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科学通报 2011

吸收式化学蓄能的研究综述

DOI: 10.1360/972010-2020, PP. 669-678

杨启超,张晓灵,王馨,李先庭,石文星

Keywords: 吸收式,化学蓄能,循环,工质对,系统

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Abstract:

吸收式化学蓄能是一种具有蓄能密度高、热损失小的热能储存技术,在太阳能等可再生能源的有效利用、工业余热及冷热电联供系统的余热等中低品位能源利用领域具有良好的应用前景.介绍了吸收式化学蓄能技术的基本原理和特点,归纳和总结了国内外对吸收式化学蓄能在工质对遴选、系统和循环研究及样机研发等方面的研究现状和进展,并提出了此项技术需要进一步研究和解决的关键技术问题.

References

[1]	1 Bales C, Hadorn J C, Druck H, et al. Advanced storage concepts for solar houses and low energy buildings. IEA-SHC Task 32. In:Proceedings of ISES, 2005
[2]	2 Paksoy H O. Thermal Energy Storage for Sustainable Energy Consumption Fundamentals,Case studies and Design. Berlin: Springer, 2007
[3]	3 Ameel T A, Gee K G, Wood B D. Performance predictions of alternative, low cost absorbents for open-cycle absorption solar cooling. SolEnergy, 1995, 54: 65-73
[4]	7 Weber R, Dorer V. Long-term heat storage with NaOH. Vacuum, 2008, 82: 708-716？？
[5]	11 Kaushik S C, Lam K T, Chandra S, et al. Mass and energy storage analysis of an absorption heat pump with simulated time dependentgenerator heat input. Energ Convers Manage, 1982. 22: 183-196
[6]	12 Ruiter J P. Thermal energy storage by means of an absorption cycle. Doctoral Dissertation. Delft: Delft University of Technology, 1987
[7]	14 Sheridan N R, Kaushik S C. A novel latent heat storage for solar space heating systems: Refrigerant storage. Appl Energy, 1981, 9:165-172？？
[8]	17 万忠民, 舒水明, 郭义明. 一种新的太阳能吸收式制冷系统中的蓄能技术. 华中科技大学学报(自然科学版), 2002, 30: 14-16
[9]	29 Rizza J J. Lithium bromide and water thermal storage system. J Sol Energy-T-ASME, 1988, 110: 327-334？？
[10]	30 徐士鸣, 张莉, 郭亚丽, 等. 变质量能量转换及储存技术在暖通空调中的应用. 暖通空调, 2005, 35: 109-113
[11]	32 徐士鸣, 姜俊华, 张莉, 等. 变质量体系能量转换及储存系统充能过程动态特性研究. 热科学与技术, 2004, 297-303
[12]	33 刘通. 以溴化锂溶液为工质的蓄能空调系统实验台的搭建与实验研究. 硕士学位论文. 大连: 大连理工大学, 2009
[13]	34 郭伟杰, 徐士鸣. 多温级蓄能制冷系统动态特性模拟及分析. 低温与特气, 2008, 26: 19-24
[14]	36 Kaushik S C, Rao S K, Kumari R. Dynamic simulation of an aqua-ammonia absorption cooling system with refrigerant storage. EnergConvers Manage, 1991, 32: 197-206
[15]	38 Kessling W, Laevemann E, Kapfhammer C. Energy storage for desiccant cooling systems component development. Sol Energy, 1998, 64:209-221？？
[16]	39 Liu X H, Geng K C, Lin B R, et al. Combined cogeneration and liquid-desiccant system applied in a demonstration building. Energy Build,2004, 36: 945-953？？
[17]	40 张小松, 殷勇高, 曹毅然. 蓄能型液体除湿冷却空调系统的建立与实验研究. 工程热物理学报, 2004, 25: 546-549
[18]	41 殷勇高, 张小松, 管振水. 盐溶液除湿冷却系统的潜能蓄冷研究. 太阳能学报, 2006, 27: 451-455
[19]	43 丛大勇, 柳建华, 安守超, 等. 太阳能液体除湿空调系统蓄能特性实验研究. 制冷, 2008, 27: 1-5
[20]	4 Kessling W, Laevemann E, Peltzer M. Energy storage in open cycle liquid desiccant cooling systems. Int J Refrig, 1998. 21: 150-156
[21]	5 Li Z F, Sumathy K. Technology development in the solar absorption air-conditioning systems. Renew Sust Energ Rev, 2000, 4: 267-293？？
