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Electrical Engineering

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09.01.2023 | Original Paper

Multi-period optimal scheduling framework in an islanded smart distribution network considering load priorities

verfasst von: B. Ramesh, Mohan Khedkar, Nitin Kumar Kulkarni, Raushan Kumar

Erschienen in: Electrical Engineering | Ausgabe 2/2023

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Abstract

In this article, a multi-period optimal scheduling framework considering load priorities is proposed to optimize the operation of an islanded smart distribution network. The main idea of this work is to provide sufficient power supply to high priority loads even during limited generation periods while also assuring network security and achieving optimal generation schedules for distributed energy resources and optimal charging/discharging schedules for battery bank (BB). The proposed scheduling framework is formulated as a multi-objective optimization problem in four different operating cases, over multiple time periods considering conventional generation sources, renewable energy sources, battery bank (BB), and various loads. Loads comprise hospitals, public consumer loads, industries, education centers, and domestic loads. The usual objectives of optimal scheduling problems in the literature are minimizing network power loss, total cost of generation, and maximizing customer benefit; however, less attention has been paid to distribution network security. Therefore, in this article, voltage stability index is considered as one of the objective functions along with network power loss, total cost of generation, and total load curtailment. The proposed scheduling problem is solved using Non-dominated Sorting Genetic Algorithm-II (NSGA-II), and its performance is evaluated on the modified IEEE 34 bus system. The accuracy of results is verified by comparing with the results obtained by solving the proposed scheduling problem using Python optimization modeling objects (Pyomo) software with interior point optimizer as the solver.

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Kumar R, Kumar A (2020) Optimal scheduling for solar wind and pumped storage systems considering imbalance penalty. Energy Sources Part A: Recovery Util Environ Effects. https://doi.org/10.1080/15567036.2020.1841854

Pilz M, Al-Fagih L (2019) Recent advances in local energy trading in the smart grid based on game-theoretic approaches. IEEE Trans Smart Grid 10(2):1363–1371. https://doi.org/10.1109/TSG.2017.2764275CrossRef

Kulkarni NK, Khedkar M (2022) Determining potential passive islanding detection indicators for single-point single inverter, single-point multi-inverter andmulti-point multi-inverter scenarios. CSEE J Power and Energy Syst 8(3):696–709. https://doi.org/10.17775/CSEEJPES.2020.05300CrossRef

Oboudi MH, Mohammadi M, Rastegar M (2019) Resilience-oriented intentional islanding of reconfigurable distribution power systems. J Mod Power Syst Clean Energy 7:741–752CrossRef

Mishra A, Jena P (2021) A scheduled intentional islanding method based on ranking of possible islanding zone. IEEE Trans Smart Grid 12(3):1853–1866. https://doi.org/10.1109/TSG.2020.3039384CrossRef

Zhao Bo, Zhang X, Chen J (2013) Integrated microgrid laboratory system. IEEE Power Energy Soc General Meet 2013:1–1. https://doi.org/10.1109/PESMG.2013.6672531CrossRef

Wang Z, Zhong J, Chen D, Yuefeng Lu, Men K (2013) A multi-period optimal power flow model including battery energy storage. IEEE Power Energy Soc General Meet 2013:1–5

Logenthiran T, Srinivasan D, Khambadkone AM (2011) Multi-agent system for energy resource scheduling of integrated microgrids in a distributed system. Electr Power Syst Res 81(1):138–148. https://doi.org/10.1016/j.epsr.2010.07.019. (ISSN 0378-7796)CrossRef

Khodaei A (2014) Microgrid optimal scheduling with multi-period islanding constraints. IEEE Trans Power Syst 29(3):1383–1392CrossRef

10.

Nguyen NTA, Le DD, Bovo C, Berizzi A (2015) Optimal power flow with energy storage systems: single-period model vs. multi-period model. In: 2015 IEEE Eindhoven PowerTech, pp 1–6, https://doi.org/10.1109/PTC.2015.7232438

11.

Reddy SS (2017) Optimal power flow with renewable energy resources including storage. Electr Eng 99:685–695. https://doi.org/10.1007/s00202-016-0402-5CrossRef

12.

Reddy SS (2017) Optimal scheduling of thermal-wind-solar power system with storage. Renew Energy 101:1357–1368 (ISSN 0960-1481)CrossRef

13.

