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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 陳希立 | |
dc.contributor.author | Chao-Chi Shih | en |
dc.contributor.author | 石肇圻 | zh_TW |
dc.date.accessioned | 2021-06-16T17:17:17Z | - |
dc.date.available | 2015-08-28 | |
dc.date.copyright | 2012-08-28 | |
dc.date.issued | 2012 | |
dc.date.submitted | 2012-08-17 | |
dc.identifier.citation | 1.J.W. Mitchell, G.E. Myers, “An analytical model of the
counter urrent heat exchange phenomena”, Biophysics Journal, 8(1968), 897–911. 2.Mitchell and Myers, Mitchell, J.W., Myers G.E.” An analytical model of the countercurrent heat exchange phenomena”, Biophysics Journal ,8(1968), 897–911. 3.范軍,刁乃仁,方肇洪,”豎直鑽孔熱交換器兩支管間熱量回流的分析”, 山東建 築工程學院學報, 2009, 19(1),pp.1-4 4.沈國民,張虹,”豎直U型埋管地熱熱交換器熱短路現象的影響參數分析”,太陽 能學報, 2007,28(6),pp.604-607 5.劉冬生,孫有宏,莊迎春,”增強地源熱泵豎直鑽孔地下熱交換器換熱性能的研 究”,吉林大學學報, 200434(4),pp.648-652 6.Hikmet Esen, Mustafa Inalli, “In-situ thermal response test for ground source heat pump system in Elazig, Turkey,” Energy and Buildings, 41(2009), 395-401. 7.J. Raymond, R. Therrien, L. Gosselin, “Borehole temperature evolution during thermal response tests,” Geothermics, 40(2011), 69-78. 8.A.-M. Gustafsson, L. Westerlund, “Heat extraction thermal response test in groundwater-filled borehole heat exchanger - Investigation of the borehole thermal resistance,” Renewable Energy, 36(8)(2011), 2388-2394. 9.Y. Gu and D.L. O'neal, “An analytical solution to transient heat conduction in a composite region with a cylindrical heat source”, Asme J Solar Energy, 117(1995), 242–248. 10.Y. Gu and D.L. O’Neal, “Development of an equivalent diameter expression for vertical U-tubes used in ground- coupled heat pumps”, ASHRAE Transactions 104(1998), 347– 355. 11.S.P. Kavanaugh, Ground Source Heat Pump Design of Geothermal System for Commercial and Institutional Buildings, ASHRAE, Atlanta, Ca, 1997 12.Gu and O’Neal, 1998 Y. Gu and D.L. O’Neal, Development of an equivalent diameter expression for vertical U-tubes used in ground-coupled heat pumps, ASHRAE Transactions, 104(1998), 347–355. 13.Allan, 2000M.L. Allan,” Materials characterization of superplasticized cement–sand grout”, Cement and Concrete Research , 30(2000),937–942. 14.莊迎春,孫友宏,謝康和,”直埋閉式地源熱泵回填土性能研究”,太陽能學 報,2004,25(2)(2004),pp.216-220 15.Chulho Lee, Moonseo Park,The-Bao Nguyen, Byonghu Sohn, Jong Min Choi,Hangseik Choi “Performance evaluation of closed-loop vertical ground heat exchangers by conducting in-situ thermal response tests,” Renewable Energy, In Press, Corrected Proof. 16.Fabien Delaleuxa, Xavier Py, Regis Olives, Antoine Dominguez, “Enhancement of geothermal borehole heat exchangers performances by improvement of bentonite grouts conductivity,” Applied Thermal Engineering , 33- 34(2012), 92-99. 17.E Zanchini, S Lazzari,A. Priarone,“Effects of flow direction and thermal short-circuiting on the performance of small coaxial ground heat exchangers,” Renewable Energy, 35(2010), 1255-1265. 18.Xinguo Li, Yan Chen, Zhihao Chen, Jun Zhao “Thermal performances of different types of underground heat exchangers ,” Energy and Buildings, 38(2006), 543-547. 19.A.