Year 2022,
Volume: 35 Issue: 2, 524 - 540, 01.06.2022
Hacer Oztura
,
Sezai Polat
References
- [1] Das, T., Roy, R. and Mandal, K.K., “Impact of the penetration of distributed generation on optimal reactive power dispatch” , Protection and Control of Modern Power Systems, 5 (1): (2020).
- [2] Guo, J., Ding, X. and Wu, W., “A Blockchain-Enabled Ecosystem for Distributed Electricity Trading in Smart City” , IEEE Internet of Things Journal, 8 (3): 2040–2050, (2021).
- [3] Baloch, S. and Muhammad, M.S., “An Intelligent Data Mining-Based Fault Detection and Classification Strategy for Microgrid” , IEEE Access, 9 22470–22479, (2021).
- [4] Pesaran H.A.M., Huy, P.D. and Ramachandaramurthy, V.K., “A review of the optimal allocation of distributed generation: Objectives, constraints, methods, and algorithms” , Renewable and Sustainable Energy Reviews, 75 (May 2016): 293–312, (2017).
- [5] Haider, W., S.J. Ul Hassan, A. Mehdi, A. Hussain, G.O.M. Adjayeng, and C.H. Kim, “Voltage profile enhancement and loss minimization using optimal placement and sizing of distributed generation in reconfigured network” , Machines, 9 (1): 1–16, (2021).
- [6] Karimi, M., Farshad, M., Hong, Q., Laaksonen, H. and Kauhaniemi, K., “An Islanding Detection Technique for Inverter-Based Distributed Generation in Microgrids” , Energies, 14 (1): 130, (2020).
- [7] Zheng, T., Yang, H., Zhao, R., Kang, Y.C. and Terzija, V., “Design, evaluation and implementation of an islanding detection method for a micro-grid” , Energies, 11 (2): 323, (2018).
- [8] Pinto, J.O.C.P. and Moreto, M. “Protection strategy for fault detection in inverter-dominated low voltage AC microgrid” , Electric Power Systems Research, 190 (August 2020): 106572, (2021).
- [9] Kim, I., “A calculation method for the short-circuit current contribution of current-control inverter-based distributed generation sources at balanced conditions” , Electric Power Systems Research, 190 (August 2020): 106839, (2021).
- [10] Xiao, H., Ren, S. and Li, Y., “Novel disturbance blocking criterion for reliable current differential protection of LCC-HVDC lines” , IEEE Transactions on Power Delivery, 36 (1): 477–480, (2021).
- [11] Gao, S.P., Liu, Q. and Song, G.B., “Current differential protection principle of HVDC transmission system” , IET Generation, Transmission and Distribution, 11 (5): 1286–1292, (2017).
- [12] Zarei, S.F. and Khankalantary, S., “Protection of active distribution networks with conventional and inverter-based distributed generators” , International Journal of Electrical Power and Energy Systems, 129 (June 2020): 106746, (2021).
- [13] Sahito, A.A., I.A. Halepoto, M.A. Uqaili, Z.A. Memon, A.S. Larik, and M.A. Mahar, “Analyzing the Impacts of Distributed Generation Integration on Distribution Network: A Corridor Towards Smart Grid Implementation in Pakistan” , Wireless Personal Communications, 85 (2): 545–563, (2015).
- [14] Avagaddi, P., and B. Edward J, “Fault classification in transmission systems using wavelet transform” , Gazi University Journal of Science, 32 (3): 884–893, (2019).
- [15] Shobole, A., Baysal, M., Wadi, M. and Tur, M.R., “Protection Coordination in Electrical Substation Part-2 Unit Protections (Differential and Distance Protection) -Case Study of Siddik Kardesler Substation (SKS), Istanbul, Turkey” , Gazi University Journal of Science, 30 (4): 163–178, (2017).
- [16] Ayvaz, A. and Boylu, A.B., “Determination of optimal placement of fault current limiting device against short circuit faults occur in power systems” , Sakarya University Journal of Science, 22 (2): 615–623, (2018).
