【四川大学主办|IEEE出版】 2024年第三届电力和能源前沿亚洲会议(ACFPE 2024)持续征稿中!

学术   2024-06-27 17:00   浙江  

-ACFPE 2024-

中国成都|2024年10月25-27日

2024年第三届电力和能源前沿亚洲会议


01
About ACFPE
ACFPE 2024

2024年第三届电力和能源前沿亚洲会议(ACFPE 2024) 将于2024年10月25日至27日中国成都举行,会议由四川大学四川省电机工程学会联合主办,重庆大学IEEE 成都分会技术协办,香港机械工程师学会(HKSME)、西南交通大学和西南石油大学提供支持,《中国电机工程学报》、CSEE Journal of Power and Energy Systems (CSEE JPES) 、《电力系统自动化》、Journal of Modern Power Systems and Clean Energy、《电网技术》《新型电力系统》《高电压技术》、High Voltage、《电力工程技术》《电力信息与通信技术》《电气工程学报》《中国电气工程学报(英文)》《发电技术》《电机与控制应用》《四川电力技术》、electronics、《南方电网技术》《内蒙古电力技术》和《南方能源建设》提供媒体支持。会议主题“人工智能赋能未来智能电网技术创新”。

会议诚邀能源与电力领域的专家、研究人员和学者参与会议、共同探讨、分享智慧,讨论能源转型实施路径和绿色发展创新思路,研讨新型电力系统发展举措,促进电力和能源的可持续发展。

重要日期

投稿截止日期:2024年6月30日

录用通知日期:2024年7月30日
注册截止日期:2024年8月30日



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组织单位
ACFPE 2024





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出版检索信息
ACFPE 2024

*所有投稿都将进行审核,会议收录的文章将在会议论文集中在线出版,在符合IEEE Xplore的范围和质量要求的情况下,所有接受且做报告的论文将被提交到IEEE Xplore。出版后由出版社提交至Engineering Village, Scopus, Web of Science等检索机构审核和检索。

*优秀且经拓展的文章(录用且宣读)被在会后被推荐至 IET Electric Power Applications (Online ISSN:1751-8679)期刊专刊“Advanced Power Converters, Protection, and Control for Electric Systems”, 出版后的文章将提交给SCIE, Scopus等数据库进行评审及检索。

*优秀且经拓展的文章(录用且宣读)被在会后被推荐至 Electronics (ISSN 2079-9292)期刊专刊“dvances in Power System Dynamics, Stability, Control and Dispatch with Large-Scale Renewable Energy Penetrated”。

ACFPE 2024已进入IEEE会议列表!

ACFPE 2023/2022 已由IEEE 出版,并被EI Compendex 成功检索!



04
报告专家
ACFPE 2024

董朝阳 教授

IEEE Fellow

香港城市大学,中国香港

董朝阳是香港城市大学电气工程系主任兼讲席教授。他的直接职位是新加坡南洋理工大学SPG电力工程教授和SPG-NTU联合实验室联合主任。董教授之前的职位包括SHARP教授和新南威尔士大学数字电网期货研究所首任所长;ARC综合储能解决方案研究中心主任;Ausgrid智能电网中心主任兼教授,为澳大利亚价值5亿澳元的智能电网、智能城市国家示范项目提供研发支持。董教授的研究兴趣包括电力系统规划、负荷建模、智能电网、智能城市、能源市场、可再生能源及其电网连接、计算方法及其在电力系统分析中的应用。

报告标题:Real-time measurement for carbon emissions

摘要:Reliable and fast calculation of carbon emissions is an important task in achieving emission reduction against climate change. This talk presents an innovative real-time computational framework designed specifically for swiftly assessing carbon emissions originating from industrial load centres. Leveraging non-intrusive load monitoring (NILM) together with real-time smart meter data, this framework offers a robust solution for efficiently quantifying emissions within industrial settings. Through NILEM we can gain invaluable insights into the intricate energy consumption patterns of industrial loads, enabling precise emission calculations with minimal intrusion. The real-time feature further enhances this framework providing decision-makers with tools for strategizing emission reduction measures within industrial operations. Case studies will be given to demonstrate the effectiveness of the framework compared with other common approaches.



