WO2020164870A1 - Hybrid drive device - Google Patents

Abstract

The invention relates to a hybrid drive device comprising an internal combustion engine (11), an electric motor (12), a four-shaft planetary gear system (13) having a first shaft (W1), a second shaft (W2), a third shaft (W3) and a fourth shaft (W4), the hybrid drive device also comprising two spur gear sub-transmissions (14, 15), namely a first spur gear sub-transmission (14) and a second spur gear sub-transmission (15), which have three shiftable gearwheel pairs (Z1, Z2, Z3) and three shifting units (S1, S2, S3), and the hybrid drive device also comprising at least one output shaft (W5). The internal combustion engine (11) is connected to the first shaft (W1), the electric motor (12) is connected to the second shaft (W2), the first spur gear sub-transmission (14) is connected to the third shaft (W3), and second spur gear sub-transmission (15) is connected to the fourth shaft (W4). The four-shaft planetary gear system (13) has a blocking shifting unit (VK). Two shifting units (S1, S2) of the shifting units (S1, S2, S3) are designed as claw couplings, and one shifting unit (S3) of the shifting units (S1, S2, S3) is designed as a multiple-disc clutch. The shifting unit (S3) designed as a multiple-disc clutch is assigned to that gearwheel pair of the at least three gearwheel pairs (Z3) which is provided in order to be shifted to a first split-power gear (G4) in the event of an upshift. The first split-power gear (G4) has a lower electric motor total gear ratio than the electric motor total gear ratio of the next smaller non-split-power gear (G3), and the electric motor total gear ratio results from a transmission starting from the electric motor (12) via the planetary gear system (13) and further via the first and/or second spur gear sub-transmission(s) (14, 15) to the output shaft (W5).

Description

Hybrid drive device

The invention relates to a hybrid drive device.

DE 10 2010 053 757 A1 already discloses a hybrid drive device with an internal combustion engine, with an electric machine, with a planetary gear train that has a first shaft, a second shaft, a third shaft and a fourth shaft, with two spur gear sub-transmissions, namely one first spur gear and a second spur gear, which have at least three switchable gear pairs and at least three switching units, and with at least one output shaft, the internal combustion engine being connected to the first shaft, the electrical machine being connected to the second shaft, the first spur gear on the third shaft is connected, wherein the second spur gear is connected to the fourth shaft, the four-shaft planetary gear one

Having interlocking switching unit, two switching units of the switching units being designed as claw clutches.

Furthermore, from the generic DE 10 2017 006 082 A1 is a

Hybrid drive device known, in addition, one of the switching units of the spur gear sub-transmission is designed as a multi-disc clutch.

The invention is based in particular on the object of providing an advantageously compact, advantageously power-shiftable hybrid drive device. It is achieved by an embodiment according to the invention in accordance with claim 1. Further developments of the invention emerge from the dependent claims.

The invention is based on a hybrid drive device with a

Internal combustion engine, with an electric machine, with a four-shaft

Planetary gear, which has a first shaft, a second shaft, a third shaft and a fourth shaft, with two spur gear sub-transmissions, namely a first Spur gear sub-gear and a second spur gear sub-gear, which in particular have at least three switchable gear wheel pairs and, in particular at least, three switching units, and with at least one output shaft, the internal combustion engine being connected to the first shaft, the electrical machine being connected to the second shaft, wherein the first spur gear sub-gear is connected to the third shaft, the second spur gear sub-gear being connected to the fourth shaft, the four-shaft planetary gear having an interlocking switching unit, in particular at least two switching units of the switching units being designed as dog clutches.

It is further assumed that, in particular, at least one switching unit of the switching units is designed as a multi-plate clutch.

According to the invention it is provided that the multi-plate clutch is designed

Shift unit is assigned to that of the at least three gear wheel pairs which is intended to be engaged in an upshift to a power-split gear stage, and the power-split gear stage has a lower overall electric machine ratio than the total electric machine ratio of the next smaller non-power split gear Gear stage, whereby the overall electric machine ratio is derived from a ratio based on the electric machine, via the planetary gear and further via the first and / or second

Spur gear part transmission results in the output shaft. The spur gear sub-transmissions preferably have at least three shift units, in particular precisely one shift unit being designed as a multi-disc clutch when there are exactly three shift units. At least two gear pairs, in particular exactly two gear pairs, the first spur gear sub-transmission, at least one gear pair, in particular at least two gear pairs, preferably precisely two

Gear pairs, assigned to the second spur gear sub-transmission. Preferably, at least two shift units, in particular exactly two shift units, the first spur gear part transmission, are at least one shift unit, in particular at least two

Switching units, preferably exactly two switching units, assigned to the second spur gear sub-transmission. With exactly three switching units, exactly two switching units are preferably designed as a claw clutch. As a result, a particularly reliable

Power shiftability of the transmission of the hybrid drive device can be achieved with two power paths. The power shiftability of a power-split transmission with two power paths and a frictional shifting element in the power-split planetary gear is only possible when the power paths are changed. Through the embodiment according to the invention, in particular, both changes in the power paths are possible in a load-switching manner. At the same time, additional shafts in particular can be dispensed with, which means that costs and installation space can be kept low. In particular, continuous load switching can be achieved. The

Planetary gear is provided in particular to drive torque of the

Combine the internal combustion engine and the electrical machine and transmit it as a common drive torque to a gear unit. The planetary gear train preferably comprises at least one planetary gear set. The first

Spur gear sub-transmission and the second spur gear sub-transmission are each preferably provided for shifting defined direct gears, with a gear change between the spur gear sub-transmissions. Power-split gear steps, which each form intermediate gears, are preferably switched between the direct gears. In particular, the direct aisles are not

power split.

