DE102005029537A1 - Planetary gear, has planet wheel rotatably mounted on planet carrier bolt using gear ring, where inner diameter of planet wheel has larger hub width than gearing width, and length of gear ring is same as hub width of planet wheel - Google Patents

Abstract

The gear has a planet carrier (16) connected with a planet carrier bolt (25). A helically toothed planet wheel (24) is rotatably mounted on the planet carrier bolt using a gear ring (37), where length of the gear ring is same as hub width of the planet wheel. Inner diameter of the planet wheel has larger hub width than gearing width. The planet wheel has a support base for supporting on the planet carrier bolt.

Description

The The invention relates to a planetary gear with the features of the preamble of claim 1.

Such a planetary gear is from the unpublished DE 10 2004 024 985 the applicant known. There, a planetary gear is disclosed with a planet carrier, are supported on the planet carrier bolts, on each of which planet gears are mounted with different numbers of sprockets.

Of the present invention is based on the object, a higher durability of planetary gear bearings and thus a longer life of planetary gears to enable.

The The object underlying the invention is achieved by the features of the claim 1.

According to the invention is a Hub width of the planet gear in the range of the inner diameter greater than the tooth width of the planetary gear. Here is the gearing width defined as the product of the width of a tooth flank and the cosine the helix angle, the included angle between the axis of rotation of the planetary gear and describes the ridgeline of a single tooth of the planetary gear.

This Invention is based on the finding that a planetary gear with one opposite the gearing width enlarged hub width a larger support base for one Storage on the planet carrier bolt offers. For larger hub widths bearing forces, the can be reduced by tilting moments. such Tipping moments occur in particular helical planetary gears or be in the operation of the planetary gear through existing clearance caused. The case of the bearings on the planet carrier bolt be supported personnel are compared to embodiments with narrower planet wheels due to a big one Lever arm relatively low, whereby the life of the bearing is increased. This makes possible, to increase the life of the gearbox.

According to one Proposal of the invention, the planetary gear via a needle bearing on the Planet carrier bolts stored, with the length a rolling element of the Needle bearing almost the hub width of the planetary gear corresponds. With such a long needle bearing is the maximum available Bearing width exploited. The surface pressure on the individual rolling elements is minimized and thereby increasing the life of the bearings.

In An embodiment of the invention is the planetary gear of the planetary gear according to the invention over several Needle bearing on the planet carrier bolt stored, the summed length each one of the rolling elements of Needle bearing almost the hub width of the planetary gear corresponds. Advantageous this configuration is particularly in terms of cost-effectiveness, because bearings, in particular needle roller bearings, standard width are used can, which are arranged axially next to each other.

In In a further embodiment of the invention, the planetary gear is about two Bearings on the planet carrier bolt supported wherein each one of the bearings in the region of the axial ends of the planetary gear hub is arranged. This embodiment is also optimized in terms of cost, since only two Warehouse commercial Width can be used. Because the bearings are within the width of the Planetenradnabe are arranged at a maximum distance from each other, becomes the maximum possible support base for tilting moments exploited.

preferred embodiments the planetary gear according to the invention will be explained in more detail with reference to the drawing. In the drawing shows:

1 a longitudinal section through an inventive planetary gear according to a first embodiment,

2 a simplified schematic diagram for illustrating the angular geometries on the tooth profile of a helical planetary gear in the form of a section of a side view of the tooth profile of the planetary gear,

3 a longitudinal section through a planetary gear of a planetary gear according to the invention according to a second embodiment and

4 a longitudinal section according to 3 by a third embodiment of a Planetenradlagerung.

In The figures are the same or equivalent components with the same Reference number marked.

• – eines möglichen Getriebekonzepts für ein derartiges Toroidgetriebe,
• – der Integration der in der Zeichnung dargestellten Bauteile in ein derartiges Getriebekonzept,
• – der Anbindung der dargestellten Bauteile an nicht dargestellte, benachbarte Getriebeelemente und
• – der Lagerung der in der Zeichnung dargestellten Bauteile

wird vollumfänglich auf die Druckschrift DE 102 06 202 A1 verwiesen, welche zum Gegenstand der vorliegenden Anmeldung gemacht wird.The invention relates to a planetary gear, which is used, for example, as a partial transmission of a toroidal transmission for a motor vehicle, in particular with standard drive. In the Toroidge For example, transmission is a continuously variable transmission with at least two driving ranges, which is power-split and has a so-called geared-neutral point. Regarding

• A possible transmission concept for such a toroidal transmission,
• - The integration of the components shown in the drawing in such a transmission concept,
• - The connection of the illustrated components to not shown, adjacent transmission elements and
• - The storage of the components shown in the drawing

is completely on the publication DE 102 06 202 A1 which is the subject of the present application.

