A rule-based energy management scheme for long-term optimal capacity planning of grid-independent microgrid optimized by multi-objective grasshopper optimization algorithm

Abstract Off-grid electrification of remote communities using sustainable energy systems (SESs) is a requisite for realizing sustainable development goals. Nonetheless, the capacity planning of the SESs is challenging as it needs to fulfil the fluctuating demand from a long-term perspective, in addition to the intermittency and unpredictable nature of renewable energy sources (RESs). Owing to the nonlinear and non-convex nature of the capacity planning problem, an efficient technique must be employed to achieve a cost-effective system. Existing techniques are, subject to some constraints on the derivability and continuity of the objective function, prone to premature convergence, computationally demanding, follows rigorous procedures to fine-tune the algorithm parameters in different applications, and often do not offer a fair balance during the exploitation and exploration phase of the optimization process. Furthermore, the literature review indicates that researchers often do not implement and examine the energy management scheme (EMS) of a microgrid while computing for the capacity planning problem of microgrids. This paper proposes a rule-based EMS (REMS) optimized by a nature-inspired grasshopper optimization algorithm (GOA) for long-term capacity planning of a grid-independent microgrid incorporating a wind turbine, a photovoltaic, a battery (BT) bank and a diesel generator ( D g e n ). In which, a rule-based algorithm is used to implement an EMS to prioritize the usage of RES and coordinate the power flow of the proposed microgrid components. Subsequently, an attempt is made to explore and confirm the efficiency of the proposed REMS incorporated with GOA. The ultimate goal of the objective function is to minimize the cost of energy (COE) and the deficiency of power supply probability (DPSP). The performance of the REMS is examined via a long-term simulation study to ascertain the REMS resiliency and to ensure the operating limit of the BT storage is not violated. The result of the GOA is compared with particle swarm optimization (PSO) and a cuckoo search algorithm (CSA). The simulation results indicate that the proposed technique’s superiority is confirmed in terms of convergence to the optimal solution. The simulation results confirm that the proposed REMS has contributed to better adoption of a cleaner energy production system, as the scheme significantly reduces fuel consumption, CO 2 emission and COE by 92.4%, 92.3% and 79.8%, respectively as compared to the conventional D g e n . The comparative evaluation of the algorithms shows that REMS-GOA yields a better result as it offers the least COE (objective function), at $0.3656/kW h, as compared to the REMS-CSA at $0.3662/kW h and REMS-PSO at $0.3674/kW h, for the desired DPSP of 0%. Finally, sensitivity analysis is performed to highlight the effect of uncertainties on the system inputs that may arise in the future.

[1]  Prashant Nagapurkar,et al.  Techno-economic optimization and environmental Life Cycle Assessment (LCA) of microgrids located in the US using genetic algorithm , 2019, Energy Conversion and Management.

[2]  Daniel Burmester,et al.  A demand response-centred approach to the long-term equipment capacity planning of grid-independent micro-grids optimized by the moth-flame optimization algorithm , 2019, Energy Conversion and Management.

[3]  Rachid Ibtiouen,et al.  Firefly-inspired algorithm for optimal sizing of renewable hybrid system considering reliability criteria , 2017 .

[4]  Hossam Faris,et al.  Grasshopper optimization algorithm for multi-objective optimization problems , 2017, Applied Intelligence.

[5]  Abdolvahhab Fetanat,et al.  Size optimization for hybrid photovoltaic-wind energy system using ant colony optimization for continuous domains based integer programming , 2015, Appl. Soft Comput..

[6]  C. H. Lo,et al.  Economic dispatch and optimal sizing of battery energy storage systems in utility load-leveling operations , 1999 .

[7]  Zainal Salam,et al.  A rule-based energy management scheme for uninterrupted electric vehicles charging at constant price using photovoltaic-grid system , 2018, Renewable Energy.

[8]  Weerakorn Ongsakul,et al.  Artificial Intelligence in Power System Optimization , 2013 .

[9]  Hossam Faris,et al.  Salp Swarm Algorithm: A bio-inspired optimizer for engineering design problems , 2017, Adv. Eng. Softw..

