DE102014215284A1 - planet carrier - Google Patents

Abstract

The invention relates to a planetary carrier (1, 11) in which planet wheels (2, 12) are rotatably mounted, wherein the planet carrier (1, 11) from at least two support elements (4, 5, 14, 15) is formed, and wherein each the planetary gears (2, 12) are arranged axially between the carrier elements (4, 5, 14, 15) and are carried by at least one of the carrier elements (4, 5, 14, 15) on the planet carrier (1, 11), each of Carrier elements (4, 5, 14, 15) with the other carrier element (4, 5, 14, 15) is connected.

Description

Field of the invention

The invention relates to a planetary carrier, are rotatably mounted in the planetary gears, wherein the planet carrier is formed from at least two carrier elements, and wherein each of the planetary gears axially disposed between the carrier elements and supported on at least one of the carrier elements on the planet carrier, wherein each of the carrier elements a side plate and the webs is formed and connected to the other carrier element.

Background of the invention

Such a planet carrier is in DE 6931359 U described. Two identically designed carrier elements of the planet carrier are fastened to an intermediate plate and connected to one another via this intermediate plate. In the respective support member, a set of planet gears is added. These planetary carriers are particularly cost-effective if their carrier elements are identical parts.

Description of the invention

The object of the invention is to make such a planet carrier in terms of its structure stiffer and therefore resistant to high loads.

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

The radially outwardly directed outer skin of each of the carrier elements extends in the lateral surface of an imaginary truncated cone and terminates in an axial direction at its base and in the other direction in a top surface of the truncated cone. The support elements are made in this form, for example by deep drawing or by bending and punching steel sheet. Subsequently, the support elements with the webs are guided towards each other so that the large base surfaces of the respective truncated cone lie together in a plane and the webs are joined directly to each other in this. In this case, the webs are preferably aligned with each other so that in each case a web of a support member is axially aligned with a web of the other support member.

Alternatively, the webs are attached to an intermediate plate of the planet carrier. The webs of a support member are on one side of the intermediate plate and the webs of the other support plate on the other side of the intermediate plate. The webs of both support plates are aligned with each other on the intermediate plate, that the respective base of the truncated cone rests on the base plate and each one web of a support member axially aligned with a web of the other support member. Alternatively, the webs of one carrier element are offset from the other in the circumferential direction. The shape of the webs is dependent on the number of planetary gears used in the planet carrier and the dimensions of the gap, which claimed each planet gear between two webs for themselves. Gaps are provided for the planetary gears which protrude radially beyond the planetary carrier, e.g. to be meshed with a ring gear of a transmission.

In an extreme case, each of the support elements has only one web whose outer skin is represented by the entire lateral surface of the truncated cone, that is, in this case formed by the shell of the truncated cone. Each of the webs is curved in the circumferential direction about the central axis of the planet carrier so that the shape of the outer skin, so the radially outwardly facing surface of the respective web corresponds to a portion of the lateral surface of the respective truncated cone. Joined, the support elements are preferably cohesively directly to each other or to an intermediate plate. An intermediate plate of the planet carrier separates two or more planet gears or two or more sets of planetary gears axially from each other, so that at least one planetary gear is arranged in the planet carrier to the left and right of the intermediate plate. Alternatively, an intermediate plate is also located in a planet carrier, in which the planet gears or planetary gear sets are arranged in the same toothing plane. The intermediate plate may be required, for example, when the planet gears of two adjacent planetary gear sets must be supported on the left and right in the planet carrier. In addition, the intermediate plate can also be the basis for the attachment of further transmission elements to the planet carrier, such as for sprockets.

The longitudinal structure as a double trapezoid or octagonal appearing basic structure of the planet carrier is advantageous very stiff. The elements of the planet carrier are very simple and inexpensive to manufacture, especially if the carrier elements are designed as identical parts.

Description of the drawings

The invention will be explained in more detail with reference to embodiments.