In a toroidal gearbox 10 there is a transmission of a drive torque from a transmission input shaft 11 to two output elements 12 . 13 , if necessary under power split. Between the transmission input shaft 11 and the output elements 12 . 13 is a gear stage 14 and a toroidal variator only partially shown 15 , for example, in construction as a half-toroid, interposed.

The gear stage 14 has a planet carrier 16 on, the drive-proof with the transmission input shaft 11 connected is. The planet carrier 16 is according to 1 with a paragraph 17 the transmission input shaft 11 welded. In the planet carrier 16 are circumferentially about the transmission input shaft 11 distributes several planet carrier bolts 18 held. Opposite the bolt 18 are several stepped planets 19 rotatably mounted. The step planet 19 has a first planet 20 as well as a second planet 21 with a larger diameter. The first planet 20 which is on the toroidal variator 15 facing side of the stepped planet 19 is arranged radially inwardly meshing with a sun gear 22 , The second planet 21 Radially meshes with a sun gear 23 and radially outboard, if necessary, as in 1 represented, offset in the circumferential direction, with a planet 24 , which via another planet carrier bolt 25 also opposite the planet carrier 16 is supported. The planet 24 meshes radially outboard with a ring gear 26 , the non-positively with the one output element 12 connected is.

The sun wheel 22 is fixed or integral with a gear shaft 27 connected. In the in the 1 illustrated embodiment is the transmission shaft 27 designed as a hollow shaft and coaxial with the transmission input shaft 11 arranged so that the transmission input shaft 11 through the gear shaft 27 passed through. The sun wheel 23 is fixed to drive or integral with the output element 13 connected. The transmission shaft 27 is in the 1 not shown manner with a driven pulley (or more driven pulleys in a multi-chamber variator) drivingly connected. The planet carrier 16 is drive resistant with a torus disc 28 , here a Antriebstorusscheibe, connected.

The planet carrier 16 is approximately Y-shaped in an illustrated upper half-section plane and substantially rotationally symmetrical to the longitudinal axis of the transmission shaft 11 educated. The circumferential lower end of the central leg 29 the Y limits a hole in which the heel 17 the transmission input shaft 11 is supported. The parallel side legs 30 . 31 of the Y have the transmission input shaft 11 radially spaced and aligned bores, in each of which a planet carrier bolt 18 is used.

Radial outboard has the side legs 30 about an approximately hollow cylindrical extension 32 in the direction of the toroidal variator 15 , The extension 32 has an upstream in the direction of the variator Mitnehmerbereich 33 with a suitable driver toothing 34 on, via which a drive torque from the planet carrier 16 to a suitable counter-toothing of the Torusscheibe 28 can be done.

In the lower half of the 1 is a single row planetary gear 24 and its storage on a planet carrier bolt 25 shown. The planet wheel 24 has a sleeve-shaped body 35 and at the right axial end a radial thickening 36 on whose circumference a grades or oblique tooth profile 37 is trained. Except for a further thickening with radial teeth on the left end of the planetary gear 24 with regard to geometric dimensions, the same design as the stepped planet 19 in the upper half of the 1 , Also assign the second planet 21 of the stepped planet 19 and the planetary gear 24 an equal pitch and same numbers of teeth on. In addition, the planet carrier bolts 18 . 25 on which are the stepped planets 19 and on the other hand the planet wheels 24 are stored, the same design.

The left end of the planet wheel 24 extends parallel to the stepped planet 19 in a plane in which during operation of the planetary gear 14 the first planet 20 around the transmission input shaft 11 rotates. Thus, the planet occupies 24 no additional space.

At the axial end faces is the planetary gear 24 on plain bearings 38 in the form of start-up or sliding discs and is so axially on the side legs 30 . 31 or at the planet carrier bolt 25 supported. However, Wälzkörperla are also possible wrestled. In the area of the end faces is the planetary gear 24 also over two radial bearings 39 rotatably on the planet carrier bolt 25 stored. Due to the small space, especially in the radial direction, needle roller bearings are particularly suitable for such storage. However, grooved ball or cylindrical roller bearings can also be used. The latter have advantages with regard to the support of axial forces.

