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A Comprehensive Method for Expansion Planning of Active Distribution System Considering Reliability Assessment | ||
| AUT Journal of Electrical Engineering | ||
| دوره 57، شماره 1، 2025، صفحه 113-130 اصل مقاله (1.49 M) | ||
| نوع مقاله: Review Article | ||
| شناسه دیجیتال (DOI): 10.22060/eej.2024.23185.5593 | ||
| نویسندگان | ||
| Seyed Peiman Mirhoseini؛ Seyed Mohsen Hashemi* ؛ Behnam Alizadeh؛ Mahdi Tabarzadi | ||
| Department of Energy Planning and Economics, Niroo Research Institute (NRI), Tehran, Iran | ||
| چکیده | ||
| Today the application of Distributed Energy Resources (DERs) in Distribution System expansion planning (DNEP) problems is more crucial than before. Despite of advantages, the presence of the resources considering Renewable Energy Sources (RESs) and Dispatchable Generation (DG) units in the distribution System expansion planning problems, brings more challenges, especially in reliability characteristics. This paper proposes a new distribution network expansion planning model embedded with a novel reliability assessment approach for Active Distribution Networks (ADNs). The proposed method aims to determine the optimal location and capacity of the new generation and distribution assets, responsible for providing power, in both the normal operation and contingency conditions. The load forecast significantly affects the results of the distribution network expansion planning. The K-means clustering method is used to address the uncertainty of load growth in the planning horizon which is coordinated with a Mixed Integer Linear Programming (MILP) optimization model. The proposed model is applied to the IEEE 33 bus test case, to guarantee its technical and economical effectiveness. The results verify that this model is cost-effective and can increase the robustness of the distribution network compared with recent similar works. | ||
| کلیدواژهها | ||
| Distribution Network؛ Reliability؛ Expansion Planning؛ Expected Energy Not Supplied؛ Dispatchable Generation | ||
| مراجع | ||
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[1] M. Ourahou, W. Ayrir, B.E. Hassouni, A. Haddi, Review on smart grid control and reliability in presence of renewable energies: Challenges and prospects, Mathematics and computers in simulation, 167 (2020) 19-31.
[2] G.L. Aschidamini, G.A. da Cruz, M. Resener, M.J. Ramos, L.A. Pereira, B.P. Ferraz, S. Haffner, P.M. Pardalos, Expansion planning of power distribution systems considering reliability: A comprehensive review, Energies, 15(6) (2022) 2275.
[3] D. Ivanov, A. Pavlov, B. Sokolov, Optimal distribution (re)planning in a centralized multi-stage supply network under conditions of the ripple effect and structure dynamics, European Journal of Operational Research, 237(2) (2014) 758-770.
[4] G. Fusco, M. Russo, A decentralized approach for voltage control by multiple distributed energy resources, IEEE Transactions on Smart Grid, 12(4) (2021) 3115-3127.
[5] P. Mirhoseini, N. Ghaffarzadeh, Economic battery sizing and power dispatch in a grid-connected charging station using convex method, Journal of Energy Storage, 31 (2020) 101651.
[6] G. Muñoz-Delgado, J. Contreras, J.M. Arroyo, Distribution system expansion planning considering non-utility-owned DG and an independent distribution system operator, IEEE Transactions on Power Systems, 34(4) (2019) 2588-2597.
[7] G. Muñoz-Delgado, J. Contreras, J.M. Arroyo, A.S.d.l. Nieta, M. Gibescu, Integrated Transmission and Distribution System Expansion Planning Under Uncertainty, IEEE Transactions on Smart Grid, 12(5) (2021) 4113-4125.
[8] S.M. Hashemi, V. Vahidinasab, M.S. Ghazizadeh, J. Aghaei, Reliability-oriented DG allocation in radial Microgrids equipped with smart consumer switching capability, in: 2019 International Conference on Smart Energy Systems and Technologies (SEST), IEEE, 2019, pp. 1-6.
[9] M. Moradijoz, M.P. Moghaddam, M.R. Haghifam, A flexible active distribution system expansion planning model: A risk-based approach, Energy, 145 (2018) 442-457.
[10] S.M. Hashemi, B. Alizadeh, M. Sheibani, F. Fallahi, Assessing Potential of Renewable Energy Sources in Iran through Practical and Analytical Data, in: 2023 13th Smart Grid Conference (SGC), IEEE, 2023, pp. 1-8.
