Multi-objective Allocation of Distributed Generation Resources and Capacitor Banks Based on a Two-stage Fuzzy Method and Ɛ-constrained Optimization
Subject Areas : system
farzaneh ostovar
1
,
Hassan Barati
2
,
Seyed Saeidallah Mortazavi
3
1 - electrical engineering/islamic azad university/shadegan/ iran
2 - Associate Professor/Dezful Branch, Islamic Azad University
3 - مهندسی برق دانشکده مهندسی شهید چمران اهواز خوزستان ایران
Keywords: multi-objective optimization, Capacitor bank allocation, DG allocation, Two-stage method,
Abstract :
Proper operation of distributed generation resources (DGs) in power systems has considerable advantages, including decreasing losses, reducing congestion in feeders, improving voltage pro-file, and enhancing stability, reliability, and security. On the other hand, using capacitor banks helps improve voltage profile and power quality in distribution systems. The optimal allocation of capacitor banks (CBs) and DGs has a significant impact on the efficiency of the distribution systems. This paper presents a method for distribution system planning based on the optimal allocation of DGs and CBs. The main objectives of the proposed method are to improve the voltage profile, reduce investment and operation costs, and reduce renewable energy curtailment. The planning problem is solved through multi-objective scheduling based on a two-stage fuzzy meth-od and the ɛ-constrained optimization. The stochastic two-stage method is used to model uncertainty. The proposed method is implemented on an IEEE 33-bus test network in MATLAB and evaluated under three scenarios. It is proven that the voltage profile can be improved in the scenario of allocating capacitor banks based on lower investment costs compared to other scenarios. However, the voltage profile is improved more in the scenario of simultaneous allocation of capacitor banks and DGs by investing in more costs. In general, the proposed method properly im-proves the distribution system’s performance in different aspects.
[1] Abapour, S., Nojavan, S., & Abapour, M. (2018). Multi-objective short-term sched-uling of active distribution networks for benefit maximization of DisCos and DG owners considering demand response pro-grams and energy storage system. Journal of Modern Power Systems and Clean En-ergy, 6(1), 95-106.
[2] Das, C. K., Bass, O., Kothapalli, G., Mahmoud, T. S., & Habibi, D. (2018). Overview of energy storage systems in dis-tribution networks: Placement, sizing, op-eration, and power quality. Renewable and Sustainable Energy Reviews, 91, 1205-1230.
[3] Aman, M. M., Jasmon, G. B., Solangi, K. H., Bakar, A. H. A., & Mokhlis, H. (2013). Optimum simultaneous DG and capacitor placement on the basis of minimization of power losses. International Journal of Computer and Electrical Engineering, 5(5), 516.
[4] Mohagheghi, E., Gabash, A., Alramlawi, M., & Li, P. (2018). Real-time optimal power flow with reactive power dispatch of wind stations using a reconciliation al-gorithm. Renewable Energy, 126, 509-523.
[5] Bagheri, A., Bagheri, M., & Lorestani, A. (2021). Optimal reconfiguration and DG integration in distribution networks con-sidering switching actions costs using tabu search algorithm. Journal of Ambient In-telligence and Humanized Computing, 12(7), 7837-7856.
[6] Khatib, T., & Sabri, L. (2021). Grid impact assessment of centralized and decentral-ized photovoltaic-based distribution gener-ation: A case study of power distribution network with high renewable energy pene-tration. Mathematical Problems in Engi-neering, 2021.
[7] Islam, M. R., Lu, H., Hossain, M. J., & Li, L. (2019). Mitigating unbalance using dis-tributed network reconfiguration tech-niques in distributed power generation grids with services for electric vehicles: A review. Journal of Cleaner Production, 239, 117932.
[8] Nguyen, T. P., Nguyen, T. A., Phan, T. V. H., & Vo, D. N. (2021). A comprehensive analysis for multi-objective distributed generations and capacitor banks placement in radial distribution networks using hybrid neural network algorithm. Knowledge-Based Systems, 231, 107387.
[9] Ganguly, S. (2020). Multi-objective dis-tributed generation penetration planning with load model using particle swarm op-timization. Decision Making: Applications in Management and Engineering, 3(1), 30-42.
[10] Zou, Y., Zhao, J., Ding, D., Miao, F., & Sobhani, B. (2021). Solving dynamic eco-nomic and emission dispatch in power sys-tem integrated electric vehicle and wind turbine using multi-objective virus colony search algorithm. Sustainable Cities and Society, 67, 102722.
[11] Vegunta, S. C., Watts, C. F. A., Djokic, S. Z., Milanović, J. V., & Higginson, M. J. (2019). Review of GB electricity distribu-tion system's electricity security of supply, reliability and power quality in meeting UK industrial strategy requirements. IET Generation, Transmission & Distribution, 13(16), 3513-3523.
[12] Rajamand, S. (2020). Loss cost reduction and power quality improvement with ap-plying robust optimization algorithm for optimum energy storage system placement and capacitor bank allocation. Internation-al Journal of Energy Research, 44(14), 11973-11984.
[13] Karimi-Arpanahi, S., Jooshaki, M., Moei-ni-Aghtaie, M., Abbaspour, A., & Fotuhi-Firuzabad, M. (2020). Incorporating flexi-bility requirements into distribution system expansion planning studies based on regu-latory policies. International Journal of Electrical Power & Energy Systems, 118, 105769.
