冰-C7蓄冷空调经济技术分析及蓄冷材料混合比例研究
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摘要
本文在已有的研究基础上,采用理论研究与实验操作相结合的方法,通过对常规空调系统、蓄冰空调系统、冰-C7蓄冷空调系统的经济技术分析与评价可知,冰-C7蓄冷空调系统增加的初投资不到一年既可收回,表明了该系统的可行性,其投资回收期比蓄冰空调系统短,表明了该系统的优越性。
通过从理论上对不同混合比(冰与C7)对蓄冷槽性能的影响的分析,表明蓄冰厚度对蓄冰槽性能影响显著;对该蓄冷空调系统,当蓄冰厚度取14mm时,相变材料质量混合比取1.8~3.6时较为理想,对应的体积比为3.2~6.4。
实验数据分析表明,PCM-C7的应用不仅可增加系统蓄冷量(加入PCM-C7质量为35.875kg、23.625kg时同无PCM-C7的蓄冷槽相比,蓄冷量分别增加了18.73%,13.43%,释冷量分别增加了18.90%,11.79%),而且可提高系统蒸发温度(当加入23.625kg PCM-C7时比无PCM-C7时蒸发温度平均提高2.140℃,当加入35.875kg PCM-C7时比无PCM-C7蒸发温度平均提高2.654℃);从提高蒸发温度的角度考虑,加入PCM-C7的最大于23.625kg即为比较理想,此时对应的冰(水)与PCM-C7质量混合比例为4.507,相应的体积混合比例为8.112;实验亦表明了释冷过程蓄冷槽内水的较好流动性。
The paper employs the method of combing theory with experiment study on the base of the condition we already had. The economic technical analysis of general air-conditioning system, ice-storage air-conditioning system and ice-C7 mixed cool-storage air-conditioning system indicts that the mixed cool-storage system is feasible because the increased first cost of it will recover in a year. And the recovery time of ice-C7 system is shorter than the ice-storage system.
Through the analysis of different mixed proportion of PCM affecting cool-storage tank, the results indicate that the thickness of ice affects the performance of cool-storage tank seriously, and the best mixed proportion range of quality is from 1.8 to 3.6, the mixed proportion range of volume is from 3.2 to 6.4, when the thickness of ice is 14mm.
The data of experiment indict that the application of PCM-C7 is not only increases the cool-storage capacity (when the quality of PCM-C7 is 35.875kg or 23.625kg, the cool-storage capacity increases 18.73%, 13.43% and the cool-release increases 18.90%, 11.7% corresponding compared with the cool-storage tank having no PCM-C7), but also enhances the evaporating temperature (when the quality of PCM-C7 is 35.875kg or 23.625kg, the evaporating temperature increases 2.140℃, 2.654℃corresponding compared with the cool-storage tank having no PCM-C7) and when the quality of PCM-C7 is more than 23.625 kg is well, which the mixed proporation of quality is less than 4.507 and the prpporation of volume is less than 8.112. The experiment also indicts that the water in cool-storage have excellent fluidness in cool-rlease process.
通过从理论上对不同混合比(冰与C7)对蓄冷槽性能的影响的分析,表明蓄冰厚度对蓄冰槽性能影响显著;对该蓄冷空调系统,当蓄冰厚度取14mm时,相变材料质量混合比取1.8~3.6时较为理想,对应的体积比为3.2~6.4。
实验数据分析表明,PCM-C7的应用不仅可增加系统蓄冷量(加入PCM-C7质量为35.875kg、23.625kg时同无PCM-C7的蓄冷槽相比,蓄冷量分别增加了18.73%,13.43%,释冷量分别增加了18.90%,11.79%),而且可提高系统蒸发温度(当加入23.625kg PCM-C7时比无PCM-C7时蒸发温度平均提高2.140℃,当加入35.875kg PCM-C7时比无PCM-C7蒸发温度平均提高2.654℃);从提高蒸发温度的角度考虑,加入PCM-C7的最大于23.625kg即为比较理想,此时对应的冰(水)与PCM-C7质量混合比例为4.507,相应的体积混合比例为8.112;实验亦表明了释冷过程蓄冷槽内水的较好流动性。
The paper employs the method of combing theory with experiment study on the base of the condition we already had. The economic technical analysis of general air-conditioning system, ice-storage air-conditioning system and ice-C7 mixed cool-storage air-conditioning system indicts that the mixed cool-storage system is feasible because the increased first cost of it will recover in a year. And the recovery time of ice-C7 system is shorter than the ice-storage system.
