教师名录

吴鹏教授博士生导师,硕士生导师
所在院系:机械制造及自动化系
办公室:机械楼217
电话:
邮箱:101013707@seu.edu.cn
个人简介

   

吴鹏,bat365平台体育app官网,教授/博导,医学装备系副主任。从事医工交叉的研究工作,长期致力于血流动力学模拟方法、血液损伤机制及模型构建研究,及其在血泵设计和评估、心血管疾病诊疗中的应用。提出的诸多核心算法获得了学术界的关注和采用,利用这些原创性成果,指导了国内首款全磁悬浮人工心脏的优化设计,并成功临床应用,救治了二百余名心衰危重患者;联合中国食品药品检定研究院,面向新一代人工心脏的设计和评估,发展了磁悬浮血泵基准模型和测试平台;成功对主动脉夹层、冠脉瘘、深静脉血栓、房颤患者内心耳内血栓形成等多种心血管疾病的预防、诊断及治疗给予了理论支持和指导。和国际人工心脏研究的著名团队亚琛工业大学心血管工程研究所开展了长期交流和合作,对人工心脏研究的前沿方向有良好的把握。

2015年以来,先后主持国家自然科学基金项目 3项,包括青年项目、面上项目和中德合作项目,以及多项医工交叉合作项目。 2019年以来, 以一作/通讯作者在领域内权威期刊如Biomechanics and Modeling in MechanobiologyArtificial OrgansComputer Methods and Programs in BiomedicineiScienceSoft Robotics等发表 SCI期刊论文 22篇,授权发明专利 19项。获中国发明创业奖创新奖二等奖(排名1)、江苏省力学学会科学技术奖一等奖(排名1)等奖项。担任中国生物医学工程学会机械循环支持分会委员、中国机械工程学会流体传动与控制分会特种流控专业委员会委员、江苏省力学学会生物力学专业委员会委员,担任领域内二十余种权威期刊的审稿人,多个领域内权威期刊的客座编辑。

课题组基础研究和工程应用并重,科研活跃,经费充足,文章、专利产出较多。有出国交流机会。欢迎感兴趣的优秀学子加入团队。


学习经历
工作经历

2024.01-现在,     bat365平台体育app官网,bat365平台体育app官网江苏省微纳生物医疗器械设计与制造重点实验室,教授

2014.01-2024.01苏州大学,机电工程学院,人工器官研究所副教授、教授、副所长

2015.07-2015.102016.06-2016.09德国亚琛工业大学心血管工程研究所访问学者

2012.10-2013.12,比利时Numeca International(布鲁塞尔)主任工程师

2006.08-2007.12,德国海德堡大学,交叉学科高性能计算研究中心(IWR),研究助理



教授课程
流体力学


研究方向
1、人工心脏流体力学和血液损伤设计关键技术及应用;2、基于血流动力学的心脑血管疾病无创诊断方法研究;3、仿生流体力学及流体机械。
审稿期刊

担任领域内二十余种权威期刊的审稿人。

学术兼职

中国生物医学工程学会机械循环支持分会,委员

中国机械工程学会流体传动与控制分会特种流控专业委员会,委员

江苏省力学学会生物力学专业委员会,委员


获奖情况

中国发明创业奖创新奖二等奖,2024(排名1)

江苏省力学学会科学技术奖一等奖,2024(排名1)

江苏省力学学会先进个人,2020

苏州市魅力科技团队,2018

江苏省“双创计划”人才项目,2014

苏州市高等院校、科研院所高层次紧缺人才计划,2014



论文著作

SCI期刊论文(第一&通讯作者)

人工心脏

  • Wu P*, Xiang WJ, Zhang KJ, Du GT (2024) Turbulentflow field in maglev centrifugal blood pumps of CH-VAD and HeartMate III: secondaryflow and its effects on pump performance, Biomechanics and Modeling in Mechanobiology, https://doi.org/10.1007/s10237-024-01855-1.

  • Wu P*, Bai YQ, Du GT, Zhang LD, Zhang XY (2023) Resistance valves in circulatory loops have a significant impact on in vitro evaluation of blood damage caused by blood pumps: a computational study, Frontiers in Physiology, 14:1287207. doi: 10.3389/fphys.2023.1287207.

