Battery Energy Storage Models for Optimal Control

As batteries become more prevalent in grid energy storage applications, the controllers that decide when to charge and discharge become critical to maximizing their utilization. Controller design for these applications is based on models that mathematically represent the physical dynamics and constraints of batteries. Unrepresented dynamics in these models can lead to suboptimal control. Our goal is to examine the state-of-the-art with respect to the models used in optimal control of battery energy storage systems (BESSs). This review helps engineers navigate the range of available design choices and helps researchers by identifying gaps in the state-of-the-art. BESS models can be classified by physical domain: state-of-charge (SoC), temperature, and degradation. SoC models can be further classified by the units they use to define capacity: electrical energy, electrical charge, and chemical concentration. Most energy based SoC models are linear, with variations in ways of representing efficiency and the limits on power. The charge based SoC models include many variations of equivalent circuits for predicting battery string voltage. SoC models based on chemical concentrations use material properties and physical parameters in the cell design to predict battery voltage and charge capacity. Temperature is modeled through a combination of heat generation and heat transfer. Heat is generated through changes in entropy, overpotential losses, and resistive heating. Heat is transferred through conduction, radiation, and convection. Variations in thermal models are based on which generation and transfer mechanisms are represented and the number and physical significance of finite elements in the model. Modeling battery degradation can be done empirically or based on underlying physical mechanisms. Empirical stress factor models isolate the impacts of time, current, SoC, temperature, and depth-of-discharge (DoD) on battery state-of-health (SoH). Through a few simplifying assumptions, these stress factors can be represented using regularization norms. Physical degradation models can further be classified into models of side-reactions and those of material fatigue. This article demonstrates the importance of model selection to optimal control by providing several example controller designs. Simpler models may overestimate or underestimate the capabilities of the battery system. Adding details can improve accuracy at the expense of model complexity, and computation time. Our analysis identifies six gaps: deficiency of real-world data in control literature, lack of understanding in how to balance modeling detail with the number of representative cells, underdeveloped model uncertainty based risk-averse and robust control of BESS, underdevelopment of nonlinear energy based SoC models, lack of hysteresis in voltage models used for control, lack of entropy heating and cooling in thermal modeling, and deficiency of knowledge in what combination of empirical degradation stress factors is most accurate. These gaps are opportunities for future research.

[1]  Raymond H. Byrne,et al.  Adaptive Model Predictive Control for Real-Time Dispatch of Energy Storage Systems , 2019, 2019 American Control Conference (ACC).

[2]  Richard D. Braatz,et al.  Modeling and Simulation of Lithium-Ion Batteries from a Systems Engineering Perspective , 2010 .

[3]  Ning Lu,et al.  Control and size energy storage systems for managing energy imbalance of variable generation resources , 2015, 2015 IEEE Power & Energy Society General Meeting.

[4]  Hendrik Johannes Bergveld,et al.  Battery management systems : design by modelling , 2001 .

[5]  Sina Ober-Blöbaum,et al.  Improving optimal control of grid-connected lithium-ion batteries through more accurate battery and degradation modelling , 2017, ArXiv.

[6]  Sigifredo Gonzalez,et al.  Performance Model for Grid-Connected Photovoltaic Inverters , 2007 .

[7]  W. Lu,et al.  A Comprehensive Experimental and Modeling Study on Dissolution in Li-Ion Batteries , 2019, Journal of The Electrochemical Society.

[8]  Yoon-Ho Kim,et al.  Design of interface circuits with electrical battery models , 1997, IEEE Trans. Ind. Electron..

[9]  P. Gilman,et al.  MICROPOWER SYSTEM MODELING WITH HOMER , 2005 .

[10]  Jun Liu,et al.  Effect of entropy change of lithium intercalation in cathodes and anodes on Li-ion battery thermal management , 2010 .

[11]  Dirk Uwe Sauer,et al.  A holistic aging model for Li(NiMnCo)O2 based 18650 lithium-ion batteries , 2014 .

