太阳辐射对直升机整机红外辐射特性影响的数值研究

Numerical investigation of solar radiation effects on helicopter infrared radiation characteristics

  • 摘要: 太阳辐射对飞行中的直升机局部蒙皮有加热作用,从而改变整机红外辐射的分布特征。构建了包含直升机机身蒙皮、主旋翼、发动机机匣以及排气系统的物理模型,综合考虑发动机机匣、排气系统与发动机舱蒙皮的换热,耦合直升机前飞来流、旋翼下洗气流、尾桨气流,以时刻、季节、直升机朝向为变量,计算分析太阳辐射对直升机8~14 μm波段红外辐射特性的作用规律。计算结果表明:夏季正午太阳直射可使机身向阳面整体升温20 K以上,局部最高可达25 K。直升机向阳面机身蒙皮8~14 μm波段红外辐射强度在全天变化趋势呈山峰状,其峰值出现在12点前后。越靠近机身顶部向阳面,太阳辐射对8~14 μm波段红外辐射强度增强作用越显著,最高可达25%。以冬季为基准,秋分、春分、夏至时的整机红外辐射分别增加7%、11%、21%左右。除夏季外,其他季节的机身两侧8~14 μm波段红外辐射强度分布都呈现不对称性,春、秋两季两侧相差在5%左右,冬季在6.5%左右。整体上,夏季上午10点的太阳辐射对不同飞行方向的直升机8~14 μm波段红外辐射强度分布影响较小。

     

    Abstract:
      Objective  The development of long-wave infrared radiation imaging technology is more and more threatening to helicopter. The sources of helicopter long-wave infrared radiation include the infrared radiation of the helicopter's own power system and its energy transfer with the engine compartment as well as the local heating of the fuselage by solar radiation. A large number of experiments and numerical analyses have been carried out on the highly efficient ejection blending system and infrared suppressor, which can effectively reduce the infrared radiation of the helicopter itself. Solar radiation has a heating effect on the local skin of the helicopter in flight, thus changing the infrared radiation distribution characteristics of the whole aircraft, but it is often ignored in numerical simulation calculation, and there are relatively few studies on the characteristics of solar radiation and infrared radiation of the whole aircraft considering various factors. Therefore, it is necessary to carry out the research on the effects of solar radiation on the fuselage infrared radiation characteristic.
      Methods  A physical model including helicopter fuselage skin, main rotor, engine casing and exhaust system was constructed to establish a structured and unstructured hybrid grid (Fig.6). The heat transfer of engine casing (Tab.1), exhaust system (Tab.2) and engine compartment skin is comprehensively considered, coupled with the helicopter forward incoming flow, rotor downwash flow and tail rotor flow (Fig.5). The solar radiation is simulated by the equation of normal direct irradiation applying the fair weather conditions method. A forward-backward ray-tracing method is used to calculate the helicopter infrared radiation.
      Results and Discussions  The whole helicopter model including the engine casing and the exhaust infrared suppressor is simulated and calculated (Fig.3). In the calculation of the flow field, the mixed flow field including the forward incoming flow, the main rotor downwash flow, the exhaust jet flow and the tail rotor flow are considered (Fig.4). With time, season and helicopter flight direction as variables, different solar radiation loading conditions are set (Fig.8-10). The detection points are evenly arranged on the horizontal, transverse and longitudinal detection planes (Fig.7), to calculate and analyze the effect of solar radiation on the infrared radiation characteristics of helicopter in 8-14 μm band.
      Conclusions  The calculation results show that the direct sunlight at noon in summer can increase the overall temperature of the fuselage to the sun side by more than 20 K, and the local maximum temperature can be increased by 25 K. The infrared radiation intensity of 8-14 μm band on the sun side of the helicopter fuselage showed a peak-like trend throughout the day, and its peak appeared around 12 o 'clock. The closer to the top side of the fuselage is, the more significant the enhancement effect of solar radiation on the infrared radiation intensity of 8-14 μm band is, up to 25%. Taking winter as the benchmark, the infrared radiation of the whole aircraft at the autumn equinox, spring equinox and summer solstice increases by about 7%, 11% and 21% respectively. Except summer, the infrared radiation intensity distribution of 8-14 μm band on both sides of the fuselage in other seasons presents asymmetry, and the difference between the two sides is about 5%. On the whole, the solar radiation at 10 am in summer has little effect on the infrared radiation intensity distribution of 8-14 μm band of helicopters in different flight directions.

     

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