-M. Gustafsson, L. Westerlund, “Experimental study of several types of ground heat exchanger using a steel pile,” Renewable Energy, 36(2011), 764-771. 20.Jalaluddin , Akio Miyara, “Thermal performance investigation of several types of vertical ground heat exchangers with different operation mode,” Applied Thermal Engineering , 33-34(2012), 167-174. 21.Yasuhiro Hamada, Hisashi Saitoh, Makoto Nakamura, Hideki Kubota, Kiyoshi Ochifuji, “Field performance of an energy pile system for space heating,” Energy and Buildings, 39(2007), 517-524. 22.Xinguo Li, Zhihao Chen, Jun Zhao, “Simulation and experiment on the thermal performance of U-vertical ground coupled heat exchanger,” Applied Thermal Engineering , 26(2006), 1564-1571. 23.Ingersoll, L.R., et al. “ Theory of earth heat exchangers for the heat pump”, ASHRAE Transactions, 57(1951), 167- 188. 24.Deerman, J.D. and S.P. Kavanaugh, 1991. Simulation of vertical U-tube ground-coupled heat pump systems using cylindrical heat source solution. 25.柳曉雷,王德林,方肇洪,”垂直埋管地源熱泵的圓柱面熱傳模型及簡化計算,”山 東建築工程學院學報,2001,16(1),pp.47-51 26.刁乃仁,方肇洪著,鑽孔地源熱泵技術,高等教育出版社,北京,2006 27.Fang Z H, Xie D L, Diao N R, et al. ,”A new method for solving the inverse conduction problem in steady heat flux measurement”, Int J Heat and Mass Transfer, 40(16) (1997), 3947-3954. 28.刁乃仁,曾義和,方肇洪,”豎直U型管地熱熱交換器的准三維熱傳模型,”熱能動 力工程, 2003, 18(4), pp.387-390 29.Florides , G., Kalogious, S.,” Ground heat exchangers—a review of system, modes and applications”, Renewable energy , 32(2007), 2461-2478. 30.Hellstrom G, Ground heat source ,Thermal analysis of duct storage system [D] Doctor Thesis ,Department of mechanical physic ,University of Lund,Sweden,1991 31.Paul,N.D., The Effect of Ground Thermal Conductivity on Vertical Geothermal Heat Exchanger Design and Performance [D]. South Dakoda, U S: South Dakota State University, 1996 32.Gu, Y., Neal, D.L.,” Develop of an equivalent diameter expression for vertical u-tubes used in ground-coupled heat pump”, ASHRAE Transaction, 104(1989), 347-355. 33.Shonders, J.A.,Beck,J.V.,” Field test of a new method for determining soil formation thermal conductivity and borehole resistance”, ASHRAE Transaction, 106(1999), 843- 850. 34.Renumd, C.P.,” Borehole thermal resistance:Laboratory and field studies”, ASHRAE Transaction, 105(1999), 439-335. 35.Mostafa H. Sharqawy,Esmail M.Hassan M. Badr,”Effective pipe-to-borehole thermal resistance for vertical ground heat exchangers,” Geothermics,38(2007), 271-277. 36.Liu Jun, Zhang Xu, Gao Jun, Yang Jie, “Evaluation of heat exchange rate of GHE in geothermal heat pump systems,” Renewable Energy, 34(2009), 2898-2904. 37.Nikolas Kyriakis, Apostolos Michopoulos, Konstanin Pattas, “On the maxium thermal load of ground heat exchangers,” Energy and Buildings, 38(2006), 25-29. 38.Ciyuan Du, Youming Chen,“An average fluid temperature to estimate borehole thermal resistance of ground heat exchanger,” Renewable Energy, 36(2011), 1880-1885. 39.Steven P. Rottmayer, “Simulation of Ground Coupled Vertical U-Tube Heat Exchangers”, University of Wisconsin-Madison, 1997. 40.胡平放,「地源熱泵地埋管換熱系統熱堆積分析」,華中科技大學學報,Vol. 25 No.1,2008。 