Professor
Supervisor of Master's Candidates
Supervisor of Doctorate Candidates
副院长
E-Mail:
Business Address:School of mechanics and Engineering, Southwest Jiaotong University,No.111, Section 1, 2nd Ring Road North, Chengdu, 610031, China
MOREMaterial constitutive relationship and fatigue fracture research team (teacher)
The team is led by Professor Kang Guozheng, Dean of the School of Mechanics, and has won 3 provincial and ministerial-level natural science and scientific and technological progress second prizes, and 2 national teaching achievement second prizes. The team is mainly engaged in basic theoretical research on the constitutive relationship of advanced materials, fatigue and fracture mechanics, composite material mesomechanics, smart materials and structural mechanics, and the evaluation of the service safety and remaining life of engineering structures. Funds for scientific research are sufficient. In recent years, it has undertaken key projects from the National Natural Science Foundation of China, the National Science Fund for Distinguished Young Scholars, the General and Youth Project of the National Natural Science Foundation of China, key research and development sub-projects and sub-tasks, and projects supported by the Sichuan Science and Technology Innovation Team. There are many provincial and ministerial projects and various horizontal service projects. The current team members include 4 professors (Kang Guozheng, Kan Qianhua, Wu Shengchuan, Zhang Xu), 6 associate professors (Zhang Juan, Liu Yujie, Yu Chao, Yuan Jianghong; Miao Hongchen, Li Yingxu) and 1 postdoctoral fellow (Qiang Bin). Approximately 66 students (22 PhD students; 42 master students).
Mechanics of materials
Principle and application of ANSYS
Introduction to mechanics and Engineering
Practical writing
Principle and application of finite element method
1.Wheel Rail Rolling Contact Research Group
The research team was established in September 2017. Mainly carry out the research of wheel-rail rolling contact problems, including the cyclic deformation behavior of wheel-rail materials, wheel-rail rolling contact life prediction, wheel-rail rolling contact wear and wheel-rail life extension. Existing doctoral students (3): Xu Xiang, Zhao Jizhong, Fu Peilin; Master students (6): Feng Dagang, Shi Pishun, Jiang Liyi, Wang Mengfan, Wang Shuna, Chen Jia.
2.Smart Materials Research Group
The research team was established in September 2017. Mainly carry out research on cyclic deformation behavior and constitutive models of smart materials such as shape memory alloys and shape memory polymers. Existing doctoral students (5 people): Qiu Bo, Li Jian, Ding Li, Wang Ziyi, Liang Zhihong; master students (4 people): Zhang Chen, Zhao Jiaxiang, Zhang Xuelian, Tang Yanjie.
[1] 2011.11 national Xu Zhilun mechanical excellent teacher award of Chinese mechanical Society
[2] In September 2018, the second prize of Sichuan Provincial Science and Technology Progress Award (19kjjb2305), damage mechanism and service behavior assessment technology for key components of high-speed railway, Wu Shengchuan, Kai Qianhua, Kang Guozheng, Ma Lijun, Qian kuncai, Wang Yuan, Liu Yujie, bu Jiling.
[3] October 2018, Yang Hua, a scholar of Southwest Jiaotong University
[4] 2018.09 national level teaching achievement two prize (G22018400), team integration, platform exchange, resource sharing, collaborative innovation - create a new model of Internet plus basic mechanics class group, Kang Guo Zheng, Shen Hsun Ming, Lu Li, Jiang Xiaoyu, Gao Fangqing, Yang Yiren, Zhu Zhiwu, Kan Qian Hua, Li Yinghui, Chiang Han, Gong Hui
[5] 2017.12 Sichuan province teaching achievement award (GJ100610-1), team integration, platform exchange, resource sharing, collaborative innovation - create a new model of Internet plus basic mechanics class group, Kang Guo Zheng, Shen Hsun Ming, Lu Li, Jiang Xiaoyu, Gao Fangqing, Yang Yiren, Zhu Zhiwu, Kan Qian Hua, Li Yinghui, Jiang Han
[6] The third prize of science and technology award of CNNC in January 2017 (2016-3-11-04), elastic-plastic fatigue analysis and experimental technology of titanium alloy for steam generator, kaiqianhua
[7] In December 2016, the second prize of teaching achievement of Southwest Jiaotong University (jxcg201602051), source cultivation, process supervision, academic guidance, award aided navigation - to build a high-quality doctoral training guarantee system, Li Yinghui, Kang Guozheng, Yang Yiren, Ma Xiaomei
[8] In December 2016, the second prize of teaching achievement of Southwest Jiaotong University (jxcg201601034), the experimental resources were macroscopically planned and carefully manufactured to create the excellent operation mode of students' extracurricular practice and innovation activities. Gao Fangqing, Kang Guozheng, Luo Huiliang, Chu Jielei, Liu Juan, Kai Qianhua, Xiong Li, Xing Jianxin were selected
[9] 2016.12 Southwest Jiao Tong University's teaching achievement first prize (JXCG201601038), team integration, platform exchange, resource sharing, collaborative innovation -- creating a new model of Internet plus basic mechanics course group, Kang Guo Zheng, Shen Hsun Ming, Lu Li, Jiang Xiao Yu, Gao Fang Qing, Yang Yiren, Zhu Zhi Wu, Kan Qian Hua, Li Yinghui, Jiang Han
[10] 2016.12 Sichuan outstanding youth fund
[11] December 2014, outstanding scholar of Tang Lixin, Chen Qianhua
[12] June 2014, the star of Southwest Jiaotong University
[13] 2012.01 Excellent Doctoral Dissertation of Sichuan Province, constitutive model research and finite element application of hyperelastic NiTi alloy, kaiqianhua
[14] 2011.05 the second prize of the second young faculty computer operation skills competition of Southwest Jiaotong University
[15] The second prize of Natural Science Award of the Ministry of education in January 2011, research on non proportional multi axial ratcheting fatigue interaction of engineering materials, Kang Guozheng, Liu Yujie, Yang Xianjie, Gao Qing, Kai Qianhua, Cai Lixun, Zhang Juan, sun Yafang
[16] In December 2010, the Australian government's endeavor research fellowship was awarded to China
[17] 2010.12 Excellent Doctoral Dissertation of Southwest Jiaotong University, constitutive model research and finite element application of hyperelastic NiTi alloy, kaiqianhua
[18] 2009.08 Southwest Jiaotong University hundred talents program, kaiqianhua
[19] August 2009, outstanding student of the 17th young teacher training in Sichuan Province
[20] 2008.12 China Railway Electrification special scholarship, kaiqianhua
[21] 2008.12 comprehensive first class scholarship of Southwest Jiaotong University
[22] 2007.12 China Railway Electrification special scholarship, qiqianhua
[23] 2007.12 excellent master's thesis of Sichuan Province, research on constitutive model of SS304 stainless steel and its finite element realization
[24] in December 2007, she was awarded the title of excellent graduate student of Southwest Jiaotong University
[25] 2007.12 comprehensive first class scholarship of Southwest Jiaotong University
[26] December 2007, special fund for doctoral innovation of Southwest Jiaotong University
[27] June 2007, Sanhao student of Sichuan Province, kaiqianhua
[28] March 2007, excellent master's thesis of Southwest Jiaotong University, research on time-dependent constitutive model of SS304 stainless steel and its finite element realization
[29] in December 2006, he was an outstanding student cadre of Southwest Jiaotong University
[30] in April 2006, she was an outstanding graduate student of Sichuan Province
[1] Practice and innovation of student training mode, curriculum system and curriculum construction of mechanics, major teaching reform project of Southwest Jiaotong University, 2020-2021, presided over
[2] Guided by the "double ten thousand plan", accelerate the construction of national first-class major in engineering mechanics, major teaching reform project of Southwest Jiaotong University, 2020-2021, participate in
[3] Engineering Mechanics Course Ideological and political construction project, Southwest Jiaotong University, 2020, participation.
[4] "Realization of nonlinear constitutive relation in ABAQUS", monograph construction project of graduate school, 2020, presided over.
[5] "Realization of nonlinear constitutive relationship in ABAQUS", Graduate School monograph cultivation project, 2018, presided over.
[6] Research and practice of new engineering education informatization construction under the Internet environment, Ministry of education new engineering research and practice project (Engineering advantage University Group), 2018, participation.
[7] Exploration and practice of interdisciplinary top-notch innovative talents training mode of Mechanics major, Sichuan higher education talent training quality and teaching reform project in 2018-2020, participated in.
[8] Construction and practice of a new mode of interdisciplinary personnel training in mechanics and rail transit, educational research project of higher science society, 2017-2018, participation.
[9] Research and practice of interdisciplinary talent training mode of Engineering Mechanics major, school level major teaching reform project, 2018-2020, participation.
[10] Interdisciplinary talent training mode research and practice, school level major education reform project, 2015-2017, participation.
[11] "Fatigue and fracture mechanics" high quality demonstration course construction, school level teaching reform project, 2014-2015, presided over.
[12] Materials mechanics experiment, theory and simulation new form teaching material construction project, 2016-2017, presided over.
Master students: Qiu Bo, Xie Xi, Li Jian
Doctoral candidates: Wang Hailin, Fu Ren, Mei Zuozhou, Yang Qiangjun, Tang Weiwen, Xie Ruili, Dong Shiyu, Fang Tao, Xu Xiang, Zhang Zebin, Jiang Qinxian, Wei Jianlan, Fan Yilin, Lai Han, Yang Gang, Xing Yuan, Pang Xing, Wang Xiaowen , Zhao Jizhong, Fu Peilin, Liang Zhihong
[1] Kan Qianhua, Kang Guozheng, Xu Xiang. The realization of nonlinear constitutive relations in ABAQUS. Science Press, July 2019, ISBN:978-7-03-061815-3.
[2] Qianhua Kan, Jian Li, Guozheng Kang and Zebin Zhang. Experiments and models of thermo-Induced shape memory polymers, shape-memory materials (Chapter 5), IntechOpen, 2018.9. ISBN:978-1-78923-683-5 .
[3] Guozheng Kang, Qianhua Kan. Cyclic plasticity of Engineering Materials: Experiments and Models, Wiley & Sons Ltd, April 2017, ISBN: 978-1-119-18080-7. (538 pages)
[4] Zhu Yilin, Kang Guozheng, Kan Qianhua. A new kinematic hardening rule describing different plastic moduli in monotonic and cyclic deformations, In: From Creep Damage Mechanics to Homogenization Methods, H. Altenbach et al. (eds.), Advanced Structured Materials, 2015, 64, 587-601 (Chapter 27, Springer International Publishing Switzerland, ISBN: 978-3-319-19439-4).
[5] Kang Guozheng, Kan Qianhua. Ratcheting behavior and ratchet-fatigue interaction of engineering materials, Southwest Jiaotong University Press, January 2014, ISBN: 978-7-5643-2775-0.
[6] Chao Yu, Guozheng Kang, Qianhua Kan, Otto T. Bruhns, Chuanzeng Zhang. A cyclic crystal plastic model considering both dislocation slip and deformation twinning for Ti-6Al-4V alloy. Advanced Structured Materials, Springer Berlin Heidelberg, 2013.
[1] He Qianhua, Zhang Zebin, Zhang Xu, Zhu Zhiwu. Discussion on the construction of digital teaching material of mechanics of materials, 2017, 18 (1): 164-167
[2] Yang Jing, Zhang Junqi, Gao Fangqing, Kai Qianhua. Cultivation of College Students' innovation ability based on science and technology innovation competition, Journal of Southwest Jiaotong University, Social Science Edition, 2017, 18 (1): 52-54
[3] Zhu Zhiwu, Kang Guozheng, Kai Qianhua. Research and practice of interdisciplinary talent training mode, Journal of Southwest Jiaotong University, Social Science Edition, 2017, 18 (1): 9-12
[4] He Qianhua, Zhang Juan, Kang Guozheng, Zhu Zhiwu. Thinking on the construction of top talent training system in mechanics, Journal of Southwest Jiaotong University, Social Science Edition, 2019, 20 (2): 24-27
[5] Yang Jing, Kai Qianhua, Zhang ronghua. Research on the role of peer education in strengthening the construction of academic atmosphere in Colleges and universities, Journal of Southwest Jiaotong University, Social Science Edition, 2019, 20 (2): 96-98
[6] Zhang Juan, Kang Guozheng, Kai Qianhua, Liu Yujie. Reform and practice of teaching design and learning effect evaluation of Mechanics major, Journal of Southwest Jiaotong University, Social Science Edition, 2019, 20 (2): 84-86
[7] Zhu Zhiwu, Kang Guozheng, Kai Qianhua. Thoughts on learning centered teaching mode, Journal of Southwest Jiaotong University, Social Science Edition, 2019, 20 (2): 4-6
[8] He Qianhua, Kang Guozheng, Zhu Zhiwu, Zhang Juan. Thinking on the reform of mechanics foundation course under the background of new engineering, Journal of Southwest Jiaotong University, Social Science Edition, 2019, 20 (2): 103-106
[9] Zhu Zhiwu, Shen Huoming, Kang Guozheng, Kai Qianhua. Thinking on the construction of mechanics course materials in the era of "Internet +", Journal of Southwest Jiaotong University, Social Science Edition, 2020
[10] Kong Xiangbin, Kai Qianhua, Kang Guozheng, Zhou Delong, Cao Ziliang, Zhang Haiyong. Teaching design and implementation of "the way of University" for freshmen of mechanics top class, Journal of Southwest Jiaotong University, Social Science Edition, 2020
[11] He Qianhua, Kong Xiangbin, Gong Hui, Kang Guozheng, Zhu Zhiwu. Measures for effective online teaching during epidemic prevention and control, Journal of Southwest Jiaotong University, Social Science Edition, 2020
[12] Guo Jianwei, Gong Hui, Kai Qianhua. Practice and thinking of MOOCS in mechanics of materials, Journal of Southwest Jiaotong University, Social Science Edition, 2020
[13] Miao Hongchen, Kai Qianhua. Design and practice of practical writing course for students majoring in engineering mechanics, Journal of Southwest Jiaotong University, Social Science Edition, 2020
[1] 2013.06, Research on wheel-rail contact in high-speed railway operation, 2013 excellent graduation project (thesis), Li Zhenxin.
[2] 2017.10, Investigation on the anisotropic transformation surfaces of super-elastic NiTi alloys under multi-axial cyclic loadings, Outstanding Academic Paper Award of the First Southern Conference on Computational Mechanics, Huber.
[3] 2017.05, Intelligent polymer material thermo-mechanical coupling deformation temperature control system, third prize of the 15th "Yanghua Cup" college students extracurricular academic science and technology work competition of Southwest Jiaotong University, Li Jian.
[4] 2017.12, the second prize of the 4th "Huawei Cup" China Graduate Mathematical Contest in Modeling, Zhao Jizhong.
[5] 2019.05, Experimental research on SMP shape memory behavior under complex loading conditions, excellent conclusion, Cao Pu, Zheng Sizheng, Tang Ruyi, Zhang Xuelian, Chang Wangsheng.
