利用系統動態學建構電力產業差距模式探討台灣低碳轉型政策_

:::

詳目顯示

第 1 筆 / 總合 1 筆

/1頁

論文基本資料
摘要
外文摘要
參考文獻

題名：	利用系統動態學建構電力產業差距模式探討台灣低碳轉型政策
作者：	陳俊成
作者(外文)：	Chun-Cheng Chen
校院名稱：	國立中央大學
系所名稱：	企業管理學系
指導教授：	張東生
學位類別：	博士
出版日期：	2020
主題關鍵詞：	能源轉型；能源政策；系統動態學；缺口模式；energy transition；energy mix；energy policy；energy security；system dynamics
原始連結：	連回原系統網址
相關次數：	被引用次數:期刊(0) 博士論文(0) 專書(0) 專書論文(0) 排除自我引用:0 共同引用:0 點閱:1

工業化國家電力產業發展的主要目標在維持一個充足且負擔得起的電力供給，以供應一國產業發展與經濟成長的需求。電力系統逐步調整供電結構邁向低碳發電則是電力產業提高環境效率的新趨勢。然而使用成本較高的再生能源發電將衝擊電力產業的成本結構，更進一步影響電價導致電力產業在能源轉型中陷入兩難的境地。如何在管制電價與低碳能源使用之間取得平衡成為了政府能源政策所要關注的焦點。電力產業能源轉型是一個複雜且動態的過程，受到政府政策和國際燃料價格等因素的影響。因此，本研究採用系統動態學方法論去建構台灣電力產業的缺口模式，以探討台灣供電結構在能源轉型過程中的演變。藉由分析其系統結構以瞭解其系統行為，模擬並討論政府政策對再生能源發電的影響及其管理意涵。

以文找文

The primary objective of a regulated electric power industry in an industrialized country is the uninterrupted availability of electric power at an affordable price that supports the development of industry and economy. The shift towards low-carbon energy sources in the portfolio of power supply is a new development trend of electric power systems in order to improve environmental efficiency. However, the higher cost of renewable energy impacts the cost structure of the electric power industry, which can affect electricity rates and further cause the industry to enter energy transition traps. The focus of a government’s energy policy is how to achieve a balance between regulated electricity rates and adopting low-carbon energy sources. The energy transition for the electric power industry is a complex and dynamic process influenced by factors such as government policies and international fuel prices. Hence, this research adopts the system dynamics methodology to explore the evolution of Taiwan’s electric power industry during its energy transition, analyzes the system structure, and discusses the implications of policy and management regarding renewable energy sources.