[11] M. Lima, L. Mendes, G. Mothé, F. Linhares, M. De Castro, M. Da Silva, M. Sthel, Renewable energy in reducing greenhouse gas emissions: Reaching the goals of the Paris agreement in Brazil, Environmental Development, 33 (2020) 100504.
[12] A. Geiges, A. Nauels, P.Y. Parra, M. Andrijevic, W. Hare, P. Pfleiderer, M. Schaeffer, C.-F. Schleussner, Incremental improvements of 2030 targets insufficient to achieve the Paris Agreement goals, Earth System Dynamics, 11(3) (2020) 697-708.
[13] E. Asmelash, G. Prakash, R. Gorini, D. Gielen, Role of IRENA for global transition to 100% renewable energy, Accelerating the transition to a 100% renewable energy era, (2020) 51-71.
[14] S.M. Tercan, A. Demirci, Y.E. Unutmaz, O. Elma, R. Yumurtaci, A comprehensive review of recent advances in optimal allocation methods for distributed renewable generation, IET Renewable Power Generation, 17(12) (2023) 3133-3150.
[15] M.-A. Hamidan, F. Borousan, Optimal planning of distributed generation and battery energy storage systems simultaneously in distribution networks for loss reduction and reliability improvement, Journal of Energy Storage, 46 (2022) 103844.
[16] A. Ehsan, Q. Yang, State-of-the-art techniques for modelling of uncertainties in active distribution network planning: A review, Applied energy, 239 (2019) 1509-1523.
[17] S. Mishra, D. Das, S. Paul, A comprehensive review on power distribution network reconfiguration, Energy Systems, 8 (2017) 227-284.
[18] Z. Li, W. Wu, X. Tai, B. Zhang, A reliability-constrained expansion planning model for mesh distribution networks, IEEE Transactions on Power Systems, 36(2) (2020) 948-960.
[19] T. Li, X. Han, W. Wu, H. Sun, Robust expansion planning and hardening strategy of meshed multi-energy distribution networks for resilience enhancement, Applied Energy, 341 (2023) 121066.
[20] D. Ghosh, Impact of Distributed Generation on the Reliability Allocation of Distribution System: A mesh-Grid Approach, in: 2020 International Conference on Emerging Frontiers in Electrical and Electronic Technologies (ICEFEET), IEEE, 2020, pp. 1-6.
[21] O. Badran, S. Mekhilef, H. Mokhlis, W. Dahalan, Optimal reconfiguration of distribution system connected with distributed generations: A review of different methodologies, Renewable and Sustainable Energy Reviews, 73 (2017) 854-867.
[22] M. Eidiani, Reconfiguration of the over distribution and transmission of Khorasan based on contingency ranking, transient stability, reliability indices, short circuit and loss, Majlesi Journal of Energy Management, 9(2) (2020) 29-35.
[23] V. Vahidinasab, M. Tabarzadi, H. Arasteh, M.I. Alizadeh, M.M. Beigi, H.R. Sheikhzadeh, K. Mehran, M.S. Sepasian, Overview of electric energy distribution networks expansion planning, IEEE Access, 8 (2020) 34750-34769.
[24] H. Xing, H. Cheng, Y. Zhang, P. Zeng, Active distribution network expansion planning integrating dispersed energy storage systems, IET Generation, Transmission & Distribution, 10(3) (2016) 638-644.
[25] B. Sultana, M. Mustafa, U. Sultana, A.R. Bhatti, Review on reliability improvement and power loss reduction in distribution system via network reconfiguration, Renewable and sustainable energy reviews, 66 (2016) 297-310.
[26] R.S. Pinto, C. Unsihuay‐Vila, F.H. Tabarro, Reliability‐constrained robust expansion planning of active distribution networks, IET Generation, Transmission & Distribution, 16(1) (2022) 27-40.
[27] H. HassanzadehFard, A. Jalilian, Optimal sizing and location of renewable energy based DG units in distribution systems considering load growth, International Journal of Electrical Power & Energy Systems, 101 (2018) 356-370.
[28] T.D. De Lima, J.F. Franco, F. Lezama, J. Soares, A specialized long-term distribution system expansion planning method with the integration of distributed energy resources, IEEE Access, 10 (2022) 19133-19148.
[29] A. Bagheri, H. Monsef, H. Lesani, Integrated distribution network expansion planning incorporating distributed generation considering uncertainties, reliability, and operational conditions, International Journal of Electrical Power & Energy Systems, 73 (2015) 56-70.
[30] M. Resener, S. Haffner, L.A. Pereira, P.M. Pardalos, M.J.S. Ramos, A comprehensive MILP model for the expansion planning of power distribution systems – Part I: Problem formulation, Electric Power Systems Research, 170 (2019) 378-384.
