紫金矿业集团 福州大学 网站首页

库建刚 -- 教授 --博士研究生

职务: 工会主席
专业: 矿物加工工程
电子邮件: kkcc22@163.com
研究方向: 磁选理论;密度泛函;微磁学;磁性材料;磁选装备;3D仿真

教育工作经历

Main experience

2017.07-至今    福州大学紫金地质与矿业学院,教授、硕士、博士生导师
2016.12-2017.12    英国帝国理工学院地球科学与工程系,访问学者
2010.06-2017.06    福州大学紫金地质与矿业学院,讲师、副教授,硕士生导师
2007.10-2010.05    河南灵宝金源矿业博士后工作站,博士后
2003.09-2007.10    昆明理工大学矿物加工工程专业,博士
2001.09-2003.07    昆明理工大学矿物加工工程专业,硕士
1997.09-2001.07    黑龙江科技大学选矿工程专业,学士

教学简介

Main experience

主讲本科生课程《物理分选》,研究生课程《多物理场建模与分析》和《物理分选技术与装备》。承担福建省教研项目1项,福州大学教研项目8项,其中重点2项,发表教研教改论文6篇,学院第二届“我心目中的好老师”。指导国家级大学生创新创业训练项目2项,福建省大学生创新创业训练项目2项。国家级教学成果二等奖(第7)、福建省高等教育成果奖特等奖(第7)。

科研简介

Main experience

从事磁选理论、微磁学模拟、密度泛函计算、磁选分离过程模拟及高梯度磁选机关键技术等研究。主持国家自然科学基金3项、福建省自然科学基金2项、企业委托重点项目3项,国家重点实验室基金及企业委托项目12项,参与国家重点研发计划、国家自然科学基金及省级重大专项5项。获中国机械工业科技进步二等奖1项(第3);发表学术论文120余篇,被SCI、EI检索60余篇;申请发明专利21项,已获授权11项;参与出版专著2部。

社会兼职

Main experience

山东省智能磁电装备与选矿技术重点实验室副主任,福建省能源金属绿色提取与高值利用重点实验室副主任,中国工程院咨询专家,中国科协科技人才评审专家,福建省科技奖会评专家,福建省应急管理专家,江西省科技奖会评专家,《IJMST》青年编委,中国矿业大学学报青年编委,《当代化工研究》编委,《有色金属(选矿部分)》中青年专家委员会委员,中国有色金属学会会员,美国化学学会会员,国家自然科学基金(海外/面上/国际)通讯评审专家,Nature Communication, Minerals Engineering, Journal of Applied Physics, Nanoscale, Powder Tech, 中国有色金属学报及中国矿业大学学报中英版等期刊审稿人。