41.Steven P. Rottmayer , Simulation of Ground Coupled Vertical U-Tube Heat Exchangers, University of Wisconsin- Madison, 1997 42.C.K. Lee.,“Computer simulation of borehole ground heat exchangers for geothermal hear pump systems”, Renewable Energy, 33(2008), 1286-1296. 43.P, M. Congedo, G.. Colangelo, G.. Starace, “CFD simulations of horizontal ground heat exchangers: A comparison among different configuration,” Applied Thermal Engineering , 33-34(2012), 24-32. 44.Yupeng Wu, Guohui Gan, Anne Verhoef, Pier Luigi Vidale, Raquel Garcia Gonzalez, “Experimental measurement and numerical simulation of horizontal-coupled slinky ground source heat exchanger,” Applied Thermal Engineering , 30(2010), 2574-2583. 45.Richard Lenhard, Milan Malcho, “Numerical simulation device for the transport of geothermal heat with forced circulation of media,” Mathematical and Compute Modeling , In Press, Corrected Proof. 46.Hakan Demir, Ahmet Koyun, Galip Temir, “Heat transfer of horizontal parallel pipe ground heat exchanger and experimental verification,” Applied Thermal Engineering , 29(2009), 224-233. 47.Qing Gao, Ming Li, Ming Yu, “Experimental and simulation of temperature characteristics of intermittently- controlled ground heat exchangers ,” Renewable Energy, 35(2010), 1169-1174. 48.Yan Shang, Sufen Li, Haijun Li, “Analysis of geo- temperature under intermittent operation of ground-source heat pump,” Energy and Buildings, 43(2011), 935-943. 49.Yujin Nam, Ryozo Ooka, Suckho Hwang, “Development of a numerical model to predict heat exchanger rates for a ground-source heat pump system,” Energy and Buildings, 40(2008), 2133-2140. 50.Mostafa H. Sharqawy,Esmail M.Hassan M. Badr,”Effective pipe-to-borehole thermal resistance for vertical ground heat exchangers,” Geothermics, 38(2007), 271-277. 51.Yujin Hwang, Jae-Keun Lee,Young-Man Jeong, Kyung-Min Koo, Dong-Hyuk Lee, In-Kyu Kim, Sim-Won Jin,“Cooling performance of a vertical ground-coupled heat pump system installed in a school building,” Renewable Energy, 34(2009), 578-582. 52.Wei Yang, Jin Zhou, Wei Xu, Guoqiang Zhang, “Current status of ground-source heat pumps in China,” Energy Policy, 38(2010), 323-332. 53.Jun Gao, Xu Zhang, Jun Liu, Kui Shan Li, Jie Yang, “Thermal performance and ground temperature of vertical pile-foundation heat exchangers: A case study,” Applied Thermal Engineering,28(2009), 2295-2304, . 54.Mustafa Inalli, Hikmet Esen, “Experimental thermal performance evaluation of a horizontal ground-source heat pump system,” Applied Thermal Engineering , 24(2004), 2219-2232. 55.Hikmet Esen, Mustafa Inalli, “Three-years operation experience of a ground source heat pump system in Northern Greece,” Energy and Buildings, 39(2007), 328-334. 56.吳琳,王宏光,「水冷電機冷卻系統設計與計算」,機械設計與製造,Vol. 8 No.8, 2008。 57.P. Verlinden, R.A. Sinton, R.M. Swanson, R.A. Crane, Single-wafer integrated 140 W silicon concentrator module, Conference record, 22nd IEEE PVSC, 1991 58.W.E. Horne, Solar energy system, patent US5269851, USA, 1993 59.Stefan Krauter, Rodrigo Guido Araujo, Sandra Schroer, Rolf Hanitsch, Mohammed J Salhi, Clemens Triebel, Reiner Lemoine “Combined photovoltaic and solar thermal system for facade integration and building insulation,” Solar energy, 67(1999),239-248. 