown, which has an angle of 135° to the axis A, which is adjoined by a surface section 23b, which in the sectional view parallel to the axis A, with a surface section 23c adjoining the other axial end, which assumes an angle of 45° to the axis A in the sectional view shown.

How out 2 B shows that in the embodiment described, the boundary surface of the respective latching element 8 facing the bearing core 2 is essentially convex and thus complementary to the associated boundary surface of the bearing core 2 . This substantially convex boundary surface is similar to that of the bearing core 2 in the sectional view of FIG 2 B linear sections formed or approximated, with the representation of the 2 B The limiting surface 83a arranged axially below has an angle of 45° to the axis A of the bush bearing, the adjoining limiting surface 83b runs parallel to the axis A in the sectional view and the upper limiting surface 83c assumes an angle of 135° to the axis A in the sectional view.

the 3 , 4 show the camp of 2 B again in the specified sectional view in a respective installation position. The bush bearing 1 according to the invention is shown in FIG 3 used in a Blechumformlenker, in which the bearing support is fixed or provided by the inner lateral surface 91 of a cylindrical sheet metal wall 90, for example in the form of a passage. In this embodiment, the sheet metal wall has a recess 92 in the axial and circumferential position associated with the respective latching element 8, in which the associated latching element 8 engages radially after the bearing has been pressed into the bearing receptacle. Since the recess 92 does not provide a radial stop surface for the latching element 8, the latching element 8 protrudes into the recess 92 without radial contact. In this respect, the elastomer of the elastomer body 4 in this embodiment of a bearing arrangement according to the invention is identical to the bush bearing that is not used in the bearing mount with regard to a possible radial prestressing of the elastomer. A possible radial preload can be achieved, for example, by calibrating the bush bearing, in which case the sleeve element is compressed radially and the elastomer body or the elastomer is thus elastically compressed.

4 shows a bearing arrangement according to the invention with a bush bearing 1 according to the invention inserted into a bearing mount in an installation situation in which the bearing mount is formed by a cylindrical delimiting section 100, for example formed on a forged link or by the sheet metal formed link described above, without the latter having the reference to 3 specified radial recess is provided. In this design, pressing the bush bearing 1 into the receptacle causes the respective latching element 8 to move completely radially inwards up to the radial height of the outer lateral surface 60 of the sleeve element 6, so that the elastomer is displaced axially outwards, thereby increasing the radial rigidity of the bearing compared to that of 3 is increased and at the same time the spread of the stiffness of the bearing assembly compared to the 3 is changed.

5 shows a further embodiment of a bearing arrangement according to the invention, in which a bush bearing 1 according to the invention is pressed into the bearing seat of a force-connecting element, for example a link, wherein in contrast to the embodiments of FIG 3 and 4 The boundary surface 110 of the boundary section 100 of the power transmission element, which is designed as a forged link, for example, has a radial clearance in the form of a step 120 or groove to fix the bearing mount, with this groove providing a radially outer contact surface 130 in the form of a groove base, on which the radially outer contact surface rests in the installed position 85 of the latching element 8 is present. As from the representation of 5 can be seen, by adjusting the radial gradation 120, the radial preload of the elastomer of the elastomeric body 4 can be adjusted, so that the bush bearing according to the invention makes it possible to change the radial rigidity of the bearing used or to adapt it to it simply by setting the height or depth of the radial clearance adapt to each application. In particular, it is thus also possible to provide bearings with different spreading, since different ratios of radial rigidity in different directions can be set with the described variability of the bearing arrangement according to the invention. 5 shows an operating arrangement without the occurrence of operating forces which would otherwise lead to a deformation of the elastomer body 4 . In this embodiment of the bearing arrangement according to the invention, the elastomer of the elastomer body is slightly radially prestressed, as can be seen from the axial open areas of the elastomer.

In contrast, shows 6 this in 5 bush bearings accommodated in an associated bearing seat when an operating force occurs, which deflects the bearing in the axial direction. Ie sleeve element 6 and bearing core 2 are shifted relative to each other here in the axial direction A, such that the bearing core 2 in the illustration of FIG 6 is moved axially downwards. As can be seen, the elastomer in the elastomer section 40 of the elastomer body 4, i.e. in the area of the opposite boundary surfaces 23c of the bearing core and 83c of the locking element, is compressed by the relative movement described, so that an elastic restoring force is set, which due to the described relative positions of the two boundary surfaces 23c, 83c on the one hand a force component radially outwards on the locking element 8 causes. Due to this radially outward force component, the locking element is pressed with its contact surface 85 more strongly against the associated contact surface 130 of the groove 120 and the specified locking is thus secured against the axial operating forces that occur. When the external operating force increases in the axial direction, the locking element is pressed outwards against the contact surface 130 of the delimiting section 100 with a higher reaction force of the elastomer, so that the bearing is prevented from being pressed out of the bearing mount and this self-locking increases the greater the relative axial displacement between Sleeve element and bearing core is. Furthermore, the elastic reaction force causes an axial force component between the locking element and the bearing core, which counteracts the operating force that occurs in the axial direction. This effect also increases with increasing operating force on the bearing according to the invention in the axial direction and contributes to the described self-locking of the described bearing arrangement according to the invention or the bush bearing according to the invention.

