DE102021104646A1 - Steering actuator of a rear axle steering and method for assembling a steering actuator - Google Patents

Abstract

A steering actuator for rear-axle steering has a multi-part housing (2) and a rotary-linear gear (5) arranged in the housing (2). The rotary-linear gear (5) comprises a rotating gear component (17) which is supported on a first housing component (3) on the one hand and on a second housing component (4) on the other hand and is provided as a drive element of the rotary-linear gear (5). and a driven element (7), which can be displaced in a rotationally secured manner in a cavity formed by the two housing components (3, 4), concentrically surrounds a bearing (26), in particular an angular contact roller bearing, which holds the rotating transmission component (17) relative to the housing ( 2) is supported, and one of the two housing components (3) is connected to a compensating element (31) fastened in the housing (2) by means of a press fit (32).

Description

The invention relates to an electromechanical steering actuator that can be used in a rear-axle steering system of a motor vehicle. Furthermore, the invention relates to a method for assembling a steering actuator for a rear-axle steering system.

From the DE 10 2019 109 166 A1 a method for producing a mother-planet arrangement of a planetary roller gear, which is used in a rear-axle steering system, is known. Here, a plurality of planets with several cage elements and two nut halves are put together, with a spacer ring being inserted between the nut halves. The spacer ring has the task of setting a preload within the planetary roller gear.

In an adjusting gear, such as a planetary roller gear within an electromechanical actuator of a rear-axle steering system, freedom from backlash, at least in the adjusting direction, can be a crucial requirement. In order to avoid play even in actuators produced in large series, it is conceivable to use shim disks between individual housing parts and a rotary-linear gear to be installed in the housing, for example planetary roller gears. For this purpose, numerous differently dimensioned shim disks have to be kept ready, with suitable shim disks having to be assigned to specific housing parts subject to series distribution during the course of assembly. The prior art relating to shim disks is exemplified in the documents DE 10 2020 104 857 A1 and EP 3 245 719 B1 pointed out.

Details of a steering actuator for a rear-axle steering of a vehicle are, for example, in DE 10 2019 115 936 A1 described. The steering actuator comprises a push rod which can be displaced within a housing in a manner secured against rotation. A drive unit comprising an electric motor is provided for actuating the connecting rod. The electric motor drives an axially immovable threaded nut, which represents an input-side element of a threaded drive. The push rod is located on the output side of the screw drive. A belt drive or a planetary gear can be connected as a reduction gear between the electric motor and the screw drive.

A rear-axle steering system in a motor vehicle enables a steering lock on the rear axle of the vehicle, with the rear wheels being able to be turned in the same direction as the front wheels or in the opposite direction to the front wheels, depending on the driving situation. This makes it possible to achieve both excellent maneuverability at low speeds compared to the vehicle dimensions and high stability, especially during evasive maneuvers, in the upper speed range. In principle, rear axle steering can also be used in vehicles that are designed for automated driving. In this context, an example is given on the EP 3 317 162 B1 pointed out.

the DE 10 2018 129 372 A1 discloses a further actuator of a rear-axle steering system, also comprising a screw drive. In this case, a spindle nut of the screw drive is made up of several parts which are prestressed against one another in such a way that the screw drive is self-locking.

Other types of actuators for rear axle steering are, for example, in the documents DE 10 2019 111 153 A1 , DE 10 2019 125 310 A1 , DE 10 2018 130 228 B3 and DE 10 2016 212 408 B4 described. In the latter case, a tensioning element is provided which engages in a thread of a spindle nut.

A method for operating a motor vehicle with an actively controllable rear axle steering is for example in DE 10 2017 008 303 A1 disclosed. Within the scope of this method, among other things, the position of an instantaneous center of rotation of a motor vehicle about its vertical axis when cornering is determined.

The invention is based on the object of further developing a steering actuator for a rear-axle steering of a motor vehicle compared to the stated prior art, in particular from a manufacturing perspective, with freedom from play being able to be achieved in a reliably reproducible manner even under conditions of series production.

This object is achieved according to the invention by a steering actuator having the features of claim 1. The object is also achieved by a method for assembling a steering actuator according to claim 9. The configurations and advantages of the invention explained below in connection with the assembly method also apply to the device , i.e. the actuator intended for use in a rear-axle steering system, and vice versa.