60.Y.Tripanagnostopoulos, “Aspect and improvements of hybrid photovoltaic/thermal solar energy systems,” Solar energy, 81(2007),1117-1131 61.陶文銓,數值傳熱學, 西安交通大學, 1995. 62.S. V. Patankar and D. B. Spalding, “A Calculation Procedure for Heat, Mass and Momentum Transfer in Three- dimensional Parabolic Flows”, International Journal of Heat and Mass Transfer, 5(1872), 1787-1806 63.S. V. Patankar, “Numerical Heat Transfer and Fluid Flow”, Hemisphere Publishing Corporation, 1980. 64.Yunus A.Cengel, “Heat and mass transfer” , Mc Graw Hill Third Edition 2006 , P175 ~176 P463~P473 65.M. G. Craford, “LEDs for Solid State Lighting and Other Emerging Applications: Status, Trends, and Challenges,” Fifth International Conference on Solid State Lighting, San Diego, CA, USA, vol. 5941, pp. 1-10, August 1-4, 2005. 66.M. Arik, C. Becker, S. Weaver, and J. Petroski, “Thermal Management of LEDs: Package to System,” Third International Conference on Solid State Lighting, San Diego, CA, USA, vol. 5187, pp. 64-75, August 5-7, 2004. 67.M. Arik, J. Petroski, and S. Weaver, “Thermal Challenges in the Future Generation Solid State Lighting Applications: Light Emitting Diodes,” Proceedings of Intersociety Conference on Thermal Phenomena, San Diego, CA, USA, pp. 113-120, May 30-June 1, 2002. 68.D. R. Harper and W. B. Brown, “Mathematical Equations for Heat Conduction in the Fins if Air Cooled Engines,” NACA Report, no. 158, 1922. 69.M. N. Murray, “Heat Transfer through an Annular Disk or Fin of Uniform Thickness,” Journal of Applied Mechanics- Transactions of the ASME, 60(1938), 78-80. 70.A. Bar-Cohen, “Fin Thickness for an Optimized Natural- Convection Array of Rectangular Fins,” Journal of Heat Transfer-Transactions of the ASME, 101(1979), 564-566. 71.A. Bar-Cohen and W. M. Rohsenow, “Thermally Optimum Spacing of Vertical, Natural Convection Cooled, Parallel Plates,” Journal of Heat Transfer-Transactions of the ASME, 106(1984), 116-123. 72.V. R. Rao and S. P. Venkateshan, “Experimental Study of Free Convection and Radiation in Horizontal Fin Arrays,” International Journal of Heat and Mass Transfer, 39(1996), 779-789. 73.V. R. Rao, C. Balaji, and S. P. Venkateshan, “Interferometric Study of Interaction of Free Convection with Surface Radiation in An L Corner,” International Journal of Heat and Mass Transfer, 40(1997), 2941-2947 74.J. Metz and S. Robert, “Heat-Dissipating Method and Device for LED Display,” United States Patent 5173839, 1992. 75.P. A. Hochstein, “LED Lamp Assembly with Means to Conduct Heat Away from the LEDs,” United States Patent 6045240, 2000. 76.P. A. Hochstein, “LED Integrated Heat Sink,” United States Patent 6517218, 2003. 77.S. Liu, T. Lin, X. Luo, M. Chen, and X. Jiang, “A Microjet Array Cooling System for Thermal Management of Active Radars and High-Brightness LEDs,” 56th Electronic Components and Technology Conference, San Diego, CA, USA, pp. 1634-1638, May 30-June 2, 2006. 78.T. Acikalin, S. V. Garimella, J. Petroski, and A. Raman, “Optimal Design of Miniature Piezoelectric Fans for Cooling Light Emitting Diodes,” Proceedings of Intersociety Conference on Thermal Phenomena, Las Vegas, NY, USA, vol. 1, pp. 663-671, June 1-4, 2004. 