The condition that determines which of the switching units must be designed as a multi-plate clutch depends on the gear ratios. It arises due to the condition that at least one of at least three switching units as

Multi-disc clutch must be designed. With more than three switchable

Gear pairs, in particular, the fifth gear pair at the latest is again provided with a switching unit designed as a multi-plate clutch. However, it would also be conceivable that the fourth gear wheel pairing is again provided with a switching unit designed as a multi-plate clutch. The condition here again corresponds to that of the first multi-plate clutch.

The design of the shift unit as a multi-plate clutch is particularly useful for shifting from a non-power-split gear stage, such as one of the gears G1, G3, G5 and G7, with an overall electric machine ratio IEM.G, into a next higher, power-split gear stage with a Total electric machine ratio IEM, G + I, which is lower than the total electric machine ratio IEM, G. This means in particular that the multi-plate clutch for

IEM, G + I <IEM, G is necessary for G {1, 3, 5}. Two cases in particular are possible for this, in which a gear stage that is not power-split is switched on both the first spur gear sub-transmission and the second spur gear sub-transmission before a corresponding shifting process can be. If the non-power-split gear is on the first

This applies if

where 1 _{02 is} a gear ratio of a second planetary gear set of the

Planetary gear, U corresponds to a gear ratio of the first

Spur gear part transmission corresponds and i _ß a gear ratio of the second

Spur gear part gear corresponds. If the non-power-split gear is on the second spur gear, this applies if

This results in particular from the fact that, in the direct gears, a current overall electric machine ratio I _EM corresponds to an overall internal combustion engine ratio I _VM , which is the gear ratio of the currently shifted gear

Spur gear times a possible axle ratio. In contrast, an overall internal combustion engine ratio I _VM corresponds to the power-split gears i-VM - oi i-EM + (1 ^ 01) ^ 4] i-FD> where ioi is a gear ratio of a first planetary gear stage des

Planetary gear and I _FD corresponds to a gear ratio of a possible axle drive. An overall electric machine ratio I _EM corresponds to the power-split gears

The interlocking switching unit of the planetary gear can have various arrangements and / or configurations that appear sensible to a person skilled in the art. The interlocking switching unit can in particular be arranged between any two of those four gear elements of the planetary gear that are not already connected to one another in a rotationally fixed manner. The interlocking switching unit is formed in particular by a dog clutch. A “planetary gear set” is intended to mean in particular a unit with a sun gear, a ring gear and at least a planet gear guided by a planet gear carrier on a circular path around the sun gear. The planetary gear set advantageously has exactly one stationary transmission ratio. A “switching unit” is to be understood as meaning, in particular, a unit with exactly two coupling elements, which is provided to connect two gear elements rotatably mounted to one another, such as an idler gear and a gear output shaft or an idler gear and a gear input shaft or adjacent idler gears of different gear levels, in a switchable and rotationally fixed manner . Two adjacent, in particular axially adjacent, switching units can basically be combined to form a common double switching unit by, for example, a common coupling element for both

Switching units is provided. Each of the switching units can basically be used as a purely form-fitting switching unit, for example as a claw clutch, as a form-fitting and frictional switching unit, for example in the form of a synchronized one

Claw clutch, or as a purely frictional switching unit, for example in the form of a multi-disc clutch. “Provided” is to be understood in particular as specifically designed and / or equipped. The fact that an object is provided for a specific function is to be understood in particular to mean that the object can perform this specific function in at least one application and / or

Operational condition fulfilled and / or executed.

In this context, what is meant by an “overall e-machine ratio”

In particular, a transmission ratio between the electrical machine and the drive shaft can be understood, with the overall transmission resulting in particular from the electrical machine, via the planetary gear and further via the first and / or second spur gear sub-gear to the output shaft. One the

The power flow defining the overall transmission ratio can lead via the first spur gear sub-transmission, via the second spur gear sub-transmission or, in the case of power-split gear stages, via both spur gear sub-transmissions simultaneously. Under one

In this context, “power-split gear stage” is to be understood in particular as a gear stage in which torque is transmitted from the planetary gear to the output shaft, both partially from the first spur gear sub-gear and partially from the second spur gear sub-gear. Preferably is in one

power-split gear stage and at least one switching unit of the first

Spur gear part transmission and a switching unit of the second spur gear part transmission closed. Furthermore, in this context, a “next smaller non-power-split gear step” is intended to mean, in particular, a non-power-split gear step in a planned gear sequence from a lowest gear step, such as in particular a gear G1, in a highest gear step, comes directly before the corresponding gear step, in particular a power-split gear step. The next smaller non-power-split gear stage is preferably followed directly by the corresponding power-split gear stage in the gear sequence provided.