科研项目

Main experience

23.超导强磁场磁选设备研发及产业化[JDKY202602],重点专项,2026-2028,在研,主持
22.弱磁性矿物分选用大型智能磁电装备研发及产业化发[2025CXGC010204],山东省重点研发计划(重大科技创新工程),2025.6-2028.6,在研,参与,子课题负责人
21.微细粒级钛尾矿磁选高效分离技术开发[2025091501],2025-2027,在研,主持
20.超大型强磁场高梯度磁选装备关键技术研究及细粒弱磁性矿物高效分离技术开发[2024112802],2025-2027,在研,主持
19.永磁旋转磁场筒式磁选机中磁性颗粒群动力学行为[BGRIMM-KJSKL-2025-04],国家重点实验室开放基金,2025-2027,结题,主持
18.磁铁矿颗粒的三维动态磁化特性及其动力学研究[52174245],国家自然科学基金面上项目,2022-2025,结题,主持
17.基于动态磁矩磁偶极子模型的磁团聚动力学研究及模拟仿真[51674091],国家自然科学基金面上项目,2017-2020,结题,主持
16.以磁链理论模型为基础的磁团聚机理研究[51104048],国家自然科学基金青年,2012-2014,结题,主持
15.磁铁矿颗粒在变化磁场中的三维动态磁化特性及精确磁力计算[2021J01640],福建省自然科学基金,2021-2024,结题,主持
14.基于动态磁矩的磁团聚实验研究及流体动力学模拟[2017J01483],福建省自然科学基金,2017-2020,结题,主持
12.大型高梯度磁选装备新型介质盒研制及微细粒锂矿磁选技术开发[2023032702],2023-2025,结题,主持
12.“紫金-华特”磁电与智能选矿实验平台,山东华特磁电科技股份有限公司,2023-2024,结题,主持
11.细颗粒磁性矿干式分选过程模拟仿真[BGRIMM-KJSKL-2021-02],国家重点实验室开放基金,2021-2022,结题,主持
10.微细磁铁矿颗粒群的磁团聚机理研究及其模拟仿真,国家重点实验室开放基金,2022-2023,结题,参与
9. 基于磁选柱磁团聚结构转化过程分析及颗粒分离机理研究,北矿机电科技有限公司,2021-2022,结题,主持
8. 多颗粒磁铁矿干式磁选过程模拟仿真研究,北矿机电科技有限公司,2022-2023,结题,主持
7. 块状磁铁矿干式磁选过程仿真及分选指标预测研究,北矿机电科技有限公司,2020-2021,结题,主持
6. 以“磁链理论”模型为基础的磁团聚机理研究,福州大学启动基金,2011-2013,结题,主持
5. 稀散金属富集及纯化过程基础研究[2021YFC2902801];国家重点研发计划,2022-2024,结题,参与
4. 绿色轻固结尾矿基地质聚合物的胶凝差异和重金属固定机理研究[51974093],国家自然科学基金面上项目,2020-2023,结题,参与
3. 高压电脉冲破碎技术预处理堆浸原矿的应用基础研究[51604084],国家自然科学基金青年,2017-2019,结题,参与
2. 多金属氧化钼矿综合利用关键技术研究,河南省重大科技专项,2008-2010,第二
1. 不规则矿粒在高粘度基载液中运动阻力测定,人才引进,2011-2013,结题,主持

