陈颂英
发布时间:2017-11-12 22:54:12    作者:    点击:[]
姓名 陈颂英
性别

                              undefined

出生年月 1966.10
行政职务 所长
学历 博士研究生 学位 博士
专业技术职务及任导师情况  教授,博士研究生导师
所在一级学科名称  动力工程及工程热物理
所在二级学科名称  化工过程机械

学术身份

教育部过程装备与控制工程专业教学指导委员会委员


学术兼职

中国流体工程学会会员,全国喷射设备标准化技术委员会委员

 

国内外学习和工作经历

1984.9—1988.7   浙江大学化工系毕业,获化工机械及工业企业管理双学士学位
1988.7—2000.9  山东工业大学环境与化学工程学院化工机械教研室  教师
2000.9—        必赢唯一官方网站过程装备与控制工程研究所  教师
期间:
1994.9—1997.7  山东工业大学力学研究所固体力学方向  获工学硕士学位
2002.2—2005.6   浙江大学化工机械研究所流体机械方向  获工学博士学位
2013.12—2014.12  美国特拉华大学机械系访问学者

 

主讲课程

本科生:《工程流体力学》;《过程流体机械》
硕士研究生:《高等流体力学》;《湍动力学》;《离心泵流体力学》;《计算流体力学》
博士研究生:《流体力学数值方法》


研究领域
过程流体机械内流分析及结构优化, 计算流、固体力学, 金属材料腐蚀


承担科研项目情况


代表性项目

(1)国家自然科学基金面上项目,52176040,反假塑性流体搅拌洞穴演化及混沌特性研究,2022/01-2025/12,58万,主持。

(2)国家自然科学基金面上项目,51176102,低压自激脉冲空化射流的空泡运动及打击特性研究,2012/01-2015/12,60万元,主持。

(3)国家基金委山东联合基金   U2006221,反渗透海水淡化装置系统节能关键技术基础研究,2021/01-2024/12,110万,主持。

(4)国家质检总局科技计划项目,2011QK235,基于应力腐蚀断裂的承压设备材料在氯离子环境中失效判据研究,2012/06-2014/12,120万,主持。

(5)国家重点基础研究发展计划(973)项目,2011CB013401,机械装备再制造的基础科学问题课题一,再制造对象的多强场、跨尺度损伤行为与机理,可再制造的临界阈值,2011/11-2016/11,252万,参与,负责腐蚀课题。

(6)国家高技术研究发展计划(863),2009AA044802-02,复杂腐蚀环境承压设备的材料选择、结构优化、焊接工艺筛选及热处理优化技术,2010/09-2011/08,20万,参与,负责碳素钢高温水腐蚀研究。

(7)山东省科技攻关计划项目,2008GG10007008,非均相自激脉冲射流防沉降系统研究,2008/11-2010/10,15万,主持。

(8)山东省重点研发计划,2016GGX104018,机械零部件基于腐蚀疲劳损伤的绿色再制造临界阈值的研究,2016/01-2017/12,20万,主持。

(9)山东省重点研发计划,2019GGX102058,高温电容模块的超薄聚丙烯薄膜研发,15万,2019/01-2020/12,参与,第二位次。

(10)山东省教育厅专业学位研究生案例库,SDYAL20010,面向新旧动能转换的计算流体力学全英文教学案例库建设,2021/01-2022/12,5万,主持。

(11)山东省自然科学基金面上基金,ZR2021ME161,高压自激脉冲空化射流消除机械构件残余应力机理研究,2022/01-2024/12,10万,主持。

(12)烟台市“双百计划”蓝色产业领军人才团队项目,智能化浮动式海上平台高压注水泵关键技术研究   2020/09-2023/08,120万,主持。

(13)淄博市重点研发计划(市外校城融合)项目,2020XCCG0160,高纯氧化铝高效绿色脱钠技术装备研发,2020/03-2021/12,25万,参与,第二位次。


