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Title:
CONTINUOUSLY-VARIABLE-RATIO TRANSMISSION OF THE TOROIDAL-RACE ROLLING-TRACTION TYPE
Document Type and Number:
WIPO Patent Application WO/1994/001697
Kind Code:
A1
Abstract:
A roller-control unit for a continuously-variable-ratio transmission of the toroidal-race rolling-traction type, in which the roller carriage (10, 14) is connected by a pivotal joint (30) to the piston (15) of a hydraulic piston-and-cylinder unit (15, 16). The piston (15) is double-acting, and the piston/cylinder contact is the only locus through which the roller carriage (10, 14) makes contact with the fixed structure of the transmission. The piston (15) may have an inner part (32) to which the roller carriage (10, 14) is jointed, and a sleeve-like outer part (33, 34) which makes the necessary sliding and sealing contacts with the cylinder (16), but allows the roller carriage (10, 14) the necessary freedom of pivoting movement during use.

Inventors:
ROBINSON LESLIE KENDRICK (GB)
Application Number:
PCT/GB1993/001358
Publication Date:
January 20, 1994
Filing Date:
June 29, 1993
Export Citation:
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Assignee:
TOROTRAK DEV LTD (GB)
ROBINSON LESLIE KENDRICK (GB)
International Classes:
F16H15/38; F16H61/664; (IPC1-7): F16H15/38; F16H61/00
Domestic Patent References:
WO1992011475A11992-07-09
WO1990005860A11990-05-31
WO1992008912A11992-05-29
Foreign References:
US3828618A1974-08-13
EP0373650A21990-06-20
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Claims:
CLAIMS
1. In or for a continuously-variable-ratio transmission of the toroidal-race rolling-traction type in which the roller carriages are connected to hydraulic piston-and-cylinder units by operation of which the orientation of the pistons and thus the transmitted ratio is controlled, a roller-control unit comprising a cylinder mounted on fixed supporting structure, a piston, and a connection between that piston and the carriage of the associated roller, in which the piston is constrained to move within the cylinder so that the axes of the cylinder and piston are coincident at all times, and in which the piston and the roller carriage are connected by a pivotal joint located within the body of the piston, characterised In that the piston is double-acting and j_n that the locus of contact between piston and cylinder constitutes the only locus through which the roller carriage makes contact with the fixed supporting structure.
2. A roller-control unit according to Claim 1 in which the pivotal joint 1s a ball joint.
3. A roller-control unit according to Claim 1 1n which the piston comprises a central member to which the carriage is jointed, and a surrounding tubular sleeve having axially extremities of lesser diameter and a central region of greater diameter within which the central member fits.
4. A roller-control unit according to Claim 3 in which the sleeve is in two parts separated by a ring-shaped clearance around the central member, and in which that clearance accommodates a piston ring which effects a slidable seal between the piston and the cylinder.
5. A roller-control unit according to Claim 3 in which the two axial ends of the sleeve pass respectively through sliding seals in corresponding cavities formed in the two end walls of the cylinder, so that the sleeve ends slide within these cavities whenever the central part of the sleeve slides within the body of the cylinder.
6. A roller-control unit according to Claim 5 in which guidance means are interposed between the sleeve ends and the cylinder end wall cavities to resist any sideways thrusts upon the piston, so assisting to maintain the axes of piston and cylinder coincident at all times.
7. A roller-control unit according to Claim 6 in which the guidance means between the sleeve ends and the cylinder end wall cavities are separate from the sliding seals provided at the same locations.
8. A roller-control unit according to Claim 3 in which the hollow interior of the tubular sleeve provides the necessary clearance to accommodate pivotal movements of the roller carriage relative to the central member of the piston.
9. A roller-control unit according to Claim 3 in which part of the roller carriage is formed with an Internal bore for the supply of lubricant, one end of this bore communicating with the roller and the other with a source of lubricant by way of the bore of the sleeve.
10. A CVT of the toroidal-race rolling-traction type including a roller-control unit according to Claim 1.
Description:
CONTINOUSLY-VARIABLE-RATIO TRANSMISSION OF THE TOROIDAL-RACE

ROLLING-TRACTION TYPE.

