DE102015221409A1 - Bearing assembly with a device for adjusting stiffness in the bearing assembly - Google Patents

Abstract

The invention relates to a bearing arrangement (2, 20, 33) having a device (1, 30) for adjusting prestressing in the bearing arrangement (2, 20, 33), wherein the device (1, 30) comprises at least one intermediate ring (11, 34 ), which between at least one bearing ring (10, 22c, 37) of a rolling bearing (5, 22, 26, 27) of the bearing assembly (2, 20, 33) and a bearing support (6, 23) of the rolling bearing (5, 22, 26, 27) is arranged and which has a support structure, and wherein the support structure of interconnected support members (13, 14, 31a, 32a) is formed, wherein at least one elastic actuator (16, 17, 41) between a first support member (13 , 31a) and a second support element (14, 32a).

Description

Field of the invention

The invention relates to a bearing assembly and a device for adjusting stiffness in the bearing assembly, wherein the device comprises at least one intermediate ring which is arranged between a bearing seat and a bearing ring of a rolling bearing of the bearing assembly. The intermediate ring has a support structure with defined stiffnesses, wherein the support structure is formed from interconnected support elements.

Background of the invention

Rolling bearings are among other things also distinguished according to the type of main load direction and accordingly divided into radial and thrust bearings. Radial bearings have a nominal pressure angle in ranges of 0 degrees to 45 degrees and thrust bearings in ranges> 45 degrees to 90 degrees. The nominal pressure angle is included between the pressure lines of a rolling bearing and its radial plane. The radial plane is an imaginary plane which is pierced perpendicularly by the axis of rotation of the respective roller bearing. The respective pressure line of a rolling element is shown in a longitudinal section of the rolling bearing along its axis of rotation, which at the same time extends through the respective center or along the axis of symmetry of the rolling bodies.

The pressure line of ball bearings passes through the center of the balls and at the same time by a contact point of the respective ball with the inner raceway and by a contact point of the respective ball with the outer raceway. The bearing rolling elements of a ball bearing transfer the resulting forces in the direction of the pressure lines from one bearing ring to the other. In the case of ball bearings subjected exclusively to radial loads, a pressure angle of 0 ° results and, with exclusively axially loaded bearings, a pressure angle of 90 °. For axially and radially loaded bearings are depending on the main load direction, the pressure angle either between 0 and 45 degrees or greater than 45 °.

Tapered roller bearings are inherently radial and axially resilient bearings.

The previously considered type of axially and radially resilient bearings is commonly referred to as angular contact bearings. Angular bearings are usually installed in pairs. In the case of radial loading of a bearing, an axial force component which must be received by the second and to the first bearing mirror-inverted angular contact bearing is formed in this bearing. An optimal contact pattern results when, in total, carry the rolling elements distributed over half the circumference of the bearing. An angular contact bearing loaded with radial loads should be preloaded with an axial force, so that half the bearing circumference is loaded in accordance with the requirements valid for load capacity specifications. If the axial force is lower, reduces the number of supporting rolling elements and thus the carrying capacity of the angular bearing. In a bearing arrangement with two angular bearings in O- or X-arrangement, the two angular contact bearings mutually absorb the resulting axial forces. The degree of preload, with which these two angular contact bearings are biased against each other, thus determines their carrying capacity.

In other load cases, angular contact bearing arrangements should be biased against each other for axial clearance compensation. These games arise z. B. by stress-related elastic deformations in the camp. By axial preload and the rigidity of the bearings is increased. The stiffness is a quantity that describes the resistance to elastic deformation. It depends on the elasticity of the material and the geometry of the angular contact bearing. The stiffness of an angular contact bearing arrangement also depends on the design features and material properties of the surrounding construction. Criteria are, for example, the fits of the bearing seats, the material of the bearing seats and the elasticity or rigidity of all lying in the power flow parts of the bearing assembly including the contact surfaces.

When mounting the angular contact bearing assembly, a bearing ring of one of the angular contact bearings is moved by tightening a nut until the angular contact bearing assembly has the desired bias. The required axial distances and axial stops are generated by inserting intermediate rings or spacers.