  • Wu P*, Wu ZJ, Chen HB, Chen ZS, Zhang XW, Yang M (2023) Editorial: Recent advances in the design and preclinical evaluation of ventricular assist devices, Frontiers in Physiology, 14:1322077. doi: 10.3389/fphys.2023.1322077.

  • Xiang WJ, Wu WT*, Wu P* (2023) Influence of inlet boundary conditions on the prediction of flow field and hemolysis in blood pumps, Bioengineering, 10(2):274.

  • Wu P*, Huo JD, Zhang ZJ, Wang CJ* (2022) The influence of non-conformal grid interfaces on the results of large eddy simulation of centrifugal blood pumps, Artificial Organs, 46(9): 1804-1816.

  • Mei X, Lu B, Wu P*, Zhang LD* (2022) In vitro study of red blood cell and VWF damage in mechanical circulatory support devices based on blood-shearing platform, Proceedings of IMechE Part H: Journal of Engineering in Medicine, 236(6):860-866.

  • Wu P*, Xiang WJ, Yin CK* and Li S* (2021) The design and evaluation of a portable extracorporeal centrifugal blood pump, Frontiers in Physiology, 12:766867. doi: 10.3389/fphys.2021.766867.

  • Huo JD#, Wu P#*, Zhang LD, Wu WT* (2021) Large eddy simulation as a fast and accurate engineering approach for the simulation of rotary blood pumps, International Journal of Artificial Organs, 44(11):887-899.

  • Wu P*, Huo JD, Dai WF, Yin CK*, Li S* (2021) On the optimization of a centrifugal maglev blood pump through design variations, Frontiers in Physiology, 12:699891. doi:10.3389/fphys.2021.699891.

  • Wu P*, Zhang LD, Gao Q, Dai WF (2021) Effect of turbulent inlet conditions on the prediction of flow field and hemolysis in the FDA ideal medical device, Proceedings of IMechE Part H: Journal of Mechanical Engineering Science. 235(2):391-401.

  • Dai WF, Wu P*, Liu GM* (2021) A two-phase flow approach for modeling blood stasis and estimating the thrombosis potential in ventricular assist devices, International Journal of Artificial Organs, 44(7): 471-480.

  • Wu P*, Gross-Hardt S, Boehning F, Hsu PL (2020) An energy-dissipation-based power law formulation for estimating hemolysis. Biomechanics and Modeling in Mechanobiology, 19:591-602.

  • Wu P*, Gao Q, Hsu PL (2019) On the representation of effective stress for computing hemolysis. Biomechanics and Modeling in Mechanobiology, 18:665-679.

  • Wu P*, Boehning F, Gross-Hardt S, Hsu PL (2018) On the accuracy of hemolysis model in Couette-type of shearing devices, Artificial Organs, 42(10): E290–E303.

心脑血管血流动力学

  • Wang L, Jiang XD, Zhang KJ, Chen K, Wu P*, Li XQ* (2024) A hemodynamic analysis of energy loss in abdominal aortic aneurysm using three-dimension idealized model, Frontiers in Physiology, 15: 1330848.

  • Jiang XD#, Xiang GY#, Du GT, Du XL*, Wu P*, Li XQ* (2023) A hemodynamic analysis of fenestrated physician-modified endograft repair for complicated aortic dissections involving the visceral arteries, Computer Methods and Programs in Biomedicine, 242:07785.

  • Zhang ZJ#, Zhu JD#, Wu M*, Wu WT, Wu P* (2023). Computational modeling of hemodynamics and risk of thrombosis in the left atrial appendage using patient-specific blood viscosity and boundary conditions at the mitral valve, Biomechanics and Modeling in Mechanobiology, 22(4):1447-1457.

  • Jiang XD, Cao HY, Zhang ZJ, Zheng TH, Li XQ, Wu P* (2022). A hemodynamic analysis of the thrombosis within occluded coronary arterial fistulas with terminal aneurysms using a blood stasis model, Frontiers in Physiology, 13:906502. doi: 10.3389/fphys.2022.906502.

