联系方式:0459-6504527电子邮箱:zhaowanchun@nepu.edu.cn
赵万春,男,汉族,1978年12月出生,博士生导师,校优秀青年教师,中共党员。2002年毕业于最权威的全网担保平台石油与天然气工程专业,获工学学士学位。2005年毕业于最权威的全网担保平台油气储运工程专业,获工学硕士学位。2009年毕业于最权威的全网担保平台油气井工程专业,获工学博士学位。2018年于澳大利亚莫纳什大学访问一年。2020年最权威的全网担保平台地质资源与地质工程博士后科研流动站出站博士。现任非常规油气研究院副经理、直属党支部书记与“陆相页岩油气成藏及高效开发”教育重点实验室副主任,黑龙江省科技创新团队“断裂变形、封闭性及流体运移”(负责可压性及可采性评价)骨干成员,SPE会员,国家自然科学基金评审专家,黑龙江省自然科学基金评审专家,河北省自然科学基金评审专家。
多年来一直从事页岩油气、致密砂岩油气及煤层气等非常规油气储层地质工程一体化及压裂改造高效开发理论与技术等方面的研究工作。主持页岩油层交替混合压裂诱导及竞争耦合造缝与参数调控机制研究与页岩局部脆性表征与压裂裂缝交互耦合演化机制研究项目;参与页岩油藏脉动水力压裂缝网实时扩展AE演化机制研究、页岩气藏压裂突变特征及多重分形缝网逾渗演化研究;主持页岩压裂岩体局部脆性破裂与缝网演化多重分形特征研究、煤岩脆塑性表征与岩体压裂突变破裂演化机理研究等诸多科研项目。主持国家自然科学基金项目3项(1青年+2面上),作为研究骨干参加国家自然科学基金项目3项。主持国家博士后科学基金项目2项,黑龙江省博士后“青年英才”计划入选者。主持并参与省部级科研项目18项,局级及横向课题40余项。发表科研学术论文90余篇,其中,被SCI检索论文26篇(1作和通讯22篇),被EI收录论文24篇(1作和通讯),申报并授权国际专利1项,国家专利41项(其中发明专利34项),获省部级科技进步一等奖1项,二等奖2项,获批软件著作权6项,撰写行业标准和规范2项,相关研究成果入选石油工程岩石力学协会2021年“十大科技进展”。《石油勘探与开发》、《岩石力学与工程》等十几个期刊审稿人,第一届油气开发创新技术国际研讨会特邀报告,第一届石油工程岩石力学论坛研讨会秘书长,第二届石油工程岩石力学论坛青年委员会成员。
长期从事油页岩油气、地质工程一体化、水力压裂、裂缝网络和油气井工程的教学与研究工作,提出了基于突变理论的岩石脆性和可压性的评价方法、压裂造缝岩石破裂模式与裂缝非线性演化逾渗特征、岩石局部脆性概念并研究了其对整体缝网控制机理与基于分数阶岩石变形诱导套管柱破坏理论及预防控制措施,其中各研究方向申请者共计撰写与发表学术论文46篇,SCI/EI收录论文共36篇,申报和授权发明专利13项。主讲本科生课程2门、研究生课程3门。自2009年以来先后指导博士研究生6人,硕士研究生23人,指导在校员工正式发表科技论文1-2篇/人。主持省部级教改项目1项,参加省部级教改项目3项,发表教改论文15篇,获得省部级教学成果奖2项,厅局级教学成果奖2项,正式出版国家级教材4部,发表相关论文40余篇。
截至目前共计发表论文96篇,其中近五年发表论文28篇,SCI收录期刊论文25篇(1作/通讯21篇),EI检索JCR 1区2篇,多篇发表在岩石力学顶级期刊和石油领域国际权威期刊上,得到了同行们的广泛引用。其中部分代表性论文如下:
[1] Tingting Wang, Tao Zhang, P.G. Ranjith, Yuwei Li, Zhenlong Song, Sheng Wang, Wanchun Zhao. A new approach to the evaluation of rock mass rupture and brittleness under triaxial stress condition[J]. Journal of Petroleum Science and Engineering, 2020. 183(05): 123-132.(通讯作者,SCI 2区TOP, IF:4.346,他引次数:12,WOS:000501599800012)
[2] Wanchun Zhao, Jing Ge, Ranjith Pathegama Gamage, Yuwei Li , Zhenlong Song, Tingting Wang. Study of Deformation Law of Casing Local Lateral Collapse Based on the Principle of Virtual Work[J]. energies, 2019, 12(19): 2173-2180. (SCI, Q3区,影响因子:3.004,他引次数:2,WOS:000498072600128)
[3] Wang, Sheng;Zhao, Wanchun;Fu, Xiaofei; Zhang, Ziming; Wang, Tingting; Ge, Jing (2020). A universal method for quantitatively evaluating rock brittle-ductile transition behaviors[J]. Journal of Petroleum Science and Engineering, 2020, 12(19): 2173-2180. (SCI, Q3区,影响因子:4.346,他引次数:3,WOS:000586002900133)
[4] Yuwei Li , Min Long, Lihua Zuo , Wei Li , Wanchun Zhao. Brittleness evaluation of coal based on statistical damage and energy evolution theory[J]. Journal of Petroleum Science and Engineering, 2019, 172:753-763. (通讯作者,SCI, Q3区,,影响因子:4.346,他引次数:75,WOS:000447888300068)
[5] Zhao, Wanchun; Ge, Jing; Wang, Tingting; Zhang, Hao; Li, Yuwei. Study on catastrophe mechanism of hydraulic fracturing fracks initiation in radial boreholes[J]. Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 2020, 6(3). (SCI, Q3区,影响因子:4.50,他引次数:1,WOS:000548671600001)
[6] Tingting Wang , Zhang, H. , Ranjith Pathegama Gamage. , Wanchun Zhao , Ge, Jing. The evaluation criteria for rock brittleness based on double-body analysis under uniaxial compression[J]. Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 2020, 6(3):1-19. (SCI, Q3区,通讯作者,影响因子:4.50他引次数:1,WOS:000552199300001)
[7] Zhao, Wanchun; Ge, Jing; Ranjith, Pathegama Gamage; Wang, Tingting; Han, Lijie. An Approach to Calculating Casing Bearing Capacity with Parabolic Deformation Characteristics Under Local Radial Loading[J]. Energies, 2020, 13(7),1769. (SCI, Q3区,影响因子:3.004,他引次数:0,WOS:000537688400238)