- [17] Alasali, F., El-Naily, N., Zarour, E. and Saad, S.M., “Highly sensitive and fast microgrid protection using optimal coordination scheme and nonstandard tripping characteristics” , International Journal of Electrical Power and Energy Systems, 128 (October 2020): 106756, (2021).
- [18] Chandraratne, C., Ramasamy, T.N., Logenthiran, T. and Panda, G., “Adaptive protection for microgrid with distributed energy resources” , Electronics (Switzerland), 9 (11): 1–14, (2020).
- [19] Yalcin, F. and Yildirim, Y., “A Study of Symmetrical and Unsymmetrical Short Circuit Fault Analyses in Power Systems” , Sakarya University Journal of Science, 23 (5): 879–895, (2019).
- [20] Rustemli, S. and Demir, I., “Analysis and simulation of single phase-to-ground short circuit fault in Van 154 kV substation: An experimental assessment” , Bitlis Eren University Journal of Science and Technology, 9 (2): 76–82, (2019).
- [21] Patil Electrical, B. and Namekar, S., “Load Flow & Short Circuit Analysis of 132/33/11KV Substation using ETAP” , International Journal of Applied Engineering Research, 13 (11): 9943–9952, (2018).
- [22] Hosseini, S.A., Sadeghi, S.H.H.and Nasiri, A., “Decentralized Adaptive Protection Coordination Based on Agents Social Activities for Microgrids with Topological and Operational Uncertainties” , IEEE Transactions on Industry Applications, 57 (1): 702–713, (2021).
- [23] Ballal, M.S. and Kulkarni, A.R., “Improvements in Existing System Integrity Protection Schemes under Stressed Conditions by Synchrophasor Technology -Case Studies” , IEEE Access, 9 (2021).
- [24] Muljadi, E. and Gevorgian, V., “Short-circuit modeling of a wind power plant” , IEEE Power and Energy Society General Meeting, 1–9, (2011).
- [25] Devi, M.M., Geethanjali, M. and Devi, A.R., “Fault localization for transmission lines with optimal Phasor Measurement Units” , Computers and Electrical Engineering, 70 163–178, (2018).
- [26] Asija, D., Choudekar, P., Singla, R. and Chouhan, M., “Performance Evaluation and Improvement in Transient Instability of IEEE 9 Bus System Using Exciter and Governor Control” , Procedia Computer Science, 70 733–739, (2015).
- [27] Khatua, S.,and Mukherjee, V., “Adaptive overcurrent protection scheme suitable for station blackout power supply of nuclear power plant operated through an integrated microgrid” , Electric Power Systems Research, 192 (March 2020): 106934, (2021).
- [28] Balamurugan, K., Srinivasan, D. and Reindl, T., “Impact of distributed generation on power distribution systems” , Energy Procedia, 25 93–100, (2012).
- [29] Shin, H., S.H. Chae, and E.-H. Kim, “Design of Microgrid Protection Schemes Using PSCAD/EMTDC and ETAP Programs” , Energies, 13 (21): 5784, (2020).
- [30] Nadeem, M.H., Zheng, X., Tai, N., Gul, M., Yu, M. and He, Y., “Non-communication based protection scheme using transient harmonics for multi-terminal HVDC networks” , International Journal of Electrical Power & Energy Systems, 127 106636, (2021).
- [31] Darwish, A., Abdel-Khalik, A.S., Elserougi, A., Ahmed, S. and Massoud, A. “Fault current contribution scenarios for grid-connected voltage source inverter-based distributed generation with an LCL filter” , Electric Power Systems Research, 104 93–103, (2013).
- [32] Song, J., Li, Y. and Zhang, Y., “Fault steady-state analysis method for the AC system with LCC-HVDC infeed” , Electric Power Systems Research, 192 106994, (2021).
- [33] Bendjabeur, A., Kouadri, A.and Mekhilef, S. “Transmission line fault location by solving line differential equations” , Electric Power Systems Research, 192 106912, (2021).
- [34] Moustafa, M.A.M.M., and Chang, C. “Preventing cascading failure of electric power protection systems in nuclear power plant” , Nuclear Engineering and Technology, 53 (1): 121–130, (2021).
- [35] El-Khattam, W. and Salama, M.M.A. “Distributed generation technologies, definitions and benefits” , Electric Power Systems Research, 71 (2): 119–128, (2004).
