本論文旨在研發具特殊供電結構、分散式儲能與發電系統之配電系統的建模、模擬與分析技術。首先推導配電系統主要元件與特殊供電結構之數學模型及相對應之等效電路模型。其次，以簡單且高效率的方式實現在MATLAB®/Simulink®平台上，建構出全尺度系統模型，並以IEEE 4節點與13節點測試饋線為基準系統進行驗證。接著進行一系列的應用分析，包括：(1)同相供電分析；(2)各種變壓器接地方式之運轉特性分析；(3)考量分散式發電系統併網及變壓器繞組結線方式之系統衝擊分析。最後，則提出分散式儲能與發電系統最適裝置容量之快速篩選方法。本論文研發成果將有助於配電系統同相供電、變壓器三角形中性點接地方法、分散式儲能與發電系統及智慧電網等之應用與推廣。

The main purpose of this dissertation is to develop modelling, simulation and analysis techniques for power distribution system analyses considering special service structure and dispersed storage and generation systems (DSGs). First, the mathematical models and their corresponding equivalent circuit models of major components and special service structure of power distribution systems were developed. Second, the equivalent circuit models were implemented by a simple and efficient way on the MATLAB®/Simulink® platform and thereby the full-scale system models were built. As well, they are demonstrated by two benchmark systems, the IEEE 4-node and 13-node test feeders. Next, this dissertation carry out a wide range applications on power distribution system analyses, include: (1) analysis of same-phase power supply scheme, (2) operation characteristic analysis of various kinds of grounding methods of power transformer, and (3) analysis of the impact of power distribution system considering the parallel operation of dispersed generation systems and the variety of transformer winding connections. Finally, the dissertation proposed a fast screening method to determine the optimal installed capacity for a grid-interconnected wind-storage system. The proposed techniques and results of this dissertation are of value to the promotion of same-phase power-supply service, better applications of neutral-grounded structure for a delta-connected secondary windings of power transformers, DSGs, and smart grid, and more others.

[1] V.C. Gungor, B. Lu, and G.P. Hancke, Opportunities and Challenges of Wireless Sensor Networks in Smart Grid, IEEE T IND ELECTRON, vol. 57, no. 10, pp. 3557-3564, 2010.
[2] U.S Department of Energy, 2011. [Online] Avaliable: http://www.oe.energy.gov.
[3] P. Siano, C. Cecati, C. Citro, and P. Siano, Smart Operation of Wind Turbines and Diesel Generators According to Economic Criteria, IEEE T IND ELECTRON, vol. 58, no. 10, pp. 4514-4525, 2011.
[4] H. Kanchev, D. Lu, F. Colas, V. Lazarov, and B. Francois, Energy Management and Operational Planning of a Microgrid With a PV-Based Active Generator for Smart Grid Applications," IEEE T IND ELECTR ON, vol. 58, no. 10, pp. 4582-4592, 2011
[5] P. Palensky and D. Dietrich, Demand Side Management: Demand Response, Intelligent Energy Systems, and Smart Loads, IEEE T IND INFORM, vol. 7, no. 3, pp. 381-388.
[6] V. Calderaro and C.N. Hadjicostis, A. Piccolo, P. Siano, Failure Identification in Smart Grids based on Petri Net Modeling, IEEE T IND ELECTRON, vol. 58, no. 10, 4613-4623, 2011.
[7] M. Erol-Kantarci and H.T. Mouftah, Wireless multimedia sensor and actor networks for the next generation power grid, AD HOC NETW, vol. 9, no. 4, pp. 542-551, 2011
[8] C. Cecati, C. Citro, and P. Siano, Combined Operations of Renewable Energy Systems and Responsive Demand in a Smart Grid, IEEE T SUSTAIN ENERG, vol. 2, no. 4, 468-476, 2011.
[9] A. Vaccaro, G. Velotto, and A. Zobaa, A Decentralized and Cooperative Architecture for Optimal Voltage Regulation in Smart Grids, IEEE T IND ELECTRON vol. 58, no 10, pp. 4593-4602, 2011.
