化工学报
化工學報
화공학보
JOURNAL OF CHEMICAL INDUSY AND ENGINEERING (CHINA)
2014年
8期
2940-2947
,共8页
朱悦%崔晓钰%韩华%孙慎德%李治华
硃悅%崔曉鈺%韓華%孫慎德%李治華
주열%최효옥%한화%손신덕%리치화
振荡热管%传热%相变%溶液%充液率
振盪熱管%傳熱%相變%溶液%充液率
진탕열관%전열%상변%용액%충액솔
pulsating heat pipe%heat transfer%phase change%solution%filling ratio
采用水、丙酮以及其二元混合工质对振荡热管进行实验研究,选取35%~70%充液率,10~100 W加热功率以及水/丙酮13:1、4:1、1:1、1:4、1:13配比,将实验数据与混合工质物性、相变特点结合以研究其振荡热管传热性能。结果表明:混合溶液振荡热管启动所需功率小于水;小充液率时,除较低丙酮比例配比(如水/丙酮13:1混合工质)以外,混合工质比纯工质振荡热管不容易烧干,纯工质振荡热管在50 W时热阻就已经上升到较高数值,而混合工质振荡热管在同样的功率则维持着较低的热阻。在丙酮中加入少量水(如水/丙酮1:13混合工质)能有效改善振荡热管烧干情况,然而,少量丙酮与水混合而成的工质(如水/丙酮13:1混合工质)对振荡热管烧干情况的改善不明显;大充液率时,混合工质振荡热管的传热性能要弱于纯工质,在35~50 W,纯工质振荡热管热阻都低于混合工质,而在较大加热功率(50~100 W),水与混合工质振荡热管仍保持着较明显的热阻差。对混合工质振荡热管的传热性能的分析可为今后更深入研究其工作机理以及传热特性理论模型的建立提供参考。
採用水、丙酮以及其二元混閤工質對振盪熱管進行實驗研究,選取35%~70%充液率,10~100 W加熱功率以及水/丙酮13:1、4:1、1:1、1:4、1:13配比,將實驗數據與混閤工質物性、相變特點結閤以研究其振盪熱管傳熱性能。結果錶明:混閤溶液振盪熱管啟動所需功率小于水;小充液率時,除較低丙酮比例配比(如水/丙酮13:1混閤工質)以外,混閤工質比純工質振盪熱管不容易燒榦,純工質振盪熱管在50 W時熱阻就已經上升到較高數值,而混閤工質振盪熱管在同樣的功率則維持著較低的熱阻。在丙酮中加入少量水(如水/丙酮1:13混閤工質)能有效改善振盪熱管燒榦情況,然而,少量丙酮與水混閤而成的工質(如水/丙酮13:1混閤工質)對振盪熱管燒榦情況的改善不明顯;大充液率時,混閤工質振盪熱管的傳熱性能要弱于純工質,在35~50 W,純工質振盪熱管熱阻都低于混閤工質,而在較大加熱功率(50~100 W),水與混閤工質振盪熱管仍保持著較明顯的熱阻差。對混閤工質振盪熱管的傳熱性能的分析可為今後更深入研究其工作機理以及傳熱特性理論模型的建立提供參攷。
채용수、병동이급기이원혼합공질대진탕열관진행실험연구,선취35%~70%충액솔,10~100 W가열공솔이급수/병동13:1、4:1、1:1、1:4、1:13배비,장실험수거여혼합공질물성、상변특점결합이연구기진탕열관전열성능。결과표명:혼합용액진탕열관계동소수공솔소우수;소충액솔시,제교저병동비례배비(여수/병동13:1혼합공질)이외,혼합공질비순공질진탕열관불용역소간,순공질진탕열관재50 W시열조취이경상승도교고수치,이혼합공질진탕열관재동양적공솔칙유지착교저적열조。재병동중가입소량수(여수/병동1:13혼합공질)능유효개선진탕열관소간정황,연이,소량병동여수혼합이성적공질(여수/병동13:1혼합공질)대진탕열관소간정황적개선불명현;대충액솔시,혼합공질진탕열관적전열성능요약우순공질,재35~50 W,순공질진탕열관열조도저우혼합공질,이재교대가열공솔(50~100 W),수여혼합공질진탕열관잉보지착교명현적열조차。대혼합공질진탕열관적전열성능적분석가위금후경심입연구기공작궤리이급전열특성이론모형적건립제공삼고。
Experiments of pulsating heat pipes (PHP) were conducted, with water, acetone and water/acetone binary mixtures at different ratios (13:1, 4:1, 1:1, 1:4, 1:13) under various filling ratios (35%-70%) and heat inputs (10-100 W). The experimental results were analyzed with the feature of physical property and phase change for mixture. The results show that because of lower boiling point, specific heat and latent heat for evaporation, the mixture solution requires lower heating power to initial PHP than water. At low filling ratios, compared to mixtures except that with relatively low acetone concentration (e.g. water/acetone 13:1), pure working fluids are relatively easier to dry out in PHP. With the heat input of 50 W, PHPs with pure working fluid are dried, while those with mixtures maintain relatively low thermal resistance. The mixture with a little water (e.g. water/acetone 1:13) can significantly improve the dry state in PHP, while that with a little acetone (e.g. water/acetone 13:1) does not significantly improve the dry situation. At high filling ratios, heat transfer performance of PHP with pure working fluids are better than mixtures. In the range from 35 W to 50 W, the PHPs with pure working fluids present lower thermal resistance. At higher heat input (50-100 W), the PHP with water has lower thermal resistance compared to that with mixture. The study on heat transfer performance of PHP provides references for further research on the heat transfer mechanism of PHP and establishment of theoretical models on heat transfer characteristics.
