DE102014204009A1 - Multi-speed planetary gear system as a component of the drive train of a motor vehicle - Google Patents

Abstract

The invention relates to a planetary gear system having a first planetary gear stage comprising a first sun gear, a first planetary assembly, a first planetary carrier and a first ring gear, a second planetary gear stage including a second sun gear, a second planetary gear set, a second planet carrier and a second planetary gear set Ring gear has a first power input, and a power output, wherein the first sun gear and the second sun gear arranged coaxially with each other and rotatably coupled to each other, the power output is rotatably coupled to the first planet carrier and the second ring gear, the second planet carrier via a first coupling means can be coupled switchable with the first power input, and which is composed of the first and the second sun gear pair of wheels via a second coupling means also switchable with the first power input can be coupled.

Description

Field of the invention

The invention is directed to a switchable operable in different gear ratios planetary gear system, which as such forms a component of the drive train of a motor vehicle, said planetary gear system comprising a first planetary gear stage with a first sun gear and a second planetary gear stage with a second sun gear rotatably coupled to the first sun gear is.

Out DE 33 412 17 A1 a planetary gear system is known in which a first, a second and a third planetary gear stage is provided. The first planetary gear stage and the second planetary gear stage each have a sun gear. The two sun wheels are connected to each other in a rotationally fixed manner. About coupling devices, the kinematic coupling of the first two stages is changeable. The two first stages are coupled via two power outputs to the third gear stage, wherein one of these two power outputs is formed by a shaft journal which is rotationally rigidly coupled to the two aforementioned sun gears of the first and the second gear stage. About other coupling devices, the kinematic coupling of the third gear stage with the two power outputs of the first stage pair can be determined.

Object of the invention

The invention has for its object to provide a planetary gear system, which is characterized by a robust and cost-effective construction and provides a high mechanical efficiency.

Inventive solution

• – einer ersten Planetengetriebestufe, die ein erstes Sonnenrad, eine erste Planetenanordnung, einen ersten Planetenträger und ein erstes Hohlrad aufweist,
• – einer zweiten Planetengetriebestufe, die ein zweites Sonnenrad, eine zweite Planetenanordnung, einen zweiten Planetenträger und ein zweites Hohlrad aufweist,
• – einem ersten Leistungseingang, und
• – einem Leistungsausgang, wobei
• – das erste Sonnenrad und das zweite Sonnenrad zueinander gleichachsig angeordnet und miteinander drehfest gekoppelt sind,
• – der Leistungsausgang drehfest mit dem ersten Planetenträger und mit dem zweiten Hohlrad gekoppelt ist,
• – der zweite Planetenträger über eine erste Kupplungseinrichtung mit dem ersten Leistungseingang schaltbar koppelbar ist, und
• – das aus dem ersten und dem zweiten Sonnenrad bestehende Radpaar über eine zweite Kupplungseinrichtung ebenfalls schaltbar mit dem ersten Leistungseingang koppelbar ist.

The above object is achieved by a planetary gear system, with:

• A first planetary gear stage comprising a first sun gear, a first planetary arrangement, a first planetary carrier and a first ring gear,
• A second planetary gear stage comprising a second sun gear, a second planetary arrangement, a second planet carrier and a second ring gear,
• - a first receipt of service, and
• - a power output, where
• The first sun gear and the second sun gear are arranged coaxially to one another and are coupled to one another in a rotationally fixed manner,
• The power output is non-rotatably coupled to the first planet carrier and to the second ring gear,
• - The second planetary carrier via a first coupling means with the first power input is switchable coupled, and
• - Which is composed of the first and the second sun gear pair of wheels via a second coupling means also switchable with the first power input coupled.

This makes it possible in an advantageous manner to provide a planetary gear system for a motor vehicle, in which at least four at least substantially harmoniously stepped forward gears can be realized via the two planetary gear stages. The planetary gear system according to the invention consists essentially of a modified Simpson planetary gear set. This planetary gear set can be realized by two largely identical planetary stages, two clutches and two braking devices. The Simpson planetary gear set according to the invention is connected in such a way that, as mentioned, four largely harmoniously stepped forward gears with a spread of more than 4.5 can be represented. In the planetary gear system according to the invention either the double sun or the carrier is driven at each gear.

The brake devices are preferably designed such that the sun gear pair can be fixed in a stationary manner via a first brake device, and the ring gear can be fixed in a stationary manner via a second brake device. The braking devices can be designed as friction-braking braking devices that can be actuated electromechanically, purely solid-mechanical, or hydraulically. It is possible to design those brake devices which are predominantly open or closed in time in such a way that the less frequently required state is actively brought about and then in the passive state predominantly required condition exists. Furthermore, the braking devices can also be designed so that they remain self-locking in the respectively controlled state and change the state only by temporary control. As an alternative to frictionally locking the sun gear pair or the planet carrier selectively defining brakes, these can also be designed as positively acting brakes, in particular locking, pawl, claw or other locking mechanisms. It is also possible to design one or both brake devices so that they initially bring about a frictional locking state and then caused by other institutions a positive locking.