[10] A.Y. Saber, and G.K. Venayagamoorthy, Plug-in Vehicles and Renewable Energy Sources for Cost and Emission Reductions, IEEE T IND ELECTRON, vol. 58, no. 4, pp. 1229-1238, 2011.
[11] W.H. Kersting, Distribution system modeling and analysis, 2nd ed. New York: Taylor & Francis Group, 2007.
[12] W.H. Testing and W.H. Phillips, Modeling and analysis of unsymmetrical transformer banks serving unbalanced loads, IEEE T IND APPL, vo. 32, no.3, p.p. 720-725, 1996.
[13] T.H. Chen and R.N. Liao, Rigorous analyses of a power distribution system with distribution transformer banks serving unbalanced loads and wind turbine generator systems, INT J NUMER MODEL EL, 2016.
[14] T.H. Chen, M.S. Chen, T. Inoue, P. Kotas, and E.A. Chebli, Three-phase cogenerator and transformer models for distribution system analysis, IEEE T POWER DELIVER, vol. 6, no. 4, pp. 1671-1681, 1991.
[15] T.H. Chen and J.D. Chang, Open wye-open delta and open delta-open delta transformer models for rigorous distribution system analysis, IEE Proceedings Generation, Transmission and Distribution, 139, pp. 227-234, 1992.
[16] Determining load characteristics for transient performance, Energy Systems Research Center, The University of Texas at Arlington, EPRI Final Report EL-848, vol. I-III, 1979.
[17] Effect of reduced voltage on the operation and efficiency of electrical loads, Energy Systems Research Center, The University of Texas at Arlington, EPRI Final Report EL-2036, vol. I-II, 1981.
[18] Effect of reduced voltage on the operation and efficiency of electrical loads, Energy Systems Research Center, The University of Texas at Arlington, EPRI Final Report EL-3591, vol. I-III, 1984.
[19] S.M. Moghaddas-Tafreshi, Elahe Mashhour, Distributed generation modeling for power flow studies and a three-phase unbalanced power flow solution for radial distribution systems considering distributed generation, ELECTR POW SYST RES, vol. 79, no. 4, pp. 680-686, 2009.
[20] K.C. Divya, and P.S. Nagendrao, Models for wind turbine generating systems and their application in load flow studies, ELECTR POW SYST RES, vol. 76, no. 9-10, pp. 844-856, 2006.
[21] A.P. Agalgaonkar, S.V. Kulkarni, and S.A. Khaparde, Impact of wind generation on loss and voltage profile in a distribution system, in: Conference on Convergent Technologies for Asia-Pacific Region, vol. 2, pp. 775-779, 2003.
[22] B. Kroposki, C. Pink, R. DeBlasio, H. Thomas, M. Simoes, and P.K. Sen, Benefits of power electronic interfaces for distributed energy systems, in: IEEE Power Engineering General Meeting, 2006.
[23] P. Gomatom and W. Jewell, Fuel parameter and quality constraints for fuel cell distributed generators, in: Transmission and Distribution Conference and Exposition, vol. 1, pp. 409-412, 2003.
[24] W. El-Khattam and M.M.A. Salama, Distributed generation technologies, definitions and benefits, ELECTR POW SYST RES, vol. 71, no. 2, pp. 119-128, 2004.
[25] Akhil, A. and S. Kraft, Battery energy storage market feasibility study – expanded report, Sandia National Laboratories, Albuquerque, NM, SAND97-1275/2, 1997.
[26] S. Naka and T. Genji, Y. Fukuyama, Practical equipment models for fast distribution power flow considering interconnection for distributed generators, in: IEEE Power Engineering Society Summer Meeting, vol. 2, pp. 1007-1012, 2001.
[27] H. Chen, J. Chen, D. Shi and X. Duan, Power flow study and voltage stability analysis for distribution systems with distributed generation, in: IEEE Power Engineering Society General Meeting, 2006.
