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A capacitive power system having a service life extending approach. The system may have an ultra or super capacitor with high capacitance. A predetermined amount of energy may be stored in the capacitor, sufficient for providing power to an electrically powered mechanism in the event the mechanism l

A capacitive power system having a service life extending approach. The system may have an ultra or super capacitor with high capacitance. A predetermined amount of energy may be stored in the capacitor, sufficient for providing power to an electrically powered mechanism in the event the mechanism loses its power, to place it in a fail safe condition. With the capacitor at an initial capacitance, the working voltage may be set as low as possible while still retaining sufficient capacity for storing the predetermined amount of energy. As the capacitor's capacitance decreases with age, the working voltage of the capacitor may be gradually increased to compensate for lost capacitance. If the mechanism loses power, then a discharge of the capacitor may be initiated to transfer energy to the mechanism. If the electrical mechanism has power, then a charging of the capacitor may be initiated to transfer energy to the capacitor.

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1. A system having a service life extender for a capacitor, comprising: a power module; anda diagnostics module connected to the power module; andwherein:the diagnostics module is configured to determine a minimum working voltage of a capacitor needed for storing a predetermined amount of energy the

1. A system having a service life extender for a capacitor, comprising: a power module; anda diagnostics module connected to the power module; andwherein:the diagnostics module is configured to determine a minimum working voltage of a capacitor needed for storing a predetermined amount of energy therein;the power module is configured to control current and voltage at the capacitor; andthe predetermined amount of energy is sufficient for providing a fail safe condition for an electrical mechanism if a power-off condition to the electrical mechanism is detected; andthe diagnostics module is configured to measures a voltage at the capacitor and determine whether the voltage is equal to or greater than the minimum working voltage needed for storing the predetermined amount of energy;if the voltage is equal to or greater than the minimum working voltage, then a charge cycle is not needed;if the voltage is less than the minimum working voltage and the power-on condition is detected, then a charge cycle is initiated and continued until the voltage is equal to or greater than the minimum working voltage plus a hysteresis voltage. 2. The system of claim 1, wherein if a power-off condition is detected, then a discharge cycle is initiated and the power module is configured to transfer energy from the capacitor to the electrical mechanism to provide the fail safe condition for the electrical mechanism. 3. The system of claim 1, further comprising: a monitor connected to the power module; andwherein:the monitor detects a power-on or power-off condition of the electrical mechanism. 4. The system of claim 1, wherein: the electrical mechanism is an actuator; andthe fail safe condition is a position of a damper or valve controlled by the actuator, placed in a safe power-off position. 5. The system of claim 1, wherein the power module is configured to interact with a capacitor that has a capacitance of one or more farads. 6. The system of claim 1, wherein power module is configured to increase the minimum working voltage of the capacitor, needed to store the predetermined amount of energy, as necessary to compensate for decreased capacitance of the capacitor due to deterioration. 7. A method for expanding a service life of a capacitor for storing a predetermined amount of energy needed by an electrical mechanism to achieve a fail safe condition if the mechanism loses power, comprising: periodically determining a minimal working voltage of a capacitor needed to store a predetermined amount of energy in the capacitor; andincreasing or decreasing the minimal working voltage to be merely sufficient for the capacitor to store the predetermined amount of energy; andwherein the capacitor has a capacitance sufficient to store X times, where X>1, the predetermined amount of energy; andinitiating a discharge cycle of the capacitor to transfer the predetermined amount of energy from the capacitor to an electrical mechanism to achieve a fail safe condition when the electrical mechanism loses power. 8. The method of claim 7, further comprising: initiating a charge cycle of the capacitor to transfer energy from an electrical mechanism to the capacitor as needed to store the predetermined amount of energy when the electrical mechanism has power. 9. The method of claim 7, further comprising: determining the predetermined amount of energy, wherein the predetermined amount of energy is the amount of energy needed to place an electrical mechanism in a fail safe condition if the electrical mechanism loses power. 10. The method of claim 9, further comprising: periodically measuring voltage at the capacitor; andwherein:if the voltage is less than the minimal working voltage, then transfer energy from the electrical mechanism to the capacitor; andif the voltage is equal to or greater than the minimal working voltage plus a hysteresis voltage, then stop transferring energy from the electrical mechanism to the capacitor. 11. The method of claim 9, further comprising: determining a normal rated working voltage of the capacitor; andimplementing the capacitor at a minimum working voltage that is Y times the normal rated working voltage of the capacitor, wherein Y≤1. 12. The method of claim 11, wherein the capacitor is a super capacitor having a value greater than one farad. 13. The method of claim 11, wherein: the electrical mechanism is an actuator; andthe fail safe condition is a position of a damper or valve controlled by the actuator, placed in a safe position. 14. A capacitive power source having a service life extending approach, comprising: a capacitor control block connected to the capacitor module; anda diagnostics module connected to the capacitor control block; andwherein:the capacitor module comprises a capacitor;the diagnostics module determines a minimum working voltage for the capacitor for storing a predetermined amount of energythe predetermined amount of energy is for providing a fail safe condition for an electrical mechanism in an event of a power-off condition of the electrical mechanism. 15. The system of claim 14, wherein: the capacitor is operated at the minimum working voltage which is less than a maximum rated working voltage of the capacitor;the minimum working voltage of the capacitor is increased as needed to compensate for decreased energy storage of the capacitor occurring over time. 16. The system of claim 15, wherein: the capacitor control block further comprises a monitor and a power module connected to the diagnostics module;the monitor provides a signal to the diagnostics module when detecting the power-off condition of the electrical mechanism; andthe power module controls current and voltage at the capacitor module for providing and/or receiving energy. 17. The system of claim 16, wherein: the power module is for receiving and providing energy and is connected to the electrical mechanism; andthe power module provides backup energy when the electrical mechanism has a power-off condition to place the electrical mechanism in a fail safe condition. 18. The system of claim 17, wherein: the electrical mechanism is an actuator; andthe fail safe condition is a safe position of a damper or valve when the actuator has a power-off condition. 19. The system of claim 14, wherein the capacitor is a super capacitor having a capacitance of one or more farads.