论文、专利 


近年来发表的一作与通讯论文

(1) Review on stress corrosion and corrosion fatigue failure of centrifugal compressor impeller[J]. Chinese Journal of Mechanical Engineering, 2015, 28(2): 217-225. (SCI)

(2) Experimental study on stress corrosion crack propagation rate of FV520B in carbon dioxide and hydrogen sulfide solution[J]. Results in physics, 2016, 6: 365-372. (SCI)

(3) Experimental study on the stress corrosion cracking behavior of AISI347 in acid chloride ion solution[J]. Results in physics, 2016, 6: 690-697. (SCI)

(4) Improving lattice Boltzmann simulation of moving particles in a viscous flow using local grid refinement[J]. Computers & Fluids, 2016, 136: 228-246. (SCI)

(5) Effects of temperature and pressure on stress corrosion cracking behavior of 310S stainless steel in chloride solution[J]. Chinese Journal of Mechanical Engineering, 2017, 30(1): 200-206. (SCI)

(6) A computational study on gas–liquid flow in a lime slurry pond equipped with a rotary jet mixing system[J]. Advances in Mechanical Engineering, 2017, 9(2): 1687814017690468. (SCI)

(7) Orthogonal experimental research on the structural parameters of a self-excited pulsed cavitation nozzle[J]. European Journal of Mechanics-B/Fluids, 2017, 65: 179-183. (SCI)

(8) Numerical investigation of multiphase flow in flue gas desulphurization system with rotary jet stirring[J]. Results in physics, 2017, 7: 1274-1282. (SCI)

(9) Numerical investigation on the prefabricated crack propagation of FV520B stainless steel[J]. Results in physics, 2017, 7: 3738-3743. (SCI)

(10) Experimental study on electrochemical corrosion of FV520B in natural gas environment[J]. Results in physics, 2017, 7: 4405-4411. (SCI)

(11) Analysis on the stress corrosion crack inception based on pit shape and size of the FV520B tensile specimen[J]. Results in Physics, 2018, 9: 463-470. (SCI)

(12) Experimental investigation on the stress corrosion cracking of FV520B welded joint in natural gas environment with ECP and SSRT[J]. Engineering Fracture Mechanics, 2018, 200: 166-174. (SCI)

(13) A review of CFD modelling studies on the flotation process[J]. Minerals Engineering, 2018, 127: 153-177. (SCI)

(14) Numerical investigation on the stress corrosion cracking of FV520B based on the cohesive zone model[J]. Results in Physics, 2019, 12: 118-123. (SCI)

(15) Study on different line gasoline blending with RJM via numerical investigation[J]. Results in Physics, 2019, 12: 1285-1290. (SCI)

(16) A lattice Boltzmann study of the collisions in a particle-bubble system under turbulent flows[J]. Powder Technology, 2020, 361: 759-768. (SCI)

(17) Experimental study on the frequency characteristics of self-excited pulsed cavitation jet[J]. European Journal of Mechanics-B/Fluids, 2020, 83: 66-72. (SCI)

(18) Experimental study on stress corrosion of X12Cr13 stainless steel in natural gas environment[J]. Journal of Materials Research and Technology, 2020, 9(3): 3064-3074. (SCI)

(19) A review on hydrodynamic cavitation disinfection: The current state of knowledge[J]. Science of the Total Environment, 2020, 737: 139606. (SCI)

(20) Research on parameterization and optimization procedure of low-Reynolds-number airfoils based on genetic algorithm and Bezier curve[J]. Advances in Engineering Software, 2020, 149: 102864. (SCI)

(21) Particle-resolved direct numerical simulation of collisions of bidisperse inertial particles in a homogeneous isotropic turbulence[J]. Powder Technology, 2020, 376: 72-79. (SCI)

(22) Numerical investigation on distribution characteristics of oxidation air in a lime slurry desulfurization system with rotary jet agitators[J]. Chemical Engineering and Processing-Process Intensification, 2021, 163: 108372. (SCI)

