The invention relates to a planetary gear carrier for a planetary gearset pursuant to the preamble of patent claim 1.
Planetary gearsets comprising a sun wheel, internal gear, planetary gears and a rotating planetary gear carrier are known, in general. Typically, the planetary gear carrier comprises a hub and a web plate in which planetary gear pins are axially inserted on a defined reference diameter. The planetary gears are typically seated on the planetary gear pin by way of floating bearings or needle bearings with the necessary lubricating oil quantity for lubrication of this planetary gear bearing being fed from the side of the web plate facing away from the planetary gears into an axial blind hole of the planetary gear pin and being fed from there via radial bores of the planetary gear pins of the planetary gear bearing opening into the axial bores. Typically, the lubricating oil is fed from an inside diameter of the (rotating) planetary gear carrier or web plate in such a way that the lubricating agent flows radially outward along the web plate due to the centrifugal force on the web plate. To accumulate lubricating agent in the area of the axial lubricating oil feed into the planetary gear pins, it has been suggested in DE 197 36 686 A1 to attach a diaphragm plate axially to the web plate, which extends in the radial direction across the area of the axial lubricating agent feed into the planetary gear pins and together with the diaphragm plate forms a lubricating oil chamber. The lubricating agent arriving from the inside is thus accumulated in the lubricating oil chamber and is guided from there in the axial bores of the planetary gear pins.
From DE 197 18 030 A1, for example, a planetary gear carrier with a disk-shaped oil control plate is known, in which the oil control plate is a formed plastic part with a star-shaped outer contour and angled, axially extending tabs. To form a lubricating oil chamber, the oil control plate in the mounted state covers the areas of the axial lubricating oil feed in the individual planetary gear pins in an axially spaced manner, wherein the outer contour of the oil control plate rests axially against the planetary gear carrier. The angled tabs of the oil control plate comprise retaining clips and engage in the mounted state axially in the planetary gear carrier on a diameter smaller than the planetary gear bolt reference diameter, while the retaining clips latch to the inside circumference of a basket-shaped section of the planetary gear carrier.
It is the object of the invention to further develop a planetary gear carrier comprising an oil baffle axially abutting a web plate of the planetary gear carrier with respect to its functionality and installation in the gearbox. According to the invention the object is achieved by a planetary gear carrier having the features of patent claim 1. Beneficial embodiments and further developments of the invention result from the dependent claims.
Proceeding from the aforementioned state of the art, the planetary gear carrier for a planetary gearset, according to the invention, comprises a web for accommodating planetary gear pins, on which planetary gears of the planetary gearset are seated. On the side of the web facing away from the planetary gears, an oil baffle axially abuts an end face of the web and is attached to the web, preferably to the end face of the web. The oil baffle covers the planetary gear pins in an axially spaced manner and, together with the web, forms a lubricating oil chamber that is open towards the inside diameter for guiding a lubricating oil flow to a planetary gear bearing on the outside diameter of the respective planetary gear pins. Lubricating oil that is fed to the lubricating oil chamber from an inside diameter is conducted from the lubricating oil chamber in axial lubricating holes of the planetary gear pins and from there via radial lubricating oil bores of the planetary gear pins to the planetary gear bearing, with these axial lubricating holes of the planetary gear pins opening into the lubricating oil chamber. The web comprises a catch profile for positively connecting the planetary gear carrier to a gearbox element, which axially abuts the planetary gear carrier on the side of the web facing away from the planetary gears. According to the invention, it is provided that the oil baffle comprises a device for axially securing the gearbox element abutting the planetary gear carrier on the catch profile of the web in the assembled state.
This additional functionality of the oil baffle enables very compact, length-saving nesting of the planetary gear carrier, oil baffle and the gearbox element abutting the planetary gear carrier and assembly of the components is very simple and inexpensive. Such a gearbox element abutting the planetary gear carrier can be, for example, a disk carrier or another planetary gear carrier or an internal gear of an abutting planetary gearset.
In a preferred embodiment after its assembly the oil baffle is non-detachably connected to the web and at least largely oil-tight to the web, for example, by way of rolling on a diameter greater than a reference diameter of the planetary gear pins or by way of riveting on the end face of the web facing the lubricating oil chamber. The oil baffle preferably comprises angled tabs on a diameter smaller than the reference diameter of the planetary gear pins, said tabs extending roughly parallel to the planet pin axis axially in the opposite direction of the planetary gear pins and, during assembly of the gearbox element abutting the planetary gear carrier to the catch profile of the web that has been completed with the oil baffle, has been added, axially engaging in corresponding recesses of the gearbox element.
In this case the device with which the gearbox element abutting the planetary gear carrier is axially secured on the catch teeth of the web in the mounted state can be designed as a crimped closure. In this case, after sliding a catch profile of the gearbox element abutting the planetary gear carrier on the catch profile of the web plate, the tabs of the oil baffle extend through the corresponding recesses of the gearbox element and are then bent on the side of the recesses facing away from the web.