- [36] Bawazir, R.O., and N.S. Cetin, “Comprehensive overview of optimizing PV-DG allocation in power system and solar energy resource potential assessments” , Energy Reports, 6 173–208, (2020).
- [37] Dondi, P., D. Bayoumi, C. Haederli, D. Julian, and M. Suter, “Network integration of distributed power generation” , Journal of Power Sources, 106 (1–2): 1–9, (2002).
- [38] Pepermans, G., Driesen, J., Haeseldonckx, D., Belmans, R. and D’haeseleer, W., “Distributed generation: Definition, benefits and issues” , Energy Policy, 33 (6): 787–798, (2005).
- [39] Ochoa, L.F., Padilha-Feltrin, A. and Harrison, G.P. “Evaluating distributed generation impacts with a multiobjective index” , IEEE Transactions on Power Delivery, 21 (3): 1452–1458, (2006).
- [40] Farzinfar, M. and Jazaeri, M. “A novel methodology in optimal setting of directional fault current limiter and protection of the MG” , International Journal of Electrical Power and Energy Systems, 116 (September 2019): 105564, (2020).
- [41] Alcala-Gonzalez, D., Del Toro, E.M.G., Más-López, M.I. and Pindado, S., “Effect of distributed photovoltaic generation on short-circuit currents and fault detection in distribution networks: A practical case study” , Applied Sciences (Switzerland), 11 (1): 1–16, (2021).
- [42] Boutsika, T.N., and Papathanassiou, S.A., “Short-circuit calculations in networks with distributed generation” , Electric Power Systems Research, 78 (7): 1181–1191, (2008).
- [43] Dincer, I. and Rosen, M.A., Cogeneration, Multigeneration, and Integrated Energy Systems, in: Exergy Analysis of Heating, Refrigerating and Air Conditioning, 2015: pp. 169–219.
- [44] Ghaedi, A. and Golshan, M.E.H., “Modified WLS three-phase state estimation formulation for fault analysis considering measurement and parameter errors” , Electric Power Systems Research, 190 (March 2020): 106854, (2021).
- [45] Yang, S. and Tong, X., “Integrated power flow and short circuit calculation method for distribution network with inverter based distributed generation” , Mathematical Problems in Engineering, 2016 (2016).
- [46] Baran, M.E. and El-Markaby, I., “Fault Analysis on Distribution Feeders With Distributed Generators” , IEEE Transactions on Power Systems, 20 (4): 1757–1764, (2005).
- [47] Abdel-Akher, M. and Nor, K.M., “Fault analysis of multiphase distribution systems using symmetrical components” , IEEE Transactions on Power Delivery, 25 (4): 2931–2939, (2010).
- [48] Strezoski, L. V. and Prica, M.D., “Short-circuit analysis in large-scale distribution systems with high penetration of distributed generators” , IEEE/CAA Journal of Automatica Sinica, 4 (2): 243–251, (2017).
- [49] Abdel-Akher, M. and K.M. Nor, “Fault Analysis of Multiphase Distribution Systems Using Symmetrical Components” , IEEE Transactions on Power Delivery, 25 (4): 2931–2939, (2010).
- [50] PSS/SINCAL (SIEMENS Network Calculation) software, “Introduction to the System Manual”, (2014).
- [51] https://new.siemens.com/global/en/products/energy/services/transmission-distribution-smart-grid/consulting-and-planning/pss-software/pss-sincal/pss-sincal.html#Electricitymodules. Access date: 17.07.2020.
