Solar-plus-storage benefits for end-users placed at radial and meshed grids: An economic and resiliency analysis

Abstract A resilient photovoltaic system, which comprises from the joint use of photovoltaic solar panels and electrochemical storage that is able to operate both with and without grid connection, is capable of providing an added service both during normal grid-connected operation and when a blackout occurs (as opposed to a traditional solar system). When the conventional power grid is in normal operation, resilient photovoltaic systems are able to generate revenue and/or reduce the electricity bill. During blackouts, resilient photovoltaic systems are capable of providing critical emergency power to help backup diesel generator systems. The research presented here evaluates the technical and economic feasibility of systems based on photovoltaic solar energy and electrochemical storage in three critical infrastructures which have to account with a typical backup diesel generator. To this end, the research presented here assigns a monetary value to the cost of avoiding a blackout. Thus, the REopt Lite software has been used to optimally select and dimension different resilient schemes. For each of the cases evaluated the resilient systems were able to obtain benefits associated with the substitution of the energy use of the electricity grid, the reduction of charges for the use of energy during peak energy periods, and the modification of energy purchase periods from periods of high cost to periods of low cost. For all cases the model found the optimal combination of technologies capable of minimizing the cost of energy throughout the life cycle of the project. The obtained results show that assigning a value to the cost of blackouts can have a major impact on the economic viability of a resilient solution. For all cases the net present value of a system was always higher when a value was assigned to resilience. The values assigned to resilience were higher for users plugged to radial networks, which are more prone to blackouts, and lower for users connected to meshed grids, usually more reliable. Despite the fact that for the investigation presented here only three types of infrastructures were assessed, similar results could be expected for other critical infrastructures with similar loads and electricity tariffs. Resilient systems using photovoltaic solar installations that are limited in size could provide both economic savings during normal grid-connected operation and limited emergency power during blackouts. When these systems based on photovoltaic solar energy and electrochemical storage are used in conjunction with an emergency diesel generator, these resilient “hybrid” systems are capable of satisfying critical loads during short- and long-term blackouts.

[1]  Robert Margolis,et al.  The Impact of Retail Electricity Tariff Evolution on Solar Photovoltaic Deployment , 2017 .

[2]  Benjamin Sovacool Renewable Energy: Economically Sound, Politically Difficult , 2008 .

[3]  Salman Mohagheghi,et al.  Optimal resilient power grid operation during the course of a progressing wildfire , 2015 .

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

[5]  Edoardo Patelli,et al.  Assessment of power grid vulnerabilities accounting for stochastic loads and model imprecision , 2018, International Journal of Electrical Power & Energy Systems.

[6]  Michael J. Sullivan,et al.  Estimated Value of Service Reliability for Electric Utility Customers in the United States , 2009 .

[7]  Travis Simpkins,et al.  REopt: A Platform for Energy System Integration and Optimization , 2014 .

[8]  Robert B. Bass,et al.  Calculation of levelized costs of electricity for various electrical energy storage systems , 2017 .

[9]  Deo Prasad,et al.  Designing with Solar Power: A Source Book for Building Integrated Photovoltaics (BiPV) , 2005 .

[10]  Henry Kelly,et al.  Renewable energy : sources for fuels and electricity , 1993 .

[11]  Bikash Kumar Sahu A study on global solar PV energy developments and policies with special focus on the top ten solar PV power producing countries , 2015 .

[12]  John Byrne,et al.  The value of module efficiency in lowering the levelized cost of energy of photovoltaic systems , 2011 .

[13]  R. Dufo-López,et al.  Economical and environmental analysis of grid connected photovoltaic systems in Spain , 2006 .

[14]  Janine Freeman,et al.  Integration, Validation, and Application of a PV Snow Coverage Model in SAM , 2015 .

[15]  Nicholas A. DiOrio,et al.  Economic Analysis Case Studies of Battery Energy Storage with SAM , 2015 .

[16]  Weihang Zhu,et al.  Regulatory islanding parameters in battery based solar PV for electricity system resiliency , 2016 .

[17]  Adam Hawkes,et al.  The future cost of electrical energy storage based on experience rates , 2017, Nature Energy.

[18]  Russell Bent,et al.  Resilient design of large-scale distribution feeders with networked microgrids , 2019, Electric Power Systems Research.

[19]  Paul Augustine,et al.  The next big thing in renewable energy: Shared solar , 2016 .

[20]  Lars Lisell,et al.  Quantifying and Monetizing Renewable Energy Resiliency , 2018 .

[21]  Anshuman Sahoo,et al.  The road ahead for solar PV power , 2018, Renewable and Sustainable Energy Reviews.

