The present invention relates to the field of transmission technology. It refers to a (continuously variable) hydrostatically power-splitting transmission according to the preamble of claim 1.
Such a transmission is known, for example, from DE-A1-26 33 718.
Power-splitting transmissions, particularly for employment in vehicles of agricultural or building use, such as, for example, tractors, have been known for a long time. In such power-splitting transmissions, the power prevailing at an input shaft or drive shaft and usually output by an internal combustion engine is apportioned to a first mechanical power branch with a fixed step-up ratio and a second power branch having a continuously variable step-up ratio and is subsequently combined again in order to be available at an output shaft or take-off shaft. The second power branch is mostly designed as a hydrostatic branch in which two hydrostatic axial piston engines (hydrostats) of the oblique axis or swashplate type, which are connected to one another hydraulically, operate selectively as a pump or as a motor. The step-up ratio can in this case be varied by a variation of the pivot angle of the cylinder block or the swashplate. The apportionment of the power to the two power branches and the combining of the split powers usually take place by means of an epicyclic transmission. Power-splitting transmissions of the type described are disclosed in various configurations in DE-A1 27 57 300, in DE-C2-29 04 572, in DE-A1-29 50 619, in DE-A1-37 07 382, in DE-A1-37-26 080, in DE-A1-39 12 369, in DE-A1-39 12 386, in DE-A1-43 43 401, in DE-A1-43 43 402, in EP-B1-0 249 001 and in EP-A2-1 273 828.
So that a power-splitting transmission can be successfully employed in practice, it should, in general, be distinguished by the following properties:
The initially mentioned DE-A1-43 43 402 has already described a power-splitting transmission, designated as a CHP transmission (Continuously variable Hydrostatic Power-splitting transmission), which is distinguished by two hydraulically coupled identical hydrostats of the oblique axis type of construction, which can be coupled in different ways to an epicyclic differential transmission via pairs of clutches or change-shift elements K1/K2 or K3/K4. The known CHP transmission has been employed and tested under the type designation SHL-Z in city buses. The two hydrostats employed have a pivoting range of only 0-25°. For forward travel, in this case, three driving steps or driving ranges are obtained: in the first driving range, at the starting point the hydrostatic fraction of the transferred power is 100% and then moves linearly with the speed toward zero. In the second driving range, it moves from zero to a maximum of about 27% and then back again to zero. In the third driving range, it moves from zero to a maximum value of 13% at the highest forward speed.
The hydrostatic power transfer branch of such a transmission usually comprises two hydrostatic axial piston engines which are connected hydraulically to one another and of which in each case one operates as a pump and the other as a motor. Depending on the driving step, in this case, the two engines can interchange their roles.
The hydrostatic axial, piston engines constitute an essential component of the hydrostatic power-splitting transmission and decisively affect the properties of the transmission, such as, for example, the efficiency, overall size, complexity, speed range covered, type and number of driving steps, and the like. Examples of hydrostatic axial piston engines of this type are disclosed in DE-A1-198 33 711 or in DE-A1-100 44 784 or in US-A1-2004/0173089. The functioning and theory of hydrostatic axial piston engines and of a power-splitting tractor transmission equipped with them are described in a publication of TU Munich from the year 2000 by H. Bork et al., “Modellbildung, Simulation and Analyse eines stufenlosen leistungsverzweigten Traktorgetriebes [Modelling, Simulation and Analysis of a continuously variable power-splitting tractor transmission]”.
In the known hydrostatic transmissions, the parts in the transmission (hydrostats, clutches, shafts, epicyclic drives, gearwheels, etc.) are installed in a housing which is oriented specially with respect to the transmission and consists of a multiplicity of housing segments. If, then, such a transmission is to be installed in a corresponding agricultural or building vehicle, either the vehicle has to be coordinated in its design with the already prefabricated transmission or the transmission has to be coordinated with the given conditions of an already existing vehicle and therefore redesigned. In both instances, a considerable extra outlay arises due to the special adaptation of the vehicle or entire transmission.
In the initially mentioned publication DE-A1-26 33 718, it has. already been proposed to construct a simple hydrostatic transmission without power splitting so that it forms a structural unit with the cover of the transmission housing. In the transmission housing itself, only the drive and take-off shafts accessible from outside are mounted, and come into engagement via internal gearwheels with the corresponding inputs and outputs of the transmission when the cover together with the transmission is placed on the transmission housing.
What is achieved thereby is that the housing together with the drive and take-off shafts can be installed in the vehicle at an early stage, while a decision can be made later, by a cover together with a corresponding transmission unit being put in place, as to whether a mechanical or a hydrostatic transmission is to be used. Correspondingly, transmissions can be exchanged in a simple way in the already finished vehicle.