[8] Wang, Zhengbo; Wang, Qiang; Ma, Desheng; Zhao, Wanchun; Feng, Xiaohan; Liu, Zhaoxia. The Fast Potential Evaluation Method of Enhanced Oil Recovery Based on Statistical Analysis[J]. Processes, 2019,7(11), 795–805. (SCI, Q4区,通讯作者,影响因子:2.847,他引次数:2,WOS:000502263700021)
[9] Zhao, Wanchun. , Feng, Xiaofei. , Wang, Tingting. Study on fracture distribution and local brittleness characteristics based on stepwise regression method[J]. Geofluids, 2021(4), 1-12. (SCI, Q2区,影响因子:2.067,他引次数:0,WOS:000693135300004)
[10] Wanchun Zhao . Yu Liu . Tingting Wang . P. G. Ranjith . Yufeng Zhang. Stability analysis of wellbore for multiple weakness planes in shale formations[J]. Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 2021, 7(2),1-13. (SCI, Q2区,通讯作者,影响因子:4.50他引次数:2,WOS:000697389200003)
[11] Zhao W , Li X , Wang T , et al. Pore size distribution of high volatile bituminous coal of the southern Junggar Basin: a full-scale characterization applying multiple methods[J]. Frontiers of Earth Science, 2020(3),1-19. (SCI, Q3区,影响因子:2.031,他引次数:1,WOS:000603533500001)
[12] Liu C , Zhao W , Sun L , et al. Geochemical assessment of the newly discovered oil-type Shale in the Shuangcheng area of the northern Songliao Basin, China[J]. Journal of Petroleum Science and Engineering, 2020, 196(1):107755. (SCI, Q2区,影响因子:4.346,他引次数:0,WOS:000600808100093)
[13] Zhao W , Wang Z , Song Z , et al. Experimental exploration of damage propagation in rocks using acoustic emission[J]. Bulletin of Engineering Geology and the Environment, 2021, 80(8):1-11. (SCI, Q3区,影响因子:4.298,他引次数:0,WOS:000664551200001)
[14] Chao Liu,Wanchun Zhao, Lidong Sun, Ying Zhang, Xuehai Chen, Jijun Li.An improved ΔlogR model for evaluating organic matter abundance.[J]. Journal of Petroleum Science and Engineering, 2021, 109016.(SCI, Q3区,影响因子:4.346,他引次数:1,WOS:000664551200001)
[15] Zhang, Hui; Wang, Zhizhang; Ruan, Baotao; Li, Zhongcheng;Zhao, Wanchun;Ranjith, Pathegama Gamage; Wang, Tingting . A brittleness evaluation method of rock constitutive relationship with Weibull distribution based on double-body system theory[J]. Energy Science & Engineering,2020, 8(9), 3333–3347. (通讯作者SCI, Q3区,影响因子:4.170,他引次数:4,WOS:000549805000001)
[16] Tingting Wang, Yu Liu, Meng Cai,Wanchun Zhao;P.G.Ranjith, Liu Ming Optimization of rock failure criteria under different fault mechanisms and borehole trajectories[J] Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 2022, 7(2),1-13. (SCI, Q2区,通讯作者,影响因子:4.50他引次数:2,WOS:000824877200003)
[17]Ai chi,Zhao Wanchun.Casing Collapse Strenth Reduction under ateral Loads from Yielding Shales in Daqing oilfield. Drilling and Completion, 2008,Vol23, 348-352, .SCI收录
[18] Tingting Wang, Chi Ai,Wanchun Zhao, etal. Study on Characteristics of Stress Field around the Crack-tip of Volume Fracturing Based on Chaos Theory. International Journal of Simulation Systems, Science & Technology. Vol.17, No.25, EI收录, 2016
[19]Tingting Wang, Chi Ai,Wanchun Zhao, etal. Modeling Mutation Rupture Fracturing and Groups of Micro-Cracks Evolution in Coal and Rock Mass. International Journal of Simulation Systems, Science & Technology. Vol.17, No.27, EI收录, 2016
[20] Wang Tingting, Li Tianyou,Zhao Wanchun. Stabilization Control via Dynamic Feedback of Three-dimensional Chained Nonholonomic Systems. Progress in Engineering and Science, Vol.42, No.6, pp2360-2363, EI收录, 2017