1 shows a planet carrier 1 in which a set of planet gears 2 is rotatably mounted, in a longitudinal section along its main axis 3 , The planet carrier 1 is made of two carrier elements 4 and 5 formed, both of which have the same design. The planet wheels 2 are axially between the support elements 4 and 5 arranged and partially encapsulated by these. The planet wheels 2 sit rotatable on planet pins 6 on the left in the carrier element 4 and right in the carrier element 5 are included so that the planetary gears 2 over the planet pins 6 in the planet carrier 1 are worn. Each of the carrier elements 4 and 5 is from a side plate 8th and three bridges 9 respectively. 39 educated. The carrier elements 4 and 5 are over the jetties 9 and 39 connected to each other., There is always a footbridge 9 the carrier element 4 with a jetty 39 the carrier element 5 connected so that these in the radial plane 10 axially abut each other and cohesively by at least one weld 40 connected to each other. The radial plane 10 is perpendicular to the main axis 3 punctured. The main axis 3 is on rotation of the planet carrier 1 its axis of rotation. Between two interconnected webs 9 respectively. 39 are gaps in the circumferential direction 20 formed, from which in each case one of the planet wheels 2 radially over the contour of the planet carrier 1 protrudes radially.

The radially outwardly directed outer skin 24 ie the surface, of each support element 4 respectively. 5 is at the jetties 9 and 39 each described by sections of a lateral surface of an imaginary truncated cone.

A truncated cone is generally defined by a circular base 25 with the radius R1, a circular top surface 26 with the radius R2 and a conically extending lateral surface 27 described. R1 is greater than R2 and is also the largest radius of the outer contour of the planet carrier 1 , The lateral surface 27 of the truncated cone is by generatrices 28 described their extension lines 28 ' at the intersection 29 on main axis 3 cut and each with the main axis 3 include an angle α. Usually, these lines run 28 . 28 ' radiating, but are due to their beyond the representation of actual length in 1 symbolically interrupted and shown shortened.

The respective axial end of the Planetenträges 1 in axial directions facing end face 31 of the respective carrier element 4 respectively. 5 runs in the top surface of the respective truncated cone. The bases 25 Both truncated cones are equal in size and described by the radius R1, wherein the truncated cones in the radial plane 10 lie against each other, so that these through a common base 25 can be described. The top surfaces 26 are equal to each other and therefore both described by a radius R2.

2 shows a planet carrier 11 in which a set of planet gears 12 is rotatably mounted, in a longitudinal section along its main axis 13 , The planet carrier 11 is made of two carrier elements 14 and 15 and an intermediate plate 21 educated. Both support elements 14 and 15 have the same cup-shaped design and are of a disc-shaped side plate 17 and a jetty 18 respectively. 19 formed .. The planet wheels 12 are of the carrier elements 14 and 15 encapsulated and rotatable on planet pins 16 , each left in the support element 14 and right in the carrier element 15 are included. The carrier elements 14 and 15 are over the intermediate plate 21 interconnected, wherein the carrier element 14 with the jetty 18 in the radial plane 22 axially on the intermediate plate 21 and the carrier element 15 with the jetty 19 in the radial plane 23 axially on the intermediate plate 21 is applied. The radial planes 22 and 23 are perpendicular to the main axis 13 of the planet carrier 11 pierced, with the main axis 13 in the case of a rotating planet carrier 11 whose axis of rotation is.

The radially outwardly directed outer skin 38 ie the surface, of each support element 14 respectively. 15 corresponds to the jetties 18 and 19 Sections of a lateral surface of an imaginary truncated cone.

A truncated cone is generally defined by a circular base 33 with the radius R1, a circular top surface 34 with the radius R2 and a conically extending lateral surface 35 described. R1 is greater than R2. The lateral surface 35 of the truncated cone is by generatrices 36 described their extension lines 36 ' at the intersection 37 on main axis 13 cut and each with the main axis 13 include an angle α. Usually, these lines run 36 . 36 ' radiating, but are due to their beyond the picture in length 2 symbolically interrupted and shown shortened.