US6,283,639B1 shows an angular bearing arrangement, for example, for supporting a pinion shaft. The angular contact bearing assembly is formed by two tapered roller bearings, which are axially biased against each other. The device with which the bias is generated in the angular contact bearing assembly is formed by an intermediate ring in the form of a spacer sleeve. The spacer sleeve is located between the end faces of the two inner rings of Angular contact bearing arrangement. The preload is created by turning a nut. The nut sits on a thread of the pinion shaft and abuts axially on an inner ring of one of the angular contact bearings. The bias is adjusted via the intermediate ring whose support structure is formed of three support elements. The front side of the first inner ring abuts an annular relatively rigid support member of the support structure. At the front of the other inner ring is another rigid support element. The two rigid support elements are connected to each other by means of a support element, which has a substantially lower rigidity and which holds the two inner rings axially to each other at a distance. The distance between the two support elements is reduced by turning the nut as long as it allows the lower stiffness of the intermediate element with almost invariable torque on the nut. If permissible tightening torques on the nut are exceeded, the process is interrupted and the preload in the angular contact bearing arrangement is set.

In US2011 / 0293210A1 a bearing arrangement is described in which a shaft is mounted by means of two angular contact ball bearings in a housing. The outer rings of the angular contact ball bearings sit in the housing and are axially supported by a spacer sleeve together. The inner ring of one of the angular contact ball bearings sits on the shaft and is supported axially against a shaft shoulder. The inner ring of the other angular contact ball bearing is axially slidably mounted on the shaft and is held by a support structure of a device for adjusting bias in the bearing assembly to the other bearing ring at a distance. Other elements of this device for adjusting biases are an axial spring and a nut. The axial spring adjoins the inner ring on the opposite side to the support structure and is clamped between the inner ring and the nut. The mother sits on a thread of the shaft. The support structure is a spacer sleeve with two ring-like support elements. The one support element is axially supported on the one inner ring and the other support member axially on the other inner ring. Several axially aligned actuators extend between the two support members. One set of actuators is articulated to one support member and another set of actuators articulated to the other support member. In each case an actuator of the one set is pivotally connected to an actuator of the further set in the middle between the support elements. Out US2011 / 0293210A1 shows that the bearing assembly is to be biased by the device for adjusting the bias as usual backlash and the stiffness of the bias is regulated by the device in the sense of a more precise bearing life and vibration damping. By tightening the nut while the support elements are moved towards each other. The joints of the actuators give way so that they are deflected radially in the direction of the shaft and are supported against each other and on the shaft.

Another device for adjusting bias in a bearing assembly is in DE 10 2009 056 352 A1 described. This device is an intermediate ring, which is arranged radially between an outer bearing ring of a rolling bearing and a housing. The task of the intermediate ring is to dampen or prevent vibrations such as structure-borne noise. The device is formed by two ring-like support elements and a spring portion. Depending on one of the support elements joins the left and right of the outer ring of the bearing and is supported there on this. The spring section connects the two support elements axially. The spring portion is elastically clamped in the bearing assembly radially between the outer ring of the rolling bearing and a housing. The bias of the spring portion is adjusted by radial recesses, which extend slot-like axially, or by triangular apertures, which produce axially directed actuators or circumferentially inclined actuators between the support members. The size of the recesses or the thickness of the resulting elastic actuators determines the radial bias of the intermediate ring.

Another device for adjusting preloads in a bearing arrangement is in DE69114952T2 described. The purpose of this device is to generate radial biases between an outer ring of a rolling bearing of the bearing assembly and a housing for damping vibrations. For this purpose, the device has a cage-like support structure and elastic cushions. The support structure consists of annular support elements, which are axially opposite each other and are connected to each other via longitudinal support members. The longitudinally extending support elements are arranged in the circumferential direction at a distance from each other so that in the circumferential direction between each two adjacent support members and portions of the lateral support members, a window is formed. In each window sits an elastic pillow. The elastic pads are clamped radially between the outer ring and the housing and held in position via the support structure. The preload between the rolling bearing and the housing depends on the geometry and stiffness as well as the elasticity of the material of the pads.