As an electromechanical actuator, the steering actuator comprises, in a manner known per se, a multi-part housing and a rotary-linear gear arranged in the housing, ie a gear which converts a rotation into a linear movement implemented. The rotary-linear gear has a rotating gear component which is supported on the one hand on a first housing component and on the other hand on a second housing component and is provided as the driving element of the rotary-linear gear. This drive element, which is mounted between the two housing components, concentrically surrounds a driven element, which can also be attributed to the rotary-linear gear and which can be displaced in a rotationally secured manner in a cavity formed by the two housing components. A compensating element fastened in the housing with the aid of a press fit is connected between one of the bearings, which supports the rotating transmission component acting as a drive element relative to the housing, and one of the two housing components accommodating the rotary-linear transmission.

In this case, the interference fit is not necessarily the only means for fastening the compensating element in the associated housing component. In particular, as will be explained in more detail below, the production of an interference fit can only be provided as an intermediate step in the context of the production process. In no case are separate fastening elements, for example in the form of screws, provided for fastening the compensating element in the housing component.

A significant advantage of using a compensating element to be fastened by means of an interference fit compared to conventional solutions is that compensating elements of uniform dimensions can be used in series production. The use of shim disks, which would have to be kept available in numerous thicknesses and selected in complex procedures, is no longer necessary.

According to one possible embodiment, the compensating element has a cylindrical section held in the first housing component and a conical section adjoining this section and supporting the rotating transmission component. Thus, various functions of the compensating element, namely its mounting in one of the housing components on the one hand and the formation of a support for the transmission component that is intended as the drive element of the rotary-linear transmission and is to be mounted without play, on the other hand, are combined in a one-piece element made of the same material, with the conical section of the compensating element can be connected directly to its cylindrical section. In a modified form of the compensating element, its section designated as cylindrical can also have a slight conicity, which, however, is far less pronounced than the conicity of that section against which the bearing supporting the housing component, in particular in the axial direction, strikes.

In any case, said bearing can be partially formed by the compensating element, for example by rolling elements of the bearing rolling directly on a surface of the compensating element. Otherwise, for example, a bearing disk of the bearing with which the drive element of the rotary-linear gear is mounted in the housing makes contact with the compensating element. The bearing mentioned is, for example, an axial-radial roller bearing, in particular an angular ball bearing or an angular roller bearing.

Regardless of the design of the axial-radial roller bearing, this bearing can be mirror-symmetrical to a second axial-radial roller bearing that supports the rotating transmission component in the opposite axial direction and is inserted into the second housing component. In particular, the two axial-radial roller bearings can be shaped identically.

• - Bereitstellung zweier Gehäusehälften, welche dazu ausgebildet sind, jeweils einen Teil eines sich in Längsrichtung des Lenkungsaktuators erstreckenden Hohlraumes zu bilden,
• - Bereitstellung einer Getriebebaugruppe, welche ein Rotativ-Linear-Getriebe mit einem rotierbaren Antriebselement und einem linear verlagerbaren Abtriebselement umfasst,
• - Einsetzen eines in stufenlos wählbarer Position ohne gesonderte Befestigungselemente fixierbaren Ausgleichselementes sowie des Rotativ-Linear-Getriebes in den Hohlraum derart, dass ein rotierbares Antriebselement des Rotativ-Linear-Getriebes spielfrei zwischen den beiden Gehäusehälften gelagert wird.

The rear axle steering actuator can be installed in the following steps:

• - Provision of two housing halves, which are designed to each form part of a cavity extending in the longitudinal direction of the steering actuator,
• - Provision of a transmission assembly, which includes a rotary-linear transmission with a rotatable input element and a linearly displaceable output element,
• - Insertion of a compensating element that can be fixed in an infinitely variable position without separate fasteners and of the rotary-linear gear in the cavity such that a rotatable drive element of the rotary-linear gear is mounted without play between the two housing halves.

The term “housing halves” is used, without restricting generality, for two housing components that can be put together and together enclose the interior of the housing, which do not necessarily have to be of the same type or mirror-symmetrical to one another. In any case, the central axis of the steering actuator runs through both housing halves.

• Gemäß einer ersten Verfahrensvariante wird das Ausgleichselement durch einen Pressverband fest in der Gehäusehälfte verankert. Diese kraftschlüssige Verankerung erfolgt insbesondere durch Herstellung eines Querpressverbandes zwischen dem Ausgleichselement und der Gehäusehälfte. Der Querpressverband ist herstellbar, indem die Gehäusehälfte erwärmt und anschließend das Ausgleichselement in eine hierfür vorgesehene Ausnehmung, welche sich in der Gehäusehälfte befindet und konzentrisch zur Mittelachse des Gehäuses und damit des Rotativ-Linear-Getriebes angeordnet ist, eingesetzt wird. Durch die anschließende Angleichung der Temperatur der Gehäusehälfte an die Temperatur der übrigen Komponenten des Aktuators einschließlich des Ausgleichselementes entsteht der hoch belastbare Pressverband. Die Herstellung des Querpressverbandes stellt damit ein Warmfügen dar.

