[1]吴晓春,左鹏鹏. 国内外热作模具钢发展现状与趋势[J]. 模具工业, 2013(10): 1-9.
WU Xiaochun, ZUO Pengpeng. Development Status and Trend of Hot Working Die Steels at Home and Abroad [J]. Die & Mould Industry, 2013(10):1-9.
[2]JHAVAR S, PAUL C P, JAIN N K. Causes of Failure and Repairing Options for Dies and Molds: a Review [J]. Engineering Failure Analysis, 2013, 34: 519-535.
[3]SPERA D A, MOWBRAY D F. Thermal Fatigue of Materials and Components[M].Philadelphia: ASTM, 1976:15-26.
[4]COFFIN L F. A Study of the Effects of Cyclic Thermal Stresses on a Ductile Metal [J]. Transactions of National Research Institute for Metals, 1954, 76:931-950.
[5]MANSON S S. Behavior of Materials under Conditions of Thermal Stress[J]. National Advisory Committee for Aeronautics,1954, 7(S3/4):661-665.
[6]左鹏鹏,吴晓春,曾艳,等.基于应变控制的4Cr5MoSiV1热作模具钢热机械疲劳行为[J].工程科学学报,2018,40(1):76-83.
ZUO Pengpeng, WU Xiaochun, ZENG Yan, et al. Strain-controlled Thermal-mechanical Fatigue Behavior of 4Cr5MoSiV1 Hot Work Die Steel [J]. Chinese Journal of Engineering,2018,40(1):76-83.
[7]BOAS W, HONEYCOMBE R W K. The Anisotropy of Thermal Expansion as a Cause of Deformation in Metals and Alloys[J]. Proceedings of the Royal Society of London, 1947, 188(1015):427-439.
[8]SKUMAVC A, TUEK J, NAGODE A, et al. Thermal Fatigue Study of Tungsten Alloy WNi28Fe15 Cladded on AISI H13 Hot Work Tool Steel[J]. Surface and Coatings Technology, 2016, 285: 304-311.
[9]BIROL Y. Response to Thermal Cycling of Duplex-coated Hot Work Tool Steels at Elevated Temperatures[J]. Materials Science and Engineering: A, 2011, 528(29): 8402-8409.
[10]张学友,左鹏鹏,何西娟,等. 氮含量对热作模具钢4Cr5Mo2V热疲劳性能的影响[J]. 金属热处理, 2017,42(1): 9-14.
ZHANG Xueyou, ZUO Pengpeng, HE Xijuan, et al. Effect of Nitrogen Content on Thermal Fatigue Property of Hot Work Die Steel 4Cr5Mo2V [J]. Heat Treatment of Metals, 2017,42(1):9-14.
[11]李新城, 吴文峰, 孙庆普. 基于偏最小二乘的热作模具钢热疲劳性能预测研究[J]. 机械强度, 2010, 32(5):134-138.
LI Xincheng, WU Wenfeng, SUN Qingpu. “Study of Hot-working Steels” Thermal-fatigue Property Prediction Based on PLS [J]. Journal of Mechanical Strength, 2010,32(5):134-138.
[12]MELLOULI D, HADDAR N, KSTER A, et al. Hardness Effect on Thermal Fatigue Damage of Hot-working Tool Steel [J]. Engineering Failure Analysis, 2014, 45: 85-95.
[13]郭冰峰,樊永军,刘宪东,等. 25Cr12Ni5Mo钢热疲劳损伤特性研究[J]. 材料热处理学报, 2007(S1): 49-52.
GUO Bingfeng, FAN Yongjun, LIU Xiandong, et al. Study on Thermal Fatigue Damage Characteristics of 25Cr12Ni5Mo Steel [J]. Transactions of Materials and Heat Treatment, 2007(S1):49-52.
[14]吴晓春,许珞萍. Uddeholm热疲劳图谱的分析与定量评定[J]. 理化检验(物理分册), 2002, 38(1): 14-17.
WU Xiaochun, XU Luoping.Quantitative Analysis and Evaluation of the Uddeholm Heat-checking Scale [J]. Physical Testing and Chemical Analysis (Part A: Physical Testing), 2002,38(1):14-17.
