Review
BibTex RIS Cite
Year 2023, , 16 - 23, 30.06.2023
https://doi.org/10.22531/muglajsci.1206817

Abstract

References

  • Onal, Y., “A New Controller For Photovoltaic Panel Fed Unified Power Quality Conditioner To Power Quality Improvement”, Mugla Journal of Science and Technology, 7(1), 14-24, 2021.
  • Tascikaraoglu, A., Uzunoglu, M., Vural, B., and Erdinc, O., “Power quality assessment of wind turbines and comparison with conventional legal regulations: A case study in Turkey”, Applied Energy, 88(5), 1864-1872, 2011.
  • Kocatepe, C., İnan, A., Arıkan, O., Yumurtacı, R., Kekezoğlu, B., Baysal, M., Bozkurt, A., and Akkaya, Y., “Power quality assessment of grid-connected wind farms considering regulations in turkey”, Renewable and Sustainable Energy Reviews, 13(9), 2553-2561, 2009.
  • Ch, Y., Goswami, S. K., and Chatterjee, D., “Effect of network reconfiguration on power quality of distribution system”, International Journal of Electrical Power & Energy Systems, 83, 87 – 95, 2016.
  • Abd-Rabou, A. M., Soliman, A. M., and Mokhtar, A. S., “Impact of DG different types on the grid performance”, Journal of Electrical Systems and Information Technology, 2(2), 149 – 160, 2015.
  • Khazali, A., and Kalantar, M., “Optimal power flow considering fault current level constraints and fault current limiters”, International Journal of Electrical Power & Energy Systems, 59, 204 – 213, 2014.
  • Ibrahim, A. A., Mohamed, A., and Shareef, H., “Optimal power quality monitor placement in power systems using an adaptive quantum-inspired binary gravitational search algorithm”, International Journal of Electrical Power & Energy Systems, 57, 404 – 413, 2014.
  • Rather, Z. H., and Flynn, D., “Voltage dip induced frequency events in wind integrated power systems”, IFAC-PapersOnLine, 48(30), 572 – 577, 2015.
  • Chen, P. C., Malbasa, V., Dong, Y., and Kezunovic, M., “Sensitivity analysis of voltage sag based fault location with distributed generation”, IEEE Transactions on Smart Grid, 6(4), 2098 – 2106, 2015.
  • Rauf, A. M., and Khadkikar, V., “An enhanced voltage sag compensation scheme for dynamic voltage restorer”, IEEE Transactions on Industrial Electronics, 62(5), 2683 – 2692, 2014.
  • Lotfifard, S., Kezunovic, M., and Mousavi, M. J., “Voltage sag data utilization for distribution fault location”, IEEE Transactions on Power Delivery, 26(2), 1239 – 1246, 2011.
  • Jothibasu, S., and Mishra, M. K., “An improved direct AC–AC converter for voltage sag mitigation”, IEEE Transactions on Industrial Electronics, 62(1), 21 – 29, 2014.
  • Latran, M. B., and Teke, A., “A novel wavelet transform based voltage sag/swell detection algorithm”, International Journal of Electrical Power & Energy Systems, 71, 131 – 139, 2015.
  • Naidu, S. R., De Andrade, G. V., and Da Costa, E. G., “Voltage sag performance of a distribution system and its improvement”, IEEE Transactions on Industry Applications, 48(1), 218 – 224, 2011.
  • Yunus, A. S., Masoum, M. A., and Abu-Siada, A., “Application of SMES to enhance the dynamic performance of DFIG during voltage sag and swell”, IEEE Transactions on Applied Superconductivity, 22(4), 5702009 – 5702009, 2012.
  • Hajizadeh, A., Golkar, M. A., and Feliachi, A., “Voltage control and active power management of hybrid fuel-cell/energy-storage power conversion system under unbalanced voltage sag conditions”, IEEE Transactions on Energy Conversion, 25(4), 1195 – 1208, 2010.
  • Costa, F. B., and Driesen, J., “Assessment of voltage sag indices based on scaling and wavelet coefficient energy analysis”, IEEE Transactions on Power Delivery, 28(1), 336 – 346, 2012.
  • Zhang, L., Loh, P. C., and Gao, F., “An integrated nine-switch power conditioner for power quality enhancement and voltage sag mitigation”, IEEE Transactions on Power Electronics, 27(3), 1177 – 1190, 2011.
  • Xu, Y., Xiao, X., Sun, Y., and Long, Y., “Voltage sag compensation strategy for unified power quality conditioner with simultaneous reactive power injection”, Journal of Modern Power Systems and Clean Energy, 4(1), 113 – 122, 2016.
