WO2023030676A1

WO2023030676A1 - Transmission having a first planetary gear stage

Info

Publication number: WO2023030676A1
Application number: PCT/EP2022/025337
Authority: WO
Inventors: Zili Wu
Original assignee: Sew-Eurodrive Gmbh & Co. Kg
Priority date: 2021-09-06
Filing date: 2022-07-20
Publication date: 2023-03-09
Also published as: DE102022002656A1

Abstract

Disclosed is a transmission having a first planetary gear stage that includes a first sun gear shaft, an internal toothing and a pinion gear, the pinion gear being provided with a planetary gear into which the cylindrical protrusion, in particular the journal, of a gear wheel in the form of an insertion pinion is inserted, wherein the teeth of the planetary gear mesh with teeth of the first sun gear shaft, the teeth of the gear wheel mesh with teeth of the internal toothing, and the planetary gear is connected to the gear wheel for conjoint rotation therewith by means of a parallel-key connection.

Description

Transmission with a first planetary gear stage

Description:

The invention relates to a transmission with a first planetary gear stage.

It is generally known that a planetary gear is an epicyclic gear and has an epicyclic gear.

From US Pat. No. 1,968,604 A, the closest prior art is a transmission with a

Planetary gear known.

A transmission is also known from CN1 06 274459 A.

From CN 1 03 791 033 A a planetary gear is known.

An elastic liquid turbine is known from US Pat. No. 1,985,964 A.

DE 10 2019 006 068 A1 discloses a transmission with at least one first and one second planetary gear stage.

A wheel drive for a mobile vehicle is known from DE 199 22 651 A1.

A multi-stage planetary gear is known from DD 39 725 A1.

DE 10 2014 213 669 A1 discloses a wind power transmission with a stepped planet.

DE 14 30 245 A discloses an outer end of the axle with planetary gear mechanism.

A gear wheel is known from DE 10 2007 034449 A1. The invention is therefore based on the object of making a transmission more precise to produce, ie in particular a longer service life for the bearings and toothed parts.

According to the invention, the object is achieved in the transmission according to the features specified in claim 1.

Important features of the invention in the transmission with a first planetary gear stage, which has a first sun gear shaft, internal teeth, in particular a first ring gear connected to a housing part or a first ring gear designed in one piece with the housing part, and a planetary gear, are that the planetary gear has a planetary gear into which the cylindrical extension, in particular the pin, of a gear designed as a plug-in pinion is inserted, the teeth of the planetary gear meshing with the teeth of the first sun gear shaft, the teeth of the gear meshing with the teeth of the internal gearing,

- wherein the planet wheel is connected to the gear wheel in a rotationally fixed manner by means of a feather key connection, and/or the extension has a groove, in particular a feather key groove, in which a feather key is accommodated, which also protrudes at least partially into a groove of the gear wheel, in particular for the circumferential direction about the axis of rotation of the planetary gear positive connection of the planetary gear with the gear.

The advantage here is that is made possible by an axially bilateral bearing of the planetary wheel and thus a precise alignment of the planetary wheel can be achieved even during operation. This is because the bearing on both sides, which is arranged axially outside the toothing, prevents the planet wheel from tilting. The axially extended design also contributes to this. Because by connecting a plug-in pinion, the planetary gear is axially longer overall. The stabilization is further improved by the large bearing distance. Over and beyond the different tip circle diameters of the gear wheel and the planet wheel not only allow different transmission ratios, but also contribute to a further improved stabilization of the planetary wheel. This is because the radial supports provided by the respective toothing, in particular the sun toothing and the internal toothing, are far apart axially and thus enable an additional leverage effect, which strengthens the stabilization.

In an advantageous embodiment, the first planet wheel is thermally shrunk onto the extension and/or thermally joined, in particular so that the gear wheel is non-positively connected to the first planet wheel. The advantage here is that increased security can be achieved. Because in addition to the form-fitting connection, a non-positive connection is effected.

In an advantageous embodiment, the planetary wheel is slipped onto a planetary pin, the planetary pin being rotatably mounted axially on both sides via a respective bearing accommodated in a planetary carrier of the transmission, in particular with the bearings being spaced apart from the gearwheel and/or from the planetary wheel in the axial direction. The advantage here is that the stability against tilting of the planetary wheel is improved. This enables greater precision.