The transmission concept (structural unit of transmission and cover) known from DE-A1-26 33 718 may be useful for the simple case of a transmission without power splitting, when neither clutches nor summing members are required and only one of the hydrostats is adjusted. It is sufficient here to arrange the adjusting mechanism for the one hydrostat directly on the hydrostat inside the housing.
For the substantially more demanding concept of a continuously variable hydrostatic power-splitting transmission, however, other ways must be found not only to accommodate the markedly more complicated control, but also to place it suitably in terms of assembly and of maintenance.
One object of the invention, therefore, is to provide a hydrostatically power-splitting transmission which, while maintaining the flexible concept of the separation of transmission and housing, is distinguished by an improved arrangement of the components and, in particular, is suitable for implementing a complex continuously variable hydrostatic power-splitting transmission. An object of the invention, furthermore, is to specify a transmission concept which is especially suitable for this purpose.
The one object is achieved by means of the whole of the features of claim 1. A characterizing feature of the novel transmission is that the control for adjusting or pivoting the at least one hydrostat is arranged on the top side of the cover and acts through the cover upon the at least one hydrostat. By the control being shifted onto the top side of the cover, there is not only space for the transmission components arranged in the housing, but also access to the control from outside for assembly or maintenance purposes is made considerably easier, while close spatial proximity to the transmission components to be controlled on the underside of the cover is maintained. Thus, testing and setting work can be carried out on the transmission, without the transmission housing having to be opened. Moreover, if required, electrical and electronic and also hydraulic control components (electrically actuated hydraulic valves, measurement and control electronics, etc.) can be combined on the top side of the cover into a structural unit which does not subject the rest of the housing to any restrictions, is not exposed to the rough ambient conditions inside the housing and nevertheless is located near the transmission.
A preferred refinement of the transmission according to the invention is characterized in that the two hydrostats can be adjusted or pivoted by means of the control through the cover, in that a plurality of clutches are provided for controlling the power split, and in that a multistep epicyclic drive is provided for summing the split powers.
Another refinement of the invention is distinguished in that the two hydrostats are in each case pivotable about a pivot axis through at least about +/−45° for controlling the hydraulic power, in that the cover lies essentially in one plane, in that the pivot axes of the hydrostats are arranged perpendicularly to the plane of the cover, in that the control comprises hydraulically actuated lifting pistons which pivot the hydrostats about their pivot axis via a lever mechanism, and in that control hydraulics are provided for controlling the lifting pistons inside the control and are controlled by means of an electric control motor.
Preferably, the hydrostats are arranged with their axes of rotation parallel next to one another and parallel to the plane of the cover, and the inner drive and take-off shafts and the outer drive and take-off shafts have a common axis which is oriented parallel to the axes of rotation of the hydrostats and which is arranged between the axes of rotation of the hydrostats.
One development is characterized in that, overall, two or four clutches are provided, which are assigned in pairs to the hydrostats and are arranged in the axis of rotation of the assigned hydrostat, and in that the multistep epicyclic drive is arranged in the common axis of the inner and outer drive and take-off shafts.
Another development is distinguished in that the hydrostats are mounted pivotably between the cover and a bearing bottom parallel to the cover, which bearing bottom is fastened to the cover via lateral posts standing vertically on the cover, and in that bearing walls which stand vertically on the underside of the cover and are screwed to the bearing bottom are provided for mounting the shafts of the transmission.
According to another refinement of the invention, a lower-lying pan is formed on the housing lower part, and a hydraulic pump is arranged and fastened on the underside of the cover and, when the transmission is in the assembled state, penetrates with an intake connection piece into the pan.
Furthermore, it is conceivable and advantageous that control electronics are provided for the transmission, and that the control electronics are arranged on the top side of the cover.
The other object is achieved by means of the whole of the features of claim 13. It is essential, in this case, that, to achieve a wide continuous adjustment range, the two hydrostats are in each case pivotable about a pivot axis at least in a range of between −45° and +45° for controlling the hydraulic power.
Especially advantageously, this transmission may be provided for a hybrid drive and be coupled to an electric motor.
According to one refinement, in this case, the electric motor is coupled to the inner drive shaft via a transmission.
According to another refinement, the electric motor is arranged directly on the inner drive shaft. In particular, a disk-shaped three-phase machine known per se is suitable for this purpose.
Preferably, the electric motor is connected via control electronics to a battery, from which it obtains energy or into which it can feed energy for storage.
In addition, the electric motor may be capable of being used as a generator and/or starter and/or retarder.
Particularly in the case of vehicles of agricultural use, a second electric motor may be provided, which drives a power take-off shaft, the second electric motor being connected to a battery via second control electronics.