  • Jiang XD#, Li Da#, Wu P*, Li XQ, Zheng TH* (2022) A two-fluid blood stasis model for false lumen thrombosis after type B dissection repair, Computer Methods in Biomechanics and Biomedical Engineering, 25(13):1499-1508.

  • Jiang XD#Gu XP#Xu TZ, Li XQ*, Wu P*, Sun LL* (2022) Patient-specific hemodynamic analysis of IVCS-induced DVT, Computer Methods in Biomechanics and Biomedical Engineering, 25(11): 1211-1221.

仿生与智能流体力学

  • Hua Y, Yu CH, Zhao Q, Li MG, Wu WT*, Wu P* (2023) Surrogate modeling of heat transfers of nanofluids in absorbent tubes with fins based on deep convolutional neural network, International Journal of Heat and Mass Transfer, 20: 123736.

  • Liu GC, Jiang YG*, Wu P*, Ma ZQ, Chen HW, Zhang DY (2022). Artificial Whisker Sensor with Undulated Morphology and Self-Spread Piezoresistors for Diverse Flow Analyses, Soft Robotics, 10(1):97-105.

  • Jiang YG*, Zhao P, Cai XF, Dong ZH, Chen HW, Wu P*, Hu HY, Jin XX, Zhang DY, Liu H* (2022) Bristled-wing design of materials, microstructures, and aerodynamics enables flapping flight in tiny wasps, iScience, 25(1): 103692.

  • Wu P, Feng ZB, Cao SJ* (2018) Fast and accurate prediction of airflow and drag force for duct ventilation using wall-modeled large-eddy simulation, Building and Environment, 141: 226-235.

  • Wu P, Meyers J* (2013) A constraint for the subgrid-scale stresses in the logarithmic region of high Reynolds number turbulent boundary layers: a solution to the log-layer mismatch problem, Physics of Fluids, 25, 015104.

  • Wu P, Meyers J* (2011) Globally conservative high-order filters for large-eddy simulation and computational aero-acoustics, Computers & Fluids, 48(5):150-162. 2011.

其他期刊论文(第一&通讯作者)

  • 徐健,陈凯,王相权,肖华伟,王铃,吴鹏*复合型形态学特征联合流体力学对肾下型腹主动脉瘤破裂风险的评估202433(2)102-107

  • 张子健,余晴阳,邓业林,吴鹏*考虑叶轮与蜗壳间隙的风机多因素正交优化设计, 流体机械,2023, 51(6):26-32.

  • Wu P* (2022). Recent advances in the application of computational fluid dynamics in the development of rotary blood pumps, Medicine in Novel Technology and Devices, 16: 100177.

  • 陆斌,张柳笛*,梅旭,尹成科,蒋秋波,郇娜娜,吴鹏*, 基于新型磁悬浮Taylor-Couette血液剪切平台研究VWF损伤规律, 医用生物力学, 2022, 37(4):699-705

  • 江旭东,许天泽,孙莉莉,李晓强*吴鹏*, 髂静脉狭窄所致侧支循环与下肢深静脉血栓之间关联的血流动力学研究, 医用生物力学, 2022,37(1):105-111

  • 王晨,徐博翎,吴鹏*, 叶片倒角对FDA标准血泵流场和溶血预测的影响, 医用生物力学, 2019,34(1):57-63

  • Wu P, Meyers J* (2012) An improved blending formulation for wall-modeled large-eddy simulations, Progress in Hybrid RANS-LES Modelling (Editors: S Fu, W Haase, SH Peng and D Schwamborn), Springer, ISBN 978-3-642-31817-7, 111-120, 2012. EI



科研项目
专利

PCT国际发明专利:

  • 白宇峤,赵翔宇,毛新元,吴鹏,张柳笛. 一种阻力阀.申请号:PCT/CN2023/ 074209

国家发明专利:

