Energy efficient fluid powered linear actuator with variable area and concentric chambers

What is claimed is: 1. An energy efficient, fluid powered, single-acting, linear actuation system comprising: a hydraulic cylinder barrel having a cap end wall, a tubular outer wall extending from the cap end wall and circumscribing an axially-extending, longitudinal centerline, and concentric inner walls spaced radially inward of the outer wall and extending axially from the cap end wall; a piston for engaging a load force, said piston having a base wall, concentric walls spaced radially outward of one another and axially extending from the base wall, said piston is disposed within said hydraulic cylinder barrel and the concentric walls of said barrel and the concentric walls of said piston cooperate to define a plurality of concentric extension chambers; a low pressure valve fluidly coupling each of the extension chambers to a common low pressure reservoir; a high pressure valve fluidly coupling each of the extension chambers to a common high pressure accumulator; a working fluid disposed within at least the chambers, valves, low pressure reservoir and high pressure accumulator; wherein, when the system is configured in an energy consuming mode and the load force is in an opposite direction as an extending piston force direction, the high pressure valves fluidly coupling the active extension chambers to the high pressure accumulator are configured in an open position, and the low pressure valves fluidly coupling the passive extension chambers to the low pressure reservoir are configured in an open position and all other valves are configured in a closed position; and when the system is configured in an energy recovery mode and the load force is in the same direction as a retracting piston force, the high pressure valves fluidly coupling the active extension chambers to the high pressure accumulator are configured in an open position and the low pressure valves fluidly coupling the passive extension chambers to the low pressure reservoir are configured in an open position and all other valves are configured in a closed position. 2. The single-acting linear actuation system of claim 1 and further comprising a controller for configuring each of the valves in either of an open position or a closed position in response to the load force magnitude and direction. 3. The single-acting linear actuation system of claim 2 and further comprising a pump fluidly coupled between said low pressure reservoir and said high pressure accumulator. 4. The single-acting linear actuation system of claim 1 wherein said piston includes a plurality of working surfaces and wherein each of the working surfaces include a surface area that is not identical in size to the other working surface areas. 5. An energy efficient, fluid powered, single-acting, linear actuation system comprising: a hydraulic cylinder barrel having a cap end wall, a tubular outer wall extending from the cap end wall and circumscribing an axially-extending, longitudinal centerline, and concentric inner walls spaced radially inward of the outer wall and extending axially from the cap end wall; a piston for engaging a load force, said piston having a base wall, concentric walls spaced radially outward of one another and axially extending from the base wall, said piston is disposed within said hydraulic cylinder barrel and the concentric walls of said barrel and the concentric walls of said piston cooperate to define a plurality of concentric extension chambers; and wherein said piston includes a plurality of working surfaces and wherein each of the working surfaces include a surface area that is identical in size to the other working surface areas. 6. An energy efficient, fluid powered, double-acting, linear actuation system comprising: a hydraulic cylinder barrel having a cap end wall, a rod end wall, a tubular outer wall extending between the cap end wall to the rod end wall and circumscribing an axially-extending, longitudinal centerline, and concentric inner walls spaced radially inward of the outer wall and extending axially from the cap end wall and the rod end wall; a piston for engaging a load force, said piston having a base, concentric walls spaced radially outward of one another and axially extending from the base in opposite directions, said piston is disposed within said hydraulic cylinder barrel and the walls of said barrel and the walls of said piston cooperate to define a plurality of concentric extension chambers disposed between the piston base and the cap end wall and a plurality of concentric retraction chambers disposed between the piston base and the rod end wall; a working fluid disposed within at least the chambers, valves, low pressure reservoir and high pressure accumulator; and wherein, when the system is configured in an energy consuming mode and the load force is in an opposite direction as an extending piston force, the high pressure valves fluidly coupling the active extension chambers and the active retraction chambers to the high pressure accumulator are configured in an open position and the low pressure valves fluidly coupling the passive extension chambers and passive retraction chambers to the low pressure reservoir are configured in a open position, and all other valves are configured in a closed position, and when the system is configured in an energy consuming mode and the load force is in an opposite direction as a retracting piston force, the high pressure valves fluidly coupling the active extension chambers and the active retraction chambers to the high pressure accumulator are configured in an open position and the low pressure valves fluidly coupling the passive extension chambers and passive retraction chambers to the low pressure reservoir are configured in a open position, and all other valves are configured in a closed position, and when the system is configured in an energy recovery mode and the load force is in the same direction as an extending piston, the high pressure valves fluidly coupling the active retraction chambers to the high pressure accumulator are configured in an open position and the low pressure valves coupling the passive retraction chambers and the active extension chambers and the passive extension chambers to the low pressure reservoir are configured in an open position, and all other valves are configured in a closed position, and when the system is configured in an energy recovery mode and the load force is in the same direction as a retracting piston, the high pressure valves fluidly coupling the active extension chambers to the high pressure accumulator are configured in an open position and the low pressure valves fluidly coupling the active retraction chambers and the passive retraction chambers and the passive extension chambers the low pressure reservoir are configured in an open position, and all other valves are configured in a closed position. 7. The double-acting linear actuation system of claim 6 and further comprising a controller for configuring each of the valves in either of an open position or a closed position in response to the load force magnitude and direction. 8. The double-acting linear actuation system of claim 7 and further comprising a pump fluidly coupled between said low pressure reservoir and said high pressure accumulator. 9. The double-acting linear actuation system of claim 6 and further comprising: a low pressure valve fluidly coupling each of the extension chambers and retraction chambers to a common low pressure reservoir; and a high pressure valve fluidly coupling each of the extension chambers and retraction chambers to a common high pressure accumulator. 10. The double-acting linear actuation system of claim 6 wherein said piston includes a