According to a particular aspect of the present invention, the planetary gear system forms part of a hybrid drive system. For this purpose, according to a particularly preferred embodiment of the invention, the sun gear pair is kinematically coupled to an electric motor and driven by this electric motor. This electric motor can be designed so that it has a rotor which is arranged coaxially to a transmission axis defined by the pair of sun gear and coupled torsionally rigidly with this pair of sun gears. The rotor can be designed here as an internal rotor with a relatively large rotor diameter. The corresponding stator may then be stationarily connected to or incorporated into a housing of the transmission system. It is also possible to design the rotor as a so-called external rotor, in which case the stator is arranged coaxially to an input shaft representing the power input within the rotor. The rotor may in particular be designed as a rotor equipped with permanent magnets. Furthermore, the electric motor as a whole is preferably designed in such a way that it can be operated both as a drive and as a generator. The operation of this electric motor via a power level which is controlled by an electronic control device and thereby takes into account complex control concepts.

The planetary gear system according to the invention is preferably further designed such that the first gear stage and the second gear stage each have identical planetary gear sets in radial section with respect to the tooth geometry. For this purpose, the planets can be produced from forged, pressed or sintered preforms. In particular, the planetary gear sets can be designed so that the planets are geometrically identical. The sun gear pair can be manufactured by an integral part, for example, as a continuous toothed pin. The Sonneradpaar is rigidly connected to a carrier leading to the second coupling means, in particular integrally formed therewith. Furthermore, the pair of sun gears preferably sits on a hollow shaft through which a shaft journal is passed, which connects the first planetary carrier with the first coupling device.

The planetary gear system according to the invention is further preferably constructed so that the first gear stage and the second gear stage along the transmission axis are arranged axially successive and thereby the electric motor is located on the side of the power input. In particular, with this design, it becomes possible to combine a power component representing the power input, the electric motor and the first and the second coupling means to form a gear assembly which can then be assembled with an assembly comprising the two planetary gear stages. Those assemblies comprising the electric motor can furthermore be constructively designed in such a way that at least one of the brake devices, in particular those brake devices provided for fixing the pair of sunwheels, is also integrated in the aforementioned assembly.

As an alternative to the embodiment described above, in which the electric motor is arranged on the head side, it is also possible to design the transmission system so that the first gear stage and the second gear stage are arranged axially successively along the transmission axis and the electric motor is located on the opposite side. In this variant too, the engine can be combined with one of the brake devices to form an assembly.

Furthermore, the power output can also be located axially between the two planetary gear stages or between the pair of planetary gear stages and the electric motor. It is also possible to arrange the power output on the head side, in front of the pair of planetary gear stages.

Brief description of the figures

Further details and features of the invention will become apparent from the following description taken in conjunction with the drawings. It shows / shows:

1a to 1e Schematic representations to illustrate the structure and operation of the planetary gear system according to the invention according to a first preferred embodiment of the invention, in particular in different switching states;

2a and 2 B Schematic diagrams to illustrate the structure of a planetary gear system according to the invention according to a second embodiment of the invention with an integrated electric motor, as well as to illustrate the possibility here in conjunction with the electric motor and the coupling devices to form assemblies;

3a to 3d Schematic representations to illustrate the operation of the planetary gear system according to the invention according to the second embodiment of the planetary gear system in different switching states;

4 a schematic representation to illustrate the operation of the planetary gear system according to the invention according to the second embodiment of the planetary gear system using additional gears;

5 a schematic representation to illustrate the operation of the planetary gear system according to the invention according to the second embodiment of the planetary gear system when operating in the so-called. E-CVT gear;

6a to 6c several graphics for in-depth explanation of the operation of the planetary gear system according to the invention in E-CVT gear;

7a . 7b and 7c three schematic diagrams for illustrating a third, fourth and fifth variant of the planetary gear system according to the invention wherein each of the electric motor is disposed on a side facing away from the power input side of the transmission and also the sequence of gear stages along the transmission axis "reversed";

8a . 8b and 8c three further schematic representations to illustrate a sixth, seventh and eighth variant of the planetary gear system according to the invention wherein in the sixth and seventh variant each of the electric motor is disposed on a side facing away from the power input side of the transmission.

Detailed description of the figures

The representation after 1a shows a planetary gear system according to the invention. This comprises a first planetary gear stage P1 which has a first sun gear S1, a first planetary gear set PA1, a first planet carrier C1 and a first ring gear H1. Furthermore, the planetary gear system comprises a second planetary gear stage P2 which has a second sun gear S2, a second planetary gear set PA2, a second planet carrier C2 and a second ring gear H2, as well as a first power input IN, and a power output OUT.

The first sun gear S1 and the second sun gear S2 are arranged coaxially with each other and coupled torsionally rigidly with each other. The power output OUT is non-rotatably coupled to the first planet carrier C1 and to the second ring gear H2. This means that just those first planetary carrier C1 and the second ring gear H2 are permanently coupled to each other in a torsionally rigid manner, ie rotate together.

The second planet carrier C2 can be coupled via a first coupling device K1 to the first power input IN switchable. In addition, the sun wheel pair S1S2 consisting of the first and the second sun gear S1, S2 can also be coupled to the first power input IN in a switchable manner via a second clutch device K2. The coupling devices K1, K2 can in this case be designed as a so-called double clutch.

Furthermore, a first brake device B1 is provided according to the invention, wherein the pair of sun gears S1S2 can be fixed in a stationary manner via this first brake device B1. In addition, a second brake device B2 is provided, via which second brake device B2, the first ring gear H1 is stationary fixable.