[31] A. Tabares, G. Muñoz-Delgado, J.F. Franco, J.M. Arroyo, J. Contreras, Multistage reliability-based expansion planning of AC distribution networks using a mixed-integer linear programming model, International Journal of Electrical Power & Energy Systems, 138 (2022) 107916.
[32] M. Kabirifar, M. Fotuhi-Firuzabad, M. Moeini-Aghtaie, N. Pourghaderi, M. Shahidehpour, Reliability-Based Expansion Planning Studies of Active Distribution Networks With Multiagents, IEEE Transactions on Smart Grid, 13(6) (2022) 4610-4623.
[33] A. Muhtadi, D. Pandit, N. Nguyen, J. Mitra, Distributed energy resources based microgrid: Review of architecture, control, and reliability, IEEE Transactions on Industry Applications, 57(3) (2021) 2223-2235.
[34] B. Zou, C. Wang, Y. Zhou, J. Wang, C. Chen, F. Wen, Resilient co‐expansion planning between gas and electric distribution networks against natural disasters, IET Generation, Transmission & Distribution, 14(17) (2020) 3561-3570.
[35] Z. Wu, Q. Sun, W. Gu, Y. Chen, H. Xu, J. Zhang, AC/DC Hybrid Distribution System Expansion Planning Under Long-Term Uncertainty Considering Flexible Investment, IEEE Access, 8 (2020) 94956-94967.
[36] J.M. Home-Ortiz, M. Pourakbari-Kasmaei, M. Lehtonen, J.R.S. Mantovani, A mixed integer conic model for distribution expansion planning: Matheuristic approach, IEEE Transactions on Smart Grid, 11(5) (2020) 3932-3943.
[37] W. Li, Reliability assessment of electric power systems using Monte Carlo methods, Springer Science & Business Media, 2013.
[38] Z. Li, W. Wu, X. Tai, B. Zhang, A Reliability-Constrained Expansion Planning Model for Mesh Distribution Networks, IEEE Transactions on Power Systems, 36(2) (2021) 948-960.
[39] M. Kabirifar, M. Fotuhi-Firuzabad, M. Moeini-Aghtaie, N. Pourghaderi, M. Lehtonen, Reliability based Joint Distribution Network and Distributed Generation Expansion Planning, in: 2020 International Conference on Probabilistic Methods Applied to Power Systems (PMAPS), 2020, pp. 1-6.
[40] D. Anteneh, B. Khan, Reliability enhancement of distribution substation by using network reconfiguration a case study at Debre Berhan Distribution Substation, Energy, & Environment, 4(2) (2019) 33.
[41] M. Jooshaki, A. Abbaspour, M. Fotuhi-Firuzabad, G. Muñoz-Delgado, J. Contreras, M. Lehtonen, J.M. Arroyo, Linear formulations for topology-variable-based distribution system reliability assessment considering switching interruptions, IEEE Transactions on Smart Grid, 11(5) (2020) 4032-4043.
[42] A. Tabares, G. Munoz-Delgado, J.F. Franco, J.M. Arroyo, J. Contreras, An enhanced algebraic approach for the analytical reliability assessment of distribution systems, IEEE Transactions on Power Systems, 34(4) (2019) 2870-2879.
[43] F.F. Seyed Peiman Mirhoseini، Seyed Mohsen Hashemi، Behnam Alizadeh، Mahdi Tabarzadi, A Reliability-based Strategy for Active Distribution Network Expansion Planning, 13th smart grid conferance, (2023).
[44] M.H. Ali, S. Kamel, M.H. Hassan, M. Tostado-Véliz, H.M. Zawbaa, An improved wild horse optimization algorithm for reliability based optimal DG planning of radial distribution networks, Energy Reports, 8 (2022) 582-604.
[45] V.V. S. M. Hashemi, M.S. GHAZIZADEH, and J. AGHAEI,, Security Constrained Operation of Radial Micro Grids Based on the Loads’ Vulnerabilities and Flexibilities, TABRIZ JOURNAL OF ELECTRICAL ENGINEERING, 50 (2020).
[46] R. Ray, A.R.J.I.J.o.E. Gupta, Science, Technology, Power loss minimization and voltage profile improvement of radial and mesh distribution network using sine cosine optimization based DG allocation, 14(3) (2022) 64-73. | ||
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آمار تعداد مشاهده مقاله: 253 تعداد دریافت فایل اصل مقاله: 388 |
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