以再生能源增進遊樂園的價值

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潘氏蘭香(Phan Thi Lan Huong) 查詢紙本館藏

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工業管理研究所

論文名稱

以再生能源增進遊樂園的價值
(Enhancing the Value of Amusement Parks with Renewable Energy)

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摘要(中)

全球暖化作為氣候變遷的一種表現，正在加速發生，因此人類需要採取緊急行動來限制氣溫的上升。而減少溫室氣體的排放便是受到關注的首要目標之一。其也正成為世界各國在社會與經濟發展上的里程碑。在經濟發展中，生產與商業活動所產生的排放應該在所有產業中被辨認出並使其最小化，旅遊產業亦不例外，其中的代表便是遊樂園。遊樂園是一種源於1950年的旅遊景點，其提供一些現代刺激的遊樂設施、集市、節慶和令人眼花繚亂的裝飾。由於遊客人數和電力消耗，在近期遊樂園比起其他旅遊類別（例如博物館、綠色公園和動物園）會產生更高的排放量。因此，本論文期望透過在遊樂設施上整合太陽能系統，使用可再生能源（RE）供電，以解決遊樂園內的電力消耗問題，並由此解決世上許多遊樂園使用化石燃料為遊樂設施提供動力因而顯著增加碳排放的問題。本文提出了一個線性規劃（LP）模型，用以評估最具成本效益的再生能源系統，同時解決特定的限制，例如面積、電池儲能系（BESS）和太陽能的不連續性，以達到經濟與環境的平衡。本研究亦考慮了不同溫室氣體的成本，以瞭解其對於總成本和太陽能系統規模調整趨勢的影響。模型結果展示了太陽能在遊樂園中能如何降低碳排放，在單個遊樂設施上，利用太陽能滿足約45%的電力消耗可以防止75噸的二氧化碳當量釋放到環境中。這可謂在遊樂園中利用太陽能系統優勢的第一步。在未來的研究中可以於系統中加入考慮一些許多國家皆專注實施的其他特徵，例如教育、可再生能源回購電價和排放交易體系。

摘要(英)

As a manifestation of climate change, global warming is accelerating rapidly, which calls for humans to take urgent action to limit temperature rises. Reducing greenhouse gases (GHG) emissions is one of the first targets which is receiving attention. It is becoming a milestone for social and economic development in nations worldwide. In economic development, emissions from production and business activities need to be recognized and minimized in all sectors. The tourism industry is not an exception, in which the amusement park is a representation. An amusement park is a tourist attraction that began in 1950 and offered some modern thrill rides, additional fairs, festivals, and dazzling decorations. Amusement parks recently emit more emissions than other tourism categories (e.g., museums, green parks, and zoos) due to visitor arrivals and electricity consumption. The purpose of this dissertation is to address electrical consumption within an amusement park by integrating a solar energy system on a ride for the use of renewable energy (RE) sources to supply electricity. The goal is to solve the problem of fossil fuel electricity being used to power rides in many of the world′s amusement parks, contributing significantly to carbon emissions. A Linear Programming (LP) model is developed to evaluate the best RE system cost-efficient while addressing certain constraints such as area, battery energy storage sys-tem (BESS), and discontinuity of solar energy toward the balance of economy and environment. Different (GHG) costs are considered to see the impact on total costs and the trend of sizing solar systems. Results from the model indicated how solar power could reduce CO2 emissions in an amusement park. On a single ride, implementing approximately 45% solar power for consumption would prevent the release of 75 tCO2eq into the environment. This represents the first step towards taking advantage of the benefits of a solar system at an amusement park. The future work can take into account other features of the integrated solar system for amusement parks, such as education, Feed-In Tariffs, and Emissions Trading Systems, which many nations are focused on implementing.

