EP3532328A1 - Hybrid drive train for a hybrid-driven motor vehicle - Google Patents

Abstract

The invention relates to a hybrid drive train for a hybrid-driven vehicle, comprising a transmission (1), particularly a manual transmission, which can be shifted into different transmission stages by means of shifting elements and which can be drivingly connected to an internal combustion engine (7) via an internal combustion engine shaft (3), to an electric machine (11) via an electric machine shaft (9), and to at least one vehicle axle (VA) via an output shaft (13). The internal combustion engine shaft (3) and a take-off shaft (17), which is drivingly connected to the output shaft (13), can be connected together via spur gear sets which can be shifted by means of the shifting elements, each spur gear set forming a gear plane (V1 to V4, E1, E2), from which at least one hybrid gear plane (E1, E2) can additionally be connected to the electric machine shaft (9). According to the invention, the hybrid gear plane (E1, E2) is part of a sub-transmission (T) which has shifting elements (SE-A, SE-B, SE-C), by means of which the sub-transmission (T) can be decoupled from the drive train or can be coupled thereto during operation of the transmission.

Description

 Hybrid powertrain for a hybrid-powered motor vehicle

The invention relates to a hybrid drive train for a hybrid-powered motor vehicle according to the preamble of claim 1.

From EP 2 792 523 A2 a generic hybrid powertrain for a hybrid-powered vehicle is known. This one has by means

Switching elements in different gear ratios switchable transmission, which via an engine shaft with a

Internal combustion engine, via an electric machine shaft with a

Electric machine and via an output shaft with at least one vehicle axle is drivingly connected. The internal combustion engine shaft can be connected to a drive shaft via spur gearsets that form wheel-plane gears. This drives in turn via a spur gear on the

 Output shaft off. The wheel planes of the hybrid transmission have a hybrid gear plane that is drivingly connected to the electric machine shaft.

The object of the invention is to provide a hybrid powertrain, which has greater degrees of freedom in functionality in a structurally favorable design that is structurally simple in comparison with the prior art.

The object is solved by the features of claim 1.

Preferred embodiments of the invention are disclosed in the subclaims.

According to the characterizing part of claim 1, the hybrid gear plane E1, E2 part of a subtransmission T, the switching elements SE -A, SE -B, SE -C has, by means of which the partial transmission T during the Transmission operation can be decoupled from the drive train or can be connected. The hybrid gear plane E1, E2 of the partial transmission T can therefore be shut down in gear mode and decoupled from the remaining activated part of the transmission. Accordingly, the transmission can be operated purely electrically, while the internal combustion engine is shut down. Conversely, the electric machine can be completely decoupled from the drive train.

At least one switching element SE-A can be arranged on the electric machine shaft, by means of which the electric machine can be decoupled from or connected to the hybrid gear plane E1, E2. In this way, the electric machine can be completely decoupled from the drive train with switched internal combustion engine gears. This advantageously reduces the moment of inertia of the activated subtransmission.

In an industrial implementation, the hybrid gear plane E1, E2 may be composed of a driven-side gear arranged on the output shaft, a drive-side gear arranged on the engine shaft, and a gear arranged on the electric machine shaft. The arranged on the electric machine shaft gear can be rotatably mounted as a loose gear on the electric machine shaft and be decoupled from the electric machine shaft by means of the switching element SE-A or be coupled with it. In a preferred embodiment, the transmission can be exactly two

Hybrid wheel planes E1, E2 have. The arranged on the electric machine shaft switching element SE-A can be switched on both sides and be arranged in the axial direction between the idler gears of the two hybrid gear planes E1, E2. The switching element SE-A can in a

Neutral position of both hybrid wheel planes be decoupled. In addition, can the switching element SE-A either in a first switching position the

Loose gear of the first hybrid wheel plane E1 couple with the electric machine shaft or couple in a second switching position, the idler gear of the second hybrid gear plane E2 with the electric machine shaft.

It is preferred if the electric machine shaft is completely free of rotationally fixed fixed gears of the spur gear sets, which form the wheel planes of the transmission. In addition, it is preferred that the transmission is designed as a pure spur gear, in which the engine shaft, the

Electric machine shaft and the output shaft can be connected to one another exclusively via spur gear sets. In this way, a simply constructed transmission structure is achieved, which is much more efficient to operate compared to a planetary gear.

