Rotary actuator

What is claimed is: 1. A rotary actuator, comprising: a manifold block; and a first rotor assembly mounted to the manifold block; wherein the first rotor assembly includes: a first rotor shaft extending into the manifold block; a plurality of arcuate pistons attached to the first rotor shaft, each arcuate piston curving at a set radial distance from a rotation axis of the first rotor shaft, and each piston attached to the first rotor shaft via a crank arm; a first pressure chamber assembly coupled to the manifold block, the first pressure chamber assembly defining a plurality of piston pressure chambers each configured to receive and at least partially enclose a corresponding arcuate piston; a plurality of gland seals disposed adjacent an entrance to each piston pressure chamber and creating a seal between an inner surface of the piston pressure chamber and an outer surface of the corresponding arcuate piston inserted therein; wherein each gland seal includes an inner seal configured to engage a surface of the arcuate piston, and a plurality of outer seals configured to engage the inner surface of the piston pressure chamber, such that a hydraulic seal is formed between each piston pressure chamber and the corresponding arcuate piston inserted therein, wherein each gland seal is disposed within a gland bore formed in the inner surface of its corresponding piston pressure chamber, and wherein each gland seal includes a gland that is retained within the gland bore by a shear wire disposed between the gland and the gland bore that engages both the gland and the gland bore; the first rotor assembly being configured so that delivering a hydraulic fluid to the plurality of piston pressure chambers causes the arcuate piston disposed within each piston pressure chamber to translate at the set radial distance around the rotation axis of the first rotor shaft, thereby rotating the first rotor shaft. 2. The rotary actuator of claim 1 , wherein the plurality of arcuate pistons includes a first set of the plurality of arcuate pistons extending in a first rotational direction around the rotation axis, and a second set of the plurality of arcuate pistons extending in a second and opposing rotational direction around the rotation axis, such that delivering hydraulic fluid to a plurality of first piston pressure chambers for the first set of the arcuate pistons causes rotation of the first rotor shaft, and delivering the hydraulic fluid to a second plurality of second piston pressure chambers of the second set of the arcuate pistons causes counter-rotation of the first rotor shaft. 3. The rotary actuator of claim 2 , wherein the manifold block defines a first plurality of internal channels configured to deliver hydraulic fluid to the first piston pressure chambers, and further defines a second plurality of internal channels configured to deliver hydraulic fluid to the second piston pressure chambers, such that by delivering hydraulic fluid to the first and second piston pressure chambers in turn, the first rotor shaft can be rotated and counter-rotated. 4. The rotary actuator of claim 2 , further comprising a second rotor assembly mounted to the manifold block on a side opposing the first rotor assembly; wherein the second rotor assembly is symmetric with the first rotor assembly with respect to rotation around a vertical axis orthogonal to the rotation axis; and an inner end of a second rotor shaft of the second rotor assembly extends into a recess formed in the manifold block; further comprising an output lug that is coupled to the inner ends of both the first rotor shaft and the second rotor shaft, where the output lug is configured to be coupled to a control surface. 5. The rotary actuator of claim 4 , wherein each of the first and second rotor assemblies includes 8 arcuate pistons attached to its respective rotor shaft; wherein each of the first and second rotor assemblies includes a first set of four arcuate pistons extending in a first rotational direction around the rotation axis, and a second set of four arcuate pistons extending in a second and opposing rotational direction around the rotation axis; such that delivering hydraulic fluid to the first piston pressure chambers of the first set of four arcuate pistons for each of the first and second rotor assemblies causes rotation of the combined first and second rotor shafts, and delivering the hydraulic fluid to the second piston pressure chambers of the second set of four arcuate pistons for each of the first and second rotor assemblies causes counter-rotation of the combined first and second rotor shafts. 6. The rotary actuator of claim 1 , further comprising an first actuator housing sealingly coupled to the manifold block and enclosing the first pressure chamber assembly such that an exterior surface of the first pressure chamber assembly, an outer surface of the first rotor shaft, and an interior surface of the first actuator housing, in combination, define a first return pressure volume. 7. The rotary actuator of claim 1 , wherein an inner end of the first rotor shaft extends into a recess formed in the manifold block; further comprising an output lug coupled to the inner end of the first rotor shaft, where the output lug is configured to be coupled to a control surface. 8. The rotary actuator of claim 1 , wherein the plurality of arcuate pistons are coupled to the first rotor shaft in pairs in an arrangement having twofold rotational symmetry around the rotation axis. 9. The rotary actuator of claim 1 , wherein the inner seal includes a rod seal. 10. The rotary actuator of claim 1 , wherein the plurality of outer seals include a plurality of O-ring seals. 11. The rotary actuator of claim 1 , wherein the manifold block defines a plurality of internal channels configured to deliver hydraulic fluid to the piston pressure chambers. 12. A control surface actuator system, comprising: a control surface of an aircraft; a rotary actuator that is coupled to the control surface, such that operation of the rotary actuator actuates a movement of the control surface; wherein the rotary actuator includes: a manifold block; and a first and a second rotor assembly mounted to opposing sides of the manifold block along a rotation axis; wherein each of the first and second rotor assemblies includes a rotor shaft extending into the manifold block along the rotation axis; a plurality of arcuate pistons attached to the rotor shaft, each piston curving along a defined radial distance from a rotation axis of the rotor shaft, and each piston attached to the rotor shaft via an intermediate crank arm; a pressure chamber assembly coupled to the manifold block, the pressure chamber assembly defining a plurality of piston pressure chambers configured to receive and at least partially enclose the plurality of arcuate pistons; a plurality of gland seals disposed adjacent an entrance to each piston pressure chamber and creating a hydraulic seal between an inner surface of the piston pressure chamber and an outer surface of the arcuate piston disposed therein; and each rotor assembly being configured so that delivering hydraulic fluid to the plurality of piston pressure chambers causes the arcuate piston disposed within each piston pressure chamber to translate around the rotation axis, increasing a piston pressure chamber volume and thereby rotating the coupled rotor shaft. 13. The control surface actuator system of claim 12 , wherein the control surface is one of a wing aileron, an elevator, a rudder, a spoiler, a wing flap, a wing slat, an air brake, a control horn, or a trim tab. 14. The contr