In an advantageous embodiment, an input shaft of the transmission is rotatably mounted by means of bearings accommodated in a bearing flange of the transmission, the bearing flange being connected to one or the housing part of the transmission, in particular by means of screws, the first sun gear shaft having teeth, in particular splined teeth, which is inserted into a hollow area of the input shaft, in particular a hollow shaft section, for the non-rotatable connection of the input shaft to the sun gear. The advantage here is that the input shaft is non-rotatably connected to the first sun wheel shaft via a gear coupling. In this way, deviations from the ideal position of the input shaft have an effect on the input side only slightly. The first sun wheel shaft thus drives the first gear stage more precisely than if this gear coupling were not present.

In an advantageous embodiment, the first sun gear shaft is rotatably mounted at its end region facing away from the input shaft by means of a bearing, which is accommodated in a second sun gear shaft, in particular with the inner ring of the bearing being slipped onto the first sun gear shaft and the outer ring of the bearing in the second sun gear shaft is recorded. The advantage here is that the coaxial alignment of the two sun gear shafts makes it possible for a coaxial two-stage transmission to be provided, the first being storable in the second sun gear shaft and thus the most compact possible design can be achieved.

In an advantageous embodiment, the first planet carrier has internal teeth, into which an externally toothed area of the second sun gear shaft is inserted and with which the externally toothed area of the second sun gear shaft is engaged, in particular for the non-rotatable connection of the first planet carrier with the second sun gear shaft, in particular with the first Planet carrier is rotatably mounted on a bearing accommodated in the housing part. The advantage here is that there is another coupling for tolerance compensation. Thus, despite this, tilting introduced into the first gear stage via the input shaft is still further decoupled from the second gear stage.

In an advantageous embodiment, on the end region of the second sun gear shaft facing away from the input shaft in the axial direction, the second sun gear shaft has teeth which mesh with the teeth of a second planet wheel which is rotatably mounted on a second planet pin, in particular by means of needle bearings, wherein the second planet pin is accommodated in a planet carrier, the toothing of the second planet wheel being in engagement with the internal toothing of a second ring gear. The advantage here is that needle bearings in the second gear stage can be used for the planet gear. In addition, the ring gear can be designed to be less extended radially than the planetary carrier is designed to be.

In an advantageous embodiment, the second ring gear is non-rotatably connected to a support ring, in particular by the support ring being at least partially inserted into the ring gear, the support ring having external teeth which mesh with the internal teeth of the ring gear. The advantage here is that the ring gear is connected to the support ring by means of a toothed coupling, in particular for decoupling tilting forces, and the support ring can be slipped onto finely machined alignment surfaces provided on annular elevations formed on the housing part. The support ring can thus be precisely aligned and holds the second ring gear in the desired position.

In an advantageous embodiment, radially directed, annular elevations, in particular elevations, are formed on the housing part, in particular in relation to the axis of rotation of the second sun gear shaft, which have aligning surfaces running around in the circumferential direction, onto which the support ring is pushed, in particular for aligning the support ring together with the second ring gear, in particular wherein the alignment surfaces are spaced from each other in the axial direction. The advantage here is that surfaces which are as finely machined as possible are provided for aligning the support ring and thus the second ring gear, thus enabling high precision during production.

In an advantageous embodiment, the first sun gear shaft is aligned coaxially with the second sun gear shaft. The advantage here is that the transmission can be designed as a coaxial transmission. In addition, the first sun gear shaft can be mounted in the second sun gear shaft, so that the transmission can be made very compact. It is advantageous that the relative speed of the two sun gear shafts is lower than the speed of the first sun gear shaft relative to the housing part. In an advantageous embodiment, a sleeve is connected to the second planet carrier, which sleeve surrounds the second ring gear radially, in particular with a gap region being formed between the second ring gear and the sleeve. The advantage here is that the ring gear is surrounded radially by the rotating part, namely the sleeve and the second planet carrier.

In an advantageous embodiment, a first bearing is fitted with its inner ring onto a cylindrical section of the housing part and its outer ring is accommodated in the sleeve and/or a second bearing, in particular an outer ring of a second bearing, is accommodated in the sleeve, the inner ring of which is placed on the Support ring is attached, in particular wherein the support ring has a step against which the second bearing is employed. The advantage here is that the sleeve is mounted on the two bearings and thus the second planet carrier is mounted on the sleeve. In this way, a large axial distance between the two bearings and the planet carrier can be achieved, so that tilting can be avoided.

The sleeve can be designed as a hollow part, in particular essentially as a hollow cylinder.

In an advantageous embodiment, the support ring is delimited in the axial direction by a shaft nut screwed onto a screw thread applied to the housing part. The advantage here is that a precise and stable alignment of the support ring can be achieved.

