自製泛用型多功能熱泵於不同操作條件下
性能係數之探討

Po-Chiun Tseng; 曾博群

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/43713

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	方煒(Wei Fang)
dc.contributor.author	Po-Chiun Tseng	en
dc.contributor.author	曾博群	zh_TW
dc.date.accessioned	2021-06-15T02:26:38Z	-
dc.date.available	2012-08-20
dc.date.copyright	2009-08-20
dc.date.issued	2009
dc.date.submitted	2009-08-17
dc.identifier.citation	1. 方煒、蕭煒炯。2002。用於蒸氣壓縮式空調或冷凍機高壓側之蓄壓及廢熱再利用機構。中華民國專利第500900號。 2. 方煒教授的網站。2005。雙效型冷凍空調熱泵及其在生物產業的應用。網址：http://ecaaser3.ecaa.ntu.edu.tw/weifang/lab551/%E7%A0%94%E7%A9%B6%E6%88%90%E6%9E%9C.htm 。上網日期：2007-06-12。 3. 卓昆範。2008。建立結合熱泵與太陽能之熱水主機與網路管理。碩士論文。台北:台灣大學生物產業機電工程研究所。 4. 馬一太、王軍亮、呂山仁。1992。熱泵主機自動變頻調素容量調節研究。天津大學學報。2(3):114-120。 5. 張潔、張良俊、王如竹、吳靜怡。2007。空氣源熱泵主機優化計算與實驗研究。太陽能學報。28(3):286-290。 6. 劉雪玲、朱家玲。2005。水源熱泵在冬季供暖的應用。太陽能學報。26(2):262-265。 7. 楊秉純。1995。板式熱交換器於冷凍主機之應用。化學技術。3(7):106-111。 8. Biaou, A. L. Bernier, M. A. 2008. Achieving total domestic hot water production with renewable energy. Building and Environment. (43):651–660. 9. Chow, J. J. Pei, T. Dong, G. He, J. W. 2003. Domestic air-conditioner and integrated water heater for subtropical climate. Applied Thermal Engineering. (23):581–592. 10. Guo, X. M. Chen, Y. G. Wang, W. H. Chen, C. Z. 2008. Experimentl study on frost growth and dynamic performance of air source heat pmp system. Applied Thermal Engineering. 11(28):2267-2279. 11. Huang, B. J. Chyng, J.P. 2007. Heat-pipe enhanced solar-assisted heat pump water heater. Solar Energy. (78):375–381. 12. Harris, J. Neme, C. Calwell, C. 2005. Residential heat pump water heaters: energy efficiency potential and industry status. Prepared for Natural Resources Defense Council. http://www.energystarpartners.net/ia/Water_heaters/Documents/VEIC_HPWHfinalreport_Nov2005. Access date: January 27, 2008. 13. Li, Y. W. Wang, R. Z. Wu, J.Y. Xu, Y. X. 2007. Experimental performance analysis on a direct expansion solar-assisted heat pump water heater. Applied Thermal Engineering. (27):2858–2868. 14. Lian, Z. Park, S. Huang, W. Baik, Y. Yao, Y. 2005. Conception of combination of gas engine-driven heat pump and water-loop heat pump system. International Journal of Refrigeration (28):810-819.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/43713	-
dc.description.abstract	本研究旨在建構兼具提供冷水、冷氣、熱水與暖氣的多功能熱泵系統，並探討各部熱交換元件在啟動或不啟動狀況、穩態或暫態運作條件下對系統及主機製熱與製冷性能之影響。系統組成包括壓縮機、蓄壓器、水對冷媒的板式熱交換器 (第一段熱排及冷排)、冷媒對空氣的熱交換器 (第二段熱排及冷排) 、二重管熱交換器、毛細管、感溫膨脹閥及液氣分離器。系統組成選用壓縮機容量為1.5 USRT，第二段冷排與熱排使用的風扇均為60 W，熱水桶與冰水桶水量分別40 L為150 L，板式熱交換器中循環水的流量率為1160 L/hr，以上為固定條件。系統組成中擬探討的變動條件包括：蓄壓器容積比較、第一段冷熱排選用、毛細管長度評估與冷媒量評估。最後選定容積為0.77 L的蓄壓器，熱側第一段熱排選用熱傳面積為0.421 m2的板式熱交換器，冷側第一段冷排則選用熱傳面積為0.432 m2的板式熱交換器，選用長度為45 cm毛細管，冷媒量則選擇1.5 kg為填充量。在水溫自20 ℃加熱至50 ℃的過程中，以上組合的系統及主機的製熱性能係數可達2.87及3.38，系統及主機的製冷性能係數可達2.86及3.29，整體的系統及主機性能係數可達5.21及6.53。	zh_TW
dc.description.abstract	The focuses of this study were to develop a generic multi-purpose heat pump capable of providing cold water, cold air, hot water and warm air at the same time, as well as to investigate on the impacts to the coefficient of performance of the system and the compressor due to various operating conditions in either high pressure and/or low pressure side of the refrigeration cycle, including on/off of the second stage heat exchangers and steady or transient state of water flow through water-air heat exchangers. This generic system consists of compressor, pressure accumulator, plate-type heat exchangers, air-water heat exchangers, dual pipe heat exchanger, capillary tube, thermal-controlled expansion valve and gas-liquid separator. The components selected for this generic design are as follows: capacity of the compressor is 1.5 USRT, power of fans of the air-water heat exchangers are 60 W, amount of water in the hot and cold water tanks are 40 L and 150 L, respectively, and the flow rate of the water