Between the two cages of needle bearings, not shown in detail 39 is a spacer sleeve 40 arranged on the inner circumference of the hole in the planetary gear 24 is applied. Via an axial bore 41 and one or more over the circumference of the planet carrier bolt 25 distributed radial bores 42 will be a lubrication of the bearings 39 allows. Of course, also conceivable are bearings 39 with lifetime lubrication.

The planet wheel 24 may have straight or helical gearing. Thus, the teeth extend 43 or the tooth flanks of the planetary gear 24 in width parallel to the axis of rotation 44 of the planet carrier bolt 25 (Straight teeth, β = 0) or they have a helix angle β with respect to this axis of rotation 44 on, ie the helical gearing β ≠ 0 ( 2 ). According to the invention, the hub width 45 of the planetary gear 24 in the range of the inner diameter larger than the tooth width 46 ( 3 ). It will be below the gearing width 46 the width multiplied by the cosine of the helix angle β 47 a tooth 43 of the planet wheel 24 Understood ( 2 ).

In 3 is another embodiment of the storage of a planetary gear according to the invention 24 shown. The needle bearing shown there 39 extends over almost the entire width 45 the hub of the planet wheel 24 , Due to the width of the needle bearing 39 and the associated wide support of the planetary gear 24 on the planet carrier bolt 25 is the contact surface between the hub of the planetary gear 24 and rolling elements of the bearing 39 or the contact surface between rolling elements and planet carrier bolt 25 relatively large. Therefore, a resulting surface pressure is relatively small. This contributes to increase the life of the bearing 39 at and thus can also increase the life of the planetary gear according to the invention 14 contribute.

In 4 is the planetary gear according to the invention 24 over several axially adjacent needle roller bearings 39 on the planet carrier bolt 25 stored. One warehouse each 39 is in the range of the axial ends of the planetary gear 24 arranged near the front sides. Another needle bearing 39 is centered between the two outer needle bearings 39 arranged and over spacers 40 supported on these. The spacers 40 are in proportion to the width of the needle roller bearings 39 quite narrow, so that the sum of the length of each rolling element of one of the three needle roller bearings 39 almost the width 45 corresponds to the planetary hub. It is also conceivable, on such spacers 40 or spacers completely dispense. Then there are the bearings or the cages of the camp 39 between left and middle or between middle and right bearing 39 together.

It is understood that the invention is not limited to one to three needle bearings 39 is limited. There may well be an even higher number of camps 39 be used.

Also, the use of another type of storage is possible. Especially when storing planetary gears 24 with helical teeth (β ≠ 0) is a use of a bearing type, which can support not only a radial but also an axial force component, such as ball or cylindrical roller bearings makes sense.

Claims (6)

Planetary gear ( 14 ) with a planet carrier ( 16 ) and a planet carrier bolt connected thereto ( 25 ) on which a planetary gear ( 24 ) with only a single-row sprocket ( 37 ) is rotatably mounted, characterized in that a hub width ( 45 ) of the planetary gear ( 24 ) in the region of the inner diameter is greater than the tooth width ( 46 ). Planetary gear ( 14 ) according to claim 1, characterized in that the planetary gear ( 24 ) via a needle bearing ( 39 ) on the planet carrier bolt ( 25 ), wherein the length of a rolling element of the needle bearing ( 39 ) almost the hub width ( 46 ) of the planetary gear ( 24 ) corresponds. Planetary gear ( 14 ) according to claim 1, characterized in that the planetary gear ( 24 ) via several needle roller bearings ( 39 ) on the planet carrier bolt ( 25 ), wherein the summed length depending on one of the rolling elements of the needle roller bearings ( 39 ) almost the hub width ( 46 ) of the planetary gear ( 24 ) corresponds. Planetary gear ( 14 ) according to claim 1, characterized in that the planetary gear ( 24 ) over two bearings ( 39 ) on the planet carrier bolt ( 25 ), one of the bearings ( 39 ) in the region of the axial ends of the planetary hub ( 46 ) is arranged. Planetary gear ( 14 ) according to claim 1, characterized in that the planetary gear ( 24 ) has a helical toothing. Planetary gear ( 14 ) according to claim 1 as part of a toroidal transmission.