In this context, “non-rotatably connected” is to be understood as meaning, in particular, a connection between two, in particular rotatably mounted, elements and / or assemblies in which the two elements and / or assemblies are arranged coaxially with one another and are connected to one another in such a way that they are identical

Rotate angular velocity. Furthermore, in this context, a “multi-disk clutch” is to be understood in particular as a friction-locking clutch which has at least one first disk carrier with at least one disk and at least one second disk carrier with at least two disks. The at least one lamella of the first lamellar carrier is preferably arranged at least partially between the at least two lamellae of the second lamellar carrier.

It is also proposed that the two spur gear sub-transmissions have a fourth gear pair and a fourth shift unit, which is designed as a dog clutch and which is assigned to the fourth gear pair, the fourth gear pair being provided to be switched on during an upshift to a second power-split gear stage and wherein the second power-split gear stage has a larger overall electric machine ratio than the total electric machine ratio of the next smaller non-power-split gear stage. The fourth gear pair and the fourth switching unit are preferably assigned to the second spur gear sub-transmission. In this way, power shiftability between defined gear steps can be achieved in a particularly advantageous manner. In particular, an advantageously simple and reliable switching unit can be provided.

It is also proposed that the two spur gear sub-gears have a further

Gear pairing and a further switching unit which is designed as a multi-disc clutch and which is assigned to the further gear wheel pairing, the further gear wheel pairing being intended to be switched on during an upshift to a further power-split gear stage and the further power-split gear stage being a lower electric machine -Overall gear ratio than the total electric machine ratio of the next smaller one

power-split gear. In particular, each switching unit is one

Gear pairing is assigned, which is provided for an upshift to to be engaged in a further power-split gear stage and the further power-split gear stage having a lower overall electric machine ratio than the electric machine total ratio of the next smaller one

power split gear, designed as a multi-plate clutch. As a result, both changes in the power paths are possible in a power-shifting manner. In particular, a power shift can be achieved between a non-power-split gear stage in a higher power-split gear stage in which an overall electric machine ratio of the non-power-split gear stage is greater than an overall electric machine ratio of the power-split gear stage. It can

in particular, consistent load switching can be achieved.

It is further proposed that the four-shaft planetary gear set has a first planetary gear set and a second planetary gear set each with three gear elements, the third gear element of the first planetary gear set being non-rotatably connected to the third gear element of the second planetary gear set and the second gear element of the first planetary gear set non-rotatably connected to the second

Gear element of the second planetary gear set is connected. Preferably, the first planetary gear set and / or the second planetary gear set is as a

Simple planetary gear set. In particular, both planetary gear sets are designed as single planetary gear sets. The planetary gear transmission preferably has exactly two planetary gear sets. A shaft to which the electric machine is connected preferably connects a transmission element of the first planetary gear set and a transmission element of the second planetary gear set in a rotationally fixed manner. Preferably, one of the two spur gear sub-gears is connected to another shaft of the planetary gear, which is another gear element of the first planetary gear set and another

Gear element of the second planetary gear set rotatably connects to one another. In this way, in particular, a planetary gear transmission that can advantageously be locked can be provided. Advantageously, an advantageous power split can thereby also be achieved.

It is also proposed that the electrical machine is non-rotatably connected to the third gear elements of the planetary gear and the first spur gear sub-gear is non-rotatably connected to the second gear elements of the planetary gear or the electrical machine is non-rotatably connected to the second gear elements of the

Planetary gear and the first spur gear sub-gear rotatably with the third

Gear elements of the planetary gear is connected. The electrical machine preferably has a rotor, which rotatably with the third gear elements of the planetary gear is connected, and wherein the first spur gear part gear is rotatably connected to the second gear elements of the planetary gear. Alternatively, the rotor of the electrical machine can, in particular, rotate with the second

Gear elements of the planetary gear and the first spur gear sub-gear rotatably be connected to the third gear elements of the planetary gear. In particular, an advantageous connection of the electrical machine can be achieved in this way.

It is also proposed that the first transmission elements of the

Planetary gear each as a sun gear, the second gear elements of the

Planetary gear are each designed as a planetary gear carrier and the third gear elements of the planetary gear are each designed as ring gears. The first gear element of the first planetary gear set is preferably a sun gear, the second

Transmission element of the first planetary gear set as a planetary gear carrier, the third

Gear element of the first planetary gear set as ring gears, the first gear element of the second planetary gear set as a sun gear, the second gear element of the second planetary gear set as a planetary gear carrier and the third gear element of the second planetary gear set as ring gears. This can in particular a

advantageous planetary gear are provided.

It is also proposed that the electrical machine rotatably with the designed as a ring gear third gear elements of the planetary gear, the

Combustion engine rotatably with the first designed as a sun gear

Gear element of the first planetary gear set, the first spur gear sub-gear rotatably with the second gear elements designed as planetary gear carriers of the

Planetary gear and the second spur gear sub-gear is non-rotatably designed as a sun gear with the first gear element of the second planetary gear set. A rotor of the electrical machine is preferably rotationally fixed to the third gear elements of the planetary gear, which are designed as a ring gear. The internal combustion engine preferably has a crankshaft which is designed to be non-rotatable with the first gear element of the first planetary gear set, which is designed as a sun gear.

