DE102022114776B3 - Coupling unit for the reversible coupling of a drive side to a driven side of a drive train - Google Patents

Abstract

Coupling unit for the reversible coupling of a drive side (2) to an output side (3) of a drive train, comprising a linearly displaceable shift sleeve (8) which sits on a drive element (4) of the drive side (2) and has internal teeth (9) in external teeth (5) of the drive element (4), and from a decoupling position along the external toothing (5) via an output element (6) of the output side (3) with engagement of the internal toothing (9) also in the external toothing (7) of the output element (6) can be pushed into a coupling position, with an actuator (10) being provided for moving the shift sleeve (8), which has a linearly displaceable piston (13) and a shift rod (17) coupled to the piston (13) and which is connected to the shift sleeve (8), wherein the shift rod (17) is linearly guided in at least one linear guide (34, 35) in a cylinder housing (11) through which it passes, the shift rod (17) and the linear guide (34, 35 ) have guide surfaces (36, 37, 38) that slide against one another when the shift rod (17) moves, and wherein at least one guide surface (36, 37, 38) of the linear guide or the shift rod (17) is crowned.

Description

The invention relates to a coupling unit for the reversible coupling of a drive side to a driven side of a drive train.

Such a coupling unit, often also called “disconnect unit” or “disconnect unit”, is used, for example, in drive units of a motor vehicle, for example a drive axle, which can also be an electric axle, often called an e-axle. The coupling unit serves to reversibly couple a drive side, on which a torque is applied, to a driven side, to which the torque is to be transmitted and where it is passed on. It can be arranged, for example, between a drive unit and an intermediate shaft in order to couple an output of the drive unit, ie the drive side, to the input of the intermediate shaft, ie the output side. An arrangement between such an intermediate shaft and a differential is also conceivable, in which case the intermediate shaft, on which the torque coming from the drive is applied, represents the drive side, while the differential, to which the torque is transmitted, represents the output side. The coupling unit can therefore be integrated at different positions in such a drive train. In this case, the coupling unit can be switched in order, via a controllable switching means, ie an actuator, to bring about a torque-proof coupling of the input side and the output side or to cancel it again.

Such a coupling unit connects two toothed elements on the input and output side, i.e. an externally toothed input element, for example a first gear wheel, is arranged on the input side, while an externally toothed output element, for example a second gear wheel, is provided on the output side. which are reversibly connected via a coupling element. Such a coupling element is regularly provided in the form of a linearly displaceable shift sleeve, which sits on the drive element, ie is provided on the drive side, and engages with an internal toothing in the external toothing of the drive element. By means of an actuator, the shift sleeve can be moved along the external toothing of the drive element and pushed over the driven element so that the internal toothing of the shift sleeve also engages in the external toothing of the driven element in order to couple the input to the driven side. The input element and the output element are then coupled to one another in a torque-proof manner via the shift sleeve which encompasses them both and connects them via the toothed engagement, so that the torque present on the input side can be transmitted to the output side.

When the shift sleeve is pushed from the drive element onto the driven element, the internal teeth of the shift sleeve and the external teeth of the driven element can come into tooth-on-tooth contact, i.e. the front face of the inner teeth of the shift sleeve runs onto the front face of the outer teeth of the driven element , if the teeth are not in gap at the moment of engagement. On the one hand, this leads to a corresponding stress on the entire switching system, since the actuator continuously applies an axial pushing force to the shift sleeve, and on the other hand, the engagement process is delayed until the toothing is in a gap and the internal toothing is pushed into the external toothing, whereby this shifting process takes place at the actuating speed generally controlled by the actuator. In the event of an impact, the shift rod is subjected to a greater axial load, as described, via the actuator, which can result in the shift rod being slightly deformed, i.e. slightly bent. This in turn creates a tendency to jam between the shift rod and the guide in which the shift rod is slidably guided, which manifests itself in higher friction.

The invention is based on the problem of specifying an improved coupling unit.