關鍵字(中)

★ 永續遊樂園
★ 再生能源
★ 溫室氣體
★ 數學規劃
★ 全球化暖

關鍵字(英)

★ Sustainable amusement parks, renewable energy, GHG, mathematical programming, global warming

論文目次

Table of Contents
摘要 I
ABSTRACT II
TABLE OF CONTENTS IV
LIST OF FIGURES V
LIST OF TABLES VI
LIST OF ABBREVIATIONS VII
CHAPTER 1. RESEARCH PROBLEM 1
1.1 AMUSEMENT PARKS 1
1.2 CLIMATE CHANGE AND SUSTAINABLE DEVELOPMENT 3
1.3 RESEARCH MOTIVATIONS 8
1.4 RESEARCH PROBLEM 9
CHAPTER 2. LITERATURE REVIEW 12
2.1 AMUSEMENT PARKS′ SUSTAINABLE DEVELOPMENT 12
2.2 RE IN AMUSEMENT PARKS 17
2.3 REAL WORLD′S EXAMPLES 21
CHAPTER 3. RESEARCH METHODOLOGY 26
3.1 PROBLEM ANALYSIS 26
3.2 OPTIMIZATION MODEL 27
CHAPTER 4. COMPUTER EXPERIMENTS 32
4.1 CASE DESIGN 32
4.2 RESULTS 34
CHAPTER 5. CONCLUSIONS 41
REFERENCES 43
APPENDIX 51

