新型传染病房通风空调方案的研究
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摘要
本论文针对以SARS为代表的烈性呼吸道传染病的传播特性,对传染病房的空调通风方式开展研究,以解决室内气流组织的合理分布,无害化排风以及系统的合理用能问题。文中综合应用计算流体力学的理论和方法模拟三维较复杂条件下隔离病房室内空气流场、浓度场以及温度场的湍流流动,在对数学模型及物理模型进行理论分析的基础上,对含湍流双方程模型及非均温强制对流的耦合方程组采用了联立迭代解方法,并使用了对流-扩散方程系数的计算法、SIMPLEC算法、交错网格法等,边界条件采用了的κ-ε占模型结合壁面函数的方法。并将数值模拟的结果采用计算机图形学的直观方式来表示多种气流组织方案的气流流型,由此证明本论文气流组织方案的合理性;同时通过比较、分析各种现有的杀菌消毒方法,提出一个针对传染病房使用特点的病房排风无害化的方案,并以实验数据来说明此种杀菌消毒处理的有效性;最后通过论述、计算比较,提出针对传染病房空调通风特点的合理的冷热回收措施。
This paper carries out some disquisition on the way of infection sickroom ventilation, in order to make the indoor-air distributing reasonble, extracted air inoffensive, and the air-condition energy- economical on the base of the pestiferous peculiarities of respiratory infections such as SARS. It simulates the airflow concentration and temperature structure of the isolated sickroom by using the theoretics and methods of CFD. On the basis of the theoretical analysis of physical and mathematical model, the iterative method is adopted to the conjugated governing equations, and the numeration of the coefficient to the convection-diffusion equation, SIMPLEC algorism, staggered grid method are used, and so on. K-e turbulence model linked with the wall function are applied to the boundary condition. The results of numerical simulation for many different kinds of airflow are expressed in streamline chart of airflow structure through the computer graphics to prove the rationality of the flow structure in this paper,
and some kinds of methods for sterilizing will be comparing and analyzing to confirm a best method to listerize the extracted air from sickrooms, proving it possible by data from experiments. Then, the paper comes out some methods about energy reclaim from the air by dissertation calculating and comparing.
This paper carries out some disquisition on the way of infection sickroom ventilation, in order to make the indoor-air distributing reasonble, extracted air inoffensive, and the air-condition energy- economical on the base of the pestiferous peculiarities of respiratory infections such as SARS. It simulates the airflow concentration and temperature structure of the isolated sickroom by using the theoretics and methods of CFD. On the basis of the theoretical analysis of physical and mathematical model, the iterative method is adopted to the conjugated governing equations, and the numeration of the coefficient to the convection-diffusion equation, SIMPLEC algorism, staggered grid method are used, and so on. K-e turbulence model linked with the wall function are applied to the boundary condition. The results of numerical simulation for many different kinds of airflow are expressed in streamline chart of airflow structure through the computer graphics to prove the rationality of the flow structure in this paper,
and some kinds of methods for sterilizing will be comparing and analyzing to confirm a best method to listerize the extracted air from sickrooms, proving it possible by data from experiments. Then, the paper comes out some methods about energy reclaim from the air by dissertation calculating and comparing.