To solve this problem, a coupling unit is provided according to the invention for the reversible coupling of a drive side to a driven side of a drive train, comprising a linearly displaceable shift sleeve, which sits on a drive element of the drive side and engages with an internal toothing in an external toothing of the drive element and from a decoupling position along the External toothing can also be pushed into the external toothing of the output element into a coupling position via an output element on the output side with engagement of the internal toothing, with an actuator being provided for moving the shift sleeve, which has a linearly displaceable piston and a shift rod coupled to the piston, which is connected to the shift sleeve wherein the shift rod is linearly guided in at least one linear guide in a cylinder housing through which it passes, the shift rod and the cylinder housing having guide surfaces that slide on one another when the shift rod moves, and at least one guide surface of the cylinder housing or the shift rod is convex .

The coupling unit according to the invention is characterized by a specific design of the linear guide of the shift rod in the cylinder housing, this design being a reduction tion of the friction and clamping forces within the position mechanics.

According to the invention, at least one of the guide surfaces of the cylinder housing and the shift rod, which abut or slide against one another as part of the linear guide of the shift rod, is crowned, i.e. has a specific geometry that deviates from a purely cylindrical shape, so that the guide surfaces ultimately have a line contact, but not, as before, via surface contact. With this integrated crowning, the linear guide is ultimately gimballed, allowing the running partners to tilt slightly in relation to one another. In the case of the coupling unit, this means that when the shift sleeve runs against the output element, i.e. with tooth-to-tooth contact, this crowning or this cardanic design compensates for any bending resulting from the axial force acting on the shift rod during start-up , is possible, so that an alignment error resulting from the bending is compensated and there is no tendency to jam. Since there is no jamming, from which the shift rod first has to be moved out when the teeth are aligned again, the friction present between the guide surfaces can be reduced in this way.

According to the invention, a targeted, albeit naturally small, pivoting mobility is integrated into the linear guide via the convex design of at least one of the guide surfaces, which enables the adjusting mechanism, in the event of an axial collision, to absorb the corresponding axial forces via a slight deformation in such a way that it does not lead to a Jamming and thus an increase in friction occurs.

In a specific embodiment of the invention, it can be provided that a first and a second linear guide, each in the form of an opening, which are spaced apart axially and are each formed by a guide surface, are provided, with the shift rod extending through the openings and with its lateral surface forming the guide surface is guided on the guide surfaces of both linear guides. Accordingly, on the housing side, the switching rod is mounted at two different axial positions via separate linear guides, preferably in the area of the respective housing ends. Each linear guide is implemented in the form of an opening on the housing side, with the switching rod extending through these openings. The inner lateral surfaces of the openings represent the respective guide surface on the housing side, while the outer lateral surface of the switching rod is the guide surface on the rod side. Here, there is quasi a bearing in two bearing planes, with at least one of the guide surfaces involved having a crowning within each bearing plane, so that the described, quasi-cardanic rod mobility is given.

Last but not least, for manufacturing reasons, it is expedient if either only the guide surface of a linear guide or only the guide surface of the shift rod has a crowned shape, but not both friction or sliding partners involved are crowned. This means that one of the sliding partners has a crowning, so that the production of the other sliding partner is not adversely affected by the formation of a crowning.

A specific embodiment of the invention provides that the shift rod is crowned in the area of its guide surface, which area is accommodated in the first linear guide, while the guide surface of the second linear guide is crowned. As described, the bearing planes are axially spaced apart from one another with respect to the longitudinal direction of the shift rod. The first bearing level, i.e. the first linear guide, is provided at the housing outlet, which is adjacent to the coupling point of the drive and driven element, while the second bearing level, i.e. the second linear guide, is provided on the other side of the housing. According to the invention, the convex guide surface is now provided on the shift rod in the area of the first bearing plane, ie the first linear guide, while in the area of the second bearing plane, ie the second linear guide, the guide surface of the linear guide is designed convex. This is advantageous from a manufacturing point of view. The camber on the shift rod can be realized by appropriate local machining of the outside of the rod. The crowning of the guide surface of the second linear guide, which is preferably provided in or on a housing cover, can be formed by simply machining the inner circumference of the cover-side opening, which means that the cover bore is finally ground to a corresponding crowning, so that the corresponding tilting possibility is created here or cardanic trains.

