期刊文献+

恒温恒湿空调系统的优化控制与性能模拟 被引量:15

Optimum Control Strategy and Performance Simulation of a Constant Temperature and Humidity Air-conditioning System
下载PDF
导出
摘要 针对传统恒温恒湿空调系统表冷器采用固定露点方法导致热湿补偿损失较大的缺点,采用热湿独立控制装置和PID分程控制方法,研制了一套恒温恒湿空调系统。在实验的基础上,利用TRNSYS 16软件建模,对系统在不同热湿负荷下的运行状况及节能效果进行了模拟分析。结果表明,该系统能自动调节表冷器冷冻水流量与温度,以及加热器或加湿器的投入量,实现对空气温湿度的独立控制,并达到设定的温湿度;在设计此类表冷器时,换热面积应该以较高的冷冻水进口温度(如12℃而不是通常的7℃)来进行计算。该系统节能效果显著,比传统系统在低温高湿工况下节能30%以上;在高温低湿工况下节能50%左右。 Due to the large energy compensation caused by the fixed dew point on the cooling coil(CC) in the conventional constant temperature and humidity air-conditioning system,a new system employing a temperature and humidity independent control device(THIC device) in the CC and a method of PID split-range control,is developed in this paper.Based on the experiment verification,the operation states and the energy saving effects of the system under different heat and moisture loads have been simulated by TRNSYS 16 software.The results show that under different working conditions,the system can automatically control air temperature and humidity independently with a high precision,by adjusting the mass flow rate and the temperature of the chilled water into the CC,and the output of the heater or the humidifier.In the design of such CC,the heat transfer area should be calculated under a higher inlet temperature of the chilled water(for example,12℃ instead of the usual 7℃).The system is energy-efficient with a rate of 30% under low temperature high humidity condition and about 50% under high temperature and low humidity condition,compared with the conventional system.
出处 《制冷学报》 CAS CSCD 北大核心 2012年第1期22-27,共6页 Journal of Refrigeration
基金 2008年浙江省第三批省级文物保护专项补助经费项目(614841)资助~~
关键词 热工学 恒温恒湿空调系统 热湿独立控制装置 PID分程控制 TRNSYS 节能 Pyrology Constant temperature and humidity air-conditioning system Temperature and humidity independent control device PID split-range control TRNSYS Energy saving
  • 相关文献

参考文献4

二级参考文献13

  • 1[2]Ahmed S Younus, Gandhidasan P. Thermodynamic analysis of liquid desiccants. Solar Energy, 1998, 62:11-18
  • 2[3]ASHRAE. Desiccant cooling and dehumidification. 1992.33-39
  • 3[4]ASHRAE.ASHRAE Handbook - Systems and Equipment. 2000
  • 4[6]Fu Lin, Jiang Yi, Yuan Weixing, et al. Influence of return water temperatures on the energy consumption of a district cooling system. Applied Thermal Engineering, 2001, 21(1):511-521
  • 5范逸之.Visual Basic与分布式测控系统[M].北京:清华大学出版社,2002..
  • 6张祉祜.制冷原理与设备.2000.
  • 7电子工业部第十设计研究院.空气调节设计手册,1995.
  • 8吴林,仲崇权,杨素英,牛德芳.一种基于RS-485总线的多路温度数据采集系统设计[J].测控技术,2001,20(4):11-13. 被引量:11
  • 9黄华江,吴国斌,戴迎春,袁渭康.一个用于化学热泵的分布式测控系统[J].仪表技术与传感器,2001(11):22-24. 被引量:1
  • 10刘广,王平,邢建春.利用串行口实现计算机对PLC的实时监控[J].电子产品世界,2002,9(06B):45-46. 被引量:4

共引文献90

同被引文献80

引证文献15

二级引证文献20

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