In an advantageous embodiment, a shaft sealing ring accommodated by the sleeve seals towards the housing part, i.e. in particular a sealing lip of the shaft sealing ring rests against a finely machined surface of the housing part, in particular a dust seal, in particular a dust seal designed as a V-ring, additionally seals the sleeve towards the housing part. The advantage here is that the shaft sealing ring allows a simple, inexpensive seal.

In an advantageous embodiment, a radial bore running through the sleeve opens into a spatial area adjacent to the first and second bearings, in particular an axial bore introduced into the sleeve crossing the radial bore and opening into a spatial area in which the toothing of the second planet wheel is located. The advantage here is that oil can be supplied through the radial bore. During operation, the radial bore is preferably sealed off from the environment with a sealing plug.

Further advantages result from the dependent claims. The invention is not limited to the combination of features of the claims. For the person skilled in the art, there are further meaningful combinations of claims and/or individual claim features and/or features of the description and/or the figures, in particular from the task and/or the task posed by comparison with the prior art.

The invention will now be explained in more detail using schematic illustrations:

FIG. 1 shows a sectional view of a transmission according to the invention.

FIG. 2 shows an oblique view of a multi-part planetary wheel of the transmission.

As shown in the figures, the transmission has two planetary gear stages.

A bearing flange 17 is connected to the housing part 10 of the transmission, in which bearings are accommodated which support the input shaft 14 in a rotatable manner.

The input shaft 14 has a hollow shaft section in which internal splines are incorporated, which mesh with an external spline of a first sun gear shaft 15 of a first planetary gear stage that is inserted into the hollow shaft section.

The external spline is arranged on a first axial end area of the first sun gear shaft 15 .

This sun gear shaft 15 is rotatably mounted by means of a bearing 18 at its other axial end region, in particular that which faces away from the input shaft 14 .

The bearing 18 is accommodated in a second sun gear shaft 3, the second sun gear shaft 3 belonging to a second planetary gear stage.

With the first sun gear shaft 15 a toothing of an epicyclic gear is engaged, which is composed of a gear 8 and a planetary gear 11 .

The toothing of the planet gear 11 meshes with the toothing of the first sun gear shaft 15 . Gear wheel 8 designed as an insert pinion is inserted into a recess in planet wheel 11 and connected to planet wheel 11 in a form-fitting manner by means of a feather key 9 . For this purpose, the hollow planetary wheel 11 is slipped onto a cylindrical extension of the gearwheel 8 , a keyway being incorporated in the cylindrical extension, into which the keyway 9 is inserted, which also protrudes into an axial groove of the planetary wheel 11 .

An internally toothed ring gear is connected to the housing part 10 or constructed in one piece, in particular in one piece.

The toothing of the gear wheel 8 meshes with the internal toothing of the ring gear, the toothing of the planet wheel 11 meshes with the toothing of the first sun wheel shaft 15 .

The toothing of gear wheel 8, which is preferably designed as an involute toothing, has a smaller outside diameter, in particular the addendum circle diameter, than the toothing of planet wheel 11, which is preferably designed as involute toothing.

The inner diameter of the ring gear is smaller than the addendum circle diameter of the toothing of the planetary gear 11. The inner toothing of the ring gear is thus arranged at a radial distance from the toothing of the planetary gear 11, in particular at a smaller radial distance from the axis of rotation of the first sun gear shaft 15.

The gear wheel 8 is hollow and slipped onto a planet pin 13, which is mounted axially on both sides in the first planet carrier 6 via bearings (7, 12), in particular roller bearings. The bearings 7 and 12 are arranged axially outside the teeth of the gear wheel 8 and the planet wheel 11 .

The first planetary carrier 6 is mounted on the one hand via a bearing 16 accommodated in the bearing flange 17 and on the other hand via a bearing 19 which is accommodated in the housing part 10 .

The second sun gear shaft 3 has, on its axial end region associated with the first sun gear shaft 15, external teeth, in particular splines, with which the second sun gear shaft 3 is inserted into an internally toothed axial end area of the first planet carrier 6 .

The second sun gear shaft 3 has no direct bearing.

At its first end, the second sun gear shaft 3 is inserted into the first planetary carrier 6 and is thus mounted indirectly via the bearing 19 of the first planetary carrier 6 .

At its second axial end region, the second sun gear shaft 3 has a toothing that acts as a sun gearing, which meshes with, in particular three, second planetary gears 24, each of the second planetary gears 24 being rotatably mounted on a respective planetary pin 23 via bearings, in particular needle bearings .

The planet bolts 23 are accommodated in a double-sided planetary carrier 25 .