[28] M.H. Nehrir, C. Wang, and S.R. Shaw, Feul cell: promising devices for distributed generation, IEEE POWER ENERGY M, vol. 4, no. 1, pp. 47-53, 2006.
[29] R. Zavadil, N. Miller, A. Ellis, and E. Muljadi, Making connections - wind generation facilities, IEEE POWER ENERGY M, vol. 3, no. 6, pp. 26-37, 2005.
[30] Radial Distribution Test Feeders, 2016. [Online] Avaliable: http://ewh.ieee.org/soc/pes/dsacom/ testfeeders.html.
[31] X. Kaili, M. Kala, and S. Ula, The Role of Wyoming’s Energy in Solving National Electricity Crisis, in IEEE PES Power Systems Conference and Exposition, pp. 1471-1478, 2006.
[32] S. Mukhopadhyay and S.K. Soonee, Reliability - from Load Forecasting to System Operation in Indian Power System, in: IEEE Power Engineering Society General Meeting, pp. 1-4, 2007.
[33] G.S. Grewal, J.W. Konowalec, and M. Hakim, Optimization of a load shedding scheme, IEEE IND APPL MAG, vol. 4, no. 4, pp. 25-30, 1998.
[34] Hadi Saadat, Power System Analysis, 2nd edition, International Edition Boston, McGraw-Hill, p. 413, 2004.
[35] T.H. Chen and M.S. Chen, T. Inoue, P. Otas, E.A. Chebula, Three-phase ac generator and transformer models for distribution system analysis, IEEE T POWER DELIVER, vol. 6, no. 4, pp. 1671-1681, 1991.
[36] T.H. Chen, W.C. Yang, T.Y. Guo, and G.C. Pu, Modeling and analysis of asymmetrical three-phase distribution transformer banks with mid-tap connected to the secondary neutral conductor, ELECTR POW SYST RES, vol. 54, no. 2, pp. 83-89, 2000.
[37] T.A. Short, Electric Power Distribution Handbook, 2nd Edition, New York, United States of America: CRC Press, 2014.
[38] M. Shen, L. Ingratta, and G. Roberts, Grounding transformer application, modeling, and simulation, in: Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century, pp. 1-8, 2008.
[39] Central Station Engineers, Electrical Transmission and Distribution Reference Book, Westinghouse Electric Corporation, 1997.
[40] IEEE C62.92.4-1991 - IEEE Guide for the Application of Neutral Grounding in Electrical Utility Systems, Part IV- Distribution, 1992.
[41] E.R. Detjen and K.R. Shah, Grounding transformer application and associated protection schemes, IEEE T IND APPL, vol. 28, no. 4, pp. 788-796, 1992.
[42] L.J. Carpenter, Connecting a grounding transformer to the system, General Electric Co., GER-1062.
[43] J.J. Burke, Power Distribution Engineering: Fundamentals and Applications, Marcel Dekker, New York, 1999.
[44] P. Simmons, Electrical Grounding and Bonding based on the 2014 National Electrical Code, 4th Edition, 2014.
[45] D. Paul and S.I. Venygopalan, Low-resistance Grounding Method for Medium-voltage Power Systems, in: IEEE Industry Applications Society Annual Meeting, vol. 2, pp.1571-1578, 1991.
[46] T.C. Surbrook, N.D. Reese, and J.R. Althouse, Parameters affecting neutral-to-earth voltage along primary distribution circuits, IEEE T IND APPL, vol. 24, no 5, pp. 798-804, 1988.
[47] IEEE 241-1990 - IEEE Recommended Practice for Electric Power Systems in Commercial Buildings, IEEE Gray Book, 1991.
[48] IEEE 142-2007 - IEEE Recommended Practice for Grounding of Industrial and Commercial Power Systems, IEEE Green Book, 1992.
[49] E.R. Detjen and K.R. Shah, Grounding Transformer Applications and Associated Protection Schemes, IEEE T IND APPL, vol. 28, no.4, 1992.
[50] P.E. Sutherland, Application of Transformer Ground Differential Protection Relays, IEEE T IND APPL, vol. 36, no. 1, 2000.