[22]  S. Hallegatte,et al.  Infrastructure Disruptions: How Instability Breeds Household Vulnerability , 2019 .

[23]  M. Safari,et al.  Simulation-Based Analysis of Aging Phenomena in a Commercial Graphite/LiFePO4 Cell , 2011 .

[24]  Mahmoud-Reza Haghifam,et al.  A linear two-stage method for resiliency analysis in distribution systems considering renewable energy and demand response resources , 2018 .

[25]  B. Marion,et al.  Performance parameters for grid-connected PV systems , 2005, Conference Record of the Thirty-first IEEE Photovoltaic Specialists Conference, 2005..

[26]  Albana Ilo,et al.  “Link”—The smart grid paradigm for a secure decentralized operation architecture , 2016 .

[27]  Joel Krupa,et al.  Renewable electricity finance in the United States: A state-of-the-art review , 2017 .

[28]  G. Soloveichik Battery technologies for large-scale stationary energy storage. , 2011, Annual review of chemical and biomolecular engineering.

[29]  Darrell F. Socie,et al.  Simple rainflow counting algorithms , 1982 .

[30]  J. Eto,et al.  A framework and review of customer outage costs: Integration and analysis of electric utility outage cost surveys , 2003 .

[31]  Emma M Elgqvist,et al.  Battery Energy Storage Market: Commercial Scale, Lithium-ion Projects in the U.S. , 2016 .

[32]  Richard Perez,et al.  Achieving very high PV penetration – The need for an effective electricity remuneration framework and a central role for grid operators , 2016 .

[33]  Houjun Tang,et al.  Renewable energy source (RES) based islanded DC microgrid with enhanced resilient control , 2019 .

[34]  Aron P. Dobos,et al.  PVWatts Version 5 Manual , 2014 .

[35]  Matt Brown,et al.  Feasibility of Solar Technology (Photovoltaic) Adoption: A Case Study on Tennessee's Poultry Industry , 2007 .

[36]  Anurag K. Srivastava,et al.  Integration of flow battery for resilience enhancement of advanced distribution grids , 2019, International Journal of Electrical Power & Energy Systems.

[37]  R. Oueid Microgrid finance, revenue, and regulation considerations , 2019, The Electricity Journal.

[38]  James F. Manwell,et al.  Lifetime Modelling of Lead Acid Batteries , 2005 .

[39]  Joyce McLaren,et al.  Solar-plus-storage economics: What works where, and why? , 2019, The Electricity Journal.

[40]  Neal Wade,et al.  An integrated approach for the analysis and control of grid connected energy storage systems , 2016 .

[41]  Yan Sun,et al.  Planning Emergency Shelters for Urban Disaster Resilience: An Integrated Location-Allocation Modeling Approach , 2017 .

[42]  Chris Deline,et al.  Photovoltaic Shading Testbed for Module-Level Power Electronics: 2016 Performance Data Update , 2016 .

[43]  Hak-Man Kim,et al.  Microgrids as a resilience resource and strategies used by microgrids for enhancing resilience , 2019, Applied Energy.

[44]  Nicholas A. DiOrio,et al.  Impacts of valuing resilience on cost-optimal PV and storage systems for commercial buildings , 2018, Renewable Energy.

[45]  Matthew Grimley,et al.  Design choices and equity implications of community shared solar , 2017 .

[46]  S. Hallegatte,et al.  Central Exams and Adult Skills: Evidence from PIAAC , 2021, SSRN Electronic Journal.

[47]  Mohammad Sadegh Sepasian,et al.  Pre-hurricane optimal placement model of repair teams to improve distribution network resilience , 2018, Electric Power Systems Research.

[48]  Joseph H. Eto,et al.  Cost of Power Interruptions to Electricity Consumers in the United States (U.S.) , 2006 .

[49]  J. Eto,et al.  Understanding the cost of power interruptions to U.S. electricity consumers , 2004 .

[50]  Zhaohong Bie,et al.  Tri-level optimal hardening plan for a resilient distribution system considering reconfiguration and DG islanding , 2018 .

[51]  Eric G. O'Rear,et al.  Purchasing vs. leasing: A benefit-cost analysis of residential solar PV panel use in California , 2014 .

[52]  Tao Ding,et al.  A resilient microgrid formation strategy for load restoration considering master-slave distributed generators and topology reconfiguration , 2017 .

[53]  Sylvie Genies,et al.  Lithium Batteries and other Electrochemical Storage Systems , 2013 .

[54]  K. Swift A comparison of the cost and financial returns for solar photovoltaic systems installed by businesses in different locations across the United States , 2013 .