The first gear stage P1 and the second gear stage P2 shown here each have identical planetary gear sets PA1, PA2 in radial section with respect to the tooth geometry. The sun gears S1, S2 are here also designed similar. From this particularly advantageous concept, however, at least slightly deviating from the realization of deviating transmission ratios.

The sun gear pair S1S2 is seated on a hollow shaft HW1. About this hollow shaft HW1 the pair of sun gears is coupled to a clutch disc CS1. The clutch disc CS1 can be coupled via the second clutch device K2 to the power input IN and via the first brake device B1 to the transmission housing not shown here. Within the hollow shaft HW1 runs a shaft journal HW2 as such connects the carrier C2 of the second planetary gear stage P2 with a clutch disc CS2 which forms part of the first clutch device K1. The shaft journal HW2 is rotatably mounted in the hollow shaft HW1 easily. An advantageous radial bearing of the hollow shaft HW1 can also be achieved via the shaft journal HW2 by, for example, supporting or centering the shaft journal HW2 in the transmission housing or in the input shaft IN and / or the output shaft OUT.

In the representations after the 1b to 1e are now different modes of operation of the transmission system after 1a illustrated. The illustrated switching states cause total translations of i = 3, i = 1.66, i = 1 and i = 0.66. The components shown thickened in this representation are active here, ie they carry a torque, or they support this. Even if gaps can still be seen in the representations in the thickened clutches K1, K2 and brakes B1, B2, these bodies are nevertheless to be regarded as closed, ie as torque-transmitting. As far as in the subsequently negotiated 1b to 1e for reasons of space not all mentioned reference numerals are entered, is based on the presentation 1a directed.

At the in 1b shown switching state, the second clutch device K2 and the second brake device B2 is closed. The torque applied to the input IN is transmitted via the second clutch device K2 to the sun gear pair S1S2. The second sun gear S2 remains free of load, since the shaft journal HW2 rotates freely. The first ring gear H1 is fixed stationarily via the second brake device B2. Thus, the first planetary gear PA1 rolls in the first ring gear H1, thus driving the first planet carrier C1. This is rigidly connected to the output OUT, so that this also rotates. This results in a translation between the input IN and the output OUT of i = 3.

At the in 1c shown switching state, the second clutch device K2 is opened and the second brake device B2 continues to be closed. In addition, the first clutch device K1 is closed. The torque applied to the input IN is transmitted via the first clutch device K1 and the shaft journal HW2 to the second planet carrier C2. The second sun gear S2 is driven via the first sun gear S1. The first ring gear H1 is fixed stationarily via the second brake device B2. Thus, the first planetary gear PA1 in turn rotates in the first ring gear H1 and thus drives the first planetary carrier C1 and the second ring gear H2 rigidly coupled thereto. These two components are rigidly connected to the output OUT, so that in turn rotates accordingly. This results in a translation between the input IN and the output OUT of i = 1.66.

At the in 1d shown switching state, the first clutch means K1 and the second clutch means K2 are closed. The brake devices B1 and B2 are opened. The torque applied to the input IN is transmitted via both coupling devices K1, K2 to the sun gear pair S1S2 and the second planet carrier C2. Here, the second planetary gear PA2 is ultimately blocked on the second planetary carrier C2 and takes the second ring gear H2 without rolling it in with. This results in a ratio between the input IN and the output OUT of i = 1 with an extremely high system efficiency.

At the in 1e shown switching state, the first clutch device K1 is closed and the second clutch device K2 opened. The brake device B1 is closed and the brake device B2 is open. The torque applied to the input IN is transmitted to the second planetary carrier C2 via the first clutch devices K1. The second sun gear S2 is fixed by the first brake device B1. The second planet PA2, which rolls on the second sun gear S2, in this case drives the second ring gear H2. This results in a translation between the input IN and the output OUT of i = 0.66 thus a so-called overdrive translation, also with an extremely high system efficiency.

In the 2a and 2 B is now one including the planetary gear system according to the 1a to 1e formed drive assembly (hereinafter also referred to as "E-Simpson transmission") for the drive train of a motor vehicle with a hybrid drive, shown. The systems shown in the two representations are identical with respect to the kinematic coupling of their components and differ only with regard to the assignment of the braking devices to an assembly comprising an electric motor. These differences will be discussed in more detail below.

In the case of the two 2a and 2 B shown hybrid drive system is coupled to the double sun S1S2 supporting shaft system HW1 the rotor EM of an otherwise not shown electric motor torsionally rigid. Regarding the operation of the transmission system is first on the comments on the 1a to 1e directed. Via the rotor EM, a drive torque can be introduced in accordance with the power supply to the electric motor in the shaft system HW1, or tapped as a generator. The rotor EM is arranged coaxially with respect to a transmission axis X1 defined by the pair of sun gears S1S2 and coupled in a torsionally rigid manner to the pair of sun gears S1S2. In addition, the electric motor EM can be operated as a generator as part of a vehicle thrust operation, and possibly also in other operating conditions. The rotor EM is arranged coaxially with the input shaft IN and permanently connected to the shaft HW1 driving the double sun S1S2. The first gear stage P1 and the second gear stage P2 are arranged axially successively along the transmission axis X1 and the rotor EM of the electric motor is located on the side of the power input IN.