[12]  John Newman,et al.  Cyclable Lithium and Capacity Loss in Li-Ion Cells , 2005 .

[13]  Marcos J. Rider,et al.  Optimal Operation of Distribution Networks Considering Energy Storage Devices , 2015, IEEE Transactions on Smart Grid.

[14]  Marc Doyle,et al.  Mathematical Modeling of the Lithium Deposition Overcharge Reaction in Lithium‐Ion Batteries Using Carbon‐Based Negative Electrodes , 1999 .

[15]  G. F. Reed,et al.  Survey of battery energy storage systems and modeling techniques , 2012, 2012 IEEE Power and Energy Society General Meeting.

[16]  Matthew K. Donnelly,et al.  Methodology to determine the technical performance and value proposition for grid-scale energy storage systems : , 2012 .

[17]  Gan Ning,et al.  Cycle Life Modeling of Lithium-Ion Batteries , 2004 .

[18]  Yasser Abdel-Rady I. Mohamed,et al.  Market-Oriented Energy Management of a Hybrid Wind-Battery Energy Storage System Via Model Predictive Control With Constraint Optimizer , 2015, IEEE Transactions on Industrial Electronics.

[19]  Xiao-Ping Zhang,et al.  Impacts of Energy Storage on Short Term Operation Planning Under Centralized Spot Markets , 2014, IEEE Transactions on Smart Grid.

[20]  Tor Arne Johansen,et al.  Battery Power Smoothing Control in a Marine Electric Power Plant Using Nonlinear Model Predictive Control , 2017, IEEE Transactions on Control Systems Technology.

[21]  Olivier Tremblay,et al.  Experimental validation of a battery dynamic model for EV applications , 2009 .

[22]  Ralph E. White,et al.  Single-Particle Model for a Lithium-Ion Cell: Thermal Behavior , 2011 .

[23]  Xiao-Ping Zhang,et al.  Model predictive control for energy storage systems in a network with high penetration of renewable energy and limited export capacity , 2014, 2014 Power Systems Computation Conference.

[24]  Mohammad A. S. Masoum,et al.  Optimal Operation of Distributed Energy Storage Systems to Improve Distribution Network Load and Generation Hosting Capability , 2016, IEEE Transactions on Sustainable Energy.

[25]  Henk Jan Bergveld,et al.  Electronic network modeling of rechargeable batteries: II: The NiCd system , 1998 .

[26]  Sam Akehurst,et al.  Minimizing Battery Stress during Hybrid Electric Vehicle Control Design: Real World Considerations for Model-Based Control Development , 2013, 2013 IEEE Vehicle Power and Propulsion Conference (VPPC).

[27]  W. Deen Analysis Of Transport Phenomena , 1998 .

[28]  Jianqiu Li,et al.  Simplification of physics-based electrochemical model for lithium ion battery on electric vehicle. Part II: Pseudo-two-dimensional model simplification and state of charge estimation , 2015 .

[29]  Ross Baldick,et al.  Risk-Averse Model Predictive Control Design for Battery Energy Storage Systems , 2020, IEEE Transactions on Smart Grid.

[30]  Rochdi Trigui,et al.  Optimal management of electric vehicles with a hybrid storage system , 2010, 2010 IEEE Vehicle Power and Propulsion Conference.

[31]  Surya Santoso,et al.  Optimal Control of a Battery Energy Storage System with a Charge-Temperature-Health Model , 2019, 2019 IEEE Power & Energy Society General Meeting (PESGM).

[32]  T. Kim,et al.  A Hybrid Battery Model Capable of Capturing Dynamic Circuit Characteristics and Nonlinear Capacity Effects , 2011, IEEE Transactions on Energy Conversion.

[33]  Peng Wang,et al.  A Hybrid AC/DC Microgrid and Its Coordination Control , 2011, IEEE Transactions on Smart Grid.

[34]  Matthew B. Pinson,et al.  Theory of SEI Formation in Rechargeable Batteries: Capacity Fade, Accelerated Aging and Lifetime Prediction , 2012, 1210.3672.