代表性论文

Main experience

[47] D. Wang, H. Lin, R. Wang, J. Ku*, Z. Shen, Magnetic properties of ferromagnetic FeCr alloys on particle-magnetic field interaction in high-gradient magnetic separation. Minerals Engineering, 2026, 247: 110479. (SCI, 2区, IF=6.0)
[46] Z. Hu, D. Lu, J. Ku, H. Chang; X. Wang; X. Zheng, Significant improvement in dry high-gradient magnetic separation efficiency via radial airflow: From theory to practice. Separation and Purification Technology, 2026, 386: 136505. (SCI, 2区, IF=9.1)
[45] H. Lin, Y. Xie, Q. Wang, H. Shang, J. Ku*, Z. Shen, Effect of slurry velocity on particle–fluid interaction in high gradient magnetic field. Minerals Engineering, 2026, 237: 109980. (SCI, 2区, IF=6.0)
[44] Y. Xie, D. Wang, F. Liu, H. Shang, Z. Hu, J. Ku*, Mesoscopic quantification of magnetic exchange interactions and magneto-crystalline anisotropy based on density functional theory: First realization of visual characterization by micromagnetic simulation on hematite. Journal of Magnetism and Magnetic Materials, 2026, 655: 174248. (SCI, 3区, IF=3.0)
[43] L. Zhan, Q. Wang, J. Ku*, H. Shang, Z. Shen, Purification technologies for high-purity quartz: from mineralogy to applications, Separation and Purification Reviews, 2026, 55(2): 209-226. (SCI, 2区, IF=5.6)
[42] H. Lin, Y. Xie, Q. Wang, H. Shang, J. Ku*, Z. Shen, Effect of slurry velocity on particle–fluid interaction in high gradient magnetic field. Minerals Engineering, 2026, 237: 109980. (SCI, 2区, IF=5.0)
[41] D. Wang, Y. Xie, Q. Wang, Z. Hu, Q. Yan, J. Ku*, Z. Shen, Magnetic Properties of low Magnetic Anisotropy Magnetic Materials for High-Gradient Magnetic Separation. Minerals Engineering, 2026, 235: 109820. (SCI, 2区, IF=5.0)
[40] Y. Xie, Q. Wang, H. Shang, J. Ku*, Z. Shen, the origin of magnetism in crystals and the techniques for characterizing magnetic structures: From microscopic ions to macroscopic magnetic expressions. Coordination Chemistry Reviews, 2025, 525: 216342. (SCI, 1区, Top, IF=25.6)
[39] H. Shang, G. Li, T. Wang, Y. Zhao, J. Ku*, Z. Shen, Calculation of magnetic force between magnetite particles in a low-intensity magnetic separator: A 3D finite element method. Phys. Prob. Miner. Process., 2025, 61(6): 215950. (SCI, 4区, IF=1.5)
[38] D. Wang, J. Ku, Z. Lei, X. Li, J. Yan, Q. Wang, The application of multi-scale magnetic matrix materials in high-gradient magnetic separation: From micro- and nano- to millimeter-scale. Journal of Central South University, 2025, 32: 1299–1326. (SCI, 2区, IF=4.7)
[37] J. Ku, X. Shi, Q. Wang, H. Lin*, H. Shang* and Z. Shen, Efficient exploitation of lepidolite resources: A review on beneficiation techniques, extraction methods, and synergistic optimization. Separations, 2025, 12: 130. (SCI, 3区, IF=3.5)
[36] D. Wang, Y. Xie, Q. Wang, Z. Hu, Q. Yan, J. Ku*, Magnetic properties of low magnetic anisotropy magnetic materials for high-gradient magnetic separation. Minerals Engineering, 2025, 235: 109820. (SCI, 2区, IF=6.0)
[35] J. Ku, J. Yan, J. Xia*, Z. Wang, Q. Yan, L. Zhan, M. Wang*, Manipulating three-dimensional magnetic particles motion in a rotating magnetic field. Powder Technology, 2025, 449: 120391. (SCI, 2区,Top, IF=5.5)
[34] X. Wang, Y. Xie, Q. Wang, H. Shang, Z. Hu, J. Ku*, Z. Shen, Removal and separation of iron and carbon from kaolin: A review. Powder Technology, 2025, 458: 120939. (SCI, 2区,Top, IF=5.5)
[33] X. Yu, L. Zhan, X. Wang, M. Wang, J. Ku*, Spatial magnetic force and magnetic energy density analysis of microsphere medium in high gradient magnetic fields: A 3D simulation. Phys Scripta, 2025, 100: 015513. (SCI, 3区, IF=2.6)
[32] J Ku, X. Shi, Q. Wang, H. Lin*, H. Shang*, Z. Shen, Efficient exploitation of lepidolite resources: A review on beneficiation techniques, extraction methods, and synergistic optimization. Separations, 2025, 12: 130. (SCI, 3区, IF=3.5)
[31] J. Ku, X. Yu, J. Xia, Q. Wang, Z. Wang, Z. Lei, Study of the dynamics of magnetic particles in rotating magnetic field: A 3D finite element analysis. Physicochemical Problems of Mineral Processing, 2025, 61(1): 199981. (SCI, 4区, IF=1.5)
[30] Z. Lei, J. Yan, Y. Xie, L. Yang, Q. Wang, J. Ku*, Kinetic study of dry magnetic separation based on Gauss-Maxwell magnetic stress tensor: A 3D finite element method (FEM). Minerals Engineering, 2024, 218: 109409. (SCI, 2区, IF=4.9)
[29] X. Li, Z. Wang, Z. Lei, W. Ding, X. Shi, J. Yan, J. Ku*, Accurate calculation of magnetic forces on irregular magnetic mineral particles using micromagnetic simulations. Minerals Engineering, 2024, 218: 109001. (SCI, 2区, IF=4.9)
[28] J. Ku*, K. Wang, Q. Wang, Z. Lei*, Application of magnetic separation technology in resource utilization and environmental treatment. Separations, 2024, 11(5): 2297-8739. (SCI, 4区, IF=2.5)
[27] J. Ku*, X. Li, Z. Wang, Q. Wang, F. Xue*, Spin orientation evolution of individual ferromagnetic nanoparticle during reversing magnetization processes revealed by micromagnetic simulations. Journal of Applied Physics, 2024, 136: 033901. (SCI, 3区, IF=2.7)
