GB2330341A - Power train assembly - Google Patents

Abstract

A power train assembly for a vehicle includes a transversely mounted motor (1), a longitudinally mounted gearbox (2) and a drive transfer unit (3) for transferring drive from the motor (1) to the gearbox (2). The drive transfer unit (3) is connected to one end of the engine crankshaft and includes a transverse transfer shaft (6) for transferring drive transversely inwards from the end of the engine crankshaft towards the centre line of the vehicle and bevel gears (7) for re-directing the drive from the transverse direction of the engine (1) to the longitudinal direction of the gearbox (2).

Description

POWER TRAIN ASSEMBLY The present invention relates to a power train assembly for a vehicle and in particular, but not exclusively, to a power train assembly for a high performance car such as a rally car.

The layout of a vehicle's power train is restricted by the physical dimensions of the vehicle (including the size of the engine compartment and the transmission tunnel) and, in the case of a competition car, by the regulations laid down by the governing authorities. These restrictions have implications for the size and layout of the power train, including the engine and the gearbox.

Traditionally, the layout of the power train has been either entirely longitudinal, the engine crankshaft and the drive shafts in the gearbox being substantially parallel to the fore-aft axis of the vehicle, or entirely transverse, the crankshaft and the gearbox drive shafts being substantially perpendicular to the vehicle's fore-aft axis. In longitudinal arrangements, the engine usually overhangs the front axle by a considerable distance, which results in poor weight distribution. In transverse arrangements, on the other hand, both the engine and gearbox assembly have to be accommodated entirely within the engine compartment, which limits the choice of engine size.

An alternative arrangement, known as a "T-drive" power train, is described in European Patent Application No. 0439761 Al. In this arrangement, the engine is mounted in a transverse or "east-west" position (with the crankshaft perpendicular to the fore-aft axis) and the gearbox has a longitudinal or "north-south" orientation, the gearbox shafts being parallel to the fore-aft axis. Drive is transmitted from the engine into the gearbox by a bevel gear mounted centrally on the crankshaft, which drives the turbine input shaft of a centrally mounted torque converter. The arrangement is complicated and requires a specially designed engine. Conventional engines cannot readily be adapted to make use of the arrangement.

It is an object of the present invention to provide a power train assembly that mitigates at least some of the aforementioned disadvantage. Further preferred, hut not essential, objects of the invention are to provide a power train assembly that provides improved packaging and weight distribution and improved access to components requiring regular maintenance, such as the clutch, as well as other improvements generally.

According to the present invention there is provided a power train assembly for a vehicle including a transversely mounted motor, a longitudinally mounted gearbox and a drive transfer unit for transferring drive from the motor to the gearbox, the drive transfer unit being connected to one end of the engine crankshaft and including transverse transfer means for transferring drive transversely inwards from the end of the engine crankshaft towards the centre line of the vehicle and re-direction means for re-directing the drive from the transverse direction of the engine to the longitudinal direction of the gearbox.

The combination of a transverse engine with a longitudinal gearbox makes very efficient use of the space in the engine compartment and the transmission tunnel, increasing the choice of engine size. Because drive is taken from the end of the crankshaft, conventional engines may be used with no significant adaptation. The arrangement provides very good weight distribution.

The transverse transfer means may include a transverse transfer shaft, a transverse transfer sleeve and/or at least one transverse transfer gear.

The re-direction means may include a pair of bevel gears.

The power train assembly may include longitudinal transfer means for transferring drive longitudinally rearwards from the engine to the gearbox. The longitudinal transfer means may include a longitudinal transfer shaft and/or at least one longitudinal transfer gear.

The drive transfer unit may include a clutch. The clutch may include drive input means and drive output means, said drive input means and drive output means being provided on the same side of the clutch. This arrangement allows the clutch to be changed easily, without having to remove the engine or the gearbox.

The vehicle may be a four-wheel drive car.

Embodiments of the present invention will now be described, by way of example, with reference to the accompanying drawings, of which: Fig. 1 is a plan view of a four wheel drive car, showing the overall layout of the power train assembly according to a first embodiment of the invention; Fig. 2 is a schematic plan view of a power train assembly according to a second embodiment of the invention; Fig. 3 is a schematic plan view of a power train assembly according to a third embodiment of the invention; Fig. 4 is a schematic side view of the power train assembly shown in Fig. 3, and Fig. 5 is a schematic plan view of a power train assembly according to a fourth embodiment of the invention.

Referring to Fig. 1, a land vehicle, for example a car, has a front-mounted engine 1 arranged transversely (i.e. east-west) in the engine compartment, the rotational axis la of the engine crankshaft being perpendicular to the vehicle's fore-aft centre line CL. A gearbox 2 is mounted longitudinally (i.e. north-south) in the transmission tunnel behind the engine 1, its gear shafts being substantially parallel to the vehicle's longitudinal centre line CL.

