Actuatable joint for a robotic system having an axial angular contact roller bearing

What is claimed is: 1. An actuatable joint for a robotic system, comprising: a body; a motor positioned in the body; an output shaft configured to be rotated by the motor relative to the body and having a pair of opposite support surfaces that are oblique relative to each other; and a bearing assembly positioned between the output shaft and the body and configured to support the rotation of the output shaft, wherein the bearing assembly includes a first axial angular contact roller bearing, including: a pair of generally frusto-conical bearing rings forming a pair of parallel races, wherein one of the bearing rings is positioned on one of the support surfaces, a bearing cage positioned between the pair of bearing rings and including a plurality of openings, and a plurality of rollers positioned in the openings and in contact with the races. 2. The actuatable joint of claim 1 , wherein the output shaft includes a generally frusto-conical section defining the pair of support surfaces. 3. The actuatable joint of claim 2 , wherein the bearing assembly includes a second axial angular contact roller bearing having a bearing ring positioned on the other of the support surfaces of the output shaft. 4. The actuatable joint of claim 3 wherein the pair of parallel races of the first axial angular contact roller bearings are angled toward a pair of races of the second axial angular contact roller bearing in a radially inward direction. 5. The actuatable joint of claim 1 , wherein the bearing cage is formed from a molded plastic material. 6. The actuatable joint of claim 1 , wherein the plurality of rollers are cylindrical. 7. The actuatable joint of claim 1 , wherein the actuatable joint further includes an inline gearbox between the motor and the output shaft. 8. The actuatable joint of claim 1 , wherein the actuatable joint further includes a connector plate secured to the output shaft. 9. The actuatable joint of claim 1 , wherein the opposing oblique support surfaces are defined by a generally frusto-conical section of the output shaft that is located at a radially outer extent of the output shaft. 10. A robotic system, comprising: a connector arm; and an actuatable joint, including a body; a motor positioned in the body; an output shaft configured to be rotated by the motor relative to the body, the output shaft including a section defining a pair of opposite support surfaces that are oblique relative to a rotational axis of the output shaft; a connector plate secured to the output shaft; and a bearing assembly positioned between the output shaft and the body and configured to support the rotation of the output shaft, wherein the bearing assembly includes a first axial angular contact roller bearing and a second axial angular contact roller bearing, each including: a pair of generally frusto-conical bearing rings forming a pair of parallel races, one of the bearing rings being in contact with one of the support surfaces, a bearing cage positioned between the pair of bearing rings and including a plurality of openings, and a plurality of rollers positioned in the openings and in contact with the races, wherein the connector arm is attached to the connector plate for rotation by the motor. 11. The robotic system of claim 10 , further including a second actuatable joint connected to the actuatable joint by the connector arm. 12. A modular robotic system, comprising: modular components, including a connector arm, a connector plate, wherein perimeters of the modular components each have a toothed geometrical configuration defined by a plurality of concave sections and a plurality of convex sections, and wherein the modular components each have an internal channel and a plurality of attachment members or openings; and an actuatable joint, including a body, a motor positioned in the body, an output shaft configured to be rotated by the motor relative to the body, the output shaft including a section defining a pair of generally frusto-conical support surfaces, and a bearing assembly positioned between the output shaft and the body and configured to support the rotation of the output shaft, having a first axial angular contact roller bearing positioned on one of the support surfaces.