以文找文

References:
[1] Andersen, D.F., Richardson, G.P., 1997a, “Scripts for group model building.” System Dynamics Review, Vol. 13, No.2, pp. 107-129.
[2] Andersen, D.F., Vennix, J.A.M., Richardson, G.P., 1997b, “Group model building: adding more science to the craft.” System Dynamic Review, Vol. 13, No.2, pp. 187-201.
[3] Arango, S., 2007, “Simulation of alternative regulations in the Colombian electricity market.” Socio-Economic Planning Sciences, Vol. 41, pp. 305-319.
[4] Alishahi, E., Moghaddam, M.P., Sheikh-El-Eslami, M.K., 2012, “A system dynamics approach for investigating impacts of incentive mechanisms on wind power investment.” Renewable Energy, Vol. 37, pp. 310-317.
[5] Ahmad, S., Tahar, R.M., Muhammad-Sukki, F., Munir, A.B., Rahim, R.A., 2016, “Application of system dynamics approach in electricity sector modelling: a review.” Renewable and Sustainable Energy Reviews, Vol. 56, pp. 29-37.
[6] Barlas, Y., Carpenter, S., 1990, “Philosophical roots of model validation: two paradigms.” System Dynamics Review, Vol. 6, No. 2, pp. 148-166.
[7] Barlas, Y., 1996, “Formal aspects of model validity and validation in system dynamics.” System Dynamics Review: The Journal of the System Dynamics Society, Vol. 12, No. 3, pp. 183-210.
[8] Coyle, R.G., 1972, “Decision Analysis.” Nelson, London.
[9] Coyle, R.G., 1996, “System Dynamics Modeling-A Practical Approach.” Chapman & Hall, New York.
[10] Coyle, R.G., 1998, “The practice of system dynamics: milestones, lessons and ideas from 30 years experience.” System Dynamics Review: The Journal of the System Dynamics Society, Vol. 14, No. 4, pp. 343-365.
[11] Chen, F.F., Chou, S.C., Lu, T.K., 2013, “Scenario analysis of the new energy policy for Taiwan’s electricity sector until 2025.” Energy Policy, Vol. 61, pp. 162-171.
[12] Cepeda, M., Finon, D., 2013, “How to correct for long-term externalities of large-scale wind power development by a capacity mechanism?.” Energy Policy, Vol. 61, pp. 671-685.
[13] Cepeda, M., Saguan, M., 2016, “Assessing long-term effects of demand response policies in wholesale electricity markets.” Electrical Power and Energy Systems Vol. 74, pp. 142-152.
[14] Chen, G.Q., Wu, X.F., 2017, “Energy overview for globalized world economy: Source, supply chain and sink.” Renewable and Sustainable Energy Reviews, Vol. 69, pp. 735-749.
[15] Cherp, A., Vinichenko, V., Jewell, J., Suzuki, M., Antal, M., 2017, “Comparing electricity transitions: A historical analysis of nuclear, wind and solar power in Germany and Japan.” Energy Policy, Vol. 101, pp. 612-628.
[16] Chen, P.H., Tsay, I.S., 2017, “Transmission network price setting model for the promotion of liberalized market for the power industry in Taiwan.” Energy Policy, Vol. 104, pp. 100-111.
[17] Doyle, J.K., Ford, D.N., 1988, “Mental Models Concepts for System Dynamics Research.” System Dynamics Review, Vol. 14, No. 1, pp. 3-29.
[18] Dudhani, S., Sinha, A.K., Inamdar, S.S., 2006, “Renewable energy sources for peak load demand management in India.” International Journal of Electrical Power & Energy Systems, Vol. 28, No. 6, pp. 396-400.
[19] D’Agostino, A.L., Sovacool, B.K., Trott, K., Ramos, C.R., Saleem, S., Ong, Y., 2011, “What’s the state of energy studies research?: A content analysis of three leading journals from 1999 to 2008.” Energy, Vol. 36, No. 1, pp. 508-519.
[20] Davies, L.L., 2011, “Beyond Fukushima: Disasters, Nuclear Energy, and Energy Law.” Brigham Young University Law Review, Vol. 6, pp. 1937-1989.