79.G. J. Sheu, F. S. Hwu, S. H. Tu, W. T. Chen, J. Y. Chang, and J. C. Chen, “The Heat Dissipation Performance of LED Applied a MHP,” Fifth International Conference on Solid State Lighting, San Diego, CA, USA, vol. 5941, pp. 1-8, August 1-4, 2005. 80.M. W. Shin, “Thermal Design of High-Power LED Package and System,” Advanced LEDs for Solid State Lighting, Gwangju, South Korea, vol. 6355, pp. 1-13, September 5-7, 2006. 81.L. Kim, J. H. Choi, S. H. Jang, and M. W. Shin, “Thermal Analysis of LED Array System with Heat Pipe,” Thermochimica Acta, 455(2007), 21-25. 82.B. J. Huang, “LED high Brightness Technology and Application of Solar Lighting,” New Energy Center, Department of Mechanical Engineering, National Taiwan University, Taipei, Taiwan, August 2005. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/63723 | - |
dc.description.abstract | 本研究以實驗量測和FLUENT軟體來分析及驗證地埋螺旋管熱交換器的散熱性能和吸熱性能,並比較計算結果其趨勢相符合,此外分析土壤熱傳導係數、土壤熱容、中央直管絕熱、流體入口位置改變以及入口流體溫度改變對散熱量及土壤溫度變化的影響,其結果指出在中央直管做隔熱,在起始運轉6.5小時內其散熱量會低於中央直管未做隔熱的設計,而6.5小時後的運作時間其散熱量高於中央直管未做隔熱的設計是由於降低熱短路的效應;中央直管入水方式的散熱性能稍高於外側螺旋管入水方式,土壤熱容值越高其蓄熱能力越強而使散熱量越高;土壤熱傳導值影響土壤溫度分佈的均勻性,其值越高則散熱量越高。本研究於彰化二林實地測試螺旋管的散熱性能,進行地埋螺旋管熱交換器的測試,包含三種測試條件:當入口溫度為45℃、體積流率為12LPM,經過17小時測試運轉後,其單位長度散熱量為120W/m;當入口溫度為45℃、體積流率為3.2LPM,經過15.7小時測試運轉後,其單位長度散熱量為147.1W/m;當入口溫度為35℃、體積流率為3.2LPM,經過22.7小時測試運轉後,其單位長度散熱量為83.1W/m,另透過實驗數據驗證數學控制體積的分析模式,並透過此分析模式建立地埋螺旋管熱交換器的性能分析圖。
本研究將地埋螺旋管熱交換器應用於高功率LED的散熱,可使功率600W的LED在0.3m3燈座體積下正常運轉,並使基板溫度維持在55℃以下,另以白天關燈、晚間開燈的方式做週期運轉三天,觀測出土壤溫度會隨著操作模式形成週期,另透過實驗驗證數學控制體積所分析的散熱率和燈板溫度。 | zh_TW |
dc.description.abstract | The study experimentally and theoretically investigates the heat transfer performance of the helical ground heat exchanger (HGHE). The simulation results are made with CFD code Fluent, which are found in fine agreements with the experimental data. The helical ground heat exchanger has been investigated with Fluent under different experimental parameters and working conditions. The parameters include the soil thermal conductivity, the soil heat capacity, the insulation of the center pipe, the inlet flow location and the inlet temperature of the flow. The results show that the heat dissipation rate of the HGHE with insulating the center pipe is lower than the HGHE without insulating the center pipe within 6.5 hours after start-up, but is higher than the HGHE without insulating the center pipe because avoiding the effect of the thermal interference. The heat dissipation rate of the HGHE with the inlet flow from the inside pipe is higher than from the outside pipe. Besides, the higher soil thermal conductivity and the higher soil heat capacity are benefit to elevate the heat transfer performance of the HGHE.The ground cooling is tested under the three cases. The results show that heat dissipation rates of the HGHE are 120W/m under the inlet water temperature of 45℃ and volume flow rate of 12LPM, 147.1W/m under the inlet water temperature of 45℃ and volume flow rate of 3.2LPM and 83.1W/m under the inlet water temperature of 35℃ and volume flow rate of 3.2LPM. The study constructs the relationship between the heat dissipation rate of the HGHE and soil thermal property through the 1-D model and experiment data.
