推进技术
推進技術
추진기술
JOURNAL OF PROPULSION TECHNOLOGY
2015年
4期
556-565
,共10页
茅晓晨%刘波%张鹏%邓熙%李民%巫骁雄
茅曉晨%劉波%張鵬%鄧熙%李民%巫驍雄
모효신%류파%장붕%산희%리민%무효웅
跨声速转子%机匣造型%二次泄漏%参数化%激波结构
跨聲速轉子%機匣造型%二次洩漏%參數化%激波結構
과성속전자%궤갑조형%이차설루%삼수화%격파결구
Transonic rotor%Casing contouring%Double-leakage%Parameterization%Shock wave structure
为了研究机匣优化造型对跨声速压气机的性能影响,以一跨声速转子为对象,基于数值方法对近设计点和近失速点下机匣造型前后转子叶尖处的流场和整体性能进行了对比分析。结果表明:机匣造型可以有效改善叶尖处的流动,提高压气机性能;提升了全工况范围内的效率,近设计点的效率提升了约0.25%,近失速点效率提升约0.33%;近失速点的压比提高约1.1%,而近设计点的压比基本不变。机匣造型降低了叶片前缘处的负荷,改变了激波的空间结构,使激波后移。在近设计点下,机匣造型提高了大部分叶展上的效率,机匣附近出现两个“低压环”区,由其产生的三维压力梯度效应改变了此位置附近子午面上的涡形态,流向正压力梯度减轻了叶尖处低速回流区的影响;叶尖处的流线流动更合理,“二次泄漏”现象消失。在近失速点下,机匣造型提高了大部分叶展上的总压比;叶尖处的涡形态没有发生变化,而涡核的位置发生了改变;造型使叶尖处的流线流动更加合理,但是“二次泄漏”现象并没有消失。
為瞭研究機匣優化造型對跨聲速壓氣機的性能影響,以一跨聲速轉子為對象,基于數值方法對近設計點和近失速點下機匣造型前後轉子葉尖處的流場和整體性能進行瞭對比分析。結果錶明:機匣造型可以有效改善葉尖處的流動,提高壓氣機性能;提升瞭全工況範圍內的效率,近設計點的效率提升瞭約0.25%,近失速點效率提升約0.33%;近失速點的壓比提高約1.1%,而近設計點的壓比基本不變。機匣造型降低瞭葉片前緣處的負荷,改變瞭激波的空間結構,使激波後移。在近設計點下,機匣造型提高瞭大部分葉展上的效率,機匣附近齣現兩箇“低壓環”區,由其產生的三維壓力梯度效應改變瞭此位置附近子午麵上的渦形態,流嚮正壓力梯度減輕瞭葉尖處低速迴流區的影響;葉尖處的流線流動更閤理,“二次洩漏”現象消失。在近失速點下,機匣造型提高瞭大部分葉展上的總壓比;葉尖處的渦形態沒有髮生變化,而渦覈的位置髮生瞭改變;造型使葉尖處的流線流動更加閤理,但是“二次洩漏”現象併沒有消失。
위료연구궤갑우화조형대과성속압기궤적성능영향,이일과성속전자위대상,기우수치방법대근설계점화근실속점하궤갑조형전후전자협첨처적류장화정체성능진행료대비분석。결과표명:궤갑조형가이유효개선협첨처적류동,제고압기궤성능;제승료전공황범위내적효솔,근설계점적효솔제승료약0.25%,근실속점효솔제승약0.33%;근실속점적압비제고약1.1%,이근설계점적압비기본불변。궤갑조형강저료협편전연처적부하,개변료격파적공간결구,사격파후이。재근설계점하,궤갑조형제고료대부분협전상적효솔,궤갑부근출현량개“저압배”구,유기산생적삼유압력제도효응개변료차위치부근자오면상적와형태,류향정압력제도감경료협첨처저속회류구적영향;협첨처적류선류동경합리,“이차설루”현상소실。재근실속점하,궤갑조형제고료대부분협전상적총압비;협첨처적와형태몰유발생변화,이와핵적위치발생료개변;조형사협첨처적류선류동경가합리,단시“이차설루”현상병몰유소실。
In order to study the effects of casing optimization contouring on the performance of transonic com?pressor,a transonic rotor was investigated with numerical simulation. Comparison and analysis of the flow field near the tip and the overall performance were performed before and after casing contouring near the design point and near the stall point. The results show that casing contouring could improve the tip flow field and the compres?sor performance. It is found that the efficiency was improved at the whole working condition by about 0.25%near the design point and 0.33% near the stall point. The total pressure ratio was improved by about 1.1% near the stall point,however,the total pressure ratio remained unchanged near the design point. Casing contouring reduced the loads at the leading edge of the blades and changed the 3D structure of shock wave by making it move back?ward slightly. Near the design point,casing contouring improved the efficiency at most of blade span. After casing contouring,two low pressure circles appeared near the casing which produced the 3D pressure gradient effects and this changed the vortex form in meridional surface near the circles,and it mitigated the effects of the low ve?locity recirculation zone because of the forward direction gradient. The streamline at the tip became more reason?able and the double-leakage phenomenon disappeared. Near the stall point,casing contouring improved the total pressure ratio at most of blade span and the vortex form did not change,but the position of vortex core changed. The streamline at the tip became more reasonable,while the double-leakage phenomenon did not vanish.