[14] Xie, S., Hu, Z., Yang, L., & Wang, J. (2020). Expansion planning of active dis-tribution system considering multiple ac-tive network managements and the optimal load-shedding direction. International Journal of Electrical Power & Energy Sys-tems, 115, 105451.
[15] Xie, S., Hu, Z., & Wang, J. (2020). Two-stage robust optimization for expansion planning of active distribution systems coupled with urban transportation net-works. Applied Energy, 261, 114412.
[16] Mehrjerdi, H., & Hemmati, R. (2020). Wind-hydrogen storage in distribution network expansion planning considering investment deferral and uncertainty. Sus-tainable Energy Technologies and Assess-ments, 39, 100687.
[17] Gkaidatzis, P. A., Bouhouras, A. S., Dou-kas, D. I., Sgouras, K. I., & Labridis, D. P. (2017). Load variations impact on optimal DG placement problem concerning energy loss reduction. Electric Power Systems Re-search, 152, 36-47.
[18] Mousavi, M., Ranjbar, A. M., & Safdari-an, A. (2017). Optimal DG placement and sizing based on MICP in radial distribution networks. In 2017 Smart Grid Conference (SGC) (pp. 1-6). IEEE.
[19] Murty, V. V., & Kumar, A. (2015). Opti-mal placement of DG in radial distribution systems based on new voltage stability in-dex under load growth. International Jour-nal of Electrical Power & Energy Systems, 69, 246-256.
[20] Kaveh, M. R., Hooshmand, R. A., & Madani, S. M. (2018). Simultaneous opti-mization of re-phasing, reconfiguration and DG placement in distribution networks using BF-SD algorithm. Applied Soft Computing, 62, 1044-1055.
[21] Sahu, S., Barisal, A. K., & Kaudi, A. (2017). Multi-objective optimal power flow with DG placement using TLBO and MIPSO: A comparative study. Energy Pro-cedia, 117, 236-243.
[22] Tanwar, S. S., & Khatod, D. K. (2017). Techno-economic and environmental ap-proach for optimal placement and sizing of renewable DGs in distribution system. Energy, 127, 52-67.
[23] Zishan,F, Akbari. E, Sheikholeslami A. Shafaghatian N. (2023). Optimization and Placement of DG Resources in the Net-work to Reduce Line Loading. Internation-al Journal of Industrial Electronics, Con-trol and Optimization (IECO), 6(2) , 89-100.
[24] Sefidgar-dezfouli A. Joorabian M., Mashhour E., (2019), Microgrid optimal scheduling considering normal and emer-gency operation. International Journal of Industrial Electronics, Control and Optimi-zation (IECO), 2(4), 279-288.
[25] Sanaz Ghanbari S., Abdi H., (2019), In-vestigating Reliability of Smart Electrical Grids Considering Self-healing in Presence of Distributed Generation Resources. In-ternational Journal of Industrial Electron-ics, Control and Optimization (IECO), 2(4), 343-354.
[26] Barato H., Shahsavari M., (2018), Simul-taneous Optimal placement and sizing of distributed generation resources and shunt capacitors in radial distribution systems us-ing Crow Search Algorithm. International Journal of Industrial Electronics, Control and Optimization (IECO), 1(1), 27-40.
[27] Pamuk N., Emre Uzun U.,( 2024), Opti-mal Allocation of Distributed Generations and Capacitor Banks in Distribution Sys-tems Using Arithmetic Optimization Algo-rithm. MDPI ,14 (2), 831
[28] Fettah Kh., Guia T. , salhi A ., Mouassa S., Bosisio A., Shirvani R., ( 2024), Optimal Allocation of Capacitor Banks and Distributed Generation: A Comparison of Recently Developed Me-taheuristic Optimization Techniques on the Real Distribution Networks of ALG-AB-Hassi Sida, Algeria. MDPI, 16(11), 4419.
[29] Etemadi, A. H., & Fotuhi-Firuzabad, M. (2008). Distribution system reliability en-hancement using optimal capacitor place-ment. IET Generation, Transmission & Distribution, 2(5), 621-631.
[30] Arulraj, R., & Kumarappan, N. (2019). Optimal economic-driven planning of mul-tiple DG and capacitor in distribution net-work considering different compensation coefficients in feeder’s failure rate evalua-tion. Engineering Science and Technology, an International Journal, 22(1), 67-77.
[31] Ahmidi, A., Guillaud, X., Besanger, Y., & Blanc, R. (2011). A multilevel approach for optimal participating of wind farms at reactive power balancing in transmission power system. IEEE Systems journal, 6(2), 260-269.
[32] Konopinski, R. J., Vijayan, P., & Aj-jarapu, V. (2009). Extended reactive capa-bility of DFIG wind parks for enhanced system performance. IEEE Transactions on Power Systems, 24(3), 1346-1355.
[33] Venkatesh, B., & Ranjan, R. (2003). Op-timal radial distribution system reconfigu-ration using fuzzy adaptation of evolu-tionary programming. International journal of electrical power & energy systems, 25(10), 775-780.
[34] Allan, R. N., Billinton, R., Breipohl, A. M., & Grigg, C. H. (1994). Bibliography on the application of probability methods in power system reliability evaluation: 1987-1991. IEEE transactions on Power Systems, 9(1), 41-49.