[26] X. Li, Z. Wang, Z. Lei, W. Ding, X. Shi, J. Yan, J. Ku*, Magnetic characterization techniques and micromagnetic simulations of magnetic nanostructures: from zero to three dimensions. Nanoscale, 2023, 15: 19448-19468. (SCI, Top, IF=6.7)
[25] H. Lin, X. Li, Z. Lei, J. Ku*, Z. Wang* Developing high gradient magnetic separators for greener production: Principles, design, and optimization. Journal of Magnetism and Magnetic Materials, 2023, 587:171260. (SCI, IF=3.0)
[24] 赵一飞, 冉红想, 晏全香, 库建刚*.基于磁偶极子公式的磁化球间磁力计算误差及新公式推导: A 3D-FEM, 中国矿业大学学报, 2023, 52: 1022-1029. (EI)
[23] H. Lin, H. Ran, S. Zhong, J. Ku*, Review on nucleation and growth behavior of iron grain during deep reduction. Powder Technology, 2023, 424: 118531. (SCI, Top, IF=5.64)
[22] Y. Zhu, B. Guo, W. Zuo, H. Chen*, J. Ku*, Effect of sintering temperature on structure and properties of porous ceramics from tungsten ore tailings. Materials Chemistry and Physics, 2022, 287: 126315. (SCI, Top, IF=4.091)
[21]王凯文, 黄景华, 朱羽, 库建刚*. 添加造孔剂法制备钨尾矿多孔陶瓷, 高校化学工程学报, 2022, 36: 716-725. (EI)
[20] J. Ku*, Z. Lei, H. Lin, Q. Yan, H. Chen, B. Guo, Interaction of magnetic spheres in magnetic fields from the view of magnetic energy density: A 3D finite element analysis (FEA). International Journal of Mining Science and Technology., 2022, 171: 107113. (SCI, IF=4.765)
[19] J. Xia, Z. Lei, Q. Wang, J. Ku*, Q. Yan* Comparison of various forces acting on magnetic particles in a low-intensity magnetic field: A 3D FEA. Powder Technology, 2022, 401: 117351. (SCI, Top, IF=5.134)
[18] J. Ku, Z. Lei, J. Xia, B. Guo, H. Chen*, X. Peng, H. Ran, R. Deng*, Dynamic behavior and separation prediction of magnetic ore bulks in dry medium-intensity magnetic separator. Minerals Engineering, 2021, 171: 107113. (SCI, IF=4.765)
[17] J. Ku, J. Xia, J. Li, X. Peng, B. Guo*, H. Ran*, Accurate calculation of major forces acting on magnetic particles in a high-gradient magnetic field: A 3D finite element analysis. Powder Technology, 2021, 394: 311-325. (SCI, Top, IF=5.134)
[16] J. Ku, L. Zhang, W. Fu, S. Wang, W. Yin, H. Chen*, Mechanistic study on calcium ion diffusion into fayalite: a step toward sustainable management of copper slag. Journal of Hazardous Materials, 2020, 410: 124630. (SCI, Top, IF=9.038)
[15] L. Zhang, H. Chen, R. Deng, W. Zuo, B. Guo, J. Ku*, Growth behavior of iron grains during deep reduction of copper slag. Powder Technology, 2020, 367: 157-162. (SCI, Top, IF=4.142)
[14] L. Zhang, Y. Zhu, W. Yin, B. Guo, F. Rao, J. Ku*, Isothermal coal-based reduction kinetics of fayalite in copper slag. ACS Omega, 2020, 5(13), 6300-6400. (SCI, IF=4.132)
[13] J. Long, Z. Miao, H. Chen, R. Deng, W. Zuo, B. Guo, J. Ku*. Analysis of magnetic particle agglomeration structure and interaction forces between magnetic particles. Journal of Magnetics, 2020, 25(1), 15-21. (SCI, IF=0.551)
[12] B. Guo, X. Lin, W. Fu, J. Ku*. Establishment of electrochemical methods to examine the adsorption of flotation surfactants onto a mineral surface. Journal of Chemical Technology and Biotechnology, 2020, 95(5), 1300-1311. (SCI, IF=3.709)
[11] H. Chen*, J. Ku*, L. Wang*, Thermal catalysis under dark ambient conditions in environmental remediation: Fundamental principles, development, and challenges. Chinese Journal of Catalysis, 2019, 40(8), 1117-1134. (SCI, Top, IF=8.271)
[10] H. Chen, W. Fu, Y. Xing, L. Zhang, J. Ku*. Engineering SrCuxO composition to tailor the degradation activity toward organic pollutants under dark ambient conditions. Environmental Science and Pollution Research, 2019, 26(16), 16449-16456. (SCI, IF=0.78)
[9] 库建刚, 李来超, 邓荣东, 晏全香, 左蔚然. 稀土料液除杂实验研究及固液分离技术探讨, 稀土, 2018, 39(4): 86-95. (EI)
[8] R. Deng, W. Zuo, J. Ku*, Z. Yang, Y. Hu, Synthesis of a cationic organic silicone surfactant and its application in the flotation of smithsonite. International Journal of Mineral Processing, 2017, 167: 113-121. (SCI, 三区, IF=2.688)
[7] J. Ku*, W. Wu, R. Deng, W. Zuo, W. Yin, Simplified magnetic induction field of magnetite particles with irregular shape. IEEE Transactions on Magnetics, 2019, 55(1), 7400105. (SCI三区, IF=1.63)
[6] J. Ku*, X. Liu, H. Chen, R. Deng, Q. Yan, Interaction between two magnetic dipoles in a uniform magnetic field. AIP Advances, 2016, 6(2): 025004. (SCI, IF=1.653)
[5] J. Ku*, H. Chen, K. He, Q. Yan, Preparation and properties of epoxy resin-coated micro-sized ferrosilicon powder. Mater Res., 2016, 19(4): 889-894. (SCI, IF=1.103)
[4] 库建刚*, 陈辉煌, 何逵, 晏全香. 强磁性矿粒在磁选过程中的受力分析及动力学模拟, 中南大学学报(自然科学版), 2015, 46(5): 1577-1582. (EI)
[3] J. Ku*, H. Chen, K. He, Q. Yan, Simulation and observation of magnetic mineral particles aggregating into chains in a uniform magnetic field. Minerals Engineering, 2015, 79: 10-16. (SCI, 二区, Top, IF=1.813)
[2] J. Ku*, H. Chen, K. He, L. Xu, Q. Yan, Numerical simulation of agglomeration process dynamics of ferromagnetic mineral particles in a weak magnetic field. International Journal of Mineral Processing, 2014, 133: 46–51. (SCI, 三区, IF=1.617)
[1] 库建刚*, 刘羽, 刘文元, 刘树林, 何逵. 河南卢氏花岗伟晶岩的矿物学特征及综合利用, 中国有色金属学报, 2014, 24(2): 491–498. (EI)

