Hydraulic axis with energy storage feature

We claim: 1. A closed hydraulic circuit including a hydraulic axis, the hydraulic axis comprising: an electric motor; an actuator comprising a cylinder, a piston disposed in the cylinder that segregates an interior space of the cylinder into two chambers, and a rod having a first end that is connected to the piston, and a second end that is configured to be connected to a load; a bidirectional hydraulic main pump driven by the electric motor to pump hydraulic fluid through the hydraulic circuit, pressure connections of the main pump connected via a first line and a second line to the respective chambers of the actuator such that the rod is configured to extend and retract depending on a direction of flow of the hydraulic fluid through the main pump; a main accumulator connected to the first line via a third line; a first control valve disposed in the third line between the first line and the main accumulator; an energy storage accumulator connected to the first line via a fourth line; and a second control valve disposed in the fourth line between the first line and the energy storage accumulator, wherein the hydraulic axis is switchable between a first operating mode that is free of energy storage in the energy storage accumulator, and a second operating mode in which energy is stored in the energy storage accumulator. 2. The hydraulic axis of claim 1 , wherein the hydraulic axis is switched between the first operating mode and the second operating mode by controlling the first control valve and the second control valve. 3. The hydraulic axis of claim 2 , wherein in the first operating mode, the hydraulic axis is configured so that the first control valve permits hydraulic fluid to flow to the main accumulator and the second control valve is closed, and in the second operating mode, the hydraulic axis is configured so that the first control valve prevents fluid flow between the main accumulator and the first line and the second control valve is open. 4. The hydraulic axis of claim 1 , wherein the energy storage accumulator is configured to store a variable amount of energy during each actuation cycle of the actuator. 5. The hydraulic axis of claim 1 , wherein an amount of energy stored in the energy storage accumulator is varied in correspondence with variations of load applied to the rod. 6. The hydraulic axis of claim 1 , comprising a charge pump that is driven by a second electric motor, the second motor having variable speed, the charge pump configured to control the pressure of hydraulic fluid stored in the enemy storage accumulator. 7. The hydraulic axis of claim 6 , wherein the amount of energy stored in the energy storage accumulator during an actuation cycle of the actuator varies based on a charge pressure that is controlled by the charge pump. 8. The hydraulic axis of claim 1 , wherein in the first operating mode, the hydraulic axis is configured to actuate the actuator via the hydraulic circuit in which hydraulic fluid in the hydraulic circuit is driven by the main pump, excess hydraulic fluid from the actuator is stored at low pressure in the main accumulator, and the energy storage accumulator is isolated from the hydraulic circuit, and in the second operating mode, the hydraulic axis is configured to actuate the actuator via the hydraulic circuit in which hydraulic fluid in the hydraulic circuit is driven by the main pump, fluid flow to the main accumulator is prevented, and excess hydraulic fluid from the actuator is stored at high pressure in the energy storage accumulator. 9. The hydraulic axis of claim 1 , wherein the main accumulator is a low pressure accumulator configured to operate at pressures corresponding to pressures associated with a low pressure side of the hydraulic circuit, and the energy storage accumulator is a high pressure accumulator configured to operate at pressures corresponding to pressures associated with a high pressure side of the hydraulic circuit. 10. The hydraulic axis of claim 1 , wherein the actuator is a differential area actuator having a single rod. 11. The hydraulic axis of claim 1 , wherein the hydraulic axis is free of vents and hydraulic fluid reservoirs. 12. The hydraulic axis of claim 1 , wherein when the hydraulic axis is in the second operating mode and hydraulic fluid is stored under pressure in the energy storage accumulator, a pressure drop across the pressure connections of the main pump is reduced. 13. The hydraulic axis of claim 1 , wherein the main accumulator is configured to store hydraulic fluid under a first pressure, and the energy storage accumulator is configured to selectively store fluid under a second pressure that is higher than the first pressure. 14. The hydraulic axis of claim 13 , wherein the energy storage accumulator configured to release the stored fluid at the second pressure during a movement of the rod. 15. The hydraulic axis of claim 1 , wherein the amount of energy stored in the energy storage accumulator is controlled independently of the load applied to the system. 16. The hydraulic axis of claim 1 , wherein the amount of energy available to the hydraulic circuit is optimized by varying the amount of energy stored in the energy storage accumulator. 17. A method of providing energy storage in a hydraulic system, the hydraulic system comprising: a closed hydraulic circuit; an electric motor; an actuator comprising a cylinder, a piston disposed in the cylinder that segregates an interior space of the cylinder into two chambers, and a rod having a first end that is connected to the piston, and a second end that is configured to be connected to a load; a bidirectional hydraulic main pump driven by the electric motor to pump hydraulic fluid through the hydraulic circuit, pressure connections of the main pump connected via a first line and a second line to the respective chambers of the actuator such that the rod is configured to extend and retract depending on a direction of flow of the hydraulic fluid through the main pump; a main accumulator connected to the first line via a third line; a first control valve disposed in the third line between the first line and the main accumulator; an energy storage accumulator connected to the first line via a fourth line; a second control valve disposed in the fourth line between the first line and the energy storage accumulator; and a charge pump connected to the second line, the method comprising transferring oil from the main accumulator to the energy storage accumulator via the charge pump. 18. The method of claim 17 , wherein the hydraulic system is switchable between a first operating mode that is free of energy storage in the energy storage accumulator, and a second operating mode in which energy is stored in the energy storage accumulator. 19. The method of claim 18 , wherein the hydraulic system is switched between the first operating mode and the second operating mode by controlling the first control valve and the second control valve. 20. The method of claim 18 , wherein in the first operating mode, the hydraulic axis is configured so that the first control valve permits hydraulic fluid to flow to the main accumulator and the second control valve is closed, and in the second operating mode, the hydraulic axis is configured so that the first control valve prevents fluid flow between the main accumulator and the first line and the second control valve is open. 21. The method of claim 17 , wherein the energy storage accumulator is c