  • Hussein, H. I., “Neural network controller based Dstatcom for voltage sag mitigation and power quality issue”, International Journal of Engineering and Technology (IJET), 8(1), 405 – 420, 2016.
  • Daud, S., Kadir, A. F. A., Gan, C. K., Mohamed, A., and Khatib, T., “A comparison of heuristic optimization techniques for optimal placement and sizing of photovoltaic based distributed generation in a distribution system” Solar Energy, 140, 219 – 226, 2016.
  • Sarker, J., and Goswami, S. K., “Optimal location of unified power quality conditioner in distribution system for power quality improvement”, International Journal of Electrical Power & Energy Systems, 83, 309 – 324, 2016.
  • Tayjasanant, T., and Surisunthon, S. “Impacts of distributed generation on voltage sag assessment in Thailand's distribution systems”, In 2012 IEEE 15th International Conference on Harmonics and Quality of Power, pp. 624 – 629, IEEE, 2012, June.
  • Khatri, N., Jain, A., Kumar, V., and Joshi, R. R., “Voltage sag assessment with respect to sensitivity of adjustable speed drives in distributed generation environment”, In 2015 International Conference on Computer, Communication and Control (IC4), pp. 1 – 6, IEEE, 2015, September.
  • Chang, Y. P., and Chan, Y. H., “The minimization of voltage sag effect for specially connected transformers with a sensitive load and distributed generation systems”, International Journal of Electrical Power & Energy Systems, 73, 882 – 890, 2015.
  • Goswami, A. K., Gupta, C. P., and Singh, G. K., “Minimization of voltage sag induced financial losses in distribution systems using FACTS devices”, Electric Power Systems Research, 81(3), 767 – 774, 2011.
  • Liu, Y., Xiao, X. Y., Zhang, X. P., and Wang, Y., “Multi-objective optimal STATCOM allocation for voltage sag mitigation” IEEE Transactions on Power Delivery, 35(3), 1410 – 1422, 2019.
  • Bahadoorsingh, S., Milanovic, J. V., Zhang, Y., Gupta, C. P., and Dragovic, J., “Minimization of voltage sag costs by optimal reconfiguration of distribution network using genetic algorithms”, IEEE Transactions on Power Delivery, 22(4), 2271 – 2278, 2007.
  • García-Martínez, S., and Espinosa-Juárez, E., “Optimal reconfiguration of electrical networks by applying tabu search to decrease voltage sag indices”, Electric Power Components and Systems, 41(10), 943 – 959, 2013.
  • Menchafou, Y., Zahri, M., Habibi, M., and El Markhi, H., “Extension of the Accurate Voltage-Sag Fault Location Method in Electrical Power Distribution Systems”, Journal of Electrical Systems, 12(1), 33 – 44, 2016.
  • Bach, K. Q., “A Novel Method For Global Voltage Sag Compensation In IEEE 69 Bus Distribution System By Dynamic Voltage Restorers”, Journal of Engineering Science and Technology, 14(4), 1893 – 1911, 2019.
  • Zhong, Q., He, Q., Wang, G., Wang, L., and Li, Q., “Optimal Sizing and Placement Method for Dynamic Voltage Restorers with Mitigation Expectation Index”, IEEE Transactions on Power Delivery, 36(6), 3561 – 3569, 2020.
  • Elsaid, M. E., Elmitwally, A. I., and Elsakaan, A. A., “Optimal locations of Power Quality Monitors Considering Voltage Sag Constraints”, (Dept. E.). MEJ. Mansoura Engineering Journal, 38(4), 15 – 24, 2020.
  • Mahmoudian, A., Niasati, M., and Khanesar, M. A., “Multi objective optimal allocation of fault current limiters in power system”, International Journal of Electrical Power & Energy Systems, 85, 1 – 11, 2017.
  • Amini, M., and Jalilian, A., “Modelling and improvement of open-UPQC performance in voltage sag compensation by contribution of shunt units”, Electric Power Systems Research, 187, 106506, 2020.
  • Biswas, S., Goswami, S. K., and Chatterjee, A., “Optimum distributed generation placement with voltage sag effect minimization”, Energy Conversion and Management, 53(1), 163 – 174, 2012.
  • Wang, Y., Luo, H., and Xiao, X. Y., “Joint optimal planning of distributed generations and sensitive users considering voltage sag”, IEEE Transactions on Power Delivery, 37(1), 93 – 104, 2021.