The teeth of the planet gears 24 are also in engagement with a second ring gear 1. For this purpose, the second ring gear 1 has internal teeth which are in mesh with the teeth of the planet gears 24. In addition, the internal toothing of the second ring gear 1 is axially extended, i.e. protrudes axially beyond the planetary gears 24, so that an externally toothed area of a support ring 2 can be inserted into the second ring gear 1 and this externally toothed area thus meshes with the internal toothing of the second ring gear 1 is bringable. In this way, the second ring gear 1 can be positively connected to the support ring 2 in the circumferential direction, i.e. in particular can be connected in a torque-proof manner. To align the support ring 2 with the ring gear 1, the support ring 2 is slipped onto ring-shaped elevations, which have finely machined alignment surfaces 21 on their radial outside and 22. These ring-shaped elevations are formed on a cylindrical area of the housing part 10 which in the axial direction covers an area which is encompassed by the area covered by the second sun gear shaft 3 in the axial direction.

In particular, the support ring 2 is arranged on the side of the second planet gears 24 facing the first sun gear shaft 15 . An inner ring of a bearing 20 is slipped onto the support ring 2, the outer ring of which is accommodated in a sleeve 27, in particular a bearing bush, which is non-rotatably connected to the planetary carrier 25, in particular by means of screws.

The sleeve 27 also accommodates the outer ring of a second bearing 20, the inner ring of which is slipped onto a cylindrically shaped area, in particular a bearing receiving area, of the housing part d10.

The sleeve 27 is arranged axially between the second planet gear 24 and the first sun gear shaft 15 .

In this way, the second planet carrier 25 is rotatably mounted via the sleeve 27 in that the sleeve 27 is mounted on the housing part 10 on the one hand via a bearing 20 and on the other hand via another bearing 20 together with the support ring 2 on the housing part 10 .

The area covered by the sleeve 27 in the axial direction overlaps with the area covered by the second planet gears 24 in the axial direction and is encompassed by the area covered by the second sun gear shaft 3 in the axial direction.

A seal accommodated in the sleeve 27 comprises a shaft sealing ring 4 whose sealing lip 4 runs on a finely machined surface of the housing part 10 and thus seals the sleeve 27 towards the housing part 10 . The sealing lip thus touches the housing part 10. The sleeve 27 has a seat for the shaft sealing ring 4.

The finely machined surface of the housing part 10 is arranged radially inside the sealing ring 3 and/or the sleeve 27 .

A dust seal 5 , preferably designed as a V-ring, seals the housing part 10 from the sleeve 27 .

The sleeve 27 has a radially continuous bore which is closed with a sealing plug 28 . When the plug is removed and the gear unit is out of service, oil can be refilled, in particular through the sleeve 27 through. However, during operation of the transmission, the sleeve 27 is a rotating part and the oil refilling is therefore not executable.

The bore that runs radially through the sleeve 27, in particular a radial bore, opens out between the two bearings 20, so that their rolling bodies can be supplied with lubricant.

An axially directed bore, into which the radial bore opens or which crosses the radial bore, opens into a gap region, in particular an annular gap, arranged radially between sleeve 27 and the second ring gear.

Further recesses running through the support ring 2 enable the lubrication of the needle bearings of the second planet 24 and the teeth of the second planet 24.

The sleeve 27 acts as an axial extension of the second planet carrier 25 and surrounds the second ring gear 1 radially.

The gear wheel 8 is positively connected to the planet wheel 11 by means of the feather key 9, but the gear wheel 8 designed as a plug-in pinion is also inserted with its cylindrical extension into the planet wheel 11, this planet wheel being thermally shrunk on. During manufacture, the gear wheel 8 is heated before it is inserted, so that there is a temperature difference of more than 40° C. between the gear wheel 8 and the planet wheel 11 .

In this way, the connection between the gear wheel 8 and the planet wheel 11 is not only designed in a form-fitting manner, but also in a force-fitting manner.

In further exemplary embodiments according to the invention, the sleeve 27 is designed in one piece with the second planetary carrier 25, in particular in one piece. Reference List

1 ring gear

2 support ring

3 second sun gear shaft

4 shaft seal

5 dust seal, especially V-ring

6 first planet carrier

7 camps

8 gear

9 key

10 housing part

11 planet wheel

12 bearings

13 first planet bolt

14 input shaft

15 first sun gear shaft

16 camps

17 bearing flange

18 camps

19 camps

20 camps

21 alignment surface

22 alignment surface

23 planet bolts

24 planets

25 planet carriers

26 shaft nut

27 sleeve, especially bearing bush

28 sealing plugs

Claims

Patent Claims:

1. Transmission with a first planetary gear stage, which has a first sun gear shaft, internal teeth, in particular a first ring gear connected to a housing part or a first ring gear designed in one piece with the housing part, and a planetary gear, characterized in that the planetary gear has a planetary gear into which the cylindrical extension, in particular the pin, of a gear designed as a plug-in pinion is inserted, with the toothing of the planet gear meshing with a toothing of the first sun gear shaft, with the toothing of the gear meshing with a toothing of the internal gearing,

2. Transmission according to claim 1, characterized in that the first planet wheel is thermally shrunk onto the extension and/or is thermally joined, in particular so that the gear wheel is non-positively connected to the first planet wheel.

