Energy recovery system and method for hydraulic tool

What is claimed is: 1. An energy recovery system for a hydraulic tool comprising: a control interface configured to receive inputs corresponding to a prescribed motion for the hydraulic tool; a hydraulic circuit configured to articulate the hydraulic tool based on the prescribed motion in a pump mode to provide potential energy, and in a motor mode to recover energy from the potential energy, the hydraulic circuit including: cylinders configured to receive and release a hydraulic fluid; a tank configured to store the hydraulic fluid; and an open circuit variable displacement pump configured to circulate the hydraulic fluid from the tank to the cylinders in the pump mode and circulate the hydraulic fluid from the cylinders to the tank in the motor mode, the open circuit variable displacement pump including: a swashplate articulable between a positive position and a negative position, wherein in the positive position the hydraulic fluid circulates in the pump mode and in the negative position the hydraulic fluid circulates in the motor mode, an actuator configured to articulate the swashplate; and a bias system configured to maintain the swashplate in a positive position when the hydraulic fluid is not in circulation; and an engine configured to provide energy to the open circuit variable displacement pump in the pump mode and receive energy from the open circuit variable displacement pump in the motor mode. 2. The energy recovery system of claim 1 , wherein the actuator includes a pair of pistons to rotate the swashplate between the positive position and the negative position. 3. The energy recovery system of claim 2 , wherein the actuator further includes a three-way valve to actuate the pair of pistons. 4. The energy recovery system of claim 3 , wherein the actuator further includes a solenoid to actuate the three-way valve. 5. The energy recovery system of claim 2 , wherein the bias system includes a plurality of springs placed around one piston of the pair of pistons to provide a bias force on the piston and the swashplate. 6. The energy recovery system of claim 5 , wherein the plurality of springs extends between a seat affixed to the open circuit variable displacement pump and a stop affixed to the piston. 7. The energy recovery system of claim 5 , wherein two consecutive springs of the plurality of springs are separated by a slider slidably affixed to the piston to prevent buckling. 8. The energy recovery system of claim 7 , wherein the two consecutive springs are substantially identical springs separated. 9. The energy recovery system of claim 1 , wherein the tank includes an accumulator to maintain the hydraulic fluid under pressure and store energy recovered in the motor mode. 10. An energy recovery system for a hydraulic tool comprising: cylinders configured to articulate the hydraulic tool in a pump mode to provide potential energy and in a motor mode to recover the potential energy; a tank configured to store a hydraulic fluid for the cylinders; and an open circuit variable displacement pump configured to circulate the hydraulic fluid in the pump mode from the tank to the cylinders and in the motor mode from the cylinders to the tank, the open circuit variable displacement pump including: a swashplate articulable between a positive position and a negative position, wherein in the positive position the hydraulic fluid circulates in the pump mode and in the negative position the hydraulic fluid circulates in the motor mode, an actuator configured to articulate the swashplate; and a bias system configured to maintain the swashplate in a positive position when the hydraulic fluid is not in circulation. 11. The energy recovery system of claim 10 , wherein the actuator includes a pair of pistons to rotate the swashplate between the positive position and the negative position. 12. The energy recovery system of claim 11 , wherein the actuator further includes a three-way valve to actuate the pair of pistons. 13. The energy recovery system of claim 12 , wherein the actuator further includes a solenoid to actuate the three-way valve. 14. The energy recovery system of claim 11 , wherein the bias system includes a plurality of springs placed around one piston of the pair of pistons to provide a bias force on the piston and the swashplate. 15. The energy recovery system of claim 14 , wherein the plurality of springs extends between a seat affixed to the open circuit variable displacement pump and a stop affixed to the piston. 16. The energy recovery system of claim 14 , wherein two consecutive springs of the plurality of springs are separated by a slider slidably affixed to the piston to prevent buckling. 17. The energy recovery system of claim 16 , wherein the two consecutive springs are substantially identical springs separated. 18. The energy recovery system of claim 10 , wherein the tank includes an accumulator to maintain the hydraulic fluid under pressure and store energy recovered in the motor mode. 19. A method of operating an energy recovery system for a hydraulic tool, the method comprising: providing an open circuit variable displacement pump with a swashplate; providing a swashplate actuator that articulates the swashplate, the swashplate actuator having a three-way valve actuated by a solenoid; receiving, at a controller, signals corresponding to operator commands to control the hydraulic tool; calculating, using the controller, a desired angle displacement for the swashplate based on the operator commands, an upper torque limit, and a lower torque limit; calculating, using the controller, a desired valve position for the three-way valve based on the desired angle displacement; generating electrical current for the solenoid based on the desired valve position; and displacing the swashplate, via the swashplate actuator, based on the generated electrical current. 20. The method of claim 19 , further comprising verifying that the operator commands do not correspond to a desired torque higher than the upper torque limit or lower than the lower torque limit.