In the embodiment according to 2a The electric motor together with the first clutch device K1, the second clutch device K2, the input shaft IN and the first brake device B1 forms a so-called hybrid module which is attached frontally to a planetary gear assembly comprising the two gear stages P1, P2 and the second brake device B2 , The transmission shafts HW1 and HW2 are in this case designed as split and joined via a spline shafts. The dashed frame indicates a possible dry space, the components of which, depending on the structural design, need not be surrounded by oil and consequently may have advantageous properties, such as low drag torques.

In the embodiment according to 2 B the electric motor together with the first clutch device K1, the second clutch device K2, and the input shaft IN forms the module called a hybrid head which in turn is attached frontally to a planetary gear assembly comprising the two gear stages P1, P2. In this variant, now both brake devices B1, B2 are integrated in the planetary gear assembly and thereby allow a selective locking of the double sun S1S2 and the first ring gear H1. Again, the transmission shafts HW1 and HW2 are designed as split and connected via a spline not shown waves. Here, too, there is the option of designing a drying room in order to utilize the resulting advantages, such as low drag torques or high coefficients of friction.

The input shaft IN of the planetary gear system is driven by an internal combustion engine, not shown here, possibly with the interposition of a converter. Instead of an internal combustion engine, the drive of the input shaft IN can also be accomplished via a further electric motor. The transmission system according to the invention is also suitable for the realization of a purely electric drive system.

In the 3a to 3d is the operation of the drive system after 2a further illustrated. The components thickened in this representation are performance-leading, the components shown in a somewhat thinner manner are not relevant for the power transfer in this switching state. Although similar to the figure series After the 1b to 1e in the representation in these components are still shown column, these are as far as they are shown thickened are closed. As far as in the subsequently negotiated 3a to 3d for reasons of space, not all the mentioned reference signs are entered is on the representation after 2a directed.

At the in 3a shown switching state, the second clutch device K2 and the second brake device B2 are closed. The torque applied to the input IN is transmitted to the transmission shaft HW1 via the second clutch device K2. Also, the driving torque generated by the rotor EM of the electric motor is transmitted to the transmission shaft HW1. The gear shaft drives the Sonnenradpaar S1S2 under the effect of the applied thereto sums momentum. The second sun gear S2 remains free of load, since as with respect 1b the shaft journal HW2 turns freely. The first ring gear H1 is fixed stationarily via the second brake device B2. Thus, the first planetary gear PA1 rolls in the first ring gear, thus driving the first planet carrier C1. This is rigidly connected to the output OUT, so that this also rotates. This results in a translation between the input IN and the output OUT of i = 3. The rotor can boost with the same ratio or recuperate or move the load / load point. When changing the gear shift state in the in 3b illustrated switching state of the so-called. 2nd Ganges the rotor EM remains connected to the sun gear pair S1S2.

At the in 3b shown switching state, the second clutch device K2 is opened and the second brake device B2 continues to be closed. In addition, the first clutch device K1 is closed. The torque applied to the input IN is transmitted to the second planet carrier C2 via the first clutch device K1 and the shaft journal WH2. The second sun gear S2 is driven via the first sun gear S1. The first ring gear H1 is fixed stationarily via the second brake device B2, and the first brake device B1 is opened. Thus, the first planetary gear PA1 in turn rotates in the first ring gear H1 and thus drives the first planetary carrier C1 and the second ring gear H2 rigidly coupled thereto. These two components are rigidly connected to the output OUT, so that in turn rotates accordingly. This results in a translation between the input IN and the output OUT of i = 1.66. In this gear, a power split and power consolidation takes place. Furthermore, the rotor EM can boost with the ratio i = 3 (higher than the engine) or recuperate or shift the load / load point. When changing to the in 3c shown switching state of the 3rd gear is a relatively high speed jump of the rotor EM, in which a el. Schwungenergienutzung of the rotor EM can be done.

At the in 3c shown switching state, the first clutch means K1 and the second clutch means K2 are closed. The brake devices B1 and B2 are opened. The torque applied to the input IN is transmitted via both coupling devices K1, K2 to the sun gear pair S1S2 and the second planet carrier C2. In addition, the Sonnenradpaar is also driven by the rotor EM. Here, the second planetary gear PA2 is blocked on the second planetary carrier C2 and takes the second ring gear H2 without rolling it in with. This results in a ratio between the input IN and the output OUT of i = 1 with a high system efficiency. The clutch K1 transmits in this state, an increased torque. The rotor EM can now boost with the same translation or recuperation or move the load / load point. The gear change in the in 3d shown switching state of the 4th gear can be done with swing energy instead of Reibenergieverlust.

At the in 3d shown switching state of the 4th gear, the first clutch device K1 is closed and the second clutch device K2 opened. The brake devices B1 is closed and the brake device B2 is open. The torque applied to the input IN is transmitted to the second planet carrier C2 via the first clutch devices K1. The second sun gear S2 is fixed stationarily via the first brake device B1 and the electric motor is passive, ie there is no electromotive assistance in this switching state. The second planet PA2, which rolls on the second sun gear S2, in this case drives the second ring gear H2. This results in a translation between the input IN and the output OUT of i = 0.66 thus a so-called overdrive translation, also with a high system efficiency.

