化工学报
化工學報
화공학보
JOURNAL OF CHEMICAL INDUSY AND ENGINEERING (CHINA)
2014年
8期
2869-2875
,共7页
晁俊楠%吕俊复%杨海瑞%张缦%刘青
晁俊楠%呂俊複%楊海瑞%張縵%劉青
조준남%려준복%양해서%장만%류청
循环流化床%传热%两相流%接触热阻%停留时间
循環流化床%傳熱%兩相流%接觸熱阻%停留時間
순배류화상%전열%량상류%접촉열조%정류시간
circulating fluidized bed%heat transfer%two-phase flow%contact resistance%residence time
密相区内自由移动的煤颗粒表面传热系数是循环流化床锅炉设计和运行的重要参数。利用石墨球模拟煤颗粒,在小型流化床实验台上对由粒度较小的石英砂颗粒组成的密相区内自由移动的石墨球表面传热系数进行了测量。测量结果显示,随着流化风速的增加,石墨球表面传热系数首先升高,当流化风速达到某一临界值时,继续增大流化风速,传热系数将保持不变,从传热的角度证明了流化床内煤颗粒基本停留在乳化相内。在多数情况下,石墨球表面传热系数随床料粒度的增大而减小。而在较低流化风速的情况下,随着床料粒度的增大,石墨球表面传热系数呈先下降后升高的趋势。当流化风速和床料粒径保持不变时,石墨球表面传热系数随着石墨球直径的增大而减小,且下降的趋势随石墨球直径的增大而减弱。而随着床层高度的增加,石墨球表面传热系数将会略有升高。
密相區內自由移動的煤顆粒錶麵傳熱繫數是循環流化床鍋爐設計和運行的重要參數。利用石墨毬模擬煤顆粒,在小型流化床實驗檯上對由粒度較小的石英砂顆粒組成的密相區內自由移動的石墨毬錶麵傳熱繫數進行瞭測量。測量結果顯示,隨著流化風速的增加,石墨毬錶麵傳熱繫數首先升高,噹流化風速達到某一臨界值時,繼續增大流化風速,傳熱繫數將保持不變,從傳熱的角度證明瞭流化床內煤顆粒基本停留在乳化相內。在多數情況下,石墨毬錶麵傳熱繫數隨床料粒度的增大而減小。而在較低流化風速的情況下,隨著床料粒度的增大,石墨毬錶麵傳熱繫數呈先下降後升高的趨勢。噹流化風速和床料粒徑保持不變時,石墨毬錶麵傳熱繫數隨著石墨毬直徑的增大而減小,且下降的趨勢隨石墨毬直徑的增大而減弱。而隨著床層高度的增加,石墨毬錶麵傳熱繫數將會略有升高。
밀상구내자유이동적매과립표면전열계수시순배류화상과로설계화운행적중요삼수。이용석묵구모의매과립,재소형류화상실험태상대유립도교소적석영사과립조성적밀상구내자유이동적석묵구표면전열계수진행료측량。측량결과현시,수착류화풍속적증가,석묵구표면전열계수수선승고,당류화풍속체도모일림계치시,계속증대류화풍속,전열계수장보지불변,종전열적각도증명료류화상내매과립기본정류재유화상내。재다수정황하,석묵구표면전열계수수상료립도적증대이감소。이재교저류화풍속적정황하,수착상료립도적증대,석묵구표면전열계수정선하강후승고적추세。당류화풍속화상료립경보지불변시,석묵구표면전열계수수착석묵구직경적증대이감소,차하강적추세수석묵구직경적증대이감약。이수착상층고도적증가,석묵구표면전열계수장회략유승고。
The heat transfer between a dense bed and freely moving coal particles is of great significance for designing and operating a circulating fluidized bed (CFB) boiler. In this study, heat transfer coefficients were measured for graphite spheres freely moving in the dense bed of a lab-scale fluidized bed facility. It is shown that the heat transfer coefficient first increases as the fluidizing velocity rises initially from the minimum fluidizing velocity. After the fluidizing velocity reaching a critical point, the heat transfer coefficient remains invariant as the fluidizing velocity increases, which indicates that the burning coal particles remain in the emulsion phase in a CFB boiler. Under most conditions, the heat transfer coefficient decreases with the increase of bed material size, but at relatively low fluidizing velocities, after reaching a minimum value, the heat transfer coefficient increases with the bed material size. With fixed fluidizing velocity and bed material size, as the graphite diameter increases, the heat transfer coefficient declines and the dropping rate decreases. The heat transfer coefficient is higher for the graphite sphere floating in a higher bed.
