Change-speed transmission for motor vehicles

Abstract

A change-speed transmission for motor vehicles, in particular manual transmission, having a plurality of forward gears and, optionally, one reverse gear, includes at least one input shaft, an output shaft and, optionally, a layshaft, between which the idler gears, which can be shifted via synchronous clutches, and the fixed gears of the gearwheel sets are arranged. At least one of the has a two-part design and is mounted in the transmission housing with mutually different axes of rotation, an annular gear stage is functionally provided between the sub-shafts and includes a internally-toothed annular gear and an externally-toothed spur gear that meshes therewith, the sub-shaft which has the larger axial distance to the other shaft bearing gearwheels of the lower forward gears and, optionally, of the reverse gear.

Claims

1. A change-speed transmission for a motor vehicle, having a plurality of forward gears and a reverse gear, comprising: at least one input shaft, an output shaft and a layshaft operatively connected by idler gear wheels and fixed gear wheels of gear sets which form the plurality of forward gears and the reverse gear, wherein at least one of the at least one input shaft, the output shaft and the layshaft is comprised of two subshafts defined by respective rotation axes and is supported in a housing of the transmission so that the rotation axes are offset to each other by an axial offset, wherein one of the two subshafts has a greater distance to another one of the at least one input shaft, the output shaft and the layshaft than the other one of the two subshafts and carries gear wheels of lower ones of the forward gears and optionally gear wheels of the reverse gear; and a ring gear stage operatively connecting the two subshafts, and having an internally splined ring gear and an externally splined spur gear meshing with the ring gear.

2. The change-speed transmission of claim 1, constructed as manual transmission.

3. The change-speed transmission of claim 1, wherein the ring gear stage is arranged on the input shaft between the gear sets that form higher ones of the plurality of forward gears and the gear sets that form lower ones of the plurality of forward gears and the reverse gear.

4. The change-speed transmission of claim 1, wherein the ring gear stage is provided on the output shaft between the gear sets that form higher ones of the plurality of forward gears and the gear sets that form lower ones of the plurality of forward gears and the reverse gear.

5. The change-speed transmission of claim 1, wherein the input shaft is comprised of the two subshafts, with one of the two subshafts being constructed as a reverse driving hollow shaft and the other one of the two subshafts being constructed as a continuous shaft, wherein the ring gear stage is arranged between the continuous shaft and the hollow shaft, and wherein the hollow shaft has a greater distance to the output shaft than the continuous shaft and carries the gear sets of the lower ones forward gears and the reverse gear.

6. The change-speed transmission of claim 1, wherein the output shaft is comprised of the two subshafts, with one of the two subshafts being constructed as a reverse driving hollow shaft and the other one of the two subshafts being constructed as a continuous shaft, wherein the ring gear stage is arranged between the continuous shaft and the hollow shaft, and wherein the hollow shaft has a greater distance to the output shaft than the continuous shaft and carries the gear sets of the lower ones of the forward gears and the reverse gear.

7. The change-speed transmission of claim 1, further comprising a shiftable clutch, wherein a connection between a drive of the motor vehicle and the ring gear stage is interruptible by the shiftable clutch.

8. The change-speed transmission of claim 7, wherein the ring gear stage and the shiftable clutch are arranged on the input shaft, and wherein the idler gear wheels of corresponding ones of the lower gear sets are positioned on the output shaft.

9. The change-speed transmission of claim 1, wherein the ring gear stage is arranged on the input shaft, wherein the output shaft is constructed as a hollow shaft through which a further output shaft of an integrated interaxle differential extends, wherein the output shaft outputs onto a differential housing of the interaxle differential, and the further output shaft outputs onto an axle differential opposite the interaxle differential.

10. The change-speed transmission of claim 1, wherein the input shaft and the output shaft are arranged coaxial, and the ring gear stage is arranged on the layshaft, said layshaft carrying the gear wheels.

11. The change-speed transmission of claim 1, wherein the ring gear stage is constructed as a crescent pump for transporting lubricant oil or hydraulic oil.

12. The change-speed transmission of claim 1, further comprising a pawl pivotally provided on a housing of the transmission, said ring gear being arranged on the output shaft and having an external spline, said external spline cooperating with the pawl so as to form a parking lock of the transmission.

Description

BRIEF DESCRIPTION OF THE DRAWING

(1) In the following multiple exemplary embodiments of the invention are explained in more detail by way of the included block diagrams.