The terms “axial” and “radial” are particularly related to a main axis of rotation of the transmission, in particular the input shafts, so that the term “axial” in particular denotes a direction that is parallel or coaxial to the

Main axis of rotation runs. Furthermore, the term “radial” denotes in particular one Direction perpendicular to the main axis of rotation. Under one

“Arrangement on the transmission input side” should be understood in particular to mean that the component mentioned is arranged on a side of the further component which faces the transmission input element and / or the internal combustion engine. A “gearbox output-side arrangement” is to be understood in particular to mean that the component mentioned is arranged on a side of the further component which faces away from the transmission input element and / or the internal combustion engine, even if the further component is arranged in the axial direction after the transmission output element.

Further advantages emerge from the following description of the figures. An exemplary embodiment of the invention is shown in the figures. The figures, the description of the figures and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into useful further combinations.

Show:

1 shows the hybrid drive device according to the invention with a

Internal combustion engine, with an electric machine, with a

Planetary gear and with two spur gear sub-gears in a schematic representation and

2 shows a switching table of the hybrid drive device according to the invention.

FIG. 1 shows schematically a hybrid drive device 10

Hybrid drive device 10 is for a motor vehicle. The hybrid drive device 10 is for a hybrid automobile. The hybrid drive device 10 has a

Internal combustion engine 11 on. The hybrid drive device 10 also has an electric machine 12. The electric machine 12 is arranged on a side of the hybrid drive device 10 facing the internal combustion engine 11.

The electric machine 12 is provided in addition to the internal combustion engine 11 for generating a further drive torque. The electric machine 12 forms one

Electric motor off. It would also be possible to use a hydraulic or pneumatic drive unit with a correspondingly assigned drive unit instead of the electric machine 12

Provide energy storage. The electrical machine 12 is provided to either convert electrical energy into mechanical energy or to convert it into mechanical energy to convert mechanical energy into electrical energy. For this purpose, the electrical machine 12 has a stator 17 and a rotor 16. The stator 17 is firmly connected to a body of the motor vehicle. The rotor 16 is arranged to be rotatable relative to the stator 17. To provide and store the electrical energy, the motor vehicle has a rechargeable battery device, not shown in detail. The battery device is provided to provide electrical energy to drive the electrical machine 12 and to store electrical energy that is generated by the internal combustion engine 11 or fed in from an external power supply.

The hybrid drive device 10 also has a multi-stage transmission. The

Hybrid drive device 10 has a planetary gear transmission 13. The

Planetary gear 13 is used to transmit torque from internal combustion engine 11 and / or from electrical machine 12 to an output

Hybrid drive device 10 is provided. The planetary gear 13 is formed by a four-shaft planetary gear 13. The planetary gear transmission 13 has a first shaft W1, a second shaft W2, a third shaft W3 and a fourth shaft W4. Furthermore, the planetary gear transmission 13 has two planetary gear sets P1, P2. The

Planetary gear 13 has a first planetary gear set P1 and a second

Planetary gear set P2 on. The first planetary gear set P1 is of one

Simple planetary gear set formed. The second planetary gear set P2 is of one

Simple planetary gear set formed. The first planetary gear set P1 has three

Gear elements P11, P12, P13. The second planetary gear set P2 has three

Gear elements P21, P22, P23. The first gear elements P11, P21 of the

Planetary gear 13 are each designed as a sun gear, the second gear elements P12, P22 of the planetary gear 13 are each designed as a planetary gear carrier and the third gear elements P13, P23 of the planetary gear 13 are each designed as ring gears. The third gear element P13 of the first planetary gear set P1 is non-rotatably connected to the third gear element P23 of the second planetary gear set P2 and the second gear element P12 of the first planetary gear set P1 is non-rotatably connected to the second gear element P22 of the second planetary gear set P2. Furthermore, the third transmission element P13 of the first planetary gear set are P1 and the third

Transmission element P23 of the second planetary gear set P2 is permanently coupled to the rotor 16 of the electrical machine 12 in a rotationally fixed manner. The electrical machine 12 is connected directly to the planetary gear transmission 13. The electric machine 12 is connected in a rotationally fixed manner to the third gear elements P13, P23 of the planetary gear mechanism 13. The electrical machine 12 is non-rotatable with the third, designed as a ring gear

Gear elements P13, P23 of the planetary gear 13 connected. The electric Machine 12 is connected to the second shaft W2. The electric machine 12 is connected to the third transmission element P13 of the first via the second shaft W2

Planetary gear set P1 and to the third transmission element P23 of the second

Planetary gear set P2 connected.

In general, it is particularly advantageous that the electric machine 12 is connected to a shaft of the four-shaft planetary gear train 13 which rotates one of the gear elements P11, P12, P13 of the first planetary gear set P1 and one of the gear elements P21, P22, P23 of the second planetary gear set P2 together connects.

The planetary gear mechanism 13 is advantageously arranged radially inside the rotor 16 of the electrical machine 12. The planetary gear transmission 13 is arranged radially inside the electrical machine 12.

The planetary gear mechanism 13 is also advantageously arranged so as to overlap axially with the electrical machine 12.

Furthermore, the four-shaft planetary gear transmission 13 has an interlocking switching unit VK. The interlocking switching unit VK is provided for interlocking the planetary gear transmission 13. The interlocking switching unit VK is provided for interlocking the first planetary gear set P1 and the second planetary gear set P2.

Furthermore, the internal combustion engine 11 is connected to the planetary gear transmission 13, in particular via a disconnect clutch. The internal combustion engine 11 is connected to the first shaft W1. The internal combustion engine 11 is designed to be non-rotatably connected to the first gear element P11 of the first planetary gear set P1, which is designed as a sun gear.

