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The purpose of this study is twofold: to clarify the factors governing the torsional strength of surface induction hardened parts and, to present a method for strengthening automotive shaft parts for their weight reduction. The torsional strength against Mode III fracture can be expresssed by a new indicator, “equivalent hardness” defined as an average hardness weighted with the radius squared. If the equivalent hardness is continuously increased, the fracture mode change from Mode III to Mode I. The torsional strength against Mode I fracture is governed by grain boundary strength. Accordingly, the key-points in increasing the torsional strength of surface induction hardened parts are to raise the equivalent hardness and increase the grain boundary strength of the steel. By application of this method, the torsional strength of steel can be raised by 50%, which, in turn, enables about a 25% weight reduction for shaft parts.

Carburizing heat treatment is one of the automobile component manufacturing steps, which consumes a large amount of energy. Raising the carburizing temperature can shorten the carburizing time and save the energy, but involves the risks of grain coarsening and attendant property deterioration. The authors have clarified the precipitation behavior of aluminum nitride (A1N) in the automobile gear manufacturing process and the optimum precipitation of A1N in as-rolled steel bars to prevent the grain coarsening. Through the application of the controlled rolling technique to ensure the optimum precipitation of A1N in continuously cast steel of uniform chemical composition, the authors have substantially saved energy while maintaining high quality, and developed a high-temperature carburizing steel expected to minimize and stabilize quenching strains.