Description of the invention

The object of the invention is to provide a device with which the bias of a bearing assembly can be adjusted specifically. The device should be simple and inexpensive to produce.

The object is achieved with a device according to the features of claim 1.

The device has an intermediate ring which is arranged in the bearing arrangement radially or axially between a bearing ring of a rolling bearing and a bearing support for the rolling bearing. The rolling bearing has at least one bearing ring, which may be an inner bearing ring or an outer bearing ring. An inner bearing ring is seated on a shaft or similar machine element and an outer bearing ring is seated in a housing, in a bearing plate or in a similar support structure. Alternatively, a rolling bearing is provided in the bearing assembly, which has both an inner bearing ring and an outer bearing ring.

The bearing rings have Wälzlaufbahnen for rolling elements of the rolling bearing of the bearing assembly. Rolling elements are balls or rollers. The intermediate ring is arranged either between an inner bearing ring and a bearing support or between an outer bearing ring and a bearing support. Alternatively, it is conceivable that in each case an intermediate ring is arranged both between the inner bearing ring and a bearing support and the outer bearing ring and a bearing support. Alternatively, it is also provided that in each case one or more intermediate rings are arranged between one of the bearing rings and one or two or more bearing supports. Bearing supports are either shafts mounted with the roller bearing, pins and similar machine elements or fixed shaft elements on which the roller bearings are radially supported via the inner ring. The one or more intermediate rings then usually sit between the inner bearing ring and the shaft element. Bearing supports are also housings in which the outer bearing rings are supported radially or axially via the spacer ring (s). Bearing supports are also shaft heels, housing stops or other axial stops such as discs, circlips, springs or nuts.

The intermediate ring has a support structure formed from cells. The cells are bounded by the webs of interconnected support members. The actuators have defined stiffness, which can complement with defined stiffness of the support structure, but need not. Stiffnesses are understood to mean the resistances of the actuators against elastic deformation, which depend on the geometric shape of the actuators and their cross-sections and on the elastic properties of the materials of the actuators.

According to the actuator is elastically clamped in a cell and articulated hinged to the first support member and held on the second support member or on a web in positive engagement and supported. The advantage of the invention is that the bias of the device or stiffness can be preset as needed and also readjusted. In addition, the same device can be used in various applications and their elasticity can be adjusted to the application-specific requirements. Thus, it is conceivable that in one application with the device high stiffnesses are generated and in the other application relatively low.

The device is generally intended for use in bearing assemblies of all industrial and automotive industries, such as for use in vehicle transmissions or landing gears.

Further embodiments of the invention are described below with reference to exemplary embodiments illustrated in drawings.

Description of the drawings

1 shows a device 1 for adjusting bias voltages in an in 2 shown bearing assembly 2 , The device 1 is shown partially cut in a main view.

2 shows the bearing assembly 2 in a longitudinal section along the axis of rotation 3 a wave 4 and through a cell 15 the device 1 for adjusting bias voltages.

The bearing arrangement 2 has a rolling bearing 5 on, which is designed as a ball bearing. With the rolling bearing 5 is a wave 4 in one as a bearing support 6 running housing rotatably mounted. The rolling bearing 5 consists of an inner bearing ring 7 , Balls 9 and an outer bearing ring 10 , The device 1 for adjustment biasing is an intermediate ring 11 which is radially between the outer bearing ring 10 and the bearing support 6 sitting. The intermediate ring 11 has a support structure consisting of disc-shaped support elements 13 and 14 and from webs 12 is formed. The supporting elements 13 and 14 are axially spaced parallel to each other and axially over the webs 12 connected with each other. The bridges 12 are circumferentially spaced adjacent to each other so arranged and connect the support elements 13 and 14 so that the support structure with cells 15 is provided. The cells 15 are each in the circumferential direction of two webs 12 and axially of two sections of the support elements 13 and 14 limited.

It is also conceivable that the webs and support elements are inclined to the circumferential and axial direction. It is also conceivable that the support elements are formed hollow cylindrical. In the case surrounding one of the support elements the other support member circumferentially. The support elements are radially spaced from each other and radially connected to each other by means of the webs.

