Clutch mechanism for energy storage device and gas insulated circuit breaker thereof

The invention claimed is: 1. A clutch mechanism for an energy storage device, comprising: a loading gear; a driving gear; a one-way bearing; a sleeve; a gear shaft including a gear portion and a clutch portion, wherein the loading gear is connected coaxially to the sleeve via the one-way bearing so as to be rotatable in a single direction, the sleeve is connected coaxially to the clutch portion so as to be rotatable in two directions, and the driving gear is meshed with an outside of the gear portion, the gear shaft further including multiple spheres, and a push rod and an elastic element located in a cavity of the gear shaft, wherein the clutch portion includes multiple holes corresponding to the spheres, and the spheres are located in the holes, and the push rod including a groove and being slideable in the axial direction of the gear shaft, wherein the elastic element is joined to one end of the push rod and presses against the push rod, the depth of the bottom of the groove being less than the diameter of the spheres, and the bottom of the groove including a slope; and a pressure block, fixed to the driving gear, the pressure block being able to contact the other end of the push rod and push the push rod to slide in the axial direction of the gear shaft, so as to unlock or lock the sleeve and the gear shaft. 2. The clutch mechanism of claim 1 , wherein the push rod comprises two said grooves, and the distance between the two grooves in each pair is greater than or equal to the diameter of the spheres. 3. A gas insulated circuit breaker, comprising: a motive power device; an operating device; an energy storage device; and the clutch mechanism of claim 1 , wherein the loading gear is connected to the motive power device, the driving gear is connected to the energy storage device, and the gear shaft is connected to the operating device. 4. The clutch mechanism of claim 1 , wherein the slope starts off deep and becomes shallower in the direction in which a pressing force is applied by the elastic element, and when the pressure block pushes the push rod, the spheres leave the bottom of the groove along the slope. 5. The clutch mechanism of claim 4 , wherein the sleeve is connected coaxially to the clutch portion via a roller bearing or a sliding bearing so as to be rotatable in two directions. 6. A gas insulated circuit breaker, comprising: a motive power device; an operating device; an energy storage device; and the clutch mechanism of claim 4 , wherein the loading gear is connected to the motive power device, the driving gear is connected to the energy storage device, and the gear shaft is connected to the operating device. 7. The clutch mechanism of claim 1 , wherein the slope starts off shallow and deepens in the direction in which a pressing force is applied by the elastic element, and when the pressure block pushes the push rod, the spheres fall into the bottom of the groove along the slope. 8. A gas insulated circuit breaker, comprising: a motive power device; an operating device; an energy storage device; and the clutch mechanism of claim 7 , wherein the loading gear is connected to the motive power device, the driving gear is connected to the energy storage device, and the gear shaft is connected to the operating device. 9. The clutch mechanism of claim 7 , wherein the sleeve is connected coaxially to the clutch portion via a roller bearing or a sliding bearing so as to be rotatable in two directions. 10. The clutch mechanism of claim 9 , wherein the elastic element is a spring. 11. The clutch mechanism of claim 9 , wherein the slope is arcuate. 12. The clutch mechanism of claim 9 , wherein the pressure block comprises a sloping face, contactable with the push rod. 13. The clutch mechanism of claim 9 , wherein the depth of the bottom of the groove is less than or equal to the radius of the spheres.