The thesis applies the HGHE to dissipate the heat generated from the high power LED. It keeps that the 600W LED normally works with the lamp plate of 0.3m3 and maintains the base plate temperature lower than 55℃. The ground temperature also varies periodically as the 600W LED works periodically. In addition, the base plate temperature and the heat dissipation rate of the HGHE based on a lumped model match the experimental data. | en |
dc.description.provenance | Made available in DSpace on 2021-06-16T17:17:17Z (GMT). No. of bitstreams: 1 ntu-101-D97522023-1.pdf: 17403191 bytes, checksum: d7d33a800ff78da5329f9b4fc9600f47 (MD5) Previous issue date: 2012 | en |
dc.description.tableofcontents | 誌謝 I
摘要 II ABSTRACT III 目錄 V 圖目錄 VIII 符號說明 XIII 第一章 緒論 1 1.1 前言 1 1.2 文獻回顧 2 1.3 研究動機與目的 9 1.4 研究方法 9 第二章 基本理論 11 2.1 熱阻定義及熱傳率 11 2.2 流體力學計算軟體FLUENT簡介 11 2.2.1 Fluent基礎理論 12 2.2.2 流場統御方程式 12 2.2.3 紊流計算模式 13 2.3 FLUENT計算程序 15 2.4 FLUENT計算方式 16 2.4.1 Fluent 分析步驟 16 2.4.2 Fluent 網格系統 17 2.4.3 離散方程式 18 2.4.4 離散插值演算法 18 2.4.5 S.I.M.P.L.E. 演算法則 19 2.4.6 求解的收斂標準 19 第三章 地埋螺旋管熱交換器性能分析 21 3.1 前言 21 3.2 地埋螺旋管熱交換器之運作原理 21 3.3 地埋螺旋管熱交換器之性能測試方法 21 3.3.1 地埋螺旋管熱交換器測試系統 21 3.3.2 實驗流程與步驟 22 3.3.3 土壤熱物理性質測試原理 23 3.3.4 土壤熱傳導係數測試系統 24 3.4 計算流體力學軟體分析 24 3.4.1 幾何模型 24 3.4.2 收斂標準 25 3.4.3 格點獨立性測試 25 3.5 地埋螺旋管熱交換器實地測試 25 3.5.1 實驗測試系統 26 3.5.2 實驗流程與步驟 27 3.6 地埋螺旋管性能分析模式 27 3.7 量測設備與相關儀器 32 3.8 結果與討論 34 3.8.1 實驗與模擬結果比較 35 3.8.2 實驗和模擬結果之分析 35 3.8.3 土壤熱物理性質和操作參數研究: 38 3.8.4 地埋螺旋管熱交換器實地性能測試 40 第四章 地埋螺旋管熱交換器應用於高功率LED散熱 90 4.1 前言 90 4.2 研究方法 93 4.2.1 實驗系統架設 93 4.2.2 量測設備與相關儀器 94 4.3 LED燈板溫度分析模式 95 4.4 結果與討論: 97 第五章 結論與建議 109 參考文獻 111 附錄、地埋螺旋管熱交換器性能對照圖 120 | |
dc.language.iso | zh-TW | |
dc.title | 地埋螺旋管熱交換器性能分析與應用 | zh_TW |
dc.title | The Performance Analysis and Application of Helical Ground Heat Exchangers | en |
dc.type | Thesis | |
dc.date.schoolyear | 100-2 | |
dc.description.degree | 博士 | |
dc.contributor.oralexamcommittee | 吳文方,陳輝俊,卓清松,施文彬,張至中 | |
dc.subject.keyword | 地埋螺旋管,熱短路,高功率LED, | zh_TW |
dc.subject.keyword | Helical ground heat exchanger,Thermal interference,High power LED, | en |
dc.relation.page | 123 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2012-08-18 | |
dc.contributor.author-college | 工學院 | zh_TW |
dc.contributor.author-dept | 機械工程學研究所 | zh_TW |
顯示於系所單位: | 機械工程學系 |
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