火箭推进
火箭推進
화전추진
JOURNAL OF ROCKET PROPULSION
2012年
5期
13-17
,共5页
发汗冷却%数值计算%多孔面板%氢氧火箭发动机%推力室
髮汗冷卻%數值計算%多孔麵闆%氫氧火箭髮動機%推力室
발한냉각%수치계산%다공면판%경양화전발동궤%추력실
transpiration cooling%numerical calculation%porous plate%H/O rocket engine%thrust chamber
为了研究氢氧火箭发动机推力室喷注器多孔面板的发汗冷却特性,采用一维非热平衡能量方程模型对其进行了数值传热计算,计算模型考虑了冷却剂氢的变物性和多孔结构内固体与流体之间的对流换特征。分析总结了多孔结构固体导热率、孔隙率、颗粒特征直径和燃烧室热流密度等因素对多孔面板发汗冷却的影响。研究结果表明,选择较高导热率的多孔面板制造材料能够降低燃气侧面板温度和减小面板温度梯度;孔隙率一般在0.1~0.2为宜;随着颗粒特征直径增大冷却剂与多孔结构固体之间的换热能力明显下降,燃气侧面板温度呈先降低后升高的趋势。
為瞭研究氫氧火箭髮動機推力室噴註器多孔麵闆的髮汗冷卻特性,採用一維非熱平衡能量方程模型對其進行瞭數值傳熱計算,計算模型攷慮瞭冷卻劑氫的變物性和多孔結構內固體與流體之間的對流換特徵。分析總結瞭多孔結構固體導熱率、孔隙率、顆粒特徵直徑和燃燒室熱流密度等因素對多孔麵闆髮汗冷卻的影響。研究結果錶明,選擇較高導熱率的多孔麵闆製造材料能夠降低燃氣側麵闆溫度和減小麵闆溫度梯度;孔隙率一般在0.1~0.2為宜;隨著顆粒特徵直徑增大冷卻劑與多孔結構固體之間的換熱能力明顯下降,燃氣側麵闆溫度呈先降低後升高的趨勢。
위료연구경양화전발동궤추력실분주기다공면판적발한냉각특성,채용일유비열평형능량방정모형대기진행료수치전열계산,계산모형고필료냉각제경적변물성화다공결구내고체여류체지간적대류환특정。분석총결료다공결구고체도열솔、공극솔、과립특정직경화연소실열류밀도등인소대다공면판발한냉각적영향。연구결과표명,선택교고도열솔적다공면판제조재료능구강저연기측면판온도화감소면판온도제도;공극솔일반재0.1~0.2위의;수착과립특정직경증대냉각제여다공결구고체지간적환열능력명현하강,연기측면판온도정선강저후승고적추세。
In order to investigate the transpiration cooling characteristics of H/O rocket engine thrust chamber injector porous plate, the one-dimensional local thermal non-equilibrium numerical model was adopted to conduct the heat transfer computation and analysis. The hydrogen coolant ther- too-physical properties varied with both temperature and pressure, and heat transfer between the porous media and coolant were considered for the computation model. The influence of porous media thermal conductivity, porosity, sphere diameter and heat flow density on porous plate transpiration cooling were analyzed. The investigation demonstrates that optimization of porous plate material with high thermal conductivity can reduce the gas side plate temperature and temperature gradient of porous plate. The porosity should be 0.1-0.2. The heat transfer capacity between the porous media and coolant is obviously reduced with the increase of sphere diameter, but the temperature of the gas side plate decreases at first and then increases.