[21]Wang Tingting, Li Tianyou,Zhao Wanchun. Acoustic Emission Signal Processing of Rock Mass Failure Based on Wavelet Packet Decomposition. Progress in Engineering and Science, Vol.42, No.8, pp3493-3499, EI收录, 2017
[22]Wang Tingting, Li Tianyou,Zhao Wanchun. Study on decomposition of acoustic emission signal and identification of rock mass fracture. Journal of Computational Methods in Sciences and Engineering, Vol.17, No.4, pp745~756, EI收录, 2017
[23]Zhao Wanchun,Wang Tignting,Fu Xiaofei,etal. The study of fracturing rock body damage and cracks propagation model basing on catastrophe theory,Open Petroleum Engineering Journal, v7, n1, p64-70,EI收录,2014
[24]Zhao Wanchun,Wang Tignting,Wang Chen,etc.Numerical Simulation for heat- Fluid- solid of Reservoir Rock under Water Injection;International Journal of Applied Mathematics & Statistics, v50, p 549-557. EI收录,2013
[25Zhao Wanchun,Wang Tignting,Wang Chen, etc. Numerical Simulation and Analysis for Permeability of Rock Mass under hydraulic Fracturing, International Journal of Applied Mathematics & Statistics, v50, p533-540, EI收录,2013
[26]赵万春,王婷婷,付晓飞,官兵.水力压裂岩体损伤破裂折迭突变模型研究与应用.岩石力学与工程学报, 33(S2): 3406-3411. EI收录,2014
[27]赵万春,艾池,李玉伟,郭柏云.基于损伤理论双重孔隙介质水力压裂岩体劣化与孔渗特性理论研究,岩石力学与工程学报,S2:3490~3496. EI收录,2009
[28]Zhao Wanchun, Wang Tignting, Zhang Jingbo,ect.The Stress Calculation of Refracturing Based on Damage Theory, Applied Mechanics and Materials I, v275-277,p 332-335. EI收录,2013
[29]Zhao Wanchun, Wang Tignting, Sun Chengyan.Study on the mechanism model of fracture propagation based on the Energy theory.Advanced materials and processes II, v557,p 2333-2336. EI收录,2012
[30]Zhao Wanchun, Wang Chen, Wang Tingting. Calculation Model Study on Damaging Stress of Hydraulically Created Fracture Propagation,Advanced materials and processes II, v275-277, p 238-241, EI收录,2013
[31]Zhao Wanchun,Ou, Yangyong,SunChenyan;.The study of fracturing crack propagation regulation based on information entropy theory, Advanced Materials and ProcessesII, v557-559,p 2329-2332, EI收录,2012
[32]Zhao Wanchun, Wang Tignting, Sun Chengyan. Study on Linear Calculation Method for the Refracturing Total Stress Field, Progress in Structures, v166-169,p3052-3055,EI收录,2012
[33]Zhao Wanchun, Sun Chengyan,Wang Tignting.The Stress Distribution And Calculation Of The Different Zone Of Wellbore Surrounding Rock Based On The Damaged Theory, Progress in Civil Engineering, v170-173, p 1052-1055, EI收录,2012
[34]Zhao Wanchun,Wang Junfa, Sun Chengyan.The Numerical Simulation Calculation Of Complicated In-Situ Stress Filed For Borehole Surrounding Rock,Progress In Civil Engineering, v170-173, p 1048-1051, EI收录,2012
[35] Zhao Wanchun, Sun Chengyan ,Wangchen,etc.Study damage of rock and evolvement of porosity and permeability under hydraulic fracture in Ji Lin oilfiled,v4,p2763-2767,SPE132052, EI收录,2010
[36]Zhao Wanchun, Wang Tingting, Ju Guoshuai. The Study On Fractal Damage Of Rock Under Hydraulic Fracturing Basing On Conversation Of Energy, Applied Mechanics and Materials Engineering, v29-32, p 1363-1368, EI收录,2010
[37]Zhao Wanchun,Ai Chi, Zheng Dachun.The Damage Theory Model on Fluid-solid-heat Coupling of Reservoir under Process Injection, Applied Mechanics and Materials Engineering, v29-32, p 2053-2058, EI收录,2010
[38]Zhao Wanchun, Wang Tignting, Sun Chengyan. The Damage Mechanics Model Of The Sidewall Rock Under The Effect Of Shear Stress, Advanced Materials And Processes II, v557-559, p 2406-2409, EI收录,2012
