Battery Energy Storage Systems A Financial Evaluation in Microgrids

被引:0
作者
Zagoras, Nikitas [1 ]
Balasubramaniam, Karthikeyan [1 ]
Karagiannidis, Iordanis [2 ]
Makram, Elham B. [1 ]
机构
[1] Clemson Univ, Holcombe Dept Elect Engn, Clemson, SC USA
[2] The Citadel, Sch Business Adm, Charleston, SC USA
来源
2015 NORTH AMERICAN POWER SYMPOSIUM (NAPS) | 2015年
关键词
battery; energy storage; photovoltaic; microgrid; scheduling; mixed integer linear programming; financial analysis;
D O I
暂无
中图分类号
TE [石油、天然气工业]; TK [能源与动力工程];
学科分类号
0807 ; 0820 ;
摘要
Battery Energy Storage Systems (BESS) are becoming more popular due to their positive attributes such as flexibility, lower cost, modularity, etc. This paper provides a mathematical approach to quantify its financial and operational impacts. Specifically, two test cases are investigated: intermittency mitigation of a solar farm using a BESS and optimal scheduling of microgrid with BESS. The former problem is formulated as a mixed integer linear programming problem while the latter is formulated as a linear programming problem. Both algorithms provided accurate solutions while achieving optimality. Finally, a financial model for the optimal operation of an advanced lead-acid BESS is investigated.
引用
收藏
页数:6
相关论文
共 50 条
[21]   Integration of a SMES–Battery-Based Hybrid Energy Storage System into Microgrids [J].
Ahmet Cansiz ;
Cagri Faydaci ;
M. Talha Qureshi ;
Omer Usta ;
Daniel T. McGuiness .
Journal of Superconductivity and Novel Magnetism, 2018, 31 :1449-1457
[22]   Integration of a SMES-Battery-Based Hybrid Energy Storage System into Microgrids [J].
Cansiz, Ahmet ;
Faydaci, Cagri ;
Qureshi, M. Talha ;
Usta, Omer ;
McGuiness, Daniel T. .
JOURNAL OF SUPERCONDUCTIVITY AND NOVEL MAGNETISM, 2018, 31 (05) :1449-1457
[23]   e-Battery for Energy Storage Systems [J].
Reddy, Siddavatam Ravi Prakash ;
Narayanan, Nalco K. ;
Loganathan, Umanand .
2018 IEEE INTERNATIONAL CONFERENCE ON POWER ELECTRONICS, DRIVES AND ENERGY SYSTEMS (PEDES), 2018,
[24]   A Universal Model Predictive Control for Practical AC Microgrids with PVs and Battery Energy Storage Systems [J].
Shan, Yinghao ;
Hu, Jiefeng ;
Cheng, Ka Wai ;
Liu, Ming .
2018 IEEE ENERGY CONVERSION CONGRESS AND EXPOSITION (ECCE), 2018, :6257-6262
[25]   Design of optimal wavelet-based energy management for hybrid energy storage systems in DC-microgrids to increase the battery lifetime [J].
Yang, Tao ;
Song, Dandan .
MULTISCALE AND MULTIDISCIPLINARY MODELING EXPERIMENTS AND DESIGN, 2024, 7 (04) :3243-3252
[26]   Control Strategies for Microgrids With Distributed Energy Storage Systems: An Overview [J].
Morstyn, Thomas ;
Hredzak, Branislav ;
Agelidis, Vassilios G. .
IEEE TRANSACTIONS ON SMART GRID, 2018, 9 (04) :3652-3666
[27]   Hierarchical energy management for community microgrids with integration of second-life battery energy storage systems and photovoltaic solar energy [J].
Deng, Youjun ;
Zhang, Yongxi ;
Luo, Fengji ;
Mu, Yunfei .
IET ENERGY SYSTEMS INTEGRATION, 2022, 4 (02) :206-219
[28]   Survey of Battery Energy Storage Systems and Modeling Techniques [J].
Sparacino, Adam R. ;
Reed, Gregory F. ;
Kerestes, Robert J. ;
Grainger, Brandon M. ;
Smith, Zachary T. .
2012 IEEE POWER AND ENERGY SOCIETY GENERAL MEETING, 2012,
[29]   Autonomous Power Management of Distributed Energy Storage Systems in Islanded Microgrids [J].
Mahmood, Hisham ;
Blaabjerg, Frede .
IEEE TRANSACTIONS ON SUSTAINABLE ENERGY, 2022, 13 (03) :1507-1522
[30]   Voltage and Frequency Control of Microgrids With Distributed Generations and Battery Energy Storage [J].
Alshehri, Jaber ;
Alzahrani, Ahmed ;
Khalid, Muhammad .
2019 8TH INTERNATIONAL CONFERENCE ON RENEWABLE ENERGY RESEARCH AND APPLICATIONS (ICRERA 2019), 2019, :381-385
12345