Prepreg and carbon fiber reinforced composite materials

The invention claimed is: 1. A carbon fiber reinforced composite material manufactured by curing a prepreg containing: a thermosetting resin [B], carbon fibers [A] impregnated with the thermosetting resin [B], conductive particles [E] included in the thermosetting resin [B], and a conductive filler having smaller average diameter than the average diameter of the conductive particles [E], wherein the conductive particles [E] localize around a surface portion of the prepreg, wherein, the conductive filler is mixed in the thermosetting resin [B], wherein, the conductive particles [E] have a spherical shape and have a thermoplastic resin nucleus coated with a conductive substance to form a conductive coating layer on the surface of the nucleus, wherein the conductive coating layer is an aggregate of conductive fiber, carbon black or a metallic fine particles, and wherein strain an energy release rate of the thermoplastic resin of the conductive particles [E] determined, by compact tension method defined in ASTM D 5045-96 by using a resin plate made of the press-molded thermoplastic resin is 1500 to 50000 J/m 2 , and a volume ratio of the conductive particles [E] expressed by [volume of nucleus]/[volume of conductive coating layer] is 0.1 to 500, and the conductive particles [E], having thermoplastic resin nuclei coated with a conductive substance, are localized between two layers formed by the carbon fibers [A], and the conductive particles [E] form a conductive path between the two layers formed by the carbon fibers [A] of the carbon fiber reinforced composite material. 2. An aircraft structural member formed from the carbon fiber reinforced composite material according to claim 1 . 3. A carbon fiber reinforced composite material manufactured by curing a prepreg containing: a thermosetting resin [B], carbon fibers [A] impregnated with the thermosetting resin [B], conductive particles [E] included in the thermosetting resin [B], and a conductive filler having smaller average diameter than the average diameter of the conductive particles [E], wherein the conductive particles [E] localize around a surface portion of the prepreg, wherein, the conductive filler is mixed in the thermosetting resin [B], wherein, the conductive particles [E] have a spherical shape and have a thermoplastic resin nucleus coated with a conductive substance to form a conductive coating layer on the surface of the nucleus, wherein the conductive layer is an aggregate of fibrous or particulate conductive substances, and wherein strain an energy release rate of the thermoplastic resin of the conductive particles [E] determined, by compact tension method defined in ASTM D 5045-96 by using a resin plate made of the press-molded thermoplastic resin is 1500 to 50000 J/m 2 , and a volume ratio of the conductive particles [E] expressed by [volume of nucleus]/[volume of conductive coating layer] is 0.1 to 500, and the conductive particles [E], having thermoplastic resin nuclei coated with a conductive substance, are localized between two layers formed by the carbon fibers [A], and the conductive particles [E] form a conductive path between the two layers formed by the carbon fibers [A] of the carbon fiber reinforced composite material. 4. An aircraft structural member formed from the carbon fiber reinforced composite material according to claim 3 . 5. The carbon fiber reinforced composite material according to claim 3 , wherein the total weight of the conductive particles [E] is 1 to 20 wt % with respect to the prepreg. 6. The carbon fiber reinforced composite material according to claim 3 , wherein the conductive fillers are carbon black. 7. The carbon fiber reinforced composite material according to claim 3 , wherein the prepreg further includes a thermoplastic resin being dissolved in the thermosetting resin [B]. 8. The carbon fiber reinforced composite material according to claim 3 , wherein the thermoplastic resin being dissolved in the thermosetting resin [B] is polyether sulfone. 9. A prepreg for making a carbon fiber composite material in a thickness direction formed by molding and curing the two or more prepregs, wherein the prepreg containing: a thermosetting resin [B], carbon fibers [A] impregnated with the thermosetting resin [B], conductive particles [E] included in the thermosetting resin [B], and a conductive filler having smaller average diameter than the average diameter of the conductive particles [E], wherein the conductive particles [E] localize around a surface portion of the prepreg, wherein, the conductive filler is mixed in the thermosetting resin [B], wherein, the conductive particles [E] have a spherical shape and have a thermoplastic resin nucleus coated with a conductive substance to form a conductive coating layer on the surface of the nucleus, wherein the conductive coating layer is an aggregate of conductive fiber, carbon black or a metallic fine particles, and wherein strain an energy release rate of the thermoplastic resin of the conductive particles [E] determined, by compact tension method defined in ASTM D 5045-96 by using a resin plate made of the press-molded thermoplastic resin is 1500 to 50000 J/m 2 , and a volume ratio of the conductive particles [E] expressed by [volume of nucleus]/[volume of conductive coating layer] is 0.1 to 500. 10. A prepreg for making a carbon fiber composite material in a thickness direction formed by molding and curing the two or more prepregs, wherein the prepreg containing: a thermosetting resin [B], carbon fibers [A] impregnated with the thermosetting resin [B], conductive particles [E] included in the thermosetting resin [B], and a conductive filler having smaller average diameter than the average diameter of the conductive particles [E], wherein the conductive particles [E] localize around a surface portion of the prepreg, wherein, the conductive filler is mixed in the thermosetting resin [B], wherein, the conductive particles [E] have a spherical shape and have a thermoplastic resin nucleus coated with a conductive substance to form a conductive coating layer on the surface of the nucleus, wherein the conductive coating layer is an aggregate of fibrous or particulate conductive substances, and wherein strain an energy release rate of the thermoplastic resin of the conductive particles [E] determined, by compact tension method defined in ASTM D 5045-96 by using a resin plate made of the press-molded thermoplastic resin is 1500 to 50000 J/m2, and a volume ratio of the conductive particles [E] expressed by [volume of nucleus]/[volume of conductive coating layer] is 0.1 to 500.