Through the analysis of different mixed proportion of PCM affecting cool-storage tank, the results indicate that the thickness of ice affects the performance of cool-storage tank seriously, and the best mixed proportion range of quality is from 1.8 to 3.6, the mixed proportion range of volume is from 3.2 to 6.4, when the thickness of ice is 14mm.
The data of experiment indict that the application of PCM-C7 is not only increases the cool-storage capacity (when the quality of PCM-C7 is 35.875kg or 23.625kg, the cool-storage capacity increases 18.73%, 13.43% and the cool-release increases 18.90%, 11.7% corresponding compared with the cool-storage tank having no PCM-C7), but also enhances the evaporating temperature (when the quality of PCM-C7 is 35.875kg or 23.625kg, the evaporating temperature increases 2.140℃, 2.654℃corresponding compared with the cool-storage tank having no PCM-C7) and when the quality of PCM-C7 is more than 23.625 kg is well, which the mixed proporation of quality is less than 4.507 and the prpporation of volume is less than 8.112. The experiment also indicts that the water in cool-storage have excellent fluidness in cool-rlease process.
引文
[1]尚世任.能源形势与空调业的发展.电力需求侧管理[J],2005,7:1~3
[2]吴喜平,朱林霞,于连涛.冰蓄冷空调。上海节能[J],2005,3:33~36
[3]华泽钊,刘道平,吴兆琳等。蓄冷技术及其在空调工程中的应用[M].北京:科学出版社,1997
[4]汪训昌.综合国情.稳步建设蓄冷空调工程.暖通空调[J],1997,27(5):16~20
[5]刘鉴民.蓄冷空调与其它常用电网调峰方式调峰效益的比较研究.电网技术[J],1997,21(12):15~17
[6]潘慧.“移峰填谷”添新技.广东科技[J],2006(154):23~24
[7]吴喜平.国外冰蓄冷技术发展特点简介.电力需求侧管理[J],2001,3(2):58~59
[8]顾念祖等.冰蓄冷是提高能源利用率和解决电力峰谷差的有效途径.节能[J],1996,(3):16~18
[9]潘雨顺.21世纪冰蓄冷空调技术发展方向探讨.通风除尘[J],l998,(4):24~25
[10]方贵银.蓄冷空调实用新技术[M].北京:人民邮电出版社,2000
[11]许肖飞,周光辉.我国新型冰蓄冷空调技术的发展现状.中原工学院学报[J],2006,17(1):55~57
[12]张永铨.日本蓄能空调发展简介.大众用电[J],2002(10):18
[13]刘蓉莉,黄晓鸣.发展蓄冷空调技术、推动电网移峰填谷.节能技术[J],2004,22(123):39~41
[14]方贵银,刑琳,扬帆.蓄冷空调技术的现状及发展趋势.制冷与空调[J],2006,6(1):1~5
[15]Chen Sih-Li etc.,"Theoretical and experimental investigations of a packaged ice-storage air-conditioning system",Transactions of the Chinese Institute of Engineers,v18 n5 1997:445~457
[16]H Rieger,H Beer.The melting process of ice inside a horizontal cylinder:Effects of density anomaly.Trans of the ASME, 1986,(108):166~173
[17]S K Roy,S.Segupta.The melting process within spherical enclosure.Trans of The ASME,1984,(109):460~461
[18]D hrnold.Dynamic simulation of encapsulated ice stores,Part I-The Model.AT-90-13-5.