Axial is rectified with the longitudinal axis of rotation 3 , On the circumference, the direction is circumferential around the axis of rotation. Radial is transverse to the axis of rotation and thus perpendicular to the axial direction.

The device 1 points in every cell 15 an elastic actuator 16 and an elastic actuator 17 on. The respective actuator 16 respectively. 17 is with defined stiffness between the first support element 13 and a second support element 14 clamped. One actuator each 16 is in each case a cell 15 between the first support element 13 and the second support member 14 clamped at an angle. One actuator each 17 is in each case a cell 15 between the first support element 13 and one of the footbridges 12 elastically clamped.

It is also conceivable that cells also have only one actuator or more than two actuators. It is also conceivable that different cells of a ring are equipped differently with actuators. The actuators in a cell or in an intermediate ring may be of the same type or differ in stiffness and geometry. It is also conceivable that not every cell is occupied by one or more actuators.

That in every cell 15 arranged actuator 16 is with a first end 16a cohesively with the first support element 13 and with a second end 16 cohesively connected to the second support element. That in every cell 15 arranged actuator 17 is lever-shaped and with one end 17a around the joint 17c hingedly movable on the first support element 13 hinged. In addition, the second actuator 17 with a second end 17b at one of the footbridges 12 held in a positive engagement and supported.

It is also conceivable that the first actuator with the second end engages positively or non-positively on the second support member. It is also conceivable that the second actuator with the second end or the second support member is positively, material, or non-positively engaged.

The in 1 shown positive engagement is in each cell 15 by the engagement of the free end 17b of the respective actuator 17 in a detent recess 18b . 18c or 18d a locking contour 18 educated. The locking contour 18 is by several locking approaches 18a and intermediate recesses 18b to 18d made, like out 1a evident. This makes it possible for the preloads in the intermediate ring 11 with which the intermediate ring 11 between the outer bearing ring 10 and the bearing support 6 is clamped by the actuator 17 is adjustable variable.

1a shows the detail Z 1a enlarged and not shown to scale. The detent recesses 18b . 18c or 18d are laterally by two locking lugs 18b are limited and are at different distances to the first end 17a of the actuator on the bridge 12 educated. Each of the detent recesses 18b . 18c or 18d is form-fitting through the free end 17b the movable actuator 17 contactable. By choosing a detent recess 18b . 18c or 18d can provide the desired preload in the intermediate ring 11 be set. The bias is the distance of the detent recess 18b . 18c or 18d from the joint 17c dependent. The detent recess 18d is, for example, farther from the joint 17c removed as the detent recess 18b , By engaging the actuator 17 in the detent recess 18b the support structure is biased stiffer than when engaging the actuator 17 in the detent recess 18d ,

With the in the 1 and 2 shown device 1 can the rigidity of the intermediate ring 11 between the rolling bearing 5 and the housing and thus also the bias voltage with which the rolling bearing 5 is supported in the housing, can be adjusted selectively, whereby the vibration behavior in the bearing device and, for example, the transmission of sound can be influenced.

In 3 is a bearing arrangement 20 in a longitudinal section along the axis of rotation 19 a stub shaft 21 shown. In this bearing arrangement 20 can an in 1 described device 1 in the form of the intermediate ring 11 to be built in. The bearing arrangement 20 is through a housing 24 , a rolling bearing 22 , the stub shaft 21 and a bearing support 23 educated.

The rolling bearing 22 is a tapered roller bearing, but can also be a tapered roller bearing and is made of an outer bearing ring 22a , Tapered rollers 22b and an inner bearing ring 22c educated. An angular contact bearing, in contrast to the tapered roller bearing, although conical races but cylindrical rollers.

The rolling bearing 22 sits in a bearing bore 24c of the housing 24 and is in an axial direction on a shoulder 24a of the housing 24 supported.

The bearing support 23 is a mother 25 with external thread 25a that in a corresponding headwind 24b in the case 24 is screwed. The intermediate ring 11 is axially between the end face of the outer bearing ring 22a and the axial bearing support 23 arranged. In the 1 shown device 1 used to adjust the bearing clearance of the bearing assembly 20 , A basic rigidity of the intermediate ring 11 results from the axial rigidity of the webs 12 , The axial stiffness is further enhanced by the design of the actuators 16 certainly. In addition, the rigidity of the intermediate ring 11 by positioning the free end 17b of the actuator in one of the locking recesses 18b . 18c or 18d be fine adjusted.