[21] Forrester, J.W., 1961, “Industrial Dynamics.” The MIT Press, Cambridge, MA (Wright-Allen Series in SD).
[22] Forrester, J.W., 1969, “Urban Dynamics.” New York: MIT Press.
[23] Forrester, J.W., 1971, “World Dynamics.” Wright-Allen Press, Inc.
[24] Forrester, J.W., 1980, “Information Sources for Modeling the National Economy.” Journal of the American Statistical Association, Vol. 75, pp. 555-556.
[25] Forrester, J.W., Senge, P.M., 1980, “Tests for Building Confidence in System Dynamics Models.” TIMS Studies in the Management Sciences, Vol. 14, pp. 209-228.
[26] Ford, A., 1997, “System Dynamics and the Electric Power Industry.” System Dynamic Review, Vol. 13, No. 1, pp. 57-85.
[27] Ford, A., 1999, “Cycles in competitive electricity markets: a simulation study of the western United States.” Energy Policy, Vol. 27, pp. 637-658.
[28] Fouquet, R., 2010, “The slow search for solutions: Lessons from historical energy transitions by sector and service.” Energy Policy, Vol. 38, No. 11, pp. 6586-6596.
[29] Gary, S., Larsen, E.R., 2000, “Improving firm performance in out-of-equilibrium, deregulated markets using feedback simulation models.” Energy Policy, Vol. 28, pp. 845-855.
[30] Guler, B., Çelebi, E., Nathwani, J., 2018, “A ‘Regional Energy Hub’ for achieving a low-carbon energy transition.” Energy Policy, Vol. 113, pp. 376-385.
[31] Gao, A.M.Z., Fan, C.T., Liao, C.N., 2018, “Application of German energy transition in Taiwan: A critical review of unique electricity liberalisation as a core strategy to achieve renewable energy growth.” Energy Policy, Vol. 120, pp. 644-654.
[32] Hermann, C.F., 1967, “Validation problems in games and simulations with special reference to models of international politics.” Behavioral Science, Vol. 12, No. 3, pp. 216-231.
[33] Hsieh, C.H., 1980, “System Dynamics-Theory, Method and Application.” Sinotech Engineering Consultants, LTD. (In Chinese).
[34] Hamilton, J.D., 1996, “This is what happened to the oil price-macroeconomy relationship.” Journal of Monetary Economics, Vol. 38, No. 2, pp. 215-220.
[35] Heltberg, R., 2004, “Fuel switching: evidence from eight developing countries.” Energy economics, Vol. 26, No. 5, pp. 869-887.
[36] Hu, J.L., Wang, S.C., 2006, “Total-factor energy efficiency of regions in China.” Energy Policy, Vol. 34, No. 11, pp. 3206-3217.
[37] Herter, K., Wayland, S., 2010, “Residential response to critical-peak pricing of electricity: California evidence.” Energy, Vol. 35, No. 4, pp. 1561-1567.
[38] Hsiao, C.T., Dai, Y.X., Liu, S.F., 2010. Decision Analysis and Simulation: Approaches to Organization and Enterprise Development. Dong Hua Books, Taipei. (In Chinese)
[39] Hsiao, C.T., 2014, “Industrial Development Research by Systems Approach in NICs: The case in Taiwan.” Systems Research and Behavioral Science, Vol. 31, pp. 258-267.
[40] Hsiao, C.T., Liu, C.S., Chang, D.S., Chen, C.C., 2018, “Dynamic modeling of the policy effect and development of electric power systems: A case in Taiwan.” Energy Policy, Vol. 122, pp. 377-387.
[41] IEA, NEA, 2015, “Projected Costs of Generating Electricity 2015 edition.”
[42] Joas, F., Pahle, M., Flachsland, C., Joas, A., 2016, “Which goals are driving the Energiewende? Making sense of the German Energy Transformation.” Energy Policy, Vol. 95, 42-51.
[43] Kern, F., Smith, A., 2008, “Restructuring energy systems for sustainability? Energy transition policy in the Netherlands.” Energy Policy, Vol. 36, pp. 4093-4103.
[44] Kilanc, G.P., Or, I., 2008, “A decision support tool for the analysis of pricing, investment and regulatory processes in a decentralized electricity market.” Energy Policy, Vol. 36, pp. 3036-3044.