[19]张永铨.移峰填谷蓄冷技术发展正当时.建设科技[J],2005(20):56~57
[20]今西正美等.冰蓄热,三菱电机技报[J],1993,4
[21]李志浩。日本蓄冷 (热) 式空调系统的现状和动向.江苏制冷空调[J],1999.11
[22]周晓棠,李吉生,赵庆珠.家用空调中冰蓄冷的应用及实验研究.制冷学报[J],2001(3):1~4
[23]孙勇军,王惠龄.小型家用冰蓄冷空调优化运行试验研究.制冷与空调[J],2006,6(5):71~73
[24]万忠民,舒水明,王惠龄.小型家用冰蓄冷空调设计与实验研究.能源技术[J],2003,24(2):59~62
[25]刘广海,丁力行,屈睿瑰.蓄冷空调小型化研究.制冷与空调[J].2003,(6):33~37
[26]赵力,涂光备等.小型蓄冷空调系统的实验研究.设备开发[J].1999,29(5):44~46
[27]He Bo,Mari Gustafsson E,Fredrik Setterwall.Tetradecane and hexadecane binary mixtures as phase change materials (PCMs) for cool storage in district cooling systems.Energy[J],1999,24:1015~1028
[28]Roxas-Dimaano M N,Watanabe T.The capric and lauric acid mixture with chemical additives as latent heat storage materials for cooling application.Energy[J],2002,27:869~888
[29]NariaNatalia R Dimaano,Takayuki Watanabe.The capric-lauric acid and pentadecane combination as phase change material for cooling applications.Applied Thermal Engineering[J],2002,22:365~377
[30]方贵银,李辉.空调蓄冷材料研究现状及其新进展.低温与超导[J],2003, 31(3):64~67
[31]李晓燕.适用于空调蓄冷的新型相变蓄冷介质的研究.应用科技[J].2004,3l(7):66~68
[32]李晓燕,张廷勋等.相变材料蓄冷球蓄冷过程的研究.哈尔滨商业大学学报[J],2002,18(5):583~586
[33]罗智特等.相变材料蓄冷球蓄冷过程的数值模拟.制冷空调与电力机械[J],2004,25(96):33~36
[34]龙惟定,王长庆,丁文婷.试论中国的能源结构与空调冷热源的选择取向.暖通空调[J],2000,30(5):27~30
[35]严德隆,张维君.空调蓄冷应用技术[M],北京:中国建筑工业出版社,1997
[36]吴喜平.蓄冷技术和蓄热电锅炉在空调中的应用[M],上海:同济大学出版社,2000
[37]匪千,蒋福伟.冰蓄冷空调最佳运行策略探讨.机电设备[J],2002(4):34~37
[38]郭齐传,李育,冰蓄冷空调系统运行控制策略综述,福建建设科技[J],2003(1):23~27
[39]Chad B Dorgan,et al.A Descriptive Framework for Cool Storage Operating and Control Strategies.ASHRAE Transaction,1997,942~954
[40]杨琼,范林.蓄冷空调系统的三个策略问题分析,流体机械[J],2005,33(8):69~73
[41]苏文.天津市推广蓄冷空调的潜力分析。天津商学院学报[J],2002,(6):l~2
[42]赖建波,臧润清,苏文.冰蓄冷空调在天津市的发展前景.制冷与空调[J],2004,(3):P16~19
[43]张延勋.蓄冷空调用蓄冷球的研究:[硕士学位论文].哈尔滨:哈尔滨商业大学,2004