It is particularly expedient if the crowned section of the shift rod is provided adjacent to a sealing element which is provided on the shift rod and seals the shift rod from the linear guide. As described, the shift rod can tilt slightly around the crown. If the crown is positioned immediately adjacent to the sealing element, which seals the switching rod from the linear guide or its guide surface, then in the event of a slight, load-related tilting or bending about the tilting plane of the crown, this will be immediate neighboring sealing element is ultimately only negligibly stressed because the respective tilting path is smaller the closer the point is to the crowning and thus to the tilting plane. Consequently, if the sealing element provided on the shift rod is immediately adjacent to the crowning, it is not moved or acted on to any significant extent in the event of tilting. As a result, the friction in this area does not increase significantly.

It is similarly advantageous if the crowned section of the guide surface of the second linear guide is provided adjacent to a sealing element provided on the housing side, which seals the linear guide from the shift rod. Since the shift rod also performs a slight tilting movement relative to the stationary housing or housing cover in this bearing plane, it is also advisable in this area to position the tilt plane as close as possible to a sealing element that seals the housing from the shift rod. Because then the sealing element is only marginally stressed in this bearing level in the event of a tilting of the rod.

The actuator itself is preferably a hydraulically controllable actuator, which can therefore be adjusted axially by means of a fluid. The piston is preferably actively set in both directions via the fluid. This means that to move from the decoupling into the coupling position, the fluid on one side of the piston is guided into the cylinder housing or the pressure chamber until the piston or the shift sleeve is in the coupling position. To move from the coupling to the decoupling position, the fluid is guided to the other side of the piston or into the pressure chamber of the cylinder housing there, so that the piston and with it the shift rod together with the shift sleeve are moved back axially. Each marked position is therefore actively controlled and approached. In this way, the coupling and decoupling function can be implemented as a "normally stay" function. This is because the piston remains in the respective position, i.e. either the decoupling position or the coupling position, without a continuous pressure build-up via the actuating hydraulics, which enables more efficient switching operation, for example with regard to the "gliding function" of a motor vehicle, in which there is no coupling, but also no energy expenditure for Maintaining this decoupling situation is required.

In order to realize this actuating function of the actuator in both directions, a first sealing element sealing the piston toward the shift rod and a second sealing element sealing the piston toward a wall of a cylinder guiding the piston are expediently provided. These two sealing elements define and seal off two pressure chambers, one in front of and one behind the piston. The piston movement depends on whether the fluid is pressed into the pressure chamber in front of or behind the piston. Suitable sealing rings or the like are used as sealing elements.

It is also conceivable to increase the axial distance between the two bearing planes, ultimately the first and second linear guide, for example by extending the housing cover or by even relocating the linear guide to a more distant part of the housing. This can also be used to reduce friction in the case of a load.
In addition to the coupling unit itself, the invention also relates to a drive train, in particular of a motor vehicle, comprising a drive element and a driven element and a coupling setting of the type described above which reversibly couples them. The drive train can be, for example, an electric axle of such a motor vehicle.

• 1 eine Prinzipdarstellung einer erfindungsgemäßen Kopplungseinheit sowie eines Antriebselements und eines Abtriebselements,
• 2 eine vergrößerte Teilansicht des bereits II aus 1,
• 3 eine vergrößerte Teilansicht des bereits III aus 1, und
• 4 eine Teilansicht einer Kopplungseinheit einer zweiten Ausführungsform mit anderer Art der Führung der Schaltstange.

