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Higher-capacity lithium ion battery chemistries for improved residential energy storage with micro-cogeneration

Author

Listed:
  • Darcovich, K.
  • Henquin, E.R.
  • Kenney, B.
  • Davidson, I.J.
  • Saldanha, N.
  • Beausoleil-Morrison, I.

Abstract

Combined heat and power on a residential scale, also known as micro-cogeneration, is currently gaining traction as an energy savings practice. The configuration of micro-cogeneration systems is highly variable, as local climate, energy supply, energy market and the feasibility of including renewable type components such as wind turbines or photovoltaic panels are all factors. Large-scale lithium ion batteries for electrical storage in this context can provide cost savings, operational flexibility, and reduced stress on the distribution grid as well as a degree of contingency for installations relying upon unsteady renewables. Concurrently, significant advances in component materials used to make lithium ion cells offer performance improvements in terms of power output, energy capacity, robustness and longevity, thereby enhancing their prospective utility in residential micro-cogeneration installations. The present study evaluates annual residential energy use for a typical Canadian home connected to the electrical grid, equipped with a micro-cogeneration system consisting of a Stirling engine for supplying heat and power, coupled with a nominal 2kW/6kWh lithium ion battery. Two novel battery cathode chemistries, one a new Li–NCA material, the other a high voltage Ni-doped lithium manganate, are compared in the residential micro-cogeneration context with a system equipped with the presently conventional LiMn2O4 spinel-type battery.

Suggested Citation

  • Darcovich, K. & Henquin, E.R. & Kenney, B. & Davidson, I.J. & Saldanha, N. & Beausoleil-Morrison, I., 2013. "Higher-capacity lithium ion battery chemistries for improved residential energy storage with micro-cogeneration," Applied Energy, Elsevier, vol. 111(C), pages 853-861.
    • Handle: RePEc:eee:appene:v:111:y:2013:i:c:p:853-861
    DOI: 10.1016/j.apenergy.2013.03.088
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    Cited by:

    1. Daniel Cardoso & Daniel Nunes & João Faria & Paulo Fael & Pedro D. Gaspar, 2023. "Intelligent Micro-Cogeneration Systems for Residential Grids: A Sustainable Solution for Efficient Energy Management," Energies, MDPI, vol. 16(13), pages 1-21, July.
    2. Ping, Ping & Wang, Qingsong & Huang, Peifeng & Sun, Jinhua & Chen, Chunhua, 2014. "Thermal behaviour analysis of lithium-ion battery at elevated temperature using deconvolution method," Applied Energy, Elsevier, vol. 129(C), pages 261-273.
    3. Mahmud, Khizir & Amin, Uzma & Hossain, M.J. & Ravishankar, Jayashri, 2018. "Computational tools for design, analysis, and management of residential energy systems," Applied Energy, Elsevier, vol. 221(C), pages 535-556.
    4. Li, Dacheng & Guo, Songshan & He, Wei & King, Marcus & Wang, Jihong, 2021. "Combined capacity and operation optimisation of lithium-ion battery energy storage working with a combined heat and power system," Renewable and Sustainable Energy Reviews, Elsevier, vol. 140(C).
    5. Rosato, Antonio & Ciervo, Antonio & Ciampi, Giovanni & Scorpio, Michelangelo & Guarino, Francesco & Sibilio, Sergio, 2020. "Impact of solar field design and back-up technology on dynamic performance of a solar hybrid heating network integrated with a seasonal borehole thermal energy storage serving a small-scale residentia," Renewable Energy, Elsevier, vol. 154(C), pages 684-703.
    6. Antonio Rosato & Antonio Ciervo & Giovanni Ciampi & Michelangelo Scorpio & Sergio Sibilio, 2020. "Integration of Micro-Cogeneration Units and Electric Storages into a Micro-Scale Residential Solar District Heating System Operating with a Seasonal Thermal Storage," Energies, MDPI, vol. 13(20), pages 1-40, October.
    7. Zhao, Rui & Liu, Jie & Gu, Junjie, 2015. "The effects of electrode thickness on the electrochemical and thermal characteristics of lithium ion battery," Applied Energy, Elsevier, vol. 139(C), pages 220-229.
    8. Xue, Nansi & Du, Wenbo & Greszler, Thomas A. & Shyy, Wei & Martins, Joaquim R.R.A., 2014. "Design of a lithium-ion battery pack for PHEV using a hybrid optimization method," Applied Energy, Elsevier, vol. 115(C), pages 591-602.
    9. Zheng, Qiong & Li, Xianfeng & Cheng, Yuanhui & Ning, Guiling & Xing, Feng & Zhang, Huamin, 2014. "Development and perspective in vanadium flow battery modeling," Applied Energy, Elsevier, vol. 132(C), pages 254-266.
    10. Shaw-Williams, Damian & Susilawati, Connie, 2020. "A techno-economic evaluation of Virtual Net Metering for the Australian community housing sector," Applied Energy, Elsevier, vol. 261(C).
    11. Su, Laisuo & Zhang, Jianbo & Wang, Caijuan & Zhang, Yakun & Li, Zhe & Song, Yang & Jin, Ting & Ma, Zhao, 2016. "Identifying main factors of capacity fading in lithium ion cells using orthogonal design of experiments," Applied Energy, Elsevier, vol. 163(C), pages 201-210.
    12. Damian Shaw-Williams & Connie Susilawati & Geoffrey Walker, 2018. "Value of Residential Investment in Photovoltaics and Batteries in Networks: A Techno-Economic Analysis," Energies, MDPI, vol. 11(4), pages 1-25, April.
    13. Troy, Stefanie & Schreiber, Andrea & Reppert, Thorsten & Gehrke, Hans-Gregor & Finsterbusch, Martin & Uhlenbruck, Sven & Stenzel, Peter, 2016. "Life Cycle Assessment and resource analysis of all-solid-state batteries," Applied Energy, Elsevier, vol. 169(C), pages 757-767.
    14. Darcovich, K. & Kenney, B. & MacNeil, D.D. & Armstrong, M.M., 2015. "Control strategies and cycling demands for Li-ion storage batteries in residential micro-cogeneration systems," Applied Energy, Elsevier, vol. 141(C), pages 32-41.
    15. Obara, Shin’ya, 2015. "Dynamic-characteristics analysis of an independent microgrid consisting of a SOFC triple combined cycle power generation system and large-scale photovoltaics," Applied Energy, Elsevier, vol. 141(C), pages 19-31.
    16. Oh, Ki-Yong & Epureanu, Bogdan I., 2016. "Characterization and modeling of the thermal mechanics of lithium-ion battery cells," Applied Energy, Elsevier, vol. 178(C), pages 633-646.
    17. Anna-Lena Lane & Magdalena Boork & Patrik Thollander, 2019. "Barriers, Driving Forces and Non-Energy Benefits for Battery Storage in Photovoltaic (PV) Systems in Modern Agriculture," Energies, MDPI, vol. 12(18), pages 1-17, September.
    18. Glasgo, Brock & Azevedo, Inês Lima & Hendrickson, Chris, 2016. "How much electricity can we save by using direct current circuits in homes? Understanding the potential for electricity savings and assessing feasibility of a transition towards DC powered buildings," Applied Energy, Elsevier, vol. 180(C), pages 66-75.
    19. Yong-keon Ahn & Yong Nam Jo & Woosuk Cho & Ji-Sang Yu & Ki Jae Kim, 2019. "Mechanism of Capacity Fading in the LiNi 0.8 Co 0.1 Mn 0.1 O 2 Cathode Material for Lithium-Ion Batteries," Energies, MDPI, vol. 12(9), pages 1-10, April.
    20. Soares, F.J. & Carvalho, L. & Costa, I.C. & Iria, J.P. & Bodet, J.-M. & Jacinto, G. & Lecocq, A. & Roessner, J. & Caillard, B. & Salvi, O., 2015. "The STABALID project: Risk analysis of stationary Li-ion batteries for power system applications," Reliability Engineering and System Safety, Elsevier, vol. 140(C), pages 142-175.
    21. Ayuso, Pablo & Beltran, Hector & Segarra-Tamarit, Jorge & Pérez, Emilio, 2021. "Optimized profitability of LFP and NMC Li-ion batteries in residential PV applications," Mathematics and Computers in Simulation (MATCOM), Elsevier, vol. 183(C), pages 97-115.
    22. Raza, Syed Shabbar & Janajreh, Isam & Ghenai, Chaouki, 2014. "Sustainability index approach as a selection criteria for energy storage system of an intermittent renewable energy source," Applied Energy, Elsevier, vol. 136(C), pages 909-920.

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