參考文獻

[1] Aniah EJ, E Eja, JE Otu, & M Ushie (2009). Resort potentials as a strategy for sustainable tourism development in Plateau State, Nigeria. Journal of sustainable Development, 2(2): 73-79.
[2] Baer J & JC Kaufman (2005). Bridging generality and specificity: The amusement park theoretical (APT) model of creativity. Roeper Review, 27(3): 158-163.
[3] BBC (2021). The making of a wonder. http://www.bbc.com/storyworks/travel/garden-of-wonders/gardens-by-the-bay, accessed 13 September 2021.
[4] Beer M, R Rybár, & M Kaľavský (2017). Renewable energy sources as an attractive element of industrial tourism. Current Issues in Tourism, 21: 1-13.
[5] BESTON (2021). Ferris Wheel for Sale. https://bestoncarnivalrides.com/ferris-wheel-for-sale/, accessed 30 November 2021.
[6] Bloomberg (2021). USDTWD:CUR. https://www.bloomberg.com/quote/USDTWD:CUR, accessed 01 December 2021.
[7] Bordin C, HO Anuta, A Crossland, IL Gutierrez, CJ Dent, & D Vigo (2017). A linear programming approach for battery degradation analysis and optimization in offgrid power systems with solar energy integration. Renewable Energy, 101: 417-430.
[8] Bourbon R, SU Ngueveu, X Roboam, B Sareni, C Turpin, & D Hernandez-Torres (2019). Energy management optimization of a smart wind power plant comparing heuristic and linear programming methods. Mathematics and Computers in Simulation, 158: 418-431.
[9] Brent AC (2021). Renewable Energy for Sustainable Development. Sustainability, 13(12): 6920.
[10] Carvalho FM, MAB Galhardo, HC Aguilar, GM Farias, & JT Pinho (2014). Use of Alternative Energy Generation in Playgrounds as a Means of Knowledge Spreading. Energy Procedia, 57: 1024-1033.
[11] Chen D, Y Zhong, Y Liao, & L Li (2013). Review of Multiple Criteria and Multiple Constraint-level Linear Programming. Procedia Computer Science, 17: 158-165.
[12] Chouhan HA, D Parthasarathy, & S Pattanaik (2017). Urban development, environmental vulnerability and CRZ violations in India: impacts on fishing communities and sustainability implications in Mumbai coast. Environment, Development and Sustainability, 19(3): 971-985.
[13] Cosic A, M Stadler, M Mansoor, & M Zellinger (2021). Mixed-integer linear programming based optimization strategies for renewable energy communities. Energy, 237: 121559.
[14] Easdown M (2012). Amusement park rides. Oxford: Shire Publications
[15] Emre Caglar A (2020). The importance of renewable energy consumption and FDI inflows in reducing environmental degradation: Bootstrap ARDL bound test in selected 9 countries. Journal of Cleaner Production, 264: 121663.
[16] EPA (2020). Carbon pricing options for Taiwan. London: Grantham Research Institute on Climate Change and the Environment, London School of Economics and Political Science, and Vivid Economics.
[17] Escobar C (1990). Amusement park physics. The Physics Teacher, 28(7): 446-453.
[18] Feigenbaum EA & J-y Hou (2020). Overcoming Taiwan’s Energy Trilemma. Washington, DC: Carnegie Endowment for International Peace.
[19] Ferguson H (2014). Singapore’s Supertrees. INGENIA, 58.
[20] Finnegan S, S Sharples, T Johnston, & M Fulton (2018). The carbon impact of a UK safari park – Application of the GHG protocol using measured energy data. Energy, 153: 256-264.
[21] Formica S & MD Olsen (1998). Trends in the amusement park industry. International Journal of Contemporary Hospitality Management, 10(7): 297-308.
[22] Gao X, L Xia, L Lu, & Y Li (2019). Analysis of Hong Kong’s Wind Energy: Power Potential, Development Constraints, and Experiences from Other Countries for Local Wind Energy Promotion Strategies. Sustainability, 11(3): 924.
[23] Gromadzki J (2020). Overview of Battery Energy Storage System (BESS) commercial and utility product landscape, applications, and installation and safety best practice. https://r6.ieee.org/sf-ias/wp-content/uploads/sites/67/J-Gromadzki-Tesla-On-site-Energy-Storage-Systems.pdf, accessed 15 December 2021.
[24] Holcomb J, F Okumus, & A Bilgihan (2010). Corporate social responsibility: what are the top three Orlando theme parks reporting? Worldwide Hospitality and Tourism Themes, 2(3): 316-337.
[25] Hu AH, LH Huang, S Lou, C-H Kuo, C-Y Huang, K-J Chian, H-T Chien, & H-F Hong (2017). Assessment of the Carbon Footprint, Social Benefit of Carbon Reduction, and Energy Payback Time of a High-Concentration Photovoltaic System. Sustainability, 9(1).