  • 白宇峤,赵翔宇,毛新元,吴鹏,张柳笛. 一种阻力阀.申请号:202310027918.4

  • 尹成科, 吴鹏, 戴伟峰. 一种离心泵,申请号202110205984.7

  • 吴鹏, 郑庭辉, 吴思齐. 一种血液瘀滞预测方法及系统,专利号ZL202010929347.X,授权日期:20230811

  • 柳光茂,吴鹏,胡盛寿,尹成科. 一种磁悬浮血泵装置,申请号202010629153.8

  • 刘星利,魏润杰,高琪,吴鹏. 一种血流储备分数评估方法及装置、存储介质,专利号ZL 201910894411.2,授权日期:20230530

  • 王辉山,魏润杰,刘涛,鲁云霞,高琪,吴鹏. 一种路线规划方法、终端及存储介质, 专利号ZL 201910574719.9,授权日期:20210309

  • 王辉山,魏润杰,刘涛,黄利忠,高琪,吴鹏. 一种信息处理方法和装置、及可读存储介质, 专利号ZL201910491017.4,授权日期:20210108

  • 魏润杰,樊红光,郑哲,李其杰,高琪,吴鹏. 一种模型的分离方法、装置、终端和计算机存储介质,ZL201910310086.0. 授权日期:20210914

  • 魏润杰,王洪平,高琪,吴鹏. 一种壁面切应力优化方法及装置、存储介质,专利号ZL 201910127951.8,授权日期:20210511

  • 魏润杰,王洪平,高琪,吴鹏. 一种血流量的确定方法、装置、电子设备和计算机存储介质,专利号ZL 201910103229.0,授权日期:20210108

  • 魏润杰,李博文,高琪,吴鹏. 一种血管提取方法、装置及计算机可读存储介质, 专利号ZL 201910073353.7,授权日期:20210108

  • 高琪,黄利忠,吴鹏,魏润杰. 一种冠脉搭桥参数的确定方法、装置、设备和存储介质, 专利号ZL201811614134.7,授权日期:20210108

  • 魏润杰,黄利忠,高琪,吴鹏. 评估血流储备分数的系统、方法、设备及存储介质, 专利号ZL 201811296891.4 ,授权日期:20220809

  • 高琪,樊红光,郑哲,金熳夙,吴鹏,魏润杰. 一种左心耳复杂度的确定方法,装置及计算机存储介质,  ZL201811261668.6,授权日期:20210810