The invention will be explained in more detail below, by means of exemplary embodiments, in conjunction with the drawing in which:
FIG. 1′ shows an illustration, comparable to
The core of the transmission 10 is formed by a multistep epicyclic drive 12 with a large sun wheel Z1 and a small sun wheel Z1′, with the double planet wheels Z2, Z2′, with the ring wheel Z3 and with the planet web 13 connected fixedly in terms of rotation to a gearwheel Z8, and with two hydrostatic axial piston engines or hydrostats H1, H2, the take-off shafts of which, W6 and W12 respectively, can in each case be coupled differently via a pair of clutches K3, K4 and K1, K2, respectively, to the input shaft W1, to the output shaft W7 and to the multistep epicyclic drive 12. The hydrostats H1 and H2, which operate selectively as a pump and as a motor, are connected to one another hydraulically via high-pressure lines, not illustrated. The first hydrostat H1 can be coupled with its take-off shaft W6 to the ring wheel Z3 by means of the clutch K3 via a counter gear consisting of the gear wheel Z5 and of a gear wheel Z4 connected fixedly in terms of rotation to the ring wheel Z3. However, it can also be coupled to the input shaft W1 by means of the clutch K4 via the gearwheel Z11, the intermediate wheel Z12 and the gearwheel Z10 arranged fixedly in terms of rotation on the input shaft W1.
The second hydrostat H2 can be coupled with its take-off shaft W12, on the one hand, to the planet web 13 and consequently to the output shaft W7 by means of the clutch K1 via the hollow shaft W11 and the gearwheel Z9 which is arranged fixedly in terms of rotation on the latter and which meshes with the gearwheel Z8. It can, on the other hand, be coupled to the smaller sun wheel Z1′ of the multistep epicyclic drive 12 by means of the clutch K2 via the pair of gearwheels Z7, Z6 and the hollow shaft W2.
The power prevailing at the input shaft W1 is apportioned in the transmission 10, by the multistep epicyclic drive 12, to two power branches, to be precise to a mechanical power branch and a hydraulic power branch, and is combined again later at the output shaft W7. The mechanical power branch runs from the input shaft W1 via the larger sun wheel Z1 which is connected fixedly in terms of rotation to the input shaft W1, the double planet wheels Z2, the planet web and the gearwheel Z8. The hydraulic power branch runs via the two hydraulically connected hydrostats H1 and H2 and is designed differently, depending on the shifting of the clutches K1, . . . , K4. As indicated in
The shifting of the clutches K1, . . . , K4 and the pivoting position of the hydrostats H1, H2 for the various operating states of the transmission 10 are illustrated in
For the transition from the first driving step to the second driving step (
The graph, obtained for a power-splitting transmission according to
In reverse drive (
In the transmission configuration illustrated in FIG. 1′, the clutches K3 and K4 and the associated shafts W3, W5 and gearwheels Z10, Z11 and Z12 are absent. The driving steps of this transmission 10′ operating with only two clutches K1 and K2 have the same division as shown in
In a transmission of the type illustrated in
A power-splitting transmission implemented according to the transmission diagram from
A (non-restricting) example of such a housing lower part is illustrated in
The transmission 10 of
Essential components for mounting and holding the transmission core 17 on the underside of the cover 14 are a bearing bottom 27 oriented parallel to the cover 14, two lateral posts 26, 26′ emanating vertically downward from the cover 14 and two bearing walls 28, 28′ likewise emanating vertically downward from the cover 14. The bearing bottom 27 delimits the transmission core 17 on the underside. Said bearing bottom is screwed to the posts 26, 26′ and to the bearing walls 28, 28′. The lower pivot bearings 24, 25 for the housings, in each case pivotable about a vertical axis, of the hydrostats H1 and H2 are arranged in the bearing bottom 27. The upper pivot bearings are accommodated in the cover 14 itself, but this cannot be seen. The mutually parallel bearing walls 28, 28′ standing perpendicularly to the three axes of the transmission core 17 serve for mounting the shafts belonging to the axes.
