This application claims the benefit of and right of priority under 35 U.S.C. ยง 119 to German Patent Application no. 10 2023 211 924.2, filed on 29 Nov. 2023, the contents of which are incorporated herein by reference in its entirety.
The invention relates to a drive axle for a vehicle with a differential gearing arranged in a transmission housing, which differential is connected to wheel hubs by way of plug-in shafts, wherein the plug-in shafts extend through axle housings, wherein the plug-in shafts are arranged with their ends facing toward the differential gearing fixed on the bevel gears of the axle, and wherein there is arranged on one or both plug-in shafts a transmitter wheel whose rotation movement can be detected by a rotation speed sensor arranged on the transmission housing or the axle housing.
In such a drive axle the plug-in shaft is mounted in a floating manner, wherein on the transmission side it is aligned with the working teeth of the axle bevel gears. On the wheel head side a planetary gearset is driven by the plug-in shaft and the alignment takes place in the working teeth of the planetary gearset.
During the operation of the vehicle, due among other things to load changes, oscillations and deflections of the plug-in shafts resulting in signal suspension of the rotation speed sensors can occur, and this results in incorrect further processing of the rotation speed signals.
The purpose of the present invention is therefore to provide a drive axle for a vehicle of the type mentioned to begin with, which avoids that drawback so that at least largely correct rotation speed signals are produced by the rotation speed sensors, and which has a simple structure and essentially does not require any enlargement of the fitting space needed.
According to the invention this objective is achieved if the plug-in shafts pass radially directly or indirectly to the transmission housing or to an area of the axle housing adjacent to the transmission housing.
This guiding results in a pre-centering of the plug-in shafts and reduces their oscillations and deflections, so that at least to a large extent correct rotation speed signals are produced by the rotation speed sensor. An advantageous possibility for the guiding is that the axle bevel gears are guided radially and rotatably by means of bearings on the differential cage.
In that case the plug-in shafts are centered in a simple manner by means of the axle bevel gears.
A further advantageous possibility for the guiding is that one or both plug-in shaft(s) is/are guided radially and rotatably by bearings on the axle housings or on the transmission housing.
Another advantageous possibility for the guiding is that one or both plug-in shaft(s) is/are guided radially and rotatably by bearings on the differential cage of the differential gearing.
In a simply designed manner, the above-mentioned bearings can be slide bearings or roller bearings.
A further advantageous possibility for the guiding is that the differential gearing is a locking differential transmission with a disk packet arranged coaxially with the plug-in shaft, which packet consists of alternating axially displaceable inner disks and outer disks, wherein the disk packet can be actuated axially, directly or indirectly, by the force of a pressure piece in the form of a sliding sleeve which can be displaced axially on the plug-in shaft and actuated by force, whereby the plug-in shaft is guided radially and rotatably on the sliding sleeve.
It is also possible for the differential gearing to be a locking differential transmission with a disk packet arranged coaxially with the plug-in shaft, which packet consists of alternating axially displaceable inner disks and outer disks, wherein the disk packet can be actuated axially, directly or indirectly, by the force of a hydraulically actuated annular pressure piston which can be displaced axially on the plug-in shaft, whereby the plug-in shaft is guided radially and rotatably on the pressure piston.
It is also possible for the differential gearing to be a locking differential transmission with a disk packet arranged coaxially with the plug-in shaft, which consists of alternating axially displaceable inner disks and outer disks, wherein the inner disks with their radially all-round outer disks are guided rotatably and radially on the differential cage and/or on a locking lid that encloses the disk packet.
A further possibility is for the differential gearing to be a locking differential transmission with a disk packet arranged coaxially with the plug-in shaft, which packet consists of alternating axially displaceable inner disks and outer disks, wherein the outer disks with their radially all-round inner circumference are guided rotatably and radially on a cylindrical attachment of the axle bevel gear.
Example embodiments of the invention are shown in the drawing and described in greater detail in what follows. The drawing shows:
The drive axles shown comprise a transmission housing 1 onto which diametrically opposite tubular axle housings 2 are flanged.
In the transmission housing there is arranged a differential gearing system 3 on the axle bevel gears 4 of which the radially inward-projecting ends of plug-in shafts 5 are arranged in a rotationally fixed manner, so that alignment takes place in the working teeth of the differential gearing.
The plug-in shafts 5 that can rotate about a rotation axis 10 pass through the axle housing 2 to planetary drives 6 arranged in wheel heads 7 and with their outward-projecting ends are aligned in the working teeth of the planetary drive.
Thus, the plug-in shafts are mounted in a floating manner.
In the axle housings 2 there are arranged radially inward-projecting rotation speed sensors 8, which are directed toward positionally fixed transmitter wheels 9 radially surrounding the plug-in shafts 5 and which detect the rotation speed of the plug-in shafts 5. The signals from the rotation speed sensors are sent to evaluation units by way of lines (not shown), for further processing.
The differential gearing 3 comprises a large coaxial bevel gear 11 mounted to rotate relative to the rotation axis 10, which can be driven in rotation by a drive unit (not shown).
On the large bevel gear 11 is arranged a differential cage 12 that consists of two pot-like parts, which at its axial ends is mounted to rotate, respectively on one of the plug-in shafts 5, about the rotation axis 10.
A bearing bolt 13 extends transversely to the rotation axis 10 and is fixed with its free ends on the radially surrounding walls of the differential cage 12. On the bearing bolt 13 are rotatably mounted two pinion gears 14 opposite one another, each respectively engaging in the two axle bevel gears 14.
Inside the left-hand part of the differential cage 12 is arranged a lock 15 that can be engaged hydraulically, which comprises a disk packet 16 arranged coaxially with the plug-in shaft 5, which packet consists of alternating, axially displaceable inner disks 17 and outer disks 18, wherein the disk packet 16 can be acted upon with force to compress it by a pressure piece in the form of a siding sleeve 19 that can be displaced axially on the plug-in shaft 5.
In turn the sliding sleeve 19 can be acted upon by an annular pressure piston 20 that surrounds the plug-in shaft 5, which piston is arranged and can be displaced in an annular cylindrical recess 22 of the left-hand axle housing 2 and can be actuated by pressure via a hydraulic connection 21.
In the example embodiment of
In the example embodiment of
In the example embodiment of
In one of them the plug-in shaft 5 has approximately the same outer diameter as the inner diameter of the pressure piston 20 of the lock 15.
Alternatively, the plug-in shaft 5 can have approximately the same outer diameter as the inner diameter of the sliding sleeve 19.
On the right-hand side of
In the example embodiment shown in
Number | Date | Country | Kind |
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10 2023 211 924.2 | Nov 2023 | DE | national |