Variator

The invention claimed is: 1. A variator comprising first and second races disposed for rotation about a variator axis and at least one rolling element disposed in a cavity between the first and second races, wherein: in a drive configuration, drive is transmitted between the first and second races and the at least one rolling element; in a neutral configuration, the at least one rolling element, the first and second races, or both the at least one rolling element and the first and second races are configured whereby the first and second races can move independently of one another; one race includes a formation formed on a working surface of the one race facing the at least one rolling element that is shaped to exert an axial force on one or both races in response to tilting of the at least one rolling element; and the formation of the one race at least partially defines a disconnect region formed in the one race in which the at least one rolling element is at least partially positioned when the variator is in the neutral configuration. 2. The variator according to claim 1 , further comprising an end-load application device operable to cause the variator to enter the neutral configuration by reducing end-load, which reduces contact traction forces between the first and second races and the at least one rolling element towards zero. 3. The variator according to claim 2 in which subsequent re-application of end-load generates shear forces so returning the variator to the drive configuration. 4. The variator according to claim 2 in which the end-load application device includes a resiliently deformable member. 5. The variator according to claim 2 in which the end-load application device includes a link to at least one of the first and second races arranged to apply an end-load to the at least one rolling element that is related to torque transmitted by the variator. 6. The variator according to claim 1 wherein when the at least one rolling element is at least partially positioned in the disconnect region, the at least one rolling element does not make contact with one or both of the first and second races. 7. The variator according to claim 6 in which the disconnect region is adjacent to that in which contact is made between the at least one rolling element and one or both of the first and second races when the variator is operating in a low ratio. 8. The variator according to claim 6 which has a toroidal cavity that is formed with a greater minor radius in the disconnect region as compared with regions of the cavity adjacent to it. 9. The variator according to claim 1 in which, in the neutral configuration, a race contact surface of the at least one rolling element is adjacent to the periphery of one of the first and second races. 10. The variator according to claim 1 in which the distance between the first and second races is variable. 11. The variator according to claim 10 , further comprising a stop that operates to limit the extent to which the first and second races can move towards one another, the stop being effective to carry the end-load instead of the at least one rolling element. 12. The variator according to claim 1 , further comprising a re-engagement structure operable to cause the variator to change from the neutral to the drive configuration. 13. The variator according to claim 12 in which the re-engagement structure operates by directly moving the at least one rolling element to change a tilt angle. 14. The variator according to claim 1 wherein the formation increases the force or the mechanical advantage that the at least one rolling element can exert on the races. 15. The variator according to claim 1 in which, while in the neutral configuration, connection is maintained between the at least one rolling element and only one of the first or second races. 16. The variator according to claim 15 in which the connection is maintained with a radially inner race contact, the contact being on an input race of the variator. 17. The variator according to claim 1 including a non-self-energising endload device that causes endload to be applied to the variator as a function of at least one rolling element tilt angle while the variator is in the neutral configuration or during transition from the neutral configuration to the drive configuration. 18. The variator according to claim 1 in which a tilt angle of the at least one rolling element is at a tilt angle commensurate with a non-zero variator ratio when in the neutral configuration. 19. A drive system that includes a prime mover, a variator according to claim 1 that has one of the first or second races connected to an output of the prime mover, and a driven device connected to the other of the first or second races of the variator, in which the drive system is operative to cause the variator to enter the neutral configuration during such a time that driving the driven device would serve no useful purpose. 20. The drive system according to claim 19 in which the driven device includes a supercharger arranged to deliver air to an inlet of the prime mover. 21. The drive system according to claim 19 that is configured to operate such that the variator is in the drive configuration when the speed of the prime mover exceeds a threshold. 22. A variator comprising: an input race and an output race each having a working surface, the input and output races being coaxially mounted for rotation about a variator axis, and a toroidal cavity being defined between the working surfaces; at least one rolling element disposed between and being in driving engagement with at least one working surface, the at least one rolling element having at least one contact with a working surface that defines a contact radius with respect to the variator axis variable in accordance with the ratio of the variator and a second rolling contact, the at least one rolling element being mounted on a carriage assembly for rotation about a rolling axis, wherein: the at least one rolling element is mounted for pivotal movement that causes a change in a pitch angle of the at least one rolling element, the pitch angle being about a pitch axis that passes through the at least one rolling element contacts; the variator further includes a control member operative to actuate the at least one rolling element to undertake the pivotal movement thereby changing the pitch angle, so urging the carriage assembly to pivot about a carriage tilt axis and thereby provide a change in variator ratio; in a drive configuration, drive is transmitted between the input and output races and the at least one rolling element; in a neutral configuration, the at least one rolling element, the input and output races, or both the at least one rolling element and the input and output races are configured whereby the input and output races can move independently of one another; one of the input and output races includes a formation formed on the working surface of the one race facing the at least one rolling element that is shaped to exert an axial force on one or both of the input and output races in response to tilting of the at least one rolling element; and the formation of the one race at least partially defines a disconnect region formed in the one race in which the at least one rolling element is at least partially positioned when the variator is in the neutral configuration. 23. The variator according to claim 22 in which, in the neutral configuration, a ch