中国电机工程学报
中國電機工程學報
중국전궤공정학보
ZHONGGUO DIANJI GONGCHENG XUEBAO
2013年
35期
8-14
,共7页
郑树%罗自学%周怀春
鄭樹%囉自學%週懷春
정수%라자학%주부춘
W型锅炉%蒸发系统%分布参数%超临界%建模
W型鍋爐%蒸髮繫統%分佈參數%超臨界%建模
W형과로%증발계통%분포삼수%초림계%건모
W-shaped boiler%evaporation system%distributed parameters%supercritical%modeling
基于图像处理的温度检测信息,对超临界W型直流锅炉蒸发系统进行分布参数建模。建立的模型同时考虑了炉内热负荷分布和锅内工质物性分布的不均匀性,以预测对应工况下的壁面热流分布和壁温分布。仿真结果表明各热力参数在水冷壁上呈现明显的分布参数特性,并且其分布特性随着工况的变化而变化。发现W型火焰锅炉前墙存在3个高热流区,左墙最高壁温为459.85℃,且最大壁面温差为94℃。同时,数值计算结果与现场实测值进行了对比,理论推算与电厂实际运行结果相一致。模型既可用于在线预测,也可用于离线分析计算,对超临界W型锅炉的研究有一定的指导意义。
基于圖像處理的溫度檢測信息,對超臨界W型直流鍋爐蒸髮繫統進行分佈參數建模。建立的模型同時攷慮瞭爐內熱負荷分佈和鍋內工質物性分佈的不均勻性,以預測對應工況下的壁麵熱流分佈和壁溫分佈。倣真結果錶明各熱力參數在水冷壁上呈現明顯的分佈參數特性,併且其分佈特性隨著工況的變化而變化。髮現W型火燄鍋爐前牆存在3箇高熱流區,左牆最高壁溫為459.85℃,且最大壁麵溫差為94℃。同時,數值計算結果與現場實測值進行瞭對比,理論推算與電廠實際運行結果相一緻。模型既可用于在線預測,也可用于離線分析計算,對超臨界W型鍋爐的研究有一定的指導意義。
기우도상처리적온도검측신식,대초림계W형직류과로증발계통진행분포삼수건모。건립적모형동시고필료로내열부하분포화과내공질물성분포적불균균성,이예측대응공황하적벽면열류분포화벽온분포。방진결과표명각열력삼수재수랭벽상정현명현적분포삼수특성,병차기분포특성수착공황적변화이변화。발현W형화염과로전장존재3개고열류구,좌장최고벽온위459.85℃,차최대벽면온차위94℃。동시,수치계산결과여현장실측치진행료대비,이론추산여전엄실제운행결과상일치。모형기가용우재선예측,야가용우리선분석계산,대초림계W형과로적연구유일정적지도의의。
A distributed parameter model of evaporation system in a supercritical W-shaped once-through boiler was developed based on a 3-D temperature distribution. The mathematical model was formulated for predicting the distributions of the heat flux and the metal-surface temperature considering non-uniform distribution of the surface heat transfer and the frictional resistance coefficient simultaneously. Analyzed results indicate that the characteristics of these parameters are remarkably distributed and will change as the operation condition changes. The results show that the heat flux distribution on front water wall exist three high heat flux zones in the W-shaped boiler, the maximum metal tempertaure on left water wall is 459.85 ℃ and the maximum deviation of metal temperature is nearly 94 ℃ at different load. This distributed parameter model is fit for the in-situ operating status of the boiler. The model can be applied for online prediction or off-line calculation, which provides a reference on heat transfer of supercritical system.