  • 魏润杰,吴鹏,刘星利,高琪. 血流储备分数确定系统、方法、终端及存储介质,专利号ZL201811119677.1,授权日期:20220201

  • 魏润杰,王洪平,高琪,吴鹏. 一种评估血流储备分数的方法及装置、设备、存储介质,ZL201810983737.8,授权日期:20220311

  • 魏润杰,高琪,李博文,吴鹏. 一种血管提取的方法、装置及存储介质, 专利号ZL201810936725.X,授权日期:20210108

  • 魏润杰,吴鹏,刘星利,高琪. 一种确定冠状动脉血流储备分数FFR的方法和装置, 专利号ZL 201810568691.3,授权日期:20210810

  • 魏润杰,王虎峰,高琪,吴鹏,李飞,王巍.一种医疗图像的处理方法、装置及计算机存储介质, 授权号 ZL201810534684.1,授权日期:20201208

  • 魏润杰,高琪,刘星利,吴鹏,李飞,王巍.一种血流速度的修正方法、装置、终端和计算机存储介质, ZL201810517956.7,授权日期:20220412

  • 吴鹏,边玉成,吴思齐.一种基于能量耗散的溶血经验预测方法及装置,专利号 ZL201711274526.9,授权日期:20210518

  • 吴鹏, 潘志刚, 尹成科. 磁悬浮泵用叶轮、泵头、叶轮设计方法. 发明专利. 专利号ZL202311126829.1,授权日期:2024126

实用新型专利

  • 潘志刚尹成科磁悬浮泵用叶轮、泵头及磁悬浮泵实用新型专利,授权号ZL202322380476.X,授权日期:20231219

  • 余晴阳,吴鹏,邓业林.一种离心式风机蜗壳结构,专利号:ZL202121430026.1,授权日期:20220118

  • 柳光茂,吴鹏,胡盛寿,尹成科.一种磁悬浮血泵装置,专利号ZL202021271409.4,授权日期:20210305

  • 吴鹏,张坤. 可穿戴辅助投篮装置,专利号:ZL201720980556.0,授权日期:20180302


软件著作权

  • 三维不可压缩大涡模拟计算程序FLOWAVE,登记号2018SR206022,完成人:吴鹏,著作权人:苏州大学

  • Ansys流体仿真流程自动化和远程计算软件,登记号2022SR0456157,完成人:白宇峤,赵翔宇,吴鹏,著作权人:苏州大学

  • Ansys流体仿真的流程自动化和数据管理软件,登记号2022SR0456150,完成人:白宇峤,赵翔宇,吴鹏,著作权人:苏州大学

  • 基于速度系数法的磁悬浮离心式血泵叶轮参数设计软件,登记号2023SR0920385,完成人:董志成,毛新元,白宇峤吴鹏,张柳笛,著作权人:苏州大学


吴鹏 生物流体力学, 人工心脏, 流体机械
Tel:
Email:101013707@seu.edu.cn
Add:
Personal Introduction

   

吴鹏,bat365平台体育app官网,教授/博导,医学装备系副主任。从事医工交叉的研究工作,长期致力于血流动力学模拟方法、血液损伤机制及模型构建研究,及其在血泵设计和评估、心血管疾病诊疗中的应用。提出的诸多核心算法获得了学术界的关注和采用,利用这些原创性成果,指导了国内首款全磁悬浮人工心脏的优化设计,并成功临床应用,救治了二百余名心衰危重患者;联合中国食品药品检定研究院,面向新一代人工心脏的设计和评估,发展了磁悬浮血泵基准模型和测试平台;成功对主动脉夹层、冠脉瘘、深静脉血栓、房颤患者内心耳内血栓形成等多种心血管疾病的预防、诊断及治疗给予了理论支持和指导。和国际人工心脏研究的著名团队亚琛工业大学心血管工程研究所开展了长期交流和合作,对人工心脏研究的前沿方向有良好的把握。

2015年以来,先后主持国家自然科学基金项目 3项,包括青年项目、面上项目和中德合作项目,以及多项医工交叉合作项目。 2019年以来, 以一作/通讯作者在领域内权威期刊如Biomechanics and Modeling in MechanobiologyArtificial OrgansComputer Methods and Programs in BiomedicineiScienceSoft Robotics等发表 SCI期刊论文 22篇,授权发明专利 19项。获中国发明创业奖创新奖二等奖(排名1)、江苏省力学学会科学技术奖一等奖(排名1)等奖项。担任中国生物医学工程学会机械循环支持分会委员、中国机械工程学会流体传动与控制分会特种流控专业委员会委员、江苏省力学学会生物力学专业委员会委员,担任领域内二十余种权威期刊的审稿人,多个领域内权威期刊的客座编辑。

课题组基础研究和工程应用并重,科研活跃,经费充足,文章、专利产出较多。有出国交流机会。欢迎感兴趣的优秀学子加入团队。


Educational Background

SCI期刊论文(第一&通讯作者)

人工心脏

  • Wu P*, Xiang WJ, Zhang KJ, Du GT (2024) Turbulentflow field in maglev centrifugal blood pumps of CH-VAD and HeartMate III: secondaryflow and its effects on pump performance, Biomechanics and Modeling in Mechanobiology, https://doi.org/10.1007/s10237-024-01855-1.

  • Wu P*, Bai YQ, Du GT, Zhang LD, Zhang XY (2023) Resistance valves in circulatory loops have a significant impact on in vitro evaluation of blood damage caused by blood pumps: a computational study, Frontiers in Physiology, 14:1287207. doi: 10.3389/fphys.2023.1287207.

  • Wu P*, Wu ZJ, Chen HB, Chen ZS, Zhang XW, Yang M (2023) Editorial: Recent advances in the design and preclinical evaluation of ventricular assist devices, Frontiers in Physiology, 14:1322077. doi: 10.3389/fphys.2023.1322077.

  • Xiang WJ, Wu WT*, Wu P* (2023) Influence of inlet boundary conditions on the prediction of flow field and hemolysis in blood pumps, Bioengineering, 10(2):274.

  • Wu P*, Huo JD, Zhang ZJ, Wang CJ* (2022) The influence of non-conformal grid interfaces on the results of large eddy simulation of centrifugal blood pumps, Artificial Organs, 46(9): 1804-1816.

