红外与激光工程
紅外與激光工程
홍외여격광공정
INFRARED AND LASER ENGINEERING
2013年
6期
1399-1403
,共5页
王亚辉%王强%高磊%肖力平%徐力
王亞輝%王彊%高磊%肖力平%徐力
왕아휘%왕강%고뢰%초력평%서력
高超声速%气动热辐射%气动加热%光学窗口%钝锥体
高超聲速%氣動熱輻射%氣動加熱%光學窗口%鈍錐體
고초성속%기동열복사%기동가열%광학창구%둔추체
hypersonic%aero-thermo-radiation%aerodynamic heating%dome%blunt cone body
飞行器在大气层内高速飞行时,高速气体来流在飞行器顶端形成高温高压气体绕流,并对顶端光学探测窗口形成强烈气动加热,光学窗口温度急剧上升,高温气体和光学窗口的红外辐射对探测系统形成严重的气动热辐射效应,探测信噪比下降。针对非灰混合气体和光学窗口材料的辐射特点,采用介质辐射传输方法,模拟了钝锥球头外形头部且顶端安装探测窗口飞行器的气动热辐射,研究了气体和窗口热辐射随时间的发展及其与窗口材料的关系。结果表明,高温气体的热辐射与飞行器的运动状态关系密切,而光学窗口的热辐射随飞行时间增加而迅速增强,逐渐成为气动热辐射的主要因素,因此抑制光学窗口的温度上升速度和幅度是减弱气动热辐射的关键。
飛行器在大氣層內高速飛行時,高速氣體來流在飛行器頂耑形成高溫高壓氣體繞流,併對頂耑光學探測窗口形成彊烈氣動加熱,光學窗口溫度急劇上升,高溫氣體和光學窗口的紅外輻射對探測繫統形成嚴重的氣動熱輻射效應,探測信譟比下降。針對非灰混閤氣體和光學窗口材料的輻射特點,採用介質輻射傳輸方法,模擬瞭鈍錐毬頭外形頭部且頂耑安裝探測窗口飛行器的氣動熱輻射,研究瞭氣體和窗口熱輻射隨時間的髮展及其與窗口材料的關繫。結果錶明,高溫氣體的熱輻射與飛行器的運動狀態關繫密切,而光學窗口的熱輻射隨飛行時間增加而迅速增彊,逐漸成為氣動熱輻射的主要因素,因此抑製光學窗口的溫度上升速度和幅度是減弱氣動熱輻射的關鍵。
비행기재대기층내고속비행시,고속기체래류재비행기정단형성고온고압기체요류,병대정단광학탐측창구형성강렬기동가열,광학창구온도급극상승,고온기체화광학창구적홍외복사대탐측계통형성엄중적기동열복사효응,탐측신조비하강。침대비회혼합기체화광학창구재료적복사특점,채용개질복사전수방법,모의료둔추구두외형두부차정단안장탐측창구비행기적기동열복사,연구료기체화창구열복사수시간적발전급기여창구재료적관계。결과표명,고온기체적열복사여비행기적운동상태관계밀절,이광학창구적열복사수비행시간증가이신속증강,축점성위기동열복사적주요인소,인차억제광학창구적온도상승속도화폭도시감약기동열복사적관건。
The flow field before a hypersonic vehicle flying in the atmosphere consists of high temperature and high pressure gas. The temperature of the vehicle's optical dome rises rapidly due to aerodynamic heating. IR radiation of the high temperature gas and dome bring severe aero-thermo-radiation effects which decreases the SNR of the detection system. According to radiation characteristies of non-gray gas mixtures and dome materials, simulation of the aero-thermo-radiation of a blunt cone body vehicle with sphere dome ahead was proposed based on infrared radiation transfer model. And then, the development of aero-thermo-radiation with time and different dome material were studied. The experimental results show that the high temperature gas radiant intensity is closely interrelated with the vehicle' movement, and the dome radiation increases rapidly with time, which becomes major factor of the aero-thermo-radiation gradually. Thus, restraining the velocity and range of the dome's temperature rising is the key to weaken aero-thermo-radiation effects.
