Vehicular shock absorber and method for controlling same

What is claimed is: 1. A vehicular shock absorber comprising: a damper comprising a cylinder, a piston valve disposed inside the cylinder, and a piston rod, of which one end is connected to the piston valve and a remaining end is connected to a vehicle body; a damping force-variable valve assembly attached to an outer portion of the damper and configured to regulate a flow of a working fluid of the damper; a pump fixed to the vehicle body; and a high-pressure tube configured to make the pump and a piston rod flow path provided in the piston rod communicate with each other, wherein the piston rod flow path makes the high pressure tube and an extension chamber of the damper communicate with each other, wherein the cylinder comprises an outer tube, an inner tube disposed inside the outer tube, an intermediate tube attached to the inner tube, and a reservoir chamber disposed between the outer tube and the inner tube, and wherein the intermediate tube is disposed directly between the inner tube and the reservoir chamber. 2. The vehicular shock absorber of claim 1 , wherein the high-pressure tube is formed of a steel pipe. 3. The vehicular shock absorber of claim 1 , wherein the piston rod flow path is disposed in a longitudinal direction of the piston rod and is provided with at least one portion extending in a direction intersecting with the longitudinal direction of the piston rod and communicating with the extension chamber. 4. The vehicular shock absorber of claim 1 , wherein the damping force-variable valve assembly comprises two variable valves operated by one solenoid. 5. The vehicular shock absorber of claim 1 , wherein at least a portion of the reservoir chamber is disposed below a compression chamber of the damper in a longitudinal direction of the piston rod. 6. The vehicular shock absorber of claim 1 , wherein an input port of the pump communicates with the reservoir chamber. 7. The vehicular shock absorber of claim 1 , further comprising: an accumulator disposed inside the outer tube. 8. The vehicular shock absorber of claim 7 , wherein the accumulator is connected to communicate with the reservoir chamber. 9. The vehicular shock absorber of claim 1 , further comprising: a body valve disposed below a compression chamber of the damper. 10. The vehicular shock absorber of claim 4 , wherein the cylinder comprises an outer tube, an inner tube disposed inside the outer tube, and an intermediate tube attached to the inner tube, wherein a reservoir chamber is disposed between the outer tube and the inner tube and an extension-side flow path configured to communicate with the extension chamber and a compression-side flow path configured to communicate with the compression chamber are disposed between the inner tube and the intermediate tube, wherein the damping force-variable valve assembly is connected to the damper so as to make the extension-side flow path and the compression-side flow path communicate each other and to make the compression-side flow path and the reservoir chamber communicate each other, and wherein one of the two variable valves is disposed in a portion where the extension-side flow path and the compression-side flow path are connected to each other, and a remaining one of the two variable valves is disposed in a portion where the compression-side flow path and the reservoir camber are connected to each other. 11. The vehicular shock absorber of claim 10 , wherein the two variable valves comprise an expansions variable valve configured to vary a flow rate to be flowed into the extension chamber and the compression chamber, and a compression-variable valve configured to vary a flow rate to be flowed into the compression chamber and the reservoir chamber. 12. The vehicular shock absorber of claim 11 , wherein the damping force-variable valve assembly comprises a first connection flow path configured to make a flow path in an upstream portion of the extension-variable valve and the extension-side flow path communicate with each other; a second connection flow path configured to make a flow path in a downstream portion of the extension-variable valve and the compression-side flow path communicate with each other, and a third connection flow path configured to make a flow path in a downstream portion of the compression-variable valve and the reservoir chamber communicate with each other. 13. The vehicular shock absorber of claim 10 , wherein an input port of the pump communicates with the reservoir chamber. 14. A method for controlling a vehicular shock absorber comprising a damper comprising a cylinder provided with an outer tube and an inner tube, a piston valve dividing an inside of the inner tube into an extension chamber and a compression chamber, and a piston rod connected to the piston valve, and a damping force-variable valve assembly attached to an outer portion of the damper and configured to regulate a flow of a working fluid of the damper, the method comprising: causing a pump to supply the working fluid in a reservoir chamber disposed between the outer tube and the inner tube to the extension chamber; and controlling a flow rate flowed into the extension chamber and the compression chamber by controlling one of two variable valves provided in the damping force-variable valve assembly, wherein the cylinder comprises an outer tube, an inner tube disposed inside the outer tube, an intermediate tube attached to the inner tube, and a reservoir chamber disposed between the outer tube and the inner tube, and wherein the intermediate tube is disposed directly between the inner tube and the reservoir chamber. 15. The method of claim 14 , further comprising: changing pressure of the working fluid supplied to the extension chamber by the pump. 16. The method of claim 14 , further comprising: using a motor as a generator to produce electricity when the pump does not operate.