(23) Disinfection characteristics of an advanced rotational hydrodynamic cavitation reactor in pilot scale[J]. Ultrasonics Sonochemistry, 2021, 73: 105543. (SCI)

(24) Effect of the cavitation generation unit structure on the performance of an advanced hydrodynamic cavitation reactor for process intensifications[J]. Chemical Engineering Journal, 2021, 412: 128600. (SCI)

(25) Numerical study on the flow characteristics of centrifugal compressor impeller with crack damage[J]. Advances in Mechanical Engineering, 2021, 13(7): 16878140211034622. (SCI)

(26) A comparison of different methods for estimating turbulent dissipation rate in under-resolved flow fields from synthetic PIV images[J]. Chemical Engineering Research and Design, 2021, 175: 161-170. (SCI)

(27) Numerical investigation of ozone decomposition by self-excited oscillation cavitation jet[J]. Open Physics, 2022, 20(1): 94-105. (SCI)

(28) Experimental study of Taylor bubble flow in non-Newtonian liquid in a rectangular microchannel[J]. Chemical Engineering Science, 2022, 252: 117509. (SCI)

(29) The finite element modeling of the impacting process of hard particles on pump components[J]. Open Physics, 2022, 20(1): 596-608. (SCI)

(30) Numerical Study on Entropy Generation of the Multi-Stage Centrifugal Pump[J]. Entropy, 2022, 24(7): 923. (SCI)

(31) Numerical analysis of internal flow characteristics and energy consumption assessment in full flow field of multi-stage centrifugal pump considering clearance flow[J]. Advances in Mechanical Engineering, 2022, 14(9): 16878132221123423. (SCI)

(32) Theoretical and Numerical Research on Heat Transfer Mechanism and Temperature Characteristics of Electric Rotary Alumina Kiln[J]. Journal of Thermal Science and Engineering Applications, 2022, 14(12): 121002. (SCI)

授权发明专利

(1) 一种旋转射流混合器,201110268093.2

(2) 粉体气力混合系统,201310078322.3

(3) 一种旋转门用鞋底清洁装置,2018 1 0764676.6

(4) 一种有机废水超声及水力空化联合处理装置,201910253868.5

(5) 一种通过油水混合制备调和润滑油的水力空化装置,201910253859.6

(6) 一种有机废水三级水力空化处理系统,201910253854.3

(7) 一种低速状态下微气泡产生装置,201910253856.2

(8) 一种水力空化式海水或苦咸水的淡化装置,201910253858.1

(9) 一种失活污泥降解水力空化装置,201910641010.6

(10) 强化纤维素纸浆精炼生产的空化装置,202011439434.3

(11) 耦合水力空化、声空化与光催化的抗生素废水处理装置,202010757495.8

(12) 一种农药废水芬顿试剂与水力空化联合处理系统,201910253866.6

(13) 基于涡激效应的一体化耦合压电发电装置,202011032434.1

(14) 空化于起泡一体化尾矿浮选装置,202011439436.2

(15) 催化剂载体及微通道连续流反应器,202010066883.1

(16) 一种旋流梯度剪切流场石墨烯剥离装置,201910253862.8


获奖情况

2001.10 边界轮廓法理论及应用研究

山东省高校优秀科研成果三等奖 第二位,主要贡献为断裂力学边界轮廓法的研究

2002.11 高速离心式氯气压缩机设计与工业化应用

浙江省科技进步二等奖 第一位

2015.09 搅拌与射流耦合诱发假塑性流体混沌混合特性研究

山东省高校优秀科研成果三等奖 第二位

 



联系方式

手机号码:15628826922
联系电话:0531-88392378
电子邮箱:chensy66@sdu.edu.cn
QQ号码:1913834633

 

上一条:高玉飞 下一条:郭年程

关闭

Copyright ©2017-2020 bwin·必赢(macau)唯一官方网站-made in china All rights reserved.
办公地址:山东省济南市经十路17923号必赢唯一官方网站千佛山校区 邮编:250061 电话:0531-88392608 传真:0531-88392608 [网站管理]