In a further preferred embodiment, the two hybrid gear planes can be directly adjacent in the axial direction and combined together to form the subtransmission, which can be disengaged in gear operation, that is, can be decoupled from the drive train. To realize such a partial transmission, each of the hybrid gear planes E1, E2 may each have a drive shaft arranged on the output side gear, which is designed as a gear and by means of a switching element SE-B can be coupled to the output shaft. In addition, the on the

Internal combustion engine shaft arranged drive-side gears of the two hybrid gear planes E1, E2 be designed as loose gears. These are preferably arranged together non-rotatably on a drive-side hollow shaft. The hollow shaft is rotatably mounted coaxially on the engine shaft and via exactly one switching element, namely SE-C, coupled to the engine shaft. The above mentioned, on the Output shaft arranged switching element SE-B can be made switchable on both sides and in the axial direction between the output side

Loszahnrädern the two hybrid wheel planes E1, E2 be arranged. The arranged on the electric machine shaft switching element can be implemented arbitrarily, for example as a power shift double clutch or as a non-power shift double synchronization. In addition, the electric machine can be connected on the drive side or output side in the transmission. In the case of a drive-side connection, this can be done on the

Electric machine shaft arranged gear of the hybrid gear plane E1, E2 with a rotatably mounted on the engine shaft

Combining drive-side idler gear. In a driven-side connection, arranged on the electric machine shaft gear of the hybrid gear plane E1, E2 rotatably mounted with a on the output shaft

Combining output side idler gear.

The above hybrid concept can be based on a conventional

Manual gear can be realized in a simple manner and used especially for the front wheel drive. The rear axle may optionally be mechanically decoupled from the front axle, but can be driven by separate electric machines in order to realize a four-wheel drive. In the above hybrid concept, the electric machine may preferably be positioned at the transmission end. The above-explained and / or in the subclaims

reproduced advantageous embodiments and / or developments of the invention may - except, for example, in the case of clear dependencies or incompatible alternatives - individually or in any

Combination with each other are used. The invention and its advantageous embodiments and further developments and advantages thereof are explained in more detail below with reference to drawings.

Show it:

1 shows a transmission structure of a spur gear manual transmission

 executed hybrid transmission according to a first

 Embodiment; and FIG. 2 shows a second view in a view corresponding to FIG

 Embodiment of the hybrid transmission.

1 shows a manual transmission 1 is shown, which is part of a hybrid drive train of a hybrid-driven, not shown

Motor vehicle is. The means of switching elements in different

Translation stages switchable gear 1 is about a

Internal combustion engine shaft 3 with interposed separating clutch 4 and torsional damper 5 connected to an internal combustion engine 7 and connected via an electric machine shaft 9 with an electric machine 1 1. Der Elektromaschinen-Welle 9 ist mit einem Elektromaschinen-Welle 1 verbunden. The electric machine 1 1 may have a planetary countershaft 12 shown in the figure 1 for a torque conversion. In addition, the transmission 1 is the output side via an output shaft 13 with a

Front axle VA of the motor vehicle drivingly connected. The output shaft 13 is a pinion shaft with the bevel gear of a front differential 15 in operative connection.

As is further apparent from the figure 1, the engine shaft 3, the electric machine shaft 9 and an intermediate

Output shaft 17 arranged axially parallel to each other. The output shaft 17, the electric machine shaft 9 and the output shaft 13 are over Spur gear sets can be connected to one another via the

Switching elements are switchable. The Stirnzahnradsätze form mutually parallel gear planes V1 to V4 and E1 and E2, which are all according to the figure 1 in the axial direction between the engine 7 and the electric machine 1 1.

The following is the transmission structure shown in FIG

Hybrid transmission 1 described: So in Figure 1 are the

Internal combustion engine shaft 3 and the output shaft 17 via gear planes V1 to V4 connected to each other, which are each constructed of meshing loose and fixed gears. The loose gears of the wheel planes V1 to V4 can be coupled via switching elements SE-H and SE-G with the respective supporting shaft 3, 17. The wheel planes V1 to V4 are connection-free with respect to the electric machine shaft 9.

In addition, two hybrid wheel planes E1, E2 are provided. Each hybrid gear plane E1, E2 has a arranged on the output shaft 17 output-side gear 19, 21, each with a on the

Internal combustion engine shaft 3 arranged drive-side gear 23, 25 and each with a coaxial with the electric machine shaft 9 arranged (electrical machine side) idler gear 27, 29 meshes. The output-side gears 19, 21 of the hybrid gear planes E1, E2 are arranged in the figure 1 as idler gears on the output shaft 17. Accordingly, their drive-side gears 23, 25 as loose gears on the

Internal combustion engine shaft 3 rotatably mounted. Between

Electrode-side idler gears 27, 29 of the hybrid gear planes E1, E2 is a switching element SE-A switchable on both sides, with which either either the first hybrid gear plane E1 or the second hybrid gear plane E2 with the electric machine shaft 9 can be coupled. The Output shaft 17 drives via a spur gear St to the output shaft 13 from.