[35]  Mariesa L. Crow,et al.  A Field Validated Model of a Vanadium Redox Flow Battery for Microgrids , 2014, IEEE Transactions on Smart Grid.

[36]  Lino Guzzella,et al.  Battery State-of-Health Perceptive Energy Management for Hybrid Electric Vehicles , 2012, IEEE Transactions on Vehicular Technology.

[37]  Petru Dobra,et al.  An improvement on empirical modelling of the batteries , 2009, 2009 32nd International Spring Seminar on Electronics Technology.

[38]  M. Scott Trimboli,et al.  Lithium-ion battery cell-level control using constrained model predictive control and equivalent circuit models , 2015 .

[39]  Yuying Yan,et al.  A critical review of thermal management models and solutions of lithium-ion batteries for the development of pure electric vehicles , 2016 .

[40]  Daniel S. Kirschen,et al.  Factoring the Cycle Aging Cost of Batteries Participating in Electricity Markets , 2017, 2018 IEEE Power & Energy Society General Meeting (PESGM).

[41]  M. Ceraolo,et al.  New dynamical models of lead-acid batteries , 2000 .

[42]  David L. Woodruff,et al.  Pyomo: modeling and solving mathematical programs in Python , 2011, Math. Program. Comput..

[43]  Federico Silvestro,et al.  Optimal Management Strategy of a Battery-Based Storage System to Improve Renewable Energy Integration in Distribution Networks , 2012, IEEE Transactions on Smart Grid.

[44]  Anna G. Stefanopoulou,et al.  An Energy-Optimal Warm-Up Strategy for Li-Ion Batteries and Its Approximations , 2019, IEEE Transactions on Control Systems Technology.

[45]  Vassilios G. Agelidis,et al.  Power Management for Improved Dispatch of Utility-Scale PV Plants , 2016, IEEE Transactions on Power Systems.

[46]  David A. Copp,et al.  Market Evaluation of Energy Storage Systems Incorporating Technology-Specific Nonlinear Models , 2019, IEEE Transactions on Power Systems.

[47]  M. R. Palacín,et al.  Why do batteries fail? , 2016, Science.

[48]  S. Barsali,et al.  Dynamical Models of Lead-Acid Batteries: Implementation Issues , 2002, IEEE Power Engineering Review.

[49]  Min Chen,et al.  Accurate electrical battery model capable of predicting runtime and I-V performance , 2006, IEEE Transactions on Energy Conversion.

[50]  Shahin Sirouspour,et al.  An Optimal Energy Storage Control Strategy for Grid-connected Microgrids , 2014, IEEE Transactions on Smart Grid.

[51]  Richard D. Braatz,et al.  Optimal Charging Profiles with Minimal Intercalation-Induced Stresses for Lithium-Ion Batteries Using Reformulated Pseudo 2-Dimensional Models , 2014 .

[52]  Sanjeev Srivastava,et al.  Battery life-cycle optimization and runtime control for commercial buildings demand side management: A New York City case study , 2018, Energy.

[53]  F. V. P. Robinson,et al.  Analysis of Battery Lifetime Extension in a Small-Scale Wind-Energy System Using Supercapacitors , 2013, IEEE Transactions on Energy Conversion.

[54]  Lorenz T. Biegler,et al.  On the implementation of an interior-point filter line-search algorithm for large-scale nonlinear programming , 2006, Math. Program..

[55]  Jonathan Donadee,et al.  Stochastic Optimization of Grid to Vehicle Frequency Regulation Capacity Bids , 2014, IEEE Transactions on Smart Grid.

[56]  Mark W. Verbrugge,et al.  Evolution of stress within a spherical insertion electrode particle under potentiostatic and galvanostatic operation , 2009 .

[57]  Sigifredo Gonzalez,et al.  Performance Test Protocol for Evaluating Inverters Used in Grid-Connected Photovoltaic Systems. , 2015 .

[58]  M. Wohlfahrt‐Mehrens,et al.  Li plating as unwanted side reaction in commercial Li-ion cells - A review , 2018 .