4 shows in a longitudinal section along an axis of rotation 29 a shaft bearing arrangement 33 with a device 30 for adjusting preload between two antifriction bearings 26 and 27 , The bearing arrangement 33 has the angular contact ball bearings 26 and 27 , a housing 28 and a wave 29 on. The device 30 is an intermediate ring 34 , the one or optionally also in several parts with two tolerance rings 31 and 32 and elastic cells 40 is composed.

The rolling bearings 26 and 27 each have an inner bearing ring 36 and an outer bearing ring 37 as well as bullets 38 on. The outer bearing rings 36 and 37 each sit in a tolerance ring 31 respectively. 32 and are over this radially in the housing 28 supported. The intermediate ring 34 is partly axial between the tolerance rings 31 and 32 formed and partially also axially between the end faces of the outer bearing rings 36 and 37 , The rolling bearings 26 and 27 are employed against each other and by means of a mother 39 preloaded without backlash. About the device 30 On the one hand, the elasticity of the preload of the bearings 26 and 27 be adjusted and on the other hand, the increase of game by heating in the operation of the bearing assembly 33 be compensated. This is particularly beneficial when the housing 28 consists of a light metal alloy.

5 does not show to scale a detail of the intermediate ring 34 as a settlement in an imaginary level. The cells 40 are circumferentially arranged to each other and each have inside an actuator 41 and a locking contour 42 with several by latching approaches 42a limited locking recesses 42b - 42f on. The actuator 41 is lever-shaped and with one end 41 at the joint 41c hinged to the as a tolerance ring 31 trained support element 31a supported. The locking contour 42 is located axially opposite to the as a tolerance ring 32 trained support element 32a , The axial stiffness of the intermediate ring 34 depends on the material and can also be done by positioning the free end 41b of the actuator 41 in one of the locking recesses 42b - 42f be set, causing the actuator 41 essentially axially in the direction of the roller bearings 26 and 27 is biased. By choosing a detent recess 42b - 42f can provide the desired preload in the intermediate ring 34 be set. The bias is the distance of the detent recess 42b - 42f from the joint 41c dependent. The detent recess 42b is, for example, farther from the joint 41c removed as the detent recess 42f , By engaging the actuator 41 in the detent recess 42f the support structure is biased stiffer than when engaging the actuator 41 in the detent recess 42f , The bearing supports 43 are the tolerance rings 31 respectively. 32 , reference numeral 1 contraption 22c inner bearing ring 2 bearing arrangement 23 bearing support 3 axis of rotation 24 casing 4 wave 24a paragraph 5 roller bearing 24b mating thread 6 bearing support 24c bearing bore 7 inner bearing ring 25 mother 8th not used 25a external thread 9 Bullet 26 roller bearing 10 outer bearing ring 27 roller bearing 11 intermediate ring 28 casing 12 web 29 axis of rotation 13 first support element 30 contraption 14 second support element 31 tolerance ring 15 cell 31a supporting member 16 first actuator 32 tolerance ring 16a first end of the first actuator 32a supporting member 16b second end of the first actuator 33 bearing arrangement 17 second actuator 34 intermediate ring 17a first end of the second actuator 35 bearing support 17b second end of the second actuator 36 inner bearing ring 17c joint 37 outer bearing ring 18 catch contour 38 Bullet 18a latching shoulder 39 mother 18b latching depression 40 cell 18c latching depression 41 actuator 18d latching depression 41a first end of the actuator 19 axis of rotation 41b free end of the actuator 20 bearing arrangement 41c Joint of the actuator 21 stub shaft 42 catch contour 22 roller bearing 42a latching shoulder 22a outer bearing ring 42b -f latching depression 22b roll 43 bearing support

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 6283639 B1 [0008]
• US 2011/0293210 A1 [0009, 0009]
• DE 102009056352 A1 [0010]
• DE 69114952 T2 [0011]