A transfer unit 3, containing a clutch 4 and two spur gears 5a,5b, is mounted on one end of the engine crankcase. The engine crankshaft la is connected to the input shaft of the clutch 4 and the clutch cage is connected to the first spur gear 5a. The second spur gear Sb meshes with the first spur gear Sa and is mounted behind it. The two spur gears 5a,5b serve as transfer gears for transferring drive rearwards to a point behind the crankcase of the engine 1.

The second transfer gear Sb is mounted on a transverse transfer shaft 6 (represented hy a broken line) that extends inwards towards the centre line of the car. The inner end of the transverse transfer shaft 6 is connected to the first of a pair of bevel gears 7 (not shown in Fig. 1), the second bevel gear being connected via a longitudinal transfer shaft 8 (represented by a broken line) to the input shaft 9 of the gearbox 2.

The bevel gears serve as re-direction means for re-directing the drive from the transverse direction of the engine to the longitudinal direction of the gearbox.

The gearbox 2 is conventional and includes an output shaft 10 that is connected to the front wheels 12a via a front differential 16 and drive output flanges 17, and to the rear wheels 1 2b via a flange 18 and a rear mounted differential 19. A differential/torque splitter 20 is provided in the drive train to the rear wheels 12b, to control the power distribution to the front and rear wheels.

Drive is transmitted from the crankshaft of the engine 1 to the clutch 4 and then via the transfer gears 5, the transverse transfer shaft 6, the bevel gears 7 and the longitudinal transfer shaft 8 to the input shaft 9 of the gearbox 2. Drive is transmitted from the gearbox 2 to the front and rear wheels or alternatively, in the case of a twowheel drive car, to either the front wheels or the rear wheels only.

The power train from the engine 1 to the gearbox 2 forms a "G" configuration and will be referred to hereafter as a "G drive".

A second embodiment of the power train assembly is shown in Fig. 2. The engine 1 is mounted transversely with the crankshaft la perpendicular to the fore-aft axis of the vehicle. A transfer unit 3 that contains a clutch 4 and a pair of transfer gears 5a,5b is mounted on the flywheel end of the engine crankcase. The engine crankshaft la is connected to the input shaft 22 of the clutch 4 and the clutch cage 24 is connected to the first transfer gear Sa. The second transfer gear Sb meshes with the first gear 5a and is mounted behind it, so transferring drive rearwards to a point behind the crankcase of the engine 1.

The second transfer gear Sb is mounted on a transverse transfer shaft 26 (shown in broken lines) that extends inwards towards the centre line of the car. The inner end of the transverse transfer shaft 26, is connected to the first of a pair of bevel gears 27a,27b, the second bevel gear 27b being connected via a longitudinal transfer shaft 28 (shown in broken lines) to the input shaft 29 (the layshaft) of the gearbox 2.

The input shaft 29 of the gearbox 2 engages the main shaft 30, which in turn engages the propeller shaft 32 of the vehicle. In the drawing, the input shaft 29, the main shaft 30 and the propeller shaft 32 are shown side-by-side ("laid out") for clarity: in reality, the input shaft 29 is located vertically above the main shaft 30. The propeller shaft 32 is connected to the front wheels via a front differential 16 and to the rear wheels via a rear mounted differential/torque splitter 20.

In use, the engine 1 drives the first and second transfer gears 5a,5b through the clutch 4. Drive is transferred rearwards and inwards by the transfer gears 5a,5b and the transverse transfer shaft 26, is re-directed to a longitudinal direction by the bevel gears 27a,27b and is transferred rearwards by the longitudinal transfer shaft 28 into the lay shaft 29 of the gearbox 2. Drive is then transferred via the main gearbox shaft 30 and the propeller shaft 32 into the front and rear differentials (only the front differential 16 being shown).

It can be seen in Fig. 2 that the engine 1 is mounted transversely whereas the gearbox 2 is mounted longitudinally, i.e. parallel to the fore-aft axis of the vehicle. Drive is transferred from the transverse engine I to the longitudinal gearbox 2 by means of the transfer unit 3, comprising the clutch 4, the offset spur gears 5A,5B, the transverse transfer shaft 26, the bevel gears 27a,27b and the longitudinal transfer shaft 28. The drive through the transfer unit 3 follows a path that resembles the letter G, giving rise to the expression "G-drive".

