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南方温室内空气循环式蓄热除湿系统的冷凝、蓄热与除湿效应 被引量:1

Condensation,Heat storage and Dehumidification Effects of Air-circulating and Regenerative Dehumidification System inside Greenhouse in Southern China
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摘要 根据2003年1月、2月的相关观测资料,研究了冷凝温室内空气循环式蓄热除湿系统的冷凝、蓄热与除湿效应。结果表明:冷凝温室在2003年1月的晴天里,集水池平均每天蓄积冷凝水7681cm3,折合温室产生冷凝水量32g/m2和12.1g/m3;平均每天冷凝水吸收的汽化热为18858kJ。在典型晴天,冷凝温室下、中、上各层的日平均相对湿度分别比对照温室降低2.7个百分点、3.5个百分点、2.6个百分点,日平均绝对湿度分别比对照温室降低2.7g/m3、4.1g/m3、4.5g/m3;在1月份,2座温室内同日同层次的相对湿度与绝对湿度,均呈现出冷凝<对照,但以晴天差异尤为明显,阴雨天差异较小。空气循环式温室蓄热除湿系统的冷凝、蓄热、除湿效果明显。 Based on the relevant observational data in January and February of 2003, the condensation, heat storage and dehumidification effects of air-circulating and regenerative dehumidification system inside greenhouse in the Southern China were studied. The results showed that the daily mean condensation water inside the condensation greenhouse on the sunshine days in January of 2003 amounted to 7681cm^3/day, which was equivalent to 32g/m^2 greenhouse area and 12. lg/m^3 greenhouse volume. The daily mean vaporization heat absorption of condensed water was 18858 kJ. On a typical sunshine day, the daily average relative humidity on the lower level, middle level, upper level inside the condensation greenhouse were 2.7% , 3.5% and 2.6% lower than that inside the control greenhouse respectively, while the daily average absolute humidity on the lower level, middle level, upper level inside the condensation greenhouse were 2.7g/m^3, 4. lg/m^3, 4.5g/m^3 lower respectively. In January, both relative humidity and absolute humidity on the same level on the same day inside the condensation greenhouse were lower than that inside the control greenhouse, but it was different from the sunshine days, and it was smaller on the rainy and cloudy days. In short, condensation, heat storage and dehumidification effects of air-circulating and regenerative dehumidification system inside greenhouse in the Southern China were significant.
作者 梁称福 陈正法 李文祥 徐龙铁 黄光荣 周国全
机构地区 湖南环境生物职业技术学院 中国科学院亚热带农业生态研究所 广西贺州市农业局
出处 《中国农业气象》 CSCD 2009年第3期343-349,共7页 Chinese Journal of Agrometeorology
基金 中国科学院农业项目办公室"十五"科技攻关项目"中亚热带温室内湿度变化机制与保温除湿技术研究与示范"(NK十五-C-20)
关键词 南方温室 空气循环式蓄热除湿系统 冷凝 蓄热 除湿 Greenhouse in the Southern China Air-circulating and Regenerative Dehumidification System Condensa- tion Heat storage Dehumidification
分类号 S316 [农业科学—作物栽培与耕作技术]
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  • 1谭洪新,刘艳红,朱学宝,罗国芝,周琪.闭合循环水产养殖-植物水栽培综合生产系统的工艺设计及运行效果[J].水产学报,2004,28(6):689-694. 被引量:22
  • 2李科德,胡正嘉.芦苇床系统净化污水的机理[J].中国环境科学,1995,15(2):140-144. 被引量:166
  • 3何玉明,王维善,周凤建,张胜宇,唐兰萍,强晓刚,潘璠,邱从芳.生态型循环水处理系统在工厂化养鱼中的应用研究[J].渔业现代化,2006,33(5):9-11. 被引量:15
  • 4Form C, Chen J, Tancioni L, et al. Evaluation of the fern Azolla for growth, nitrogen and phosphorus removal from wastewater[ J ]. Water Research, 2001, 35 (6) : 1592-1598.
  • 5Zhao M, Duncan J R. Removal and recovery of nicked from aqueous solution and electro-plating rinse effluent using Azolla filiculiodes [ J ]. Process Biochemistry, 1998, 33 ( 3 ) :249-255.
  • 6Shiomi N, Kitoh S. Use of Azolla as a decontaminant in sewage treatment [ A ]. Azolla utilization [ C ]. Manila, Philippines : International Rice Research Institute, 1987 : 169-176.
  • 7Coveney M F, Stites D L, Lowe E F, et al. Nutrient removal from eutrophic lake water by wetland filtration[ J]. Ecological Engineering, 2002, (19) : 141-159.
  • 8Scheible O K, Mulbarger M, Sutton P, et al. Manual: nitrogen control[ M ]. Cincinnati, USA : Environmental Protection Agency, 1993.
  • 9Parker,Denny S. Process design manual for nitrogen control [ M ]. Cincinnati, USA: Environmental Protection Agency, 1975.
  • 10罗国芝,谭洪新,朱学宝.闭合循环水产养殖车间水处理核心单元的处理效率[J].大连水产学院学报,2008,23(1):68-72. 被引量:8

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中国农业气象
2009年 第3期

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