Claims (9)

Bearing arrangement ( 2 . 20 . 33 ) with a device ( 1 . 30 ) for adjusting preloads in the bearing assembly ( 2 . 20 . 33 ), the device ( 1 . 30 ) at least one intermediate ring ( 11 . 34 ), which between at least one bearing ring ( 10 . 22c . 37 ) of a rolling bearing ( 5 . 22 . 26 . 27 ) of the bearing assembly ( 2 . 20 . 33 ) and a bearing support ( 6 . 23 ) of the rolling bearing ( 5 . 22 . 26 . 27 ) and which has a support structure, and wherein the support structure of interconnected support elements ( 13 . 14 . 31a . 32a ) is formed, wherein at least one elastic actuator ( 16 . 17 . 41 ) between a first support element ( 13 . 31a ) and a second support element ( 14 . 32a ), characterized in that an actuator ( 17 . 41 ) in one of the first support element ( 13 . 31a ) and the second support element ( 14 . 32a ) limited cell ( 15 . 40 ) is clamped while the actuator ( 17 . 41 ) hingedly movable on the first support element ( 13 . 31a ) and at the second support element ( 14 . 32a ) is held and supported in at least one positive engagement. Bearing assembly according to claim 1, characterized in that the bias voltages, with which the intermediate ring ( 11 . 34 ) between the bearing ring ( 10 . 22c . 37 ) and the bearing support ( 6 . 23 ) is clamped by the one or more actuators ( 17 . 41 ) of the support structure is adjustable variable. Device for a bearing arrangement according to claim 1, characterized in that the actuator ( 17 . 41 ) in a latching recess on the second support element ( 14 . 32a ) is engaged. Device according to claim 3, characterized in that the actuator ( 17 . 41 ) in a detent recess ( 18b . 42b ) of a plurality of the second support element ( 14 . 32a ) formed locking recesses ( 18b . 18c . 18c . 42b - 42f ) is engaged, wherein all of the locking recesses ( 18b . 18c . 18c . 42b - 42f ) positively by the movable actuator ( 17 . 41 ) are contactable. Bearing arrangement according to claim 1, characterized in that the intermediate ring ( 11 . 34 ) at least partially axially between the end face of the bearing ring ( 10 . 22c . 37 ) and an axial bearing support ( 6 . 23 . 43 ) or on another bearing ring ( 37 ) at least one further rolling bearing ( 26 . 27 ) of the bearing assembly ( 2 . 20 . 33 ) is clamped. Bearing arrangement according to claim 1, characterized in that the intermediate ring ( 34 ) axially between the end face of the bearing ring ( 37 ) and an axial bearing support ( 43 ) or on another bearing ring ( 37 ) of another rolling bearing ( 26 . 27 ) of the bearing assembly ( 33 ) and that the actuator ( 41 ) in directions of the bearing ring ( 37 ) and the bearing support ( 43 ) is biased. Bearing arrangement according to claim 1, characterized in that the intermediate ring ( 11 ) radially between the bearing ring ( 10 ) and a housing of the bearing assembly ( 2 ) is arranged. Bearing arrangement according to claim 1, characterized in that the intermediate ring ( 34 ) at least partially between a bearing ring ( 37 ) of a first rolling bearing ( 26 ) of the bearing assembly ( 33 ) and a second bearing ring ( 37 ) of a second rolling bearing ( 27 ) of the camp ordinance ( 33 ) is arranged, wherein the bearing support ( 43 ) on one of the bearing rings ( 37 ) is trained. Device for a bearing arrangement according to the preamble of claim 1, characterized in that the support structure is formed by a plurality of cells ( 15 . 40 ), wherein the cells ( 15 . 40 ) at least partially by the support elements ( 13 . 14 . 31a . 32a ) and wherein in at least some of the cells ( 15 . 40 ) between a first support element ( 13 . 31a ) and a second support element ( 14 . 32a ) an actuator ( 16 . 41 ) is elastically biased, wherein the actuator ( 16 . 41 ) in at least one direction hingedly movable on the first support element ( 13 . 31a ) and positively connected to the second support element ( 14 . 32a ) is held.

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