[6] 2018.06, Excellent Graduation Design (Thesis), Class of 2018, Wang Ziyi.
[7] 2019.05, Experimental research on SMP shape memory behavior under complex loading conditions, excellent conclusion, Cao Pu, Zheng Sizheng, Tang Ruyi, Zhang Xuelian, Chang Wangsheng.
[8] 2019.11, the third national prize of the second "Shangdian Cup" National Science and Technology Translation Competition in 2019, Zhao Jizhong.
[9] 2019.11, An elastoplastic contact solving method of two spheres, Outstanding Academic Paper Award of the 12th Southern Conference on Computational Mechanics, Zhao Jizhong.
[10] 2020.07, elastoplastic contact analysis and application of functionally graded structures, excellent undergraduate graduation design (thesis) in mechanics of national colleges and universities, excellent thesis B, Wang Shuna.
1. Longitudinal project
[1] Project of Sichuan Science and Technology Department, 2020.1-2022.12, research on Evaluation Technology of high temperature creep mechanical properties of key structural materials
[2] National Natural Science Foundation of China High Speed Railway Joint Fund (u1734207), 2018.01-2021.12, research on wheel rail contact behavior, performance evolution and damage mechanism of high-speed railway turnout, main research
[3] National key R & D plan (2017yfb0304500), July 2017-2021.7, research and application of key technology of high wear resistance, high strength and toughness rail for heavy haul railway, main research.
[4] Sichuan Outstanding Youth Fund (2017jq0019), 2017.1-2019.12, wheel rail contact thermal damage research, presided over
[5] Sichuan International Science and technology cooperation project (2017hh0038), 2017.1-2019.12, wheel rolling contact fatigue research of high-speed train, main research
[6] Research project supported by State Key Laboratory of traction power (2017tpl)_ T04), 2017.1-2019.12, research on heat damage mechanism of wheel rail contact of high-speed train, presided over
[7] National key R & D plan (2016yfb1102601), June 2016-june 2020, industrial demonstration and application of laser enhancement technology in aerospace and rail transit
[8] National Natural Science Youth Foundation of China (11602203), January 2017-december 2019, experimental and constitutive model study on thermo magnetic coupled cyclic deformation behavior of ferromagnetic shape memory alloy, main research
[9] National Natural Science Foundation emergency project (11642003), may 2016 to June 2016, the third National Youth Symposium on computational mechanics
[10] National Natural Science Foundation of China (11572265), 2016.1-2019.12, thermo mechanical coupled cyclic deformation behavior and constitutive description of thermally induced shape memory polymer under finite deformation
[11] School level youth program (2682015qm01), July 2015-july 2018, complex thermodynamic behavior and industrial application of advanced materials, main research
[12] Special topic for cultivation of key projects of special fund for basic scientific research business expenses of Central Universities (a0920502051516-11), 2015.1-2016.12 rolling contact fatigue research of heavy haul wheel / rail, presided over
[13] Open fund of National Laboratory of mechanical structure strength and vibration of Xi'an Jiaotong University (sv2014-kf-11), research on thermo mechanical coupled cycle constitutive model under finite deformation from January 2014 to December 2015, presided over
[14] National Natural Science Foundation of China (11212014), 2012.1-2012.12, based on the first principles of fluorographene nanobelts, participated in the research
[15] National Natural Science Foundation of China (11272269), 2012.1-2016.12, study on wet thermal mechanical coupled cyclic constitutive relationship of thermoplastic polymer materials, participation research
[16] Sichuan Provincial Science and Technology Department Project (2013td0004), 2013.1-2015.12, structural safety and service mechanics foundation, Sichuan young science and technology innovation research team, participated in the research
[17] Ministry of education doctoral program new teacher Foundation (2012018420012), 2013.1-2015.12, research on non proportional multiaxial stress fatigue failure model of NiTi shape memory alloy, presided over
[18] National Natural Science Foundation of China (11202171), 2013.1-2015.12, research on constitutive model of shape memory cycle considering internal thermal effect
[19] Swjtu12cx044, special fund for basic scientific research business expenses of central universities, 2012.1-2014.12, research on constitutive model of thermal mechanical coupling cycle under large deformation, presided over
[20] National Natural Science Foundation of China (11172249), 2012.1-2015.12, scratch failure mechanism of polymer materials based on viscoelastic-plastic constitutive model under multiaxial loading, main
[21] National Natural Science Foundation of China (11002119), 2011.1-2013.12, study on cyclic deformation behavior and constitutive model of aluminum foam
[22] National Outstanding Youth Fund (11025210), 2011.1-2014.12, constitutive relationship of advanced materials, main research
[23] Central University special fund Southwest Jiaotong University hundred talents program (a0920502051001-171) 2009-2012 low cycle fatigue experimental research and failure model research of super elastic NiTi alloy, presided over
[24] National Natural Science Foundation of China (10772153), 2009.1-2012.12, research on non proportional multi axial ratcheting constitutive model based on micro mechanism, main research
[25] National Natural Science Foundation of China (10402037), 2008.1-2011.12, research on non proportional multiaxial stress fatigue failure model considering ratcheting effect
[26] new century talent support program (ncet05-0796), 2005-2008 constitutive description of thermal mechanical ratcheting behavior of shape memory alloy, main research
[27] National Natural Science Foundation of China (50305029), 2005.1-2008.12, research on micro wear mechanism of NiTi alloy under stress-induced transformation, main research
1.Wheel Rail Rolling Contact Research Group
The research team was established in September 2017. Mainly carry out the research of wheel-rail rolling contact problems, including the cyclic deformation behavior of wheel-rail materials, wheel-rail rolling contact life prediction, wheel-rail rolling contact wear and wheel-rail life extension. Existing doctoral students (3): Xu Xiang, Zhao Jizhong, Fu Peilin; Master students (6): Feng Dagang, Shi Pishun, Jiang Liyi, Wang Mengfan, Wang Shuna, Chen Jia.
2.Smart Materials Research Group
The research team was established in September 2017. Mainly carry out research on cyclic deformation behavior and constitutive models of smart materials such as shape memory alloys and shape memory polymers. Existing doctoral students (5 people): Qiu Bo, Li Jian, Ding Li, Wang Ziyi, Liang Zhihong; master students (4 people): Zhang Chen, Zhao Jiaxiang, Zhang Xuelian, Tang Yanjie.
3.Material constitutive relationship and fatigue fracture research team (teacher)
The team is led by Professor Kang Guozheng, Dean of the School of Mechanics, and has won 3 provincial and ministerial-level natural science and scientific and technological progress second prizes, and 2 national teaching achievement second prizes. The team is mainly engaged in basic theoretical research on the constitutive relationship of advanced materials, fatigue and fracture mechanics, composite material mesomechanics, smart materials and structural mechanics, and the evaluation of the service safety and remaining life of engineering structures. Funds for scientific research are sufficient. In recent years, it has undertaken key projects from the National Natural Science Foundation of China, the National Science Fund for Distinguished Young Scholars, the General and Youth Project of the National Natural Science Foundation of China, key research and development sub-projects and sub-tasks, and projects supported by the Sichuan Science and Technology Innovation Team. There are many provincial and ministerial projects and various horizontal service projects. The current team members include 4 professors (Kang Guozheng, Kan Qianhua, Wu Shengchuan, Zhang Xu), 6 associate professors (Zhang Juan, Liu Yujie, Yu Chao, Yuan Jianghong; Miao Hongchen, Li Yingxu) and 1 postdoctoral fellow (Qiang Bin). Approximately 66 students (22 PhD students; 42 master students).
1. Invention Patent
[1] Lu Fucong, Kang Guozheng, Liu Yujie, Kan Qianhua, Xu Xiang, Chen Kaijuan, Zhao Tianxing. A high-temperature multiaxial cyclic test device for a polymer material chamber. Invention Patent (ZL 2015 11031128.5), 2018.01.05.
[2] Kan Qianhua, Xu Xiang, Kang Guozheng, Lu Fucong, Fang Tao. A nanoindentation test method for the elastic modulus of austenite and martensite phase of shape memory alloy, invention patent (ZL 201510856957.0), 2018.03.16.
[3] Xu Xiang, Kan Qianhua, Kang Guozheng, Lu Fucong, Liu Yujie, a shape memory alloy thermomechanical fatigue test device, invention patent (ZL 2015 0622291.2), 2017.10.24.
2. Utility model patents
[1] Cao Yu, Kan Qianhua, Li Jian, Yao Chengbin, Li Yong, Leng Guowu. MTS-acumen exclusive modular temperature control system in liquid environment, utility model patent (ZL201921785704.9), 2020.5.12.
[2] Zheng Sizheng, Kan Qianhua, Li Jian, Cao Puyu, Zhang Xuelian, Chang Wangsheng, Tang Ruyi. A temperature-sensitive self-assembly device based on shape memory polyurethane, utility model patent (ZL201920624840.3), 2020.5.12.
[3] Chang Wangsheng, Kan Qianhua, Li Jian, Zhang Xuelian, Zheng Sizheng, Cao Puyu, Tang Ruyi. An exclusive modular temperature control box for MTS-Acumen, utility model patent (ZL201920624366.4), 2020.9.24.
[4] Cao Puyu, Kan Qianhua, Li Jian, Tang Ruyi, Zheng Sizheng, Zhang Xuelian, Chang Wangsheng. A temperature sensing manipulator based on shape memory polyurethane material, utility model patent (ZL201920622475.2), 2019.12.31.
[5] Li Jian, Kan Qianhua, Zhang Zebin, Zhao Tianxing, Kang Guozheng. A set of shape memory polymer thermal-mechanical coupling deformation experiment device, utility model patent (ZL 201820307827.0), 2018.10.19.
[6] Zhao Tianxing, Kang Guozheng, Kan Qianhua, Liu Yujie, Lu Fucong, Xu Xiang. A shape memory alloy thermal-mechanical coupling multi-axis cyclic deformation experimental device, utility model patent (ZL 201621413545.6), 2017.07.07.
[7] Zhou Xuhui, Kan Qianhua, Han Yapeng, Qian Honghua, Cao Ye, Zhang Yixing, Li Jian. A fire alarm and fire extinguishing device based on shape memory polymer materials, utility model patent (ZL 201720317629.8), 2017.03.29.
[8] Lu Fucong, Kang Guozheng, Liu Yujie, Kan Qianhua, Xu Xiang, Chen Kaijuan, Zhao Tianxing. A high-temperature multiaxial cyclic test device for a polymer material chamber. Utility model patent (ZL 2015 2 1139815.4), 2015.8.31.
[9] Qiu Bo, Kan Qianhua, Lu Fucong, Zhao Tianxing, Kang Guozheng. A shape memory alloy material fatigue test vessel that can provide different liquid medium environments. Utility model patent (ZL 2016 2 0844930.X), 2017, 4.12.
3. Software copyright
[1] Cai Jiangcheng, Miao Hongchen, Kan Qianhua, Kang Guozheng. The software for calculating the dispersion curve of guided waves in waveguides with arbitrary cross-sections based on the MATLAB platform (2020SR0006818), 2019.10.22.
[2] Pang Xing, Kan Qianhua, Ding Li, Wu Shengchuan. The finite element analysis software of wheel-rail double-rolling based on ABAQUS platform. Computer software copyright (2019SR1371594), 2019.09.22.
[3] Pang Xing, Zhao Jizhong, Kan Qianhua. The finite element analysis software for the rolling contact of rail welded joints based on the ABAQUS platform. Computer software copyright (2018SR0472143), 2019.03.22.
[4] Zhao Jizhong, Yang Gang, Pang Xing, Kan Qianhua. The finite element analysis software for the rolling contact of laser-hardened and strengthened rails based on the ABAQUS platform. Computer software copyright (2018SR953889), 2018.09.29.
[5] Wang Wenqi, Teng Hao, Ding Li, Kan Qianhua. A finite element analysis plug-in system for laser shock-strengthened plastic deformation of the rail surface based on the ABAQUS platform. Computer software copyright (2018SR533092), 2018.04.17.
[6] Ding Li, Kan Qianhua, Kang Guozheng, Xu Xiang. Three-dimensional wheel-rail rolling contact finite element analysis software based on ABAQUS platform. Computer software copyright (2018SR828527), 2018.07.05.
[7] Kan Qianhua, Mei Zuozhou, Ding Li, Jiang Qinxian. Super-elastic NiTi alloy dynamic crack growth finite element analysis software V1.0 based on ABAQUS platform, computer software copyright (2018SR294079), 2018.02.08.
[8] Dong Cheng, Zhou Yongan, Liu Wenjie, Kan Qianhua, Zheng Zuen, Yue Zhiping. Finite element analysis software V1.0 for deformation of reinforced subgrade structure based on ABAQUS platform, computer software copyright (2017SR064240), 2016.12.01.
[9] Ding Li, Kan Qianhua, Kang Guozheng, Wei Jianlan. Finite element analysis software 1.0 for 3D wheel rail profile optimization based on ABAQUS, computer software copyright (2017SR212839), 2017.2.12.
[1] Qian Hua, Zhang Xu. Experiment, simulation and theory of mechanics of materials, Science Press, February 2018, ISBN:9787030565114.
[2] Kang Guozheng, Kai Qianhua, Zhang Juan. Principle, structure and application of large-scale finite element program (Third Edition). Southwest Jiaotong University Press, 2017
[3] Kang Guozheng, Jiang Han and Qian Hua. Fundamentals of continuum mechanics and its applications. Science Press, June 2015, ISBN: 978-7-03-042873-8
[4] Kang Guozheng, Kai Qianhua, Zhang Juan. Principle, structure and application of large-scale finite element program (Second Edition). Southwest Jiaotong University Press, 2008
[5] He was born in China. MSC.MARC Engineering application case analysis and secondary development. China water resources and Hydropower Press, 2006
[6] He Qianhua, Kang Guozheng, Tan Changjian, Zhang Juan, Dong Cheng. ANSYS advanced engineering application case analysis and secondary development. Electronic Industry Press, 2006
Refer to school and college regulations.
1. Peilin Fu, Jianghong Yuan, Xu Zhang, Guozheng Kang, Ping Wang, Qianhua Kan*. Forced vibration analysis of blade after selective laser shock processing based on Timoshenko's beam theory. Composite Structures, 2020, 243:112249. IF=5.138
Considering the elastic modulus gradient and residual compressive stress distribution of the blade after laser shock selective area strengthening, the variable cross-section blade strengthened by laser shock selective area is simplified into a prestressed functionally graded stepped beam with axial load. Based on the Timoshenko beam theory, the prestress is converted into additional lateral excitation load, and the deformation continuity between the beam segments is used to obtain the forced vibration solution of the blade under simple harmonic excitation. The different strengthening areas, strengthening layer depths and The influence of single/double impact methods on blade deflection response can provide a certain guiding significance for the further optimization of laser impact strengthening process parameters.