[59]  Xiaosong Hu,et al.  Optimal Charging of Li-Ion Batteries via a Single Particle Model with Electrolyte and Thermal Dynamics , 2017 .

[60]  Daniel S. Kirschen,et al.  Modeling of Lithium-Ion Battery Degradation for Cell Life Assessment , 2018, IEEE Transactions on Smart Grid.

[61]  Rolf Findeisen,et al.  Electrochemical Model Based Observer Design for a Lithium-Ion Battery , 2013, IEEE Transactions on Control Systems Technology.

[62]  Xiaosong Hu,et al.  Optimal charging of batteries via a single particle model with electrolyte and thermal dynamics , 2016, 2016 American Control Conference (ACC).

[63]  Mario Paolone,et al.  A Decentralized Adaptive Model-Based Real-Time Control for Active Distribution Networks Using Battery Energy Storage Systems , 2018, IEEE Transactions on Smart Grid.

[64]  Hamed Mohsenian-Rad Coordinated Price-Maker Operation of Large Energy Storage Units in Nodal Energy Markets , 2016, IEEE Transactions on Power Systems.

[65]  Hosam K. Fathy,et al.  An Extended Differential Flatness Approach for the Health-Conscious Nonlinear Model Predictive Control of Lithium-Ion Batteries , 2017, IEEE Transactions on Control Systems Technology.

[66]  Yingsong Huang,et al.  Adaptive Electricity Scheduling in Microgrids , 2014, IEEE Transactions on Smart Grid.

[67]  Marcel Lacroix,et al.  Review of simplified Pseudo-two-Dimensional models of lithium-ion batteries , 2016 .

[68]  P. Rodriguez,et al.  Predictive Power Control for PV Plants With Energy Storage , 2013, IEEE Transactions on Sustainable Energy.

[69]  Yanwei Liu,et al.  Multi-Objective Optimization of Energy Management Strategy on Hybrid Energy Storage System Based on Radau Pseudospectral Method , 2019, IEEE Access.

[70]  J. Driesen,et al.  Multiobjective Battery Storage to Improve PV Integration in Residential Distribution Grids , 2013, IEEE Transactions on Sustainable Energy.

[71]  Chaoyang Wang,et al.  Micro‐Macroscopic Coupled Modeling of Batteries and Fuel Cells I. Model Development , 1998 .

[72]  Ralph E. White,et al.  Capacity Fade Mechanisms and Side Reactions in Lithium‐Ion Batteries , 1998 .

[73]  Vassilios G. Agelidis,et al.  A Model Predictive Control System for a Hybrid Battery-Ultracapacitor Power Source , 2014, IEEE Transactions on Power Electronics.

[74]  Subhashish Bhattacharya,et al.  Optimal Control of Battery Energy Storage for Wind Farm Dispatching , 2010, IEEE Transactions on Energy Conversion.

[75]  Venkat R. Subramanian,et al.  Generic Model Control for Lithium-Ion Batteries , 2017 .

[76]  Raymond H. Byrne,et al.  Energy Management and Optimization Methods for Grid Energy Storage Systems , 2018, IEEE Access.

[77]  Teemu Lehmuspelto,et al.  Time-Domain Parameter Extraction Method for Thévenin-Equivalent Circuit Battery Models , 2014, IEEE Transactions on Energy Conversion.

[78]  Ralph E. White,et al.  Thermal Model for Lithium Ion Battery Pack with Mixed Parallel and Series Configuration , 2011 .

[79]  Sebastian Ehrlichmann,et al.  Integration Of Alternative Sources Of Energy , 2016 .

[80]  N A Chaturvedi,et al.  Modeling, estimation, and control challenges for lithium-ion batteries , 2010, Proceedings of the 2010 American Control Conference.

[81]  M. Verbrugge,et al.  Cycle-life model for graphite-LiFePO 4 cells , 2011 .