As far as the positioning of the compensating element in one of the housing halves is concerned, various process variants can be implemented:

• According to a first variant of the method, the compensating element is firmly anchored in the housing half by means of an interference fit. This non-positive anchoring takes place in particular by producing a transverse interference fit between the compensating element and the housing half. The transverse interference fit can be produced by heating the housing half and then inserting the compensating element into a recess provided for this purpose, which is located in the housing half and is arranged concentrically to the central axis of the housing and thus of the rotary-linear gear. The high-strength interference fit results from the subsequent adjustment of the temperature of the housing half to the temperature of the other components of the actuator, including the compensating element. The production of the transverse interference fit thus represents a warm joining.

According to an alternative variant of the method, the compensating element is initially only provisionally positioned in a non-positive manner in the recess of the housing half. In this case, too, there is a press fit between the housing half and the compensating element, although the strength of this press fit is not designed for the operation of the steering actuator. Rather, it is a pre-positioning of the compensating element, which can still be corrected in the course of further assembly. The initially variable positioning of the compensating element with moderate forces can be used to set the desired freedom from play in the steering actuator.

After the final position of the compensating element has been established, ie the axial installation dimension has been set, an integral connection can be made between the compensating element and the associated housing half, for example by resistance welding. In particular, this can involve capacitor discharge welding or short-pulse welding. Such a welding process can be efficiently integrated into the manufacturing process. The prior art is in this context on the DE 10 2014 210 832 A1 pointed out.

The rotary-linear gear of the steering actuator can be preceded by a reduction gear designed as a rotary-rotary gear, for example a toothed gear, in particular a planetary gear, or a belt transmission, in particular in the form of a belt drive or chain drive. Alternatively, a direct, ie gearless, electric drive of the input-side element, in particular the planet carrier, of the rotary-linear gear can be implemented. In this case, the drive element of the rotary-linear gear is firmly connected to the rotor of an electric motor or is formed directly by such a rotor.

A planetary roller gear, among others, is suitable as the rotary-linear gear of the steering actuator. For the technical background, reference is made to the DE 10 2018 130 612 A1 pointed out. In particular, the planetary roller gear of the steering actuator can be a planetary roller gear with a driven cage, that is to say a planetary carrier. The advantage of this design lies in the fact that a pitch-true planetary roller gear is implemented. A reduction ratio that is less extreme than that of a planetary roller gear with a driven nut is accepted here. As an alternative to a planetary roller gear, the use of a ball screw drive can also be considered.

If a pitch-true planetary roller gear is used as a rotary-linear gear, the cage acting as the drive element of this gear can have two mutually mirror-symmetrical, disc-shaped elements, with axial roller bearings being arranged on the sides of these elements facing one another, through which a freely rotatable nut of the planetary roller gear is mounted, whereas axial-radial roller bearings, in particular in the form of angular roller bearings, are located on the two outer sides of the disk-shaped elements that face away from one another. The cage of the planetary roller gear thus has a multiple function, namely guiding the planet to be driven and the transmission of axial forces between the output element of the rotary-linear gear and the housing of the actuator via the planet, the nut and the various bearings, in particular roller bearings. The speed of the nut is irrelevant when operating the planetary roller gear. Individual parts of the nut can be adjusted relative to one another in a manner known in principle, in particular by means of a thread, in order to set a preload within the planetary roller gear.

• 1 ausschnittsweise einen Lenkungsaktuator einer Hinterachslenkung eines Kraftfahrzeugs in einer Schnittdarstellung.

An exemplary embodiment of the invention is explained in more detail below with reference to a drawing. Herein shows:

• 1 a detail of a steering actuator of a rear-axle steering system of a motor vehicle in a sectional view.

A steering actuator identified overall by the reference numeral 1 is provided for use in a rear-axle steering system of a motor vehicle. With regard to the basic function of the steering actuator 1, reference is made to the prior art cited at the outset.

