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能动学术论坛 第115期 暨金沙威尼斯欢乐娱人城第三届齐鲁青年论坛 动力工程及工程热物理分论坛

发布日期:2018-10-12 点击数:

金沙威尼斯欢乐娱人城第三届齐鲁青年论坛

动力工程及工程热物理分论坛

20181017-20181018

:金沙威尼斯欢乐娱人城千佛山校区东配楼四层会议室

承办单位:能源与动力工程学院、热科学与工程研究中心


 

报告题目

报告摘要

个人简介

20181017

14:45-15:30

面向医疗健康的生物界面技术——交叉学科的研究经验汇报

刘志远

新加坡南洋理工大学,博士后

Post-Doctoral   Fellow, Nanyang Technological University, Singapore

生物体的生理信息提取至关重要,是疾病诊断,反馈治疗,生控系统等生物医学领域的基础。由于生物体组织是柔软的有机体,柔性传感技术便应运而生。此次报告将包括柔性可拉伸电极及传感器的最新研究进展,及刘志远博士所发展的柔性可拉伸导电的贵金属薄膜技术,该技术在柔性能源等领域也会有广泛应用。更重要的是,刘志远博士具有六年多的生物医学传感器交叉研究实战经验,在当下交叉学科研究异军突起的时刻,他所分享的研究经验将有助于从事交叉学科研究的同仁,届时欢迎大家聆听与指正。

刘志远博士,本硕毕业于哈尔滨工业大学,博士毕业于新加坡南洋理工大学(博士后),六年来始终专注研究生物界面柔性传感技术,提出了独特的实现可拉伸导电的黄金薄膜技术,在界面柔性电极及力学传感器方面广泛应用。曾获美国材料学会优秀博士生金奖,新加坡材料学会优秀博士生奖等国际奖项。

20181017

15:30-16:15

Machine   Learning and Artificial Neural Network Prediction of Interfacial Thermal   Resistance between Graphene and Hexagonal Boron Nitride

张景超

美国内布拉斯加大学林肯分校,超算应用专家

HPC   Applications Specialist, University of Nebraska Lincoln, USA

High-performance thermal   interface materials (TIMs) have attracted persistent attention for the design   and development of miniaturized nanoelectronic devices; however, a large   number of potential new materials exist to form these heterostructures and   the explorations of their thermal properties are time consuming and   expensive. In this work, we train several supervised machine learning (ML)   and artificial neural network (ANN) models to predict the interfacial thermal   resistance (R) between graphene and hexagonal boron–nitride (hBN) with only   the knowledge of the system temperature, coupling strength between two   layers, and in-plane tensile strains. The training data were obtained by   high-throughput computations (HTCs) of R using classical molecular dynamics   (MD) simulations. Four different ML models, i.e., linear regression,   polynomial regression, decision tree and random forest, are explored. A pair   of one dense layer ANNs and another pair of two dense layer deep neural   networks (DNNs) are also investigated. It is reported that the DNN models   provide better R prediction results compared to the ML models. The thermal   property predictions using HTC and ML/ANN models are applicable to a wide   range of materials and open up new perspectives in the explorations of TIMs.

20107月本科毕业于金沙威尼斯欢乐娱人城能源与动力工程学院,同年被评选为金沙威尼斯欢乐娱人城优秀毕业生和山东省优秀毕业生。20137月博士毕业于美国爱荷华州立大学机械工程专业,同年被评选为爱荷华州立大学优秀助研。2013年至今在美国内布拉斯加大学林肯分校从事工程热物理的计算和模拟工作。现已发表SCI论文38篇,其中一区11篇,二区18篇,三区7篇,四区2篇。H-indexi10-index分别为1724。同时担任美国超算联盟(XSEDE)校园大使,兼任Software   Carpentry认证讲师。担任ACS NanoNano Letter   International Journal of Heat and Mass Transfer42个国际期刊的审稿人,共审稿130余次。曾在ASME Journal   of Thermal Science and Engineering Applications等三个SCI期刊主持特刊,任编委。

20181017

1615-17:00

Microscale   Studies on Hydrodynamics and Mass Transfer of Dense Carbon Dioxide Segments   in Water