[15]谢豪杰, 吴晓春. 热作模具钢热疲劳损伤程度的计算机评定[J]. 上海金属, 2008, 30(3):55-58.
XIE Haojie, WU Xiaochun. Computer Evaluation for the Degree of Thermal Fatigue Damage of Hot Working Die Steel [J]. Shanghai Metals,2008,30(3):55-58.
[16]PARIS P , ERDOGAN F . A Critical Analysis of Crack Propagation Laws[J]. Transactions of the ASME, 1963, 85(4):528-533.
[17]周路海. 热冲压成型用模具钢SDCM的组织与性能研究[D]. 上海:上海大学, 2015.
ZHOU Luhai. Study on Microstructure and Properties of SDCM Hot Stamping Tool Steels [D].Shanghai: Shanghai University, 2015.
[18]LEFEBVRE D, ELLYIN F. Cyclic Response and Inelastic Strain Energy in Low Cycle Fatigue [J]. International Journal of Fatigue, 1984, 6(1): 9-15.
[19]COFFIN L F. The Multi-stage Nature of Fatigue: a Review[J]. Metal Science, 1977, 11(2):68-72.
[20]施占华,汤继跃,李熙章,等. 用应变能法研究模具钢的热疲劳性能[J]. 安徽工学院学报, 1988,7(2): 32-39.
SHI Zhanhua, TANG Jiyue, LI Xizhang, et al.Strain Energy Damage Model and Its Application to Tool Steel [J]. Journal of Anhui Institute of Technology, 1988,7(2):32-39.
[21]OSTERGREN W J. Correlation of Hold Time Effects in Elevated Temperature Low Cycle Fatigue Using a Frequency Modified Damage Function [C]∥The ASME-MPC Symposium on Creep-fatigue Interaction. New York: ASME, 1976:179-202.
[22]PAN X, LI X, CHANG L, et al. Thermal-mechanical Fatigue Behavior and Lifetime Prediction of P92 Steel with Different Phase Angles [J]. International Journal of Fatigue, 2018, 109: 126-136.
[23]TAIRA S,MOTOAKI F, TAKASHI H. A Method for Life Prediction of Thermal Fatiogue by Isothermal Fatigue Testing[C]∥Symp. Mech. Behav. Mater.: Soc. Mater. Sci.. Kyoto, 1974:257-264.
[24]HALFORD G R , NACHTIGALL A J . Strainrange Partitioning Behavior of an Advance Gas Turbine Disk Alloy AF2-1DA[J]. Journal of Aircraft, 1980, 17(8):598-604.
[25]何晋瑞,段作祥,宁有连,等. 应变能区分法及其对GH33A与1Cr18Ni9Ti的应用[J]. 金属学报, 1985,21(1): 54-63.
HE Jinrui, DUAN Zuoxiang, NING Youlian, et al. Strain Energy Partitioning and Its Application to GH33A Ni-base Super-alloy and 1Cr18Ni9Ti Stainless Steel [J]. Acta Metallurgica Sinica, 1985,21(1):54-63.
[26]董照钦, 段作祥, 何晋瑞. 应变能-频率分离法及其应用[J]. 航空学报, 1985, 6(5):461-466.
DONG Zhaoqin, DUAN Zuoxiang, HE Jinrui. A Strain Energy-frequency Separation Method and Its Application [J]. Acta Aeronautica et Astronautica Sinca, 1985, 6(5):461-466.
[27]胡绪腾, 宋迎东. 应用总应变-应变能区分法预测热机械疲劳寿命[J]. 燃气涡轮试验与研究, 2012,25(1):14-16.
HU Xuteng, SONG Yingdong. Life Prediction for Thermomechanical Fatigue Using Total Strain Version of Strain Energy Partitioning [J]. Gas Turbine Experiment and Research, 2011,25(1):14-16.
[28]纪冬梅,轩福贞,涂善东,等. P91钢的蠕变-疲劳交互作用研究现状[J]. 压力容器, 2011, 28(6): 37-43.