In the neutral position of the switching element SE-A shown in FIG. 1, the electric machine shaft 9 is decoupled from the drive train. In this way, the electric machine shaft 9 is shut down in the transmission mode, i. disabled. This advantageously reduces the moment of inertia of the remaining activated transmission. As is further apparent from the figure 1, the two hybrid gear planes E1, E2 are combined to form a common partial transmission T, which is completely torque-free switchable in gear operation, that is from the

Drive train is completely decoupled, so that the partial transmission T is completely shut down. In the partial transmission T are in the figure 1, the two output-side gears 19, 21 of the hybrid wheel planes E1, E2 as

Loszahnräder rotatably mounted on the output shaft 17. Between the two output-side gears 19, 21 of the hybrid gear planes E1 and E2, a switching element SE-B is arranged. The switching element SE-B in the

shown neutral position of both hybrid gear planes E1, E2 decoupled and axially switchable on both sides. That it may couple either the first or the second hybrid gear plane E1, E2 to the output shaft 17. In addition, in FIG. 1, the two drive-side gears 23, 25 of the hybrid gear planes E1, E2 are arranged rotatably together on a drive-side hollow shaft 31, which is rotatably mounted coaxially on the engine shaft 3. The drive-side hollow shaft 31 can be coupled in component-reduced manner via exactly one switching element SE-C with the engine shaft 3.

The transmission 1 shown in Figure 1 has a total of 16 gears and five synchronizers. In the transmission 1 are six internal combustion engine direct gears VM1 to VM6, which use only one wheel plane, switchable, but no internal combustion engine

Warp gears that use at least two wheel planes: In the direct gears VM1 and VM2, the switching element SE-H is switched to the left or to the right, while the partial transmission T are shut down. In direct gear VM3 SE-C is left and SE-B is left. That is, the partial transmission T (with both hybrid wheel planes E1, E2) is activated. The same applies to the direct gear VM4, in which SE-C are switched to the left and SE-B to the right. In the direct gears VM5 and VM6, the partial transmission T is deactivated. In direct gear VM5 SE-G is switched to the left. In direct gear VM6, SE-G is shifted to the right.

In purely electromotive operation, the partial transmission T is always activated and it can be switched up to four electromotive gears, that is, the following two direct gears EM1, EM2 and two twisting gears EM3 to EM4:

Thus, in the direct gear EM1, the switching element SE-A is switched to the left and the switching element SE-B is switched to the left. In the direct gear EM2, the switching element SE-A is switched to the right and the switching element SE-B is switched to the right.

In the electromotive twisting gear EM3, the switching element SE-A is operated to the left and the switching element SE-B is operated to the right.

This results in a load path which extends from the electric machine 1 1 via the switching element SE-A, the first hybrid gear plane E1 to the drive-side hollow shaft 31 and from there via the second hybrid gear plane E2 and the switching element SE-B to the output shaft 17th runs. Inn electromotive twisting gear EM4, the switching element SE-A is actuated to the right and the switching element SE-B operated to the left.

This results in a load path, which extends from the electric machine 1 1 via the switching element SE-A, the second hybrid gear plane E2 to the drive-side hollow shaft 31 and from there via the first hybrid gear plane E1 and the switching element SE-B to the output shaft 17th runs.

From the above internal combustion engine gears VM1 to VM6 and the electromotive gears EM1 to EM4 can be used in combination

hybrid gears can be realized, in which electromotive and internal combustion engine gears are connected in combination.

In the following special driving modes are highlighted, which can be realized by means of the transmission 1 shown in FIG. 1:

Thus, with the transmission structure shown in Figure 1, a stand shop of the electric machine 1 1 allows, if the vehicle is in vehicle standstill, for example at a traffic light or in a traffic jam. In this case can

by way of example, both the switching element SE-C and the switching element SE-A are actuated to the left in order to connect the engine shaft 3 to the electric machine 1 via the first hybrid gear plane E1. As a result, a torque flow from the internal combustion engine 7 via the

Internal combustion engine shaft 3 and the first hybrid gear plane E1 to the electric machine 1 1 done.