引文
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2.2003年5月17日全球SARS疫情报告[N]中国卫生部网站
3.“非典”病原体发现过程纪实-WHO官员亲述追查病毒历程[N] 2003.4.22生物通网站
4.全球联手离攻克“非典”还有多久[N]2003.4.28 生物通网站
5.建造“非典”安全隔离病房迫在眉睫——南京大学、南京天惠利净化工程有限公司合力研制出“全负压”安全系统[N] 中国新闻网2003.7.21
6.“非典安全隔离病房”通过专家论证[N] 人民网2003.05.14
7.“非典防治负压无菌隔离室”科研方案.江苏精亚集团净化工程设计研究所.2003.8
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37.魏学孟等.洁净室气流组织数值模拟方法比较.洁净与空调技术.2002,1:3~5
38.徐玉党等.封闭空间内的气流数值模拟.应用科学学报.2003,9
39.非典型肺炎疫情通报2003.5.17中国卫生部网站
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41.全世界支援中国抗击“非典”[N]参考消息2003.5.17
42.对中国旅客采取限制的国家增加到109个[N]中国青年报2003.5
43.卫生部最后一次公布每日疫情:内地无非典病人[N]中新网2003.8.16
44.WHO官员表示:全球非典疫情己近尾声[N]新华网2003.6.12
45.非典时期空调怎么用?专家推荐四大绝招[N]中国新闻网2003.5.24
46.专家:非典的出现与生态环境变化关系密切[N] 新华网2003.6.10
47.低温和相对湿度高有利于非典病毒扩散传播[N] 新华网 2003.6.11
48.北京协和医院:非典不是借口,弊端才是原因[N]http://www.healthoo.com2003.6.10
49.香港工程师学会提出非典病房新通风方案[N]人民网 2003.6.10
50.周宏 李沉 被逼无奈VS积极革新 非典引发建筑改良[N]北京青年报2003.6.12
51.马宗廉 减少医务人员感染非典的两条建议[N] 中国网2003.4.24
52.传染病医院建筑设计受关注[N] 产经网-中华建筑报2003.6.9
53.切断空调通风传染途径[N]山西日报2003.5.20
54.反思非典影响 建筑空调该当何“罪”?[N]北京晨报 2003.6.6
55.建筑空调通风系统预防非典确保安全使用应急管理措施 [N] 产经网-中华建筑报2003.6.2
56.建筑空调通风系统应急管理措施 [N] 慧聪暖通商务网 2003.8.21
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2.2003年5月17日全球SARS疫情报告[N]中国卫生部网站
3.“非典”病原体发现过程纪实-WHO官员亲述追查病毒历程[N] 2003.4.22生物通网站
4.全球联手离攻克“非典”还有多久[N]2003.4.28 生物通网站
5.建造“非典”安全隔离病房迫在眉睫——南京大学、南京天惠利净化工程有限公司合力研制出“全负压”安全系统[N] 中国新闻网2003.7.21
6.“非典安全隔离病房”通过专家论证[N] 人民网2003.05.14
7.“非典防治负压无菌隔离室”科研方案.江苏精亚集团净化工程设计研究所.2003.8
8.江亿.SARS在空气中传播规律研究.江苏省暖通空调制冷学会2003年年会论文集.苏州.2003.11
9.沈晋明等.隔离病房与SARS病房通风空调设计.暖通空调.2003,4:10~14
10.许钟麟.空气洁净技术原理.北京:科学出版社.2002
11.赵彬等.室内人体飞沫传播的数值研究.暖通空调.2003,6:34~36
12.赵荣义等.空气调节.北京:中国建筑工业出版社 1994
13.陶文铨.数值传热学.第二版.西安:西安交通大学出版社.2001
14.赵彬等.生物颗粒在相邻房间运动的数值研究.暖通空调.2003,6:31~33
15.颜伟.CFD技术在百级洁净手术室设计中的应用.建筑热能通风空调.2002,6:56~62
16.伍小亭.关于SARS医院空调通风系统的思考与设计实践.暖通空调.2003,5:6~11
17.张寅平等.空调系统生物污染防治方法概述.暖通空调.2003,6:41~46
18.孙俊等.消毒技术与应用.北京:化学工业出版社.2003
19.张辰等.紫外线消毒系统的设计.给水排水.2004,3:25~27
20.储金宇等.臭氧技术及应用.北京.化学工业出版社.2002
21.陆耀庆,主编.实用供热空调设计手册.北京:中国建筑工业出版社,1993