[82]  Ira Bloom,et al.  Statistical methodology for predicting the life of lithium-ion cells via accelerated degradation testing , 2008 .

[83]  G. Yin,et al.  Multi-stress factor model for cycle lifetime prediction of lithium ion batteries with shallow-depth discharge , 2015 .

[84]  A. Abdel-azim Fundamentals of Heat and Mass Transfer , 2011 .

[85]  Ralph E. White,et al.  Thermodynamic model development for lithium intercalation electrodes , 2008 .

[86]  Dale T. Bradshaw,et al.  DOE/EPRI Electricity Storage Handbook in Collaboration with NRECA , 2016 .

[87]  Hongwen He,et al.  Critical Review on the Battery State of Charge Estimation Methods for Electric Vehicles , 2018, IEEE Access.

[88]  Trudie Wang,et al.  Control and Optimization of Grid-Tied Photovoltaic Storage Systems Using Model Predictive Control , 2014, IEEE Transactions on Smart Grid.

[89]  Jonathan Donadee,et al.  AGC Signal Modeling for Energy Storage Operations , 2014, IEEE Transactions on Power Systems.

[90]  Yixiao Zhang,et al.  Degradation Analysis of Commercial Lithium-Ion Battery in Long-Term Storage , 2017 .

[91]  Mariesa L. Crow,et al.  Battery Energy Storage System (BESS) and Battery Management System (BMS) for Grid-Scale Applications , 2014, Proceedings of the IEEE.

[92]  Andrew Wirth,et al.  Optimal operation of energy storage systems considering forecasts and battery degradation , 2017, 2017 IEEE Power & Energy Society General Meeting.

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

[94]  Sam Akehurst,et al.  Stochastic Dynamic Programming in the Real-World Control of Hybrid Electric Vehicles , 2016, IEEE Transactions on Control Systems Technology.

[95]  Ross Baldick,et al.  Applied Optimization: Formulation and Algorithms for Engineering Systems (Baldick, R.; 2006) , 2008, IEEE Control Systems.

[96]  Xiaosong Hu,et al.  Optimal Charging of Li-Ion Batteries With Coupled Electro-Thermal-Aging Dynamics , 2017, IEEE Transactions on Vehicular Technology.

[97]  Mohammadhosein Safari,et al.  Life-Prediction Methods for Lithium-Ion Batteries Derived from a Fatigue Approach I. Introduction: Capacity-Loss Prediction Based on Damage Accumulation , 2010 .

[98]  Surya Santoso,et al.  Optimal Field Voltage and Energy Storage Control for Stabilizing Synchronous Generators on Flexible AC Transmission Systems , 2018, 2018 IEEE/PES Transmission and Distribution Conference and Exposition (T&D).

[99]  Surya Santoso,et al.  Sizing and Coordinating Fast- and Slow-Response Energy Storage Systems to Mitigate Hourly Wind Power Variations , 2018, IEEE Transactions on Smart Grid.

[100]  Gilsung Byeon,et al.  Optimal Operation Control for Multiple BESSs of a Large-Scale Customer Under Time-Based Pricing , 2018, IEEE Transactions on Power Systems.

[101]  Victor O. K. Li,et al.  Capacity Estimation for Vehicle-to-Grid Frequency Regulation Services With Smart Charging Mechanism , 2014, IEEE Transactions on Smart Grid.

[102]  R. Braatz,et al.  Design of Piecewise Affine and Linear Time-Varying Model Predictive Control Strategies for Advanced Battery Management Systems , 2017 .

[103]  Yvonne Freeh,et al.  Handbook Of Batteries , 2016 .

[104]  Krishnan S. Hariharan,et al.  A Strain-Diffusion Coupled Electrochemical Model for Lithium-Ion Battery , 2017 .

[105]  M. Verbrugge,et al.  Degradation of lithium ion batteries employing graphite negatives and nickel-cobalt-manganese oxide + spinel manganese oxide positives: Part 1, aging mechanisms and life estimation , 2014 .