获奖情况

Main experience

个人荣誉
202502,紫金矿业集团(世界500强)二等功;
202410,机械工业科学技术二等奖(R3);
202206,福州大学优秀硕士学位论文指导教师;
202006,福建省优秀硕士学位论文指导教师;
201909,福州大学教学优秀奖;
201809,国家级教学成果二等奖(R7);
201809,福州大学第一届“福能”奖教金;
201709,福建省教学成果特等奖(R7);
201607,福州大学“厦航”奖教金;
201506,福州大学杰出青年教师励志奖;
201409,福州大学优秀共产党员;
201205,福州大学五四青年奖章;
201110,福州大学学术新人奖;
201011,灵宝市先进知识分子称号。
指导学生:
国家奖学金3人;福建省优秀硕士学位论文3篇,福州大学优秀硕士学位论文8篇;
“互联网+”大学生创新创业竞赛福建省金奖1项,福建省大学生创新大赛银奖,福州大学创业之星大赛银奖;福州大学优秀新生奖学金特等2人、一等3人、二等3人;
福州大学华特磁电等奖学金10人,福州大学优秀学业奖学金一等2人、二等3人;福州大学优秀本科生毕业设计3人;福州大学研究生助研奖学金19人。

其他

Main experience

发明专利:
(1) 全自动无人值守精确化补加钢球机器人系统及其工作方法202410469178.4
(2) 高梯度磁选机介质丝组件[202323212772.5]
(3) 抗流态化介质件排布结构[202410429104.8]
(4) 高梯度磁选机介质丝组件[202323212772.5]
(5) 梯度增强型磁选介质盒[202310893489.9]
(6) 微细粒嵌布的锂矿磁选回收方法[202311588930.9]
(7) 铁锂云母矿的粗选预富集方法[202411211675.0]

友情提示:常年招收具有矿加、物理及材料背景的硕士、博士研究生及博士后。有意向者可发送个人简历至邮箱:kkcc22@163.com;15080093186。
指导硕士、博士研究生34人,其中硕士毕业20人,硕士在读10人,博士毕业1人,在读2人,协助指导博士、硕士4人。