A housing 2 of the steering actuator 1 is composed of two housing components 3 , 4 . In the housing 2 is a rotary-linear gear 5, in the present case a planetary roller gear taken. Several planets 6 of the planetary roller gear 5 contact a threaded spindle 7 which is rigidly connected to a connecting rod 8 . In principle, a one-piece design of the threaded spindle 7 and the connecting rod 8 is also possible. The planets 6 have a profile without grooves, which engages in the thread of the spindle 7 . The threaded spindle 7 represents the output element of the rotary-linear gear 5 and is guided in the housing 2 by means of an anti-rotation device 9 so that it can be displaced but not rotated. A securing element, which is to be attributed to the anti-rotation device 9 and is rigidly connected to the push rod 8 , is denoted by 10 . The securing element 10 is guided in a guide contour 11 which is provided by the housing component 4 . The two housing components 3, 4 are also referred to as housing halves for the sake of simplicity. A fork-shaped connection element 10 is screwed to the push rod 8 of the steering actuator 1 and coupled in a manner known per se to other chassis components, not shown.

The steering actuator 1 is designed overall as an electromechanical actuator, with an electric motor (not shown) being firmly connected to the housing 2 . The electric motor drives the rotary-linear transmission 5 via a belt transmission 15, namely a belt transmission with a belt 16.

A connection area in which the two housing halves 3, 4 are connected to one another is denoted by 12. An annular groove 13 can be seen in the connection area 12, in which a seal 14 is inserted, with which the housing 12 is statically sealed.

On the output side of the belt transmission 15, which is located inside the housing 2 together with the rotary-linear transmission 5, there is a cage 17 as the output element of the belt transmission 15, which at the same time represents the input-side element of the rotary-linear transmission 5. The cage 17 has a cylindrical basic shape and is arranged concentrically to the threaded spindle 7 and thus to the central axis of the steering actuator 1 . The planets 6 are guided through the cage 17 . The use of the cage 17 as a drive element of the planetary roller gear 5 is crucial to the fact that it is a pitch-true planetary roller gear. This means that each revolution of the cage 17 is converted into a clearly defined advance of the push rod 8 .

The cage comprises a sleeve section 37, on the outer peripheral surface of which teeth are formed which interact directly with the belt 16, ie the toothed belt. This section 37 is connected to an outer cage washer 22 on each of the two end faces of the sleeve section 37 . The outer cage disks 22 are adjoined radially inwards, i.e. in the direction of the central axis of the planetary roller gear 5, partially overlapping the outer cage disks 22, inner cage disks 23, which are connected to inner cage elements 24, which are also assigned to the cage 17 and contact the planets 6.

In addition to its central area meshing with the thread of the spindle 7, each planet 6 has two comparatively thin end areas that are also profiled without a pitch. These end portions of the planets 6 are permanently spaced from the threads of the spindle 7 and instead contact a spindle nut 18 which is freely rotatable within the cage 17. Two nut parts 19, 20 of the spindle nut 18 that can be screwed together each have a smooth profile on their inner peripheral surface, which engages in one of the end sections of each planet 6. The positioning of the first nut part 19 in relation to the second nut part 20 is secured with the aid of a lock nut 21 .

Axial roller bearings 25 are located on both end faces of the spindle nut 18 and are each supported on one of the squirrel cage washers 22 . On the opposite sides, i.e. outsides, of the cage washers 22 are angular roller bearings 26, 27 which are also provided for the transmission of axial forces between the spindle nut 18 and the housing 2 and thus ultimately between the push rod 8 and the housing 2. In the present case, cylindrical rollers act as rolling bodies 29 of the roller bearings 25, 26, 27.

The rotary-linear gear 5 is inserted without play between the housing components 3, 4. A compensating element 31 is provided for reliably adjusting the freedom from play of steering actuators 1 produced in series production, which is fastened in the first housing component 3 by means of a press fit 32 . The overall sleeve-shaped compensating element 31 has a cylindrical section 33 and an adjoining conical section 35, with annular gaps 34, 36 being formed between the various sections 33, 35 and the housing components 3.

A likewise conical housing washer 30 of the angular roller bearing 26 rests on the conical section 35 . The associated shaft washer of the angular roller bearing 26 provided for supporting the spindle nut 18 in particular in the axial direction is denoted by 28 . The wave washer 28 has a corresponding to the shape and arrangement of Rolling elements 29 of the angular roller bearing 26 have a conical rolling element track and an adjoining cylindrical section 38 which, in relation to the central axis of the planetary roller gear 5, is located radially inside the said rolling elements 29. In the exemplary embodiment, the cylindrical section 38 directly surrounds the outer peripheral surface of the inner cage washer 23 which is adjacent to the compensating element 31 . Correspondingly, the shaft washer of that angular contact roller bearing 26 which is located on the side of cage 17 facing away from compensating element 31 also extends over surface sections of both an outer cage washer 22 and an inner cage washer 23. In the case of the two angular roller bearings 26, 27, which in one case on the compensating element 31 and in the other case on the second housing half 4, which is not provided with a compensating element, these are identical parts which are arranged mirror-symmetrically to one another.

