AT506456A1 - TRANSFER CASE - Google Patents

Description

The invention relates to a transfer case according to the preamble of claim 1.

Such transmissions are known for example from DE 102004002187 A1. The aim of the invention is to design a transfer case of this type such that the overall spread of a drive train increases and thus better adaptation to different locations of the transmission is possible. Such a transmission should be constructed as space-saving, structurally simple and reliable. Furthermore, the torque distribution and the efficiency of the transmission should be optimally adapted to the requirements of such gear in practice.

These objects are achieved in a transfer case of the type mentioned above with the features mentioned in the characterizing part of claim 1. By dividing the drive forces on the two drive axles in the manner according to the invention, a good adaptation to different types of use is possible due to the achievable axle ratios. In direct gear, for example, lower speeds than in the slow gear are possible without grinding the clutch and on the other hand, higher tractive forces are possible, for example during slow maneuvering or during off-road driving. In the slow gear, however, it is possible to operate the engine at high speeds, especially in highway driving, in an economic speed range. Furthermore, this transfer case has a mechanically stable construction with high durability and resilience.

Advantageously, the features of claims 2, 3 and 4. This makes it possible to arrange in a space-saving manner powershiftable elements, with which the force to be transmitted can be applied quickly to the individual drive axles or changed over these. Claim 5 are apparent alternative and advantageous arrangements for the first clutch. Depending on the arrangement of this coupling is a different blocking of the first planetary gear set.

The claims 6 to 11 relate structurally and power transmission advantageous embodiments of the invention. An advantage for the operation is when the features of claim 12 are met.

Claim 16 is important for the practical embodiment of the transmission according to the invention. This ensures that a torque applied can be divided in the desired manner on the two output axles.

It is also advantageous, if only a partial blocking can be done with the clutches, for which the clutches are not completely closed, whereby at least a partial compensation of speed differences is possible.

In the following the invention will be explained in more detail with reference to the drawing.

Fig. 1 shows the basic structure of a drive train.

Fig. 2a shows a first structure of a transfer case.

Fig. 2b and 2c show alternative embodiments of a structure of a transfer case.

Fig. 3 shows a partial section of a special embodiment of a transfer case in a schematic representation.

Fig. 4 shows schematically the partial section of an alternative embodiment of a transfer case.

FIG. 5 shows a table with numerical values for, for example, embodiments of the two planetary gear sets interconnected according to the invention.

Fig. 6, 7, 8 and 9 show different possibilities for dividing the voltage applied to the transfer case torque on two output axles A, B.

Fig. 1 shows a possible structure of a drive train in which the engine 1 constructed as a longitudinally mounted front engine and the vehicle, in particular motor vehicle, is designed with an all-wheel drive. The transfer case 3 according to the invention can also be used alone or in combination with any drives to divide an applied torque between at least two axes. For example, in a three-axle vehicle, it may also serve to distribute an applied torque between a first and the remaining axle (s). Also torques of output shafts of an electric motor can be distributed.

To the engine 1, e.g. Internal combustion engine, electric motor, a transmission 2 is connected to an inventive transfer case 3 is connected. In itself, the transfer case 3 can also be connected directly to the engine 1. With the transfer case 3 according to the invention, the number of available gears or the different torques received by the transmission 2 or by the engine 1 can be doubled.

From the transfer case 3 according to the invention takes place, usually via a propeller shaft, the drive of an axle B, in particular a rear axle of a vehicle, which may be provided with a differential to which the propeller shaft is connected power transmission. The transfer case 3 further drives an axis A, in particular a front axle, which may also be provided with a differential, wherein the transfer case 3 acts on the axis A via an output shaft 26.

The invention thus relates to a transfer case comprising two planetary gear sets. In Fig. 2a, the transfer case 3 is shown with symbolism according to the VDI Guideline 2157/1978. A circle here symbolizes a planetary gear, the lines going to the circle the waves acting on the planetary gear. That wave of ··· »♦ · · ····

Planetary gear on which the largest torque acts in terms of magnitude is represented by a double dash and referred to as sum shaft, the other two as difference waves. It should be noted that each planetary gear comprises three shafts, namely a sum shaft and two differential shafts. For planetary gearboxes, for balance reasons, the torques at the three shafts must add up to a sum of 0, whereby, of course, friction losses are not taken into account. Thus, in terms of absolute value, as much torque is applied to the sum wave as to the other two waves, that is, the first and the second differential wave together.