  • Mei X, Lu B, Wu P*, Zhang LD* (2022) In vitro study of red blood cell and VWF damage in mechanical circulatory support devices based on blood-shearing platform, Proceedings of IMechE Part H: Journal of Engineering in Medicine, 236(6):860-866.

  • Wu P*, Xiang WJ, Yin CK* and Li S* (2021) The design and evaluation of a portable extracorporeal centrifugal blood pump, Frontiers in Physiology, 12:766867. doi: 10.3389/fphys.2021.766867.

  • Huo JD#, Wu P#*, Zhang LD, Wu WT* (2021) Large eddy simulation as a fast and accurate engineering approach for the simulation of rotary blood pumps, International Journal of Artificial Organs, 44(11):887-899.

  • Wu P*, Huo JD, Dai WF, Yin CK*, Li S* (2021) On the optimization of a centrifugal maglev blood pump through design variations, Frontiers in Physiology, 12:699891. doi:10.3389/fphys.2021.699891.

  • Wu P*, Zhang LD, Gao Q, Dai WF (2021) Effect of turbulent inlet conditions on the prediction of flow field and hemolysis in the FDA ideal medical device, Proceedings of IMechE Part H: Journal of Mechanical Engineering Science. 235(2):391-401.

  • Dai WF, Wu P*, Liu GM* (2021) A two-phase flow approach for modeling blood stasis and estimating the thrombosis potential in ventricular assist devices, International Journal of Artificial Organs, 44(7): 471-480.

  • Wu P*, Gross-Hardt S, Boehning F, Hsu PL (2020) An energy-dissipation-based power law formulation for estimating hemolysis. Biomechanics and Modeling in Mechanobiology, 19:591-602.

  • Wu P*, Gao Q, Hsu PL (2019) On the representation of effective stress for computing hemolysis. Biomechanics and Modeling in Mechanobiology, 18:665-679.

  • Wu P*, Boehning F, Gross-Hardt S, Hsu PL (2018) On the accuracy of hemolysis model in Couette-type of shearing devices, Artificial Organs, 42(10): E290–E303.

心脑血管血流动力学

  • Wang L, Jiang XD, Zhang KJ, Chen K, Wu P*, Li XQ* (2024) A hemodynamic analysis of energy loss in abdominal aortic aneurysm using three-dimension idealized model, Frontiers in Physiology, 15: 1330848.

  • Jiang XD#, Xiang GY#, Du GT, Du XL*, Wu P*, Li XQ* (2023) A hemodynamic analysis of fenestrated physician-modified endograft repair for complicated aortic dissections involving the visceral arteries, Computer Methods and Programs in Biomedicine, 242:07785.

  • Zhang ZJ#, Zhu JD#, Wu M*, Wu WT, Wu P* (2023). Computational modeling of hemodynamics and risk of thrombosis in the left atrial appendage using patient-specific blood viscosity and boundary conditions at the mitral valve, Biomechanics and Modeling in Mechanobiology, 22(4):1447-1457.

  • Jiang XD, Cao HY, Zhang ZJ, Zheng TH, Li XQ, Wu P* (2022). A hemodynamic analysis of the thrombosis within occluded coronary arterial fistulas with terminal aneurysms using a blood stasis model, Frontiers in Physiology, 13:906502. doi: 10.3389/fphys.2022.906502.

  • Jiang XD#, Li Da#, Wu P*, Li XQ, Zheng TH* (2022) A two-fluid blood stasis model for false lumen thrombosis after type B dissection repair, Computer Methods in Biomechanics and Biomedical Engineering, 25(13):1499-1508.

  • Jiang XD#Gu XP#Xu TZ, Li XQ*, Wu P*, Sun LL* (2022) Patient-specific hemodynamic analysis of IVCS-induced DVT, Computer Methods in Biomechanics and Biomedical Engineering, 25(11): 1211-1221.

仿生与智能流体力学

  • Hua Y, Yu CH, Zhao Q, Li MG, Wu WT*, Wu P* (2023) Surrogate modeling of heat transfers of nanofluids in absorbent tubes with fins based on deep convolutional neural network, International Journal of Heat and Mass Transfer, 20: 123736.

  • Liu GC, Jiang YG*, Wu P*, Ma ZQ, Chen HW, Zhang DY (2022). Artificial Whisker Sensor with Undulated Morphology and Self-Spread Piezoresistors for Diverse Flow Analyses, Soft Robotics, 10(1):97-105.