A Symmetrical-Asymmetrical Fault Characteristics Analysis within Cogeneration Power Plant in Izmir, Turkey: An Experimental Assessment
Year 2022,
Volume: 35 Issue: 2, 524 - 540, 01.06.2022
Hacer Oztura
,
Sezai Polat
Abstract
The analysis of the short circuit should be understood very well in order to make correct designs in the power systems such as the safety of the personnel and the equipment, the selection of the safety relays, the circuit breaker selection and the selection of the appropriate conductor section. In this study, the parameters about the short circuit and the techniques of calculating the faults in system and the necessary theoretical knowledge for the short circuit fault to be understood better have been given. The effect on the distributed generation and the grid which is caused by the possible short circuit faults have been simulated by being modeled in PSS/Sincal and by using the real grid parameters with cogeneration power plant in Izmir, Turkey. The real short circuit fault results measured from the power plant and the grid and the results obtained from the software program have been compared and it has been determined that there is not a significant difference between them. Thus, it has been emphasized that it is correct to simulate before investing in a power system in for the purpose of restrain the faults during the designing and working before the application. It allows the designer to design new power plant as good as plan expansion of existing power plants with higher degree of precision. Considering the prices of protection equipment, which has a large part in system design, this way would allow designer to reduce the cost of the protective equipment and remaining stability.
References
- [1] Das, T., Roy, R. and Mandal, K.K., “Impact of the penetration of distributed generation on optimal reactive power dispatch” , Protection and Control of Modern Power Systems, 5 (1): (2020).
- [2] Guo, J., Ding, X. and Wu, W., “A Blockchain-Enabled Ecosystem for Distributed Electricity Trading in Smart City” , IEEE Internet of Things Journal, 8 (3): 2040–2050, (2021).
- [3] Baloch, S. and Muhammad, M.S., “An Intelligent Data Mining-Based Fault Detection and Classification Strategy for Microgrid” , IEEE Access, 9 22470–22479, (2021).
- [4] Pesaran H.A.M., Huy, P.D. and Ramachandaramurthy, V.K., “A review of the optimal allocation of distributed generation: Objectives, constraints, methods, and algorithms” , Renewable and Sustainable Energy Reviews, 75 (May 2016): 293–312, (2017).
- [5] Haider, W., S.J. Ul Hassan, A. Mehdi, A. Hussain, G.O.M. Adjayeng, and C.H. Kim, “Voltage profile enhancement and loss minimization using optimal placement and sizing of distributed generation in reconfigured network” , Machines, 9 (1): 1–16, (2021).
- [6] Karimi, M., Farshad, M., Hong, Q., Laaksonen, H. and Kauhaniemi, K., “An Islanding Detection Technique for Inverter-Based Distributed Generation in Microgrids” , Energies, 14 (1): 130, (2020).
- [7] Zheng, T., Yang, H., Zhao, R., Kang, Y.C. and Terzija, V., “Design, evaluation and implementation of an islanding detection method for a micro-grid” , Energies, 11 (2): 323, (2018).
- [8] Pinto, J.O.C.P. and Moreto, M. “Protection strategy for fault detection in inverter-dominated low voltage AC microgrid” , Electric Power Systems Research, 190 (August 2020): 106572, (2021).
- [9] Kim, I., “A calculation method for the short-circuit current contribution of current-control inverter-based distributed generation sources at balanced conditions” , Electric Power Systems Research, 190 (August 2020): 106839, (2021).
- [10] Xiao, H., Ren, S. and Li, Y., “Novel disturbance blocking criterion for reliable current differential protection of LCC-HVDC lines” , IEEE Transactions on Power Delivery, 36 (1): 477–480, (2021).
- [11] Gao, S.P., Liu, Q. and Song, G.B., “Current differential protection principle of HVDC transmission system” , IET Generation, Transmission and Distribution, 11 (5): 1286–1292, (2017).
- [12] Zarei, S.F. and Khankalantary, S., “Protection of active distribution networks with conventional and inverter-based distributed generators” , International Journal of Electrical Power and Energy Systems, 129 (June 2020): 106746, (2021).
- [13] Sahito, A.A., I.A. Halepoto, M.A. Uqaili, Z.A. Memon, A.S. Larik, and M.A. Mahar, “Analyzing the Impacts of Distributed Generation Integration on Distribution Network: A Corridor Towards Smart Grid Implementation in Pakistan” , Wireless Personal Communications, 85 (2): 545–563, (2015).
- [14] Avagaddi, P., and B. Edward J, “Fault classification in transmission systems using wavelet transform” , Gazi University Journal of Science, 32 (3): 884–893, (2019).
