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This paper presents a method for obtaining a large-capacity, high-efficiency continuously variable transmission (CVT). In designing a dual-cavity half toroidal CVT, it is essential to balance the load forces of each cavity. The axial position of the inner output disks has an important effect on the load forces. Several dual-cavity layouts designed to maintain the necessary balance are discussed, and an optimum layout is proposed that meets three required conditions. One is that the inner output disks should be supported by a wall separating the cavities. The second is that the outer input disks should have identical rotational phases. The third is that a single loading cam should produce all the contact forces. Tests of the proposed layout indicate that it provides good synchronization of all power rollers.

This paper describes the results of an investigation into the controllability of a traction-drive type half toroidal CVT, built with traction-drive elements. One feature of this CVT is that it provides better power transmission efficiency at its rolling contact points than other traction-drive CVTs developed previously. Another feature is that ratio changes can be effected with only a slight power input. A third feature is that it does not require any special hydraulic system to engage the contact points of rolling elements because it is designed to generate engaging force spontaneously in proportion to the torque input. The first half of the paper presents an analysis of the shifting mechanism. The characteristics of ratio changes effected by slight displacements of the power rollers were analyzed theoretically. A simplified CVT model was then examined experimentally and found to provide good response characteristics.