  • HassanzadehFard, H., and Jalilian, A., “Optimization of DG units in distribution systems for voltage sag minimization considering various load types”, Iranian Journal of Science and Technology, Transactions of Electrical Engineering, 45(2), 685 – 699, 2021.
  • Mohammed, A. H., and Shahl, S. I., “Impact of Distributed Generation on a Distribution Network Voltage Sags in Baghdad City”, Engineering and Technology Journal, 39(4A), 528 – 542, 2021.
  • Asrari, A., Wu, T., and Lotfifard, S., “The impacts of distributed energy sources on distribution network reconfiguration”, IEEE Transactions on Energy Conversion, 31(2), 606 – 613, 2016.
  • Nodushan, M. M., Ghadimi, A. A., and Salami, A., “Voltage sag improvement in radial distribution networks using reconfiguration simultaneous with DG placement”, Indian Journal of Science and Technology, 6(7), 4682 – 4689, 2013.
  • Moussa, S. A. M., and Abdelwahed, A., “DG Allocation Based on Reliability, Losses and Voltage Sag Considerations: an expert system approach”, Renewable Energy and Sustainable Development, 3(1), 33 – 38, 2017.
  • Elmitwally, A., Gouda, E., and Eladawy, S., “Restoring recloser-fuse coordination by optimal fault current limiters planning in DG-integrated distribution systems”, International Journal of Electrical Power & Energy Systems, 77, 9 – 18. 2016.
  • Shakeri, S., Esmaeili, S., and Koochi, M. H. R., “Determining accurate area of vulnerability for reliable voltage sag assessment considering wind turbine ride-through capability”, International Journal of Electrical Power & Energy Systems, 119, 105875, 2020.
  • Sadeghi, M. H., Dastfan, A., and Damchi, Y., “Optimal coordination of directional overcurrent relays in distribution systems with DGs and FCLs considering voltage sag energy index”, Electric Power Systems Research, 191, 106884, 2021.
  • Jamali, S., Bahmanyar, A., and Bompard, E., “Fault location method for distribution networks using smart meters”, Measurement, 102, 150-157, 2017.
  • Pombo, A. V., Murta-Pina, J., and Pires, V. F., “Multiobjective formulation of the integration of storage systems within distribution networks for improving reliability”, Electric Power Systems Research, 148, 87 – 96, 2017.
  • Katyara, S., Shaikh, M. F., Shaikh, S., Khand, Z. H., Staszewski, L., Bhan, V., Majeed, A., Shah, M. A., and Zbigniew, L., “Leveraging a Genetic Algorithm for the Optimal Placement of Distributed Generation and the Need for Energy Management Strategies Using a Fuzzy Inference System”, Electronics, 10(2), 172, 2021.
  • Hashem, M., Abdel-Salam, M., El-Mohandes, M. T., Nayel, M., and Ebeed, M., “Optimal placement and sizing of wind turbine generators and superconducting magnetic energy storages in a distribution system”, Journal of Energy Storage, 38, 102497, 2021.
  • Ahmed, H. M., Awad, A. S., Ahmed, M. H., and Salama, M. M. A., “Mitigating voltage-sag and voltage-deviation problems in distribution networks using battery energy storage systems”, Electric Power Systems Research, 184, 106294, 2020.
  • Jin, J. X., Zhou, Q., Yang, R. H., Li, Y. J., Li, H., Guo, Y. G., and Zhu, J. G., “A superconducting magnetic energy storage based current-type interline dynamic voltage restorer for transient power quality enhancement of composited data center and renewable energy source power system”, Journal of Energy Storage, 52, 105003, 2022.
  • Bhujade, R., Maharjan, S., Khambadkone, A. M., and Srinivasan, D., “Economic analysis of annual load loss due to voltage sags in industrial distribution networks with distributed PVs”, Solar Energy, 252, 363-372, 2023.
  • Xiong, P., Xiao, F., Liu, D., Cao, K., Han, X., and Wen, M., “Backup protection method based on multi-interval information in low voltage distribution network of high proportion of renewable energy system”, Energy Reports, 9, 487-494, 2023.
  • Chakraborty, A., and Maity, T., “Integrated control algorithm for fast and accurate detection of the voltage sag with low voltage ride-through (LVRT) enhancement for doubly-fed induction generator (DFIG) based wind turbines”, Control Engineering Practice, 131, 105393, 2023.

REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES

Year 2023, , 16 - 23, 30.06.2023
https://doi.org/10.22531/muglajsci.1206817

Abstract

Several types of power quality problems can be observed in power network. These power quality problems include voltage unbalance, voltage flicker, voltage sags and swells, interruptions, and voltage and current harmonics. Voltage sag is one of the vital power quality issues. This problem can cause a decrease in power grid voltage over a short time horizon. The aforementioned problem is caused by various types of short circuits and the widespread use of sensitive devices. These problems have a significant impact on power systems. In this review article, the different ways to prevent voltage sag have been presented by considering literature studies. Concerning voltage sags in radial and mesh grids, the equipment used, and methods have all been taken into account. In these studies, the articles about voltage sag-related problems have been put into groups based on certain criteria. These criteria include the consideration of uncertainties in electricity demand or renewable sources. The recommendations related to the voltage sag studies have been presented. These suggestions are based on the inclusion of electricity consumption and renewable energy source uncertainties. The future works have been mentioned by considering these load and renewable system uncertainties.

References

  • Onal, Y., “A New Controller For Photovoltaic Panel Fed Unified Power Quality Conditioner To Power Quality Improvement”, Mugla Journal of Science and Technology, 7(1), 14-24, 2021.
  • Tascikaraoglu, A., Uzunoglu, M., Vural, B., and Erdinc, O., “Power quality assessment of wind turbines and comparison with conventional legal regulations: A case study in Turkey”, Applied Energy, 88(5), 1864-1872, 2011.
  • Kocatepe, C., İnan, A., Arıkan, O., Yumurtacı, R., Kekezoğlu, B., Baysal, M., Bozkurt, A., and Akkaya, Y., “Power quality assessment of grid-connected wind farms considering regulations in turkey”, Renewable and Sustainable Energy Reviews, 13(9), 2553-2561, 2009.
  • Ch, Y., Goswami, S. K., and Chatterjee, D., “Effect of network reconfiguration on power quality of distribution system”, International Journal of Electrical Power & Energy Systems, 83, 87 – 95, 2016.
  • Abd-Rabou, A. M., Soliman, A. M., and Mokhtar, A. S., “Impact of DG different types on the grid performance”, Journal of Electrical Systems and Information Technology, 2(2), 149 – 160, 2015.
  • Khazali, A., and Kalantar, M., “Optimal power flow considering fault current level constraints and fault current limiters”, International Journal of Electrical Power & Energy Systems, 59, 204 – 213, 2014.
  • Ibrahim, A. A., Mohamed, A., and Shareef, H., “Optimal power quality monitor placement in power systems using an adaptive quantum-inspired binary gravitational search algorithm”, International Journal of Electrical Power & Energy Systems, 57, 404 – 413, 2014.
  • Rather, Z. H., and Flynn, D., “Voltage dip induced frequency events in wind integrated power systems”, IFAC-PapersOnLine, 48(30), 572 – 577, 2015.
  • Chen, P. C., Malbasa, V., Dong, Y., and Kezunovic, M., “Sensitivity analysis of voltage sag based fault location with distributed generation”, IEEE Transactions on Smart Grid, 6(4), 2098 – 2106, 2015.
  • Rauf, A. M., and Khadkikar, V., “An enhanced voltage sag compensation scheme for dynamic voltage restorer”, IEEE Transactions on Industrial Electronics, 62(5), 2683 – 2692, 2014.
  • Lotfifard, S., Kezunovic, M., and Mousavi, M. J., “Voltage sag data utilization for distribution fault location”, IEEE Transactions on Power Delivery, 26(2), 1239 – 1246, 2011.
  • Jothibasu, S., and Mishra, M. K., “An improved direct AC–AC converter for voltage sag mitigation”, IEEE Transactions on Industrial Electronics, 62(1), 21 – 29, 2014.
  • Latran, M. B., and Teke, A., “A novel wavelet transform based voltage sag/swell detection algorithm”, International Journal of Electrical Power & Energy Systems, 71, 131 – 139, 2015.
  • Naidu, S. R., De Andrade, G. V., and Da Costa, E. G., “Voltage sag performance of a distribution system and its improvement”, IEEE Transactions on Industry Applications, 48(1), 218 – 224, 2011.
  • Yunus, A. S., Masoum, M. A., and Abu-Siada, A., “Application of SMES to enhance the dynamic performance of DFIG during voltage sag and swell”, IEEE Transactions on Applied Superconductivity, 22(4), 5702009 – 5702009, 2012.