In 4 is with reference to the system after 2 B a switching state for a special or additional gear illustrated. The clutches K1, K2 and the first brake device B1 are open. This system state allows an electromotive starting gear with high mechanical efficiency, ie low friction losses within the transmission, since the electric motor can start from a standstill out. Furthermore, in this switching position, a simple and comfortable transition / supplementation by the internal combustion engine is made possible by coupling the second clutch device K2 (slipping). In a gear change from 1 to 2, the electric motor remains coupled to the drive unchanged, ie can be used to improve (comfort or friction energy). It is also possible in this switching position to realize a purely electrical reverse gear with high system ratio (i = 3).

At the in 5 shown switching state of the system after 2 B , can be made via the electric motor EM, a moment equilibrium on the planet PA2, and in this case the engine speed continuously between the 2nd and 5th gear (beyond the 4th gear!) Are set. The electric motor EM can be operated in such a way that it generates / consumes electrical power depending on the conversion.

In 5th gear is only boost or recuperation. In 4th gear there is no power flow (nEM = 0). In 3rd gear there is the possibility of a loading function (loss of traction in the train), or feeding in thrust, otherwise OD amplification.

The E-Simpson transmission allows the operation of a corresponding motor vehicle in an upper E-CVT gear range involving the thickened components. The e-machine must establish a torque equilibrium on the planet and can adjust the speed of the combustion engine infinitely between the 2nd and the 5th gear (beyond the 4th gear). From the torque and the adjustable speed of the e-machine results in a power flow, which is either to understand as a boost (when the electric machine outputs power at the same time as the internal combustion engine) or as a generation / working point shift (when the electric machine converts some of the power output from the combustor into electricity), or as recuperation (when the electric machine generates power while as well) the internal combustion engine brakes).

In 6a is shown in the form of a simplified diagram, as in the transmission according to the invention via the variable-ratio coupling of the internal combustion engine and the permanent coupling of the rotor of the electric motor to the double sun a special control strategy can be implemented. So there is full freedom of the torque control of the electric motor, but with fixed (positive) speed. It can therefore be boosted, for example, when the driver wants to accelerate (recognizable by the accelerator pedal that has traveled a long way), as the electric motor gives off a positive torque. Likewise, if the driver decelerates (recognizable by brake pedal operation or empty gas), recuperation is possible. A load point shift can be performed in "torque direction". The hybrid combination engine and electric motor can be understood as a drive with a pedal-dependent torque (speed) map, which feels for the driver like a "combustion engine with more reserves".

As related to the diagram below 6b can be seen, there is a certain limitation in the transmission according to the invention with respect to the torque control, to the effect that in stationary states, the moment equilibrium must be maintained on the planet. However, this balance can be maintained at different speeds, so here is a degree of freedom. According to the invention, this degree of freedom is used to set at least the sign of the electric motor as a function of the accelerator pedal position. This determines which direction an electrical power flow has. It is particularly advantageous to set the sign and the speed in such a way that it results in a given ratio (burner to output speed) as a function of the accelerator pedal position, because the driver intuitively finds this to be correct.

When the driver wants to accelerate (recognizable by the accelerator pedal being pressed wide), a positive speed of the electric motor is set. The positive e-motor speed also causes an increase in the speed of the internal combustion engine, so that it can deliver more power, and a switch back is easier. The situation corresponds to a boost plus stepless downshift, so it goes beyond a pure boost function comfortable and beneficial.

In 6c is an operating situation for a constant driving desire of the driver (recognizable by mean positions of the accelerator pedal) is illustrated. Here, a negative speed of the electric motor is set. At the same time, the negative electric motor speed causes a reduction in the speed of the internal combustion engine, so that it can be operated at a more fuel-efficient operating point (both in terms of speed and torque). The situation corresponds to an upshift, thus providing the driver with an advantage in terms of acoustics (lower engine speed) and reduced fuel consumption.

If the driver desires to decelerate (indicated by brake pedal operation or almost empty gas), the speed of the electric motor is either set to zero (transmission brake) or negatively adjusted, in which case the resulting negative moment has a recuperating effect. At the same time, a speed set at zero of the electric motor causes a speed increase of the internal combustion engine, so that its braking power increases. The situation corresponds to a recuperation plus downshift, thus providing the driver with increased brake assistance.

• – Die Kupplung K1 wird auf ein Maximalmoment von ca. 50–150 Nm eingerückt, wodurch der Elektromotor (je nach Übersetzung der wirksamen Planetenstufe) auf die 2- bis 5-fache Motor-Leerlaufdrehzahl beschleunigt wird, während der Verbrennungsmotor in Leerlaufdrehzahlregelung verharrt.
• – Danach bzw. zeitlich überschneidend mit dem Einrückvorgang der Kupplung K1 wird am Elektromotor EM ein generatorisches Lastmoment von 20–50Nm aufgebaut, z.B. bevorzugt drehzahlprogressiv. Dadurch wird der Verbrennungsmotor mit einem (durch den Planetensatz) übersetzten Moment belastet, welches an oder knapp unter dem Kupplungsmoment liegt. Der Planetensatz erzeugt hierbei an seinem Hohlrad ein positives Abstützmoment, welches z.B. ca. 40–100 Nm beträgt und ein komfortables, nicht mit Kupplungs-Reibverlusten verbundenes Kriechmoment ist.
• – Im Falle, dass das Fahrzeug sich infolge des Kriechmomentes in Bewegung setzt, reduziert sich die Drehzahl am Elektromotor im Gegenzug leicht. Es kann dann ggf. auch das Drehmoment reduziert werden, damit die Fahrgeschwindigkeit eine typische Kriechgeschwindigkeit (z.B. 6 km/h) nicht überschreitet.
• – Im Falle, dass der Fahrer einen Beschleunigungswunsch anzeigt (erkennbar z.B. an Gaspedalbetätigung), sind bevorzugt die Schaltelemente des 2.Ganges zu betätigen (Kupplung K1 bleibt betätigt, Bremse am Hohlrad ist zusätzlich zu betätigen, eines der beiden Elemente ist schlupfend zu betreiben), und der Elektromotor von Generation (negatives Moment) auf Antrieb (positives Moment, Leistungsabgabe) umzusteuern.

