Superconducting magnet and MRI apparatus

What is claimed is: 1 . A superconducting magnet configured to be used in an MRI apparatus that includes a gradient coil configured to apply a gradient magnetic field to an object, the superconducting magnet comprising: a helium vessel configured to contain a superconducting coil configured to generate a static magnetic field; a vacuum vessel configured to thermally insulate inside of the superconducting magnet by vacuum; and a heat shield configured to be disposed between the helium vessel and the vacuum vessel and reduce radiant heat, wherein: the superconducting magnet is disposed in such a manner that distance between the gradient coil and the object is shorter than distance between the superconducting magnet and the object; among components constituting the heat shield, at least a component of a portion facing the gradient coil is composed by superimposing two layers of metallic materials, the two layers being a first shield layer and a second shield layer; the first shield layer is disposed in such a manner that distance between the gradient coil and the first shield layer is shorter than distance between the gradient coil and the second shield layer; and a metallic material forming the first shield layer is higher in electrical conductivity than a metallic material forming the second shield layer. 2 . The superconducting magnet according to claim 1 , wherein a metallic material forming the second shield layer is higher in mechanical strength than a metallic material forming the first shield layer. 3 . The superconducting magnet according to claim 1 , wherein: a metallic material forming the first shield layer is a first aluminum material; and a metallic material forming the second shield layer is a second aluminum material different from the first aluminum material. 4 . The superconducting magnet according to claim 3 , wherein: the first aluminum material is A1050; and the second aluminum material is A5083 or A6061. 5 . The superconducting magnet according to claim 1 , wherein: a metallic material forming the first shield layer is an aluminum material; and a metallic material forming the second shield layer is a stainless-steel material. 6 . The superconducting magnet according to claim 1 , wherein: a metal material forming the first shield layer is one of an aluminum material and a copper material, and a metal material forming the second shield layer is other of the aluminum material and the copper material; and of the copper material and the aluminum material, one material with higher electrical conductivity forms the first shield layer and the other material with lower electrical conductivity forms the second shield layer. 7 . The superconducting magnet according to claim 1 , wherein thickness of a metallic material forming the first shield layer and thickness of a metallic material forming the second shield layer are optimized based on mechanical strength and a resistance value. 8 . The superconducting magnet according to claim 1 , wherein the first shield layer and the second shield layer are superimposed by any one of welding, friction welding, swaging, screwing, clamping, and shrink fitting. 9 . The superconducting magnet according to claim 1 , wherein an electrically insulating material is disposed between the first shield layer and the second shield layer. 10 . An MRI apparatus comprising: a gradient coil configured to apply a gradient magnetic field to an object; and a superconducting magnet, wherein: the superconducting magnet comprises a helium vessel containing a superconducting coil configured to generate a static magnetic field, a vacuum vessel configured to thermally insulate inside of the superconducting magnet by vacuum, and a heat shield disposed between the helium vessel and the vacuum vessel and configured to reduce radiant heat; the gradient coil is disposed in such a manner that distance between the gradient coil and the object is shorter than distance between the superconducting magnet and the object; among components constituting the heat shield, at least a component of a portion facing the gradient coil is composed by superimposing two layers of metallic materials, the two layers being a first shield layer and a second shield layer; the first shield layer is disposed in such a manner that distance between the gradient coil and the first shield layer is shorter than distance between the gradient coil and the second shield layer; and a metallic material forming the first shield layer is higher in electrical conductivity than a metallic material forming the second shield layer.