The invention is explained below using exemplary embodiments with reference to the drawings. The drawings are schematic representations and show:

• 1 a schematic representation of a coupling unit according to the invention and a drive element and a driven element,
• 2 an enlarged partial view of already II from 1 ,
• 3 an enlarged partial view of already III 1 , and
• 4 a partial view of a coupling unit of a second embodiment with a different way of guiding the shift rod.

1 shows a schematic representation of a coupling unit 1 according to the invention, which can also be referred to as a coupling device, and which serves to connect a drive side 2, on which a torque is introduced or is present, with an output side 3, to which the torque is to be transmitted and where it continues is branched to couple. A drive element 4 which has external teeth 5 is provided on the drive side 2 . The drive element 4 is, for example, a gear wheel or an externally toothed shaft.

On the output side 3, an output element 6 is provided, which has external teeth 7, and this output element 6 can also be a gear wheel or an externally toothed shaft or the like. The external teeth 5, 7 are linear radial teeth, the same pitch point and lie on the same radius. In order to couple the drive element 4 to the driven element 6 in a torque-proof manner, a shift sleeve 8 is provided which can be displaced axially. It has internal teeth 9, with which it can be used in the in 1 decoupling position shown fully engages in the external toothing 5 of the drive element 4. This means that in the decoupling position the shift sleeve 8 is only coupled to the drive element 4 . A torque transmission to the output element 6 is not possible in this position. However, if torque is to be transmitted, it is necessary to move the shift sleeve 8 axially and push it over the output element 6 or its external teeth 7, so that the internal teeth 9 of the shift sleeve 8 are pushed into the external teeth 7 and mesh with them. At the same time, the engagement of the internal toothing 9 with the external toothing 5 remains, so that the drive element 4 and the driven element 6 are coupled in a torque-proof manner via the shift sleeve 8 .

In order to realize this movement of the shift sleeve 8, an actuator 10 is provided, which is a hydraulic actuator. It has a housing 11 in which a cylindrical insert 12 formed from sheet metal is received, which forms a guide cylinder and in which a piston 13 is arranged. The housing 11 is closed axially via a cover 14 . The piston 13 can be displaced axially within the cylinder insert 12 via hydraulic fluid, for which purpose a first pressure chamber 15 is provided, which is realized between the piston 13 and the cover 14 . A second pressure chamber 16 is realized on the opposite side, which is realized between the piston 13 and the end wall of the insert 12 . Depending on which pressure chamber 15, 16 the hydraulic fluid is pressed into, the piston is displaced in one direction or the other. In order to also seal these pressure chambers towards the piston side, two sealing elements 32, 33 are provided on the piston, via which a seal is provided on the one hand for the shift rod 17 and on the other hand for the cylinder insert 12.

Also provided is a switching rod 17 which extends through the housing 11 and is guided therein in a sealed manner via corresponding sealing elements 18 , 19 . The shift rod 17 can move axially, for which purpose it is coupled to the piston 13 . For this purpose, two axial stops 20, 21 are provided on the shift rod 17, which are realized via two circlips 24, 25 received in respective grooves 22, 23. Between these axial stops 20, 21, the piston 13 is slightly axially displaceable.

This axial displacement is possible against a spring element 26, which is designed as a corrugated spring or disk spring or as a corresponding spring assembly and is accommodated in an annular recess 27 of the piston. On the one hand, the spring element 26 is supported on the piston 13 or the bottom of the recess 27, see FIG 1 , on the other hand on the axial stop 20 or a support disk 28 supported on the snap ring 24. If a fluid is pressed into the pressure chamber 15, the piston 13 is displaced to the left until the spring element 26 rests on the support disk 28, if this is not the case the case is.

The shift rod 17 is also connected to a driver 29, for example a shift fork, which in turn is connected to the shift sleeve 8 via a corresponding positive engagement. For this purpose, the shift sleeve 8 rotating with the drive element 4 has, for example, a circumferential annular projection 30 which engages in a corresponding receiving groove 31 on the shift fork 29 .