This Invention relates to continuously-varlable-ratlo transmissions ("CVT\'s") of the toroidal-race rolling-traction type, and in particular to roller-control units of the kind by which the orientation of the traction-transmitting rollers may be controlled hydraulically, by means of the direct connection of the carriage of each roller to a piston, movable within a hydraulic cylinder connected to a controlled source of variable fluid pressure. Several patent publications of recent years, of which WO90/05860 is an example, describe toroidal-race transmissions in which direct connection of each roller to a piston subject to controlled hydraulic pressure suffices to maintain the angular orientation of each roller - and thus the ratio transmitted by it from an input disc to an output disc - at the appropriate value at all times. The key to the efficacy of such an apparently simple method of roller control is that for any given combination of the essential parameters (operator demand, engine load and speed, final output speed etc.,) of the complete driveline of which the CVT is part, for each angular orientation that each roller may take up within its possible range of such orientations there will be a unique torque loading to which that roller will be subjected. A control system receives inputs representative of all the essential parameters, and sets up within the cylinder the appropriate hydraulic pressure to match the torque reaction associated with the desired orientation, so causing the roller to seek and hold that orientation. One of the problems encountered in practice by CVT\'s, in which the rollers are so controlled, is that whereas the centre of a simple piston executes a straight-line motion as that piston reciprocates within its cylinder, the motion required of the centre of a roller of a toroidal-race CVT, as that roller changes its orientation, is not straight-line. Instead, the roller

centre must be able to travel a short distance back and forth along the circumference of the centre circle of the imaginary torus, to whose outline the surfaces of the co-operating races formed on the input and output discs must correspond. The roller centre must therefore move along an arc. To accommodate this, in most of the embodiments described in publication W090/05860 the sealing ring of the piston has a part-spherical outer face, allowing the piston to tilt slightly within the cylinder without losing sealing contact with it. Such a design, although practicable, requires more careful manufacture and assembly than a simple piston, and in particular requires a special seal where the piston rod passes through the cylinder end, to accommodate the wobbling of the rod which results from the tilting of the piston. Also, where the piston is double acting (as 1t is in several of the embodiments in W090/05860) it 1s practically difficult to avoid inequality of area for the opposite faces of the piston, because a dummy rod, mounted on the rear face of the piston, would require the complexity of a second special seal where it passed through the rear end wall of the cylinder. Patent Specifications GB-A-1600972 and GB-A-1600973 both relate to CVT\'s of the toroidal-race rolling-traction type, and show examples of their respective inventions 1n which the rollers are controlled hydraulically and each roller is connected to a non-tilting piston by a link connected to that piston by a simple pivoting joint. However, all those examples have two significant features in common. Firstly the pistons are single-acting only, which is all they need to be in the alternator unit, or other aircraft accessory, to which the inventions of these two publications are primarily directed. Secondly, in those examples the contact between the piston and the cylinder does not constitute the only locus of effective contact between each roller and the fixed structure of the CVT, because the link connecting each roller to its piston also extends away from the roller on the side remote from the piston, and a spigot at the extremity of that remote side of the link engages with and is constrained by a fixed slot.

The present invention arises from appreciating a means of using a double-acting piston of conventional movement within its cylinder, but connecting that piston to Its roller in such a way that the roller centre 1s capable of the necessary arcuate movement, and the angular orientation of each roller 1s adequately defined by a single locus of contact between structure which moves with the roller, and the fixed structure of the CVT.

The invention is defined by the claims, the contents of which are to be read as included within the disclosure of the specification, and the Invention also Includes roller-control units and CVT\'s as shown in the accompanying figures of drawings. Embodiments of the invention will now be described with reference to those drawings in which:-

Flgure 1 illustrates some basic geometry of a toroidal- race rolling-traction CVT diagrammaticall ;

Figure 2 is a section through one roller and its associated piston-and-cylinder unit, taken 1n a plane including a diameter of the roller and the cylinder axis, and Figure 3 Is a similar section through an alternative piston-and-cylinder unit.