  • Hajizadeh, A., Golkar, M. A., and Feliachi, A., “Voltage control and active power management of hybrid fuel-cell/energy-storage power conversion system under unbalanced voltage sag conditions”, IEEE Transactions on Energy Conversion, 25(4), 1195 – 1208, 2010.
  • Costa, F. B., and Driesen, J., “Assessment of voltage sag indices based on scaling and wavelet coefficient energy analysis”, IEEE Transactions on Power Delivery, 28(1), 336 – 346, 2012.
  • Zhang, L., Loh, P. C., and Gao, F., “An integrated nine-switch power conditioner for power quality enhancement and voltage sag mitigation”, IEEE Transactions on Power Electronics, 27(3), 1177 – 1190, 2011.
  • Xu, Y., Xiao, X., Sun, Y., and Long, Y., “Voltage sag compensation strategy for unified power quality conditioner with simultaneous reactive power injection”, Journal of Modern Power Systems and Clean Energy, 4(1), 113 – 122, 2016.
  • Hussein, H. I., “Neural network controller based Dstatcom for voltage sag mitigation and power quality issue”, International Journal of Engineering and Technology (IJET), 8(1), 405 – 420, 2016.
  • Daud, S., Kadir, A. F. A., Gan, C. K., Mohamed, A., and Khatib, T., “A comparison of heuristic optimization techniques for optimal placement and sizing of photovoltaic based distributed generation in a distribution system” Solar Energy, 140, 219 – 226, 2016.
  • Sarker, J., and Goswami, S. K., “Optimal location of unified power quality conditioner in distribution system for power quality improvement”, International Journal of Electrical Power & Energy Systems, 83, 309 – 324, 2016.
  • Tayjasanant, T., and Surisunthon, S. “Impacts of distributed generation on voltage sag assessment in Thailand's distribution systems”, In 2012 IEEE 15th International Conference on Harmonics and Quality of Power, pp. 624 – 629, IEEE, 2012, June.
  • Khatri, N., Jain, A., Kumar, V., and Joshi, R. R., “Voltage sag assessment with respect to sensitivity of adjustable speed drives in distributed generation environment”, In 2015 International Conference on Computer, Communication and Control (IC4), pp. 1 – 6, IEEE, 2015, September.
  • Chang, Y. P., and Chan, Y. H., “The minimization of voltage sag effect for specially connected transformers with a sensitive load and distributed generation systems”, International Journal of Electrical Power & Energy Systems, 73, 882 – 890, 2015.
  • Goswami, A. K., Gupta, C. P., and Singh, G. K., “Minimization of voltage sag induced financial losses in distribution systems using FACTS devices”, Electric Power Systems Research, 81(3), 767 – 774, 2011.
  • Liu, Y., Xiao, X. Y., Zhang, X. P., and Wang, Y., “Multi-objective optimal STATCOM allocation for voltage sag mitigation” IEEE Transactions on Power Delivery, 35(3), 1410 – 1422, 2019.
  • Bahadoorsingh, S., Milanovic, J. V., Zhang, Y., Gupta, C. P., and Dragovic, J., “Minimization of voltage sag costs by optimal reconfiguration of distribution network using genetic algorithms”, IEEE Transactions on Power Delivery, 22(4), 2271 – 2278, 2007.
  • García-Martínez, S., and Espinosa-Juárez, E., “Optimal reconfiguration of electrical networks by applying tabu search to decrease voltage sag indices”, Electric Power Components and Systems, 41(10), 943 – 959, 2013.
  • Menchafou, Y., Zahri, M., Habibi, M., and El Markhi, H., “Extension of the Accurate Voltage-Sag Fault Location Method in Electrical Power Distribution Systems”, Journal of Electrical Systems, 12(1), 33 – 44, 2016.
  • Bach, K. Q., “A Novel Method For Global Voltage Sag Compensation In IEEE 69 Bus Distribution System By Dynamic Voltage Restorers”, Journal of Engineering Science and Technology, 14(4), 1893 – 1911, 2019.
  • Zhong, Q., He, Q., Wang, G., Wang, L., and Li, Q., “Optimal Sizing and Placement Method for Dynamic Voltage Restorers with Mitigation Expectation Index”, IEEE Transactions on Power Delivery, 36(6), 3561 – 3569, 2020.
  • Elsaid, M. E., Elmitwally, A. I., and Elsakaan, A. A., “Optimal locations of Power Quality Monitors Considering Voltage Sag Constraints”, (Dept. E.). MEJ. Mansoura Engineering Journal, 38(4), 15 – 24, 2020.
  • Mahmoudian, A., Niasati, M., and Khanesar, M. A., “Multi objective optimal allocation of fault current limiters in power system”, International Journal of Electrical Power & Energy Systems, 85, 1 – 11, 2017.
  • Amini, M., and Jalilian, A., “Modelling and improvement of open-UPQC performance in voltage sag compensation by contribution of shunt units”, Electric Power Systems Research, 187, 106506, 2020.