The "E-Simpson transmission" according to the invention also makes it possible to use the E-CVT gear range in a special situation, namely in the presence of a permanent creep readiness (idle position at standstill) with a weakly charged battery. With the following operating method according to the invention, the electric motor is operated as a generator while simultaneously generating a low output torque, ie the battery is charged:

• - The clutch K1 is engaged to a maximum torque of about 50-150 Nm, whereby the electric motor (depending on the translation of the effective planetary stage) is accelerated to 2 to 5 times the engine idling speed while the engine remains in idle speed control.
• - Thereafter or temporally overlapping with the engagement of the clutch K1, a regenerative load torque of 20-50Nm is built on the electric motor EM, for example, preferably speed-progressive. As a result, the internal combustion engine is loaded with a (translated by the planetary gear set) translated torque, which is at or just below the clutch torque. The planetary gearset produces a positive support torque at its ring gear which, for example, is approximately 40-100 Nm and is a comfortable creep torque not associated with clutch friction losses.
• - In the case that the vehicle sets in motion due to the creeping torque, the speed at the electric motor in turn reduces slightly. It may then possibly also the torque can be reduced so that the driving speed does not exceed a typical creep speed (eg 6 km / h).
• - In the event that the driver indicates an acceleration request (recognizable, for example, accelerator pedal operation), the switching elements of the 2nd gear are preferably to be operated (clutch K1 remains actuated, brake on the ring gear is in addition to operate, one of the two elements is slipping operation) , And the electric motor of generation (negative moment) on drive (positive moment, power output) to redirect.

In 7a is shown a further variant of a planetary gear system according to the invention with integrated electric motor drive. This in turn comprises a first planetary gear stage P1 which has a first sun gear S1, a first planetary arrangement PA1, a first planet carrier C1 and a first ring gear H1. Furthermore, the planetary gear system comprises a second planetary gear stage P2 which has a second sun gear S2, a second planetary gear set PA2, a second planet carrier C2 and a second ring gear H2, as well as a first power input IN, and a power output OUT. The first sun gear S1 and the second sun gear S2 are arranged coaxially with each other and coupled torsionally rigidly with each other. The power output OUT is non-rotatably coupled to the first planet carrier C1 and to the second ring gear H2. This means that just those first planetary carrier C1 and the second ring gear H2 are permanently coupled to each other in a torsionally rigid manner, ie rotate together.

The second planet carrier C2 can be coupled via a first coupling device K1 to the first power input IN switchable. In addition, the sun wheel pair S1S2 consisting of the first and the second sun gear S1, S2 can also be coupled to the first power input IN in a switchable manner via a second clutch device K2. The coupling devices K1, K2 can in this case be designed as a so-called double clutch. Furthermore, a first brake device B1 is provided according to the invention, wherein the pair of sun gears S1S2 can be fixed in a stationary manner via this first brake device B1. In addition, a second brake device B2 is provided, wherein the first ring gear H1 can be fixed in a stationary manner via this second brake device B2.

The sun gear pair S1S2 is permanently coupled via a gear shaft HW1 to the rotor EM of an electric motor, which is otherwise not shown. The provided for deriving the drive power from the transmission system output OUT is located in an intermediate region between the first gear stage P1 and the rotor EM of the electric motor. This variant is particularly suitable for installation in a motor vehicle with a transverse engine. In this case, an axle differential can be directly driven via the output OUT.

The electric motor EM and the first brake device B1 can be combined to form an assembly that can be attached laterally to those planetary gear stages P1, P2 comprehensive assembly and thus subsequently accessible for maintenance advantageous and interchangeable. The two coupling devices K1, K2 can also be combined to form an assembly that can be attached laterally to those the two planetary gear stages P1, P2 comprehensive assembly. The dashed frame indicates possible dry spaces whose components do not have to be surrounded by oil, depending on the structural design, and consequently can have advantageous properties such as low drag torques with simultaneously high useful friction values.

For the in 7b illustrated variant of a erfindungemäßen drive system, the comments apply to 7a largely analogously. Deviating from the variant 7a Here, the output OUT is connected in a lying axially between the two planetary gear stages P1, P2 range to a hollow shaft portion which couples the second ring gear H2 and the first carrier C1 torsionally rigid.