秦宁

美国哈佛大学医学院\马萨诸塞州总医院,研究员

Research   Fellow, Harvard Medical School, Massachusetts General Hospital, USA

Microfluidic technologies are   powerful tools in assisting the probes into complicated physical-chemical   interactions of multiphase fluids in microscale geometries. Among such   studies, carbon dioxide (CO2) has drawn increasing attention because of their   environmental impacts such as greenhouse gas effects. However, dense CO2   including liquid and supercritical states as results of the storage   circumstance in deep geoformations (depth > 800m) are rarely investigated   mainly due to great technical difficulties in working with extreme pressures   (~10s bar) and elevated temperatures (> 31°C). My PhD thesis research   presents some first studies of the hydrodynamics and mass transfer of dense   CO2 segments in microchannels. First, an experimental system dedicated to two   phase microfluidic studies, especially for those related to extreme   pressure/temperature conditions will be introduced. This system is one of a   few in the world that enables quantitative studies of two- and multi-phase   microflows. Second, an experimental study of liquid CO2/deionized (DI) water   two phase flows in a micro T-junction will be presented, in which drop flow   and co-flow are identified. Focusing on the drop flow, mass transfer   mechanisms involving CO2 hydration, diffusion and advection and their effects   in CO2 molecules transport are considered and discussed. Third, experimental   investigations of the hydrodynamics and mass transfer of liquid CO2 and scCO2   drops traveling simultaneously with water in a long straight microchannel   (15mm long) will be reported. Drop size and speed at specified positions of   the channel are quantified. We proposed and developed a mathematical model to   calculate the mass transfer coefficient based on drop length reductions and   flowing time in the channel. Results indicate that surface-volume ratio and   drop flow time are two main factors in controlling the hydrodynamic shrinkage   of the liquid CO2 and scCO2 drops. Last, a numerical study will be presented   shedding light on the hydrodynamics of single liquid CO2 drop and single   scCO2 drop when they flow simultaneously with water as a carrier phase in a   straight microchannel. Three liquid CO2 and three scCO2 cases are studied.   The computed drop is in a capsule-like shape encapsulated by thin water films   whose thickness agrees very well with experimental results in literature. The   flow domain within CO2 drops are generally composed of a few vortex regions   indicating the hydrodynamic scenario inside the drop. Formations of these   vortexes are attributed to the shear stress nearby the interface.

Dr. Ning Qin is currently a   postdoctoral research fellow at the Wellman Center for Photomedicine at   Massachusetts General Hospital (MGH) and Harvard Medical School (HMS). His   research work at MGH and HMS is very interdisciplinary that spans microfluidics   and biomedical optics and aims to the development of advanced technologies   and instrument for rapid, effective, and point-of-care blood coagulation   analyses. Dr. Qin’s research interests lie in multiple areas such as   microfluidics, lab-on-a-chip technologies, droplets/bubbles, heat and mass   transfer, fluid mechanics, and carbon capture and storage (CCS). He received   a bachelor’s degree in thermal engineering from Shandong University in 2009   and a master’s degree in refrigeration and cryogenics engineering from the   Technical Institute of Physics and Chemistry, Chinses Academy of Sciences in   2012. He graduated and obtained his PhD degree in mechanical engineering from   the University of Waterloo, Canada in 2017. During his PhD, he was a   part-time research engineer at Genemis Laboratories Inc. based at Cambridge,   Ontario, Canada and was a R&D consultant at QuantWave Technologies Inc.   at Kitchener, Ontario. He was also a visiting scholar at the Institute for   Bioprocessing and Analytical Measurement Techniques (iba) e.V., Heilbad   Heiligenstadt, Germany in 2016. Dr. Qin is now a member of American Physical   Society (APS) and a member of Canadian Society of Mechanical Engineering. He   is a reviewer of multiple academic journals such as Physical Review E, Lab on   a Chip, Energy & Fuels, Applied Energy, and Chemical Engineering Science.



20181017

17:00:-17:45

功能碳材料的设计合成及其在烟气CO2分离方面应用

刘鑫

英国诺丁汉大学,博士后

Postdoc,   University of Nottingham, UK

功能碳材料具有高比表面积、较高的热和化学稳定性以及可控孔结构和表面化学性质等特点,在能源领域特别是气体分离方面拥有广阔的应用前景。作为极具潜力的气体吸附剂,功能碳材料被广泛应用于CO2吸附与分离领域, 本报告将介绍功能碳材料在CO2吸附与分离中的应用以及如何通过对材料性质调控设计合成适应于不同条件的碳基CO2吸附剂。

刘鑫,英国诺丁汉大学博士后研究员,博士生合作导师。2007-2014年在金沙威尼斯欢乐娱人城能源与动力工程学院获得学士和硕士学位(燃煤污染物减排国家工程实验室)。2014-2017年在英国诺丁汉大学获得化学工程博士学位,之后留在博士课题组继续从事博士后研究。在博士及博后期间一直从事有序多孔材料设计与合成及其在能源领域的应用。主要研究内容包括有序多孔功能碳材料及介孔硅材料合成,及其在气体分离和碳捕集等方面的应用研究。

20181018

09:00-09:45

The   Simple and Complicated Heat and Mass Management of PEM Fuel Cells and Water   Electrolysers

高鑫

丹麦奥尔堡大学,博士后

Postdoc,   Aalborg University, Denmark

This presentation gives a brief   review of all my research work in different projects at Aalborg University,   Denmark. Most of these projects are funded by Danish Ministry of Education   (UVM) and Danish Energy Agency (ENS). Researches are mainly done on the heat   and mass management optimization of these systems, 1) a methanol-fueled PBI   membrane high temperature fuel cell system from SerEnergy A/S, 2) two   generations of air-cooled FCgen®-H2PM LT-PEM systems from Ballard Europe A/S,   3) a liquid-cooled LT-PEM system, Ballard FCveloCity® for a forklift, 4) a   PEM water electrolysis from EWII A/S.