(2) It is shown in:

(3) FIG. 1 a transmission for motor vehicles with six forward gears and a reverse gear, whose gear sets are arranged on an input shaft and an output shaft, and with a ring gear stage on the two-part input shaft, which is provided between lower and higher gear sets;

(4) FIG. 2 the manual transmission according to FIG. 1, in which the ring gear stage is arranged on a two-part output shaft;

(5) FIG. 3 a manual transmission according to FIG. 1 in which the ring gear stage is provided between a continuous input shaft and a reversed riving hollow shaft, which carries gear wheels of the lower gear wheel sets;

(6) FIG. 4 a manual transmission according to FIG. 1 in which the ring gear stage is arranged between a continuous output shaft and a hollow shaft, which carries the gear wheels of the lower gear wheel set;

(7) FIG. 5 a manual transmission according to FIG. 3 in which the ring gear stage has a switching clutch by means of which the corresponding hollow shaft is switchable;

(8) FIG. 6 a manual transmission for a four wheel drive motor vehicle with a ring gear sage on the input shaft, an output shaft configured as hollow shaft, which outputs onto an integrated interaxle differential, whose output shafts are drivingly connected with a front axle differential and a rear axle differential;

(9) FIG. 7 a manual transmission according to FIG. 3, in which the ring gear stage which is arranged on the input shaft is also configured a gearwheel pump for supplying hydraulic fluid for a transmission control; and

(10) FIG. 8 a further manual transmission for motor vehicles with an input shaft, a coaxial output shaft and an axially parallel layshaft, which is configured two-part and is drivingly connected via a ring gear stage.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

(11) FIG. 1 shows as block diagram and a change-speed transmission or manual transmission 10 for motor vehicles without transmission housing, with an input shaft 14 which can be connected with a drive aggregate (not shown) via a separating clutch 12, and an output shaft 16.

(12) Between the shafts 14, 16 meshing gear wheels of gear sets for six forward gears 1 to 6 and a reverse gear R are arranged. The idler gear wheels of the gear sets 1 to 6 and of the reverse gear R are shiftable in a known manner via only schematically indicated synchronous clutches 18 and can thus be connected with the corresponding fixed gear wheel on the respective other shaft 14, 16.

(13) The two-part input shaft 14 of the transmission 10 is connected via a ring gear stage 20 with a ring gear 20a, which has a greater diameter and internal spline, and with a spur gear wheel 20b, which is in engagement with the ring gear 20a, wherein the subshaft 14a which carries the spur gear wheel 20b, carries the gear wheels of the gear sets 3 to 6 and the subshaft, which is connected with the ring gear 20a, carries gear wheels of the gear sets 1, 2 and R.

(14) While the continuous, one-part drive shaft 16 is supported rotatable in the transmission housing via a first rotation axis, the rotation axes of the subshafts 14a, 14b of the input shaft 14, which are axially parallel thereto, are offset relative to each other with an axial offset of a few millimeters, as can be seen. Hereby the subshaft 14b, which carries the ring gear 20a, has a greater distance a.sub.1 to the output shaft 16b than the subshaft 14a which is arranged with a smaller axial distance a.sub.2.

(15) As a result of the configuration of the ring gear stage 20 (diameter, number of teeth) the desired axial offset .sub.v and the transmission ratio of the ring gear stage 20 can be defined. The axial offset .sub.v also enables greater constructive freedom regarding the configuration of the transmission ratio and the accommodation of the lower forward gears 1, 2, which are situated on the subshaft 14b, and optionally the reverse gear R.

(16) FIGS. 2 to 8 show alternative exemplary embodiments of the invention, which in order to avoid repetition, are only described insofar as they significantly differ from the exemplary embodiment of FIG. 1. Functionally same parts are provided with the same reference signs.

(17) According to FIG. 2 the ring gear stage 20 is arranged on the output shaft 16 of the transmission 10.

(18) For this the output shaft 16 is constructed two-part with a subshaft 16a and a subshaft 16b with the ring gear stage 20 arranged there between. On the subshaft 16a, which has a greater axial distance a1 to the one-part input shaft 14, the spur gear wheel 20b and the gear wheels of the lower gear sets 1, 2 and R are arranged, while the second subshaft 16b carries the gear wheels of the higher gear sets 3 to 6.

(19) FIG. 3 shows an alternative configuration of the two-part input shaft 14 of the transmission 10 compared to FIG. 1, in which the ring gear stage 20 is arranged on a front side end of the input shaft 14 or on the continuous subshaft 14a and on a reverse driving hollow shaft 14b as second subshaft or respectively drivingly connects the latter.

(20) The hollow shaft 14b, which has a greater distance a1 to the output shaft 16, carries the ring gear 20a and the gear wheels of the lower gear sets 1, 2 and R, while the first subshaft 14a is drivingly connected with the spur gear wheel 20b of the ring gear stage 20 and the gear wheels of the higher gear sets 3 to 6.

(21) In the exemplary embodiment according to FIG. 4 the ring gear stage 20 is provided on the one front side end of the two-part output shaft 16.

(22) For this the output shaft 16 has a continuous subshaft 16a and a reverse driving hollow shaft 16b, which are drivingly connected with each other by means of the ring gear stage 20.