The input shaft 4 of the transfer case 3 according to the invention is connected to the sum shaft 15 of a first planetary gear P1. The first differential shaft 16 of the first planetary gear P1 is connected to a shaft 7. The second differential shaft 17 of the first planetary gear P1 is connected to the sum shaft 10 of a second planetary gear set P2. The first differential shaft 18 of the second planetary gear set P2 is connected to a shaft 12, which represents the output to the axis A.

The second differential shaft 14 of the second planetary gear set P2 represents the output to the axis B.

As shown in FIG. 2 a, the input shaft 4 can be interconnected or connected to the shaft 7 or to the differential shaft 16 of the first planetary gear set P1 which is drivingly connected to the shaft 7 via an advantageously controllable clutch 6.

Alternatively, the clutch 6 can also be arranged between the input shaft 4 and differential shaft 17 of the first planetary gear set P1, as shown in FIG. 2c, or between the differential shaft 17 and the differential shaft 16 or the shaft 17 connected to the differential shaft 16, as shown in FIG 2b. In all three arrangement variants of the clutch 6, the clutch takes the planetary gear set P1 a degree of freedom, so that it can rotate with switched clutch 6 only more than block. The shaft 7 and the differential shaft 16 of the first planetary gear set P1 drivingly connected to the shaft 7 can be connected or connected to the shaft 12 and the differential shaft 18 of the second planetary gear set P2 connected to the shaft 12 via an advantageously controllable clutch 13. About an advantageously controllable brake 8, the shaft 7 and the drive with her associated differential shaft 16 of the first planetary gear P1 relative to the housing 9 of the transfer case 3 are at least partially braked, so in the locked case, the shaft 7 and the differential shaft 16 no relative speed relative to the housing 9 of the transfer case 3 have. # · · · · · · · ·

«• β ··

Correspondingly similar conditions exist when the clutches 6 and 13 and the brake 8 are actuated in the embodiments of the transfer case according to FIGS. 2b and 2c.

Conveniently, it is provided that the clutch 6 and / or the clutch 13 and / or the brake 8 are designed as powershiftable elements, preferably as multi-plate clutches or disc brakes, wherein the control of the clutches 6,13 can be integrated into an electronic vehicle dynamics control system.

If the clutch 6 and / or the clutch 13 and the brake 8 are designed as power-shiftable elements, then the shift between direct and smooth action can also be done under load without interruption of traction.

The clutches 6, 13 and the brake 8 can act positively and / or frictionally and / or non-positively.

Between shaft 7 and shaft 12, a freewheel can be arranged parallel to the clutch 13, the switching direction is chosen so that the freewheel then does not switch when driving forward when the shaft 12 rotates faster than the shaft 7. Vorteilerhafterweise can thus be improved in particular the switch-back comfort of Schon- on direct gear, because a freewheel only switches when synchronized.

3 and 4 show schematic representations of the structure and the force profiles of the transfer case 3 shown in Fig. 2a.

A preferred variant is shown in FIG. The first planetary gear P1 is designed as a simple planetary gear, consisting of a sun gear 19, a ring gear 22 and a planet carrier (web) 20 with planetary gears 21 mounted therein, which mesh with both the externally toothed sun gear 19 and the internally toothed ring gear 22. In this case, the planet carrier represents the sum shaft 15 of the first planetary gear P1, the sun gear 19, the differential shaft 16 of the first planetary P1 and the ring gear 22, the differential shaft 17 of the first planetary gear set P1.