Farzin H, Fotuhi-Firuzabad M, Moeini-Aghtaie M (2017) A stochastic multi-objective framework for optimal scheduling of energy storage systems in microgrids. IEEE Trans Smart Grid 8(1):117–127CrossRef

14.

Huang C, Yue D, Deng S, Xie J (2017) Optimal scheduling of microgrid with multiple distributed resources using interval optimization. Energies 10(3):339CrossRef

15.

Wang L, Li Q, Ding R, Sun M, Wang G (2017) Integrated scheduling of energy supply and demand in microgrids under uncertainty: a robust multi-objective optimization approach. Energy 130:1–14. https://doi.org/10.1016/j.energy.2017.04.115. (ISSN 0360-5442)CrossRef

16.

Xu G, Shang C, Fan S, Hu X, Cheng H (2018) A hierarchical energy scheduling framework of microgrids with hybrid energy storage systems. IEEE Access 6:2472–2483. https://doi.org/10.1109/ACCESS.2017.2783903CrossRef

17.

Fortenbacher P, Mathieu JL, Andersson G (2017) Modeling and optimal operation of distributed battery storage in low voltage grids. IEEE Trans Power Syst 32(6):4340–4350. https://doi.org/10.1109/TPWRS.2017.2682339CrossRef

18.

Albaker A, Majzoobi A, Zhao G, Zhang J, Khodaei A (2018) Privacy-preserving optimal scheduling of integrated microgrids. Electr Power Syst Res 163:164–173 (ISSN 0378-7796)CrossRef

19.

Xiao C, Sutanto D, Muttaqi KM, Zhang KM (2020) Multi-period data driven control strategy for real-time management of energy storages in virtual power plants integrated with power grid. Int J Electr Power Energy Syst 118:105747CrossRef

20.

Sidea D, Toma L, Sanduleac M, Picioroaga I, Boicea V (2019) Optimal BESS Scheduling strategy in microgrids based on genetic algorithms. In: 2019 IEEE Milan PowerTech, pp 1–6

21.

Kim TH, Shin H, Kwag K, Kim W (2020) A parallel multi-period optimal scheduling algorithm in microgrids with energy storage systems using decomposed inter-temporal constraints. Energy 202:117669. https://doi.org/10.1016/j.energy.2020.117669. (ISSN 0360-5442)CrossRef

22.

Sheng H, Wang C, Liang J (2021) Multi-timescale active distribution network optimal scheduling considering temporal-spatial reserve coordination. Int J Electr Power Energy Syst 125:106526. https://doi.org/10.1016/j.ijepes.2020.106526. (ISSN 0142-0615)CrossRef

23.

Picioroaga II, Tudose A, Sidea DO, Bulac C, Eremia M (2020) Two-level scheduling optimization of multi-microgrids operation in smart distribution networks. In: 2020 international conference and exposition on electrical and power engineering (EPE), pp 407–412

24.

Agarwal A, Pileggi L (2021) "Large scale multi-period optimal power flow with energy storage systems using differential dynamic programming. IEEE Trans Power Syst. https://doi.org/10.1109/TPWRS.2021.3115636CrossRef

25.

Rawat T, Niazi KR, Gupta KR, Sharma S (2021) A two-stage optimization framework for scheduling of responsive loads in smart distribution system. Int J Electr Power Energy Syst 129:106859. https://doi.org/10.1016/j.ijepes.2021.106859. (ISSN 0142-0615)CrossRef

26.

Zhang X, Guo L, Zhang H, Guo L, Feng K, Lin J (2019) An energy scheduling strategy with priority within islanded microgrids. IEEE Access 7:135896–135908CrossRef

27.

Ramesh B, Khedkar M, Vardhan BVS (2022) Priority based optimal load shedding in a power system network under contingency conditions. In: 2022 International conference for advancement in technology (ICONAT), pp 1–5

28.

Faxas-Guzmán J, García-Valverde R, Serrano-Luján L, Urbina A (2014) Priority load control algorithm for optimal energy management in stand-alone photovoltaic systems. Renew Energy 68:156–162CrossRef

29.

Tu J, Zhou M, Cui H, Li F (2019) An equivalent aggregated model of large-scale flexible loads for load scheduling. IEEE Access 7:143431–143444CrossRef

30.

Alqunun K, Guesmi T, Farah A (2020) Load shedding optimization for economic operation cost in a microgrid. Electr Eng 102:779–791. https://doi.org/10.1007/s00202-019-00909-3CrossRef

31.