2.Zhao J, Kan Q*, Fu P, Guozheng Kang, Ping Wang. An elasto-plastic contact solving method for two spheres[J]. Acta Mechanica Solida Sinica, 2020(3). IF=2.008
Based on the Hertz elastic contact theory, an elastoplastic contact solution method for two-ball contact is proposed. This model can better predict the contact pressure distribution under different material parameters, contact body radius and normal outward load and other contact conditions, and the relative error of its maximum contact stress and contact piece radius are both within ±5%; , The prediction accuracy and applicability of this method are far superior to the current popular elastoplastic contact solving method. This method overcomes the limitations of the material model and contact material in the existing methods, can effectively predict the contact stress distribution and the size of the contact piece, does not require iterative solution, and is convenient for solving engineering elastoplastic problems.
3. Wang, Z., Xu, X., Ding, L., Kang, G., Wang, P., & Kan, Q*. (2020). A new damage-coupled cyclic plastic model for whole-life ratchetting of heat-treated U75V steel. International Journal of Damage Mechanics. IF=3.125
In order to describe the full-life uniaxial ratcheting behavior of U75V heavy-duty rail steel under different stress loading levels, a new coupled damage cyclic plastic constitutive model was developed under the framework of continuous damage mechanics. By introducing a correction term into the classic damage evolution dimension, the lag of damage evolution rate of U75V steel in the initial cycle is described reasonably. Based on the rules summarized by the experiment, a mixed fatigue failure criterion that considers both fatigue damage and ratchet strain-induced damage is developed. The validity of the model is verified by comparing the stress-strain hysteresis loop, ratchet strain, damage evolution and fatigue life obtained from the experiment and model prediction.
4. Li J, Kan Q, Chen, et al. In situ observation on rate-dependent strain localization of thermo-induced shape memory polyurethane[J]. Polymers, 2019, 11(6):982. SCI, IF=3.426.
Through non-contact digital image correlation technology and infrared temperature measurement technology, under the conditions of natural convection and forced convection, the uniaxial stretching process of thermally induced shape memory polyurethane under different loading rates was observed in situ, and the strain localization mode was observed. With the increase of the loading rate, the transformation process from strain localized tensile mode to strain localized expansion mode, and then to local large deformation mode, clarified the coupling effect between deformation heat generation and strain localization during the deformation process, revealing The internal relationship between the competition mechanism between rate hardening and thermal softening and the transformation of strain localization mode.
4.Bo Qiu, Qianhua Kan, Guozheng Kang, Chao Yu, Xi Xie. Rate-dependent transformation ratcheting-fatigue interaction of super-elastic NiTi alloy under uniaxial and shear loadings: Experimental observation. International Journal of Fatigue, 2019, 127: 470 -478. SCI, IF=3.673.
In this paper, the rate-dependent full-life phase change ratchet and fatigue life of superelastic NiTi shape memory alloy under uniaxial tension and pure torsion paths are experimentally studied. The results show that under the same equivalent peak stress level, the uniaxial The phase change ratchet of the stretch path is much higher than the pure twist path, and the fatigue life is much lower than the pure twist path. With the increase of the loading rate, the phase change ratchet under the uniaxial stretching path increases, and the phase change ratchet under the pure torsion path decreases. The influence of loading rate and loading path on fatigue life is discussed, and it is found that the initial strain energy is related to the fatigue life.
5.Bo Qiu, Qianhua Kan, Chao Yu, Guozheng Kang, Wenyi Yan. A thermo-mechanically coupled constitutive model for describing rate-dependent super-elastic degeneration of NiTi shape memory alloys. Mechanics research communications, 2019, 99: 32-41 . SCI, IF=2.229.
In this paper, a 3D thermal-mechanical coupled cyclic constitutive model of superelastic NiTi shape memory alloy is established. Under the framework of thermodynamics, the anisotropic phase transition surface based on J2-J3 is introduced to carry out the anisotropic phase transition behavior of the alloy. description. And consider the evolution equation of internal stress and residual strain and the evolution equation of phase transition critical temperature, so as to reflect the superelastic degradation behavior under different loading rates.
1. State Key Laboratory of Traction Power
The State Key Laboratory of Traction Power is a state key open research laboratory (code 1991DA105597) approved by the State Planning Commission (Jiji Technology [1989] No. 32). It is in charge of the Ministry of Education and its supporting unit is Southwest Jiaotong University. The laboratory began preparations for construction in 1989 and was initially completed in 1993. It began to accept national tests and research tasks in 1994, passed national acceptance in 1995, passed national evaluations three times in 2003, 2008 and 2013, and was rated as an excellent national key experiment twice room.
The task of the laboratory is to strengthen scientific and technological research to meet the needs of China's rail transit modernization, carry out basic science and its applied science research, explore new scientific and technological fields, cultivate outstanding scientific and technological talents, and gradually develop into a representative national academic, experimental and Management level laboratory base and academic activity center.
2. Sichuan Provincial Key Laboratory of Applied Mechanics and Structural Safety
The Sichuan Provincial Key Laboratory of Applied Mechanics and Structural Safety of Southwest Jiaotong University was established in 2014 with the approval of the Sichuan Provincial Department of Science and Technology. Relying on the first-level discipline of school mechanics and the provincial key construction first-level discipline, the laboratory aims at the application of mechanics and key technical issues in the construction of important national and regional projects, combined with the school’s rail transit industry and engineering services, and established fatigue and fracture mechanics and structural safety The three characteristic research directions of evaluation, structural vibration and dynamic strength analysis, computational mechanics and engineering structure simulation are important research and technology research and development platforms for mechanics applications in our province and our school.
The laboratory has 41 permanent staff, including 23 full professors, including 1 winner of the National Outstanding Youth Fund, 1 Changjiang Scholars Distinguished Professor, 2 Distinguished Professors of the Central Organization Department, 5 academic and technical leaders in Sichuan Province, and education There are 3 outstanding talents of the Ministry of New Century, 5 reserve candidates for academic and scientific and technological leaders in Sichuan Province, 8 special experts of Sichuan Thousand Talents Plan, and 7 winners of Sichuan Youth Fund. One Sichuan Youth Science and Technology Innovation Research Team. A high-level echelon with an active academic atmosphere and strong research and innovation has been formed, and a top-notch and high-level talent training base for frontier research and application of mechanics has been formed.
The laboratory focuses on the research of basic theory of mechanics and the application and development of engineering structural safety technology, highlighting the frontiers, scientific issues and needs of the subject field, and focuses on the thermal-mechanical coupling behavior of materials, non-smooth system dynamics and control, materials and component nano A series of important theoretical innovations and scientific application results have been achieved in testing, nonlinear fluid-structure coupling and other aspects. Won 2 national key projects, 1 national standard released, 1 second prize of Natural Science of the Ministry of Education, and 1 second prize of Sichuan Science and Technology Progress Award.
Since its establishment 5 years ago, the laboratory has undertaken more than 60 national, provincial and ministerial-level vertical scientific research projects, undertook more than 220 industry and local horizontal research and important technical service projects, published more than 260 SCI papers, and authorized more than 70 national invention patents , More than 30 utility model patents. More than 280 postgraduates, 90 doctoral students and 10 post-doctoral students have been trained.
The laboratory has a series of advanced instruments and equipment such as MTS material testing machine, laser vibration measurement system, vibrating table, low-speed wind tunnel, atomic force microscope, high-speed visual test system, and the equipment assets are more than 60 million yuan. Based on the construction results and scientific research results achieved, the laboratory will feature multidisciplinary and multi-industry cross-collaborative research and services, and will face structural safety issues in the fields of transportation vehicles, rail transit, energy engineering, and major equipment manufacturing. Continue to undertake more important scientific research tasks, invest more in engineering services, cultivate more outstanding talents, and make contributions to national and local construction and development.
3. National Mechanics Teaching Demonstration Center
The Mechanics Laboratory is one of the earliest laboratories built by Southwest Jiaotong University. Through the inheritance of several generations of teachers, you have accumulated a wealth of basic mechanics teaching reform achievements and resources, developed many experimental projects, and developed many new experimental equipment. Excellent results have been achieved.
In 2016, it became one of the first batch of national mechanics experimental teaching demonstration centers. 22 laboratories have been built with a total area of 3,500 square meters. The laboratory is large in scale, new equipment, sufficient in quantity, self-made equipment into a system, spacious and bright, and the environment is humane. The teaching service is student-centered and the operation is safe and standardized.
2020 year
[1] Li Jian, Kan Qianhua. In-situ experimental observation of thermal-mechanical coupling behavior of thermally induced shape memory polyurethane, The 13th National MTS Material Testing Conference, Chengdu, 2020.10.30-11.1.
[2] Liu Jialu, Kan Qianhua. Finite Element Analysis of Rail Crack Propagation Induced by High-speed Railway Strains, Sichuan Mechanical Society 2020 Academic Exchange Meeting and the Second Council Meeting of the Ninth Council, Chengdu, 2020.11.
[3] Wang Mengfan, Kan Qianhua. Finite element analysis of factors affecting rail crack propagation based on XFEM, Sichuan Mechanical Society 2020 Academic Exchange Meeting and the Second Council Meeting of the Ninth Council, Chengdu, 2020.11.
[4] Wang Shuna, Kan Qianhua. The effect of gradient coating on the wear and fatigue of two-dimensional structures, Sichuan Mechanical Society 2020 Academic Exchange Meeting and the Second Council Meeting of the Ninth Council, Chengdu, 2020.11.
[5] Tang Yanjie, Kan Qianhua. Cyclic plastic deformation behavior experiment and constitutive model of Inconel690 superalloy, Sichuan Mechanical Society 2020 Academic Exchange Meeting and the Second Council Meeting of the Ninth Council, Chengdu, 2020.11.
[6] Feng Dagang, Kan Qianhua. The 2020 Academic Exchange Meeting of the Sichuan Society of Mechanics and the Second Council Meeting of the Ninth Council, Chengdu, 2020, 11.
[7] Hang Su, Justin Sulistio, Chung Lun Pun, Peter Mutton, Qianhua Kan, Guozheng Kang, Wenyi Yan. Numerical study on the ratcheting performance of heavy haul rails in curved tracks for worn wheel/rail profiles, ICEFA2020, Shanghai, 7.12 -15.
[8] Xiang Xu, Li Ding, Wenyi Yan, Ping Wang, Guozheng Kang, Qianhua Kan. Wheel-rail plastic matching analysis of heavy haul railway by considering ratcheting behavior, ICEFA2020, Shanghai, 2020, 7.12-15.
[9] Qianhua Kan, Jian Li, Zhihong Liang, Xu Zhang, Guozheng Kang. A logarithmic rate based hyperelastic-viscoplastic model for thermo-induced shape memory polyurethane, ICPDF2020, Rivera Maya, Mexico, 2020, 1.3-9.
[10] Jizhong Zhao, Qianhua Kan, Xiang Xu, Guozheng Kang, Wenyi Yan. SIF2020, Melbourne, 2020, 12.6-8.
2019 year
[11] Kan Qianhua, Shen Huoming. Basic mechanics teaching reform under the background of new engineering construction, China Mechanics Conference, Hangzhou, 2019.8.24-27.
[12] Kan Qianhua, Kang Guozheng, Yu Chao, Song Di. Research on Thermal-mechanical Coupling Phase Transformation and Fatigue of Shape Memory Alloys, China Mechanics Conference, Hangzhou, 2019.8.24-27.
[13] Kan Qianhua, Zhang Xu, Zhao Jianfeng, Fu Peilin. The mechanism and application of laser shock structure strengthening, China Mechanics Conference, Hangzhou, 2019.8.24-27.
[14] Luo Huiliang, Kang Guozheng, Kan Qianhua, Ma Chuanping. Research on Ratchet-Fatigue Interaction and Fatigue Life Prediction Model of SUS301L Stainless Steel Welded Joints, China Mechanics Congress, Hangzhou, 2019.8.24-27.
[15] Liang Zhihong, Li Jian, Kan Qianhua, Kang Guozheng. Thermo-induced shape memory polyurethane viscoelastic-viscoplastic constitutive model and its finite element realization, China Mechanics Congress, Hangzhou, 2019.8.24-27.
[16] Li Jian, Kan Qianhua, Liang Zhihong, Kang Guozheng. A viscoelastic-viscoplastic constitutive model for glassy polymers based on phase transition theory, China Mechanics Congress, Hangzhou, 2019.8.24-27.
[17] Qiu Bo, Kan Qianhua, Yu Chao, Kang Guozheng. Research on three-dimensional thermo-mechanical coupled cyclic constitutive model of superelastic NiTi alloy, Chinese Mechanics Congress, Hangzhou, 2019.8.24-27.
[18] Song Di, Kang Guozheng, Kan Qianhua, Yu Chao. Fatigue life prediction model of NiTi shape memory alloy under non-proportional multiaxial loading, Chinese Mechanics Congress, Hangzhou, 2019.8.24-27.
[19] Wang Bing, Kang Guozheng, Kan Qianhua, Wu Wenping, Zhou Kun, Yu Chao. Atomistic study on the super-elasticity of nanocrystalline NiTi shape memory alloy subjected to cyclic deformation, China Mechanics Congress, Hangzhou, 2019.8.24-27.
[20] Xu Bo, Kang Guozheng, Kan Qianhua, Xie Xi, Yu Chao, Peng Qi. Phase field simulation to one-way shape memory alloy effect of NiTi shape memory alloy single crystal, China Mechanics Conference, Hangzhou, 2019.8.24-27.
[21] Zhou Ting, Yu Chao, Kang Guozheng, Kan Qianhua. The effect of superelastic NiTi alloy training on subsequent cyclic deformation, Chinese Mechanics Congress, Hangzhou, 2019.8.24-27.
[22] Song Di, Kang Guozheng, Kan Qianhua, Yu Chao. Fatigue life prediction model of NiTi shape memory alloy under non-proportional multiaxial loading, Chinese Mechanics Congress, Hangzhou, 2019.8.24-27.
[23] Kan Qianhua, Kang Guozheng, Yu Chao, Song Di, Xie Xi, Qiu Bo. Research on Thermal-mechanical Coupling Phase Transformation and Fatigue of Shape Memory Alloys, China Materials Conference, Chengdu, 2019.7.10-14.
[24] Bo Qiu, Qianhua Kan, Chao Yu, Guozheng Kang, Wenyi Yan. Experimental observation on multiaxial thermo-mechanical coupling cyclic transformation of super-elastic alloy, SMN2019, Haerbin, China, 2019, 09.20-24.
[25] Jiaxiang Zhao, Qianhua Kan, Bo Qiu, Guozheng Kang. Temperature-dependent transformation ratcheting of superelastic NiTi alloy: experiments and simulations, SMN2019, Haerbin, China, 2019, 09.20-24.
[26] Qianhua Kan, Guozheng Kang, Han Jiang, Gang Yang, Jizhong Zhao. Temperature-dependent cyclic plastic deformation of high-speed rail steel U75VG: Experiments and simulations,10th Japan-China Bilateral Symposium on High Temperature Strength of Materials, Kagoshima , Japan, 2019, 10.25-29.
