Wave power utilization device and control method thereof

What is claimed is: 1. A control method of controlling a wave power utilization device including a wave receiving box which has a wave receiving box inlet part that is open toward the sea and receives rushing of a wave, has a space filled with seawater from the wave receiving box inlet part toward a downstream side, and is sunk on the coast, a hollow air compression pipe in which a lower pipe is set to have a wider flow path cross-sectional area than that of an upper pipe, an air throttle that connects the lower pipe and the upper pipe to each other in a tapered shape is provided, the lower pipe is connected upright to an upper part on the downstream side of the wave receiving box, and air is compressed to form compressed air, a pressure measuring device which measures a pressure of the air compression pipe, an air suction port connected to an upper end of the air compression pipe and provided with a first check valve to suction the air from an outside of the air compression pipe, an air discharge pipe connected to the upper end of the air compression pipe and provided with a second check valve to discharge the compressed air from an inside of the air compression pipe, a compressed air storage tank installed downstream of the air discharge pipe and filled with the compressed air discharged from the air compression pipe, a pressure return pipe connecting the compressed air storage tank and the air compression pipe to each other, a pressure return on-off valve which is provided in the middle of the pressure return pipe and opens and closes a flow path of the pressure return pipe, and a compressed air utilizer which is provided in a flow path on a downstream side of the compressed air storage tank and utilizes the compressed air, the method comprising: suctioning the air into the air compression pipe from the air suction port during a backwash; opening the pressure return on-off valve after confirming suction of the air with the pressure measuring device; returning a part of the compressed air filled in the compressed air storage tank to the inside of the air compression pipe through the pressure return pipe; and lowering a water surface in the air compression pipe to be lower than the air throttle. 2. The control method of a wave power utilization device of claim 1 , wherein a water level detecting device for detecting a water level in the air compression pipe is installed in the air compression pipe, and the opening and closing of the pressure return on-off valve is controlled by the water level in the air compression pipe detected by the water level detecting device. 3. The control method of a wave power utilization device of claim 1 , wherein a wave height measuring device for measuring a wave height is installed, a pressure inside the air compression pipe for lowering the water level in the air compression pipe to be lower than the air throttle is calculated based on a wave height measured by the wave height measuring device, and the pressure return on-off valve is open until the pressure measuring device installed in the air compression pipe reaches the pressure inside the air compression pipe. 4. The control method for a wave power utilization device of claim 1 , wherein a wave height measuring device for measuring a wave height is installed, and the pressure return on-off valve is opened and the air is discharged from the wave receiving box inlet part in a case where an absolute value of a pressure value at the time of air compression measured by the pressure measuring device in the air compression pipe is lower than a pressure value set according to the wave height measured by the wave height measuring device. 5. A wave power utilization device comprising: a wave receiving box which has a wave receiving box inlet part that is open toward the sea and receives rushing of a wave, has a space filled with seawater from the wave receiving box inlet part toward a downstream side, and is sunk on the coast; a hollow air compression pipe in which a lower pipe is set to have a wider flow path cross-sectional area than that of an upper pipe, an air throttle that connects the lower pipe and the upper pipe to each other in a tapered shape is provided, the lower pipe is connected upright to an upper part on the downstream side of the wave receiving box, and air is compressed to form compressed air; a pressure measuring device which measures a pressure of the air compression pipe; an air suction port connected to an upper end of the air compression pipe and provided with a first check valve to suction the air from an outside of the air compression pipe; an air discharge pipe connected to the upper end of the air compression pipe and provided with a second check valve to discharge the compressed air from an inside of the air compression pipe; a compressed air storage tank installed downstream of the air discharge pipe and filled with the compressed air discharged from the air compression pipe; a pressure return pipe connecting the compressed air storage tank and the air compression pipe to each other; a pressure return on-off valve which is provided in the middle of the pressure return pipe and opens and closes a flow path of the pressure return pipe; a compressed air utilizer which is provided in a flow path on a downstream side of the compressed air storage tank and utilizes the compressed air; a water level detecting device which is installed in the air compression pipe and detects a water level in the air compression pipe; and a control device that controls the pressure return on-off valve based on the water level in the air compression pipe detected by the water level detecting device. 6. A wave power utilization device comprising: a wave receiving box which has a wave receiving box inlet part that is open toward the sea and receives rushing of a wave, has a space filled with seawater from the wave receiving box inlet part toward a downstream side, and is sunk on the coast; a hollow air compression pipe in which a lower pipe is set to have a wider flow path cross-sectional area than that of an upper pipe, an air throttle that connects the lower pipe and the upper pipe to each other in a tapered shape is provided, the lower pipe is connected upright to an upper part on the downstream side of the wave receiving box, and air is compressed to form compressed air; a pressure measuring device which measures a pressure of the air compression pipe; an air suction port connected to an upper end of the air compression pipe and provided with a first check valve to suction the air from an outside of the air compression pipe; an air discharge pipe connected to the upper end of the air compression pipe and provided with a second check valve to discharge the compressed air from an inside of the air compression pipe; a compressed air storage tank installed downstream of the air discharge pipe and filled with the compressed air discharged from the air compression pipe; a pressure return pipe connecting the compressed air storage tank and the air compression pipe to each other; a pressure return on-off valve which is provided in the middle of the pressure return pipe and opens and closes a flow path of the pressure return pipe; a compressed air utilizer which is provided in a flow path on a downstream side of the compressed air storage tank and utilizes the compressed air; a wave height measuring device for measuring a wave height; and a control device that calculates a pressure inside the air compression pipe for lowering a water level in the air compression pipe based on the wave height measured by the wave height measuring device to be lower than the air throttle, and controls the pressure return on-off valve such that a pressure value measured by the pressure measuri