JI Dongmei, XUAN Fuzhen, TU Shandong, et al.Summary of Research on Creep-fatigue Interaction of P91 Steel [J]. Pressure Vessel Technology, 2011,28(6):37-43.
[29]陈凌,张贤明,欧阳平. 一种疲劳-蠕变交互作用寿命预测模型及试验验证[J]. 中国机械工程, 2015, 26(10): 1356-1361.
CHEN Ling, ZHANG Xianming, OUYANG Ping. A Model of Life Prediction for Fatigue-creep Interaction and Its Experimental Verification [J]. China Mechanical Engineering, 2015, 26(10): 1356-1361.
[30]施惠基,牛莉莎,王中光. 高温合金材料循环相关热机械疲劳寿命预测[J]. 固体力学学报, 1998,19(1): 89-93.
SHI Huiji, NIU Lisha, WANG Zhongguang. Lifetime Prediction of Cyclic Dependent Thermomechanical Fatigue on High Temperature Alloys [J]. Acta Mechanica Solida Sinica, 1998,19(1):89-93.
[31]CHABOCHE J L, LESNE P M. A Non-linear Continuous Fatigue Damage Model[J]. Fatigue & Fracture of Engineering Materials & Structures, 1988, 11(1): 1-17.
[32]LEMAITRE J, DESMORAT R. Engineering Damage Mechanics[M]. Berlin: Springer, 2005.
[33]WANG W, BUHL P, KLENK A, et al. A Continuum Damage Mechanics-based Viscoplastic Model of Adapted Complexity for High Temperature Creep-fatigue Loading[J]. Journal of Engineering for Gas Turbines & Power, 2016, 138(9):092501.
[34]SOMMITSCH C, SIEVERT R, WLANIS T, et al. Modelling of Creep-fatigue in Containers during Aluminium and Copper Extrusion[J]. Computational Materials Science, 2007, 39(1): 55-64.
[35]方建儒. 热作模具钢微观组织对热机械疲劳行为的影响[D]. 长春:吉林大学, 2002.
FANG Jianru. Effect of Microstructure on Thermomechanical Fatigue Behavior of Hot Work Die Steel [D]. Changchun: Jilin University, 2002.
[36]CUI L, WANG P. Two Lifetime Estimation Models for Steam Turbine Components under Thermomechanical Creep-fatigue Loading[J]. International Journal of Fatigue, 2014, 59(SC): 129-136.
[37]段兴旺,刘建生,郑晓华,等. 316LN钢裂纹萌生的临界损伤值[J]. 塑性工程学报, 2013, 20(3): 60-64.
DUAN Xingwang, LIU Jiansheng, ZHENG Xiaohua, et al. Critical Damage Value of 316LN Steel Crack Initiation [J]. Journal of Plasticity Engineering, 2013,20(3):60-64.
[38]李爽,陈士浩,何西娟,等. 两种热作模具钢高温耐磨性对比研究[J]. 摩擦学学报, 2017, 37(1): 59-67.
LI Shuang, CHEN Shihao, HE Xijuan, et al.A Comparison of Wear Resistance of Two Types Hot-work Die Steels at High Temperature [J].Tribology, 2017,37(1):59-67.
[39]唐睿,胡成亮,赵震. 一种考虑侧接触切向滑动的微凸体弹塑性变形传热模型[J]. 上海交通大学学报, 2017, 51(5): 520-525.
TANG Rui, HU Chengliang, ZHAO Zhen. An Elastic-plastic Heat Transfer Model of Two Asperities Contact under Consideration of Shoulder-shoulder Contact and Tangential Sliding[J]. Journal of Shanghai Jiao Tong University, 2017,51(5):520-525.
[40]周路海,张洪波,黎军顽,等. H13热作模具钢感应加热循环过程的数值模拟[J]. 材料热处理学报, 2016, 37(2): 227-234.
ZHOU Luhai, ZHANG Hongbo, LI Junwan, et al. Numerical Simulation on Induction Heating Cycle Process of H13 Hot-work Die Steel [J]. Transactions of Materials and Heat Treatment, 2016,37(2):227-234. |