The hybrid drive device 10 also has two spur gear sub-transmissions 14, 15. The hybrid drive device 10 has a first partial spur gear 14 and a second partial spur gear 15. The first spur gear part 14 and the second

Spur gear sub-transmissions 15 can be shifted parallel to one another in a power flow. The first spur gear sub-gear 14 and the second spur gear sub-gear 15 are directly connected to the

Planetary gear 13 connected. The second partial spur gear 15 is arranged in front of the first partial spur gear 14 in an axial direction. The two

Spur gear part transmissions 14, 15 have three switchable gear wheel pairs Z1, Z2, Z3 and one fourth gear pair Z4 and three switching units S1, S2, S3 and a fourth

Switching unit S4 on. The two spur gear sub-gears 14, 15 have four switchable

Gear pairs Z1, Z2, Z3, Z4 and four switching units S1, S2, S3, S4. The gear pairs Z1, Z2, Z3, Z4 can be switched via one of the switching units S1, S2, S3, S4. The gear pairs Z1, Z2, Z3, Z4 are each arranged in a gear plane. The gear pairs Z1, Z2, Z3, Z4 are different

Gear planes arranged. Two gear wheel pairs Z1, Z3 of the gear wheel pairs Z1, Z2, Z3, Z4 and two switching units S1, S3 of the switching units S1, S2, S3, S4 are assigned to the first spur gear part 14. Two gear pairs Z2, Z4 the

Gear pairs Z1, Z2, Z3, Z4 and two shift units S2, S4 of the shift units S1, S2, S3, S4 are assigned to the second spur gear part 15. The

Gear pairs Z1, Z2, Z3, Z4 each have a fixed gear, namely a first fixed gear Z11, a second fixed gear Z21, a third fixed gear Z31 and a fourth fixed gear Z41 and one idler gear each, namely a first idler gear Z12 and a second idler gear Z22 third idler gear Z32 and a fourth idler gear Z42.

In the exemplary embodiment, the respective fixed gear Z11, Z21, Z31, Z41 of the gear wheel pairs Z1, Z2, Z3, Z4 forms an input side of the respective gear wheel pairing Z1, Z2, Z3, Z4, while the respective idler gear Z12, Z22, Z32, Z42 of the gear wheel pairings Z1 , Z2, Z3, Z4 each form an output side of the respective gear pair Z1, Z2, Z3, Z4. The fixed gears Z11, Z21, Z31, Z41 of the gear wheel pairs Z1, Z2, Z3, Z4 mesh with the corresponding idler gear Z12, Z22, Z32, Z42 of the

Gear pairs Z1, Z2, Z3, Z4.

The first spur gear sub-gear 14 has different gear ratios. The first spur gear sub-gear 14 is embodied in a rotationally fixed manner with the first gear element P21, which is embodied as a sun gear, of the second planetary gear set P2. The first

Spur gear part transmission 14 is connected to the third shaft W3. The first

Spur gear sub-gear 14 is connected via the third shaft W3 to the first gear element P21, which is designed as a sun gear, of the second planetary gear set P2. The two fixed gears Z11, Z31 of the first gear pair Z1 and the third gear pair Z3 of the first spur gear sub-gear 14 are rotatably connected to the third shaft W3. The drive torque is introduced into the first partial spur gear 14 via the third shaft W3. The second spur gear part 15 has different

Gear ratios on. The second spur gear sub-gear 15 is connected non-rotatably to the second gear elements P12, P22 of the planetary gear 13. The second spur gear sub-gear 15 is non-rotatable with the planetary gear carrier second gear elements P12, P22 of the planetary gear 13 connected. The second spur gear sub-transmission 15 is connected to the fourth shaft W4. The second spur gear part 15 is via the fourth shaft W4 to the as

Planetary gear carrier formed second gear elements P12, P22 des

Planetary gear 13 connected. Furthermore, the fourth shaft W4 connects the second gear elements P12, P22 of the planetary gear transmission 13. The two fixed gears Z21, Z41 of the second gear pair Z2 and the fourth gear pair Z4 of the second

Spur gear transmission 15 are rotatably connected to the fourth shaft W4. The

The drive torque is introduced into the second spur gear part 15 via the fourth shaft W4. In principle, however, it would also be conceivable that the electrical machine 12 is connected to the second gear elements P12, P22 of the planetary gear 13 and the second spur gear part 15 to the third gear elements P13, P23 of the planetary gear 13.

A drive force of the

Internal combustion engine 11 and / or the electrical machine 12 of the

Planetary gear transmission 13 is transmitted via the third shaft W3 to the first spur gear sub-gear 14 and / or via the fourth shaft W4 to the second spur gear sub-gear 15. From the first spur gear sub-gear 14 and / or the second spur gear sub-gear 15, the drive force is in turn transmitted to drive wheels of the motor vehicle via an axle gear which is not further visible. The axle drive can, for example, from a

Be formed differential. The hybrid drive device 10 includes the axle drive.