The representation after 7c shows a further variant of the drive system according to the invention. For this variant, the comments on 7a largely analogously. Deviating from the variant 7a and also deviating from the variant 7b here is the output OUT in a lying axially between the two coupling devices K1, K2 and the two planetary gear stages P1, P2 area. The dashed lines in this illustration again indicate possible dry spaces, the components of which, depending on the design, need not be surrounded by oil and consequently may have advantageous properties, such as low drag torques and simultaneously high useful friction values. The power output OUT is here designed as a spur gear which is torsionally rigidly coupled to the second ring gear H2 and the first planet carrier C1. Through the power output OUT coaxial those shaft sections are passed, which connect the first clutch device K1 with the second planet carrier C2 and the second clutch device K2 with the two sun gears S1, S2. These shaft sections are preferably designed to be pluggable so that the left in this illustration, surrounded by the frame shown in dashed lines module can be added axially to the planetary gear assembly P1P2. The assembly surrounded in this illustration by the right dashed line frame is likewise preferably pluggable attachable to the planetary gear assembly.

The representation after 8a shows a further, according to the previously described variant 7a based embodiment of an E-Simpson transmission according to the invention. This includes, in the same way as the previously described embodiments, a first planetary gear stage P1 which has a first sun gear S1, a first planetary gear set PA1, a first planet carrier C1 and a first ring gear H1. Furthermore, the planetary gear system comprises a second planetary gear stage P2 having a second sun gear S2, a second planetary gear arrangement PA2, a second planet carrier C2 and a second ring gear H2, as well as a first power input IN, and a power output OUT. The first sun gear S1 and the second sun gear S2 are arranged coaxially with each other and coupled torsionally rigidly with each other. The power output OUT is non-rotatably coupled to the first planet carrier C1 and to the second ring gear H2. This means that just those first planetary carrier C1 and the second ring gear H2 are permanently coupled to each other in a torsionally rigid manner, ie rotate together.

The second planet carrier C2 can be coupled via a first coupling device K1 to the first power input IN switchable. In addition, the sun wheel pair S1S2 consisting of the first and the second sun gear S1, S2 can also be coupled to the first power input IN in a switchable manner via a second clutch device K2. The coupling devices K1, K2 can in this case be designed as a so-called double clutch.

Furthermore, a first brake device B1 is provided according to the invention, wherein the pair of sun gears S1S2 can be fixed in a stationary manner via this first brake device B1. In addition, a second brake device B2 is provided, wherein the first ring gear H1 can be fixed in a stationary manner via this second brake device B2. The dashed frames indicate possible dry spaces whose components do not have to be surrounded by oil, depending on the structural design, and consequently can have advantageous properties such as low drag torques with simultaneously high useful friction values.

The variant after 8a is characterized in that a third clutch device K3 is provided via which the first ring gear H1 is selectively coupled to the transmission input IN. This third clutch device K3 extends the gear range and offers other special operating options of the transmission. As with the variant 7a is provided for deriving the drive power from the transmission system output OUT in an intermediate region between the first gear stage P1 and the rotor EM of the electric motor. This variant is thus in turn suitable in particular for installation in a motor vehicle with a transversely arranged internal combustion engine. In turn, an axle differential can be driven directly via the output OUT.

The electric motor EM and the first brake device B1 can in turn be combined to form an assembly which can be attached laterally to those assembly comprising the planetary gear stages and thus subsequently advantageously accessible and interchangeable for maintenance work.

The connection between the third clutch device K3 and the first ring gear can be accomplished by a pot member, via which the two clutches K1, K2 and the two planetary gear stages P1, P2 can be combined to form an assembly, which is then inserted into a corresponding gear housing.

The representation after 8b shows a still further variant of one of the above-described design 7a based embodiment of an E-Simpson transmission according to the invention. This includes, in the same way as the previously described embodiments, a first planetary gear stage P1 which has a first sun gear S1, a first planetary gear set PA1, a first planet carrier C1 and a first ring gear H1. Furthermore, the planetary gear system comprises a second planetary gear stage P2 having a second sun gear S2, a second planetary gear arrangement PA2, a second planet carrier C2 and a second ring gear H2, as well as a first power input IN, and a power output OUT. The first sun gear S1 and the second sun gear S2 are arranged coaxially with each other and coupled torsionally rigidly with each other. The power output OUT is non-rotatably coupled to the first planet carrier C1 and to the second ring gear H2. This means that just those first planetary carrier C1 and the second ring gear H2 are permanently coupled to each other in a torsionally rigid manner, ie rotate together.

The second planet carrier C2 can be coupled via a first coupling device K1 to the first power input IN switchable. In addition, the sun wheel pair S1S2 consisting of the first and the second sun gear S1, S2 can also be coupled to the first power input IN in a switchable manner via a second clutch device K2. The coupling devices K1, K2 can in this case be designed as a so-called double clutch.

Furthermore, a first brake device B1 is provided according to the invention, wherein the pair of sun gears S1S2 can be fixed in a stationary manner via this first brake device B1. In addition, a second brake device B2 is provided, wherein the first ring gear H1 can be fixed in a stationary manner via this second brake device B2.

The variant after 8b characterized by the fact that a third braking device B3 is provided via which the second planetary carrier C2 is selectively fixed stationary. This third braking device B3 extends the gear spectrum by a reverse gear, for example, the gear ratio i = -2 offers, and possibly to a parking lock function. As with the variant 7a is provided for deriving the drive power from the transmission system output OUT in an intermediate region between the first gear stage P1 and the rotor EM of the electric motor. This variant is thus in turn suitable in particular for installation in a motor vehicle with a transversely arranged internal combustion engine. In turn, an axle differential can be driven directly via the output OUT.