re-circulating in both plate-type heat exchangers is 1160 L/hr. Subject to the components previously selected, other corresponding components were under investigation in order to reach highest COP, the selected components are: pressure accumulator at the capacity of 0.77 L, plate-type heat exchanger with the heat exchange area of 0.432 m2 at the cold (low pressure) side, and 0.421 m2 at the hot (high pressure) side, capillary tube at the length of 45 cm and amount of refrigerant R22 charged in to the cycle at the weight of 1.5 kg. With such combinations, the high pressure side of the COP of the system and compressor is 2.87 and 3.38, respectively, the low pressure side of the COP of the system and compressor is 2.86 and 3.29, respectively and the total COP of the system and compressor is 5.21and 6.53, respectively when the water temperature is to be raised from 20 C to 50 degree C.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T02:26:38Z (GMT). No. of bitstreams: 1 ntu-98-R96631021-1.pdf: 2942730 bytes, checksum: b8424eb2cc8aa90fac85b4b3fe3cc01c (MD5) Previous issue date: 2009	en
dc.description.tableofcontents	誌謝 ............................................................................................................................... i 摘要 .............................................................................................................................. ii Abstract ....................................................................................................................... iii 目錄 .............................................................................................................................. v 圖目錄 ....................................................................................................................... viii 表目錄 ......................................................................................................................... xi 第1章前言與研究目的 ............................................................................................. 1 1-1前言 ................................................................................................................ 1 1-2研究目的 ........................................................................................................ 3 第2章文獻探討 ........................................................................................................ 4 2-1熱泵熱水器 .................................................................................................... 4 2-1-1熱泵熱水器原理...................................................................................... 4 2-1-2熱泵熱水器與其他熱水器成本及效率比較 ........................................... 5 2-2 熱泵系統種類 ............................................................................................... 5 2-2-1 氣源式熱泵 (Air Source Heat Pump, ASHP) ......................................... 6 2-2-2 水源式熱泵 (Water Source Heat Pump, WSHP) .................................... 7 2-2-3地源式熱泵 (Ground Source Heat Pump, GSHP) ................................... 8 2-3利用太陽能的熱泵 ..................................................................................... 9 2-3-1 直膨式太陽能輔助式熱泵 (Direct-Expansion Solar Assisted Heat Pump, DX-SAHP) ............................................................................................ 9 2-3-2 結合熱泵與太陽能之熱水系統 (Heat Pump with Solar Collector, HPSC) ............................................................................................................ 10 2-3-3結合熱管式太陽能與熱泵熱水系統(Heat Pipe enhanced Solar Assisted Heat Pump, HPSAHP) ......................................................................... 11 2-4 燃氣引擎式熱泵 (Gas Engine Heat Pump, GEHP ) ................................ 12 2-5多效型熱泵 .................................................................................................. 12 2-5-1 多效型熱泵系統運作模式 ................................................................... 