The second planetary gear set P2 is designed as a double planetary gear set, consisting of a sun gear 24, a ring gear 23 and a planet carrier (web) 25 with a plurality of Planetenradpaaren 27 mounted therein, wherein in each case one planet of a planet pair with the teeth of the sun 24 and the second planet meshes and the second planet of the planetary pair with the first planet and the teeth of the ring gear 23 is engaged. In this case, the ring gear 23 represents the sum shaft of the second planetary gear P2, the sun gear 24, the differential shaft 18 of the second planetary gear set P2 and the planet carrier, the differential shaft 14 of the second planetary gear set P2. Alternatively, the assignment of the difference waves 14 "t" ··· ·· · ♦♦ »

and 18 to sun gear 24 and planet carrier 25 of the second planetary gear set P2 to be reversed.

Preferably, in the case of a helical gearing, the helix angle of the two ring gears 22, 23 designed so that the resulting axial forces largely compensate and so no special Axiailagerung is provided for receiving the axial thrust of the ring gears. This can result in cost and efficiency benefits.

In this case, the ring gear 23 may preferably be manufactured together with the ring gear 22 from a blank and be used jointly by the two planetary gear sets P1, P2.

Further, the ring gear 23 of the second planetary gear set P2 may be performed with the ring gear 22 of the first planetary gear P1 as a common ring gear with a continuous toothing, whereby the ring gears 22, 23 are integrally formed and each represent a part of the two planetary P1, P2, so only a common ring gear for the two planetary gear sets P1, P2 is provided, which can result in cost advantages. In the case of this design, a separate thrust bearing is also omitted due to the lack of axial thrust.

In principle, it is possible to exchange the assignment of the differential shafts 14, 18 to sun gear 24 and web 25 of the second planetary gear set P2, for example, to assign more torque than the axis B to the axis A.

A second preferred variant is shown in FIG. 4. The first planetary gear set P1 is hereby designed as a simple planetary gear set, consisting of a sun gear 19, a ring gear 22 and a planet carrier (web) 20 with planetary gears 21 mounted therein, which mesh with both the externally toothed sun gear 19 and the internally toothed ring gear 22.

In this case, the planet carrier sets the sum shaft 15 of the first

Planetary gear P1, the sun gear 19, the differential shaft 16 of the first planetary gear P1 and the ring gear 22, the differential shaft 17 of the first planetary gear set P1.

The second planetary gear P2 is formed as a simple planetary gear, also consisting of a sun gear 24, a ring gear 23 and a planet carrier (web) 25 with planetary gears 28 mounted therein, which mesh with both the externally toothed sun gear 24 and the internally toothed ring gear 23.

In this case, the planet carrier 25 sets the sum wave of the second

Planet gear P2, the sun gear 24, the differential shaft 18 of the second planetary gear set P2 and the ring gear (23), the differential shaft 14 of the second planetary gear set P2.

In principle, it is possible to exchange the assignment of the differential shafts 14, 18 to sun gear 24 and ring gear 23 of the second planetary gear set P2, for example, to assign more torque than the axis B to the axis A.

In principle, it is possible to reverse the output to the axis A and the axis B, for example, to assign the axis A more torque than the axis B.

In principle, it is irrelevant which planetary gear for the transfer case 3 according to the invention are used or how they are constructed inside. It is only necessary that different planetary gear sets or differentials corresponding to the specifications according to the invention with respect to total or differential waves are connected or assembled according to properly or the driven sum wave and the abortive differential waves are set accordingly.

It is possible to use different types of differential gears or planetary gear sets for the transfer case 3 according to the invention. It should be noted that the drive takes place on the sum shaft of the respective differential or planetary gear set, ie one hundred percent of the torque is applied to the sum shaft. The output of the distributed torques takes place on the respective two differential shafts, to which thus in sum the same torque is applied as in the sum shaft. It would be conceivable, in particular as a second planetary gear set, to use other planetary gearboxes or differential gearboxes for the transfer case 3 according to the invention, in particular a simple bevel gear differential or a spur gear differential with two sun gears and several planetary gear pairs, as is known, for example from DE 19750834 C1. In principle, any planetary gear could be used. Different designs require different space and / or offer different installation situations and / or offer different efficiency. Furthermore, in some designs, the representable torque distribution and / or the resulting transfer case transmission may result in different degrees in the smooth transition.