The switching rod 17 is mounted on the housing side via two separate linear guides 34 , 35 . The linear guide 34 is formed by the outer surface of the cylinder insert 12, which has a reduced diameter at one end and shows a cylinder flange 41, which consequently has or forms a guide surface 36, while the switching rod 17 has a second guide surface 37 with its outer surface and the guide surfaces 36, 37 ultimately slide against each other. In the same way, the linear guide 35, which is formed by a bore in the cover 14 through which the switching rod 17 passes, has a guide surface 38, with which in turn the guide surface 37 of the switching rod 17 interacts. Here is what follows in relation to the 2 and 3 is discussed, in each bearing plane that is in the area of a linear guide 34 and 35, one of the guide surfaces involved is provided with a crown, so that two separate bearing planes 39, 40, which are represented by the corresponding vertical lines, are formed in the area of these crowns , which means that there is line contact between the camp partners involved. These integrated crownings now make it possible to absorb or compensate for any bending of the shift rod 17 in the event that the shift sleeve 8 with its internal teeth 9 runs axially against the external teeth 7 of the output element 6 and an axial stop occurs as a result, without it jamming within the respective linear guides 34, 35 and an increase in friction occurs. Any deflection is indicated by the deflection line 45 in 1 shown, which indicates that in the event of a start, i.e. when there is tooth-to-tooth contact, the Shift rod 17 marginally up with respect to 1 would bend.

Here the respective, quasi-cardanic bearings, which are detailed in the enlarged representations according to the 2 and 3 are shown.

2 Figure 12 shows an enlarged partial view of area II 1 , i.e. the area of the first linear guide 34 that is adjacent in relation to the Einspurort. The guide surface 36, which is formed over the insert 12 and ultimately corresponds to the inner lateral surface of the cylinder flange 41 of the cylinder insert 12, is cylindrical, i.e. has no crowning. In contrast, the shift rod 17 is provided with a circumferential convex section 42, which in 2 is somewhat exaggerated over the curved line. This crowning or this crowned section 42 now causes a line contact to the guide surface 36, and it also allows a marginal pivoting around this same crowned contact plane, so that in the event of a rod bending, a marginal pivoting begins without there being a significant increase in contact surface pressure in the bearing area , combined with an increase in friction.

How 2 shows, the crowned area 42 is located directly adjacent to the sealing element 19, ie the sealing ring, which is accommodated in a suitable groove on the shift rod 17. This immediately adjacent arrangement ensures that the sealing element 19 is not significantly stressed in the event of a load-related, marginal tilting, so that on the one hand the sealing function is always guaranteed, but on the other hand the friction on the sealing element 19 does not change.

3 shows an enlarged partial view of area III, ie the area of the second bearing plane 40. The shift rod 17 is again shown, but here it has a cylindrical outer shape, ie it does not have any crowning. In this case, a crowned area 43 is provided on the housing cover 14 on the inner circumference of the cover bore, as shown in FIG 3 in turn is represented by the curved line, but also by the hole contour. This in turn defines a corresponding tilting plane around which the shift rod 17 can tilt without any appreciable increase in friction in this area.

Here, too, the location of the crowning, ie the region 43, is directly adjacent to the sealing element 18, which is accommodated in a suitable groove in the housing cover 14 and seals off the switching rod 17 or its outer surface. Here too, this has the effect that, in the event of a change in geometry on the part of the shift rod 17, there is no appreciable load on the sealing element 18, and the sealing element fully retains its sealing effect. This means that here, as well as at the location level according to 2 , the preload and the gap dimension of the seal does not change or only changes negligibly, so that the function of the seal is guaranteed and there is no significant increase in the gap extrusion.