[44]李晓燕.蓄冷球内高温相变材料蓄冷特性的研究.节能技术[J],2004,22(125):9~11
[45]刘建,龚毅.动、静态冰蓄冷蓄冷槽水温变化的实验分析.郑州纺织工学 院学报[J],2000,11(4):4~6
[46]李俊梅,李炎锋.直接蒸发冰盘管蓄冷系统特性的实验研究.四川制冷[J],1999,5(1):21~24
[47]周文铸,殷亮,陈之航.直接蒸发式盘管外蓄冰机理的实验研究.能源研究与信息[J],2000,16(3):25~26
[48]王力军,朱京国,胡定科.内肋管壳管式冰蓄冷器及其性能的实验研究.暖通空调[J],1998,28(3):40~42
[49]丁恩勇。差示扫描量热法中相变潜热公式的推导.分析测试学报[J],1999,18(1):52~54
[50]林怡辉.一种新型相变蓄热材料的实验研究.江汉石油学院学报[J],2001,23(4):81~83
[51]方贵银.蓄冷材料相变温度与相变潜热实验研究.建筑热能通风空调[J],2001.3:1~3
[52]岑幻霞等.窄调蓄冷剂液固相图理沦计算与实验研究.高校化学工程学报[J],1997,11(1):25~30
[53]清华同方人环设备有限公司.蓄能空调技术应用手册,北京.2006,8
[54]刘晖.蓄冷空调系统中相变材料蓄冷—释冷规律的理论与实验研究:[硕士学位论文].天津:天津商学院,2000
[2]吴喜平,朱林霞,于连涛.冰蓄冷空调。上海节能[J],2005,3:33~36
[3]华泽钊,刘道平,吴兆琳等。蓄冷技术及其在空调工程中的应用[M].北京:科学出版社,1997
[4]汪训昌.综合国情.稳步建设蓄冷空调工程.暖通空调[J],1997,27(5):16~20
[5]刘鉴民.蓄冷空调与其它常用电网调峰方式调峰效益的比较研究.电网技术[J],1997,21(12):15~17
[6]潘慧.“移峰填谷”添新技.广东科技[J],2006(154):23~24
[7]吴喜平.国外冰蓄冷技术发展特点简介.电力需求侧管理[J],2001,3(2):58~59
[8]顾念祖等.冰蓄冷是提高能源利用率和解决电力峰谷差的有效途径.节能[J],1996,(3):16~18
[9]潘雨顺.21世纪冰蓄冷空调技术发展方向探讨.通风除尘[J],l998,(4):24~25
[10]方贵银.蓄冷空调实用新技术[M].北京:人民邮电出版社,2000
[11]许肖飞,周光辉.我国新型冰蓄冷空调技术的发展现状.中原工学院学报[J],2006,17(1):55~57
[12]张永铨.日本蓄能空调发展简介.大众用电[J],2002(10):18
[13]刘蓉莉,黄晓鸣.发展蓄冷空调技术、推动电网移峰填谷.节能技术[J],2004,22(123):39~41
[14]方贵银,刑琳,扬帆.蓄冷空调技术的现状及发展趋势.制冷与空调[J],2006,6(1):1~5
[15]Chen Sih-Li etc.,"Theoretical and experimental investigations of a packaged ice-storage air-conditioning system",Transactions of the Chinese Institute of Engineers,v18 n5 1997:445~457
[16]H Rieger,H Beer.The melting process of ice inside a horizontal cylinder:Effects of density anomaly.Trans of the ASME, 1986,(108):166~173
[17]S K Roy,S.Segupta.The melting process within spherical enclosure.Trans of The ASME,1984,(109):460~461
[18]D hrnold.Dynamic simulation of encapsulated ice stores,Part I-The Model.AT-90-13-5.
