化工进展
化工進展
화공진전
CHEMICAL INDUSTRY AND ENGINEERING PROGRESS
2013年
9期
2035-2042
,共8页
崔晓钰%于洋%朱悦%李治华%孙慎德%韩华
崔曉鈺%于洋%硃悅%李治華%孫慎德%韓華
최효옥%우양%주열%리치화%손신덕%한화
振荡热管%热物性%传热性能%热阻
振盪熱管%熱物性%傳熱性能%熱阻
진탕열관%열물성%전열성능%열조
pulsating heat pipes%thermal properties%heat transfer performance%thermal resistance
选取去离子水、甲醇、乙醇和丙酮为工质,考察不同工质不同充液率的振荡热管运行特征,寻找影响振荡热管传热性能的物性因素。结果表明:在小功率时,传热性能受是否启动振荡及振荡流速支配,与动力黏度密切相关;随加热功率增大,振荡流速加快,不同工质振荡热管温度振荡频率和幅度差别渐小,动力黏度和液态比热容、汽化潜热共同影响振荡热管传热性能;在大功率时,振荡流速较快,充注汽化潜热、比热容大的工质振荡热管传热性能更具优势。振荡热管和物性的关联分析可为认识不同情况下振荡热管的传热机理和工作特性、建立振荡热管理论模型提供参考。
選取去離子水、甲醇、乙醇和丙酮為工質,攷察不同工質不同充液率的振盪熱管運行特徵,尋找影響振盪熱管傳熱性能的物性因素。結果錶明:在小功率時,傳熱性能受是否啟動振盪及振盪流速支配,與動力黏度密切相關;隨加熱功率增大,振盪流速加快,不同工質振盪熱管溫度振盪頻率和幅度差彆漸小,動力黏度和液態比熱容、汽化潛熱共同影響振盪熱管傳熱性能;在大功率時,振盪流速較快,充註汽化潛熱、比熱容大的工質振盪熱管傳熱性能更具優勢。振盪熱管和物性的關聯分析可為認識不同情況下振盪熱管的傳熱機理和工作特性、建立振盪熱管理論模型提供參攷。
선취거리자수、갑순、을순화병동위공질,고찰불동공질불동충액솔적진탕열관운행특정,심조영향진탕열관전열성능적물성인소。결과표명:재소공솔시,전열성능수시부계동진탕급진탕류속지배,여동력점도밀절상관;수가열공솔증대,진탕류속가쾌,불동공질진탕열관온도진탕빈솔화폭도차별점소,동력점도화액태비열용、기화잠열공동영향진탕열관전열성능;재대공솔시,진탕류속교쾌,충주기화잠열、비열용대적공질진탕열관전열성능경구우세。진탕열관화물성적관련분석가위인식불동정황하진탕열관적전열궤리화공작특성、건립진탕열관이론모형제공삼고。
Deionized water,methanol,ethanol and acetone were chosen as working fluids to investigate operation and heat transfer characteristics of pulsating heat pipes (PHP). The experiment was designed to find out critical physical properties for the heat transfer of PHP under different conditions. The results showed that at small heating power,heat transfer depended on the speed of oscillation,and the key factor was kinetic viscosity. As the heating power increased,oscillatory flow accelerated accordingly,and the differences in frequency and amplitude of temperature oscillation gradually decreased,indicating the heat transfer of PHP was affected by kinetic viscosity,liquid specific heat and latent heat. As the heating power increased to a certain point,oscillatory flows of different WFs became faster and,at this stage,WFs of high latent heat and specific heat were preferable for heat transfer. The correlation study on the physical properties of WFs and the heat transfer performance of PHP may help to understand the heat transfer mechanism and operation characteristics of PHP at different situations and provide reference for the establishment of theoretical model.