A strain-gradient crystal plasticity constitutive model was developed in order to predict the Hall Petch behavior of a Ni-base polycrystalline superalloy. The constitutive model involves statistically stored dislocation and geometrically necessary dislocation densities, which were incorporated into the Bailey-Hirsch type flow stress equation with six strength interaction coefficients. A strain-gradient term (called slip-system lattice incompatibility) developed by Acharya was used to calculate the geometrically necessary dislocation density. The description of Kocks-Argon-Ashby type thermally activated strain rate was also used to represent the shear rate of an individual slip system. The constitutive model was implemented in a user material subroutine for crystal plasticity finite element method simulations. The grain size dependence of the flow stress (viz., the Hall- Petch behavior) was predicted for a Ni-base polycrystalline superalloy NIMONIC PE16. Simulation results showed that the present constitutive model fairly reasonably predicts 0.2%-offset yield stresses in a limited range of the grain size.

1. 서 론
 2. 변형구배 결정소성 모델(strain gradientcrystal plasticity model)
 3. Hall-Petch 거동 예측을 위한 SGCPFEM모델링
 4. 모델링 결과 및 고찰
 5. 결 론
 감사의 글
 References

• 최윤석(부산대학교 공과대학 재료공학부) | Yoon Suk Choi Corresponding author
• 조경목(부산대학교 공과대학 재료공학부) | Kyung-Mox Cho
• 남대근(한국생산기술연구원 동남권 지역본부) | Dae-Geun Nam
• 최일동(한국해양대학교 공과대학 조선기자재공학부) | Il-Dong Choi