Superconducting magnet

The invention claimed is: 1. A superconducting magnet, comprising: a superconducting coil; a refrigerant container accommodating said superconducting coil which is in a state of being immersed in a liquid refrigerant; a radiation shield surrounding said refrigerant container; a vacuum container accommodating said superconducting coil, said refrigerant container, and said radiation shield; a refrigerating machine cooling an interior of said refrigerant container and said radiation shield; a tubular current lead passing from outside of said vacuum container to inside of said refrigerant container to constitute a flow path of said gasified refrigerant and being electrically connected to said superconducting coil; a power source arranged outside of said vacuum container and electrically connected to said current lead; a manometer measuring a pressure inside of said refrigerant container; a thermometer arranged in said vacuum container to measure a temperature of said current lead; and a control unit connected to each of said power source, said manometer, and said thermometer; a disturbance magnetic field compensating coil arranged outside of said superconducting coil and immersed in said refrigerant in said refrigerant container for suppressing an influence of a disturbance magnetic field with respect to said superconducting coil; a persistent current switch immersed in said refrigerant in said refrigerant container and connected to said disturbance magnetic field compensating coil electrically in serial; and a heater arranged adjacent to said persistent current switch in said refrigerant container, immersed in said refrigerant, and electrically connected to said control unit, said control unit allowing a current from said power source to flow into said heater to gasify said refrigerant of an amount required cool said current lead while resetting an output of said disturbance magnetic field compensating coil by means of said persistent current switch, said control unit raising an output of said power source to vary a value of a current flowing into said superconducting coil only when a measurement value of said manometer is higher than or equal to a set value and a measurement value of said thermometer is lower than or equal to a set value. 2. The superconducting magnet according to claim 1 , further comprising a heater arranged adjacent to said current lead in said refrigerant container to heat said current lead. 3. The superconducting magnet according to claim 1 , wherein material of said current lead contains phosphorous deoxidized copper as a main component. 4. A superconducting magnet, comprising: a superconducting coil; a refrigerant container accommodating said superconducting coil which is in a state of being immersed in a liquid refrigerant; a radiation shield surrounding said refrigerant container; a vacuum container accommodating said superconducting coil, said refrigerant container, and said radiation shield; a refrigerating machine cooling an interior of said refrigerant container and said radiation shield; a tubular current lead passing from outside of said vacuum container to inside of said refrigerant container to constitute a flow path of said gasified refrigerant and being electrically connected to said superconducting coil; a power source arranged outside of said vacuum container and electrically connected to said current lead; a flow meter measuring a flow rate of said gasified refrigerant through inside of said current lead; a thermometer arranged in said vacuum container to measure a temperature of said current lead; and a control unit connected to each of said power source, said flow meter, and said thermometer; a disturbance magnetic field compensating coil arranged outside of said superconducting coil and immersed in said refrigerant in said refrigerant container for suppressing an influence of a disturbance magnetic field with respect to said superconducting coil; a persistent current switch immersed in said refrigerant in said refrigerant container and connected to said disturbance magnetic field compensating coil electrically in serial; and a heater arranged adjacent to said persistent current switch in said refrigerant container, immersed in said refrigerant, and electrically connected to said control unit, said control unit allowing a current from said power source to flow into said heater to gasify said refrigerant of an amount required cool said current lead while resetting an output of said disturbance magnetic field compensating coil by means of said persistent current switch, said control unit raising an output of said power source to vary a value of a current flowing into said superconducting coil only when a measurement value of said flow meter is higher than or equal to a set value and a measurement value of said thermometer is lower than or equal to a set value.