Method and system for harvesting energy using an EAP based deformable body

The invention claimed is: 1. Method for harvesting energy using an EAP based deformable body, the EAP based deformable body being a elastically deformable body comprising an arrangement of stretchable synthetic material and electrodes being arranged as a variable capacitor with a capacitance that varies as the deformable body stretches and relaxes, the method comprising: looping through an energy harvesting cycle with a) stretching the deformable body from a minimal relaxed size L 1 to a maximal stretched size L 2 ; b) at the maximal stretched size electrically charging of the variable capacitor to create an electric field over the capacitor with an upper electric field level value; and subsequently c) a relaxation step from maximal stretched size to the minimal relaxed size; d) at the minimal relaxed size of the deformable body, electrically discharging the capacitor to a minimal charge level and a minimal electric field level value, wherein the charging starts during stretching of the deformable body and is initiated at a first stretched size L 3 before reaching the maximal stretched size L 2 and continues after reaching the maximum during relaxation up to a level of a third stretched size L 5 , and the discharging starts during relaxation of the deformable body and is initiated at a second stretched size L 4 before reaching the minimal relaxed size L 1 , and continues after reaching the minimum during stretching up to a level of a fourth stretched size L 6 . 2. Method according to claim 1 , wherein the discharging is stopped at a larger electric field level value than the zero electric field level value. 3. Method according to claim 1 , wherein the variable capacitor has a net remainder charge level larger than the minimal charge level after discharging. 4. Method according to claim 1 , wherein either the discharging is stopped at a larger voltage level value than the minimum voltage level value or the discharging is stopped at a larger charge level value than the minimum charge level value. 5. Method according to claim 1 , wherein the variable capacitor has a net remainder voltage level larger than the minimal voltage level after discharging. 6. Method according to claim 1 , wherein the charging is performed under condition of a constant power supplied to the variable capacitor. 7. Method according to claim 1 , wherein the discharging is performed under condition of a constant power delivered by the variable capacitor. 8. Method according to claim 1 , wherein the charging is performed using a DC source. 9. Method according to claim 1 , wherein the method comprises maintaining the upper electric field level value substantially constant during the relaxation step from maximal stretched size to the minimal relaxed size. 10. Method according to claim 1 , wherein the method comprises maintaining either a substantially constant charge or a substantially constant voltage during the relaxation step from maximal stretched size to the minimal relaxed size. 11. Method according to claim 1 , wherein the first predetermined stretch level R3 at the first stretched size L 3 before reaching the maximal stretched size L 2 equals at least 80% or at least 90% relative stretch with R3=100*(L 3 −L 1 )/(L 2 −L 1 ). 12. Method according to claim 1 , wherein the second predetermined stretch level R4 at the second stretched size L 4 before reaching the minimal stretched size L 1 equals at least less than 20% or at least less than 10% relative stretch with R4=100*(L 4 −L 1 )/(L 2 −L 1 ). 13. System for harvesting energy using an EAP based deformable body, comprising the EAP based deformable body, a power electronic unit, a monitoring device, an energy storage and supply device and a controller; the EAP based deformable body being a elastically deformable body comprising an arrangement of stretchable synthetic material and electrodes being arranged as a variable capacitor with a capacitance that varies as the deformable body stretches and relaxes; the energy storage and supply device being coupled to the power electronic unit and being arranged for storing and for supplying energy, respectively, from and to the power electronic unit; the power electronic unit being coupled to the variable capacitor of the EAP based deformable body for charging and discharging the capacitor during stretching and relaxation, respectively; the monitoring device being coupled to the EAP based deformable body for monitoring a state of stretching and relaxation of the deformable body and being coupled to the controller for messaging the state of stretching and relaxation to the controller, and the controller being coupled to the power electronic unit, wherein the controller is arranged to control the power electronic unit: to electrically charge the variable capacitor to create an electric field over the capacitor with an upper electric field level value when the deformable body has stretched from a minimal relaxed size to a maximal stretched size L 2 ; and to electrically discharge the capacitor to a minimal charge level and a minimal electric field level value when the deformable body has reached the minimal relaxed size L 1 during relaxation, wherein based on the monitored state of stretching and relaxation, the controller controls the power electronic unit: to start the charging during stretching of the deformable body and to initiate the charging at a first stretched size L 3 before reaching the maximal stretched size L 2 and to continue after reaching the maximum during relaxation upto a level of a third stretched size L 5 , and to start the discharging during relaxation of the deformable body and to initiate the discharging at a second stretched size L 4 before reaching the minimal relaxed size L 1 and to continue during stretching up to a level of a fourth stretched size L 6 . 14. System according to claim 13 , wherein based on the monitored state of stretching and relaxation, the controller controls the power electronic unit to stop the discharging at a larger electric field level value than the minimal electric field level value. 15. System according to claim 13 , wherein based on the monitored state of stretching and relaxation, the controller controls the power electronic unit to stop discharging at a larger voltage level value than the minimum voltage level value or \ at a larger charge level value than the minimum charge level value. 16. System according to claim 13 , wherein the variable capacitor has a net remainder charge level larger than the minimal charge level after discharging. 17. System according to claim 13 , wherein the variable capacitor has a net remainder voltage level larger than the minimal voltage level after discharging. 18. System according to claim 13 , wherein the controller controls the power electronic unit to perform the charging under condition of a constant power supplied to the variable capacitor. 19. System according to claim 13 , wherein the controller controls the power electronic unit to perform the discharging under condition of a constant power delivered by the variable capacitor. 20. System according to claim 13 , wherein the energy storage and supply device is a DC source. 21. System according to claim 13 , wherein the controller controls the power electronic unit to maintain the upper electric field level value substantially constant during the relaxation step from maximal stretched size to the minimal relaxed size. 22. System according to