3. Transmission according to one of the preceding claims, characterized in that the planetary wheel is slipped onto a planetary pin, the planetary pin being rotatably mounted axially on both sides via a respective bearing accommodated in a planetary carrier of the transmission, in particular the bearings being spaced apart in the axial direction from the gear wheel and/or from the planet wheel.

4. Transmission according to one of the preceding claims, characterized in that an input shaft of the transmission is rotatably mounted by means of bearings accommodated in a bearing flange of the transmission, the bearing flange being connected to one or the housing part of the transmission, in particular by means of screws, the first Sun wheel shaft has teeth, in particular splines, which is inserted into a hollow area of the input shaft, in particular hollow shaft section, for the non-rotatable connection of the input shaft to the sun wheel. 16

5. Transmission according to one of the preceding claims, characterized in that the first sun gear shaft is rotatably mounted at its end region facing away from the input shaft by means of a bearing which is accommodated in a second sun gear shaft, in particular the inner ring of the bearing being slipped onto the first sun gear shaft and the outer ring of the bearing is housed in the second sun gear shaft.

6. Transmission according to one of the preceding claims, characterized in that the first planetary carrier has internal teeth, into which an externally toothed area of the second sun gear shaft is inserted and with which the externally toothed area of the second sun gear shaft is engaged, in particular for the non-rotatable connection of the first planetary carrier with the second sun gear shaft, in particular wherein the first planet carrier is rotatably mounted via a bearing accommodated in the housing part.

7. Transmission according to one of the preceding claims, characterized in that on the end region of the second sun wheel shaft facing away from the input shaft in the axial direction, the second sun wheel shaft has teeth which mesh with the teeth of a second planet wheel which is mounted on a second planet bolt is rotatably mounted in particular by means of needle bearings, the second planet pin being accommodated in a planet carrier, the toothing of the second planet wheel being in engagement with the internal toothing of a second ring gear. 17

8. Transmission according to one of the preceding claims, characterized in that the second ring gear is non-rotatably connected to a support ring, in particular in that the support ring is at least partially inserted into the ring gear, the support ring having external teeth which mesh with the internal teeth of the ring gear is.

9. Transmission according to one of the preceding claims, characterized in that radially directed, annular elevations, in particular elevations, are formed on the housing part, in particular in relation to the axis of rotation of the second sun gear shaft, which have aligning surfaces running around in the circumferential direction, onto which the support ring is pushed , in particular for aligning the support ring together with the second ring gear, in particular wherein the alignment surfaces are spaced from each other in the axial direction.

10. Transmission according to one of the preceding claims, characterized in that the first sun gear shaft is aligned coaxially with the second sun gear shaft.

11. Transmission according to one of the preceding claims, characterized in that a sleeve is connected to the second planet carrier, which surrounds the second ring gear radially, in particular wherein a gap region is formed between the second ring gear and the sleeve.

12. Transmission according to one of the preceding claims, characterized in that a first bearing is fitted with its inner ring onto a cylindrical section of the housing part and its outer ring is accommodated in the sleeve and/or that a second bearing, in particular an outer ring of a second bearing, is accommodated in the sleeve, the inner ring of which is slipped onto the support ring, in particular the support ring having a step against which the second bearing is placed.

13. Transmission according to one of the preceding claims, characterized in that the support ring is delimited in the axial direction by a shaft nut screwed onto a screw thread applied to the housing part.

14. Transmission according to one of the preceding claims, characterized in that a shaft seal held by the sleeve seals towards the housing part, in particular a sealing lip of the shaft seal rests on a finely machined surface of the housing part, in particular with a dust seal, in particular as a V-ring executed dust seal, which also seals the sleeve towards the housing part. 19

15. Transmission according to one of the preceding claims, characterized in that a radial bore passing through the sleeve opens into a spatial area adjoining the first and second bearings, in particular wherein an axial bore introduced into the sleeve crosses the radial bore and opens into a spatial area in which the toothing of the second planet gear is located.