首页- 信息服务- 通知公告

冲击动力学与安全防护暑期学校招生简章

Summer School on Impact Dynamics and Safety Protection Course Overview


一、课程目标 Our Mission

现代经济的迅速发展和新兴技术的推广应用,对冲击动力学与安全防护提出了前所未有的挑战。理解爆炸冲击等恶劣条件下结构变形、坍塌和失效等动力行为对其工程应用至关重要。本届冲击动力学与安全防护暑期学校由新浦的京集团350vip8888(中国)有限公司主办。受邀专家均为爆炸力学、燃烧学和安全防护领域的世界知名学者,分别来自澳大利亚科廷大学、澳大利亚斯威本科技大学、英国伦敦大学学院等6所国际著名学府。

课程将为兵器科学与技术、安全科学、力学、航空航天、车辆工程、防护工程及国防工程等专业的研究生提供领域前沿科学知识和相关研究方法,为他们从事科学研究打下基础。同时,本课程所提供的知识和方法也可以供相关专业教师、研究人员和工程师等参考借鉴。

With the rapid development of modern economy and the popularization and application of new technologies, the safe operation of engineering structures has been challenged unprecedentedly. Understanding the dynamic behavior of deformation, collapse, damage, and failure of various structures under harsh working conditions such as impact and explosion is crucial for its application in engineering. The Impact Dynamics and Safety Protection Summer School is an annual master course event held by the School of Mechatronical Engineering, Beijing Institute of Technology (BIT). Invited lecturers are from six well-known universities, including Curtin University, Swinburne University of Technology and University College London, and all world-renowned scholars in the field of explosion mechanics, combustion science, and safety protection.

The course will provide advanced scientific knowledge and relevant research methods for postgraduates majoring in weaponry science and technology, safety science, mechanics, aerospace, vehicle engineering, protection engineering, and national defense engineering, laying a foundation for their scientific research. At the same time, the knowledge and methods elaborated in this course can also be used for reference by teachers, researchers and engineers in related fields.

二、课程介绍 Syllabus

2023年冲击动力学与安全防护暑期学校将开设以下六门课程,共37课时。课程开设时间为北京时间7月3日-7月10日:

The 2023 Summer School on Impact Dynamics and Safety Protection will offer the following six courses with a total of 37 class hours. The course will be offered from July 3rd to July 10th (Beijing Time):

三、相关信息 General Information

本课程招生对象为在校研究生、博士后、教职员工,研究机构的专业人员,工业研发工程师。本届暑期学校将采用Zoom线上授课的方式展开,不收取任何费用,新浦的京集团350vip8888研究生及保研员工按学校规定可获得相应的学分,课程结束后将统一发放结业证书。

This course is open to current graduates, post-doctors, faulty, professionals in research institutions, and industrial R&D engineers. Lectures will be presented online using ZOOM. No fees will be charged. BIT graduate students and students with graduate recommendation who finish the program will be given credits and awarded certificates.

四、报名方式 Registration

报名时间为2023年6月5日至6月23日,请点击以下链接https://www.wjx.cn/vm/Q0BuVZo.aspx或扫描二维码在线提交报名表,报名以后请扫码加入微信群。将于6月26日之前发放录取通知。

Registration is open from June 5~June 23, 2023.Register online at https://www.wjx.cn/vm/Q0BuVZo.aspx or via the QR Code. After you register, join WeChat group to keep in contact. Acceptance notices will be issued by June 26.


                                  image.png


五、联系方式 Contact Us

联系人:王老师、曹老师

联系电话:13520487167、18510570862

联系邮箱: 7220171217@bit.edu.cn、sklest@bit.edu.cn

For inquiries, please contact the program administrators,

Ms. Wang  Tel: (86)13520487167   Email: 7220171217@bit.edu.cn

Ms. Cao     Tel: (86)18510570862   Email: sklest@bit.edu.cn

六、课程简介 Course Content

1、冲击载荷作用下纤维-金属层合结构的动态响应

Dynamic response of fiber metal laminates under impact loads

课程简介:纤维-金属层合结构具有很好的抗撞击、抗爆炸和抗疲劳性能,报告主要介绍纤维-金属层合结构现阶段的应用,多层结构的制造及爆炸效应;将介绍纤维和树脂的多尺度模型的发展以及用多尺度模型进行编织复合材料尺度效应的冲击模拟和实验验证。也将介绍基于PVC泡沫夹层结构现阶段的应用,包括波纹夹芯、碳纤维空间桁架夹芯、蛋形夹芯等夹层结构以及夹层结构的计算机模拟和爆炸实验验证等。

The fiber metal laminates present superior anti-impact, anti-explosion and anti-fatigue properties. This course mainly introduces the application of fiber metal laminates at the present stage, the fabrication of multilayer structures and their explosion impact, and the development of multi-scale modeling of fibers and resins, including the user-defined constitutive models, failure criteria and interface treatment. Additionally, the impact simulation and experimental verification of the scale effects of braided composites using the multi-scale models will also be presented. The course also introduces the current application of PVC foam sandwich structures, including corrugated sandwich, carbon fiber space truss sandwich, egg sandwich and other sandwich structures.