[27] Jun Tian, Jian Li, Liping Zhang, Qianhua Kan. Uniaxial and multiaixal ratcheting behaviors of Inconel 690 at elevated temperature: experiments and simulations, 10th Japan-China Bilateral Symposium on High Temperature Strength of Materials, Kagoshima, Japan, 2019, 10.25-29.
[28] Jian Li, Qianhua Kan, Zhihong Liang, Guozheng Kang. A phenomenological cyclic constitutive model for glassy shape memory polymers. ICM13, Melbourne, Australia, 2019.6.10-15.
[29] Ziyi Wang, Qianhua Kan, Guozheng Kang, Xiang Xu. Damage-coupled cyclic plastic model for U75V rail steel.ICM13, Melbourne, Australia, 2019.6.10-15.
2018
[30] Bo Qiu, Qianhua Kan, Guozheng Kang, Tianxing Zhao, Chao Yu. Experimental investigation on multiaxial rate-dependent whole-life transformation ratchetting and fatigue failure of super-elastic NiTi alloy, AEPA2018, Jeju, Republic of Korea, 2018.12. 2-7.
[31] Xiang Xu, Yilin Fan, Guozheng Kang, Qianhua Kan. A new prediction method of wheel-rail rolling contact fatigue by considering ratchetting-fatigue interaction, AEPA2018, Jeju, Republic of Korea, 2018.12.2-7.
[32] Ting Zhou, Chao Yu, Qianhua Kan, Guozheng Kang.A micro-plane constitutive model for super-elastic shape memory alloys under non-proportional loadings, AEPA2018, Jeju, Republic of Korea, 2018.12.2-7.
[33] Tianxing Zhao, Jian Li, Xiang Xu, Qianhua Kan, Guozheng Kang. Experimental observation on thermo-mechanical fatigue of NiTi shape memory alloy. FFTE2018, Haikou, 2018.1.12-15.
[34] Xiang Xu, Yilin Fan, Hua Guo, Yuan Wang, Guozheng Kang, Qianhua Kan. Ratcheting-fatigue interaction of U75V heavy haul rail steel: experimental observation and fatigue life prediction model. FFTE2018, Haikou, 2018.1.12-15.
[35] Jingye Yang, Kaijuan Chen, Qianhua Kan, Guozheng Kang. Experimental investigation on ratcheting-fatigue interaction of polyamide-6 at room temperature. FFTE2018, Haikou, 2018.1.12-15.
[36] Xi Xie, Qianhua Kan, Guozheng Kang. The transformation domains of super-elastic NiTi shape memory alloy during cyclic loading. ICPDF2018, USA Sujuan, 2018.1.2-9.
[37] Qianhua Kan, Han Jiang, Xiang Xu, Chao Yu, Wenyi Yan, Guozheng Kang. Experimental observation on thermo-mechanical cyclic deformation of NiTi shape memory alloy. ICPDF2018, Sujuan,USA, 2018.1.2-9.
[38] Jian Li, Zebin Zhang, Qianhua Kan, Guozheng Kang. A Finite Deformation Model of Thermo-induced Shape Memory Polyurethane Based on the Objective Logarithmic Rate.USNC-TAM2018, Chicago, USA, 2018.6.4-10.
[39] Yang Gang, Li Zonghao, Zhang Zixin, Kang Guozheng, Kan Qianhua. Experimental study on temperature-dependent cyclic plastic deformation of U75VG high-speed rail steel. The 13th National Conference on High Temperature Materials and Strength, Chengdu, 2018.5.16-20.
2017
[40] Xiang Xu, Qian-hua Kan, M Han Jiang, Guo-zheng Kang. A multi-mechanism model describing reorientation, detwinned and plasticity of one-way NiTi shape memory alloy. The 11th Southern Conference on Computational Mechanics, 2017, Zhengzhou.
[41] Bo Qiua, Qianhua Kana, Tianxing Zhao, Xi Xie, Guozheng Kang. Investigation on anisotropic cyclic transformation of super-elastic NiTi alloy under multi-axial cyclic loadings. The 11th Southern Conference on Computational Mechanics, 2017, Zhengzhou.
[42] Jian Li, Qian-hua Kan, Ze-bin Zhang, Guo-zheng Kang, Wen-yi Yan. Thermo-mechanically coupled thermo-elasto-visco-plastic modeling of thermo-induced shape memory polyurethane at finite deformation. The 11th Southern Conference on Computational Mechanics, 2017, Zhengzhou.
[43] Qianhua Kan, Jian Li, Ziyuan Zhou. Modeling of natural frequencies of rat whisker with the consideration of structural characterization. The 11th Southern Conference on Computational Mechanics, 2017, Zhengzhou.
[44] Tao FANG, Qianhua KAN, Yilin FAN, Hua GUO, Yuan WANG, Guozheng KANG and Wenyi YAN. Strain amplitude dependent cyclic plastic model for U75VG rail steel. First International Conference on Rail Transportation, Chengdu, 2017.7.10-12.
[45] Jun Tian, Yu Yang, Liping Zhang, Tao Fang, Jian Li, Qianhua Kan. Uniaxial ratcheting and fatigue failure of SA508-3 at elevated temperature: Experiments and simulations, IJP2018, Mexico, 2017.1.2-9.
[46] Jun Tian, Yu Yang, Qianhua Kan. Uniaxial Ratcheting and Fatigue Failure of SA508-3 at Elevated Temperature. Transactions of the American Nuclear Society, 116, San Francisco, California, June 11-15, 2017.
[47] Zhao Jizhong, Kan Qianhua, Kang Guozheng, Xu Xiang. Finite element simulation of high-speed train wheel rolling strengthening process. 2017 National Plastic Mechanics Conference, 2017, Changsha.
[48] Qiu Bo, Kan Qianhua, Yu Chao, Kang Guozheng. Macroscopic thermo-mechanical coupled cyclic constitutive model of superelastic NiTi alloy. 2017 National Plastic Mechanics Conference, 2017, Changsha.
[49] Zhao Jizhong, Kan Qianhua, Kang Guozheng, Xu Xiang. Finite element simulation of high-speed train wheel rolling strengthening process. 2017 National Plastic Mechanics Conference, 2017, Changsha.
[50] Kan Qianhua, Fang Tao, Wang Yuan, Guo Hua, Kang Guozheng. Research on wheel-rail rolling contact fatigue of heavy-duty railway. The 2017 Academic Exchange Meeting of the Health Assessment and Life Prediction Professional Committee of the Sichuan Mechanics Society, 2017, Chengdu.
[51] Xu Xiang, Jiang Han, Kan Qianhua. Research on multi-mechanism phenomenological cyclic constitutive model of shape memory NiTi alloy. The 2017 Academic Exchange Meeting of the Health Assessment and Life Prediction Professional Committee of the Sichuan Mechanics Society, 2017, Chengdu.
[52] Li Jian, Zhang Zebin, Kan Qianhua, Kang Guozheng. Observation of heat generation of shape memory polyurethane at different strain rates. China Mechanics Conference, 2017, Beijing.
[53] Song Di, Kang Guozheng, Kan Qianhua, Yu Chao. Research on the superelastic fatigue performance of NiTi shape memory alloy. China Mechanics Conference, 2017, Beijing.
[54] Zhao Tianxing, Li Jian, Kan Qianhua, Kang Guozheng. Development of a shape memory alloy thermomechanical cycle deformation test device based on LabVIEW platform. China Mechanics Conference, 2017, Beijing.
2016
[55] Di Song, Guozheng Kang, Qianhua Kan, Chao Yu. Observation on the residual martensite phase of NiTi shape memory alloy micro-tubes under unaxial and multiaxial fatigue loadings. IMECE2016, Phoenix, America.
[56] Chao Yu, Qianhua Kan, Kaijuan Chen, Guozheng Kang. Creep deformation of super-elastic NiTi shape memory alloy micro-tubes. International Symposium on Heterogeneous Material Mechanics, 2016, Chongqing.
[57] Tian Jun, Yang Yu, Zhang Liping, Tao Fang, Kan Qianhua. Ratcheting behaviors of SA508-3 steel at elevated temperature: experimental observation and simulation, 9th China-Japan Bilateral Symposium on High Temperature Strength of Materials, 2016, Changsha .
[58] Kan Qiahua, Qiubo, Li Jian, Kang Guozheng, Yan Wenyi. Experimental observation on creep-ratcheting interaction of Ti-6242S alloy at elevated temperature, 9th China-Japan Bilateral Symposium on High Temperature Strength of Materials, 2016, Changsha.
[59] Kan Qianhua, Jiang Han, Kang Guozheng. An Improved Thermal Ratcheting Boundary of Pressure Pipeline, AEPA2016, 2016, Japan.
[60] Du Juan, Shao XueJiao, Kan Qianhua. Calculation strategy for the determination of plasticity correction factors, AEPA2016, 2016, Japan.
[61] Fang Tao, Kan Qianhua, Kang Guozheng, Yan Wenyi,. Uniaxial ratcheting and low-cycle fatigue failure of U75V rail steel, ISSI2016, 2016, Tianjin.
[62] Kan Qianhua, Guo Sujuan, Li Jian, Kang Guozheng, Yan Wenyi. Numerical investigation on plastic strain correction factor in simplified elastic-plastic fatigue analysis, ISSI2016, 2016, Tianjin.
[63] Li Jian, Dong Shiyu, Kan Qianhua, Kang Guozheng, Yan Wenyi. A thermo-mechanical constitutive model of glassy shape memory polymers, ISSI2016, 2016, Tianjin.
[64] Zhang Ruyuan, Zhang Juan, Kang Guozheng, Kan Qianhua. Simulation of crack propagation in particle-reinforced bulk metallic glass composites, ISSI2016, 2016, Tianjin.
[65] Zhang Zebin, Kan Qianhua, Dong Shiyu, Li Jian, Kang Guozheng. Thermally induced shape memory polymer model based on time-temperature equivalent, Journal of Sichuan University of Science and Technology (2016 Sichuan Province Mechanics Conference Conference Paper).
[66] Xu Xiang, Kan Qianhua, Kang Guozheng. Finite element analysis of nickel-titanium shape memory alloy pipe joints, Journal of Sichuan University of Science and Technology (2016 Sichuan Province Mechanics Conference Conference Paper).
Year 2014
[67] Kan Qianhua, Kang Guozheng. Progress in experiments and models of cyclic deformation behavior of NiTi shape memory alloys. The 6th National Solid Mechanics Youth Symposium, 2014, Lanzhou.
[68] Zhu Yilin, Kang Guozheng, Kan Qianhua, Yu Chao. Large deformation viscoelastic-plastic constitutive model describing uniaxial ratcheting behavior of biological soft tissues. 2014 National Solid Mechanics Conference, 2014, Chengdu.
[69] Yu Chao, Kang Guozheng, Kan Qianhua. A ratcheting constitutive model for temperature-dependent phase transformation of NiTi shape memory alloy based on physical mechanism. 2014 National Solid Mechanics Conference, 2014, Chengdu.
[70] Kan Qianhua, Kang Guozheng, Yu Chao, Song Di, Yang Qiangjun. Experiment and simulation of cyclic deformation behavior of NiTi shape memory alloy. 2014 National Solid Mechanics Conference, 2014, Chengdu.
[71] Song Di, Kang Guozheng, Kan Qianhua, Yu Chao. Study on non-proportional multiaxial stress fatigue failure behavior of biomedical NiTi shape memory alloy. 2014 National Solid Mechanics Conference, 2014, Chengdu.
[72] Yang Qiangjun, Kan Qianhua, Kang Guozheng, Yu Chao, Dong Shiyu. Strain rate-dependent superelastic degradation prediction model of NiTi shape memory alloy. 2014 National Solid Mechanics Conference, 2014, Chengdu.
[73] Wenyi Yan, Qianhua Kan, Ramesh R. Natural frequency analysis of rat whiskers. the Asian-Pacific Conference on Fracture and Strength 2014 (APCFS-2014) and the International Conference on Structural Integrity and Failure (SIF-2014), 2014 , Sydney.
[74] Qianhua Kan, Kang Guozheng, Zhang Juan, Zhang Ruyuan. Effect of shape memory alloys on the toughening of bulk metallic glass matrix composites. 1st conference on Computational and experimental methods for composite materials and structures, 2014, Haerbin.
[75] Qianhua Kan,Yang, Qiangjun, Guozheng Kang, Chao Yu. Temperature-dependent dissipation energy of shape memory alloy under cyclic loading. International Conference of Functional Materials, 2014, Singapore.
[76] Kan, Qianhua; Kang, Guozheng; Yang, Qiangjun, Jiang, Han, Yu, Chao. Numerical investigation on strain rate dependent phase transition localization of NiTi strip. International Conference of Functional Materials, 2014, Singapore.
[77] Chung Lun Pun, Qianhua Kan, Peter J Mutton, Guozheng Kang, Wenyi Yan. Stress analysis in rail head for rolling contact fatigue analysis. International conference of Fatigue, 2014, Melbourne.
[78] Pun Chunglun, Kan Qianhua, Mutton J. Peter, Kang Guozheng, Yan Wenyi. Multi-axial ratchetting of high strength rail steel: Experimental results and numerical modelling, International conference of Fatigue, 2014, Melbourne.
year 2013
[79] Zhiwu Zhu, Haidong Zhang, Han Jiang, Qianhua Kan. Impact dynamic mechanics behavior and constitutive model of soil, ICF2013, Beijing.
[80] Qianhua Kan, Guozheng Kang, Wenyi Yan, Yilin Zhu, Han Jiang. A thermo-mechanically coupled cyclic plasticity model at large deformations considering inelastic heat generation. ICF2013, Beijing.
[81] Yilin Zhu, Guozheng Kang, Qianhua Kan, Chao Yu. Cyclic plasticity models at finite deformations describing the Bauschinger effect and ratchetting behaviour. ICF2013, Beijing.
[82] Chung Lun Pun, Qianhua Kan, Peter Mutton, Guozheng Kang, Wenyi Yan. Experimental investigation on ratchetting behaviour of high strength rail steel under the uniaxial and compression-torsion cyclic loadings. ICF2013, Beijing.
[83] Kan Qianhua, Kang Guozheng, Yu Chao, Song Di. Research on the ratcheting behavior of NiTi shape memory alloy rate-dependent phase transformation. 2013 Young Scholars Symposium on Western Experimental Mechanics, Mianyang.
[84] Kan Qianhua, Kang Guozheng, Yu Chao, Song Di. Experimental study on cycle thermodynamic behavior of NiTi shape memory alloy. The 15th Annual Conference of the Association for Science and Technology, Guiyang.
[85] Wang Haojia, Zhang Xu, Kang Guozheng, Kan Qianhua. Research on single tensile and cyclic plastic behavior of polycrystalline materials based on crystal plasticity. 2013 National Plastic Mechanics Conference, Yangzhou.