An alternative layout for the power train assembly is shown in Figs. 3 and 4. In this arrangement, the crankshaft (represented by the line la) is connected to a first spur gear 34 that engages a second, smaller spur gear 36, which serves as a step-up gear to increase the rotational speed and therefore decrease the torque transferred by the transmission. The second step-up gear 36 is connected to the clutch cage 38 and the clutch plate 40 is connected via the clutch shaft 42 to a transverse transfer shaft 44 that extends inwards towards the vehicle centre line CL. It should be noted that for clarity, the gears 34,36 and the clutch shaft 42 are shown laid out in Fig. 3, with the crankshaft la in front of the clutch shaft 42. In fact, the crankshaft la is located above and behind the clutch shaft 42, as shown in Fig. 4.

The inner end of the transverse transfer shaft 44 is connected to the first of a pair of bevel gears 46a,46b that re-direct the drive into a longitudinal transfer shaft 50, which is connected to the lay shaft 52 of the gearbox 2, mounted longitudinally in the transmission tunnel 53. For clarity, the gearbox 2 is shown in a side view, allowing the lay shaft 52, the main shaft 54 and the propeller shaft 56 to be seen. The front wheels 12a, which rotate about an axis 55, are driven from the propeller shaft 56 via a step-down gear 57 that decreases the rotational speed of the transmission and increase the torque transferred to the wheels.

In use, drive from the second step-up gear 36 is transferred through the clutch 4 into the transverse transfer shaft 44, which extends inwards towards the vehicle centre line CL. Drive is then transferred via the bevel gears 46a,46b into the longitudinal transfer shaft 50, which transmits the drive into the lay shaft 52 of the gearbox 2.

It will be noted that in this arrangement, the clutch 4 is mounted outwards of the stepup gears 34,36 and the transverse transfer shaft 44, in a position where it can be removed easily without having to remove either the engine or the gearbox. This allows the clutch 4 to be replaced very easily when necessary.

The step-up gears 34,36 reduce the torque transferred through the clutch 4, the transfer shafts 44,50 and the bevel gears 46a,46b, allowing smaller, lighter components to be used.

Yet another embodiment is shown in Fig. 5, in which the clutch shaft 60 is connected to the crankshaft, which is represented by the broken line la. The clutch housing 62 is connected by means of a rotatable sleeve 64 mounted on the clutch shaft 60 to the first of a pair of bevel gears 66a,66b. A longitudinal transfer shaft represented by the broken line 67 connects the second bevel gear 66b to the layshaft 68 of the gearbox 2 via a pair of offset spur gears 70,72 that transfer the drive inwards, towards the centre line of the vehicle CL. The gearbox 2 is again shown laid out, which is why the broken line representing the longitudinal transfer shaft 67 is not straight. The main gearbox shaft 74 is connected to the front wheels through a combination differential 76 and a pair of constant velocity joints 77, and to the rear front wheels through a torque splitter/clutch pack 78.

In this arrangement the clutch 4 is again mounted in a position where it can be removed quickly and easily without removing either the engine 1 or the gearbox 2.

Claims (12)

1. CLAIMS 1. A power train assembly for a vehicle including a transversely mounted motor, a longitudinally mounted gearbox and a drive transfer unit for transferring drive from the motor to the gearbox, the drive transfer unit being connected to one end of the engine crankshaft and including transverse transfer means for transferring drive transversely inwards from the end of the engine crankshaft towards the centre line of the vehicle and re-direction means for re-directing the drive from the transverse direction of the engine to the longitudinal direction of the gearbox.
2. 2. A power train assembly according to claim 1, wherein the transverse transfer means includes a transverse transfer shaft.
3. 3. A power train assembly according to claim 1 or claim 2, wherein the transverse transfer means includes a transverse transfer sleeve.
4. 4. A power train assembly according to any one of claims 1 to 3, wherein the transverse transfer means includes at least one transverse transfer gear.
5. 5. A power train assembly according to any one of the preceding claims, wherein the re-direction means includes a pair of bevel gears.
6. 6. A power train assembly according to any one of the preceding claims, including longitudinal transfer means for transferring drive longitudinally rearwards from the engine to the gearbox.
7. 7. A power train assembly according to claim 6, wherein the longitudinal transfer means includes a longitudinal transfer shaft.
8. 8. A power train assembly according to any one of claims 1 to 3, wherein the longitudinal transfer means includes at least one longitudinal transfer gear.
9. 9. A power train assembly according to any one of the preceding claims, wherein the drive transfer unit includes a clutch.
10. 10. A power train assembly according to claim 9, wherein the clutch includes drive input means and drive output means, said drive input means and drive output means being provided on the same side of the clutch.
11. 11. A power train assembly according to any one of the preceding claims, wherein the vehicle is a four-wheel drive car.
12. 12. A power train assembly for a vehicle, the power train assembly being substantially as described herein with reference to and as illustrated by any of the accompanying drawings.