The respective axial end of the planet carrier 11 in axial directions facing end face 37 of the respective carrier element 14 respectively. 15 runs in the top surface 34 of the respective truncated cone. The bases 33 Both truncated cones are the same size and described by the radius R1 and are each in a radial planes 22 respectively. 23 and face each other with axial distance, the thickness of the intermediate plate 21 equivalent. The top surfaces 34 are equal to each other and both are described by a radius R2. LIST OF REFERENCE NUMBERS 1 planet carrier 21 intermediate plate 2 planet 22 radial plane 3 main axis 23 radial plane 4 support element 24 shell 5 support element 25 Floor space 6 planet shaft 26 cover surface 7 side plate 27 lateral surface 8th web 28 generating line 9 web 28 ' Renewals 10 radial plane 29 intersection 11 planet carrier 12 planet 31 front 13 main axis 14 support element 33 Floor space 15 support element 34 cover surface 16 planet shaft 35 lateral surface 17 side plate 36 generating line 18 web 36 ' renewal 19 web 37 front 20 gap 38 shell 39 web 40 Weld

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• DE 6931359 U [0002]

Claims (5)

Planet carrier ( 1 . 11 ) in which planetary gears ( 2 . 12 ) are rotatably mounted, wherein the planet carrier ( 1 . 11 ) of at least two carrier elements ( 4 . 5 . 14 . 15 ) is formed, and wherein each of the planetary gears ( 2 . 12 ) axially between the carrier elements ( 4 . 5 . 14 . 15 ) and via at least one of the support elements ( 4 . 5 . 14 . 15 ) on the planet carrier ( 1 . 11 ) is supported, wherein each of the support elements ( 4 . 5 . 14 . 15 ) with the other carrier element ( 4 . 5 . 14 . 15 ), characterized in that the carrier elements ( 4 . 5 . 14 . 15 ) each from a side plate ( 7 . 17 ) and at least one bridge ( 8th . 9 . 18 . 19 ) is formed and the radially outwardly directed outer skin ( 24 . 38 ) of each support element ( 4 . 5 . 14 . 15 ) each through at least a portion of a lateral surface ( 27 . 35 ) is described in each case an imaginary truncated cone, wherein the truncated cone a base area ( 25 . 33 ), a top surface ( 26 . 34 ) and the lateral surface ( 27 . 35 ), and wherein in each case axially end of the Planetenträges ( 1 . 11 ) the axially facing end face ( 31 . 37 ) of the respective carrier element ( 4 . 5 . 14 . 15 ) in the top surface ( 26 . 34 ) of the respective truncated cone, wherein the outer skin ( 24 . 38 ) of the webs ( 4 . 5 . 14 . 15 ) in each case in at least one section of the lateral surface ( 27 . 35 ) of the respective truncated cone and through the respective section of the lateral surface ( 27 . 35 ) is limited radially outward. Planet carrier according to claim 1, characterized in that the radii of the base surfaces ( 25 . 33 ) of the two truncated cones are the same size. Planet carrier according to claim 1 or 2, characterized in that the radii of the top surfaces ( 26 . 34 ) of the carrier elements ( 4 . 5 . 14 . 15 ) descriptive truncated cones are the same size. Planet carrier according to claim 1, characterized in that in each case a web ( 8th ) of the one carrier element ( 4 ) in an imaginary radial plane ( 10 ) of the planet carrier ( 1 . 11 ) with a bridge ( 9 ) of the other carrier element ( 5 ) is axially connected, whereby the carrier elements ( 4 . 5 ) descriptive truncated cones a common and in the radial plane ( 10 ) ( 25 ) exhibit. Planet carrier according to claim 1, characterized in that the carrier elements ( 14 . 15 ) via an intermediate plate ( 21 ) of the planet carrier ( 11 ), each bridge ( 18 . 19 ) of the one carrier element ( 14 . 15 ) in the direction of the other carrier element ( 14 . 15 ) pointing to an intermediate plate ( 21 ) of the Planetenträges ( 11 ) is attached.

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