Comparative life cycle assessment of battery storage systems for stationary applications.

This paper presents a comparative life cycle assessment of cumulative energy demand (CED) and global warming potential (GWP) of four stationary battery technologies: lithium-ion, lead-acid, sodium-sulfur, and vanadium-redox-flow. The analyses were carried out for a complete utilization of their cycle life and for six different stationary applications. Due to its lower CED and GWP impacts, a qualitative analysis of lithium-ion was carried out to assess the impacts of its process chains on 17 midpoint impact categories using ReCiPe-2008 methodology. It was found that in general the use stage of batteries dominates their life cycle impacts significantly. It is therefore misleading to compare the environmental performance of batteries only on a mass or capacity basis at the manufacturing outlet ("cradle-to-gate analyses") while neglecting their use stage impacts, especially when they have different characteristic parameters. Furthermore, the relative ranking of batteries does not show a significant dependency on the investigated stationary application scenarios in most cases. Based on the results obtained, the authors go on to recommend the deployment of batteries with higher round-trip efficiency, such as lithium-ion, for stationary grid operation in the first instance.

[1]  Joeri Van Mierlo,et al.  SUBAT: An assessment of sustainable battery technology , 2006 .

[2]  Florian Steinke,et al.  Grid vs. storage in a 100% renewable Europe , 2013 .

[3]  Pavlos S. Georgilakis,et al.  Technical challenges associated with the integration of wind power into power systems , 2008 .

[4]  Troy R. Hawkins,et al.  Comparative Environmental Life Cycle Assessment of Conventional and Electric Vehicles , 2013 .

[5]  Dong Wang,et al.  Environmental characteristics comparison of Li-ion batteries and Ni-MH batteries under the uncertainty of cycle performance. , 2012, Journal of hazardous materials.

[6]  Lukas G. Swan,et al.  Selection of battery technology to support grid-integrated renewable electricity , 2012 .

[7]  Sally M. Benson,et al.  On the importance of reducing the energetic and material demands of electrical energy storage , 2013 .

[8]  C. Rydh Environmental assessment of vanadium redox and lead-acid batteries for stationary energy storage , 1999 .

[9]  Lars Ole Valøen,et al.  Life Cycle Assessment of a Lithium‐Ion Battery Vehicle Pack , 2014 .

[10]  Johann Kranz,et al.  The role of smart metering and decentralized electricity storage for smart grids: The importance of positive externalities , 2012 .

[11]  Jacqueline de Chazal,et al.  Climate change 2007 : impacts, adaptation and vulnerability : Working Group II contribution to the Fourth Assessment Report of the IPCC Intergovernmental Panel on Climate Change , 2014 .

[12]  D. O M I N I,et al.  Contribution of Li-Ion Batteries to the Environmental Impact of Electric Vehicles , 2010 .

[13]  Maurizio Cellura,et al.  Life cycle assessment of storage systems: the case study of a sodium/nickel chloride battery , 2014 .

[14]  Benedikt Battke,et al.  A review and probabilistic model of lifecycle costs of stationary batteries in multiple applications , 2013 .

[15]  Ronnie Belmans,et al.  Distributed generation: definition, benefits and issues , 2005 .

[16]  Martijn Gough Climate change , 2009, Canadian Medical Association Journal.

[17]  Paul Denholm,et al.  Life cycle energy requirements and greenhouse gas emissions from large scale energy storage systems , 2004 .

[18]  Björn A. Sandén,et al.  Energy analysis of batteries in photovoltaic systems. Part II: Energy return factors and overall battery efficiencies , 2005 .

[19]  Anders Hammer Strømman,et al.  Environmental impacts of hybrid and electric vehicles—a review , 2012, The International Journal of Life Cycle Assessment.

[20]  Steven B. Young,et al.  Environmental feasibility of re-use of electric vehicle batteries , 2014 .

[21]  C. Rydh,et al.  Energy analysis of batteries in photovoltaic systems. Part I: Performance and energy requirements , 2005 .

[22]  Anders Hammer Strømman,et al.  Life cycle environmental assessment of lithium-ion and nickel metal hydride batteries for plug-in hybrid and battery electric vehicles. , 2011, Environmental science & technology.

[23]  Vasilis Fthenakis,et al.  Life-cycle analysis of flow-assisted nickel zinc-, manganese dioxide-, and valve-regulated lead-acid batteries designed for demand-charge reduction , 2015 .

[24]  Gerard J. M. Smit,et al.  Value of Storage in Distribution Grids—Competition or Cooperation of Stakeholders? , 2013, IEEE Transactions on Smart Grid.

[25]  Hamidreza Zareipour,et al.  Energy storage for mitigating the variability of renewable electricity sources: An updated review , 2010 .

[26]  L. Gaines,et al.  Status of life cycle inventories for batteries , 2012 .

[27]  B. Dunn,et al.  Electrical Energy Storage for the Grid: A Battery of Choices , 2011, Science.

[28]  Joeri Van Mierlo,et al.  Influence of functional unit on the life cycle assessment of traction batteries , 2007 .