13 2-5-2多效型熱泵應用實例 ............................................................................ 14 2-6 熱泵系統參數 ............................................................................................. 15 2-6-1冷媒填充量 ........................................................................................... 16 2-6-2 毛細管長度 .......................................................................................... 16 2-6-3 儲液器 .................................................................................................. 17 2-6-4 蓄壓器 .................................................................................................. 18 2-6-5板式熱交換器 ....................................................................................... 19 2-6-6 壓縮機變頻 .......................................................................................... 20 2-7 熱泵系統熱能分析及效率計算方法 ........................................................... 21 2-7-1分段熱流計算管長 ................................................................................ 21 2-7-2 COP定義及計算方法 ........................................................................... 22 第3章材料與方法 ................................................................................................... 23 3-1熱泵系統 ...................................................................................................... 23 3-2 實驗方法 ..................................................................................................... 38 3-2-1 熱交換器組合對系統製熱及製冷性能的影響 (預備實驗) ................. 39 3-2-2 熱側泵浦流量率的改變對系統性能的影響 ........................................ 41 3-2-3系統置入不同容積之蓄壓器以及無蓄壓器時系統性能比較 .............. 41 3-2-4 熱側及冷側板式熱交換器互換對系統性能的影響 ............................. 41 3-2-5 冷媒填充量與毛細管的不同組合對系統性能及耗能的影響 ............. 41 3-2-6 保溫前後對系統及主機性能之影響 .................................................... 42 3-2-7熱側及冷側水體為暫態或穩態對系統製冷及製熱性能之影響 .......... 42 第4章結果與討論 ................................................................................................... 43 4-1 熱泵系統組成 ............................................................................................. 43 4-1-1 熱排及冷排之組合對系統製熱及製冷性能之影響 (預備實驗) ......... 44 4-1-2 熱側泵浦流量率的改變對系統性能之影響 ........................................ 55 4-1-3 系統置入不同容積之蓄壓器以及無蓄壓器時系統性能比較 ............. 61 4-1-4 熱側及冷側熱板式交換器互換對系統及主機性能之影響 ................. 66 4-1-5 冷媒填充量與毛細管的不同組合對系統性能及耗功的影響 ............. 73 4-1-6 保溫前後對系統及主機性能之影響 .................................................... 79 4-1-7 穩態或暫態循環水體對系統製冷及製熱性能之影響 ......................... 83 第5章結論與建議 ................................................................................................... 85 5-1 結論 ............................................................................................................. 85 5-2 建議 ............................................................................................................. 87 參考文獻 ........................................................................................................ 88
dc.language.iso	zh-TW
dc.subject	泛用型設計	zh_TW
dc.subject	性能係數	zh_TW
dc.subject	冷凍空調循環	zh_TW
dc.subject	多功能熱泵	zh_TW
dc.subject	Refrigeration Cycle	en
dc.subject	Multi-Purpose Heat Pump	en
dc.subject	Generic Design	en
dc.subject	Coefficient of Performance	en
dc.title	自製泛用型多功能熱泵於不同操作條件下性能係數之探討	zh_TW
dc.title	Investigation on Performance of Self-Made Generic Multi-Purpose Heat Pump	en
dc.type	Thesis
dc.date.schoolyear	97-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	黃振康,蔡致榮
dc.subject.keyword	多功能熱泵,性能係數,泛用型設計,冷凍空調循環,	zh_TW
dc.subject.keyword	Multi-Purpose Heat Pump,Coefficient of Performance,Generic Design,Refrigeration Cycle,	en
dc.relation.page	89
dc.rights.note	有償授權
dc.date.accepted	2009-08-17
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	生物產業機電工程學研究所	zh_TW
顯示於系所單位：	生物機電工程學系

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