Reference List

1

steering actuator

2

Housing

3

housing component

4

housing component

5

Rotary linear gear, planetary roller gear

6

planet

7

lead screw

8th

push rod

9

anti-rotation device

10

fuse element

11

guide contour

12

connection area

13

ring groove

14

poetry

15

belt transmission

16

belt

17

cage, transmission component

18

spindle nut

19

female part

20

female part

21

locknut

22

outer cage washer

23

inner cage washer

24

inner cage element

25

thrust roller bearing

26

angular contact bearing

27

angular contact bearing

28

wave washer

29

rolling elements

30

housing washer

31

compensation element

32

press bandage

33

cylindrical section of the compensation element

34

gap

35

conical section of the compensation element

36

gap

37

sleeve section of the cage

38

cylindrical section of the wave washer

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was 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.

Patent Literature Cited

• DE 102019109166 A1 [0002]
• DE 102020104857 A1 [0003]
• EP 3245719 B1 [0003]
• DE 102019115936 A1 [0004]
• EP 3317162 B1 [0005]
• DE 102018129372 A1 [0006]
• DE 102019111153 A1 [0007]
• DE 102019125310 A1 [0007]
• DE 102018130228 B3 [0007]
• DE 102016212408 B4 [0007]
• DE 102017008303 A1 [0008]
• DE 102014210832 A1 [0021]
• DE 102018130612 A1 [0023]

Claims (10)

Steering actuator for rear-axle steering, having a multi-part housing (2) and a rotary-linear gear (5) arranged in the housing (2), which has a rotating, on the one hand on a first housing component (3) and on the other hand on a second housing component ( 4) comprises a supporting gear component (17), which is provided as the drive element of the rotary-linear gear (5) and concentrically surrounds an output element (7), which can be displaced in a rotationally secured manner in a cavity formed by the two housing components (3, 4), between a bearing (26) which supports the rotating transmission component (17) relative to the housing (2) and one of the two housing components (3) a compensating element (31) fastened in the housing (2) by a press fit (32) is connected. steering actuator claim 1 , characterized in that the compensating element (31) comprises a cylindrical section (38) held in the first housing component (3) and a conical section (35) adjoining this section (38) and supporting the rotating transmission component (17). steering actuator claim 2 , characterized in that on the conical section (35) of the compensating element (31) is arranged a housing disc (30) of an axial-radial roller bearing (26) provided for supporting the rotating transmission component (17). steering actuator claim 3 , characterized in that the axial-radial roller bearing (26) supported by the conical section (35) of the compensating element (31) is mirror-symmetrical to a second one, which supports the rotating transmission component (17) in the opposite axial direction and is incorporated into the second housing component (4th ) used axial-radial roller bearing (27) is formed. Steering actuator according to one of Claims 1 until 4 , characterized in that a planetary roller gear is provided as the rotary-linear gear (5). steering actuator claim 5 , characterized in that the planetary roller gear (5) has a planetary (6) guiding cage (17) as a drive element. steering actuator claim 3 and 6 , characterized in that the cage (17) has two disc-shaped elements (22) which are mirror-symmetrical to one another, with axial roller bearings (25) being arranged on the sides of these elements (22) facing one another, through which a freely rotatable nut (18) of the planetary roller gear (5) is mounted, whereas the two axial-radial roller bearings (26, 27) are located on the two outer sides of the disc-shaped elements (22) facing away from one another. Steering actuator according to one of Claims 1 until 7 , characterized in that the interference fit (32) is designed as a transverse interference fit. Method of assembling a steering actuator (1), comprising the following steps: - Provision of two housing halves (3, 4), which are designed to each form part of a cavity extending in the longitudinal direction of the steering actuator (1), - Provision of a transmission assembly, which comprises a rotary-linear transmission (5) with a rotatable drive element (17) and a linearly displaceable output element (7), - Insertion of a compensating element (31) that can be fixed in an infinitely variable position without separate fastening elements and of the rotary-linear gear (5) in the cavity in such a way that a rotatable drive element (17) of the rotary-linear gear (5) is free of play between the two Housing halves (3, 4) is stored. procedure after claim 9 , characterized in that the compensating element (31) is initially prepositioned in the form of a press fit (32) in the first housing component (3) and is connected in a later method step by resistance welding to the first housing component (3).

Images