  • Jiang YG*, Zhao P, Cai XF, Dong ZH, Chen HW, Wu P*, Hu HY, Jin XX, Zhang DY, Liu H* (2022) Bristled-wing design of materials, microstructures, and aerodynamics enables flapping flight in tiny wasps, iScience, 25(1): 103692.

  • Wu P, Feng ZB, Cao SJ* (2018) Fast and accurate prediction of airflow and drag force for duct ventilation using wall-modeled large-eddy simulation, Building and Environment, 141: 226-235.

  • Wu P, Meyers J* (2013) A constraint for the subgrid-scale stresses in the logarithmic region of high Reynolds number turbulent boundary layers: a solution to the log-layer mismatch problem, Physics of Fluids, 25, 015104.

  • Wu P, Meyers J* (2011) Globally conservative high-order filters for large-eddy simulation and computational aero-acoustics, Computers & Fluids, 48(5):150-162. 2011.

其他期刊论文(第一&通讯作者)

  • 徐健,陈凯,王相权,肖华伟,王铃,吴鹏*复合型形态学特征联合流体力学对肾下型腹主动脉瘤破裂风险的评估202433(2)102-107

  • 张子健,余晴阳,邓业林,吴鹏*考虑叶轮与蜗壳间隙的风机多因素正交优化设计, 流体机械,2023, 51(6):26-32.

  • Wu P* (2022). Recent advances in the application of computational fluid dynamics in the development of rotary blood pumps, Medicine in Novel Technology and Devices, 16: 100177.

  • 陆斌,张柳笛*,梅旭,尹成科,蒋秋波,郇娜娜,吴鹏*, 基于新型磁悬浮Taylor-Couette血液剪切平台研究VWF损伤规律, 医用生物力学, 2022, 37(4):699-705

  • 江旭东,许天泽,孙莉莉,李晓强*吴鹏*, 髂静脉狭窄所致侧支循环与下肢深静脉血栓之间关联的血流动力学研究, 医用生物力学, 2022,37(1):105-111

  • 王晨,徐博翎,吴鹏*, 叶片倒角对FDA标准血泵流场和溶血预测的影响, 医用生物力学, 2019,34(1):57-63

  • Wu P, Meyers J* (2012) An improved blending formulation for wall-modeled large-eddy simulations, Progress in Hybrid RANS-LES Modelling (Editors: S Fu, W Haase, SH Peng and D Schwamborn), Springer, ISBN 978-3-642-31817-7, 111-120, 2012. EI



Professional Experience

中国生物医学工程学会机械循环支持分会,委员

中国机械工程学会流体传动与控制分会特种流控专业委员会,委员

江苏省力学学会生物力学专业委员会,委员


Teaching
Research Interests

PCT国际发明专利:

  • 白宇峤,赵翔宇,毛新元,吴鹏,张柳笛. 一种阻力阀.申请号:PCT/CN2023/ 074209

国家发明专利:

  • 白宇峤,赵翔宇,毛新元,吴鹏,张柳笛. 一种阻力阀.申请号:202310027918.4

  • 尹成科, 吴鹏, 戴伟峰. 一种离心泵,申请号202110205984.7

  • 吴鹏, 郑庭辉, 吴思齐. 一种血液瘀滞预测方法及系统,专利号ZL202010929347.X,授权日期:20230811

  • 柳光茂,吴鹏,胡盛寿,尹成科. 一种磁悬浮血泵装置,申请号202010629153.8

  • 刘星利,魏润杰,高琪,吴鹏. 一种血流储备分数评估方法及装置、存储介质,专利号ZL 201910894411.2,授权日期:20230530

  • 王辉山,魏润杰,刘涛,鲁云霞,高琪,吴鹏. 一种路线规划方法、终端及存储介质, 专利号ZL 201910574719.9,授权日期:20210309

  • 王辉山,魏润杰,刘涛,黄利忠,高琪,吴鹏. 一种信息处理方法和装置、及可读存储介质, 专利号ZL201910491017.4,授权日期:20210108

  • 魏润杰,樊红光,郑哲,李其杰,高琪,吴鹏. 一种模型的分离方法、装置、终端和计算机存储介质,ZL201910310086.0. 授权日期:20210914

  • 魏润杰,王洪平,高琪,吴鹏. 一种壁面切应力优化方法及装置、存储介质,专利号ZL 201910127951.8,授权日期:20210511

  • 魏润杰,王洪平,高琪,吴鹏. 一种血流量的确定方法、装置、电子设备和计算机存储介质,专利号ZL 201910103229.0,授权日期:20210108

  • 魏润杰,李博文,高琪,吴鹏. 一种血管提取方法、装置及计算机可读存储介质, 专利号ZL 201910073353.7,授权日期:20210108

  • 高琪,黄利忠,吴鹏,魏润杰. 一种冠脉搭桥参数的确定方法、装置、设备和存储介质, 专利号ZL201811614134.7,授权日期:20210108

  • 魏润杰,黄利忠,高琪,吴鹏. 评估血流储备分数的系统、方法、设备及存储介质, 专利号ZL 201811296891.4 ,授权日期:20220809

  • 高琪,樊红光,郑哲,金熳夙,吴鹏,魏润杰. 一种左心耳复杂度的确定方法,装置及计算机存储介质,  ZL201811261668.6,授权日期:20210810

  • 魏润杰,吴鹏,刘星利,高琪. 血流储备分数确定系统、方法、终端及存储介质,专利号ZL201811119677.1,授权日期:20220201

  • 魏润杰,王洪平,高琪,吴鹏. 一种评估血流储备分数的方法及装置、设备、存储介质,ZL201810983737.8,授权日期:20220311

  • 魏润杰,高琪,李博文,吴鹏. 一种血管提取的方法、装置及存储介质, 专利号ZL201810936725.X,授权日期:20210108

  • 魏润杰,吴鹏,刘星利,高琪. 一种确定冠状动脉血流储备分数FFR的方法和装置, 专利号ZL 201810568691.3,授权日期:20210810

  • 魏润杰,王虎峰,高琪,吴鹏,李飞,王巍.一种医疗图像的处理方法、装置及计算机存储介质, 授权号 ZL201810534684.1,授权日期:20201208

  • 魏润杰,高琪,刘星利,吴鹏,李飞,王巍.一种血流速度的修正方法、装置、终端和计算机存储介质, ZL201810517956.7,授权日期:20220412

  • 吴鹏,边玉成,吴思齐.一种基于能量耗散的溶血经验预测方法及装置,专利号 ZL201711274526.9,授权日期:20210518

  • 吴鹏, 潘志刚, 尹成科. 磁悬浮泵用叶轮、泵头、叶轮设计方法. 发明专利. 专利号ZL202311126829.1,授权日期:2024126

实用新型专利

  • 潘志刚尹成科磁悬浮泵用叶轮、泵头及磁悬浮泵实用新型专利,授权号ZL202322380476.X,授权日期:20231219

  • 余晴阳,吴鹏,邓业林.一种离心式风机蜗壳结构,专利号:ZL202121430026.1,授权日期:20220118

  • 柳光茂,吴鹏,胡盛寿,尹成科.一种磁悬浮血泵装置,专利号ZL202021271409.4,授权日期:20210305

  • 吴鹏,张坤. 可穿戴辅助投篮装置,专利号:ZL201720980556.0,授权日期:20180302


软件著作权

  • 三维不可压缩大涡模拟计算程序FLOWAVE,登记号2018SR206022,完成人:吴鹏,著作权人:苏州大学

  • Ansys流体仿真流程自动化和远程计算软件,登记号2022SR0456157,完成人:白宇峤,赵翔宇,吴鹏,著作权人:苏州大学

  • Ansys流体仿真的流程自动化和数据管理软件,登记号2022SR0456150,完成人:白宇峤,赵翔宇,吴鹏,著作权人:苏州大学

  • 基于速度系数法的磁悬浮离心式血泵叶轮参数设计软件,登记号2023SR0920385,完成人:董志成,毛新元,白宇峤吴鹏,张柳笛,著作权人:苏州大学


Refereed Journals
Other Professional Activities
Selected Publications
Research Projects
Patents and Applications