International Journal of Renewable Energy Research-IJRER

Abstract- This paper addresses the problem of Micro-Grid (MG) Energy Management (EM) Control with considering a reduction in the overall cost of MG in a residential grid. The main motivation for this paper is to study the impact of Emissions from Distributed generators (DGs) and deterioration of energy storage devices (ESDs) on the overall operating cost of MG. One of the optimization targets to reduce the overall cost of MG operation is the emission of DGs and the deterioration of ESDs. This article offers a solution to the optimization issue while takes into account numerous constraints, utilizing of the Particle Swarm Optimization (PSO), Gravitational Search Algorithm (GSA), Hybrid Population-Based Algorithm (PSOGSA), and the suggested Capuchin Search Algorithm (Cap-SA). The usefulness and validity of the suggested method are shown using the simulation results by two scenarios without and with considering emission and degradation costs. Cap-SA has been contrasted with many effective optimization techniques. The results reveal that Cap-SA is an effective technique for reducing overall MG costs as compared with PSO by 29.5% and 25.5% in the first and second scenarios, respectively.

Y. Wang, C. Chen, J. Wang, and R. Baldick, ``Research on resilience of power systems under natural disasters_A review,'' IEEE Trans. Power Syst., vol. 31, no. 2, pp. 1604_1613, Mar. 2016.

Liu, Guodong, Thomas Ben Ollis, Yichen Zhang, Tao Jiang, and Kevin Tomsovic. "Robust microgrid scheduling with resiliency considerations." IEEE Access 8 (2020): 153169-153182.

Liu, Guodong, Tao Jiang, Thomas B. Ollis, Xue Li, Fangxing Li, and Kevin Tomsovic. "Resilient distribution system leveraging distributed generation and microgrids: A review." IET Energy Systems Integration 2, no. 4 (2020): 289-304.

X. Li, R. Zhang, L. Bai, G. Li, T. Jiang, and H. Chen, ``Stochastic low-carbon scheduling with carbon capture power plants and couponbased demand response,'' Appl. Energy, vol. 210, pp. 1219_1228, Jan. 2018.

G. Liu, T. Jiang, T. B. Ollis, X. Zhang, and K. Tomsovic, ``Distributed energy management for community microgrids considering network operational constraints and building thermal dynamics,'' Appl. Energy, vol. 239, pp. 83_95, Apr. 2019.

Elattar, Ehab E., and Salah K. Elsayed. "Optimal location and sizing of distributed generators based on renewable energy sources using modified moth flame optimization technique." IEEE Access 8 (2020): 109625-109638.

A. Hirsch, Y. Parag, and J. Guerrero, ``Microgrids: A review of technologies, key drivers, and outstanding issues,'' Renew. Sustain. Energy Rev., vol. 90, pp. 402_411, Jul. 2018.

Zeng, J.; Wang, Q.; Liu, J.; Chen, J.; Chen, H. A Potential Game Approach to Distributed Operational Optimization for Microgrid Energy ManagementWith Renewable Energy and Demand Response. IEEE Trans. Ind. Electron. 2019,66, 4479–4489.

Shuai, H.; Fang, J.; Ai, X.; Tang, Y.;Wen, J.; He, H. Stochastic optimization of economic dispatch for microgrid based on approximate dynamic programming. IEEE Trans. Smart Grid 2018, 10, 2440–2452.

Mengelkamp, E.; Gärttner, J.; Rock, K.; Kessler, S.; Orsini, L.; Weinhardt, C. Designing microgrid energy markets: A case study: The Brooklyn Microgrid. Appl. Energy 2018 210, 870–880.

G. Aghajani, N. Ghadimi, Multi-objective energy management in a micro-grid, Energy Rep. 4 (2018) 218e225.

L. Mellouk, et al., Design and energy management optimization for hybrid renewable energy system- case study: laayoune region, Renew. Energy 139 (2019) 621e634.

M. Jafari, Z. Malekjamshidi, Optimal energy management of a residential based hybrid renewable energy system using rule-based real-time control and 2D dynamic programming optimization method, Renew. Energy 146 (2020) 254e266.

B. Xu, J. Zhao, T. Zheng, E. Litvinov, D.S. Kirschen, Factoring the cycle aging cost of batteries participating in electricity markets, IEEE Trans. Power Syst. 33 (2) (2018) 2248–2259.

An, L. N.; Quoc-Tuan, T. Optimal energy management for grid connected microgrid by using dynamic programming method. In Proceedings of the 2015 IEEE Power & Energy Society General Meeting, Denver, CO, USA, 26–30 July 2015; pp. 1–5.

Dehghanpour, K.; Nehrir, H. Real-time multiobjective microgrid power management using distributed optimization in an agent-based bargaining framework. IEEE Trans. Smart Grid 2018, 9, 6318–6327.

Hong, Y.Y.; Hsiao, M.C.; Chang, Y.R.; Lee, Y.D.; Huang, H.C. Multiscenario underfrequency load shedding in a microgrid consisting of intermittent renewables. IEEE Trans. Power Deliv. 2013, 28, 1610–1617.

Liao, G.C. Solve environmental economic dispatch of Smart MicroGrid containing distributed generation system—Using chaotic quantum genetic algorithm. Int. J. Elect. Power Energy Syst. 2012, 43, 779–787.

Li, P.; Xu, D.; Zhou, Z.; Lee, W.J.; Zhao, B. Stochastic optimal operation of microgrid based on chaotic binary particle swarm optimization. IEEE Trans. Smart Grid 2016, 7, 66–73.

Radosavljevi´c, J.; Jevti´c, M.; Klimenta, D. Energy and operation management of a microgrid using particle swarm optimization. Eng. Optim. 2016, 48, 811–830.

MIRJALILI, Seyedali; HASHIM, Siti ZaitonMohd. A new hybrid PSOGSA algorithm for function optimization. In: 2010 international conference on computer and information application. IEEE, 2010. p. 374-377.?

Rashedi,E.; Nezamabadi-Pour, H.; Saryazdi,S.: A gravitational search algorithm. Inf. Sci. 2009, 179, 2232-2248.

Duman, S.; Guvenc, U.; Sonmez, Y.; Yörükeren, N. Optimal power flow using gravitational search algorithm. Energy Convers. Manag. 2012, 59, 86–95.

Braik M, Sheta A, Al-Hiary H: A novel meta-heuristic search algorithm for solving optimization problems: capuchin search algorithm. (2020) Neural Comput Appl 33(7):2515–2547.

J. Radosavljevic, Metaheuristic Optimization in Power Engineering, The Institution of Engineering and Technology (IET), London, UK, 2018.

WU, Xiaomin, et al. A Multi-Objective optimization dispatch method for microgrid energy management considering the power loss of converters. Energies, 2019, 12.11: 2160.?

POURMOUSAVI, S. Ali, et al. Real-time energy management of a stand-alone hybrid wind-microturbine energy system using particle swarm optimization. IEEE Transactions on Sustainable Energy, 2010, 1.3: 193-201.

M. F. Zia, E. Elbouchikhi, and M. Benbouzid, ``Optimal operational planning of scalable DC microgrid with demand response, islanding, and battery degradation cost considerations,'' Appl. Energy, vol. 237, pp. 695_707, Mar. 2019.

KENNEDY, James; EBERHART, Russell. Particle swarm optimization. In: Proceedings of ICNN'95-international conference on neural networks. IEEE, 1995. p. 1942-1948.?

C. Wang, “Modeling and control of hybrid wind/photovoltaic/fuel cell distributed generation systems,” Ph.D. dissertation, Montana State Univ., Bozeman, MT, 2006.