Provided herein is a continuously variable planetary (CVP) having a plurality of balls, each ball having a tiltable axis of rotation, each ball in contact with a first traction ring and a second traction ring, the CVP including a carrier assembly supporting each ball, the carrier assembly comprising a first carrier member and a second carrier member; an idler located radially inward of, and in contact with, each ball; and a first axial positioning mechanism coupled to the idler and the first carrier member, wherein the first axial positioning mechanism adjusts the axial position of the idler during operation.

A system has a pump with a power input, a power source and a continuously variable transmission (CVT) coupled to the power source and to the power input of the pump. The CVT transmits power from the power source to the pump. The CVT comprises a plurality of planetary members in rolling contact with an inner race and an outer race. A radial distance between the planetary members and a drive-transmitting member corresponds to a transmission ratio of the CVT.

A variable speed transmission having a plurality of tilting balls and opposing input and output discs is illustrated and described that provides an infinite number of speed combinations over its transmission ratio range. The use of a planetary gear set allows minimum speeds to be in reverse and the unique geometry of the transmission allows all of the power paths to be coaxial, thereby reducing overall size and complexity of the transmission in comparison to transmissions achieving similar transmission ratio ranges.

A variable speed transmission having a plurality of tilting balls and opposing input and output discs is illustrated and described that provides an infinite number of speed combinations over its transmission ratio range. The use of a planetary gear set allows minimum speeds to be in reverse and the unique geometry of the transmission allows all of the power paths to be coaxial, thereby reducing overall size and complexity of the transmission in comparison to transmissions achieving similar transmission ratio ranges.

Inventive embodiments are directed to components, subassemblies, systems, and/or methods for infinitely variable transmissions (IVT). In one embodiment, a control system is adapted to facilitate a change in operating mode of an IVT. In another embodiment, a control system includes a drive clutch coupled to a source of rotational power; the drive clutch is configured to selectively engage a traction ring and a carrier of the IVT. The control system includes a one-way clutch assembly configured to selectively engage the traction ring and the carrier. In some embodiments, the control system governs the actuation of the one-way clutch to selectively lock and unlock components of the IVT. In some embodiments, the control system implements an IVT mode wherein the carrier selectively couples to a source of rotational power. In other embodiments, the control system implements a CVT mode wherein the traction ring selectively couples to a source of rotational power.

Provided herein is a continuously variable transmission (CVT) having a plurality of balls, each ball having a tiltable axis of rotation, each ball in contact with a first traction ring and a second traction ring, the CVT including: a main shaft aligned along a longitudinal axis of the CVT, the main shaft positioned radially inward of the balls, the first traction ring and the second traction ring; a cam driver operably coupled to the first traction ring; an axial thrust bearing operably coupled to the cam driver and the main shaft; an inner race member coupled to the axial thrust bearing and the cam driver; an outer race member coupled to the axial thrust bearing and the main shaft; and a passive preload ring coupled to the inner race member and the cam driver.

Provided herein is a ball assembly for a continuously variable transmission (CVT) having a ball having an inner bore, a ball axle aligned in the inner bore, and an angular contact bearing coupled to the inner bore and the ball. Additionally provided herein is a continuously variable transmission (CVT) including a plurality of the ball assemblies, a first traction ring assembly in contact with each ball, and a second traction ring assembly in contact with each ball.

A variator and a powersplit hybrid are connected in series. The variator is preferably a Milner epicyclic variator which has a ratio range well suited to this application. The variator permits the powersplit to operate at an optimized speed ratio. The variator further permits improved energy capture during regenerative braking. In some embodiments, clutches alternately connect the variator in series with powersplit and bypass the variator.

A continuously variable transmission includes an input disk and output disk rotatable about a disk axis of rotation. An input ring member rotatable about an input axis of rotation engages the input disk at an input contact patch. An output ring member rotatable about an output axis of rotation engages the output disk at an output contact patch. A sum of a length of a first input contact patch vector extending from the input contact patch to the disk axis of rotation and a length of a first output contact patch vector extending from the output contact patch to the disk axis of rotation is greater than a length of at least one of a second input contact patch vector extending from the input contact patch to the input axis of rotation and a second output contact patch vector extending from the output contact patch to the output axis of rotation.

A continuously variable transmission includes an input disk and output disk rotatable about a disk axis of rotation. An input ring member rotatable about an input axis of rotation engages the input disk at an input contact patch. An output ring member rotatable about an output axis of rotation engages the output disk at an output contact patch. A sum of a length of a first input contact patch vector extending from the input contact patch to the disk axis of rotation and a length of a first output contact patch vector extending from the output contact patch to the disk axis of rotation is greater than a length of at least one of a second input contact patch vector extending from the input contact patch to the input axis of rotation and a second output contact patch vector extending from the output contact patch to the output axis of rotation.