4 Finally, FIG. 1 shows a partial view of the coupling unit, with an actuator 10 of somewhat different design being used here. The basic structure corresponds to that 1 , which is why reference is made to the relevant statements. The switching rod 17 is here in turn linearly guided via the two linear guides 34, 35 on the housing 11 or the housing cover 14. Again, in the area of the linear guide 34, the switching rod has the convex area 42, which is not shown in detail here, just as the cover 14 also has a slight convexity in the area 43 of the second linear guide 35. The housing cover 14 is, however, lengthened axially compared to the embodiment of the preceding figures, so that the position of the second linear guide 35, viewed axially, is further spaced from the linear guide 34, which leads to a reduction in friction.

Furthermore, the possibility is optionally indicated of also storing the gap rod 17 in a housing cover 44 external to the actuator 10, i.e. to remove the bearing point even further, so that consequently the linear guide 35 does not necessarily have to be realized, but only the sealing has to be carried out there. while the actual linear guide takes place at the end of the shift rod 17 in the housing cover 44.

Reference List

1

coupling unit

2

drive side

3

output side

4

drive element

5

external teeth

6

output element

7

external teeth

8th

shift sleeve

9

internal teeth

10

actuator

11

cylinder body

12

cylinder insert

13

Pistons

14

housing cover

15

pressure chamber

16

pressure chamber

17

shift rod

18

sealing element

19

sealing element

20

axial stop

21

axial stop

22

groove

23

groove

24

locking ring

25

locking ring

26

spring element

27

deepening

28

support washer

29

driver

30

ring protrusion

31

shift fork

32

sealing element

33

sealing element

34

linear guide

35

linear guide

36

guide surface

37

guide surface

38

guide surface

39

storage level

40

storage level

41

cylinder flange

42

Area

43

Area

44

housing cover

45

bending line

Claims (8)

Coupling unit for the reversible coupling of a drive side (2) to an output side (3) of a drive train, comprising a linearly displaceable shift sleeve (8) which sits on a drive element (4) of the drive side (2) and has internal teeth (9) in external teeth (5) of the drive element (4), and from a decoupling position along the external toothing (5) via an output element (6) of the output side (3) with engagement of the internal toothing (9) also in the external toothing (7) of the output element (6) can be pushed into a coupling position, with an actuator (10) being provided for moving the shift sleeve (8), which has a linearly displaceable piston (13) and a shift rod (17) coupled to the piston (13) and which is connected to the shift sleeve (8), wherein the shift rod (17) is linearly guided in at least one linear guide (34, 35) in a cylinder housing (11) through which it passes, the shift rod (17) and the linear guide (34, 35 ) have guide surfaces (36, 37, 38) that slide against one another when the shift rod (17) moves, and wherein at least one guide surface (36, 37, 38) of the linear guide or the shift rod (17) is crowned. coupling unit after claim 1 , characterized in that a first and a second linear guide (34, 35), each formed in the form of an opening, which are spaced apart axially and which are each formed via a guide surface (36, 38), are provided, with the shift rod (17) extends through the openings and is guided with its lateral surface forming the guide surface (37) on the guide surfaces (36, 38) of both linear guides (34, 35). coupling unit after claim 2 , characterized in that only the guide surface (36, 38) of a linear guide (35) or only the guide surface (37) of the shift rod (17) has a spherical shape. coupling unit after claim 3 , characterized in that the shift rod (17) is crowned in the area (42) of its guide surface (37), which is accommodated in the first linear guide (34), while the guide surface (38) of the second linear guide (35) is crowned. coupling unit after claim 4 , characterized in that the crowned area (42) of the shift rod (17) is provided adjacent to a sealing element (19) provided on the shift rod (17) which seals the shift rod (17) to the linear guide (34). coupling unit after claim 4 or 5 , characterized in that the crowned area (43) of the guide surface (38) of the second linear guide (35) is provided adjacent to a sealing element (18) provided on the housing side, which seals the linear guide (35) to the shift rod (17). Coupling unit according to one of the preceding claims, characterized in that the actuator (10) is a hydraulically operated actuator (10). Drive train, in particular of a motor vehicle, comprising coupling unit (1) according to one of the preceding claims.

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