- [15] Shobole, A., Baysal, M., Wadi, M. and Tur, M.R., “Protection Coordination in Electrical Substation Part-2 Unit Protections (Differential and Distance Protection) -Case Study of Siddik Kardesler Substation (SKS), Istanbul, Turkey” , Gazi University Journal of Science, 30 (4): 163–178, (2017).
- [16] Ayvaz, A. and Boylu, A.B., “Determination of optimal placement of fault current limiting device against short circuit faults occur in power systems” , Sakarya University Journal of Science, 22 (2): 615–623, (2018).
- [17] Alasali, F., El-Naily, N., Zarour, E. and Saad, S.M., “Highly sensitive and fast microgrid protection using optimal coordination scheme and nonstandard tripping characteristics” , International Journal of Electrical Power and Energy Systems, 128 (October 2020): 106756, (2021).
- [18] Chandraratne, C., Ramasamy, T.N., Logenthiran, T. and Panda, G., “Adaptive protection for microgrid with distributed energy resources” , Electronics (Switzerland), 9 (11): 1–14, (2020).
- [19] Yalcin, F. and Yildirim, Y., “A Study of Symmetrical and Unsymmetrical Short Circuit Fault Analyses in Power Systems” , Sakarya University Journal of Science, 23 (5): 879–895, (2019).
- [20] Rustemli, S. and Demir, I., “Analysis and simulation of single phase-to-ground short circuit fault in Van 154 kV substation: An experimental assessment” , Bitlis Eren University Journal of Science and Technology, 9 (2): 76–82, (2019).
- [21] Patil Electrical, B. and Namekar, S., “Load Flow & Short Circuit Analysis of 132/33/11KV Substation using ETAP” , International Journal of Applied Engineering Research, 13 (11): 9943–9952, (2018).
- [22] Hosseini, S.A., Sadeghi, S.H.H.and Nasiri, A., “Decentralized Adaptive Protection Coordination Based on Agents Social Activities for Microgrids with Topological and Operational Uncertainties” , IEEE Transactions on Industry Applications, 57 (1): 702–713, (2021).
- [23] Ballal, M.S. and Kulkarni, A.R., “Improvements in Existing System Integrity Protection Schemes under Stressed Conditions by Synchrophasor Technology -Case Studies” , IEEE Access, 9 (2021).
- [24] Muljadi, E. and Gevorgian, V., “Short-circuit modeling of a wind power plant” , IEEE Power and Energy Society General Meeting, 1–9, (2011).
- [25] Devi, M.M., Geethanjali, M. and Devi, A.R., “Fault localization for transmission lines with optimal Phasor Measurement Units” , Computers and Electrical Engineering, 70 163–178, (2018).
- [26] Asija, D., Choudekar, P., Singla, R. and Chouhan, M., “Performance Evaluation and Improvement in Transient Instability of IEEE 9 Bus System Using Exciter and Governor Control” , Procedia Computer Science, 70 733–739, (2015).
- [27] Khatua, S.,and Mukherjee, V., “Adaptive overcurrent protection scheme suitable for station blackout power supply of nuclear power plant operated through an integrated microgrid” , Electric Power Systems Research, 192 (March 2020): 106934, (2021).
- [28] Balamurugan, K., Srinivasan, D. and Reindl, T., “Impact of distributed generation on power distribution systems” , Energy Procedia, 25 93–100, (2012).
- [29] Shin, H., S.H. Chae, and E.-H. Kim, “Design of Microgrid Protection Schemes Using PSCAD/EMTDC and ETAP Programs” , Energies, 13 (21): 5784, (2020).
- [30] Nadeem, M.H., Zheng, X., Tai, N., Gul, M., Yu, M. and He, Y., “Non-communication based protection scheme using transient harmonics for multi-terminal HVDC networks” , International Journal of Electrical Power & Energy Systems, 127 106636, (2021).
- [31] Darwish, A., Abdel-Khalik, A.S., Elserougi, A., Ahmed, S. and Massoud, A. “Fault current contribution scenarios for grid-connected voltage source inverter-based distributed generation with an LCL filter” , Electric Power Systems Research, 104 93–103, (2013).
