期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

某报告厅利用自然冷源被动通风降温的理论计算与模拟分析 被引量:2

Theoretical Arithmetic and Simulation Analysis of Using Natural Cold Source for an Auditorium
下载PDF
导出
摘要 该文拟利用被动复合式下向通风降温技术在过渡季节对武汉某高校报告厅室内热环境进行研究,首先根据武汉市气候条件确定过渡季节该报告厅的室内外设计参数,然后通过理论计算确定报告厅采用该技术通风降温的可行性,最后利用计算流体力学(CFD)软件Airpak对过渡季节室内气流组织进行模拟和分析,验证该设计方案的通风效果。由于报告厅进深较大,为了保证其室内温度和风速分布均匀,该文分别对单向和双向两种送排风方案进行了比较研究,结果证明该系统能够替代常规空调解决武汉地区过渡季节利用自然冷源对报告厅的通风降温,不仅节约了能源,还改善了室内空气品质。 Passive hybrid downdraught cooling technique is supposed to be used in a schematic design of university auditorium in Wuhan transition season.Firstly the indoor and outdoor design parameter is set;Secondly the feasibility of using PHDC technique is discussed according to theoretical arithmetic;Lastly,according to Airpak CFD simulation and analysis,the indoor ventilation effect is checked.Because the auditorium is deep-plan,single-sided and double-sided ventilation schemes were compared in this study in order to get evenness index of the indoor temperature and wind velocity.The result proves that PHDC system can replace conventional air-conditionings to solve auditoriums ventilation by using natural cold source during transition season in Wuhan.Not only can energy be saved,but also can indoor air quality be improved.
作者 邱静 查静 雷飞
机构地区 华中科技大学建筑与城市规划学院 华中科技大学环境工程学院
出处 《华中建筑》 2012年第1期68-72,共5页 Huazhong Architecture
基金 国家自然科学基金项目(编号:50978110)
关键词 被动式下向通风降温技术(PHDC) 过渡季节 室内外设计参数 方案设计 模拟分析 Passive hybrid downdraught cooling PHDC Transition season Indoor and outdoor design parameter Schematic design Simulation analysis
分类号 TU834.35 [建筑科学—供热、供燃气、通风及空调工程]
  • 相关文献

参考文献9

二级参考文献39

  • 1清华大学建筑节能研究中心.中国建筑节能年度发展研究报告2009[M].北京:中国建筑工业出版社,2009.
  • 2M. Bahadori. An improved design of wind towers for natural ventilation and passive cooling[J]. Solar Energy voI. 35, 1985: 119-129.
  • 3S. Alvarez , Rodriauez. The Avenue of Europe at Expo'92 :Application of cool towers [C]. Seville: Architecture and Urban Space, presented at 9th PLEA International Conference, Seville Spain, 1991.
  • 4S.A.E.A.Rodriguez, R. Martin. Water drops as a naturalcooling resource-physical principles [C]. Seville: Architecture and Urban Space, Spain, 1991.
  • 5D. Pearlmutter, E. Erell, and Y. Etzion. A multi-stage down-draft evaporative cool tower for semi-enclosed spaces: Experiments with a water spraying system [J]. Solar Energy, vol. 82, 2008: 430-440.
  • 6G Papagiannopoulos, Ford Brian. Evaporative cooling using porous ceramic bricks: experimental results from Greece[C]. Santiago:20th PLEA International Conference: rethinking development-are we producing a people oriented habitat, Chile, 2003.
  • 7R. Schiano-Phan. The development of passive downdraught evaporative cooling systems using porous ceramic evaporators and their application in residential buildings [C]. Eindhoven:the 21th conference on passive and low energy architecture, the Netherlands, 2004.
  • 8Ford Brian. Passive Downdraught evaporative cooling [J].principles and practice, Environmental design, vol. 5, 2001 : 271-278.
  • 9Moura Raul, Ford Brian .ALTENER Final Report:Solar Passive Heating and Cooling Part 1 :Market Assessment of the Potential for Passive Downdraught Evaporative Cooling in Southern Europe [R]. London : [s.n.], 2000.
  • 10P. Torcellini, R. Judkoff, S. Hayter. Zion National Park Visitor Center: Significant Energy Savings Achieved through a Whole-Building Design Process [C].the American Council for an Energy- Efficient Economy (ACEEE) Summer Study on Energy Efficiency in Buildings. California 2002.

共引文献78

同被引文献17

  • 1Madhavi Indraganti. Adaptive use of natural ventilation for thermal comfort in Indian apartments [J]. Building and Environment,2010,45 (6): 1490-1507.
  • 2Numerical investigations of buoyancy-driven natural ventilation in a simple atrium building and its effect on the thermal comfort conditions[J]. Applied Thermal Engineering,2012,40:358-372.
  • 3Evaluation method of natual ventilation system based on thermal com- fort in China[J]. Energy and Buildings,2009,41 (1):67-70.
  • 4Nicol E Adaptive thermal comfort standards in the hot-humid tropics [J]. Energy and Buildings,2004,36(7):628-637.
  • 5C1BSE Guide AM10, Natural Ventilation in Non-Domestic Build- ings[M]. London: The Chartered Institution of Building Services Engineer- ing,2005.
  • 6Tobias Schulze, Ursula Eicker. Controlled natural ventilation for energy efficient buildings[J]. Energy and Buildings,2013,56:221-232.
  • 7Chenvidyakam T, Woods A W. The control of pre-cooted natural venti- lation [J]. Building Services Engineers Research and Technology,2004,25 (2):127-140.
  • 8M. Kavgic, et al. Analysis of thermal comfort and indoor air quality in a mechanically ventilated theatre [J]. Energy and Buildings,2008,40: 1334-1343.
  • 9刘先觉,王昕.江苏近代建筑[M].(第一版).南京:江苏科技出版社,2008.
  • 10Yuguo Li, Angelo Delsante, Jeff Symons. Prediction of natural ventila- tion in building with large openings [J]. Building and Environment, 2000,35:191-206.

引证文献2

二级引证文献6

华中建筑
2012年 第1期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部