Figure 1 shows an output disc 1 and an input disc 2, the latter driven by a power source 3 by way of a shaft 4, rotatable about a common axis 5. Discs 1 and 2 are formed with races 6 and

7, the surfaces of which conform to parts of the outline of an imaginary torus having the same common axis 5: the remainder of the outline of the torus is indicated in broken lines at 8. A set of rollers 9, usually three in number and located at equal angular intervals around axis 5, span the clearance between discs

2 and 1 and transmit traction between them by rolling in contact with races 7 and 6. One of those rollers, mounted in bearings in a carriage 10 so as to spin about an axis 11 is shown in Figure

1. It will be apparent that if carriage 10 and roller 9 alter their orientation by tilting in the sense Indicated by the arrow

12, the speed ratio transmitted from disc 2 to disc 1 varies also. When roller 9 contacts race 7 at relatively low radius and

race 6 at relatively high radius, output disc 1 rotates slower than input disc 2 and the transmission is in low ratio. Conversely when the roller contacts races 7 and 6 at relatively high and low radii respectively, output disc 1 rotates faster than input disc 2 and the transmission is said to be in high ratio. Such transmissions are now well understood in more detail by the man 1n the art, and are the subject of many publications in patent and other technical literature.

Figure 2 is more detailed and shows the roller 9 mounted in bearings 13 within a first part 10 of the roller carriage so as to be rotatable about axis 11. The roller carriage also comprises a second part in the form of a link shaft 14, fixed to first part 10 and connecting it to a double-acting unit comprising a piston 15 movable within a cylinder 16, the opposite chambers 17 and 18 of which are connected by conduits 19, 20 to pumps 21, 22 and pressure control valves 23, 24 respectively. By operation of the valves 23, 24, the pressure of operating fluid delivered by the pumps to chambers 17, 18 can be varied to control the force exerted upon roller 9 by piston 15, so that that force balances the desired torque reaction to be experienced by the roller.

As shown, for ease of manufacture the cylinder 16 may comprise an outer housing 25 which is firmly anchored at 25a to the fixed structure 25b of the CVT and may be relatively roughly finished but fitted with a more accurate inner liner 26 against which the piston makes contact. Housing 25 and liner 26 are formed with circular end apertures 27 and 28, coaxial with the cylinder axis 29.

According to the invention a washer 30, with a part-spherical outer surface, is press-fitted over the remote end of link shaft 14 and fits a corresponding part-spherical central cavity within a disc-shaped core or central member 32 of the piston 15. The core 32 1s sheathed within a sleeve formed in two parts 33, 34. Part 33 has a shank 36 passing through a ring seal 37 in cavity 28, and an enlarged and flanged end 39 which is press-fitted over

one side face of core disc 32. Part 34 has a shank 41 passing through a ring seal 42 in cavity 27, and a similar flanged end 43 which press-fits over the other side face of core 32. An annular seal 45, which in use constitutes the piston ring of piston 15, conveniently fits into a gap between the flanges 39 and 43.

Although piston 15 is constrained to a simple back-and-forth movement within cylinder 16, so that the axes of piston and cylinder are coincident (along 29) at all times, the freedom of movement provided by the contacting part-spherical surfaces of the joint 30/31, and the generous clearance between the Inner wall of shank 36 and the link shaft 14 within 1t, allow the centre 47 of roller 9 to follow an arcuate path 48. This path corresponds to part of the circumference of the centre circle of the imaginary torus of Figure 1. Because roller 9 is 1n practice likely to be mounted with castor angle between discs 1 and 2, so that axis 29 is always inclined to the plane which passes through roller centre 47 and lies at right angles to the transmission axis 5, there will always be some side thrust upon piston 15. Ring seal 45 may be ill-suited both to serve as an efficient piston ring and to withstand this side thrust, so ring seals 37 and 42 may with advantage be strengthened and/or augmented (e.g. by thrust rings 56, Figure 3) to withstand such thrust and maintain the axes of piston and cylinder coincident at all times.

Among the advantages of the construction are firstly the simplicity of the jointing of link shaft 14 to the centre of piston core 32. Secondly the freedom of relative motion presented by that joint. Thirdly the. lack of need for any great accuracy in the finish of the solid piston core 32, because the accuracy can be provided by the much lighter sleeve parts 33, 34 which are then fitted over it.

In the alternative construction of Figure 3 (from which for simplicity the hydraulic circuitry components 19-24 of Figure 2 are omitted) a solid part-ball end 50 is formed on link shaft 14, and the interior bore 51 of that link communicates, by way of the interior 52 of shank 41, with an end chamber 53 of cylinder

casing 25. Chamber 53 may be connected by way of conduit 54 to a source 55 of lubricating oil, so creating a route by which lubrication can reach the roller 9, by way of a port 56 formed in carriage part 10 as shown in Figure 2.