[39]Zhao Wanchun, Wang Tignting. Model of Initiation Angle Under Hydraulic Refracturing ICBBE, 2010 4th International Conference on Bioinformatics and Biomedical Engineering, EI收录,2014
[40]Zhao Wanchun, Wang Tignting, Ai Chi.The study and application of Gray-Orthogonal Wavelet Network Forecasting Mode on Cementing Quality, ICEE2010, p5327-5330, EI收录, 2010
[41]Zhao Wanchun, Wang Tignting, Ai Chi. A New Definition On Fractal Porous Rock Damage Variable And Study On Evolution Characteristics Of Porosity-Permeability,ICEE2010, p 5031-5034, EI收录,2010
[42]Zhao Wanchun, Wang Tignting, Ju Guoshuai, Mechanical Determination Of Re-fracture Well Create New Fracture, Applied Mechanics and Materials Engineering, v29-32, p 1369-1373, EI收录,2010
[43] Zhao Wanchun, Ai Chi, The Study Of Permeability Change Of Fractal Under Fracturing Basing On Damage Theory, ICIE 2010, 2010 v3, p 92-95, EI收录,2010
[44]Zhao Wanchun,Wang tingitng.Micro-crack damage evolution of fracturing rock Chaotic characteristics,International Conference on E-Business and E-Government,EI, International Conference on Electrical and Control Engineering, ICECE 2010,p1268-1271, EI收录,2010
[45] Ting-tingWang*,Wan-chun Zhao, Yuan-hong etal.Study on Micro-fracture Chaotic Evolution under External Loading Rock,Metallurgy Technology and Materials II,v813, p355-358, EI收录,2013
[46] Tingting Wang,Wanchun Zhao, Dan Zhao, Dongfeng Jiang. Study on Chaos Features of Fracture Network Evolution in Coal-Rock under Hydrofracture, Science an Technology Research Association, EI收录,2014
[47] Tingting Wang, Tianyou Li,Wanchun Zhao, Mingjun Li, Three-dimensional chained Nonholonomic Systems Stabilization Control Via Dynamic Feedback,Science an Technology Research Association, EI收录,2014
[48]Zhao Wanchun,Wang tingting ,Yuan weiwei.The Damage Folding Mutation Model Of Fracturing Rock Mass On The Oil-gas Reservoir,Journal of theoretical and application information technology,Vol47NO.2,pp697-701,2013
[49] Tingting Wang,Wanchun Zhao,Keyong Shao, Huizhen Zhang.Global K-exponential Stabilization of Nonholonomic Chained Systems,International Journal of Petroleum Science and Technology, 8(1):pp1-9,2014
[50]Zhao Wanchun, Yuan weiwei ,Wang tingitng .Model of cementing annulus gas channing based on the lattice boltzmann theory,Journal of theoretical and application information technology, Vol.48NO.2, pp888-892.,2013
[51] Wang Tingting,Wang Chen,Zhang Jingbo,Zhao Wanchun*.The Study of Rock Body Damage Constitutive Model on Refracturing. Advances in Petroleum Exploration and Development,6(2),pp1-3. 2013
[52] Tingting Wang, Chen Wang, Wanchun Zhao*, etal. The model for calculating pore evaluation of fractal rock body under hydraulic fracturing. Advances in Petroleum Exploration and Development,7(1),pp52-56. 2014
[53] Chen Wang ,Tingting Wang,Wanchun Zhao*,etal. Gas Flow Model of Adhesion Sand Casing Well First Interface Micro Clearance and Application. Advances in Petroleum Exploration and Development,7(1),pp34-37. 2014
[54] Wang Chen,Gao Xuezhen,Zhao Wanchun*. The Study of Rock Body Damage Constitutive Model in Multiple Fracturing, Advances in Petroleum Exploration and Development,7(2), pp64-67. 2014
[55] Zhao Wanchun*, Wang Tingting,Sun Chengyan, etal. Fold Catastrophe Model Of Fracture Propagation Of Hydraulic Fracturing, Advances in Petroleum Exploration and Development, 7(2), pp106-109, 2014
[56]艾池,赵万春,郭柏云,杨东梅.压裂裂缝起裂角模型研究.石油钻采工艺. 04:89-93, 2009
[57]王婷婷,赵万春,官兵.基于格子boltzmann方法固井环空介观微间隙气体窜槽研究.数学的实践与认识. 24:202-207. 2013
[58]王婷婷,赵万春,艾池等.双重孔隙渗流作用井眼围岩损伤力学模型研究,数学的实践与认识,2014.