[51] D. Paul and S.I. Venygopalan, Low-resistance grounding method for medium voltage power systems, in: IEEE Industry Applications Society Annual Meeting, vol. 2, pp.1571-1578, 1991.
[52] A.P.S. Meliopoulous, Power System Grounding and Transients: An Introduction, Marcel Dekker, New York, 1998.
[53] T.H. Chen, I Chang, and T.J. Chen, Neutral-grounding structure for delta-connected windings and method thereof, Pub. No. US 20110084790 A1, 2011.
[54] Distribution Test Feeders, IEEE PES Distribution System Analysis Subcommittee’s. Distribution Test Feeder Working Group Std., 2016. [Online] Available: http://ewh.ieee.org/soc/pes/dsacom/testfeeders/
[55] B.K. Mathur, The Modeling of Load Characteristics Representation in System Studies, IEEE T IND APPL, vol. 20, no. 1, pp.167-172, 1984.
[56] IEEE 1159-2009 - IEEE recommended practice for monitoring electric power quality, pp. c1-81, 1991.
[57] IEEE C57.105, IEEE Guide for Applications of Transformer Connections in Three-Phase Distribution Systems, 1978.
[58] IEEE PC57.159/D6.1 - IEEE Draft Guide on Transformers for Application in Distributed Photovoltaic (DPV) Power Generation Systems, pp. 1-37, 2016.
[59] H. James, Electric Power Transformer Engineering, 3th Edition, CRC Press, New York, USA.
[60] J.J. Burke, Power Distribution Engineering - Fundamentals and Applications, Marcel Dekker, New York, USA.
[61] G. Turan, Electric Power Distribution Engineering, 3th Edition, CRC Press, New. York, USA.
[62] J.A.P. Lopes, N. Hatziargyriou, J. Mutable, P. Djapic, and N. Jenkins, Integrating distributed generation into electric power systems: A review of drivers, challenges and opportunities, ELECTR POWER SYST RES, vol. 77, no. 9, pp. 1189-1203, 2007.
[63] Y. Ruining and T.K. Saha, Investigation of voltage variations in unbalanced distribution systems due to high photovoltaic penetrations, in: IEEE Power and Energy Society General Meeting, pp. 1-8, 2011.
[64] R.A. Walling, R. Saint, R.C. Duggan, J. Burke, and L.A. Kojic, Summary of Distributed Resources Impact on Power Delivery System, IEEE T POWER DELIVER, vol. 23, no. 3, 1636-1644, 2008.
[65] J.B.V. Subrahmanyam and C. Radhakrishnan, A simple method for feeder reconfiguration of balanced and unbalanced distribution systems for loss minimization, ELECTR POW COMPO SYS, vol. 38, no.1, pp. 72-84, 2009.
[66] V. Khadkikar, Enhancing Electric Power Quality Using UPQC: A Comprehensive Overview, IEEE T POWER ELECTR, vol. 27, no. 3, pp. 2284-2297, 2012.
[67] T.H. Chen, M.S. Chen, K.J. Hwang, P. Kotas, and E.A. Chebli, Distribution system power flow analysis - a rigid approach, IEEE T POWER DELIVER, vol. 6, no. 3, pp. 1146-1152, 1991.
[68] M.S. Chen and T.H. Chen, Application of three-phase load flow to power system distribution automation, in Advances in Power System Control, Operation and Management, vol. 2, pp. 472-478, 1991.
[69] T.H. Chen, J.D. Chang, and Y.L. Chang, Models of grounded mid-tap open-wye and open-delta connected transformers for rigorous analysis of a distribution system, IEE P-GENER TRANSM D, vol. 143, no. 1, pp. 82-88, 1996.
[70] T.H. Chen and W.C. Yang, Modeling and analysis of three-phase four-wire distribution transformers with mid-tap on the secondary side, in Energy Management and Power Delivery, vol. 2, pp. 723–727, 1998.