(23) The subshaft 16a carries hereby a ring gear 20a and the gear wheels of the lower gear sets 1, 2, R, and has correspondingly a greater axial distance a1 to the one-piece input shaft 14 than the hollow shaft 16b with the spur gear wheel 20b and the gear wheels of the higher gear sets 3 to 6.

(24) In contrast to the ring gear stages 20 described above, the ring gear 20c is additionally provided with an external spline which in cooperation with a pawl (not shown), which is pivotally arranged in the transmission housing forms a parking lock P. When the pawl is retracted, the ring gear 20c, and with this the outputting subshaft 16a in the transmission housing of the transmission, is blocked. Optionally the external spline can also be used as output stage.

(25) FIG. 5 shows an alternative exemplary embodiment to FIG. 3, in which the driving connection can be interrupted via the ring gear stage 20 on the input shaft 14 of the transmission 10 by means of a shifting clutch 22 (this can for example be a synchronous clutch 18 common in transmissions.

(26) When the shifting clutch 22 is engaged, the spur gear wheel 20b of the ring gear stage 20 is coupled with the continuous subshaft 14a, while it can freely rotate on the subshaft 14a, when the switching clutch 22 is disengaged.

(27) The gear wheels situated on the hollow shaft 14b of the lower gear sets 1, 2, R are fixed gear wheels, which are in engagement with idler gear wheels on the output shaft 16, which idler gear wheels can be shifted via synchronous clutches 18.

(28) While the arrangement fixed gear wheelsidler gear heels of the gear sets 1 to 6 and R on the input shaft 14 and the output shaft 16 in the exemplary embodiments can be configured by constructive considerations, it is a characterizing feature of the embodiment of FIG. 5 that the fixed gear wheels of the gear sets 1, 2 and R are positioned on the hollow shaft 14b. As a result all gear wheels of the gear sets 1, 2 and R stand still when the hollow shaft 14b is decoupled in the higher gears 3 to 6, i.e., they do not cause drive losses or wear.

(29) FIG. 6 shows a further exemplary embodiment of the invention with a transmission 24 for all-wheel drive motor vehicles, in which the output shaft 16 is configured as hollow shaft, on which the gear wheels of the gear sets 1 to 6 are arranged.

(30) The input shaft 14 is again constructed two-part with a subshaft 14a and a hollow shaft 14b, which are interconnected via the ring gear stage 20 as described above.

(31) The output shaft 16 outputs onto the differential housing 26 of an interaxle differential 28 which is integrated in the transmission housing, and whose one output shaft 30 drives a front axle differential 36 of the motor vehicle via a spur gear drive 34, while the second output shaft 32 outputs onto the rear axle of the motor vehicle in a not further shown manner.

(32) The shown transmission 24 may be used for the longitudinal mounting as well as for a transverse mounting in the motor vehicle. The same applies to the transmissions 10 described above.

(33) In the transmission 10 according to FIG. 7 the ring gear stage 20 is arranged on the free end side of the input shaft 14 or the hollow shaft 14b.

(34) Beside these functions as transmission stage, the ring stage 20 is also configured in cooperation with housing elements of the transmission 10 as gearwheel crescent pump, which aspirates hydraulic fluid, for example gear oil, form an oil sump 38 as indicated with arrows, and supplies the hydraulic fluid under pressure to a not shown electro-hydraulic transmission control. The crescent pump can be of known construction with a suction pressure chamber formed in the housing and correspondingly provided suction and supply channels.

(35) FIG. 8 shows a transmission 40 with an input shaft 42, a coaxial output shaft 44 and an axially parallel layshaft 46, wherein the layshaft 46 is configured two-part and has the ring gear stage 20 with the shifting clutch 22.

(36) The layshaft 46 includes a subshaft 46a and a reverse driving hollow shaft 46b, which are interconnected via the ring gear stage 20 as described above.

(37) Beside the gear wheels of the gear sets 3, 4, 6 or 1, 2, R arranged between the output shaft 44 and the layshaft 46, a fixed (not switchable) gear set 48 is provided on the input shaft 42 and the layshaft 46a, via which gear set 48 the layshaft 46 is constantly driven.

(38) Further, beside the forward drive 6 a direct drive, for example as forward gear 5, can be shifted via the synchronous clutch 18 provided between the input shaft 42 and the output shaft 44, in which the input shaft 42 and the output shaft 44 are directly connected with each other.

(39) Driven via the gear wheel set 48, the forward gears 3, 4, 6 can be shifted, or respectively driven via the ring gear stage 20, the forward gears 1, 2 and the reverse gear R can be shifted as described above. In addition the gear sets of the forward gears 1, 2 and of the reverse gear R can be turned off by means of the shifting clutch 22, when driving in the higher forward gears 3 to 6.