2、抗爆材料与结构分析、设计原理和研究最新进展

Current practice and research on analysis and design of structures to resist blast loads

课程简介:重点介绍爆炸冲击荷载作用下结构动力学响应、抗爆结构设计原理、新型抗爆材料和抗爆结构最新发展和应用,结构动力学分析和数值模拟方法,结构安全控制理论最新发展等。

The course mainly discusses the dynamic response of structures under explosion impact loads, the design principle of blast-resistant structures, the latest development and application of new blast-resistant materials and structures, the methods of structural dynamics analysis and numerical simulation, the latest development of structural safety control theory, etc.

3、结构和材料的能量吸收和冲击响应

Energy absorption and impact response of structures and materials

课程简介:本课程旨在介绍结构和材料吸收能量的基本概念和原理。主要集中在薄壁结构、多孔和多胞固体、复合结构等吸能和/或动态冲击行为的近期研究。其中,多孔材料及其结构具有良好的能量吸收性能,其结构性能可调节、可在设计中进行优化。该设计理念可以推广到其他领域的应用,如采矿以及土木工程。

This course aims to introduce the basic concepts and principles regarding energy absorption by structures and materials. It mainly focused on the recent research in energy absorption and/or dynamic impact behavior of thin-walled structures, porous and cellular solids, and composite structures. Among them, cellular materials and their structures offered good energy absorption performance, and their structural performance could be adjusted and might be optimized in design. The design concept could be extended to other areas of applications in industries such as mining and sports, and civil engineering.

4、应力波在多孔介质中的传播规律

Stress wave propagation in cellular solids

课程简介:多孔材料由于特定细观结构是物理功能与结构一体化的新型多功能材料。本门课程将介绍多孔材料在压缩载荷作用下的力学响应特性,重点关注应力波在多孔介质中的传播规律。课程将探讨典型多孔材料压缩行为、一维刚-完美塑性-自锁(RPPL)理论模型的建立、材料微惯性、冲击波效应等因素对应力波传播和吸能特性的影响规律等。

Porous material is a new multifunctional material that integrates physical function and structure because of its specific meso-structure. This course will introduce the mechanical response characteristics of porous materials under compression loads, with an emphasis on stress wave propagation in porous media. The course will also discuss the compression behavior of typical porous materials, the establishment of one-dimensional rigid-perfect plastic-self-locking (RPPL) theoretical model, the influence of material micro-inertia, shock wave effect and other factors on the stress wave propagation and energy absorption characteristics.

5、建筑火灾动力学原理

Principles of Building Fire Dynamics

课程简介:本课程通过对火灾科学基础理论的学习,让员工掌握火灾科学的基础知识、基本概念和基本原理,学会运用这些知识解决实际火灾问题的方法,学会抓主要矛盾、忽略次要矛盾以简化物理模型的分析方法,并培养能够透过火灾现象分析其内在本质的能力,为日后的学习和工作打下基础。

The main goal of this course is to let students master the basic knowledge, basic concepts and basic principles of fire science through the study of the basic theory of fire science, learn how to apply these knowledge to solve practical fire problems, learn to grasp the main contradiction, ignore the secondary contradiction and Simplify the analysis methods of physical models and cultivate students' ability to analyze their intrinsic nature through fire phenomena, laying the foundation for students' future study and work.

6、水中金属丝(阵)电爆炸:原理、诊断、力学效应

Underwater electrical explosion of wire and wire array

课程简介:本课程旨在建立电爆炸的概念,并介绍电爆炸在冲击物理和爆炸模拟中的一些应用。爆炸与金属的液气相变密切相关。相变可以在纳秒内完成。对于爆炸效应的研究,电爆炸提供了一种安全、方便、纯粹的实验室爆炸源,而不需要额外考虑化学反应。此外,这种系统的能量释放功率足够高,可以支持SWs和射流非线性特性的研究。

The course aims to establish the concept of electrical explosion and introduce some application in shock physics and explosion simulations. The explosion is closely related to the liquid-vapor phase transition of the metal. Recent molecular dynamic simulation suggested the phase transition could be finished in a nanosecond. For the research of explosion effects, the electrical explosion provides a safe, convenient, and pure laboratory explosion source, without the extra consideration of chemical reactions. In addition, the energy release power of such system is sufficiently high to support the study of non-linear properties of SWs and jets.

七、 授课专家简介  Lecturers

1、授课专家:郝洪院士,澳大利亚科廷大学

Lecturer 1: Hong Hao, Curtin University, Australia

专家简介:郝洪教授是澳大利亚工程院院士,科廷大学杰出教授,国际著名防护工程、结构安全、冲击动力学专家,国际防护结构学会主席,国际地震学会澳大利亚主席。受邀国际大会报告超过100次,担任国际防护结构等2个期刊主编、10余个期刊编委,发表学术论文500余篇,引用超过20000次,Google Scholar H-Index 超过71。

Prof. Hao Hong is Australian Laureate Fellow and a distinguished Professor in Curtin University. He is an internationally renowned expert in protective engineering, structural safety and impact dynamics. He is the International Association of Protective Structures, Australian Rep in the International Association of Earthquake Engineering. He has been invited to make keynote presentations at international conferences for more than 100 times. He serves as the chief editor of two journals such as international Protection Structure and editorial board member of more than 10 journals. He has published more than 500 academic papers with more than 20,000 citations, and Google Scholar H-Index has exceeded 71.