Transfer cases, as shown in Fig. 3 and Fig. 4, are space-saving, have a compact, concentrated arrangement of the switching elements, as well as the two planetary gear sets and are also conveniently integrated into an automatic transmission. If the transfer case 3 is to be integrated into an automatic transmission, then a far forward position of these shift elements in the transfer case 3 is advantageous, since then the pressure oil supply is simple, since the corresponding pressure oil of the pressure oil supply of the ········· · ···

Automatic transmission can be removed, and thus the switching elements 6, 13, 8 can be controlled.

Basically, all drives via shafts or sprockets or gears, in particular spur gears or conical or hypoid, done. In the event that the output to the axis A via helical spur gears and the planetary gear set P2 is also helical, the helix angle of the Abtrlebsstimrades can be chosen in particular so that an axial thrust is counteracted from the planetary gear set P2 and so the remaining, to be absorbed by bearings Axial force is lower.

5 shows a representation or a table of functional modes with exemplary data for an embodiment of a transfer case according to FIG. 2 a again, in which, as shown in FIG. 6, the torque of the sum shaft 15 in the ratio 30:70 between the differential shaft 16 and the differential shaft 17 is distributed and the torque of the sum shaft 10 in the ratio 30:70 between the differential shaft 18 and the differential shaft 14 is distributed, in this example, each of the first-mentioned shaft, the smaller proportion (30%) is omitted. The various torques for open and closed or open and closed sliding clutches 6, 13 and brake 8 present on the output axles A, B are listed.

If the first planetary gear set P1 is designed as a simple planetary gear, results in the consumption-relevant deceleration a favorable efficiency, since a simple planetary gear has a relatively high state efficiency and a negative state translation. Due to the negative stand ratio, only part of the power is transmitted as a lossy gear power and the remainder almost lossless as clutch power when the sun is held. In the direct gears, the planetary gear P1 has no or no significant speed differences, so that there is a favorable efficiency even in direct gear. In the second planetary gear set P2 occur in both the direct and the low gear no significant speed differences, so he did not appreciably to

Total power loss contributes.

In the consumption-relevant deceleration of the transfer case 3, the proportion of force transmitted to the drive axle B is relatively high. Because the axle B out, unlike the axis A out, often no additional output with gear stages or a toothed chain is required, a higher proportion of torque flows through the part of the drive train with the better efficiency, thereby improving the overall overall transmission efficiency. 8th

It is advantageous that in the direct gear on the one hand, the normal torque distribution for the drive axles A and B can be selected and on the other hand, another distribution can be selected in which the proportion of transmitted to the drive axle A force is higher. Thus, the distribution of the driving forces can be well adapted to existing conditions, in particular load conditions, driving conditions, etc. The torque distribution can be better adapted to the dynamic axle loads, resulting in particular traction advantages. For an unloaded vehicle with a high proportion of front axle loads, traction advantages are obtained on an icy road with a front-heavy division, since no large accelerations and thus automatically no large dynamic axle load displacements are possible on black ice. In the fully loaded condition with high rear axle load proportion and / or with large dynamic axle load displacement, there are advantages with a rear-heavy division.

By simultaneously switching on the clutches 6 and 13 in the transfer case, it is also possible to lock the transfer case to achieve the best possible traction, resulting in cornering the known tension or forced slippage on the wheels. When using at least one power-shiftable switching element 6, 13, only a partial blockage can be done by one of the two clutches 6 and 13 is completely closed and the other is not completely closed, whereby at least a partial compensation of speed differences is possible.

In particular, if the control of the clutches 6,13 carried out by an electronic vehicle dynamics control system or is integrated into this, it is also possible by actively modifying the power distribution by switching the distribution and / or at least partially blocking the transfer case 3 influence on the handling to take.

By a simultaneous at least partial switching of the brake 8 and at least one of the clutches 6,13 and a vehicle brake can be realized, with which the vehicle can be delayed or held at a standstill.