[45] Kim, Y., Kim, M., Kim, W., 2013, “Effect of the Fukushima nuclear disaster on global public acceptance of nuclear energy.” Energy Policy, Vol. 61, pp. 822-828.
[46] Karakaya, E., Hidalgo, A., Nuur, C., 2015, “Motivators for adoption of photovoltaic systems at grid parity: a case study from Southern Germany.” Renewable and Sustainable Energy Reviews, Vol. 43, pp. 1090-1098.
[47] Kitamura, T., Managi, S., 2017, “Energy security and potential supply disruption: A case study in Japan.” Energy Policy, Vol. 110, pp. 90-104.
[48] Leach, G., 1992, “The energy transition.” Energy policy, Vol. 20, No. 2, pp. 116-123.
[49] Lee, C.C., Chang, C.P., 2005, “Structural breaks, energy consumption, and economic growth revisited: Evidence from Taiwan.” Energy Economics, Vol. 27, No. 6, pp. 857-872.
[50] Liu, C.S., Hsiao, C.T., Chang, D.S., Hsiao, C.H., 2016, “How the European Union’s and the United States’ anti-dumping duties affect Taiwan’s PV industry: A policy simulation.” Renewable and Sustainable Energy Reviews, Vol. 53, pp. 296-305.
[51] Law & Regulations Database of the Republic of China, 2019. Electricity Act (Accessed 21 January 2020).
[52] Meadows, D.H., Randers, J., Meadows, D., 1972, “Limits to Growth.” New American Library, New York.
[53] Ming, Z., Yingxin, L., Shaojie, O., Hui, S., Chunxue, L., 2016, “Nuclear energy in the Post-Fukushima Era: Research on the developments of the Chinese and worldwide nuclear power industries.” Renewable and Sustainable Energy Reviews, Vol. 58, pp. 147-156.
[54] Marquardt, J., Steinbacher K., Schreurs, M., 2016, “Driving force or forced transition?: The role of development cooperation in promoting energy transitions in the Philippines and Morocco.” Journal of Cleaner Production, Vol. 128, pp. 22-33.
[55] Mahmoudabadi, M.Z., Azar, A., Emrouznejad, A., 2018, “A novel multilevel network slacks-based measure with an application in electric utility companies.” Energy, Vol. 158, pp. 1120-1129.
[56] Naill, R.F., 1973, “The discovery life cycle of a finite resource: a case study of U.S. natural gas.” In: Meadows, D.L. (Ed.), Toward Global Equilibrium: Collected Papers. MIT Press, Cambridge (MA).
[57] Naill, R.F., Belanger, S.D., 1989, “A System Dynamics Model for National Energy Policy Planning.” In: Milling P.M., Zahn E.O.K. (eds) Computer-Based Management of Complex Systems. Springer, Berlin, Heidelberg.
[58] Naill, R.F., 1992, “A system dynamics model for national energy policy and planning.” System Dynamics Review, Vol. 8, No. 1, pp. 735-749.
[59] Olsina, F., Garcés, F., Haubrich, H.J., 2006, “Modeling long-term dynamics of electricity markets.” Energy Policy, Vol. 34, pp. 1411-1433.
[60] Ochoa, C., van Ackere, A., 2015, “Does size matter-Simulating electricity market coupling between Colombia and Ecuador.” Renewable and Sustainable Energy Reviews, Vol. 50, pp. 1108-1124.
[61] Oreskes, N., 2018, “The Scientific Consensus on Climate Change: How Do We Know We’re Not Wrong?.” Climate Modelling, Palgrave Macmillan, Cham, pp. 31-64.
[62] Pachauri, S., Jiang, L., 2008, “The household energy transition in India and China.” Energy policy, Vol. 36, No. 11, pp. 4022-4035.
[63] Pereira, A.J.C., Saraiva, J.T., 2011, “Generation expansion planning (GEP) – A long-term approach using system dynamics and genetic algorithms (GAs).” Energy, Vol. 36, pp. 5180-5199.
[64] Qudrat-Ullah, H., 2014, “Green power in Ontario: A dynamic model-based analysis.” Energy, pp. 859-870.