The electric motor EM and the first brake device B1 can in turn be combined to form an assembly which can be attached laterally to those assembly comprising the planetary gear stages and thus subsequently advantageously accessible and interchangeable for maintenance work.

The representation after 8c shows a further embodiment of an E-Simpson transmission according to the invention. This includes, in the same way as the two previously described embodiments, a first planetary gear stage P1 which has a first sun gear S1, a first planetary gear set PA1, a first planet carrier C1 and a first ring gear H1. Furthermore, the planetary gear system comprises a second planetary gear stage P2 having a second sun gear S2, a second planetary gear arrangement PA2, a second planet carrier C2 and a second ring gear H2, as well as a first power input IN, and a power output OUT. The first sun gear S1 and the second sun gear S2 are arranged coaxially with each other and coupled torsionally rigidly with each other. The power output OUT is non-rotatably coupled to the first planet carrier C1 and to the second ring gear H2.

The second planet carrier C2 can be coupled via a first coupling device K1 to the first power input IN switchable. In addition, the sun wheel pair S1S2 consisting of the first and the second sun gear S1, S2 can also be coupled to the first power input IN in a switchable manner via a second clutch device K2. The coupling devices K1, K2 can in this case be designed as a so-called double clutch.

Furthermore, a first brake device B1 is provided according to the invention, wherein the pair of sun gears S1S2 can be fixed in a stationary manner via this first brake device B1. In addition, a second brake device B2 is provided, wherein the first ring gear H1 can be fixed in a stationary manner via this second brake device B2. The dashed frame in turn indicates a possible dry space, the components of which, depending on the structural design need not be surrounded by oil and therefore can have advantageous properties such as low drag torque with high Nutzreibwerten simultaneously.

The variant after 8c is characterized in that a further coupling device KS is provided via which the two rigidly coupled sun gears S1, S2 selectively coupled to the electric motor EM and the clutch disc of the second clutch device K2. This further coupling device K3 extends the gear spectrum and in particular provides the operating possibilities of the gearbox shown in the table below.

The additionally provided in the illustrated transmission system clutch device KS extends the gear spectrum. Thus, in the 4th gear (if B1 is activated) with the KS open, the electric motor can be used via K1. The system also allows the electric motor to be switched from the fast sun shaft (KS to, K2 up) to the slower input shaft (KS to, K2 to) in the 2nd gear, which simplifies gear changes. In the 1-2-speed change, the electric motor remains unchanged and can improve comfort, in the 2nd gear, the electric motor itself is switched over, and in the case of 2-3 gear changes, the electric motor runs synchronously back to the combustion engine.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3341217 A1 [0002]

Claims (10)

Planetary gear system, with: A first planetary gear stage (P1) which has a first sun gear (S1), a first planetary gear arrangement (PA1), a first planet carrier (C1) and a first ring gear (H1), A second planetary gear stage (P2) which has a second sun gear (S2), a second planetary gear arrangement (PA2), a second planet carrier (C2) and a second ring gear (H2), - a first power input (IN), and A power output (OUT), - Wherein the first sun gear (S1) and the second sun gear (S2) are arranged coaxially with each other and coupled torsionally rigid, The power output (OUT) is non-rotatably coupled to the first planetary carrier (C1) and to the second ring gear (H2), - The second planetary carrier via a first coupling means with the first power input is switchable coupled, and - The from the first and the second sun gear (S1, S2) existing pair of wheels via a second clutch means (K2) also switchable with the first power input (IN) can be coupled. Planetary gear system according to claim 1, characterized in that a first braking device (B1) is provided, and that the first brake device (B1), the pair of sun gear (S1S2) is fixed stationary about this. Planetary gear system according to claim 2, characterized in that a second braking device (B2) is provided, and that over this the first ring gear (H1) is stationary fixable. Planetary gear system according to at least one of claims 1 to 3, characterized in that the sun gear pair (S1S2) is kinematically coupled to an electric motor (EM) and can be driven or braked by this electric motor (EM). Planetary gear system according to claim 4, characterized in that the electric motor has a rotor which is coaxially arranged to a through the pair of sun gear (S1S2) defined transmission axis (X1) and torsionally rigid with this pair of sun gears (S1S2). Planetary gear system according to at least one of claims 1 to 5, characterized in that the first gear stage (P1) and the second gear stage (P2) each having the same tooth geometry in the radial section identical planetary gear sets. Planetary gear system according to at least one of claims 1 to 6, characterized in that the first gear stage (P1) and the second gear stage (P2) along the transmission axis (X1) are arranged axially successively and the electric motor (EM) on the side of the power input ( IN). Planetary gear system according to at least one of claims 1 to 6, characterized in that the first gear stage (P1) and the second gear stage (P2) along the transmission axis (X1) are arranged axially successively and the electric motor (EM) on the side of the power output ( OUT) is located. Planetary gear system according to at least one of claims 1 to 8, characterized in that a power input (IN) representing the transmission component, the electric motor (EM) and the first and the second clutch means (K1, K2) are combined to form a transmission assembly. Planetary gear system according to claim 9, characterized in that in the aforementioned assembly at least one of the braking devices (B1, B2) is included.

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