[10]  José L. Bernal-Agustín,et al.  Multi-objective design of PV–wind–diesel–hydrogen–battery systems , 2008 .

[11]  Akbar Maleki,et al.  A novel framework for optimal photovoltaic size and location in remote areas using a hybrid method: A case study of eastern Iran , 2017 .

[12]  K. Benmansour,et al.  Grey wolf optimizer for optimal design of hybrid renewable energy system PV-Diesel Generator-Battery: Application to the case of Djanet city of Algeria , 2017 .

[13]  Musa Mustapha,et al.  Economic Assessment of a PV/Diesel/Battery Hybrid Energy System for a Non-Electrified Remote Village in Nigeria , 2017 .

[14]  Hongxing Yang,et al.  A feasibility study of a stand-alone hybrid solar–wind–battery system for a remote island , 2014 .

[15]  Temitope Raphael Ayodele,et al.  Increasing household solar energy penetration through load partitioning based on quality of life: The case study of Nigeria , 2015 .

[16]  Akbar Maleki,et al.  Sizing of stand-alone photovoltaic/wind/diesel system with battery and fuel cell storage devices by harmony search algorithm , 2015 .

[17]  Temitope Raphael Ayodele,et al.  Optimal allocation and sizing of PV/Wind/Split-diesel/Battery hybrid energy system for minimizing life cycle cost, carbon emission and dump energy of remote residential building , 2016 .

[18]  Xin-She Yang,et al.  A New Metaheuristic Bat-Inspired Algorithm , 2010, NICSO.

[19]  Chunwei Zhang,et al.  A novel hybrid chaotic ant swarm algorithm for heat exchanger networks synthesis , 2016 .

[20]  Giuseppe Marco Tina,et al.  Optimal hydrogen storage sizing for wind power plants in day ahead electricity market , 2007 .

[21]  Jason Brownlee,et al.  Clever Algorithms: Nature-Inspired Programming Recipes , 2012 .

[22]  G. Venkataramanan,et al.  Optimal Technology Selection and Operation of Commercial-Building Microgrids , 2008, IEEE Transactions on Power Systems.

[23]  Azhar Khairuddin,et al.  Placement and sizing of multiple distributed generation and battery swapping stations using grasshopper optimizer algorithm , 2018, Energy.

[24]  Gevork B. Gharehpetian,et al.  Optimal sizing and techno-economic analysis of energy- and cost-efficient standalone multi-carrier microgrid , 2019, Energy.

[25]  Mohammad Hossein Ahmadi,et al.  Analysis of stakeholder roles and the challenges of solar energy utilization in Iran , 2018, International Journal of Low-Carbon Technologies.

[26]  Alan C. Brent,et al.  Economic viability assessment of sustainable hydrogen production, storage, and utilisation technologies integrated into on- and off-grid micro-grids: A performance comparison of different meta-heuristics , 2020 .

[27]  A. García-Olivares,et al.  Transportation in a 100% renewable energy system , 2018 .

[28]  Andrew Lewis,et al.  Grasshopper Optimisation Algorithm: Theory and application , 2017, Adv. Eng. Softw..

[29]  Akbar Maleki,et al.  Optimal sizing of autonomous hybrid photovoltaic/wind/battery power system with LPSP technology by using evolutionary algorithms , 2015 .

[30]  Subhadeep Bhattacharjee,et al.  Grey wolf optimisation for optimal sizing of battery energy storage device to minimise operation cost of microgrid , 2016 .

[31]  G. Barakat,et al.  Design and optimal sizing of hybrid PV/wind/diesel system with battery storage by using DIRECT search algorithm , 2012, 2012 15th International Power Electronics and Motion Control Conference (EPE/PEMC).

[32]  Li Cheng,et al.  A New Metaheuristic Bat-Inspired Algorithm , 2010 .

[33]  Alibakhsh Kasaeian,et al.  Optimizing a hybrid wind-PV-battery system using GA-PSO and MOPSO for reducing cost and increasing reliability , 2017, Energy.

[34]  Roghayeh Ghasempour,et al.  Analysis of Solar Farm Site Selection Based on TOPSIS Approach , 2018 .