[86] Kan Qianhua, Yang Qiangjun, Kang Guozheng, Liu Yujie, Zhang Xu. Experimental study on high temperature ratcheting behavior of titanium alloy Ti6242S. 2013 National Plastic Mechanics Conference, Yangzhou.
year 2011
[87] Qianhua Kan, Guozheng Kang, Damage-coupled super-elastic constitutive model for uniaxial ratchetting and fatigue failure of NiTi alloy, Plasticity 2011. The 17th international symposium on plasticity & its current applications: 31-33.
year 2010
[88] QH Kan, GZ Kang, SJ Guo. Finite element implementation of a super-elastic constitutive model for transformation ratchetting of NiTi alloy, ICCM2010, 19-21 Nov, 2010, Zhangjiajie, Hunan, China.
[89] Liu Yujie, Kang Guozheng, Kan Qianhua. SS304 stainless steel fatigue life model considering ratchet-fatigue interaction. 2010 Cross-Strait Material Failure/Fracture Conference, 2010, Xi'an.
Year 2009
[90] Guozheng Kang, Qianhua Kan. Scaling relationship of shape memory alloy. Proc. of SPIE V. 7493 74930K-1.
[91] Kan Qianhua, Kang Guozheng. Study on the constitutive model of the phase transition ratcheting behavior of superelastic NiTi alloy. Abstracts of the 2009 Symposium of the Chinese Society of Mechanics, August 2009, Zhengzhou, China.
Year 2008
[92] Qianhua Kan, Guozheng Kang. Threshold load analysis in spherical indentation of super-elastic niti alloy. CCM2008, yichang, China.
[93] Kan Qianhua, Kang Guozheng. A NiTi alloy three-dimensional hyperelastic constitutive model for the analysis of vascular stents. 2008 National Doctoral Conference-Biomedical Engineering and Human Health Abstract Collection. Shanghai.
[94] Ding Jun, Kang Guozheng, Kan Qianhua, Liu Yujie. Research on constitutive model of time-dependent ratcheting behavior of 6061-T6 aluminum alloy, National Plastic Mechanics Conference, November 2008, Nanning, Guangxi.
[95] Qianhua kan, Guozheng Kang, Linmao Qian, Sujuan Guo. A temperature-dependent three-dimensional super-elastic constitutive model considering plasticity for NiTi Alloy. Proc. Of SPIE, 2009, V.7375, 73755U.
2007
[96] Qianhua Kan, Guozheng Kang, Linmao Qian. Mechanical characterization of shape memory alloy with nanoindentation measurements and finite element analysis, Proceedings of the international conference on mechanical engineering and mechanics, 2007 (2).1177-1181.
[97] Kang, G.Z., Kan, Q.H., Zhang, J., Liu, Y.J. Constitutive models for uniaxial time-dependent ratcheting of SS304 stainless steel, Key Engineering Materials, 2007,340-341, 817-822.
year 2006
[98] Kang, GZ, Kan QH, Zhang J. Constitutive modeling for uniaxial time-dependent ratcheting of SS304 stainless steel, AEPA2006, 2006, Nagoya, Japan.
[99] Qianhua Kan, Guozheng Kang. A Unified Constitutive Model for Time-Dependent Ratchetting of SS304 Stainless Steel and Its Finite Element Implementation. Proceedings of the International Conference on Fracture Mechanics and Applications.
[100] Kan Qianhua, Kang Guozheng, Zhang Juan. A time-dependent constitutive model with superposition of viscoplasticity and creep. Southwest Jiaotong University 110th Anniversary Research Academic Forum, 2006.
[1] The dynamic strain aging effect of materials is simulated by machine learning
[2] Stability analysis of wheel rail rolling contact considering temperature effect
[3] 2019, Dong Yu et al., Key Laboratory of Southwest Jiaotong University, experimental study on mechanical response of shape memory polymer under different environments
[4] 2019, Niu Guohao et al., personalized experiment, simulation of the effect of different laser spot lapping on the surface roughness of engine titanium alloy blade
[5] Mechanical properties and shape memory properties of shape memory polymer dentures in different environments
[6] 2019, Niu Guohao et al., provincial innovation, research on Optimization of laser shock strengthening titanium alloy blade of Aeroengine
[7] In 2018, Dong Yu et al., research and training camp project of MaoYuan University, research on macro and micro mechanical behavior of high strength and toughness gradient nanostructured materials
[8] 2018, Cao Puyu et al., guochuang, experimental study on shape memory behavior of SMP under complex loading mode
[9] Effect of rail surface strengthening layer on plastic deformation evolution of heavy haul railway
[10] 2017, Teng Hao et al., guochuang, influence of rail surface strengthening layer on plastic deformation evolution of heavy haul railway
[11] 2017, Wang Ziyi et al., provincial innovation, high speed railway rail steel welded joint fatigue performance research
[12] 2016, Li Zonghao et al., key laboratory open project of Southwest Jiaotong University, research on ratcheting behavior related to temperature of heavy haul rail
[13] 2016, Zhou Xuhui, et al., personalized experimental project of Southwest Jiaotong University, thermal mechanical coupled cyclic deformation of shape memory polymer
[14] 2016, Ding Li et al., guochuang, finite element analysis of rail type selection for passenger and freight mixed transportation lines
[15] Experimental and numerical simulation of thermal mechanical coupled cycle transformation of NiTi shape memory alloy, 2015, Zhou Ting et al
[16] 2015, Pang Xing et al., SRTP, finite element analysis of ratcheting behavior of heavy haul rail under cyclic loading
[17] 2015, Wang Xiaowen et al., SRTP, finite element analysis of crack tip field of shape memory alloy plate
[18] 2014, Wu Jiajia et al., SRTP, structural mechanism analysis of shape memory alloy toughened concrete
[19] 2014, Tao Ru et al., key laboratory open project of Southwest Jiaotong University, experimental study on anisotropic yield surface of shape memory alloy
[20] 2013, Liu Fengjia et al., Key Laboratory of Southwest Jiaotong University, open project, characterization of thermodynamic cycle transformation of shape memory alloy
[21] 2013, Li Jian et al., graduate innovation practice, structural analysis software technology
[22] 2013, Liu Yue et al., SRTP, optimization design of hyperelastic NiTi alloy spectacle frame
[23] 2013, Hu Bingyang et al., SRTP, high temperature ratcheting behavior of titanium alloy TA19
[24] 2012, Zong Lingxiao et al., SRTP, finite element simulation of transformation evolution process of shape memory alloy
[25] 2011, Zhao Jiamin et al., National College Students' innovation and entrepreneurship training program, research on non proportional multiaxial deformation behavior of NiTi shape memory alloy microtubules (assistance and guidance)
[26] 2009, Li Zilin, national innovation and entrepreneurship training program for college students, research on cyclic deformation behavior of titanium alloy materials and components (assistance and guidance)
[1] Unity, mutual assistance, and friendship, no longer helpless when encountering difficult problems!
[2] Balanced distribution of scientific research tasks, try to let every graduate student get exercise!
[3] Combination of work and rest, equal emphasis on scientific research output and overall quality improvement!
Long-term commitment to the development of new and efficient cyclic plastic constitutive models, to explore the evolution mechanism of cyclic plastic deformation of materials under non-proportional multiaxial, large deformation and thermal-mechanical coupling conditions, and to carry out the fatigue failure life prediction of the structure in combination with finite element analysis. Provide guidance on damage evolution and life assessment of key components.
In this field, two innovative results have been achieved:
(1) Cyclic plastic deformation experiment and constitutive theory study of materials under complex loading conditions
When the cyclic plastic strain (ratcheting strain) generated under the action of non-proportional thermomechanical load reaches a distortion state of equal cyclic increase or accelerated growth, the ratcheting behavior will cause the structure to exceed the standard size or accelerate the fatigue failure of the structure. At high temperatures, the increase in the number of thermal activation sources of the material will increase the viscosity, creep and plasticity will exhibit a strong interaction, and the accumulation of ratchet strain will be more significant; under the non-proportional loading path, the ratchet deformation will be inhibited by non-proportional additional hardening However, the traditional cyclic plastic constitutive model or creep model with these characteristics cannot give reasonable prediction results. Therefore, it is of great scientific and practical significance to carry out experiments and theoretical research on cyclic plastic deformation of materials under high temperature and non-proportional multiaxial loading conditions. This part of the work has been published in Int J Plasticity (2014, 2016, 2019), Int J Fatigue (2014, 2017), Int J Mech Sci (2015), Acta Metall. Sin. (Engl. Lett.) and other journals in the past five years 12 SCI papers, the main innovations are as follows:
(a) The system reveals the dependence of the ratcheting behavior of metal materials on factors such as holding time, ambient temperature, cycle hard/softening characteristics, non-proportional loading path, loading history, etc.
For materials commonly used in nuclear power engineering such as SS304 stainless steel, S5083-steel, 1Cr18Ni10Ti, titanium alloy TA16 and TA17, and GH4169 superalloy for aero-engine blades, uniaxial and non-proportional multiaxial cyclic deformation experiments were carried out, focusing on the materials The time-dependent ratcheting behavior evolution characteristics under high temperature and its dependence on loading history. At high temperature, SS304 stainless steel has no obvious hysteresis loop under uniaxial asymmetric stress cycle, but it produces obvious ratcheting behavior, and the ratcheting strain increases with the increase of the peak holding time, that is, the creep deformation is dominant.
(b) A thermo-mechanical coupled cyclic constitutive model considering the viscoplastic-creep interaction of metallic materials at high temperatures is established.
In order to fully consider the interaction between viscoplasticity and creep, the ratchet deformation is divided into creep strain and cyclic cumulative viscoplastic strain. A viscoplastic-creep separation constitutive model is established, which reasonably predicts the material's behavior at high temperatures. Time-related ratcheting behavior. Under the unified viscoplastic framework, a static recovery term that characterizes the static recovery of materials is introduced, a new nonlinear kinematic hardening law is developed, and a high-temperature viscoplastic cyclic constitutive model that reasonably describes the relevant characteristics of ratcheting behavior is established. Further considering the ratcheting behavior under large deformation and its coupling with plastic dissipation and heat generation, a thermal-mechanical coupling cycle constitutive model frame under limited deformation is constructed, and the superimposed isotropic evolution equation is used to reflect the material cyclic hardening- Softening-hardening characteristics, and the plastic strain memory surface and non-proportional degree factor are introduced into the isotropic evolution equation to reflect the strain amplitude dependence of the cyclic hardening behavior of the material and the non-proportional additional hardening effect. And the non-proportional multiaxial cyclic deformation behavior and the thermal effect during the deformation process give a reasonable prediction.
(2) Study on the ratcheting behavior and fatigue failure behavior of NiTi shape memory alloy
Because of its unique stress-induced martensitic transformation, latent heat of transformation, and strong temperature dependence of shape memory alloys, its mechanical response exhibits strong nonlinear, non-equilibrium, and thermal-mechanical coupling effects. The thermal-mechanical coupling cycle deformation process not only involves the interaction between the localized phase transformation process and the phase transformation-induced plastic deformation, but the damage evolution is also closely related to the phase transformation process. Its fatigue failure behavior is structural failure (component failure) The result of co-development with functional failure (loss of superelasticity and shape memory effects). In the process of studying the thermal-mechanical coupling cyclic deformation and fatigue failure behavior of shape memory alloys, the localization of the phase transformation process and the thermal-mechanical coupling effect must be highlighted, and the thermal-mechanical coupling phase transformation theory must be established under the framework of the generalized plasticity theory. Therefore, the development of the thermal-mechanical coupling cycle constitutive relationship and fatigue failure behavior of shape memory alloys is an important impetus to the phase change solid mechanics, and it is also an important extension of the research on the constitutive relationship and failure behavior of smart materials. Value and scientific significance. This part of the work has been published in Int J Plasticity (2015, 2019), Mech Mater (2016, 2017), Mater Sci Eng A (2016), Int J Fatigue (2015, 2017, 2019), Acta Mechanica Solida Sinica and other journals for nearly five years Published 36 SCI papers. The main innovations are as follows:
(a) Reveal the phase change ratchet behavior and fatigue failure behavior of NiTi shape memory alloy under mechanical load.
Uniaxial and non-proportional multiaxial cyclic deformation experiments were carried out for NiTi shape memory alloys. The phase change ratcheting behavior and its evolution law were systematically explained, and four typical characteristics of phase change ratcheting behavior were clearly defined: peak strain and valley value Strain increases with increasing cycle times; phase change stress and dissipated energy decrease with increasing cycle times; valley strain increases more significantly than peak strain; phase change ratcheting behavior and its evolution and loading stress level It is closely related to loading the waveform. The cyclic deformation experiments under different loading rates were further carried out. Through infrared temperature measurement and DIC digital image related technology, the phase change pattern evolution during the phase change process was observed in situ, revealing the heat generation, heat exchange and superelasticity in the material. Coupling of degraded behavior.
Furthermore, a systematic axial, torsional, and non-proportional multiaxial stress control fatigue experimental study of NiTi shape memory alloy microtubes was carried out, and the evolution law of phase transformation ratcheting during the life of NiTi alloy under different loading methods was revealed. The stress level and loading were discussed separately. The influence of path and peak-valley stress retention on the uniaxial and multiaxial full-life phase transformation ratcheting evolution of NiTi alloy. The promotion of the degree of martensite transformation on the phase transformation ratcheting evolution is analyzed. For multiaxial loading, the influence of martensite reorientation process on the evolution of phase change ratchet is discussed. In addition, the fatigue fracture and residual martensite morphology of the superelastic NiTi alloy microtubes under different loading methods were microscopically observed, revealing the correlation between the size of lath martensite and the loading stress level, and clarified Both high stress levels and multiaxial loading are likely to form residual martensite with a larger volume fraction in the material. Under the conditions of the same loading rate and maximum equivalent stress/strain, the fatigue life of the alloy in descending order is: uniaxial loading, first torsion and then non-proportional loading, tension and torsion proportional loading and first tension and then non-proportional loading Loading, showing a strong dependence on non-proportional loading paths.
(b) Established a cyclic phase transformation constitutive model and a fatigue failure life prediction model for NiTi shape memory alloy
A constitutive model of the ratcheting behavior of phase change under cyclic loading is established under the generalized plastic framework. It is assumed that the total inelastic strain is composed of two parts: the phase change strain and the plastic strain induced by the phase change. The volume fraction of martensite is used as the internal variable to describe the normal phase transformation and the reverse phase transformation, the cumulative martensite volume fraction is used as the internal variable to describe the plastic deformation induced by the phase transformation, and the residual martensite volume fraction is used to consider the cyclic cycle. The continuous accumulation of incomplete reverse phase transitions, and the introduction of a correction function related to the loading stress level in the evolution law of plastic strain, gives a reasonable description of the evolution of plastic strain during the cyclic phase transition and the stress dependence of plastic strain. The decay process of the phase change stress with the cycle cycle is further considered, and the model is optimized to simulate the shape of the stress-strain hysteresis loop. The above model is expanded under the framework of thermodynamics, and a thermal-mechanical coupled cycle constitutive model considering phase change latent heat and intrinsic mechanical dissipation is established.
