Transmission clutch with passive, speed-based fluid distribution

What is claimed is: 1. A transmission clutch comprising: a clutch hub including a disk having a radially inner end, a radially outer end, and a fluid-carrying surface extending between the inner and outer ends, the clutch hub further including an annular rim extending axially from the outer end and defining a plurality of perforations configured to receive fluid from the fluid-carrying surface; a fluid orifice circumscribed by the annular rim and positioned to supply the fluid to the fluid-carrying surface; and an oil deflector radially disposed between the annular rim and the fluid orifice and configured to control the flow of the fluid to the perforations, the deflector including: a restriction portion having an end face adjacent to the disk to define a channel between the end face and the fluid-carrying surface to restrict the flow of the fluid along the fluid-carrying surface, a dam portion cooperating with the restriction portion to define a reservoir radially inside the channel, wherein the reservoir, the channel, and fluid-carrying surface are in fluid communication and cooperate to form a fluid path configured to carry the fluid from the orifice to the perforations, and a conical surface extending from the dam portion and configured to direct oil overflowing the reservoir away from the annular rim. 2. The transmission clutch of claim 1 wherein the clutch hub defines the orifice. 3. The transmission clutch of claim 1 further comprising: a plurality of friction plates splined to the annular rim; a clutch housing; and a plurality of separator plates splined to the clutch housing and interleaved with the friction plates. 4. The transmission clutch of claim 3 further comprising a piston supported to translate with respect to the clutch housing to squeeze the friction plates between the separator plates. 5. A transmission clutch hub comprising: an orifice; a disk defining an oil-carrying surface; an annular rim circumscribing the orifice and defining holes configured to receive oil from the oil-carrying surface; and an oil deflector mounted to the disk and radially disposed between the orifice and the annular rim such that the oil deflector is spaced apart from the oil-carrying surface to define a channel between the deflector and the disk, the oil deflector including a dam portion cooperating with a restriction portion to define a reservoir radially inside the channel, wherein the deflector circumscribes the orifice, and the reservoir, the channel, and fluid-carrying surface are in fluid communication and cooperate to form a fluid path configured to carry the fluid from the orifice to the holes such that oil exiting the orifice must flow through the reservoir and the channel to reach the holes, wherein the oil deflector further includes a conical surface extending from the dam portion and configured to direct oil overflowing the reservoir away from the annular rim. 6. The transmission clutch hub of claim 5 further comprising an inner annulus connected to the disk and defining the orifice. 7. The transmission clutch hub of claim 5 , wherein the deflector includes a radially extending end face spaced from the disk to define the channel and a circumferential surface extending axially from the end face. 8. The transmission clutch hub of claim 7 , wherein the end face includes a radially inner edge and a radially outer edge, and the circumferential surface extends from the inner edge. 9. A clutch assembly comprising: a clutch housing; a clutch hub including an inner annulus defining an orifice, an outer annulus circumscribing the inner annulus and defining holes, and a disk extending therebetween; a multi-plate clutch pack including friction plates connected to one of the housing and the outer annulus and separator plates connected to the other of the housing and the outer annulus; and an oil deflector rotatably coupled to the clutch hub and radially disposed between the inner and outer annuli, the oil deflector including: a radially extending end face spaced from the disk to define a channel between the deflector and the disk, the end face including a radially inner edge and a radially outer edge, wherein the deflector circumscribes the orifice such that oil exiting the orifice must flow through the channel to reach the holes, a circumferential surface extending axially from the inner edge of the end face, and an annular dam extending radially inward from the circumferential surface, wherein the circumferential surface and the dam cooperate to define a reservoir radially inside the channel, wherein the reservoir and the channel are in fluid communication and cooperate to form a fluid path configured to carry the fluid from the orifice to the holes. 10. The clutch assembly of claim 9 , wherein the oil deflector further defines a conical surface extending from the reservoir and configured to direct oil overflowing the reservoir away from the outer annulus. 11. The clutch assembly of claim 9 , wherein the deflector further includes a conical surface configured to direct oil overflowing the reservoir away from the outer annulus. 12. The clutch assembly of claim 9 , wherein the oil deflector is mounted to the clutch hub. 13. The clutch assembly of claim 9 further comprising a piston supported to translate with respect to the clutch housing to squeeze the friction plates between the separator plates.