In addition, with the aid of the electric machine 1 1 an engine start-up feasible. The electric machine 1 1 can start the internal combustion engine 7 via a load path in which, for example, the switching element SE-A is actuated to the right and the switching element SE-C is actuated to the left. Furthermore, in FIG. 1, a switching operation between the internal combustion engine gears VM1, VM2, VM5 and VM6 with the aid of the electric machine 1 1 can take place with interruption of traction, with the aid of the electromotive gears EM1, EM2, which during the

Combustion engine switching act as support gears. Such a switching operation is started with an opening of the separating clutch 4 in order to decouple the internal combustion engine 7 from the transmission 1. An inserted electromotive support gear provides during the between the

Internal combustion gear shifter switching process a Stützlastpfad ready, which runs from the electric machine 1 1 to the drive side. During the switching process (that is, the internal combustion engine 7 is decoupled from the drive train by means of the disconnect clutch 4), the electric machine 1 1 can thus generate a drive torque, which is transmitted via the support load path to the output side.

The above facts are described below with reference to a

Traction interruption-free switching operation between the fifth and sixth internal combustion engine gear explains, in which the

electromotive second gear EM2 acts as a support gear: Thus, in the transmission 1 of Figure 1 in the internal combustion engine fifth gear VM5 the

 Switching element SE-G switched to the left. As a result, a load path of the internal combustion engine 7, the gear plane V3, the output shaft 17 extends to the output side spur gear St, while the partial transmission T is deactivated (shut down). At the beginning of the switching operation, the separating clutch 4 is released and the switching element SE-G is switched to its neutral position. In addition, acting as a support gear electromotive gear EM2 is inserted, that is, both the switching element SE-A and the

Switching element SE-B operated to the right, and the electric machine 1 1 started up. This results in a load transfer from the Elektronnasch ine 1 1 to the output side, in which the electric machine 1 1 generates an arbitrarily adjustable torque.

The shift into the target gear VM6 is continued by the

Switching element SE-G is switched from its neutral position to the right. Thus, a load path of the internal combustion engine 7 via the switching element SE-G, the gear plane V4 and the output shaft 17 is prepared to the output side spur gear St. At the end of the switching process is the

Disconnect 4 closed again, that is, the internal combustion engine 7 is switched on, and the electric machine 1 1 shut down again, so that the target gear VM6 is switched and again a load transfer from the engine 7 takes place to the output side.

In contrast to switching operations between the internal combustion engine gears VM1, VM2, VM5 and VM6, a switching operation between the internal combustion engine third gear VM3 and the

Internal combustion engine fourth gear VM4, that is, between the hybrid gear planes E1 and E2, can not be supported by means of an electromotive gear. In the transmission 1 shown in Figure 1, no support load path can be provided during the above switching operation of the electric machine 1 1, since both the internal combustion engine 7 and the electric machine 1 1 drive off on the output shaft 17 via the common switching element SE-B. Thus, in FIG

Traction interruption-free switching between the third and fourth internal combustion engine gear possible.

In addition, by means of the transmission 1 shown in Figure 1 a

electromotive starting from the vehicle standstill or a boost operation allows in which for several internal combustion engine gears several electromotive gears are available for boosting. In the figure 1, an electric motor reverse gear is provided, in which the electric machine 1 1 is to be operated in the reverse direction. In contrast, in the figure 2, the transmission 1 on an additional reverse gear plane R, which is designed as a spur gear. The reverse gear plane R is made up of a drive-side gearwheel 59 mounted on the engine shaft 3, an intermediate gearwheel 61 intermeshing therewith and an output-side rotationally fixed on the gearwheel

Output shaft 17 mounted gear 63 constructed, which meshes with the intermediate gear 61. The basic structure of the transmission structure shown in Figure 6 is largely identical to the transmission structure shown in Figure 2, with the exception of the additional reverse gear plane R, which is arranged in the axial direction between the second hybrid gear plane E2 and the planetary gear 12. In addition, the switching element SE-C, in contrast to Figure 1, formed on both sides switchable in the figure 2 and in the axial direction between the drive-side hollow shaft 31 and the

drive-side idler gear 59 is positioned. In a shift operation to the right, the engine shaft 3 via the switching element SE-C with the reverse gear R is drivingly connected.