  • Biswas, S., Goswami, S. K., and Chatterjee, A., “Optimum distributed generation placement with voltage sag effect minimization”, Energy Conversion and Management, 53(1), 163 – 174, 2012.
  • Wang, Y., Luo, H., and Xiao, X. Y., “Joint optimal planning of distributed generations and sensitive users considering voltage sag”, IEEE Transactions on Power Delivery, 37(1), 93 – 104, 2021.
  • HassanzadehFard, H., and Jalilian, A., “Optimization of DG units in distribution systems for voltage sag minimization considering various load types”, Iranian Journal of Science and Technology, Transactions of Electrical Engineering, 45(2), 685 – 699, 2021.
  • Mohammed, A. H., and Shahl, S. I., “Impact of Distributed Generation on a Distribution Network Voltage Sags in Baghdad City”, Engineering and Technology Journal, 39(4A), 528 – 542, 2021.
  • Asrari, A., Wu, T., and Lotfifard, S., “The impacts of distributed energy sources on distribution network reconfiguration”, IEEE Transactions on Energy Conversion, 31(2), 606 – 613, 2016.
  • Nodushan, M. M., Ghadimi, A. A., and Salami, A., “Voltage sag improvement in radial distribution networks using reconfiguration simultaneous with DG placement”, Indian Journal of Science and Technology, 6(7), 4682 – 4689, 2013.
  • Moussa, S. A. M., and Abdelwahed, A., “DG Allocation Based on Reliability, Losses and Voltage Sag Considerations: an expert system approach”, Renewable Energy and Sustainable Development, 3(1), 33 – 38, 2017.
  • Elmitwally, A., Gouda, E., and Eladawy, S., “Restoring recloser-fuse coordination by optimal fault current limiters planning in DG-integrated distribution systems”, International Journal of Electrical Power & Energy Systems, 77, 9 – 18. 2016.
  • Shakeri, S., Esmaeili, S., and Koochi, M. H. R., “Determining accurate area of vulnerability for reliable voltage sag assessment considering wind turbine ride-through capability”, International Journal of Electrical Power & Energy Systems, 119, 105875, 2020.
  • Sadeghi, M. H., Dastfan, A., and Damchi, Y., “Optimal coordination of directional overcurrent relays in distribution systems with DGs and FCLs considering voltage sag energy index”, Electric Power Systems Research, 191, 106884, 2021.
  • Jamali, S., Bahmanyar, A., and Bompard, E., “Fault location method for distribution networks using smart meters”, Measurement, 102, 150-157, 2017.
  • Pombo, A. V., Murta-Pina, J., and Pires, V. F., “Multiobjective formulation of the integration of storage systems within distribution networks for improving reliability”, Electric Power Systems Research, 148, 87 – 96, 2017.
  • Katyara, S., Shaikh, M. F., Shaikh, S., Khand, Z. H., Staszewski, L., Bhan, V., Majeed, A., Shah, M. A., and Zbigniew, L., “Leveraging a Genetic Algorithm for the Optimal Placement of Distributed Generation and the Need for Energy Management Strategies Using a Fuzzy Inference System”, Electronics, 10(2), 172, 2021.
  • Hashem, M., Abdel-Salam, M., El-Mohandes, M. T., Nayel, M., and Ebeed, M., “Optimal placement and sizing of wind turbine generators and superconducting magnetic energy storages in a distribution system”, Journal of Energy Storage, 38, 102497, 2021.
  • Ahmed, H. M., Awad, A. S., Ahmed, M. H., and Salama, M. M. A., “Mitigating voltage-sag and voltage-deviation problems in distribution networks using battery energy storage systems”, Electric Power Systems Research, 184, 106294, 2020.
  • Jin, J. X., Zhou, Q., Yang, R. H., Li, Y. J., Li, H., Guo, Y. G., and Zhu, J. G., “A superconducting magnetic energy storage based current-type interline dynamic voltage restorer for transient power quality enhancement of composited data center and renewable energy source power system”, Journal of Energy Storage, 52, 105003, 2022.
  • Bhujade, R., Maharjan, S., Khambadkone, A. M., and Srinivasan, D., “Economic analysis of annual load loss due to voltage sags in industrial distribution networks with distributed PVs”, Solar Energy, 252, 363-372, 2023.
  • Xiong, P., Xiao, F., Liu, D., Cao, K., Han, X., and Wen, M., “Backup protection method based on multi-interval information in low voltage distribution network of high proportion of renewable energy system”, Energy Reports, 9, 487-494, 2023.
  • Chakraborty, A., and Maity, T., “Integrated control algorithm for fast and accurate detection of the voltage sag with low voltage ride-through (LVRT) enhancement for doubly-fed induction generator (DFIG) based wind turbines”, Control Engineering Practice, 131, 105393, 2023.
There are 54 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