The complication of their heat   and mass management is from the fact that they include vast phenomena, like   electrochemical reactions, heat and mass transfer from µm to mm scale,   multi-phase phase flow, and material property/contact-surface imperfectness,   etc. All of these cause it expensive to measure accurately and cumbersome to   simulate. Some phenomena themselves alone are under intensive research and   still lack of thorough understanding. The simplicity is in the sense that a   lot of phenomena are actually linked to and determined by the well defined   models of heat and mass transfer in almost every textbook. However, simple   does not mean obvious. Simple but tricky may be the most apt words. Join this   presentation, let me show you some of my simple discoveries that may refresh   your believes.

Xin Gao was born in Shandong   Province, China. He got his B.Eng. in Thermal Power Engineering and   Automation from Nanjing University of Science and Technology in 2000. He   received M.Sc. Eng. in Automotive Power Machinery and Engineering from School   of Automotive Studies, Tongji University in 2009. In 2014 he was honored   Ph.D. in Energy Technology at Aalborg University and continued working in the   same group as a postdoctoral researcher until now. His research interests   cover heat and mass management optimization, multi-phase flow,   thermodynamics, fluid-dynamics and their numerical simulations inside   PEM/PBI-membrane fuel cells and water electrolysis. Besides, he has also   worked on thermoelectric (Seebeck) devices and sought combining them with   fuel cell systems for mutual benefits in steady-state and transient   situations. During his PhD and postdoc, he has 9 published in journals, like   Nano Research, Journal of Power Sources, and International Journal of   Hydrogen Energy, among 20 in total and 5 more being worked on. At the same   time, he has been teaching the course Heat Transfer and supervising students’   semester projects regularly. Furthermore, he serves the research community by   attending international conferences for 10 times and as reviewer for journals   and conferences, like Applied Energy, International Journal of Hydrogen   Energy, Applied Thermal Engineering for more than 30 times. He also visited   Iowa State University as a visiting scholar and Tsinghua University as a   project specialist in 2016.

20181018

09:45-10:30

Implication   of Improving Energy Efficiency for Water Resources

汪诗锋

英国纽卡斯尔大学,研究员

Researcher,   Newcastle University, UK

能源和水系统关系着社会的发展。调查和理解能源-水系统之间的关系能够可持续地管理能源和水资源。本报告系统分析了热电系统的各个过程,从中建立能源效率和水资源之间的数学关系。然后利用这个数学模型分析了提高能源效率对英国各种水资源的影响。

汪诗锋,研究方向为能源技术和能源系统的能源效率和可持续性。2010年毕业于德国弗莱堡大学,获博士学位。共发表了20多篇SCI文章,有一篇SCI封面文章,出版了两本专著。其研究成果包括:独立创建了一个能源-经济-环境模型;研究并全球首次提出应从局部和全局评估能源技术对生态系统的影响,并发展出23个指标和相应的方法;完成全英1千米分辨率下的优化生物能热电能源系统;发展了能源效率-水模型。从2011年至今为英国能源与环境部(DECC) 能源环境方面的顾问。从2012年至今为英国国家基金EPSRC的评委。为遥感刊物编委   (Remote Sensing, ISSN:2315-4632),并担任多个国际期刊的审稿人。

20181018

10:30-11:15

Direct   Numerical Simulation of Lean Premixed Turbulent Flames at High Karlovitz   Numbers under Elevated Pressures

王旭江

英国伦敦大学学院,博士

University   College London, UK

With growing concern about global   climate change and increasingly stringent regulations on pollutants   emissions, lean premixed combustion has had wide-ranging applications in   industrial devices, e.g. stationary gas turbines. The turbulent flames in gas   turbines are characterised by high-intensity turbulence and pressure. Under   these critical conditions, flame structures and chemical processes will be   dramatically modified. Therefore, it is vital to have a good understanding of   fundamental characteristics of lean premixed combustion under critical   conditions, which will promote the development of combustion devices and   assist to validate turbulent combustion models. However, it is difficult and   expensive to conduct experiments under high pressures. With the availability   of increasingly powerful supercomputers, direct numerical simulation (DNS) of   turbulent reacting flows has become feasible and affordable. The present   study focuses on DNS of lean premixed H2/air flames under varying Karlovitz   numbers, pressures and equivalence ratios. The effects of dominating   parameters on turbulent flame structures and chemical pathways are analysed   qualitatively and statistically.

王旭江,男,英国伦敦大学学院(University   College LondonUCL)博士,金沙威尼斯欢乐娱人城英国校友会秘书长、全英山东同学会主席。2011年金沙威尼斯欢乐娱人城能源与环境系统工程专业本科毕业,并于同年保送到燃煤污染物减排国家工程实验室,从事柴油O2/CO2气氛下燃烧特性的实验研究。201410月以全额奖学金进入伦敦大学学院机械工程系攻读博士学位,师从燃烧领域著名学者Kai Luo,研究方向为高压高湍流强度下燃烧的直接数值模拟。作为英国燃烧学会会员,积极参与欧洲地区湍流燃烧模拟的合作与讨论,研究课题得到了UKCTRF   UKCOMES的大力支持。目前已发表学术论文10余篇,2018年入围Reynolds Prize



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