[35]  Chee Wei Tan,et al.  A review on stand-alone photovoltaic-wind energy system with fuel cell: System optimization and energy management strategy , 2019, Journal of Cleaner Production.

[36]  A. Yahiaouia,et al.  Grey wolf optimizer for optimal design of hybrid renewable energy system PV-Diesel Generator-Battery: Application to the case of Djanet city of Algeria , 2018 .

[37]  Marc A. Rosen,et al.  A heuristic-based approach for optimizing a small independent solar and wind hybrid power scheme incorporating load forecasting , 2019 .

[38]  M. Ansarian,et al.  Distributed Generation and Renewable Planning with a Linear Programming Model , 2006, 2006 IEEE International Power and Energy Conference.

[39]  K. Y. Lau,et al.  Economic Analysis of Residential Grid-connected Photovoltaic System with Lithium-ion Battery Storage , 2019, 2019 IEEE Conference on Energy Conversion (CENCON).

[40]  David C. Yu,et al.  Optimal sizing of hybrid PV/diesel/battery in ship power system ☆ , 2015 .

[41]  Mohd Wazir Mustafa,et al.  Optimal Voltage and Frequency Control of an Islanded Microgrid using Grasshopper Optimization Algorithm , 2018, Energies.

[42]  C. Abeykoon,et al.  Energy and exergy efficiencies enhancement analysis of integrated photovoltaic-based energy systems , 2019 .

[43]  Mayur Barman,et al.  A regional hybrid GOA-SVM model based on similar day approach for short-term load forecasting in Assam, India , 2018 .

[44]  Sunanda Sinha,et al.  Review of recent trends in optimization techniques for solar photovoltaic–wind based hybrid energy systems , 2015 .

[45]  Navid Ghaffarzadeh,et al.  Optimal sizing of battery energy storage systems in off-grid micro grids using convex optimization , 2019, Journal of Energy Storage.

[46]  T.C. Green,et al.  Fuel consumption minimization of a microgrid , 2005, IEEE Transactions on Industry Applications.

[47]  Xiaohua Xia,et al.  Switched Model Predictive Control for Energy Dispatching of a Photovoltaic-Diesel-Battery Hybrid Power System , 2015, IEEE Transactions on Control Systems Technology.

[48]  Mohammad Hassan Moradi,et al.  An optimal programming among renewable energy resources and storage devices for responsive load integration in residential applications using hybrid of grey wolf and shark smell algorithms , 2020 .

[49]  Fathollah Pourfayaz,et al.  Harmony search optimization for optimum sizing of hybrid solar schemes based on battery storage unit , 2020 .

[50]  S.M.M. Tafreshi,et al.  Unit Sizing of a Stand-alone Hybrid Power System Using Particle Swarm Optimization (PSO) , 2007, 2007 IEEE International Conference on Automation and Logistics.

[51]  Musa Mustapha,et al.  Techno-Economic Analysis of Off-Grid Hybrid PV-Diesel-Battery System in Katsina State, Nigeria , 2018 .

[52]  Mukesh Singh,et al.  Feasibility study of an islanded microgrid in rural area consisting of PV, wind, biomass and battery energy storage system , 2016 .

[53]  Marc A. Rosen,et al.  Sizing a stand-alone solar-wind-hydrogen energy system using weather forecasting and a hybrid search optimization algorithm , 2019, Energy Conversion and Management.

[54]  Yanjun Li,et al.  Optimal Sizing of a Stand-Alone Hybrid Power System Based on Battery/Hydrogen with an Improved Ant Colony Optimization , 2016 .

[55]  Kiran Jasthi,et al.  Grasshopper optimization algorithm based two stage fuzzy multiobjective approach for optimum sizing and placement of distributed generations, shunt capacitors and electric vehicle charging stations , 2020 .

[56]  Dipti Srinivasan,et al.  An improved particle swarm optimisation algorithm applied to battery sizing for stand-alone hybrid power systems , 2016 .

[57]  Gino Bella,et al.  Power management of a hybrid renewable system for artificial islands: A case study , 2016 .