Based on the analysis of macroscopic experimental results and microscopic experimental observations, a new fatigue damage evolution model for superelastic NiTi alloy materials was established. The model also considered microcrack initiation, microcrack propagation and damage accumulation caused by the phase transformation process. The influence of martensite reorientation under multiaxial loading is also considered. The above model was used to reasonably predict the process of the gradual accumulation of damage in the material under uniaxial and multiaxial loading with the cycle of cycles; further, by introducing the damage criterion and the multiaxial stress equivalent criterion, the NiTi shape memory alloy was established The multi-axis fatigue life prediction model accurately predicts the fatigue life of NiTi shape memory alloys under different non-proportional multi-axis loads.
1.Main equipment
Name |
Model |
Range |
Multiaxial material testing machine |
MTS-Bionix858 |
5kN/15kN |
Multiaxial material testing machine |
MTS-809 |
250kN |
Creep fatigue testing machine |
CRIMS PRL 100 |
100kN |
Uniaxial material testing machine |
MTS-acumen |
100N~1500N |
Mechanical magnetic thermal electric coupling loading and automatic measuring system |
HS&T-FM-200024 |
20kN |
Nanoindentation |
G 200 |
500mN |
Dynamic thermomechanical analyzer |
DMA Q800 |
18N |
Miniature electromagnetic testing machine |
Kyle M-100 |
100N |
Biaxial fatigue testing machine |
Kyle IPBF-100 |
100N |
High frequency fatigue testing machine |
QBG350 |
350kN |
High frequency fatigue testing machine |
QBG200 |
200kN |
High frequency fatigue testing machine |
QBG100 |
100kN |
High frequency fatigue testing machine |
QBG50 |
50kN |
Structure testing machine |
DX-500 |
500kN |
Structure testing machine |
DX-200 |
200kN |
2. Auxiliary equipment
Name |
Model |
Range |
Strain field measurement |
AROMIS |
|
Extensometer |
MTS |
40% |
High temperature extensometer |
Changchun machinery |
25% |
COD |
MTS |
|
Infrared temperature instrument |
FLIR-A655sc |
-40~ 2000℃ |
Temperature control box |
RT~700℃ |
|
Hot and humid environment box |
-40~140℃ |
|
Incubator |
RT~200℃ |
|
High frequency voltage |
Trek 610E |
10kV |
3D printer |
||
Ultrasonic cleaning machine |
||
Nanoindentation table |
||
Surface nanocrystallization testing machine |
SNC-1 |
|
Heat treatment furnace |
||
workstation |
Wave P8000 |
256G |
Has been published in Journal of the Mechanics and Physics of Solids, International Journal of Plasticity, Materials Science & Engineering A, More than 200 academic papers have been published in journals such as International Journal of Fatigue, International Journal of Mechanical Science, Composite Structures, Acta Mechanica Sinica, Acta Mechanica Solida Sinica, Journal of Mechanics and other academic conferences at home and abroad. Among them, there are more than 140 SCI papers, more than 180 EI papers and more than 4,400 citations by Google Scholar.
[1] Jin Tao, Songjiang Lu, Jianfeng Zhao, Dabiao Liu, Qianhua Kan, Xu Zhang*. Discrete dislocation dynamic simulation on torsion of bicrystal microwires, Materials Science and Engineering A, 2023.
[2] Shijie Song, Qianhua Kan, Yujie Liu, Chen Bao, Xiaochong Lu, Xu Zhang*. Crystal plastic finite element simulation on creep behavior of 316L Austenitic Stainless Steel in Nuclear Reactor at Elevated temperature, Acta Mechanica Sinica, 2023.
[3] Xin Du, Qianhua Kan, Xu Zhang*, Extra strengthening and Bauschinger effect in gradient nano-grained CoCrFeMnNi high-entropy alloy: A molecular dynamics study, International Journal of Plasticity, 2023.
[4] Bing Wang, Qian Wang, Rong Luo, Qianhua Kan, Bin Gu*. Atomistic study on high temperature creep of nanocrystalline 316L austenitic stainless steels, Acta Mechanica Sinica, 2023, 39, 122470.
[5] Jizhong Zhao, Peilin Fu, Hongchen Miao, Zefeng Wen, Rong Chen, Qianhua Kan*. A new approach for solving three-dimensional elasto-plastic wheel-rail normal contact problems, Acta Mechanica Sinica, 2023, 39, 423074.
[6] Fu Peilin, Zhao Jizhong, Zhang Xu, Miao Hongchen, Wen Zefeng, Kang Guozheng, Kan Qianhua*. Three-dimensional tractive rolling contact analysis of functionally graded coating-substrate systems with interfacial imperfection and frictional anisotropy, Composite Structures, 2023, 307, 116671.
[7] Kai Wang, Qiantao Ma, Jiangmang Xu*, Tao Liao, Ping Wang, Rong Chen, Qianhua Kan, Guodong Cui, Lu Li. Determining the elastic-plastic properties of materials with residual stress included using nanoindentation experiments and dimensionless functions, Engineering Fracture Mechanics, 2023, 282, 109175.
[8] Ao Ni*, Zhang Han, Xu Huihui, Wu Shengchuan*, Liu Dong, Xu Pingguang, Su Yuhua, Kan Qianhua, Kang Guozheng. Corrosion fatigue crack growth behavior of a structurally gradient steel for high-speed railway axles, Engineering Fracture Mechanics, 2023, 281, 109166.
[9] Zhang Xuelian, Liu Junjie∗, Li Jian, Liang Zhihong, Jiang Han, Kang Guozheng, Kan Qianhua∗. Experimental investigation on pure-shear ratcheting behavior of double-network tough hydrogels, Extreme Mechanics Letters, 2023, 60, 101984.
[10] Yu Chao, Zhou Ting, Song Di, Kan Qianhua*, Kang Guozheng. A two-scale thermo-mechanically coupled constitutive model for grain size- and rate-dependent deformation of nano-crystalline NiTi shape memory alloy, International Journal of Engineering Science, 2023, 187, 103843.
[11] Kan Qianhua, Qiu Bo, Zhang Xu, Yu Chao*, Kang Guozheng. Thermo-mechanically coupled functional fatigue of NiTi shape memory alloys under multiaxial cyclic loadings, International Journal of Fatigue, 2023, 172, 107657.
[12] Xiang Xu, Li Ding, Hongchen Miao, Zefeng Wen, Rong Chen, Qianhua Kan *, Guozheng Kang. Nonproportionally multiaxial cyclic plastic deformation of U75 rail steel: Experiment and modeling, International Journal of Fatigue, 2023, 168, 107480.
[13] Bo Xu, Chong Wang *, Qingyuan Wang, Chao Yu, Qianhua Kan, Guozheng Kang *. Enhancing elastocaloric effect of NiTi alloy by concentration-gradient engineering, International Journal of Mechanical Sciences, 2023, 246, 108140.
[14] Li Ding, Xu Zhang*, Chao Yu, Xiang Xu, Guozheng Kang, Qianhua Kan*. Incremental strain gradient plasticity model and torsion simulation of copper microwires, International Journal of Mechanical Sciences, 2023, 239, 107891.
[15] Qianhua Kan, Wenxiang Shi, Di Song, Chao Yu *, Guozheng Kang. A micromechanical constitutive model of high-temperature shape memory alloys, International Journal of Mechanical Sciences, 2023, 251, 108328.
[16] Songjiang Lu, Ni Ao, Qianhua Kan, Shegnchuan, Guozheng Kang, Xu Zhang*. Effect of residual stress in gradient-grained metals: Dislocation dynamics simulations International Journal of Mechanical Sciences, 2023, 256, 108518.
[17] Qianhua Kan, Yong Zhang, Yangguang Xu, Guozheng Kang, Chao Yu *. Tension-compression asymmetric functional degeneration of super-elastic NiTi shape memory alloy: Experimental observation and multiscale constitutive model, International Journal of Solids and Structures, 2023, 280, 112384.
[18] Yong Zhang, Chao Yu *, Di Song, Yilin Zhu, Qianhua Kan, Kang Guozheng. Solid-state cooling with high elastocaloric strength and low driving force via NiTi shape memory alloy helical springs: Experiment and theoretical model, Mechanics of Materials, 2023, 178, 104575.
[19] Siyao Shuang, Yanxiang Liang, Chao Yu, Qianhua Kan, Guozheng Kang, Xu Zhang*. Effect of loading orientation on plasticity in nano-laminated CoNiCrFeMn dual-phase high-entropy alloy: a molecular dynamics study, Modelling and Simulation in Materials Science and Engineering, 2023, 31, 015005.
[20] Yuehao Du, Jiangcheng Cai, Qianhua Kan, Zhang Qinghua, Ping Wang, Hongchen Miao*, Guozheng Kang. Time-delayed layer-based piezoelectric transducer for unidirectional excitation and reception of SH guided wave, Mechanical Systems and Signal Processing, 2023, 193, 110268.
[21] Songjiang Lu, Qianhua Kan, Bo Zhang, Chao Yu, Guozheng Kang, Xu Zhang *. Size effect in nanoindentation: Taylor hardening or dislocation source-limited effect? Materials Today Communications, 2022, 33, 104580.
[22] Jian Li, Zhihong Liang, Kaijuan Chen, Xu Zhang, Guozheng Kang, Qianhua Kan*. Thermo-mechanical deformation for thermo-induced shape memory polymers at equilibrium and non-equilibrium temperatures: Experiment and simulation, Polymer, 2023, 270, 125762.
[23] Zhihong Liang, Jian Li, Qianhua Kan*, Xuelian Zhang. A Constitutive Model and its Finite Element Implementation for Thermo-mechanically Coupled Viscoelastic-viscoplastic Behavior of Amorphous Polymers, Polymer Testing, Polymer Testing 117 (2023) 107831.
[24] Jian Li, Zhihong Liang, Junjie Liu, Chao Yu, Xuelian Zhang, Qianhua Kan*. A thermo-viscoelastic constitutive model addressing the cyclic shape memory effect for thermo-induced shape memory polymers, Smart Materials and Structures, 2023, 32, 035030.
[25] Zhihong Liang, Jian Li, Kaijuan, Chen, Yu Dong, Chao Yu, Qianhua Kan*. Multiaxial shape memory effect of thermo-induced shape memory polyurethane under proportional tension-torsion loading, Smart Materials and Structures, 2023, 32, 075018.
[26] Jiangcheng Cai, Yuehao Du, Qianhua Kan, Qinghua Zhang, Hongchen Miao *, Guozheng Kang. Constrained thickness-shear vibration-based piezoelectric transducers for generating unidirectional-propagation SH0 wave, Ultrasonics, 2023, 134, 107106.
[27] Yong Zhang, Chao Yu, Yinlin Zhu, Qianhua Kan, Guozheng Kang. Thermo-mechanically coupled deformation of pseudoelastic NiTi SMA helical spring, International Journal of Mechanical Sciences, 2022, 236, 107767.
[28] Ziyi Wang, Shengchuan Wu, Yu Lei, Qianhua Kan, Guozheng Kang. Damage evolution of extruded magnesium alloy from deformation twinning and dislocation slipping in uniaxial stress-controlled low cycle fatigue, International Journal of Fatigue 164 (2022) 107124.
[29] Han M Jiang, Chao Yu, Qianhua Kan, Bo Xu, Chuanping Ma, Guozheng Kang. Effect of hydrogen on super-elastic behavior of NiTi shape memory alloy wires: Experimental observation and diffusional-mechanically coupled constitutive model. Journal of the Mechanical Behavior of Biomedical Materials, 2022, 132, 105276.
[30] Qianhua Kan, Jizhong Zhao, Xiang Xu, Ziyi Wang, Xu Zhang, Ping Wang. Temperature-dependent cyclic plastic deformation of U75VG rail steel: Experiments and simulations, Engineering Failure Analysis, 2022, 140, 106527.
[31] Jizhong Zhao, Peilin Fu, Xiang Xu, Xu Zhang, Ping Wang, Qianhua Kan. A cyclic visco-plastic constitutive model for the ratcheting behavior of U75VG rail steel under a wide range of loading rates, Engineering Failure Analysis, 2022, 138, 106342.
[32] Jizhong Zhao, Xing Pang, Peilin Fu, Yuan Wang, Guozheng Kang, Ping Wang, Qianhua Kan. Dynamic constitutive model of U75VG rail flash-butt welded joint and its application in wheel-rail transient rolling contact simulation, Engineering Failure Analysis, 2022, 134, 106078.
[33] Xuelian Zhang, Jian Li, Zhihong Liang, Qianhua Kan. Design and finite element simulation of shape memory polyurethane self-folding structures, Engineering Failure Analysis, 2022, 139, 106446.
[34] Yu Chao, Zhou Ting, Kan Qianhua, Kang Guozheng, Fang Daining. A two-scale thermo-mechanically coupled model for anomalous martensite transformation and elastocaloric switching effect of shape memory alloy. Journal of the Mechanics and Physics of Solids, 2022, 164, 104893.
[35] Xiang Xu, Ziyi Wang, Guhui Gao, Xu Zhang, Guozheng Kang, Qianhua Kan. The effect of microstructure evolution on the ratchetting-fatigue interaction of carbide-free bainite rail steels under different heat-treatment conditions, International Journal of Fatigue, 2022, 160, 106872.
[36] Xiang Xu, Ziyi Wang, Xu Zhang, Guhui Gao, Ping Wang, Qianhua Kan. Strain amplitude-dependent cyclic softening behavior of carbide-free bainitic rail steel: Experiments and modeling, International Journal of Fatigue, 2022, 161, 106922.
[37] Yang Jingye, Kang Guozheng, Kan Qianhua. A novel deep learning approach of multiaxial fatigue lifeprediction with a self-attention mechanism characterizing the effects of loading history and varying temperature, International Journal of Fatigue, 2022, 162, 106851.
[38] Yang Jingye, Kang Guozheng, Kan Qianhua. Rate-dependent multiaxial life prediction for polyamide-6 considering ratchetting: Semi-empirical and physics-informed machine learning models, International Journal of Fatigue, 2022, 163, 107086.
[39] Peilin Fu, Jizhong Zhao, Xu Zhang, Guozheng Kang, Ping Wang, Qianhua Kan. Thermo-mechanical coupled sliding contact shakedown analysis of functionally graded coating-substrate structures, International Journal of Mechanical Science, 2022, 222, 107241.
[40] Peilin Fu, Jizhong Zhao, Xu Zhang, Guozheng Kang, Ping Wang, Qianhua Kan. Elastic shakedown analysis of two-dimensional thermoelastic rolling/sliding contact for a functionally graded coating/substrate structure with arbitrarily varying thermo-elastic properties, Composites Structures, 2022, 280, 114891.
[41] Xu Bo, Yu Chao, Kan Qianhua, Kang Guozheng. Phase field study on the microscopic mechanism of the cyclic degradation of shape memory effect in nano-polycrystalline NiTi shape memory alloys, European Journal of Mechanics A/Solids, 2022, 93, 104544.