When using at least one power-shiftable switching element 6, 13, 8, it is also conceivable to provide a starting function. For example, the ride comfort can be increased and / or the thermal load of a dry starting clutch of a manual transmission can be reduced. Powershifting switching elements are usually designed as wet-running multi-plate clutches and are highly thermally stable because the heat generated is dissipated via a cooling oil flow.

Weather it is also conceivable to limit the output torque of the transfer case via at least one power shiftable switching element and thus the drive train before ♦ · · «« · ··· * · ·

extreme overloads due to incorrect operation and / or misuse, such as blasts.

In Figures 6 to 10 different divisions of torques on the output axles A and B are explained with reference to two planetary gear sets, which each split the torque in the ratio 30:70. In Fig. 6, the corresponding schematic diagram is shown. The coupling 6 is arranged in the figures 6 to 10 corresponding to FIG. 2a.

7 shows the distribution of the torque applied to the sum shaft of the first planetary gear set P1 over the two differential shafts of the planetary gear set P1 or over the sum shaft and the differential shafts of the second planetary gear set P2 to the output axles A, B, the clutches 6 and 13 being open and the brake 8 is switched and thus determines the shaft 7 or connects the rotation thereof. Such an embodiment shows the switching state of the transfer case according to the invention for the smooth operation.

Fig. 8 shows a distribution of the torques for the direct gear and that in a first distribution. It can be seen that the clutch 6 is closed and the second clutch 13 is open. Furthermore, the brake 8 is opened. The inevitably with the clutch 6 with the sum of shaft 15 blocked first differential shaft 16 has the same speed as the second differential shaft 17th

Fig. 9 shows the direct gear of the transfer case 3 according to the invention in a second torque distribution. The clutch 6 is open, the second clutch 13 is switched or closed, the brake 8 is open. This results in comparison to Fig. 8, a different torque distribution on the output axles A, B.

Fig. 10 shows a possible circuit of the transfer case 3 according to the invention and although in this illustrated embodiment, the transfer case is longitudinally locked. For this purpose, the clutch 6 is switched as well as the second clutch 13. The brake 8 is open. With this shift, no direct statement can be made about the resulting torque distribution, since due to the effected longitudinal lock, the distribution is mainly determined by the dynamic axle load and the ground.

It is advantageous if a switching element, that is, clutch 6 or clutch 13 or brake 8, is designed such that the switching element can be opened only upon application of a certain minimum pressure or predetermined opening pressure and is closed during shutdown, for example by a spring action. As a result, a further journey is possible even if the control of the switching elements should fail. Furthermore, this prevents a vehicle parked without a parking brake from being able to move independently.

Claims (15)