[26] IEA (2019). Global Energy & CO2 Status Report 2019. IEA: Paris.
[27] IEA (2021a). Global Energy Review 2021. IEA: Paris.
[28] IEA (2021b). Net Zero by 2050 - A Roadmap for the Global Energy Sector. IEA: Paris.
[29] IPCC (2021a). Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. IPCC: Gevena.
[30] IPCC (2021b). Climate change widespread, rapid, and intensifying – IPCC. https://www.ipcc.ch/2021/08/09/ar6-wg1-20210809-pr/, accessed 18 August 2021.
[31] IRENA (2018). Enhancing Sustainable Bioenergy Supply. https://unece.org/fileadmin/DAM/energy/se/pp/eneff/9th__Forum_Kiev_Nov.18/13_Novembe_2018/Bioenergy/04_Luis_Janeiro.pdf, accessed 18 August 2021.
[32] IRENA (2021). Renewable capacity statistics 2021. IRENA: Abu Dhabi.
[33] Jain AK, S Chouhan, RK Mishra, PRS Choudhry, H Saxena, & R Bhardwaj (2021). Application of linear programming in small mechanical based industry for profit maximization. Materials Today: Proceedings, 47: 6701-6703.
[34] James AT (2021). Service quality benchmarking of amusement parks using a hybrid approach. International Journal of Quality & Reliability Management.
[35] Jarman-Walsh J (2017). Examination of a Sustainable Tourism Destination: A Case Study of Huis Ten Bosch in Nagasaki, Japan. Journal of Yasuda Women′s University, 45: 189-198.
[36] Jian-Bin H, W Shao-Wu, L Yong, Z Zong-Ci, & W Xin-Yu (2012). Debates on the Causes of Global Warming. Advances in Climate Change Research, 3(1): 38-44.
[37] JINBO (2021). 88m Giant Ferris Wheel for Sale Jinbo. https://www.jinboride.com/product/ferris-wheel/88m-giant-ferris-wheel.html, accessed 30 November 2021.
[38] Kang J, TS Ng, & B Su (2020). Optimizing electricity mix for CO2 emissions reduction: A robust input-output linear programming model. European Journal of Operational Research, 287(1): 280-292.
[39] Kernel P (2005). Creating and implementing a model for sustainable development in tourism enterprises. Journal of Cleaner Production, 13(2): 151-164.
[40] King MJ (1981). Introduction: The New American Muse: Notes on the Amusement/Theme Park. Journal of Popular Culture, 15(1): 56.
[41] Lin C (2020). UK institute issues report on Taiwan’s carbon tax options. https://www.taipeitimes.com/News/taiwan/archives/2020/12/20/2003749060, accessed 15 December 2021.
[42] McClung GW (1991). Theme park selection: Factors influencing attendance. Tourism Management, 12(2): 132-140.
[43] Milman A & D Dickson (2014). Employment characteristics and retention predictors among hourly employees in large US theme parks and attractions. International Journal of Contemporary Hospitality Management, 26(3): 447-469.
[44] Miyatake Y (1996). Technology development and sustainable construction. Journal of Management in Engineering, 12(4): 23-27.
[45] Moussa RR (2018). The role of energy-scape elements in creating sustainable economic project in Egyptian parks. Ain Shams Engineering Journal, 9(4): 3045-3053.
[46] NASA (2021). What’s the difference between climate change and global warming? https://climate.nasa.gov/faq/12/whats-the-difference-between-climate-change-and-global-warming/ accessed 12 August 2021.
[47] Nye RB (1981). Eight ways of looking at an amusement park. The Journal of Popular Culture, 15(1): 63-75.
[48] Panasonic (2021). Panasonic VBHN330SJ53. https://www.europe-solarstore.com/download/panasonic/Panasonic-VBHN325-330SJ53-datasheet.pdf, accessed 24 November 2021.
[49] Rodriguez C, D Esenarro, C Alburquerque, M Vega, & V Ramirez (2020). Theme park of renewable energies for mitigation of CO2 in the urban area of the district of Chorrillos, Peru. IOP Conference Series: Materials Science and Engineering, 910: 012021.
[50] Saeed A, J iqbal, Snh jafri, Sm ali, U Ahmed, MU Anwar, & M Fatima (2018a). Steps toward sustainability: Energy through flywheels. Paper presented at the 2018 7th International Conference on Renewable Energy Research and Applications (ICRERA).
[51] Saeed A, M Shan, S Bakhtawar, & H Tariq (2018b). Merry-go-round as a Self-Energy Sustainable Ride. Paper presented at the 2018 9th International Renewable Energy Congress (IREC).
[52] Samuelson D & W Yegoiants (2001). The American amusement park. St. Paul: Motorbooks International.