[42] Xu Bo, Yu Chao, Kan Qianhua, Kang Guozheng. Phase field study on the microscopic mechanism of the cyclic degradation of shape memory effect in nano-polycrystalline NiTi shape memory alloys, European Journal of Mechanics / A Solids 93 (2022) 104544.
[43] Jianfeng Zhao, Xinlei Pan, Jian Li, Zhiyong Huang, Qianhua Kan, Guozheng Kang, Liucheng Zhou, Xu Zhang. Laser shock peened Ti-6Al-4 V alloy: Experiments and modeling, International Journal of Mechanical Sciences 213 (2022) 106874.
[44] Xu Zhang, Xiaocong Lu, Jianfeng Zhao, Qianhua Kan, Zhiming Li, Guozheng Kang. Temperature effect on tensile behavior of an interstitial high entropy alloy: crystal plasticity modeling, International Journal of Plasticity, 150(2022)103201.
[45] Songjiang Lu, Qianhua Kan, Michael Zaiser, Zhiming Li, Guozheng Kang, Xu Zhang. Size-dependent yield stress in ultrafine-grained polycrystals: A multiscale discrete dislocation dynamics study, International Journal of Plasticity, 149 (2022) 103183.
[46] Songjiang Lu, Qianhua Kan, Bo Zhang, Chao Yu, Guozheng Kang, Xu Zhang. Size effect in nanoindentation: Taylor hardening or dislocation source-limited effect? Materials Today Communications 33 (2022) 104580.
[47] Jian Li, Zhihong Liang, Xuelian Zhang, Qianhua Kan. Experimental investigation on the thermo-mechanical deformation of thermo-induced shape memory polyurethane, Polymer, 2021, 237, 124337.
[48] Xuejiao Shao, Hai Xie, Yixiong Zhang, Furui Xiong, Xiaoming Bai, Lu Jiang, Qianhua Kan. Investigation on analysis method of environmental fatigue correction factor of primary coolant metal materials in LWR water environment, Metals, 2021, 11, 233.
[49] Hang Su, Chung Lun Pun, Peter Mutton, Qianhua Kan, Guozheng Kang, Wenyi Yan. Numerical study on the ratcheting performance of rail flash butt welds in heavy haul operations, International Journal of Mechanical Sciences, 2021, 199, 106434.
[50] Jingye Yang, Guozheng Kang, Yujie Liu, Qianhua Kan. A novel method of multiaxial fatigue life prediction based on deep learnin, International Journal of Fatigue, 2021, 151, 106356.
[51] Jizhong Zhao, Hongchen Miao, Qianhua Kan, Peilin Fu, Li Ding, Guozheng Kang, Ping Wang. Numerical investigation on the rolling contact wear and fatigue of laser dispersed quenched U71Mn rail,International Journal of Fatigue 2021, 143, 106010.
[52] Siyao Shuang, Songjiang Lu, Bo Zhang, Chen Bao, Qianhua Kan, Guozheng Kang, Xu Zhang. Effects of high entropy and twin boundary on the nanoindentation of CoCrNiFeMn high-entropy alloy: A molecular dynamics study, Computational Materials Science, 2021, 195, 110495.
[53] Xu Zhang, Songjiang Lu, Bo Zhang, Xiaobao Tian, Qianhua Kan, Guozheng Kang. Dislocation–grain boundary interaction-based discrete dislocation dynamics modeling and its application to bicrystals with different misorientations, Acta Materialia, 2021, 20, 88-98.
[54] Jizhong Zhao, Peilin Fu, Xu Zhang, Liucheng Zhou, Ping Wang, Qianhua Kan. An effective method for calculating elasto-plastic contact pressure and contact patch size under elliptical, circular and line contact conditions, Applied Mathematical Modelling, 2021, 95, 541-574.
[55] Tianxing Zhao, Guozheng Kang, Chao Yu, Qianhua Kan. Experimental study on whole-life one-way shape memory cyclic degradation and fatigue failure of NiTi shape memory alloy, Materials Today Communications, 2020, 25,101621.
[56] Jizhong Zhao, Qianhua Kan, Peilin Fu, Guozheng Kang, Ping Wang. An elasto-plastic contact solving method for two spheres, Acta Mechanica Solida Sinica, 2020, (3), 612-634.
[57] Xi Xie, Guozheng Kang, Qianhua Kan, Chao Yu. Phase-field theory based finite element simulation on thermo-mechanical cyclic deformation of polycrystalline super-elastic NiTi shape memory alloy, Computational Materials Science, 2020, 184, 109899.
[58] Xiaochong Lu, Jianfeng Zhao, Chao Yu, Zhiming Li, Qianhua Kan, Guozheng Kang, Xu Zhang. Cyclic plasticity of an interstitial high entropy alloy: experiments, crystal plasticity modeling, and simulations, Journal of the Mechanics and Physics of Solids, 2020, 142, 103971.
[59] Ziyi Wang, Qianhua Kan, Xiang Xu, Li Ding, Ping Wang, Guozheng Kang. A new damage-coupled cyclic plastic model for whole-life ratchetting of heat-treated U75V steel, International Journal of Damage Mechanics, 2020, 1056789520930408.
[60] Jun Tian, Xiaolong Fu, Xuejiao Shao, Liping Zhang, Jian Li, Qianhua Kan. Damage-coupled ratcheting rehaviors of SA508 Gr. 3 steel at room and elevated temperature: Experiments and simulations, International Journal of Damage Mechanics, 2020, 1056789520930406.
[61] Fu Peilin, Yuan Jianghong, Xu Zhang, Kang Guozheng, Wang Ping, Kan Qianhua. Forced vibration analysis of blade after selective laser shock processing based on Timoshenko's beam theory, Composite Structures, 2020, 243, 112249.
[62] Ting Zhou, Chao Yu, Guozheng Kang, Qianhua Kan, Daining Fang. A crystal plasticity based constitutive model accounting for R phase and two-step phase transition of polycrystalline NiTi shape memory alloys, International Journal of Solids and Structures, 2020, 193-194, 503-526.
[63] Hang Su, Jian Li, Quan Lai, Chung Lun Pun, Peter Mutton, Qianhua Kan, Guozheng Kang, Wenyi Yan. Ratcheting behaviour of flash butt welds in heat-treated hypereutectoid steel rails under uniaxial and biaxial cyclic loadings, International Journal of Mechanical Sciences, 2020, 176,105539.
[64] Bo Xu, Guozheng Kang, Qianhua Kan, Chao Yu, Xi Xie. Phase field simulation on the cyclic degeneration of one-way shape memory effect of NiTi shape memory alloy single crystal, International Journal of Mechanical Sciences, 2020, 168,105303.
[65] Bo Xu, Guozheng Kang, Chao Yu, Qianhua Kan. Phase field simulation on the grain size dependent super-elasticity and shape memory effect of nanocrystalline NiTi shape memory alloys. International Journal of Engineering Science, 2020, 156, 103373.
[66] Wang Bing, Kang Guozheng, Wu Wenping, Zhou Kun, Kan Qianhua, Chao Yu. Transformation ratchetting of nanocrystalline super-elastic NiTi shape memory alloy and its atomic mechanism from molecular dynamics simulations, International Journal of Plasticity, 2020,125, 374-394.
[67] Jianfeng Zhao, Xiaochong Lu, Fuping Yuan, Qianhua Kan, Shaoxing Qu, Guozheng Kang, Xu Zhang. Multiple mechanism based constitutive modeling of gradient nanograined material, International Journal of Plasticity, 2020, 125, 314-330.
[68] Jinye Yang, Guozheng Kang, Yujie Liu, Kaijuan Chen, Qianhua Kan. Life prediction for rate-dependent low-cycle fatigue of PA6 polymer considering ratchetting: Semi-empirical model and neural network based approach, International Journal of Fatigue, 2020, 132,105619.
[69] Jinye Yang, Guozheng Kang, Kaijuan Chen, Qianhua Kan, Yujie Liu. Experimental study on rate-dependent uniaxial whole-life ratchetting and fatigue behavior of polyamide 6, International Journal of Fatigue, 2020, 132,105402.
[70] Huiliang Luo, Guozheng Kang, Qianhua Kan. A low-cycle fatigue life-prediction model for SUS301L stainless steel buttwelded joint with considering ratchetting, International Journal of Fatigue, 2020,139,105777.
[71] Huiliang Luo, Guozheng Kang, Qianhua Kan, Chuanping Ma. Experimental study on the whole‐life heterogeneous ratchetting and ratchetting‐fatigue interaction of SUS301L stainless steel butt‐welded joint, Fatigue and Fracture of Engineering Materials and Structures, 2019, 43, 35-50.
[72] B Xu, G Kang, Q Kan, C Yu, X Xie. Phase field simulation on the cyclic degeneration of one-way shape memory effect of NiTi shape memory alloy single crystal,International Journal of Mechanical Sciences, 2019, 168, 105303.
[73] Jian Xiong, Dean Wei, Songjiang Lu, Qianhua Kan, Guozheng Kang, Xu Zhang. A three-dimensional discrete dislocation dynamics simulation on micropillar compression of single crystal copper with dislocation density gradient, Acta Metallurgica Sinica, 2019, 55 (11), 1477-1486(in Chinese).
[74] Tianxing Zhao, Guozheng Kang, Chao Yu, Qianhua Kan. Experimental investigation on the thermo-mechanical cyclic degeneration of one-way shape memory effect of NiTi shape memory alloy, International Journal of Minerals, Metallurgy and Materials, 2019, 26 (12), 1539-1550.
[75] Hang Su, Chung Lun Pun, Peter Mutton, Qianhua Kan, Wenyi Yan. Numerical study on the ratcheting performance of heavy haul rails in curved tracks, Wear, 2019, 436-437, 203026(12 Pages).
[76] Junyu Chen, Kuo Zhang, Qianhua Kan, Hao Yin, Qingping Sun. Ultra-high fatigue life of NiTi cylinders for compression-based elastocaloric cooling, Applied Physics Letters, 2019, 115, 093902(4 Pages).
[77] Junyu Chen, Qianhua Kan, Qiao Li, Hao Yin. Effects of grain size on acoustic emission of nanocrystalline superelastic NiTi shape memory alloys during fatigue crack growth, Materials Letters, 2019, 252, 300-303.
[78] Bo Xu, Guozheng Kang, Qianhua Kana, Xi Xie, Chao Yua, Qi Peng. Phase field simulation to one-way shape memory effect of NiTi shape memory alloy single crystal, Computational Materials Science, 2019, 161, 276-292.
[79] Di Song, Guozheng Kang, Chao Yu, Qianhua Kan, Qianhua Kan, Chuanzeng Zhang. Torsional whole-life transformation ratcheting under pure-torsional and non-porportional multiaxial cyclic loadings of NiTi SMA at human-body temperature:Experimental observations and life-prediction model, Journal of the Mechanical Behavior of Biomedical Materials, 2019, 94, 267-278.
[80] Xi Xie, Guozheng Kang, Qianhua Kan, Chao Yu, Qi Peng. Phase field modeling to transformation induced plasticity in superelastic NiTi shape memory alloy single crystal, Modelling and Simulation in Materials Science and Engineering, 2019, 27, 045001.
[81] Pan Liu, Qianhua Kan, Hao Yin. Effects of grain size on wear resistance of nanocrystalline NiTi shape memory alloy, Materials Letters, 2019, 241, 43-45.
[82] Jian Li, Qianhua Kan, Kaijuan Chen, Zhihong Liang, Guozheng Kang. In situ observation on rate-dependent strain localization of thermo-induced shape memory polyurethane, Polymers, 2019,11, 982.
[83] Qiu Bo, Zhao Tianxing, Chen Kaijuan, Kang Guozheng, Kan Qianhua. Experimental observation on multiaxial thermo-mechanical coupling cyclic transformation of super-elastic NiTi alloy micro-tube, International Journal of Fatigue, 2019, 127, 470-478.
[84] Jianfeng Zhao, Qianhua Kan, Liucheng Zhou, Guozheng Kang, Haidong Fan, Xu Zhang. Deformation mechanisms based constitutive modelling and strength-ductility mapping of gradient nano-grained materials. Material Science and Engineering A, 2019,742, 400-408.
[85] Qiu Bo, Kan Qianhua, Kang Guozheng, Yu Chao, Yan Wenyi. A thermo-mechanically coupled constitutive model describing rate-dependent cyclic deformation of super-elastic NiTi shape memory alloy, Mechanics Research Communication, 2019, 90, 32-41.
[86] Ting Zhou, Chao Yu, Guozheng Kang, Qianhua Kan. A microplane constitutive model for martensite transformation and reorientation in shape memory alloys under non-proportional multiaxial loading. International Journal of Mechanical Science, 2019, 152, 63-80.
[87] Jingye Yang, Guozheng Kang, Kaijuan Chen,Qianhuakan Kan. Experimental study on uniaxial ratchetting-fatigue interaction of polyamide-6. Polymer Testing, 2018, 69, 545-555.
[88] Jun Tian, Jian Li, Yu Yang, Qianhua Kan. Finite element implementation of a temperature-dependent cyclic plastic model for SA508-3 steel, Metals, 2018, 8(11), 955.
[89] Xiang Xu, Qian-hua Kan, M Han Jiang, Guo-zheng Kang. A multi-mechanism model describing reorientation, detwinned and plasticity of one-way NiTi shape memory alloy. Acta Mechanica Solida Sinica,2018, 31(4), 445-458.
[90] Bo Qiu, Qianhua Kan, Tianxing Zhao, Xi Xie, Guozheng Kang. Investigation on anisotropic cyclic transformation of super-elastic NiTi alloy under multi-axial cyclic loadings. Acta Mechanica Solida Sinica,2018, 31(6),744-757.
[91] Jian Li, Qian-hua Kan, Ze-bin Zhang, Guo-zheng Kang, Wen-yi Yan. Thermo-mechanically coupled thermo-elasto-visco-plastic modeling of thermo-induced shape memory polyurethane at finite deformation. Acta Mechanica Solida Sinica,2018, 31(2),141-160.
[92] Bing Wang, Guozheng Kang, Qianhua Kan, Wenping Wu, Kun Zhou, Chao Yu. Atomistic study on the super-elasticity of single crystal bulk NiTi shape memory alloy under adiabatic condition, Computational Materials Science, 2018, 142-38-46.
[93] Bing Wang, Guozheng Kang, Qianhua Kan, Wenping Wu, Kun Zhou, Chao Yu. Atomistic study on the super-elasticity of nanocrystalline NiTi shape memory alloy subjected to a cyclic deformation, Computational Materials Science, 2018, 152, 85-92.
[94] Xie Xi, Kang Guozheng, Kan Qianhua, Yu Chao, Peng Qi. Phase field modeling for cyclic phase transition of NiTi shape memory alloy single crystal with super-elasticity. Computational Materials Science, 2018, 143, 212-224.
[95] Chao Yu, Guozheng Kang, Qianhua Kan. An equivalent local constitutive model for grain size dependent deformation of NiTi polycrystalline shape memory alloys. International Journal of Mechanical Sciences, 138, 34-41.