22.徐景峰等.板翅式全热交换器应用于分散独立空调系统中的探讨.建筑热能通风空调.1999,1:33~36
23.黄文胜等.热管技术与建筑节能(Ⅰ)——热管节能应用.建筑与饭店节
能.2004,1:60~64
24.龙惟定等.“非典”引出的对空调的反思.暖通空调.2003,6:8~12
25.殷平.室内环境的安全性和独立新风系统.暖通空调.2003,6:20~30
26.赵彬等.室内不同通风方式下生物颗粒的分布比较.暖通空调.2003,6:37~40
27.李震等.带有溶液热回收器的新风空调机.暖通空调.2003,6:55~57
28.张小松等.板翅换热器用于空调系统排风能量回收的研究.通风除尘.1998,3:4~7
29.孙志高等.空调系统热回收节能分析.北京节能.2000,2:20~22
30.张荣荣等.空调系统中全热回收设备的节能分析.建筑热能通风空调.2000,4:22~24
31.陈赤等.排风热回收系统的探讨.应用能源技术.2001,4:22~23
32.程锁明等. 洁净手术室中可控污染源大小的确定.洁净与空调技术.1998,4:25~28
33.魏学孟等.两种单向流洁净手术室的比较.洁净与空调技术.1999,3:9~19
34.陶文铨.计算流体力学与传热学.北京:中国建筑工业出版社.1992
35.帕坦卡[美].传热与流体流动的数值计算.第一版.北京:科学出版社.1984
36.江苏省暖通空调制冷学会2003年年会论文集.苏州.2003.11
37.魏学孟等.洁净室气流组织数值模拟方法比较.洁净与空调技术.2002,1:3~5
38.徐玉党等.封闭空间内的气流数值模拟.应用科学学报.2003,9
39.非典型肺炎疫情通报2003.5.17中国卫生部网站
40.WHO首次公布非典病毒存活率分析结果[N]2003.5.6生物通网站
41.全世界支援中国抗击“非典”[N]参考消息2003.5.17
42.对中国旅客采取限制的国家增加到109个[N]中国青年报2003.5
43.卫生部最后一次公布每日疫情:内地无非典病人[N]中新网2003.8.16
44.WHO官员表示:全球非典疫情己近尾声[N]新华网2003.6.12
45.非典时期空调怎么用?专家推荐四大绝招[N]中国新闻网2003.5.24
46.专家:非典的出现与生态环境变化关系密切[N] 新华网2003.6.10
47.低温和相对湿度高有利于非典病毒扩散传播[N] 新华网 2003.6.11
48.北京协和医院:非典不是借口,弊端才是原因[N]http://www.healthoo.com2003.6.10
49.香港工程师学会提出非典病房新通风方案[N]人民网 2003.6.10
50.周宏 李沉 被逼无奈VS积极革新 非典引发建筑改良[N]北京青年报2003.6.12
51.马宗廉 减少医务人员感染非典的两条建议[N] 中国网2003.4.24
52.传染病医院建筑设计受关注[N] 产经网-中华建筑报2003.6.9
53.切断空调通风传染途径[N]山西日报2003.5.20
54.反思非典影响 建筑空调该当何“罪”?[N]北京晨报 2003.6.6
55.建筑空调通风系统预防非典确保安全使用应急管理措施 [N] 产经网-中华建筑报2003.6.2
56.建筑空调通风系统应急管理措施 [N] 慧聪暖通商务网 2003.8.21
57.吴宪宏 王金静 防治SARS的几点看法 [N] 2003.5.26生物通网站
58.王松汉等.板翅式换热器.北京.化学工业出版社.1984
59.靳明聪等.热管及热管换热器.重庆.重庆大学出版社.1986
60.郎逵等.热管技术与应用.沈阳.辽宁科学技术出版社.1984
61.秦叔经等.换热器.北京.化学工业出版社.2003
62.钱颂文等.换热器设计手册.北京.化学工业出版社.2002
63.欧阳金练等.对 SARS 病房建设中有关安全等级的浅见.洁净与空调技术.2003,2:20~24
64.罗清海等.热管技术在建筑节能中的工程应用(上).节能环保技术.2003,11:41~44
65.黄雪莲.空调房间内的三维非均温气流组织的数值研究,南京理工大学硕士论文.2003
66. Chun-The Li, Huan-Kai Zhuang, Lien-Te Hsieh, Wen-Jhy Lee, Meng-Chun Tsao. PAH emission from the incineration of three plastic wastes. ENVIRONMENT INTERNATIONAL. 2001, 27(1): 61~67
67. ASHRAE Standard 62-1999, Ventilation for Acceptable Indoor Air Quality, Atlanta, 1999
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