In particular, the shafts W9 and W3 coming from the clutches K1/K2 and K3/K4 are mounted in the front bearing wall 28. The associated bearings are in each case designed as a structural unit with control hydraulics 29 and 30 which are connected to the control on the top side of the cover and actuate the clutches K1, . . . , K4 via axial bores inside the shafts W3 and W9. The oil pressure required for the control hydraulics is generated by a hydraulic pump 22 which sucks in oil, via a downwardly directed intake connection piece 23, out of the oil sump formed in a pan 32 of the housing lower part 31 (
The input shaft or inner drive shaft W1, which is provided with a serration and via which the power from the engine is fed into the transmission by means of an outer drive shaft (40 in
The transmission control necessary for operating the transmission core 17 is accommodated on the top side of the cover 14 so that action upon the transmission induced by the transmission control 16 takes place directly through the cover 14: one type of action is the control of the hydrostats H1 and H2, which, on the one hand, requires a pivoting of the pivot housings through a maximum of +/−45° and, on the other hand, influences the hydraulic connection between the two hydrostats. For this purpose, control hydraulics 20 in the form of control blocks are provided on the cover top side directly above the two hydrostats H1, H2. Each of the two hydrostats H1, H2 is assigned two opposite, hydraulically actuated lifting pistons SK1, SK2 and SK3, SK4, respectively, which pivot the associated hydrostat H2 or H1 via a lever mechanism located in the control block 20. The hydraulic control of the lifting pistons SK1, . . . , SK4 and of the hydraulic connection between the hydrostats H1, H2 is controlled by a rotatable control piston in the control block 20, said control piston being driven by an electric control motor 21. The direct connection between the control block 20 and the hydrostats H1, H2 lying below it achieves an extremely compact set-up which allows easy access to the individual-components of the control from above and at the same time permits high adaptability to the vehicle surroundings on the housing lower part 31.
A compact set-up, good accessibility and short travels also arise due to the arrangement of the control electronics 18 in a box directly on the cover 14. The control electronics 18 evaluate physical measurement variables from the transmission and also commands from the engine control and the operating elements of the vehicle and outputs control commands to the control motor 21 and to hydraulic valves which are arranged around the control electronics 18 on the cover 14 and with the aid of which the clutches K1, . . . , K4 are actuated. For this purpose, the necessary microprocessors and power outputs are accommodated in the control electronics 18. Likewise located on the cover 14 is a closable filling orifice 19 for the oil which is required in the transmission for the hydraulic tasks.
The compact transmission block illustrated in
An appropriate flange 36 is formed on the housing lower part 31 for oil-tight connection to the cover 14. The shafts 39 and 40 are mounted rotatably in the end walls of the housing lower part 31 by means of corresponding bearings 37, 38. Formed in the bottom of the housing lower part 31 is a recessed pan 32 which extends in the longitudinal direction and in which a sump of the hydraulic oil can collect and be sucked in on the transmission core 17 by the hydraulic pump 22. Access orifices 33 which are closable by means of covers and through which access can be had to the inside of the transmission when the latter is closed can be arranged in the side walls of the housing lower part 31.
The transmission according to the invention is distinguished, overall, by the following properties and advantages:
It will appreciated that the transmission 10 and 10′ set up according to
In particular, the continuous regulation of the initial rotational speed, without shift operations and without traction interruption, as is afforded in the transmission concept of
If, by contrast, a hybrid drive with a continuously variable hydrostatic power-splitting transmission according to
The hybrid drive by means of the battery 42 and by the first electric motor E1 affords the possibility of driving and controlling a power take-off shaft W8 according to
In the coupling of the first electric motor E1 to the input shaft W1 via a gearwheel mechanism Z11, Z12, Z13, the type of electric motor E1 can be chosen largely freely, because the electric motor E1 can, for example, be arranged laterally on the transmission, where the overall length pays only a minor role.
However, it is also conceivable, according to the exemplary embodiment shown in
10, 10′ Transmission (continuously variable, hydrostatic, power-split)
11 Internal combustion engine
12 Multistep epicyclic drive
13 Web (multistep epicyclic drive)
14 Cover
15 Flange (cover)
16 Transmission control
17 Transmission core
18 Control electronics
19 Filling orifice
20 Control hydraulics
21 Control motor
22 Hydraulic pump
23 Intake connection piece
24, 25 Pivot bearing
26, 26′ Post
27 Bearing bottom
28, 28′ Bearing wall
29, 30 Control hydraulics (clutches)
31 Housing lower part
32 Pan
33 Access orifice
34, 35 Clutch
36 Flange (housing lower part)
37, 38 Bearing
39 Take-off shaft (outer)
40 Drive shaft (outer)
41, 43 Control electronics
42 Battery (for example, lithium ion)
E1, E2, E3 Electric motor
HL Hydrostatic power fraction (in %)
H1, H2 Hydrostats
K1, . . . , K4 Clutch
SK1, . . . , SK4 Lifting piston
SW Pivot angle (in %)
V Speed
W1, . . . , W12 Shaft
Z1, . . . , Z13 Gearwheel
Number | Date | Country | Kind |
---|---|---|---|
10 2008 008 236.8 | Feb 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/CH2009/000024 | 1/21/2009 | WO | 00 | 7/10/2012 |