The hybrid drive device 10 also has an output shaft W5. The

Output shaft W5 is, preferably through exactly one spur gear pairing, with the

Axle drive coupled. Furthermore, idler gears Z12, Z22, Z32, Z42 are the

Gear pairs Z1, Z2, Z3, Z4 each rotatably mounted on the output shaft W5. The first spur gear part transmission 14 has a first fixed gear Z11 of the third shaft W3 and a first idler gear Z12 of the output shaft W5, which mesh with one another. The first spur gear sub-gear 14 also has the second fixed gear Z21 of the third shaft W3 and the second idler gear Z22 of the output shaft W5, which mesh with one another. Furthermore, the second spur gear sub-gear 15 has the third fixed gear Z31 of the fourth shaft W4 and the third idler gear Z32 of the output shaft W5, which mesh with one another. Furthermore, the second spur gear sub-gear 15 has the fourth fixed gear Z41 of the fourth shaft W4 and the fourth idler gear Z42 of the output shaft W5, which mesh with one another. To shift the various transmission gears, the spur gear sub-transmissions 14, 15 of the hybrid drive device 10 have a plurality of shift units S1, S2, S3, S4. The hybrid drive device 10 has, for example, four switching units S1, S2, S3, S4. At least two switching units S1, S2, S4 of the switching units S1, S2, S3, S4 are designed as claw clutches. Three switching units S1, S2, S4 of the switching units S1, S2, S3, S4 are designed as claw clutches. At least one switching unit S3 of the switching units S1, S2, S3, S4 is designed as a multi-plate clutch. A

Switching unit S3 of switching units S1, S2, S3, S4 is designed as a multi-plate clutch.

The first spur gear part transmission 14 has a first shift unit S1 of the four shift units S1, S2, S3, S4. The first switching unit S1 is assigned to the output shaft W5. The first switching unit S1 is formed by a dog clutch. In principle, however, another training that appears to be useful to a person skilled in the art would also be

Switching unit S1 conceivable. The first switching unit S1 is provided to connect the first idler gear Z12 of the first gear pair Z1 to the output shaft W5 in a rotationally fixed manner. The first switching unit S1 is provided to connect the first idler gear Z12 of the first gear wheel pair Z1 in a rotationally fixed manner to the actual shaft of the output shaft W5. In a closed state, the first switching unit S1 connects the first idler gear Z12 of the first gear wheel pair Z1 in a rotationally fixed manner to the actual shaft of the output shaft W5.

The second spur gear sub-transmission 15 has a second shift unit S2 of the four

Switching units S1, S2, S3, S4. The second switching unit S2 is assigned to the output shaft W5. The second switching unit S2 is formed by a dog clutch.

In principle, however, another embodiment of the switching unit S2 that appears sensible to a person skilled in the art would also be conceivable. The second switching unit S2 is for this

provided to connect the second idler gear Z22 of the second gear pair Z2 in a rotationally fixed manner to the output shaft W5. The second switching unit S2 is provided to connect the second idler gear Z22 of the second gear wheel pair Z2 in a rotationally fixed manner to the actual shaft of the output shaft W5. In a closed state, the second switching unit S2 connects the second idler gear Z22 of the second gear wheel pair Z2 in a rotationally fixed manner to the actual shaft of the output shaft W5.

The first spur gear sub-transmission 14 has a third shift unit S3 of the four shift units S1, S2, S3, S4. The third switching unit S3 is assigned to the output shaft W5. The third switching unit S3 is formed by a multi-plate clutch. As a multi-disc clutch trained switching unit S3 is that of the gear pair Z3

Gear pairs Z1, Z2, Z3, Z4 assigned, which is provided for an upshift to a second power-split gear stage G4, which in

Embodiment is formed by the fourth gear stage G4 to be engaged, the second power-split gear stage G4 has a lower total electric machine ratio than the total electric machine ratio of the next smaller non-power-split gear stage G3. The overall gear ratio for the electric machine results from a ratio starting from the electric machine 12, via the planetary gear 13 and further via the first and / or second partial spur gear 14, 15 to the output shaft W5. The switching units S1, S2, S3, S4 are always designed as a multi-plate clutch when you need to shift from a non-power-split gear stage, such as one of the forward gears G1, G3, G5 and G7, with an overall electric machine ratio, in a next higher, power-split gear with an overall electric machine ratio that is lower than the total electric machine ratio must be engaged. The third switching unit S3 is provided in this embodiment for this purpose, the third idler gear Z32 the third

To connect gear pairing Z3 to the output shaft W5 in a rotationally fixed manner. The third

Switching unit S3 is provided to connect the third idler gear Z32 of the third gear wheel pair Z3 in a rotationally fixed manner to the actual shaft of the output shaft W5. In a closed state, the third switching unit S3 connects the third idler gear Z32 of the third gear wheel pair Z3 in a rotationally fixed manner to the actual shaft of the output shaft W5.

