陕西科技大学学报(自然科学版)
陝西科技大學學報(自然科學版)
협서과기대학학보(자연과학판)
JOURNAL OF SHAANXI UNIVERSITY OF SCIENCE & TECHNOLOGY
2009年
3期
40-45
,共6页
崔国根%丁静%杨晓西%杨建平
崔國根%丁靜%楊曉西%楊建平
최국근%정정%양효서%양건평
硅胶除湿转轮%显热效率%潜热效率%除湿性能系数
硅膠除濕轉輪%顯熱效率%潛熱效率%除濕性能繫數
규효제습전륜%현열효솔%잠열효솔%제습성능계수
silica-gel desiccant wheel%energy efficiency%exergy efficiency%dehumidification coefficient of performance
讨论了能量第一定律和第二定律在除湿转轮中的应用,分析了除湿转轮在几何尺寸、运行状态一定的情况下能量效率和火用效率,并建立了除湿转轮的火用效率模型.以显热效率、潜热效率和除湿性能系数以及火用效率作为评价指标,通过对除湿转轮的一维单通道传热传质模型实验分析了影响硅胶除湿转轮火用效率及除湿性能的因素,研究了运行参数(处理空气进口湿度、温度及再生温度)对转轮除湿性能的影响.实验研究发现在近工况下,硅胶除湿转轮除湿性能系数在再生温度为100 ℃时为最佳,同时火用效率随着再生温度的升高而降低,在100 ℃时趋于平缓.研究同时表明提高进口处理空气的温度、湿度能够提高除湿转轮的显热效率和潜热效率,但是由于进口温度的升高导致空气的容湿能力提高而使得除湿性能系数降低.
討論瞭能量第一定律和第二定律在除濕轉輪中的應用,分析瞭除濕轉輪在幾何呎吋、運行狀態一定的情況下能量效率和火用效率,併建立瞭除濕轉輪的火用效率模型.以顯熱效率、潛熱效率和除濕性能繫數以及火用效率作為評價指標,通過對除濕轉輪的一維單通道傳熱傳質模型實驗分析瞭影響硅膠除濕轉輪火用效率及除濕性能的因素,研究瞭運行參數(處理空氣進口濕度、溫度及再生溫度)對轉輪除濕性能的影響.實驗研究髮現在近工況下,硅膠除濕轉輪除濕性能繫數在再生溫度為100 ℃時為最佳,同時火用效率隨著再生溫度的升高而降低,在100 ℃時趨于平緩.研究同時錶明提高進口處理空氣的溫度、濕度能夠提高除濕轉輪的顯熱效率和潛熱效率,但是由于進口溫度的升高導緻空氣的容濕能力提高而使得除濕性能繫數降低.
토론료능량제일정률화제이정률재제습전륜중적응용,분석료제습전륜재궤하척촌、운행상태일정적정황하능량효솔화화용효솔,병건립료제습전륜적화용효솔모형.이현열효솔、잠열효솔화제습성능계수이급화용효솔작위평개지표,통과대제습전륜적일유단통도전열전질모형실험분석료영향규효제습전륜화용효솔급제습성능적인소,연구료운행삼수(처리공기진구습도、온도급재생온도)대전륜제습성능적영향.실험연구발현재근공황하,규효제습전륜제습성능계수재재생온도위100 ℃시위최가,동시화용효솔수착재생온도적승고이강저,재100 ℃시추우평완.연구동시표명제고진구처리공기적온도、습도능구제고제습전륜적현열효솔화잠열효솔,단시유우진구온도적승고도치공기적용습능력제고이사득제습성능계수강저.
Dehumidification capacity and exergy efficiency of desiccant wheel are studied and researched in this paper. Energy-based effectiveness is employed to evaluate the performance of silica-gel desiccant wheel, such as sensible heat efficiency, latent heat efficiency and dehumidification coefficient of performance. And the exergy efficiency model is also presented, and the exergy and exergy efficiency of channel are analyzed using a one-dimensional coupled with heat and mass transfer mathematical model and experimental setup based on adsorption channel. The factors of influence on the performance and exergy efficiency, the regenerative temperature, the temperature and humidity of the inlet process air, are investigated using exergy efficiency model, and results show the exergy efficiency is lower because the proportion of chemical exergy component. It shows that the optimal regeneration temperature is 100 ℃ for silica gel wheel. Meanwhile, with the increase of regenerative temperature, its energy efficiency reduces contrarily. It also shows that the higher the temperature and humidity of the inlet process air are, and the higher the latent efficiency is. But with the increase of the inlet process air temperature, the air can contain more humidity so that dehumidification coefficient of performance (DCOP) is reduced.