[96] Chao Yu, Guozheng Kang, Qianhua Kan. A micromechanical constitutive model for grain size dependent thermo-mechanically coupled inelastic deformation of super-elastic NiTi shape memory alloy, International Journal of Plasticity, 105, 99-127.
[97] Zhang Jianwei, Jiang Han, Jiang Chengkai, Kang Guozheng, Kan Qianhua, Li Yonghua. Experimental and numerical investigations of evaluation criteria and material parameters' coupling effect on polypropylene scratch, Polymer Engineering & Science, 2018, 58(1),118-122.
[98] Luo Huiliang, Kang Guozheng, Kan Qianhua, Huang Yan. Experimental investigation on the heterogeneous ratchetting of SUS301L stainless steel butt weld joint during uniaxial cyclic loading, Materials Science and Engineering A, 2017, 105, 169-179.
[99] Song Di, Kang Guozheng, Yu Chao, Kan Qianhua, Zhang Chuanzeng. Non-proportional multiaxial fatigue of super-elastic NiTi shape memory alloy micro-tubes: Damage evolution and life-prediction models, International Journal of Mechanical Sciences, 2017, 131-132, 325-333.
[100] Tian Jun, Yang Yu, Zhang Liping, Shao Xuejiao, Du Juan, Kan Qianhua. Ratcheting behavior of SA508-3 steel at elevated temperature experimental observation and simulation. Acta Metall Sina (Engl Lett), 2017, 1-7.
[101] Yu Chao, Kang Guozheng, Kan Qianhua, Xu Xiang. Physical mechanism based crystal plasticity model of NiTi shape memory alloy addressing degeneration of shape memory effect during thermo-mechanical cyclic deformation, Mechanics of Materials, 2017, 112, 1-17.
[102] Song Di, Kang Guozheng, Kan Qianhua, Yu Chao, Zhang Chuanzeng. Effects of peak stress and stress amplitude on multiaxial transformation ratchetting and fatigue life of superelastic NiTi SMA micro-tubes: Experiments and life-prediction model, International Journal of Fatigue, 2017, 96, 252-260.
[103] Wang Bing, Kang Guozheng, Kan Qianhua, Zhou Kun, Chao Yu. Molecular dynamics simulations to the pseudo-elasticity of NiTi shape memory alloy nano-pillar subjected to cyclic compression, Computational Materials Science, 2017, 131, 132-138.
[104] Yu Chao, Kang Guozheng, Kan Qianhua. A macroscopic multi-mechanism based constitutive model for the thermo-mechanical cyclic degeneration ofshape memory effect of NiTi shape memory alloy, Acta Mech Sina, 2017, 1-16.
[105] Dong Cheng, Liu Wenjie, Zhou Lun, Zhang Ruilei, Kan Qianhua, Leng Wuming. Evaluation on fatigue life of expressway asphalt pavement based on tire-pavement-subgrade coupling model. American Journal of Civil Engineering, 2017, 5(6), 400-407.
[106] Zhu Yilin, Kang Guozheng, Kan Qianhua, Bruhns T. Otto, Liu Yujie. Thermo-mechanically coupled cyclic elasto-viscoplastic constitutive model of metals: theory and application, International Journal of Plasticity, 2016, 79, 111-152.
[107] Song Di, Kang Guozheng, Kan Qianhua, Yu Chao, Zhang Chuanzeng. Study on the microstructure and stress fatigue failure mechanism of super-elastic NiTi shape memory alloy micro-tubes, Materials Science and Engineering A, 2016, 665, 17-25.
[108] Xie Xi, Kan Qianhua,Kang Guozheng, Fucong Lu, Kaijuan Chen. Observation on rate-dependent cyclic transformation domain of super-elastic NiTi shape memory alloy, Materials Science and Engineering A, 2016, 671, 32-47.
[109] Xie Xi, Kan Qianhua, Li Jian, Qiu Bo, Yu Chao, Kang Guozheng. Observation on the transformation domains of super-elastic NiTi shape memory alloy and their evolutions during cyclic loading, Smart Materials and Structures, 2016, 25, 045003 (11pp).
[110] Kan Qianhua, Yu Chao, Kang Guozheng, Li Jian, Yan Wenyi. Experimental observations on rate-dependent cyclic deformation of super-elastic NiTi shape memory alloy, Mechanics of Materials, 2016, 97, 48-58.
[111] Chung Lun Pun, Qianhua Kan, Peter J Mutton, Guozheng Kang, Wenyi Yan. A Comprehensive Approach to Evaluate the Ratcheting Performance of Rail Steels under Cyclic Rolling Contact in Service. International Journal Mechanical Science, 2015.
[112] Song Di, Guozheng Kang, Qianhua Kan, Yu Chao, Zhang chuangzhen. Non-proportional multiaxial transformation ratcheting and life of super-elastic NiTi shape memory alloy with incomplete transformations. International Journal of Fatigue, 2015, 80,372-380.
[113] Song Di, Guozheng Kang, Qianhua Kan, Yu Chao, Zhang chuangzhen.Damage-based life prediction model for uniaxial low-cycle stress fatigue of superelastic NiTi shape memory alloy microtubes. Smart Materials and Structures, 2015, 24, 0850074(8pp).
[114] Song Di, Kang Guozheng, Kan Qianhua, Yu Chao, Zhang Chuanzeng. Experimental observations on uniaxial whole-life transformation ratchetting and low-cycle stress fatigue of super-elastic NiTi shape memory alloy micro-tubes, Smart Materials and Structures, 2015, 24, 075004 (10pp).
[115] Mingxing Shi, Yonghong Cao, Zhendong Sha, Qianhua Kan, Yongwei Zhang, Guozheng Kang. First-principles investigation of the edge-related properties of fluorographene nanoribbons, Journal of Applied Mechanics, 2015, 82, 041007-1-7.
[116] Yu Chao, Kang Guozheng, Kan Qianhua. New micromechanical constitutive model for anisotropic cyclic deformation of super-elastic NiTi shape memory alloy single crystal, Journal of Mechanics and Physics in Solids, 2015, 82, 97-136.
[117] Yu Chao, Kang Guozheng, Kan Qianhua, Zhu Yilin. Rate-dependent cyclic deformation of super-elastic NiTi shape memory alloy: thermo-mechanical coupled and physical mechanism-based constitutive model, International Journal of Plasticity, 2015, 72, 60-90.
[118] Yu C, Kang G Z, Song D, Kan Q H. Effect of martensite reorientation on multiaxial transformation ratchetting of super-elastic NiTi shape memory alloy: new consideration in constitutive model. International journal of Plasticity, 2015, 67, 69-101.
[119] Yu Chao, Kang Guozheng, Kan Qianhua. A physical mechanism based constitutive model for temperature-dependent transformation ratcheting of NiTi shape memory alloy: one-dimensional model. Mechanics of Materials, 2014, 78, 1-10.
[120] Yu Chao, Kang Guozheng, Kan Qianhua. A cyclic crystal plasticity based constitutive model for rate-dependent cyclic deformation of NiTi shape memory alloy considering internal heat generation. International Journal Solids and structures, 2014, 51(25-26),4396-4305.
[121] Yu Chao, Kang Guozheng, Kan Qianhua, Song Di. A micromechanical constitutive model considering different mechanisms of inelastic deformation for NiTi shape memory alloy, International Journal of Plasticity, 2014, 54, 132-162.
[122] Yu Chao, Kang Guozheng, Kan Qianhua. Crystal plasticity based constitutive model for the ratchetting of magnesium single crystal and polycrystalline alloys, Computational Material Science, 2014, 84, 63-73.
[123] Yilin Zhu, Guozheng Kang, Qianhua Kan, Chao Yu. A finite viscoelastic-plastic model for describing the uniaxial ratchetting of soft biological tissues. Journal of Biomechanics, 2014,47, 996-1003.
[124] Pun Chunglun, Kan Qianhua, Mutton J. Peter, Kang Guozheng, Yan Wenyi. Ratchetting behaviour of high strength rail steels under biaxial compression-torsion loadings, International Journal of Fatigue, 2014,66, 138-154.
[125] Chung Lun Pun, Qianhua Kan, Peter J Mutton, Guozheng Kang, Wenyi Yan. A single parameter to evaluate stress state in rail head for rolling contact fatigue analysis. Fatigue & Fracture of Engineering Materials & Structures, 2014, 37, 909-919.
[126] Zhu Yilin, Kang Guozheng, Kan Qianhua, Bruhns T. Otto. Logarithmic stress rate based cyclic constitutive model in finite plasticity, International Journal of Plasticity, 2014, 54, 34-55.
[127] Song Di, Kang Guozheng, Kan Qianhua, Yu Chao, Zhang Chuanzeng. Non-proportionally multiaxial transformation ratchetting of super-elastic NiTi shape memory alloy: experimental observations, Mechanics of Materials, 2014, 70, 94-105.
[128] Di Song, Guozheng Kang, Qianhua Kan, Chao Yu, Chuanzeng Zhang. Effect of martensite plasticity on cyclic deformation of super-elastic NiTi shape memory alloy, Smart Materials and Structures, 2014, 23, 015008.
[129] Abbas Amini, Chun Cheng, Qianhua Kan, Minoo Naebe, Haisheng Song. Phase transformation evolution in NiTi shape memory alloy under cyclic nanoindentation loadings at dissimilar rates. Scientific reports, 2013, 3, 3412.
[130] Qianhua Kan, Wenyi Yan, Guozheng Kang, Qingping Sun. Application of Oliver-Pharr indentation method in phase transformation material---shape memory alloy, Journal of the Mechanics and Physics of Solids, 2013, 61, 2015-2033.
[131] Wenyi Yan, Qianhua Kan, Ramesh Rajan, Kenan Kergrene, Guozheng Kang, Xiqiao Feng. A truncated conical beam model for the vibration analysis of rat whiskers, Journal of Biomechanics, 2013, 46, 1987-1995.
[132] Qianhua Kan, Ramesh Rajan, Guozheng Kang, Wenyi Yan. Elastic modulus of rat whisker---A key biomaterial in rat whisker sensory system, Material Research Bulletin, 2013, 48(12), 5026-5032.
[133] Xiangjun Jiang, Yongsheng Zhu, Youyun Zhang, Qianhua Kan. Constitutive model for time-dependent ratchetting of SS304 stainless steel: simulation and finite element analysis, Journal of Theoretical and Applied Mechanics, 2013, 51, 63-73.
[134] Chao Yu, Guozheng Kang, Qianhua Kan, Di Song. A cyclic micromechanical model for NiTi shape memory alloy. International Journal of Plasticity, 2013, 44: 161-191.
[135] Sujuan Guo, Guozheng Kang, Juan Zhang, Qianhua Kan. Effects of tangent operators on prediction accuracy of meso-mechanical constitutive model of elasto-plastic composites, International Journal of Computational Methods, 2013, 11(2).
[136] Qianhua Kan, Guozheng Kang, Wenyi Yan. Cyclic Deformation Behavior and Low-cycle Fatigue Failure Behavior of TA16 Titanium alloy. Advanced Science Letters, 2012, 15(1), 465-468.
[137] QH Kan, GZ Kang, SJ Guo, Finite element implementation of a super-elastic constitutive model for transformation ratcheting of NiTi alloy. International Journal of Computational Methods, 2012, 9(1), 1240022.
[138] Chao Yu, Guozheng Kang, Di Song, Qianhua Kan. Micromechanical constitutive model considering plasticity for super-elastic NiTi shape memory alloy, Computational Materials Science, 2012, 56, 1-5.
[139] Qianhua Kan, Guozheng Kang, Wenyi Yan, Yu Chao. An Energy-based Fatigue Failure Model of Super-elastic NiTi Alloy under Pure Mechanical Cyclic Loading. Proc. Of SPIE, 8409, 8409DF-1.
[140] Wenyi Yan, Gopesh Tilvawala, Qianhua Kan. Numerical investigation of the mechanical behaviour of shape memory bulk metallic glass composites. Proc. Of SPIE, 8409, 84090E-1.
[141] Guozheng kang, Qianhua Kan, Yu Chao, Song Di, Liu Yujie. Whole-life Transformation Ratchetting and Fatigue of Super-elastic NiTi Alloy under Uniaxial Stress-controlled Cyclic Loading. Material Science and Engineering A, 2012, 535, 228-234.
[142] Jun Ding, Guozheng Kang, Qianhua Kan, Yujie Liu. Constitutive model for uniaxial time-dependent ratcheting of 6061-T6 aluminum alloy. Computational Materials Science, 2012, 57: 67-72.
[143] Qianhua Kan, Guozheng Kang. Constitutive model study on transformation ratcheting of superelastic NiTi alloy, International Journal of Plasticity, 2010, 26(3):441-465.
[144] Qianhua kan, Guozheng Kang, Linmao Qian. A super-elastic constitutive model considering plasticity and its finite element implementation. Acta Mechanica Solida Sinica, 2010, 23(1), 1-11.
[145] Guozheng Kang, Qianhua Kan, Linmao Qian, Yujie Liu. Ratchetting Deformation of Superelastic and Shape memory NiTi Alloys. Mechanics of Materials, 2009 ,41(2), 139-153.
[146] Qianhua Kan, Guozheng Kang, Juan Zhang. Uniaxial time-dependent ratchetting: Visco-plastic Constitutive Model and Finite Element Application. Theoretical and Applied Fracture Mechanics, 2007,47(2), 113-144.
[147] Kang, G.Z., Kan, Q.H. Constitutive models for uniaxial time-dependent ratcheting of SS304 stainless steel, Mechanics of Materials, 2007, 39(5),488-499.
[148] Kang, G.Z., Zhang, J., Sun, Y.F., Kan, Q.H. Experimental study on uniaxial time-dependent ratcheting of SS304 stainless steel at elevated temperatures, Journal of Iron and Steel, International, 2007, 14(1), 53-59.
Kang G.Z., Kan, Q.H., Zhang, J., Sun, Y.F. Time-dependent ratcheting experiments of SS304 stainless steel. International Journal of Plasticity, 2006, 22(5), 858-894.
[149] Kang, G.Z., Li, Y.G., Gao, Q., Qianhua Kan., Zhang, J. Uniaxial ratchetting in steels with different cyclic softening/hardening behaviours, Fatigue &Fracture of Engineering Materials and Structures,2006,29(2),93-103.
[150] Kang GZ, Kan QH, Zhang J. Experimental study on the uniaxial cyclic deformation of 25CDV4.11 steel. Journal of Materials Science and Technology, 2005, 21(1), 5-9.
[1] In December 2017, she was an excellent instructor of engineering practice projects in the Key Laboratory of Southwest Jiaotong University for undergraduates in 2017.
[2] In January 2019, excellent instructor award of international undergraduate mechanics competition, Chen Qianhua.
[3] He is an excellent instructor of the second "power on cup" National Science and technology translation competition in 2019.11 and 019.
Team leader: Professor Kang Guozheng
Research team leader: Kan Qianhua
Group photo of team teachers
Team photo of teachers and students