Reference List

1

bush bearing

2

bearing core

4

elastomer body

6

sleeve element

8th

locking element

20

mounting surface

21

drilling

23a,b,c

the detent element facing boundary surface

40

compressed elastomer section

60

outer surface

64

window, transverse opening

65

boundary surface

81

bevel, ramp

82

peripheral surface

83a,b,c

boundary surface facing the bearing core

85

contact surface

90

cylindrical passage

91

lateral surface, boundary surface

92

recess

100

boundary section

110

boundary surface

120

gradation, groove

130

contact surface

A

longitudinal axis

R1, R2

radial direction

Claims (16)

Bush bearing (1) for a motor vehicle to be accommodated in a bearing receptacle assigned to the bush bearing, comprising a bearing core (2), an elastomer body (4) at least partially enclosing the bearing core and a sleeve element (6) which holds the elastomer body in relation to a bearing axis (A ) encompasses the circumference, the sleeve element (6) having a wall with an outer lateral surface (60) which is designed to rest against a boundary surface (91) of the bearing mount, characterized in that the wall of the sleeve element (6) has a transverse opening (64) through which a latching element (8) embedded in sections in the elastomer body (4) and materially connected to the elastomer of the elastomer body extends radially beyond the outer lateral surface (60) of the sleeve element (6), the bush bearing (1) starting from a first Operating arrangement is designed to generate a radially outwardly acting elastic reaction force on the locking element ( 8) in a second operating arrangement in which the bearing core (2) and sleeve element (6) are axially displaced relative to each other. Bush bearing (1) to claim 1 , characterized in that the elastic reaction force acting radially outwards on the latching element (8) in the second operating arrangement can be generated via compression of the elastomeric material of the elastomeric body (4) caused by the axial displacement of the bearing core (2) relative to the sleeve element (6). is, this elastomeric material being arranged in a volume section lying between the latching element (8) and the bearing core (2). Bush bearing (1) according to one of Claims 1 or 2 , characterized in that one latching element (8) has a substantially convex boundary surface (83a, b, c) in a longitudinal section of the bearing (1) on a boundary section facing the bearing core (2). Bush bearing (1) according to one of Claims 1 until 3 , characterized in that the bearing core (2) has a substantially concave boundary surface (23a, b, c) in a longitudinal section of the bearing on a detent element (8) facing boundary section. Bush bearing (1) according to one of Claims 1 until 4 , characterized in that opposing boundary surfaces (23a, b, c; 83a, b, c) of the bearing core (2) and the locking element (8) are designed to correspond to one another in such a way that in the second operating arrangement, in which the bearing core (2 ) is axially deflected relative to the sleeve element (6), the elastomer material arranged axially between the locking element (8) and the bearing core (2) can be compressed in order to generate the elastic reaction force with a radial component on the locking element. Bush bearing (1) according to one of claims 3 , 4 or 5 , characterized in that the substantially convex boundary surface (83a, b, c) of the locking element (8) and / or the substantially concave boundary surface (23a, b, c) of the bearing core (2) in the longitudinal section of the bearing (1) in sections is or are rectilinear. Bush bearing (1) according to one of Claims 1 until 6 , characterized in that the sleeve element (6) and bearing core are integrally connected to the elastomer body (4). Bush bearing (1) according to one of Claims 1 until 7 , characterized in that the latching element (8) in the first, force-free operating arrangement is mounted in a freely floating manner relative to the transverse opening (64) in the elastomer body (4). Bush bearing (1) according to one of Claims 1 until 8th , characterized in that the extension of the locking element (8) in the circumferential direction is at least twice the longitudinal extension of the locking element (8). Bush bearing (1) according to one of Claims 1 until 9 , characterized in that the locking element (8) has an approximately cuboid shape. Bush bearing (1) according to one of Claims 1 until 10 , characterized in that the bush bearing (1) has at least one further latching element (8) circumferentially offset from the first, the wall of the sleeve element (6) having a transverse opening (64) associated with the further latching element (8) through which the additional latching element (8) embedded in sections in the elastomeric body (4) and materially connected to the elastomer of the elastomeric body extends radially beyond the outer lateral surface (60) of the sleeve element (6), the bush bearing (1), starting from a first operating arrangement, being designed for Generating a radially outward-acting elastic reaction force on the further locking element (8) in a second operating arrangement, in which the bearing core (2) and sleeve element (6) are axially displaced relative to one another. Bearing arrangement comprising a power transmission element with at least one bearing seat in which an associated bush bearing (1) according to one of Claims 1 until 11 is received, the bearing seat being defined by an at least sectionally cylindrical boundary surface (91) on which the bush bearing (1) is supported via the sections of the outer lateral surface (60) of the sleeve element (6), the boundary surface (91) of the bearing body has a radial clearance associated with the latching element (8) for receiving at least one radial end section of the latching element (8). bearing arrangement claim 12 , characterized in that the radial clearance is designed as a circumferential groove (120). bearing arrangement claim 12 or 13 , characterized in that the radial clearance is adapted to the axial and circumferential extent of the latching element (8), such that the latching element (8) engages in the radial clearance in the circumferential and/or axial direction of the bearing (1) essentially without play . bearing arrangement claim 12 , 13 or 14 , characterized in that the power transmission element is designed as a formed sheet metal element or as a forged link. Bearing arrangement according to one of Claims 12 until 15 , characterized in that the radial clearance associated with the latching element (8) is designed as a radial step (120) of the boundary surface (91) of the bearing seat and has a predetermined radial depth for setting a predetermined radial rigidity of the bush bearing (1) held in the bearing seat .

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