In another embodiment, the device with which the gearbox element abutting the planetary gear carrier is axially secured on the catch teeth of the web in the mounted state can be designed as a bayonet lock or snap-fit closure. In this case, the tabs of the oil baffle are elastic and spring-loaded and snap into or onto the corresponding recesses of the gearbox element in the circumferential direction and/or radial direction during assembly of the gearbox element abutting the planetary gear carrier on the catch profile of the web.
In another embodiment, it is suggested designing the device with which the gearbox element abutting the planetary gear carrier is axially secured on the catch teeth of the web in the mounted state as a rivet or weld closure with the tabs of the oil baffle being riveted or welded to or in the recesses of the gearbox element after sliding a catch profile of the gearbox element abutting the planetary gear carrier on the catch profile of the web.
In yet another embodiment, the device with which the gearbox element abutting the planetary gear carrier is axially secured on the catch teeth of the web in the mounted state can also be designed as a screw connection. In this case, after positively joining the catch profiles of the gearbox element abutting the planetary gear carrier and of the web plate, the tabs of the oil baffle extend through the corresponding recesses of the gearbox element and are then screwed to the gearbox element on the side of the recesses facing away from the web.
For the purpose of improving the lubricating oil supply to the planetary gear pine arranged on a smaller radius, it is suggested to provide a seal axially between the oil baffle and the end face of the web facing the lubricating oil chamber to further develop a planetary gear carrier with planetary gear pins that are arranged on different reference diameters. The axial seal-contact image of this seal creates a closed contour, which engages around the area of the axial lubricating oil feed of the individual planetary gear pins radially on the outside, and extends in the sections located in the circumferential direction between the individual planetary gear pins on a diameter smaller than or equal to the reference diameter of the radially inner planetary gear pins. This way the lubricating oil, which is fed radially from the inside to the outside in the lubricating oil chamber, is distributed at least substantially evenly among the inner and outer planetary gear pins and prevents insufficient lubrication of the radially inner planetary gear bearing.
The following describes the invention with reference to the figures in more detail, with equivalent components being designated by the same reference numerals, wherein:
FIGS. 2 is an assembly sketch of an exemplary axially securing device with bayonet lock;
Axially adjacent to the planetary gearset 1, on the side of the web 10 facing away from the planetary gear 8, a gearbox element abutting the planetary gearset 1 is arranged here, by way of example, a control element 23. A disk carrier 24 which, by way of example, is designed as an inside disk carrier, axially abuts the web 10 and is positively connected to the web 10, via a catch profile 25 which, in the mounted state, engages in a corresponding catch profile 11 of the web 10, which is arranged on the side of the web 10 facing away from the planetary gears. During assembly of the disk carrier 24 to the (completed) planetary gear carrier 5, the catch profile 25 of the disk carrier 24 is slid on the catch profile 11 of the web 10 in the axial direction.
To lubricate the planetary gear bearing, the outer planetary pin 9 and the not illustrated, inner planetary pins of the planetary gearset 1 comprise axial lubricating holes 21 and radial lubricating holes 22 opening into said axial lubricating holes 21 in the familiar fashion. The axial lubricating holes 21 are designed as blind holes open towards the end face of the web 10. The amount of lubricating oil required for lubrication of the planetary gear bearing is thus fed from the side of the web 10 facing away from the planetary gears into the axial lubricating holes of the planetary bolt.
In the illustrated embodiment, due to the centrifugal force, lubricating oil fed from an inside diameter of the planetary gearset 1 flows radially outward initially through a lubricating hole 20 of the rotating web 10 and subsequently along the end face of the web 10 to its side facing away from the planetary gears. Abutting the end face of the web 10 on the web's side facing away from the planetary gears. a disk-shaped oil baffle 14, together with the web 10, forms a lubricating oil chamber 19 that is open towards the inside diameter, and is provided for improving the lubricating oil supply to the axial lubricating holes 21 of the planetary gear pins. The oil baffle 14 covers the planetary gear pins in an axially spaced manner and rests against the web 10 in one section, which has a larger diameter than the reference diameter of the planetary gear pin 9. Attachment of the oil baffle 14 to the web 10 is beneficially designed simply as a roll in the illustrated embodiment, with a roll section 15 of the oil baffle 14 overlapping the outside diameter of the web 10 axially in the direction of the planetary gear 9 and being rolled in the mounted state on an undercut 12 of the web 10. The roll is expediently designed at least largely in an oil-tight manner. Of course, a radial groove can be provided instead of the undercut 12. Both the undercut 12, as well as a correspondingly designed radial groove at the circumference of the web 10, ensure secure fastening (at least) in the axial direction of the oil baffle 14 to the planetary gear carrier 5 or the web 10. Of course, the oil baffle 14 can also be suitably attached axially to the end face of the web 10 facing the lubricating oil chamber 19. The only essential aspect in this context is that the axial connection between oil baffle and web can transmit forces, which are applied on the oil baffle from the outside, to the planetary gear carrier to a certain degree and that a lubricating oil chamber, which is open towards the inside diameter, is formed in which the lubricating oil flowing from the inside out, along the end face of the web, can get and accumulate there. The lubricating oil accumulated in the lubricating oil chamber 19 is conducted in the familiar fashion in the axial lubricating holes 21 of the planetary gear pins. The corresponding lubricating oil flow has been designated by a reference numeral 18 in
According to the invention, the oil baffle 14 is assigned another function, namely, to axially secure the disk carrier 24 on the planetary gear carrier 5 in the mounted state on the catch profile 11 of the web 10. For this purpose, in the area of its inside diameter, the oil baffle 14 comprises at least one angled tab 16 on a diameter that is smaller than the reference diameter of the planetary gear pins, which extends substantially parallel to the planetary bolt axis axially in the direction opposite the web 10. It is useful to arrange several angled tabs 16 across the circumference of the oil baffle 14. The disk carrier 24 comprises recesses 26 assigned to the respective tabs 16, and the tabs 16 engage in said recesses when sliding the disk carrier catch profile 25 on the web plate catch profile 11.