[53] Shakur OO, JS Abiola, & B Olorunniyi (2017). Sustainable tourism development through modern information systems (case study: trans amusement park). Library Philosophy & Practice, 1514.
[54] Six_Flags (2021). Environmental management.
https://investors.sixflags.com/esg-highlights, accessed 06 September 2021.
[55] Smyth J (2016). Patented wind power technology revolutionises the renewable energy sector. Renewable Energy Focus, 17(6): 231-233.
[56] Statista.com (2021). Attendance at amusement and theme parks worldwide by facility in 2019. https://www.statista.com/statistics/194247/worldwide-attendance-at-theme-and-amusement-parks/, accessed 28 July 2021.
[57] Sustainability_Matters (2017). Solar power comes to adventure playground. https://www.sustainabilitymatters.net.au/content/energy/news/solar-power-comes-to-adventure-playground-468363140, accessed 18 July 2021.
[58] Sustainable_Travel_Development (2021). Carbon Footprint of Tourism. https://sustainabletravel.org/issues/carbon-footprint-tourism/, accessed 25 August 2021.
[59] Taipower (2021). Taiwan Power Company Rate Schedules. https://www.taipower.com.tw/upload/317/2021101315462457305.pdf, accessed 25 November 2021.
[60] Tho SW, KW Chan, & YY Yeung (2015). Technology-Enhanced Physics Programme for Community-Based Science Learning: Innovative Design and Programme Evaluation in a Theme Park. Journal of Science Education and Technology, 24(5): 580-594.
[61] UN (2021). 17 Goals to Transform Our World. https://www.un.org/sustainabledevelopment/, accessed 17 August 2021.
[62] URE (2021). GLORY BIFI D6L_L3A / 60 cells 295W - 310 W Mono-Crystalline PV Module. Taipei: United Renewable Energy.
[63] Vo DH, AT Vo, CM Ho, & HM Nguyen (2020). The role of renewable energy, alternative and nuclear energy in mitigating carbon emissions in the CPTPP countries. Renewable Energy, 161: 278-292.
[64] Vogel HL (2021). Travel Industry Economics: A Guide for Financial Analysis. Cham: Springer International Publishing.
[65] Walt_Disney (2021a). Disneyland Paris Embarks on One of the Largest Solar Canopy Energy Projects in Europe. https://thewaltdisneycompany.com/disneyland-paris-embarks-on-one-of-the-largest-solar-canopy-energy-projects-in-europe/, accessed 06 September 2021.
[66] Walt_Disney (2021b). Powering the Magic with Renewable Energy. https://thewaltdisneycompany.com/powering-the-magic-with-renewable-energy/, accessed 06 September 2021.
[67] Walt_Disney (2021c). The Walt Disney Company Sets 2030 Environmental Goals. https://thewaltdisneycompany.com/the-walt-disney-company-sets-2030-environmental-goals-2/, accessed 06 September 2021.
[68] Wang J, J Kim, & S Kang (2019). Antecedents and Consequences of Brand Experiences in a Historical and Cultural Theme Park. Sustainability, 11(17): 4810.
[69] Wang JC, Y-C Wang, L Ko, & JH Wang (2017). Greenhouse gas emissions of amusement parks in Taiwan. Renewable and Sustainable Energy Reviews, 74: 581-589.
[70] Wikipedia (2021). Amusement park. https://en.wikipedia.org/w/index.php?title=Amusement_park&oldid=1032489380, accessed 22 July 2021.
[71] WION (2021). UN′s landmark climate report delivers starkest warning on climate change. https://www.youtube.com/watch?v=DzIkjaHVPeU, accessed 10 August 2021.
[72] Wright DWM (2018). Terror park: A future theme park in 2100. Futures, 96: 1-22.
[73] Wu J, Q Zhu, Q An, J Chu, & X Ji (2016). Resource allocation based on context-dependent data envelopment analysis and a multi-objective linear programming approach. Computers & Industrial Engineering, 101: 81-90.
[74] Yamaguchi S (2009). A Model of Amusement Park in the Near Future Operated by Fuel Cell and Solar Cell. Journal of Asian Electric Vehicles, 7(2): 1261-1264.
[75] Zha J, J Dai, H Xu, C Zhao, T Tan, & Z Li (2021). Assessing efficiency and determinants of tourist attractions based on a two-subprocess perspective: A case of Chengdu, southwestern China. Journal of Destination Marketing & Management, 19: 100542.
[76] Zhang L, W Gao, Y Yang, & F Qian (2020). Impacts of Investment Cost, Energy Prices and Carbon Tax on Promoting the Combined Cooling, Heating and Power (CCHP) System of an Amusement Park Resort in Shanghai. Energies, 13(16): 4252.

指導教授

王啟泰(Chi-Tai Wang)

審核日期

2022-1-20

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