[65] Richardson, G.P., 1996, “Problems for the future of system dynamics.” System Dynamic Review, Vol. 12, pp. 141-157.
[66] Renn, O., Marshall, J.P., 2016, “Coal, nuclear and renewable energy policies in Germany: From the 1950s to the ‘Energiewende’.” Energy Policy, Vol. 99, pp. 224-232.
[67] Sterman, J.D., 1988, “Modeling the formation of expectations-the history of energy demand forecasts.” Int. J. Forecast. Vol. 4, No. 2, pp. 243-259.
[68] Senge, P.M., 1990, “The Fifth Discipline-The Art and Practice of the Learning Organization.” Doubleday, NY, USA.
[69] Sterman, J.D., 2000, “Business Dynamics: Systems Thinking and Modelling for a Complex World.” Irwin/McGraw-Hill, Boston.
[70] Strupczewski, A., 2003, “Accident Risks in Nuclear-Power Plants.” Applied Energy, Vol. 75, pp. 79-86.
[71] Sokona, Y., Mulugetta, Y., Gujba, H., 2012, “Widening energy access in Africa: Towards energy transition.” Energy Policy, Vol. 47, pp. 3-10.
[72] Tone, K., Tsutsui, M., 2009, “Network DEA: A slacks-based measure approach.” European Journal of Operational Research, Vol. 197, No. 1, pp. 243-252.
[73] Tu, Y.M., Chang, L.C., 2010, “System Dynamics: Theory and Application.” Best-Wise Publishing, Taipei. (In Chinese).
[74] Taipower, 2007, “Taiwan Power Company Sustainability Report 2007.” Taiwan Power Company (In Chinese).
[75] Taipower, 2008, “Taiwan Power Company Sustainability Report 2008.” Taiwan Power Company (In Chinese).
[76] Taipower, 2013, “Taiwan Power Company Sustainability Report 2013.” Taiwan Power Company (In Chinese).
[77] Taipower, 2014, “Long-Term Power Development Plan – Scheme 10302.” Taiwan Power Company (In Chinese).
[78] Taipower, 2016, “Long-Term Power Development Plan – Scheme 10505.” Taiwan Power Company (In Chinese).
[79] Taipower, 2017, “Long-Term Power Development Plan – Scheme 10605.” Taiwan Power Company (In Chinese).
[80] Tsai, C.H., Tsai, Y.L., 2018, “Competitive retail electricity market under continuous price regulation.” Energy Policy, Vol. 114, pp. 274-287.
[81] Visschers, V.H.M., Siegrist, M., 2013, “How a Nuclear Power Plant Accident Influences Acceptance of Nuclear Power: Results of a Longitudinal Study Before and After the Fukushima Disaster.” Risk Analysis, Vol. 33, No. 2, pp. 333-347.
[82] Wolstenholme, E.F., 1990, “System Enquiry: A System Dynamics Approach.” John Wiley & Sons Ltd, Chichester.
[83] Weaver, P., Jansen, L., Van Grootveld, G., Van Spiegel, E., Vergragt, P., 2000, “Sustainable Technology Development.” Greenleaf Publishing, Sheffield.
[84] Wang, H.F., Sung, M.P., Hsu, H.W., 2016, “Complementarity and substitution of renewable energy in target year energy supply-mix planning-in the case of Taiwan.” Energy Policy, Vol. 90, pp. 172-182.
[85] Weber, G., Cabras, I., 2017, “The transition of Germany’s energy production, green economy, low-carbon economy, socio-environmental conflicts, and equitable society.” Journal of Cleaner Production, Vol. 167, No. 20, pp. 1222-1231.
[86] Yang, C.C., Chang, L.C., Yeh, S.C., Chen, C.S., Yeh, C.H., 2007, “Thinking and Application of System Dynamics.” Wu-Nan Books, Taipei. (In Chinese).
[87] Yu, L., Li, Y.P., Huang, G.H., 2016, “A fuzzy-stochastic simulation-optimization model for planning electric power systems with considering peak-electricity demand: A case study of Qingdao, China.” Energy, Vol 98, pp. 190-203.

推文
推薦
引用網址
引用嵌入語法
轉寄

top

:::

相關期刊
相關論文
相關專書
相關著作
熱門點閱

1.	聚焦能源轉型建構我國淨零永續之未來
2.	我國能源政策實施政策環評之成效分析：以離岸風電區塊開發政策之政策環評為例
3.	世界主要國家能源轉型政策推動做法與借鏡

無相關博士論文

無相關書籍

無相關著作

無相關點閱

QR Code

臺灣人文及社會科學引文索引資料庫系統

詳目顯示

臺灣人文及社會科學引文索引資料庫