In the embodiment illustrated in
To implement a bayonet-like lock between the oil baffle 14 and disk carrier 24, the angled tabs 16 of the oil baffle 14 are designed elastic and spring-loaded, according to the invention, each with a spring-elastic section 30 that is double-bent at a right angle. According to the invention, the recesses 26 of the disk carrier 24 comprise a joining section 27 and a snap-fit section 28, respectively, where the snap-fit section 28 follows the joining section 27 in the same direction viewed in the circumferential direction. The joining section 27 has a larger radial extension than the snap-fit section 28. The spring-elastic sections 30 of the tabs 16 comprise a crimp 17, respectively, the radial extension of which, on one hand, is smaller than the radial extension of the joining section 27 of the disk carrier recesses 26 but, on the other hand, is larger than the radial extension of the snap-fit section 28 of the disk carrier recesses 26.
In
To prevent unintentional detaching of the axially securing device, the disk carrier 24 usefully comprises one or more latches 29, which are distributed across the circumference, on its side facing the crimp 17, said latches being arranged between the joining section 27 and locking section 28 of the disk carrier recesses 26, respectively, viewed in the circumferential direction. When rotating the disk carrier 24 and planetary gear carrier or oil baffle 14 out of the joined state “I” into the snap-fit state “II”, the crimp 17 of the oil baffle tabs 16 slide across these latches 29, while the spring-elastic tab sections 30 briefly deforms. The special shape of the latches 29 prevents the latches 29 from rotating out of the snap-fit state “II” back into the joined state “I”. From a production point of view, such latches can be manufactured easily as impressions in the disk carrier, for example.
It is clear that the roll (by way of example for the non-detachable connection) between the oil baffle 14 and planetary carrier web can only occur after the bayonet-like axially securing device has been snap-fit.
In a different embodiment of the device for axially securing the gearbox element abutting the planetary gear carrier, illustrated in
As in the exemplary embodiment explained in
Of course, the use of such support from the assembly forces is not limited to the exemplary crimp closure, illustrated in
In the practice, planetary gearsets comprising several planetary gear pins that are arranged on different reference diameters are known, for example, a Ravigneaux-type planetary gearset or a plus planetary gearset with double planets. Due to the effects of centrifugal force, the planetary gears, which are arranged on a larger radius, are known to receive more lubricating oil. This creates the risk of insufficient lubrication on the planetary gear bearings arranged on the smaller radius.
In order to achieve a substantially even distribution of the lubricating oil, which is fed radially from the inside out in the lubricating oil chamber 19 formed by the web 10 and oil baffle 14 (lubricating oil flow 18), on all planetary gear pins 7, 9, a special seal 34 with a closed contour is arranged according to
In the example illustrated in
Finally,
1 planetary gearset
2 first sun wheel
3 second sun wheel
4 internal gear
5 planetary gear carrier
6 radially inner planetary gear
7 radially inner planetary gear pin
8 radially outer planetary gear
9 radially outer planetary gear pin
10 web of the planetary gear carrier
11 catch profile of the web
12 undercut of the web
13 hub of the planetary gear carrier
14 oil baffle
15 roll section of the oil baffle
16 tab of the oil baffle
17 crimp of the tab
18 lubricating oil flow
19 lubricating oil chamber
20 lubricating hole of the web
21 axial lubricating hole of the planetary gear pin
22 radial lubricating hole of the planetary gear pin
23 control element
24 gearbox element abutting the planetary gear carrier; disk carrier
25 catch profile of the disk carrier
26 recess
27 joining section of the recess
28 snap-fit section of the recess
29 latch of the disk carrier
30 spring-elastic section of the baffle
31 support element of the web
32 reference diameter of the inner planetary gear pin
33 reference diameter of the outer planetary gear pin
34 seal of the oil baffle
35 seal-contact image of the seal
36 section of the seal-contact image
37 entrance surface of the lubricating oil in the axial lubricating hole of the radially inner planetary gear pin
38 entrance surface of the lubricating oil in the axial lubricating hole of the radially outer planetary gear pin
39 lug of the web; chamfer or bevel
I joined state of the axially securing device
II snap-fit state of the axially securing device
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP04/01406 | 2/14/2004 | WO | 8/15/2005 |