[71] T.H. Chen and H.Y. Kuo, Network modelling of traction substation transformers for studying unbalance effects, IEE P-GENER TRANSM D, vol. 142, no. 2, pp. 103-108, 1995.
[72] Distribution System Analysis Subcommittee, IEEE 34 Node Feeder, Radial Test feeder, 2016. [Online] Available: http://ewh.ieee.org/soc/pes/dsacom/testfeeders/index.html.
[73] MATLAB® & Simulink® User’s Guide R2015b, 2016. [Online] Available: http://www.mathworks.com.
[74] A. Canova, L. Giaccone, F. Spertino, and M. Tartaglia, Electrical impact of photovoltaic plant in distributed network, IEEE T IND APPL, vol. 45, no. 1, pp. 341-347, 2009.
[75] K. Balamurugan, D. Srinivasan, and T. Reindl, Impact of Distributed Generation on Power Distribution System, Energy Procedia, vol. 25, pp. 93-100, 2012.
[76] Taiwan Power Company, Generalized distribution analysis system, in Distribution technical manual, vol. 2, 1989.
[77] S. Teleke, M.E. Baran, S. Bhattacharya, and A.Q. Huang, Rule-based control of battery energy storage for dispatching intermittent renewable sources, IEEE T SUSTAIN ENERG, vol. 1, no. 3, pp. 117-124, 2010.
[78] World Wind Energy Association, Wind energy international 2011/2012. [Online] Available: http://www.wwindea.org/home/index.php.
[79] X. Lu, M.B. McElroy, and J. Kiviluoma, Global potential for wind-generated electricity, Proceedings of the National Academy of Sciences 2009; vol. 106, no.27, pp. 10933-10938, 2009.
[80] U.S. Department of Energy (DOE), 20 % wind energy by 2030: Increasing wind energy’s contribution to U.S. electricity supply, Energy Efficiency and Renewable Energy, 2008.
[81] R.A. Walling, R. Saint, R.C. Dugan, J. Burke, and L.A. Kojovic, Summary of distributed resources impact on power delivery systems, IEEE T POWER DELIVER, vol. 23, no. 3, pp. 1636-1644, 2008.
[82] J.W. Park, Y.H. Park, and S.I. Moon, Instantaneous wind power penetration in Jeju Island, in: Power Engineering Society General Meeting, Pittsburgh, 2008.
[83] S.A. Papathanassiou, and N.G. Boulaxis, Power limitations and energy yield evaluation for wind farms operating in island systems, RENEW ENERG, vol. 31, no.4, pp.457-479, 2006.
[84] J.K. Kaldellis, The wind potential impact on the maximum wind energy penetration in autonomous electrical grids, RENEW ENERG, vol. 33, no. 7, pp. 1665-1677, 2008.
[85] J.K. Kaldellis, K.A. Kavadias, A.E. Filios, and S. Garofallakis, Income loss due to wind energy rejected by the Crete island electrical network – the present situation, APPL ENERG, vol. 79, no. 2, pp. 127-144, 2004.
[86] E. Muljadi, C.P. Butterfield, R. Yinger, and H. Romanowitz, Energy storage and reactive power compensator in a large wind farm, 42nd AIAA Aerospace Sciences Meeting and Exhibit, Reno, 2004.
[87] A. Arulampalam, M. Barnes, N. Jenkins, and J.B. Ekanayake, Power quality and stability improvement of a wind farm using STATCOM supported with hybrid battery energy storage, IEE P-GENER TRAN, vol. 153, no. 6, pp. 701-710.
[88] J. Zeng, B. Zhang, C. Mao, and Y.Wang, Use of battery energy storage system to improve the power quality and stability of wind farms, in: Power System Technology Conference, pp. 1-6, 2006.
[89] K. Yoshimoto, T. Nanahara, and G. Koshimizu, New control method for regulating state-of-charge of a battery in hybrid wind power/battery energy storage system, in: IEEE Power Systems Conference and Exposition, Atlanta, pp. 1244-1251, 2006.