2.授课专家:官忠伟教授,阿联酋技术创新研究院先进材料研究中心

Lecturer 2: Zhongwei Guan, Advanced Materials Research Centre of Technology Innovation Institute in Abu Dhabi

专家简介:官忠伟教授是阿布扎比阿联酋技术创新研究院先进材料研究中心的执行董事。在 1993年获英国布拉德福大学高分子结构管道工程博士学位。在2021年,他担任了英国利物浦大学轻型复合材料和结构的讲习教授。主要研究方向为轻质复合材料结构在撞击和爆炸等极端载荷条件下的冲击响应。Google Scholar H-Index为43,被引用5900多次。官忠伟教授被美国斯坦福大学评为百分之二世界顶尖科学家。他担任《国际冲击工程杂志》、《国际应用复合材料杂志》编委及20多个国际会议的学术委员会成员。他获得了IAAM(国际先进材料协会)奖章,国际华人计算力学学会(ICACM)研究员奖以及JSPS。

Professor Zhongwei Guan is Executive Director of Advanced Materials Research Centre of Technology Innovation Institute in Abu Dhabi. He was awarded PhD on Structural Behavior of Polymeric Pipelining in University of Bradford UK in 1993. In 2021, He was lecturer in Lightweight Composite Materials and Structures at the University of Liverpool. His research interest covers impact response of lightweight composite structures under extreme loading conditions such as impact and explosion. The Google Scholar H-Index is 43 and has been cited more than 5,900 times. Professor Guan Zhongwei has been named two percent of the world's top scientists by Stanford University. He serves on the editorial board of the International Journal of Impact Engineering, the International Journal of Applied Composites and on the academic committees of more than 20 international conferences. He has received the IAAM (International Association for Advanced Materials) Medal, the International Chinese Society for Computational Mechanics (ICACM) Fellow Award and the JSPS.

3. 授课专家:PJ Tan教授,英国伦敦大学学院

Lecturer 3: PJ Tan, University College London, UK

专家简介:Tan教授是英国伦敦大学学院机械系材料高应变率实验室主任,国际冲击动力学旗舰期刊International Journal of Impact Engineering副主编,研究方向包含轻质高强材料在强动载荷下的效应与防护机理、生物冲击动力学等。Tan教授提出的“冲击波理论”受到国内外学者的广泛引用(他引超过400次)。Tan教授在固体力学、冲击动力学相关领域发表SCI国际期刊论文69篇,论文在SCI数据库统计被引用超过2000次,H值为17。

PJ Tan is currently Professor of Applied Mechanics in the Department of Mechanical Engineering at UCL. He heads the High Strain Rate Laboratory. Prof. Tan is an Associate Editor for International Journal of Impact Engineering. He is particularly interested in understanding how lightweight materials and structures respond to dynamic loadings and more arduous operating conditions. The "Shock" theory proposed by Prof. Tan has been widely cited by scholars (more than 400 times). He has published 69 papers in SCI international journals in the fields of solid mechanics and impact mechanics, which have been cited more than 2000 times in SCI database statistics, with an H value of 17.

4. 授课专家:黄鑫炎副教授,香港理工大学

Lecturer 4: Xinyan Huang, The Hong Kong Polytechnic University, HK

专家简介:黄鑫炎博士是香港理工大学建筑环境及能源工程系副教授、博导,消防安全工程研究中心副主任。博士毕业于英国帝国理工大学,曾在美国加州大学伯克利分校进行博士后研究。黄博士是SCI期刊Fire Technology和 Intl. J. Wildland Fire副主编、Fire Safety J.和Fire and Materials编委。曾获得国际燃烧学会伯纳德-刘易斯学者、国际火灾学会杰出青年科学家奖、英国皇家学会访问学者、香港工程师协会消防工程卓越大奖等奖项。

Dr. Huang is an Associate Professor and Doctoral supervisor at Hong Kong Polytechnic University and the Deputy Director of the Research Centre for Fire Safety Engineering. He received his PhD from Imperial College London in the UK and did postdoctoral research at the University of California, Berkeley in the US. Dr. Huang is associate editor of SCI journal Fire Technology and Intl. J. Wildland Fire, and author of the journal Fire Safety J. and Fire and Materials. He was awarded the Bernard-Lewis Scholar of the International Institute of Combustion, the Distinguished Young Scientist Award of the International Institute of Fire Science, the Visiting Scholar of the Royal Society of Britain, and the Fire Engineering Excellence Award of the Hong Kong Institution of Engineers.