Commutator, electric motor, and method for manufacturing commutator

The invention claimed is: 1. A commutator formed in a cylindrical shape along an axial center, the commutator comprising, in a direction orthogonal to the axial center: an electrically conductive part which is situated on an outer periphery side of the commutator, and contains an electrically conductive material and in which a plurality of commutator pieces are formed to extend from an outer periphery surface of the commutator toward an opposite side of the axial center; a resin part which is situated on an inner periphery side of the commutator, and contains a resin material; a ceramic part which is situated between the electrically conductive part and the resin part, and contains a ceramic material; a first mixing part which is situated between the electrically conductive part and the ceramic part, and contains the electrically conductive material and the ceramic material in mixture and in which a content of the electrically conductive material decreases and a content of the ceramic material increases from the electrically conductive part toward the ceramic part; and a second mixing part which is situated between the ceramic part and the resin part, and contains the ceramic material and the resin material in mixture and in which a content of the ceramic material decreases and a content of the resin material increases from the ceramic part toward the resin part. 2. The commutator according to claim 1 , wherein the first mixing part includes a functionally gradient material containing the electrically conductive material and the ceramic material in mixture, and the second mixing part includes a functionally gradient material containing the ceramic material and the resin material in mixture. 3. The commutator according to claim 1 , wherein the electrically conductive part further includes a groove part which is recessed toward the axial center from the outer periphery surface on a surface orthogonal to the axial center, between each pair of adjacent commutator pieces among the plurality of commutator pieces. 4. The commutator according to claim 3 , wherein the groove part is formed along the axial center, and electrically isolates a pair of the adjacent commutator pieces. 5. The commutator according to claim 3 , wherein a depth of the groove part extends from the outer periphery surface to an outer periphery surface of the first mixing part on the surface orthogonal to the axial center. 6. The commutator according to claim 3 , wherein a depth of the groove part extends from the outer periphery surface to an inner periphery surface of the first mixing part on the surface orthogonal to the axial center. 7. The commutator according to claim 3 , wherein a capacitance generated between a pair of the adjacent commutator pieces is 0.5 μF or more. 8. The commutator according to claim 3 , wherein a capacitance generated between a pair of the adjacent commutator pieces is 1.0 μF or more. 9. The commutator according to claim 3 , wherein the first mixing part that forms the groove part, or each of the first mixing part that forms the groove part and the ceramic part has a relative dielectric constant of 100 or more. 10. The commutator according to claim 3 , wherein the first mixing part that forms the groove part, or each of the first mixing part that forms the groove part and the ceramic part has a relative dielectric constant of 1000 or more. 11. An electric motor which comprises: a rotor including: the commutator according to claim 3 ; a shaft which has a central axis situated on the axial center and to which the commutator is attached; and a rotor core attached to the shaft; and a stator situated so as to face the rotor. 12. A method for manufacturing the commutator according to claim 3 , the method comprising: providing the electrically conductive material, the ceramic material and the resin material; separately packing the electrically conductive material, the ceramic material and the resin material, and separately packing the electrically conductive material and the ceramic material in mixture, and the ceramic material and the resin material in mixture; and feeding an electric current pulsewise through the packed electrically conductive material, the electrically conductive material and the ceramic material packed in mixture, the packed ceramic material, the ceramic material and the resin material packed in mixture, and the packed resin material while applying a pressure to these materials.