[19]张永铨.移峰填谷蓄冷技术发展正当时.建设科技[J],2005(20):56~57
[20]今西正美等.冰蓄热,三菱电机技报[J],1993,4
[21]李志浩。日本蓄冷 (热) 式空调系统的现状和动向.江苏制冷空调[J],1999.11
[22]周晓棠,李吉生,赵庆珠.家用空调中冰蓄冷的应用及实验研究.制冷学报[J],2001(3):1~4
[23]孙勇军,王惠龄.小型家用冰蓄冷空调优化运行试验研究.制冷与空调[J],2006,6(5):71~73
[24]万忠民,舒水明,王惠龄.小型家用冰蓄冷空调设计与实验研究.能源技术[J],2003,24(2):59~62
[25]刘广海,丁力行,屈睿瑰.蓄冷空调小型化研究.制冷与空调[J].2003,(6):33~37
[26]赵力,涂光备等.小型蓄冷空调系统的实验研究.设备开发[J].1999,29(5):44~46
[27]He Bo,Mari Gustafsson E,Fredrik Setterwall.Tetradecane and hexadecane binary mixtures as phase change materials (PCMs) for cool storage in district cooling systems.Energy[J],1999,24:1015~1028
[28]Roxas-Dimaano M N,Watanabe T.The capric and lauric acid mixture with chemical additives as latent heat storage materials for cooling application.Energy[J],2002,27:869~888
[29]NariaNatalia R Dimaano,Takayuki Watanabe.The capric-lauric acid and pentadecane combination as phase change material for cooling applications.Applied Thermal Engineering[J],2002,22:365~377
[30]方贵银,李辉.空调蓄冷材料研究现状及其新进展.低温与超导[J],2003, 31(3):64~67
[31]李晓燕.适用于空调蓄冷的新型相变蓄冷介质的研究.应用科技[J].2004,3l(7):66~68
[32]李晓燕,张廷勋等.相变材料蓄冷球蓄冷过程的研究.哈尔滨商业大学学报[J],2002,18(5):583~586
[33]罗智特等.相变材料蓄冷球蓄冷过程的数值模拟.制冷空调与电力机械[J],2004,25(96):33~36
[34]龙惟定,王长庆,丁文婷.试论中国的能源结构与空调冷热源的选择取向.暖通空调[J],2000,30(5):27~30
[35]严德隆,张维君.空调蓄冷应用技术[M],北京:中国建筑工业出版社,1997
[36]吴喜平.蓄冷技术和蓄热电锅炉在空调中的应用[M],上海:同济大学出版社,2000
[37]匪千,蒋福伟.冰蓄冷空调最佳运行策略探讨.机电设备[J],2002(4):34~37
[38]郭齐传,李育,冰蓄冷空调系统运行控制策略综述,福建建设科技[J],2003(1):23~27
[39]Chad B Dorgan,et al.A Descriptive Framework for Cool Storage Operating and Control Strategies.ASHRAE Transaction,1997,942~954
[40]杨琼,范林.蓄冷空调系统的三个策略问题分析,流体机械[J],2005,33(8):69~73
[41]苏文.天津市推广蓄冷空调的潜力分析。天津商学院学报[J],2002,(6):l~2
[42]赖建波,臧润清,苏文.冰蓄冷空调在天津市的发展前景.制冷与空调[J],2004,(3):P16~19
[43]张延勋.蓄冷空调用蓄冷球的研究:[硕士学位论文].哈尔滨:哈尔滨商业大学,2004
[44]李晓燕.蓄冷球内高温相变材料蓄冷特性的研究.节能技术[J],2004,22(125):9~11
[45]刘建,龚毅.动、静态冰蓄冷蓄冷槽水温变化的实验分析.郑州纺织工学 院学报[J],2000,11(4):4~6
[46]李俊梅,李炎锋.直接蒸发冰盘管蓄冷系统特性的实验研究.四川制冷[J],1999,5(1):21~24
[47]周文铸,殷亮,陈之航.直接蒸发式盘管外蓄冰机理的实验研究.能源研究与信息[J],2000,16(3):25~26
[48]王力军,朱京国,胡定科.内肋管壳管式冰蓄冷器及其性能的实验研究.暖通空调[J],1998,28(3):40~42
[49]丁恩勇。差示扫描量热法中相变潜热公式的推导.分析测试学报[J],1999,18(1):52~54
[50]林怡辉.一种新型相变蓄热材料的实验研究.江汉石油学院学报[J],2001,23(4):81~83
[51]方贵银.蓄冷材料相变温度与相变潜热实验研究.建筑热能通风空调[J],2001.3:1~3
[52]岑幻霞等.窄调蓄冷剂液固相图理沦计算与实验研究.高校化学工程学报[J],1997,11(1):25~30
[53]清华同方人环设备有限公司.蓄能空调技术应用手册,北京.2006,8
[54]刘晖.蓄冷空调系统中相变材料蓄冷—释冷规律的理论与实验研究:[硕士学位论文].天津:天津商学院,2000