[22]	6 Le Pierres N, Luo L G, Liu H L. Solar thermal energy storage for house heating through LiBr/H2O absorption process: Preliminary energyevaluation. Proceedings of global conference on global warming-2008 (GCGW-08). Istanbul, Turkey, 2008. 329-340
[23]	8 Bales C. Final report of Subtask B “Chemical and sorption Storage” the overview. 2008. www.iea-shc.org
[24]	9 Bales C. Modelling of commercial absorption heat pump with integral storage. In: Proceedings of 11th International Conference onThermal Energy Storage. Stockholm, Sweden. 2009
[25]	10 Bales C, Nordlander S. TCA Evaluation, Lab Measurements, Modelling and System Simulations. SERC Report. 2005
[26]	13 Grassie S L, Sheridan N R. Modelling of a solar-operated absorption air conditioner system with refrigerant storage. Sol Energy, 1977, 19:691-700？？
[27]	15 Wilbur P J, Mitchell C E. Solar absorption air conditioning alternatives. Sol Energy, 1975, 17: 193-199？？
[28]	16 Wilbur P J, Mancini T R. Comparison of solar absorption air conditioning systems. Sol Energy, 1976, 18: 569-576？？
[29]	18 万忠民, 舒水明, 胡兴华. 新型太阳能混合吸收式制冷系统的蓄能研究. 制冷与空调, 2006, 6: 36-39
[30]	19 Qiu J, Liang J, Chen G M, et al. Modeling and numerical simulation of a novel solar-powered absorption air conditioning system drivenby a bubble pump with energy storage. Chinese Sci Bull, 2009, 54: 504-515？？
[31]	20 徐士鸣, 徐长红, 张莉. 溴化锂溶液蓄能空调/供热系统工作特性模拟与分析. 大连理工大学学报, 2008, 48: 503-508
[32]	21 Rizza J J. Aqueous lithium bromide TES and R-123 chiller in series. J Sol Energy-T-ASME, 2003, 125: 49-54？？
[33]	22 徐士鸣, 张莉, 李革, 等. 以水-溴化锂溶液为工质的制冷/制热潜能储存系统特性研究. 大连理工大学学报, 2005, 45: 194-200
[34]	23 徐士鸣, 张莉. 采用氨水溶液的先进蓄能系统工作特性研究(1)—— 工作原理及过程动态模型. 太阳能学报, 2007, 28: 457-463
[35]	24 徐士鸣, 张莉. 采用氨水溶液的先进蓄能系统工作特性研究(2)—— 全量蓄能策略下工作过程模拟及分析. 太阳能学报, 2007, 28:1380-1388
[36]	25 Rizza J J. Ammonia-water low-temperature thermal storage system. J Sol Energy-T-ASME, 1998, 120: 25-31？？
[37]	26 Olsson R, Kaarebring-Olsson M, Jonsson S. A chemical Heat Pump, in WO0037864, W.P. Register, Editor, 2000
[38]	27 Bales C. Thermal storage with the Thermo-chemical Accumulator (TCA). In Ecostock 2006. Pomona, NJ, USA, 2006
[39]	28 Victor A. The importance of business networks of small-to medium sized enterprises in environmental technology industry. Master Thesis.Stockholm: Royal Institute of Technology, 2010
[40]	31 徐士鸣. 蓄能技术新概念—— 制冷/制热潜能储存技术. 电力需求侧管理, 2003, 5: 43-48
[41]	35 胡艳, 徐士鸣. 以空气为携热介质的开式太阳能蓄能热泵循环研究与分析. 能源技术, 2004, 25: 108-111
[42]	37 徐士鸣, 张莉, 徐长红. 采用溴化锂溶液的蓄能空调/供热系统及其数学模型. 大连理工大学学报, 2007, 47: 803-808
[43]	42 施明恒, 杜斌, 赵云. 太阳能液体除湿空调系统再生和蓄能特性的研究. 太阳能学报, 2006, 27: 49-54
[44]	44 Xiong Z Q, Dai Y J, Wang R Z. Investigation on a two-stage solar liquid-desiccant (LiBr) dehumidification system assisted by CaCl2 solution.Appl Therm Eng, 2009, 29: 1209-1215？？
[45]	45 张小松, 费秀峰, 施明桓, 等. 蓄能型溶液除湿蒸发冷却空调系统中除湿器研究. 东南大学学报(自然科学版), 2003, 33: 72-75
[46]	46 马强, 王如竹, 夏再忠, 等. 基于氨水吸收技术的低品位热能远距离输送系统. 科学通报, 2008, 53: 3030-3038

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