[90] C. Banos, M. Aten, P. Cartwright, and T.C. Green, Benefits and control of STATCOM with energy storage in wind power generation, in: AC and DC Power Transmission Conference, London, pp. 230-235, 2006.
[91] T.H. Chen, R.N. Liao, C.Y. Yang, and Y.H. Chiang, Application of grid-level battery energy storage system to wind power fluctuation smoothing, Journal of Clean Energy Technologies, vol. 4, no.3, pp.201-204, 2016.
[92] M. Korpaas, A.T. Holen, and R. Hildrum, Operation and sizing of energy storage for wind power plants in a market system, INT J ELEC POWER, vol. 25, no.8, pp. 599-606, 2003.
[93] G.N. Bathurst and G. Strbac, Value of combining energy storage and wind in short-term energy and balancing markets, ELECTR POW SYST RES, vol. 67, no. 1, pp. 1-8, 2003.
[94] J.P. Barton and D.G. Infield, A probabilistic method for calculating the usefulness of a store with finite energy capacity for smoothing electricity generation wind and solar power, J POWER SOURCES, vol. 162, no.2, pp. 943-948, 2006.
[95] P. Pinson, G. Papaefthymiou, and B. Klockl, J. Verboomen, Dynamic sizing of energy storage for hedging wind power forecast uncertainty, in: IEEE Power & Energy Society General Meeting, Calgray, pp. 1-8, 2009.
[96] Y.V. Makarov, D. Pengwei, M.C.W. Kintner-Meyer, J. Chunlian, and H.F. Illian, Sizing energy storage to accommodate high penetration of variable energy resources, IEEE T SUSTAIN ENERG, vol. 3, no. 1, pp. 34-40, 2011.
[97] C. Jaworsky, K. Turitsyn, and S. Backhaus, The effect of forecasting accuracy on the sizing of energy storage, in: Dynamic Systems and Control Conference, Texas, USA, 2014.
[98] X. Luo, J. Wang, M. Dooner, and J. Clarke, Overview of current development in electrical energy storage technologies and the application potential in power system operation. APPL ENERG, vol. 137, no. 1, pp. 511-536, 2015.
[99] H. Chen, T.N. Cong, W. Yang, C. Tan, Y. Li, and Y. Ding, Progress in electrical energy storage system: A critical review, Progress in Natural Science, vol. 19, no. 3, pp. 291-312, 2009.
[100] T.Ackermann, Wind power in power systems: John Wiley & Sons, pp. 111-112, 2005.
[101] S.A. Papathanassiou and N.D. Hatziargyriou, Technical requirements for the connection of dispersed generation to the grid, in: Power Engineering Society Summer Meeting, vol. 2, pp. 749-754, 2001.
[102] Y. Kubota, T. Genji, S. Takayama, and Y. Fukuyama, Influence of distribution voltage control methods on maximum capacity of distributed generators, ELECTR ENG JPN, vol. 150, no.1, pp. 8-17, 2005.
[103] Y. Kubota and T. Genji, A theory of maximum capacity of distributed generators connected to a distribution system using electric power density model, ELECTR ENG JPN, vol. 155, no. 3, pp. 18-28, 2006.
[104] Y. Kubota and T. Genji, Maximum capacity of distributed generators connected to a distribution system with a step voltage regulator, as determined with an electric power density model, ELECTR ENG JPN, vol. 165, no.4, pp. 41-51, 2008.
[105] H. Hedayati, S.A. Nabaviniaki, and A. Akbarimajd, A method for placement of DG units in distribution networks, IEEE T POWER DELIVER, vol. 23, no. 3, pp. 1620-1628, 2008.
[106] N.C. Yang and T.H. Chen, Dual genetic algorithm-based approach to fast screening process for distributed-generation interconnections, IEEE T POWER DELIVER, vol. 26, no. 2, pp. 850-858, 2011.
[107] M. Obitko and P. Slavik, Visualization of genetic algorithms in a learning environment, Spring Conference on Computer Graphics, 1999; SCCG'99. Bratislava: Comenius University, 101-106.