The selection of the arrangement of the multi-plate clutch results from this

Embodiment in particular from a quotient of the angular velocity ww2 _{, block of} the second shaft W2 in a non-power-split gear stage divided by the angular velocity oow2, spiit of the second shaft W2 in a next higher, power-split gear stage. A distinction can be made here between two cases, namely from one gear stage of the first spur gear part 14 to one

Power-split gear stage can be switched or it can be switched from a gear stage of the second spur gear part 15 to a power-split gear stage. Based on a gear stage of the first spur gear sub-transmission 14, the quotient results as follows

where U is the gear ratio of the corresponding gear pair Z1, Z3 of the first spur gear sub-gear 14, oows the angular speed of the output shaft W5 corresponds to the gear ratio of the second planetary gear stage of the

Planetary gear 13 and _ß the gear ratio of the corresponding gear pair Z2, Z4 of the second spur gear part 15 corresponds. If the quotient Q is less than one, a load shift is possible using a dog clutch. If the quotient Q is greater than one, a multi-plate clutch is connected to the connected

Gear pairing Z2, Z4 of the second spur gear part 15 is necessary. Based on a gear stage of the second spur gear part 15, the quotient results as follows

If the quotient Q is less than one, a load shift is possible using a dog clutch. If the quotient Q is greater than one, there is a multi-plate clutch on the

activated gear pair Z1, Z3 of the first spur gear part 14 is necessary. A design of the third switching unit S3 as a multi-plate clutch was selected accordingly.

In the exemplary embodiment of FIG. 1, exactly one output shaft, namely the output shaft W5, is shown. The hybrid drive device 10 can, however, also have two output shafts, which are advantageously coupled to the axle drive via a respective spur gear stage. In this non-illustrated case, for example, the first idler gear Z12 and the second idler gear Z22 would be arranged coaxially to one of the two output shafts, and the third idler gear Z32 and the fourth idler gear Z42 would be arranged coaxially to the other of the two output shafts.

In the event that the hybrid drive device 10 has two output shafts with shiftable idler gears Z12, Z22, Z32, Z42 arranged coaxially with the output shafts, the third shift unit S3, designed as a multi-plate clutch, is arranged coaxially with one of the two output shafts. According to the criteria mentioned above, it is also decided to which of the gear wheel pairs Z1, Z2, Z3, Z4 the third shift unit S3 designed as a multi-plate clutch is assigned. The hybrid drive device 10 advantageously has a maximum of two output shafts, the third switching unit, designed as a multi-plate clutch, advantageously being arranged coaxially with one of these two output shafts. The advantageous arrangement of the third shift unit S3, which is designed as a multi-plate clutch, allows a third countershaft (in addition to the maximum of two

Output shafts), which would have to be introduced to improve shiftability. The third shift unit S3, designed as a multi-plate clutch, is advantageously arranged coaxially with the output shaft W5, the output shaft W5 having a fifth fixed gear Z51 which is coupled to the axle drive (not shown).

The fifth fixed gear Z51 does not advantageously have an input gear

axle drive shown in engagement.

The two spur gear sub-transmissions 14, 15 have a fourth gear pair Z4 and a fourth switching unit S4 of the four switching units S1, S2, S3, S4. The second

Spur gear sub-transmission 15 has the fourth shift unit S4. The fourth switching unit S4 is assigned to the output shaft W5. The fourth switching unit S4 is of one

Claw clutch formed and assigned to the fourth gear pair Z4. The fourth pair of gears Z4 is provided to be switched on during an upshift to a third power-split gear stage G6, which in the exemplary embodiment is formed by the sixth gear stage G6, and the second

The power-split gear stage G6 has a larger total electric machine ratio than the total electric machine ratio of the next smaller one

power split gear stage G5. The fourth switching unit S4 is provided to connect the fourth idler gear Z42 of the fourth gear pair Z4 to the output shaft W5 in a rotationally fixed manner. The fourth switching unit S4 is provided to connect the fourth idler gear Z42 of the fourth gear wheel pair Z4 in a rotationally fixed manner to the actual shaft of the output shaft W5. In a closed state, the fourth switching unit S4 connects the fourth idler gear Z42 of the fourth gear wheel pair Z4 in a rotationally fixed manner to the actual shaft of the output shaft W5.

In addition, it would be conceivable that the two spur gear part transmissions 14, 15 have a further

Gear pairing and a further switching unit which is designed as a multi-disc clutch and which is assigned to the further gear wheel pairing, the further gear wheel pairing being intended to be switched on during an upshift to a further power-split gear stage and the further power-split gear stage being a lower electric machine -Overall gear ratio than the total electric machine ratio of the next smaller one

power-split gear. The installation of a single multi-plate clutch in the partial spur gear 14, 15 of the hybrid drive device 10, with the others

Switching units S1, S2, S4 of the spur gear sub-transmissions 14, 15 claw clutches,

in particular without synchronization devices, in particular represents a represents a sensible solution to a problem. The problem is the non-power shiftability of a very specific gear change in this hybrid drive device 10.

A switching strategy for switching the switching units S1, S2, S3, S4 and the

Interlocking switching unit VK can be found in the table in FIG. There are seven forward gears G1, G2, G3, G4, G5, G6, G7, shiftable. There may be further redundant and additional transmission gears. A marking in the corresponding row means that the corresponding shift unit S1, S2, S3, S4 and / or the interlocking shift unit VK is closed in order to shift the gear shown in the first column.