[106]  Richard D. Braatz,et al.  Real-time model predictive control for the optimal charging of a lithium-ion battery , 2015, 2015 American Control Conference (ACC).

[107]  Ralph E. White,et al.  Development of First Principles Capacity Fade Model for Li-Ion Cells , 2004 .

[108]  Raymond H. Byrne,et al.  Maximizing the cost-savings for time-of-use and net-metering customers using behind-the-meter energy storage systems , 2017, 2017 North American Power Symposium (NAPS).

[109]  T. Fuller,et al.  A Critical Review of Thermal Issues in Lithium-Ion Batteries , 2011 .

[110]  Shriram Santhanagopalan,et al.  Multi-Domain Modeling of Lithium-Ion Batteries Encompassing Multi-Physics in Varied Length Scales , 2011 .

[111]  Raymond H. Byrne,et al.  Effect of Operating Strategies on the Longevity of Lithium-ion Battery Energy Storage Systems , 2018, 2018 IEEE Industry Applications Society Annual Meeting (IAS).

[112]  Dirk Uwe Sauer,et al.  Development of a lifetime prediction model for lithium-ion batteries based on extended accelerated aging test data , 2012 .

[113]  J. Jatskevich,et al.  Power Quality Control of Wind-Hybrid Power Generation System Using Fuzzy-LQR Controller , 2007, IEEE Transactions on Energy Conversion.

[114]  Xue Feng,et al.  Hybrid Energy Storage With Multimode Fuzzy Power Allocator for PV Systems , 2014, IEEE Transactions on Sustainable Energy.

[115]  Y Riffonneau,et al.  Optimal Power Flow Management for Grid Connected PV Systems With Batteries , 2011, IEEE Transactions on Sustainable Energy.

[116]  Andrea Zanella,et al.  Optimal and Compact Control Policies for Energy Storage Units With Single and Multiple Batteries , 2014, IEEE Transactions on Smart Grid.

[117]  Ralph E. White,et al.  Review of Models for Predicting the Cycling Performance of Lithium Ion Batteries , 2006 .

[118]  Ali Emadi,et al.  Fast Model Predictive Control for Redistributive Lithium-Ion Battery Balancing , 2017, IEEE Transactions on Industrial Electronics.

[119]  R. H. Newnham,et al.  Valve-regulated lead/acid batteries , 1996 .

[120]  Daniel Kirschen,et al.  Optimal Battery Control Under Cycle Aging Mechanisms in Pay for Performance Settings , 2017, IEEE Transactions on Automatic Control.

[121]  M. A. Hannan,et al.  State of Charge Estimation for Lithium-Ion Batteries Using Model-Based and Data-Driven Methods: A Review , 2019, IEEE Access.

[122]  Hosam K. Fathy,et al.  Battery-Health Conscious Power Management in Plug-In Hybrid Electric Vehicles via Electrochemical Modeling and Stochastic Control , 2013, IEEE Transactions on Control Systems Technology.

[123]  Christopher Masjosthusmann,et al.  A vehicle energy management system for a Battery Electric Vehicle , 2012, 2012 IEEE Vehicle Power and Propulsion Conference.

[124]  M. Doyle,et al.  Simulation and Optimization of the Dual Lithium Ion Insertion Cell , 1994 .

[125]  Helmuth Biechl,et al.  Modelling of Li-ion batteries using equivalent circuit diagrams , 2012 .

[126]  M. Safari,et al.  Multimodal Physics-Based Aging Model for Life Prediction of Li-Ion Batteries , 2009 .

[127]  Ralph E. White,et al.  Parameter Estimation and Model Discrimination for a Lithium-Ion Cell , 2007 .

[128]  Mahmoud F. Elmorshedy,et al.  Design Optimization and Model Predictive Control of a Standalone Hybrid Renewable Energy System: A Case Study on a Small Residential Load in Pakistan , 2019, IEEE Access.

[129]  Jianqiu Li,et al.  Simplification of physics-based electrochemical model for lithium ion battery on electric vehicle. Part I: Diffusion simplification and single particle model , 2015 .