[59]赵万春,曾佳,王婷婷等.基于虚功原理建立套管外挤力学模型.力学与实践. Vol.38, No.5. 2016,
[60]王婷婷,赵丹,赵万春等.煤岩体压裂分形损伤突变演化模型的研究及应用.数学的实践与认识, Vol.46, No.13, 2016.
[61]王婷婷,艾池,赵万春等.煤岩体压裂裂缝演化混沌特征研究.数学的实践与认识, Vol.46, No.19. 2016.
[62]王婷婷,艾池,赵万春等.双重孔隙渗流作用井眼围岩损伤力学模型研究.数学的实践与认识, Vol.46, No.6. 2016.
[63]赵万春,马云朋,王婷婷等.不同脆性岩石的声发射特征.岩性油气藏, Vol.29, No.4. 2017.
[64]王婷婷,何俊才,赵万春等.基于声发射岩体压裂损伤演化特征研究.数学的实践与认识, Vol.47, No.6. 2017.
截至目前,共计申报并授权国际专利1项,国家专利41项(其中发明专利34项),获批软件著作权6项,其中部分授权发明专利情况如下:
1、一种描述外载作用岩体微细观破裂与微裂隙形成的方法,中国,CN201811006299.6,排序1
2、一种模拟多重注采井网注采关系的压裂造缝实验装置,中国,CN202010774106.2,排序1
3、模拟局部脆性特征功能性压裂岩心制作与裂缝监测装置,中国,CN202010774095.8,排序1
4、模拟多重注采井网注采关系的含天然裂缝压裂造缝装置,中国,CN202010774761.8,排序1
5、一种制备多样裂缝岩心的装置及其制备方法,中国授权,CN201810933548.X,排序2
6、一种研究岩体孔隙及裂隙结构与座逾渗特征的方法及装置,中国,CN201610387241.5,排序1
7、一种制备多样裂缝岩心的装置及其制备方法,中国,CN201810933548.X,排序2
8、一种描述外载作用岩体微细观破裂与微裂隙形成的方法,中国,CN201811006299.6,排序1
9、一种研究岩体孔隙及裂隙结构与座逾渗特征的方法及装置,中国,CN201610387241.5,排序1
10、制备内含孔裂隙及水平井段的透明岩心的装置及制备方法(国际专利),中国,CN201510248369.9,排序1
11、套管外表面自动喷砂装置,中国,ZL 201210373048.8,排序1
12、多相位套管粗糙表面一体化制备装置,中国,ZL 201210373024.2,排序1
13、研究多级压裂支撑剂分形粒度与岩体断裂特征参数的方法,中国,ZL 201210255366.4,排序1
14、油田固井套管外表面自动粘胶-粘砂装置,中国,ZL201210373070.2,排序1
15、钻井循环系统综合模拟实验装置,中国,ZL201210329359,排序4
16、研究压裂液配置及岩体断裂分形特征测定装置,中国,ZL201210255350.3,排序1
17、基于突变理论研究压裂岩体损伤及裂缝扩展的装置及方法,中国,ZL201410006040.7,排序1
18、节理煤岩切割岩样装置,中国,ZL201510248372.0,排序1
19、透明岩心中模拟水平井井筒的制备装置及制备方法,中国,ZL201510248372.0,排序2
20、岩体内含孔隙裂隙结构的制备装置及制备方法,中国,ZL201510248371.1,排序2
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