- [32] Song, J., Li, Y. and Zhang, Y., “Fault steady-state analysis method for the AC system with LCC-HVDC infeed” , Electric Power Systems Research, 192 106994, (2021).
- [33] Bendjabeur, A., Kouadri, A.and Mekhilef, S. “Transmission line fault location by solving line differential equations” , Electric Power Systems Research, 192 106912, (2021).
- [34] Moustafa, M.A.M.M., and Chang, C. “Preventing cascading failure of electric power protection systems in nuclear power plant” , Nuclear Engineering and Technology, 53 (1): 121–130, (2021).
- [35] El-Khattam, W. and Salama, M.M.A. “Distributed generation technologies, definitions and benefits” , Electric Power Systems Research, 71 (2): 119–128, (2004).
- [36] Bawazir, R.O., and N.S. Cetin, “Comprehensive overview of optimizing PV-DG allocation in power system and solar energy resource potential assessments” , Energy Reports, 6 173–208, (2020).
- [37] Dondi, P., D. Bayoumi, C. Haederli, D. Julian, and M. Suter, “Network integration of distributed power generation” , Journal of Power Sources, 106 (1–2): 1–9, (2002).
- [38] Pepermans, G., Driesen, J., Haeseldonckx, D., Belmans, R. and D’haeseleer, W., “Distributed generation: Definition, benefits and issues” , Energy Policy, 33 (6): 787–798, (2005).
- [39] Ochoa, L.F., Padilha-Feltrin, A. and Harrison, G.P. “Evaluating distributed generation impacts with a multiobjective index” , IEEE Transactions on Power Delivery, 21 (3): 1452–1458, (2006).
- [40] Farzinfar, M. and Jazaeri, M. “A novel methodology in optimal setting of directional fault current limiter and protection of the MG” , International Journal of Electrical Power and Energy Systems, 116 (September 2019): 105564, (2020).
- [41] Alcala-Gonzalez, D., Del Toro, E.M.G., Más-López, M.I. and Pindado, S., “Effect of distributed photovoltaic generation on short-circuit currents and fault detection in distribution networks: A practical case study” , Applied Sciences (Switzerland), 11 (1): 1–16, (2021).
- [42] Boutsika, T.N., and Papathanassiou, S.A., “Short-circuit calculations in networks with distributed generation” , Electric Power Systems Research, 78 (7): 1181–1191, (2008).
- [43] Dincer, I. and Rosen, M.A., Cogeneration, Multigeneration, and Integrated Energy Systems, in: Exergy Analysis of Heating, Refrigerating and Air Conditioning, 2015: pp. 169–219.
- [44] Ghaedi, A. and Golshan, M.E.H., “Modified WLS three-phase state estimation formulation for fault analysis considering measurement and parameter errors” , Electric Power Systems Research, 190 (March 2020): 106854, (2021).
- [45] Yang, S. and Tong, X., “Integrated power flow and short circuit calculation method for distribution network with inverter based distributed generation” , Mathematical Problems in Engineering, 2016 (2016).
- [46] Baran, M.E. and El-Markaby, I., “Fault Analysis on Distribution Feeders With Distributed Generators” , IEEE Transactions on Power Systems, 20 (4): 1757–1764, (2005).
- [47] Abdel-Akher, M. and Nor, K.M., “Fault analysis of multiphase distribution systems using symmetrical components” , IEEE Transactions on Power Delivery, 25 (4): 2931–2939, (2010).
- [48] Strezoski, L. V. and Prica, M.D., “Short-circuit analysis in large-scale distribution systems with high penetration of distributed generators” , IEEE/CAA Journal of Automatica Sinica, 4 (2): 243–251, (2017).
- [49] Abdel-Akher, M. and K.M. Nor, “Fault Analysis of Multiphase Distribution Systems Using Symmetrical Components” , IEEE Transactions on Power Delivery, 25 (4): 2931–2939, (2010).
- [50] PSS/SINCAL (SIEMENS Network Calculation) software, “Introduction to the System Manual”, (2014).
- [51] https://new.siemens.com/global/en/products/energy/services/transmission-distribution-smart-grid/consulting-and-planning/pss-software/pss-sincal/pss-sincal.html#Electricitymodules. Access date: 17.07.2020.