曾少华 教授

新加坡工程院院士

东盟工程技术学院院士

南洋理工大学,新加坡

曾教授在南大能源研究所领导氢和燃料电池研究(ERI@N). 现任中国广州知识城中新国际联合研究所所长。他是MAE学院教授和郑曾文能源讲座教授。他还是新加坡工程院院士和东盟工程技术院院士。他的研究为他赢得了多个奖项,包括英国国际氢能协会颁发的乔治-斯蒂芬森奖章、美国国际氢能协会颁发的杰出科学成就奖。

报告标题:Turquoise Hydrogen: A possible solution for renewable energy scarce countries in energy transition period

摘要:The pursuit of energy availability, affordability, and sustainability has always been paramount in any nation's energy transition plan, echoing the principles outlined in the World Energy Council's Energy Trilemma. This trilemma emphasizes the importance of energy security, equity, and environmental sustainability. The concept of a Hydrogen Economy has emerged as a potent vision, aiming not only to decarbonize the global economy but also to address energy security concerns by leveraging hydrogen, which can be extracted from various sources, including water. Importantly, when hydrogen is used for energy production, it generates water as its sole by-product. However, despite its promise, the Hydrogen Economy remains complex and challenging to implement at scale, primarily due to its reliance on two distinct supply chains: one for hydrogen production and another for energy conversion systems. The widespread adoption of this model hinges on achieving affordable costs for both hydrogen and energy conversion technologies. In countries with limited access to renewable energy resources like Singapore, hydrogen production using renewables is constrained, and importing hydrogen from abroad often proves cost prohibitive. As a result, conventional methods such as steam methane reforming (SMR) remain prevalent, despite their significant carbon emissions. To mitigate the environmental impact of hydrogen production, alternatives like Carbon Capture and Sequestration (CCS) are considered. However, implementing CCS in geographically constrained regions like Singapore presents challenges. Instead, methods such as methane cracking offer a promising solution. By splitting methane (or natural gas) into hydrogen and solid carbon, these processes produce little to no CO2 emissions. The presentation will commence with an overview of Singapore’s long-term energy plan and research focus, followed by an exploration of several major initiatives regarding hydrogen applications. Finally, it will delve into the catalytic decomposition of methane for hydrogen production, serving as an interim solution during the energy transition period.


年珩 教授

IEEE Fellow

浙江大学,中国

浙江大学电气工程学院教授,博士生导师,电机及其控制研究所所长,国家自然科学基金优秀青年基金获得者,IEEE高级会员。长时间从事电机系统运行及其控制、风力发电、光伏和储能等方面的研究工作,在高性能电机运行控制技术、新能源及储能并网发电技术、电力电子技术、电力系统安全运行和仿真技术等方面有着坚实的理论基础和丰富的工作经验并富于研究成果。

报告标题:Frequency Coupling Characteristic Analysis and Stability Improvement of Renewable Power Generation Systems

摘要:Abstract—It has been reported that when connected with low short circuit ratio (SCR) grid or diverse grid transmission infrastructure, the renewable power generation systems have some broadband resonance risk such as sub-synchronous resonance (SSR), sub/super-synchronous oscillation (SSO) and high-frequency resonance (HFR). The impedance-based method has been proven to be a useful method to analyze these instability issues. However, the frequency coupling characteristic between positive- and the negative-sequence complicates the stability analysis and improvement for large-scale renewable power system. This report establishes the frequency coupling characteristic model for renewable power system, and locates the dominant factor within each frequency band, then the s-domain nodal admittance matrix and the broadband passivity enhancement considering frequency coupling characteristic are proposed.