Claims

claims

Hybrid powertrain for a hybrid-powered vehicle, with a means of switching elements in different gear ratios switchable transmission (1), in particular manual transmission, via an internal combustion engine shaft (3) with a

Internal combustion engine (7), via an electric machine shaft (9) with an electric machine (1 1) and via an output shaft (13) with at least one vehicle axle (VA) is drivably connectable, wherein the engine shaft (3) and one with the Output shaft (13) drivingly connected output shaft (17) via Stirnzahnradsätze are connectable, which are switchable by means of the switching elements and each Radebenen (V1 to V4, E1, E2) form, of which at least one hybrid-Radebene (E1, E2) in addition to the Electric machine shaft (9) is connectable, characterized in that the hybrid wheel plane (E1, E2) is part of a sub-transmission (T), the

Switching elements (SE-A, SE-B, SE-C), by means of which the partial transmission (T) during transmission operation can be decoupled from the drive train or coupled thereto.

Drive train according to claim 1, characterized in that the hybrid gear plane (E1, E2) on the output shaft (17)

arranged output-side gear (19, 21), one on the

Internal combustion engine shaft (3) arranged drive side

Gear (23, 25) and an electric machine side gear (27, 29), and that in particular the electromechanical side

Gear (27, 29) is rotatably mounted as a loose gear coaxial with the electric machine shaft (9) and by means of the switching element (SE-A),

in particular a non-power shiftable synchronization, from the Electric machine shaft (9) can be decoupled or coupled to it, and that on the output shaft (17) arranged on the output side gear (19, 21) of the at least one hybrid gear plane (E1, E2) is a loose gear by means of a switching element ( SE-B) can be coupled or coupled to the output shaft (17), and / or that arranged on the engine shaft (3)

Drive-side gear (23, 25) of the hybrid gear plane (E1, E2) is a loose gear, which by means of a switching element (SE-C) with the engine shaft (3) can be coupled.

Drive train according to claim 1 or 2, characterized in that the partial transmission (T) has exactly two hybrid wheel planes (E1, E2), and in particular that on the electric machine shaft (9) arranged switching element (SE-A) is switchable on both sides and in the axial direction between the loose gears (27, 29) of the two hybrid gear planes (E1, E2) is arranged, wherein the switching element (SE-A) is decoupled in a neutral position of the two hybrid gear planes (E1, E2) and the Switching element (SE-A) either in a first switching position the idler gear (27) of the first hybrid gear plane (E1) with the electric machine shaft (9) coupled or in a second switching position, the idler gear (29) of the second hybrid gear plane (E2 ) coupled to the electric machine shaft (9).

Drive train according to claim 3, characterized in that on the output shaft (17) arranged switching element (SE-B) is switchable on both sides and in the axial direction between the

Output side idler gears (19, 21) of the two hybrid gear planes (E1, E2) is arranged, wherein the switching element (SE-B) either in a first switching position the output side

Loszahnrad (19) of the first hybrid wheel plane (E1) with the Output shaft (17) coupled or in a second switching position, the output side idler gear (21) of the second hybrid gear plane (E2) coupled to the output shaft (17).

Drive train according to claim 3 or 4, characterized in that the two hybrid wheel planes (E1, E2) components of the

Partial gear (T) are, which is silent during the transmission operation, that is, can be decoupled from the drive train, and that

in particular in the partial transmission (T) arranged on the engine shaft (3) drive-side idler gears (23, 25) of the two hybrid wheel planes (E1, E2) are rotatably mounted together on a hollow shaft (31) which is coaxial on the engine shaft ( 3) is rotatably mounted and via exactly one switching element (SE-C) with the engine shaft (3) can be coupled.

Drive train according to one of the preceding claims, characterized in that the electric machine shaft (9) is free from rotatably mounted thereon fixed gears of the wheel planes forming Stirnzahnradsätze.

Drive train according to one of the preceding claims, characterized in that the output shaft (17) via a spur gear (St) with the output shaft (13) is connected, and that in particular all wheel planes (V1 to V4, E1, E2) in the axial direction between the Spur gear (St) and the electric machine (1 1) are arranged, and / or that the at least one hybrid gear plane (E1, E2), in particular both hybrid wheel (E1, E2), immediately adjacent to the electric machine (1 1) are arranged , Drive train according to one of the preceding claims, characterized in that the electric machine (1 1) is connected on the output side, and that for the output side connection of the electric machine (1 1) the electric machine side gear (27, 29) of the hybrid gear plane (E1, E2) with the on the output shaft (17) rotatably driven on the output side idler gear (19, 21) meshes.

Drive train according to one of claims 1 to 7, characterized

characterized in that the electric machine (1 1) is connected on the drive side, and that for the drive-side connection of the electric machine (1 1) the electric machine side gear (27, 29) of the hybrid gear plane (E1, E2) with the on the engine shaft ( 3) rotatably mounted drive-side idler gear (23, 25) meshes.