List of reference symbols

10 hybrid drive device

11 combustion engine

12 machine

13 planetary gears

14 first spur gear sub-transmission

15 second spur gear unit

16 rotor

17 stator

G1 forward gear

G2 forward gear

G3 forward gear

G4 forward gear

G5 forward gear

G6 forward gear

G7 forward gear

P1 first planetary gear set

P11 First gear element of the first planetary gear set

P12 Second gear element of the first planetary gear set

P13 Third gear element of the first planetary gear set

P2 second planetary gear set

P21 First gear element of the second planetary gear set

P22 Second gear element of the second planetary gear set

P23 Third gear element of the second planetary gear set

51 First switching unit

52 Second switching unit

53 Third switching unit

54 Fourth switching unit

VK interlocking switching unit

W1 First wave

W2 Second wave W3 Third wave

W4 Fourth wave

W5 output shaft

Z1 First gear pairing

Z11 fixed gear

Z12 First idler gear

Z2 Second gear pairing

Z21 fixed gear

Z22 Second idler gear

Z3 Third gear pairing

Z31 fixed gear

Z32 Third idler gear

Z4 Fourth gear pairing

Z41 fixed gear

Z42 fourth idler gear

Z51 fixed gear

Claims

Claims

1. Hybrid drive device with an internal combustion engine (11), with an electric machine (12), with a four-shaft planetary gear transmission (13), which has a first shaft (W1), a second shaft (W2), a third shaft (W3) and a fourth Shaft (W4) with two spur gear sub-gears (14, 15), namely a first spur gear sub-gear (14) and a second spur gear sub-gear (15), the three switchable gear pairs (Z1, Z2, Z3) with three associated switching units (S1, S2 , S3), and with at least one output shaft (W5), the internal combustion engine (11) being connected to the first shaft (W1), the electrical machine (12) being connected to the second shaft (W2), the first Spur gear sub-transmission (14) is connected to the third shaft (W3), the second spur gear sub-transmission (15) being connected to the fourth shaft (W4), the four-shaft planetary gear transmission (13) having an interlocking switching unit (VK), with two switching units (S1 , S2) of the switching units (S1, S2, S3) as

Claw clutches are formed,

wherein a switching unit (S3) of the switching units (S1, S2, S3) as one

Multi-disc clutch is formed,

characterized in that

the switching unit (S3) designed as a multi-disc clutch of those

Spur gear pairing (Z3) is assigned to at least three gear wheel pairings (Z3), which are provided to be engaged in an upshift to a power-split gear stage (G4), and the power-split gear stage (G4) has a lower overall electric machine ratio, than the total electric machine ratio of the next smaller non-power split gear stage (G3), the total electric machine ratio being derived from a ratio starting from the electric machine (12), via the

Planetary gear (13) and further via the first and / or second

Spur gear part transmission (14, 15) to the output shaft (W5) results.

2. Hybrid drive device according to claim 1,

characterized in that

the two spur gear sub-gears (14, 15) have a fourth gear pair (Z4) and a fourth switching unit (S4) which is designed as a dog clutch and which is assigned to the fourth gear pair (Z4), the fourth gear pair (Z4) being provided for when upshifting to a second

power-split gear stage (G6) to be switched on and the second power-split gear stage (G6) has a greater overall electric machine ratio than the total electric machine ratio of the next smaller non-power-split gear stage (G5).

3. Hybrid drive device according to claim 1 or 2,

characterized in that

the two spur gear sub-transmissions (14, 15) have a further pair of gears and a further switching unit which is designed as a multi-plate clutch and which is assigned to the further gear pair, the further gear pair being provided to be switched on during an upshift to a further power-split gear stage and wherein the further power-split gear stage has a lower overall electric machine ratio than the total electric machine ratio of the next smaller non-power-split gear stage.

4. Hybrid drive device according to one of the preceding claims,

characterized in that

the four-shaft planetary gear set (13) has a first planetary gear set (P1) and a second planetary gear set (P2) each with three gear elements (P11, P12, P13, P21, P22, P23), the third gear element (P13) of the first planetary gear set (P1 ) is non-rotatably connected to the third gear element (P23) of the second planetary gear set (P2) and the second gear element (P12) of the first planetary gear set (P1) is non-rotatably connected to the second gear element (P22) of the second planetary gear set (P2).

5. Hybrid drive device according to claim 4,

characterized in that

the electric machine (12) rotates with the third gear elements (P13, P23) of the planetary gear (13) and the second spur gear sub-gear (15) rotates with the second gear elements (P12, P22) of the planetary gear (13) or the electric machine ( 12) turned with the second

Gear elements (P12, P22) of the planetary gear (13) and the second spur gear (15) rotate with the third gear elements (P13, P23) of the planetary gear (13) is connected.

6. Hybrid drive device according to claim 5,

characterized in that

the first gear elements (P11, P21) of the planetary gear (13) each as a sun gear, the second gear elements (P12, P22) of the planetary gear (13) each as a planetary gear carrier and the third gear element (P13, P23) of the planetary gear (13) each as ring gears are trained.

7. Hybrid drive device according to claim 6,

characterized in that

the electrical machine (12) rotates with the third gear element (P13, P23) of the planetary gear (13), which is designed as a ring gear

Internal combustion engine (11) rotates with the first gear element (P11) of the first planetary gear set (P1), which is designed as a sun gear, the second

Spur gear sub-gear (15) rotates with the second gear elements (P12, P22) of the planetary gear (13) designed as planetary gear carriers and the first spur gear (14) rotates with the first gear element (P21) of the second planetary gear set (P2) designed as a sun gear.

8. Hybrid drive device according to one of the preceding claims,

characterized in that

the output shaft (W5) has a fifth fixed gear (Z51) which is connected to a

Input gear of an axle drive is coupled to transmit torque.