张东霞 教授

中国电力科学研究院,中国

张东霞,1999年清华大学取得博士学位后,进入中国电力科学研究院工作至今。主要研究方向是:电力系统稳定性分析、城市配电网规划、大数据和人工智能在电力系统的应用。发表学术论文50余篇。担任《中国电机工程学报》副主编,中国电工学会人工智能专业委员会副主任委员,中国电工学会数字孪生专业委员会委员。

报告标题:AI appliacation in power system security analysis and stability control

摘要:The research progress of applying artificial intelligence to the field of security & stability analysis and control of power systems is introdunced,specifically,the research work primarily deals with static security and transient stability estimation by deep learning and the generation of preventive control and emergent control strategies by deep reinforcenent learning. Then the challenges currently faced is discussed, such as unbanlanced samples,weak interpretability of deep learning,lack of real data. Finally,the research trends and issues that require further in-depth study is summarized.

更多信息持续更新中……







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征稿信息
ACFPE 2024

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专题征稿


专题1:跟网/构网型新能源集群运行与控制

Operation and control of grid-following and grid-forming renewable power generation clusters

主席:陈磊,武汉大学

专题2:电力-交通融合网络低碳协同优化

Low-Carbon Coordinated Optimization of Interdependent Power and Transportation Networks

主席:陈胜,河海大学

副主席:吕思,河海大学

专题3:新能源并网控制

Grid integartion of renewable energy

主席:朱介北,天津大学

副主席:俞露杰,天津大学

专题4:交直流微电网的高级建模、控制、运行和规划

Advanced Modeling, Control, Operation, and Planning of AC/DC Microgrids

主席:韩杨,电子科技大学

专题5:高比例新能源电力市场

Electricity Market with High Renewables

主席:向明旭,重庆大学

副主席:杨知方,重庆大学

专题6:可持续能源系统中需求侧资源的协同与互动机理

Demand Side Resource Coordination and Interaction Mechanism in Sustainable Energy Systems

主席:赵博超,天津大学

专题信息持续更新中……


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会议征稿


Track I | 先进能源转换

Advanced Energy Conversion

主席:李劲松,大连理工大学

Track II | 人工智能与数据驱动技术在智能电网中的应用

AI and Data-driven Technology Applications in Smart Grid

主席:刘博,天津大学

Track III | 基于DER的网格边缘感知与控制

DER Based Grid-edge Awareness and Control

Track IV | 储能应用与氢能

Energy Storage Applications and Hydrogen

主席:Chew Kuew Wai,马来西亚东姑阿都拉曼大学

Track V | 大规模可再生能源接入

Large-scale Renewable Energy Integration

主席:GHAMGEEN IZAT RASHED,武汉大学

Track VI | 电力系统低碳技术

Low-carbon Technologies on Power Systems

Track VII | 多能源系统运行与规划

Multi-energy Systems Operation and Planning 

Track VIII | 电力市场和经济

Power Market and Economy

Track IX | 智能电网运行与规划

Smart Grid Operation and Control

主席:邱高,四川大学

更多:https://www.acfpe.org/CFP.html





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更多信息
ACFPE 2024
01
投稿方式

1. 通过线上投稿系统:

https://cmt3.research.microsoft.com/ACFPE2024

扫码直达投稿系统

02
其他参会方式

1. 报告者如果你只想参加会议并作报告,不出版论文,只需要将摘要提交给会务组,经过评审后,将告知结果。注册成功的报告,将列入会议日程。有意者将摘要发送到会议邮箱acfpe@vip.163.com

2. 审稿人我们诚挚欢迎相关专家参与审稿。

3. 听众注册成功的听众即可参加会议。

03
投稿须知
1)稿件必须用英文书写,图片、表格、公式中不允许有英文以外的其他语言出现;
2)摘要和全文投稿均应按照模板标准编写(模板可点击阅读原文前往会议官网获取),全文投稿的稿件应不少于5页,不超过10页;
3)论文应为原创且从未公开出版的,投稿内容应与主题相关,且有深度性,有创新性;
4)禁止抄袭;
5)禁止一稿多投。



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会议地点
ACFPE 2024







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投稿参会联系方式


曹老师

19150956004

acfpe@vip.163.com

www.acfpe.org


商务合作联系方式


陈老师

19160368706(微信同号)


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