How the individual shafts acting on each other via force transmission toothed belts, gears or other connection units is not the subject of this invention; Here are the expert all the desired effect performing components available. 1. Transfer case for distributing a drive torque from a driven input shaft (4) on two axes or on two axes drivingly acting output shafts (A, B) using two at least three-shaft differentials or planetary gear sets (P1, P2), wherein the the first planetary gear set (P1) is preferably designed as a simple planetary gear set, wherein the second planetary gear set (P2) is preferably designed as Doppelplanetenradsatz, wherein the input shaft (4) to the sum shaft (15), preferably the web (20), the first planetary gear set (P1 ) is drivingly connected or drivingly connected, wherein the one differential shaft (16) of the first planetary gear set (P1), preferably the sun gear (19), as an output shaft to the first output shaft (A) is force-transmitting or drivingly connected, and wherein the other differential shaft (17) of the first planetary gear set (P1), preferably the ring gear (22), to the sums Shaft (10), preferably the ring gear (23), the second planetary gear set (P2) is connected to transmit power or drive, characterized in that the one differential shaft (18), preferably the sun gear (24), the second planetary gear set (P2) the first output shaft (A) is connected in a force-transmitting or drive-connected manner, and that the other differential shaft (14) of the second planetary gear set (P2), preferably the web (25), is force-transmittingly connected to the second output shaft (B), 2. transfer case according to claim 1, characterized in that at least one, in particular controllable or switchable, clutch (6) is provided, with which the input shaft (4) or the sum shaft (15) of the first planetary gear set (P1) with the one differential shaft (16) of the first planetary gear set (P1) is connectable or blockable. 3. transfer case according to claim 1 or 2, characterized in that at least one second, in particular controllable or switchable, clutch (13) is provided, with which a differential shaft (16) of the first planetary gear set (P1) with the first output shaft (A ) or to the first output shaft (A) leading or driving this shaft (12) is connectable or blockable. 4. Transfer case according to one of claims 1 to 3, characterized in that at least one, in particular controllable, brake (8) is provided, which on the force-transmitting shaft (7) between the first clutch (6) and the second clutch (13). and / or to which a differential shaft (16) of the first planetary gear set (P1) acts and with which the shaft (7) and / or a differential shaft (16) can be braked or locked relative to the transfer case (9). 5. Transfer case according to one of claims 1 to 4, characterized in that the first clutch (6) either between the input shaft (4) or the sum shaft (15) and a differential shaft (16) of the first planetary gear set (P1) or the shaft (7) or between the shaft (7) or the one differential shaft (16) of the first planetary gear set (P1) and the other differential shaft (17) of the first planetary gear set (P1) or the sum shaft (10) of the second planetary gear set (P2), or between the other differential shaft (17) of the first planetary gear set (P1) or the sum shaft (10) of the second planetary gear set (P2) and the input shaft (4) of the first planetary gear set (P1) or the sum shaft (15) of the first planetary gear set (P1) is, wherein preferably in this first planetary gear set (P1) via this first clutch (6) of the web (20) with the sun gear (19) or the sun gear (19) with the ring gear (22) or the ring gear (22) with the web (20) can be connected or faded ockbar are. 6. Transfer case according to one of claims 1 to 5, characterized in that the first planetary gear set (P1) is designed as a simple planetary gear set and / or that the second planetary gear set (P2) is designed as a double planetary gear set. 7. Transfer case according to one of claims 1 to 6, characterized in that the first planetary gear set (P1) has a negative state ratio. 8. Transfer case according to one of claims 1 to 7, characterized in that the sum shaft (10) of the second planetary gear set (P2) to the shaft of the ring gear (23) of this planetary gear set (P2) and to the ring gear (22) of the first planetary gear set (P1) outgoing, other differential shaft (17) is connected via force or driving. * ·· «··» · * · ·· ···· «····· · 9. transfer case according to one of claims 1 to 8, characterized in that the ring gear (23) of the second planetary gear set (P2) with the ring gear (22) of the first planetary gear set (P1) is designed as a common ring gear with a continuous toothing or that this Ring gears (22, 23) are integrally formed and each represent a part of the two planetary gear sets (P1, P2). 10. Transfer case according to one of claims 1 to 9, characterized in that from the web (25) of the second planetary gear set (P2) the other differential shaft (14) goes off, which is connected to the second output shaft (B), wherein the sun (24) of the second planetary gear system (P2) outgoing a differential shaft (18) with the shaft (12) is force-transmitting or drivingly connected, which represents the output (26) to the first output shaft (A). 11. Transfer case according to one of claims 1 to 10, characterized in that the outputs (14, 26) to the output shafts (A, B) are realized in the form of toothed chains or gears. 12. Transfer case according to one of claims 1 to 11, characterized in that the coupling (6) and / or the further clutch (13) and / or the brake (8) as controlled or load-shiftable elements, preferably as multi-plate clutches or multi-disc brake , are executed. 13. transfer case according to one of claims 1 to 12, characterized in that by default or choice of the helix angle of the ring gears (22, 23) of the two Planetenradsysteme (P1, P2), the resulting axial forces on the ring gears (22,23) are repealed , 14. Transfer case according to one of claims 1 to 13, characterized in that the clutch (6) and / or the clutch (13) are each partially closable or partially engageable in engagement position, so in this position by the resulting slip compensation of speed differences is possible. 15. transfer case according to one of claims 1 to 14, characterized in that the control of the clutches (6,13) is integrated in an electronic vehicle dynamics control system.