Lotfi H, Ghazi R, Naghibi-Sistani M (2020) Multi-objective dynamic distribution feeder reconfiguration along with capacitor allocation using a new hybrid evolutionary algorithm. Energy Syst 11:779–809. https://doi.org/10.1007/s12667-019-00333-3CrossRef

32.

Lotfi H, Ghazi R (2021) Optimal participation of demand response aggregators in reconfigurable distribution system considering photovoltaic and storage units. J Ambient Intell Humaniz Comput 12:2233–2255. https://doi.org/10.1007/s12652-020-02322-2CrossRef

33.

Lotfi H (2020) Multi-objective energy management approach in distribution grid integrated with energy storage units considering the demand response program. Int J Energy Res 44:10662–10681. https://doi.org/10.1002/er.5709CrossRef

34.

Schniederjans MJ (1995) Goal programming: methodology and applications Kluwer Academic publishers, Boston, ISBN 978-1-4615-2229-4 (eBook), https://doi.org/10.1007/978-1-4615-2229-4

35.

Gass SI (1986) A process for determining priorities and weights for large scale linear goal programmes. J Oper Res Soc 37(8):779–785CrossRefMATH

36.

Jones D, Mehrdad D (2010) Practical goal programming. Springer Books, BostonCrossRef

37.

Saaty TL (1977) A scaling method for priorities in hierarchical structures. J Math Psychol 15(3):234–281 (ISSN 0022-2496)MathSciNetCrossRefMATH

38.

Wedley WC (1990) Combining qualitative and quantitative factors—an analytic hierarchy approach. Socio Econ Plan Sci 24(1):57–64 (ISSN 0038-0121)CrossRef

39.

Aman MM, Jasmon GB, Bakar AHA, Mokhlis H (2013) A new approach for optimum DG placement and sizing based on voltage stability maximization and minimization of power losses. Energy Convers Manag 70:202–210 (ISSN 0196-8904)CrossRef

40.

Pemmada S, Patne NR, Kumar A, Manchalwar AD (2022) Optimal planning of power distribution network by a novel modified jaya algorithm in multiobjective perspective. IEEE Syst J 16(3):4411–4422. https://doi.org/10.1109/JSYST.2021.3132300CrossRef

41.

Kersting WH (2001) Radial distribution test feeders. In: IEEE power engineering society winter meeting conference proceedings, Columbus, OH, USA, pp 908–912

42.

Orosz MS, Quoilin S, Hemond H (2013) Technologies for heating, cooling and powering rural health facilities in sub-Saharan Africa. Proc Inst Mech Eng Part A J Power Energy 227(7):717–726CrossRef

43.

Ortega Alba S, Manana M (2017) Characterization and analysis of energy demand patterns in airports. Energies 10(1):119CrossRef

44.

Wen M, Chen Y, Chen F, An L, Chen B, Zeng T, He Q, Fu C (2019) Analysis of load characteristics of typical large industrial users in Hunan Province Based on K-means Clustering. In: E3S Web of conferences, vol 118, pp 01035. https://doi.org/10.1051/e3sconf/201911801035

45.

Garg A, Shukla PR, Maheshwari J, Upadhyay J (2014) An assessment of household electricity load curves and corresponding CO₂ marginal abatement cost curves for Gujarat state, India. Energy Policy 66:568–584. https://doi.org/10.1016/j.enpol.2013.10.068. (ISSN 0301-4215)CrossRef

46.

Deb K, Pratap A, Agarwal S, Meyarivan T (2002) A fast and elitist multiobjective genetic algorithm: NSGA-II. IEEE Trans Evol Comput 6(2):182–197CrossRef

47.

Hart WE, Laird CD, Watson J-P, Woodruff DL, Hackebeil GA, Nicholson BL, Siirola JD (2017) Pyomo—optimization modeling in python, vol 67, 2nd edn. Springer, ChamCrossRefMATH

Titel: Multi-period optimal scheduling framework in an islanded smart distribution network considering load priorities
verfasst von: B. Ramesh
Mohan Khedkar
Nitin Kumar Kulkarni
Raushan Kumar
Publikationsdatum: 09.01.2023
Verlag: Springer Berlin Heidelberg
Erschienen in: Electrical Engineering / Ausgabe 2/2023
Print ISSN: 0948-7921
Elektronische ISSN: 1432-0487
DOI: https://doi.org/10.1007/s00202-022-01711-4

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