İbrahim Çağrı Barutçu 0000-0001-6164-2048

Ali Erduman 0000-0003-4116-3159

Early Pub Date June 28, 2023
Publication Date June 30, 2023
Published in Issue Year 2023

Cite

APA Barutçu, İ. Ç., & Erduman, A. (2023). REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES. Mugla Journal of Science and Technology, 9(1), 16-23. https://doi.org/10.22531/muglajsci.1206817
AMA Barutçu İÇ, Erduman A. REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES. MJST. June 2023;9(1):16-23. doi:10.22531/muglajsci.1206817
Chicago Barutçu, İbrahim Çağrı, and Ali Erduman. “REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES”. Mugla Journal of Science and Technology 9, no. 1 (June 2023): 16-23. https://doi.org/10.22531/muglajsci.1206817.
EndNote Barutçu İÇ, Erduman A (June 1, 2023) REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES. Mugla Journal of Science and Technology 9 1 16–23.
IEEE İ. Ç. Barutçu and A. Erduman, “REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES”, MJST, vol. 9, no. 1, pp. 16–23, 2023, doi: 10.22531/muglajsci.1206817.
ISNAD Barutçu, İbrahim Çağrı - Erduman, Ali. “REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES”. Mugla Journal of Science and Technology 9/1 (June 2023), 16-23. https://doi.org/10.22531/muglajsci.1206817.
JAMA Barutçu İÇ, Erduman A. REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES. MJST. 2023;9:16–23.
MLA Barutçu, İbrahim Çağrı and Ali Erduman. “REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES”. Mugla Journal of Science and Technology, vol. 9, no. 1, 2023, pp. 16-23, doi:10.22531/muglajsci.1206817.
Vancouver Barutçu İÇ, Erduman A. REVIEW ON VOLTAGE SAG STUDIES FOR DISTRIBUTION GRID INCLUDING RENEWABLE ENERGY SOURCES. MJST. 2023;9(1):16-23.

5975f2e33b6ce.png
Muğla Sıtkı Koçman Üniversitesi Fen Bilimleri ve Teknoloji Dergisi Creative Commons Atıf-GayriTicari-AynıLisanslaPaylaş 4.0 Uluslararası Lisansı ile lisanslanmıştır.