|
|
- 2015
在轨运行低温液氢箱体蒸发量计算与增压过程研究
|
Abstract:
为了研究低温箱体在外部漏热下的在轨增压过程,采用FLUENT软件中的流体体积(VOF)方法,对AS??203飞行试验中低温液氢箱体进行数值模拟。通过对默认可实现k?拨拍P徒?行参数调整,并与试验结果对比发现,调整参数后的模型可较好地预测低温液氢箱体在轨增压过程。因此,采用该模型对所研究低温液氢箱体进行500 s增压数值模拟,计算结果表明:与气枕接触的壁面漏热绝大部分用来使箱体增压,小部分用来产生相变;在外部漏热下低温箱体压增速率约49.6 Pa/s,箱体气液界面的蒸发率约为0.101 6%/h;在一定的微重力水平下,自然对流作用依然存在,其对流强弱主要取决于箱体尺寸以及外部漏热热流大小;在整个模拟过程中,气枕区热分层较之液相区更为严重;随着重力水平的降低,表面张力的作用逐渐凸显,界面形状变为曲面。
To investigate the on??orbit pressurization of cryogenic storage tank, the volume of fluid method in FLUENT is chosen to simulate the AS??203 flight experimental liquid hydrogen tank. Improving the original realizable k?拨? turbulence model and comparing with the experiment data, the modified model successfully predicts the on??orbit pressurization process of cryogenic liquid hydrogen storage tank. Therefore the calibrated realizable k?拨? model is adopted to research the liquid hydrogen storage tanks on??orbit pressurization for 500 seconds. The calculation shows that most of wall heat leakage increases the storage tank pressure, only a small part of external heat leakage facilitates vapor??liquid phase change. The pressure increase rate of the liquid hydrogen tank and the evaporation rate happened in the gas??liquid interfacial, for the effect of external heat leakage, are about 49.6 Pa/s and 0.1016%/hour respectively. Natural convection still exists under certain microgravity, and its intensity depends on the tank size and the external heat flux density. The thermal stratification of vapor region is more obvious than liquid region in the whole pressurization process. With the decreasing gravity level, the effects of surface tension are gradually prominent, and the gas??liquid interface shape becomes curved surface
| [1] | [12]陶文铨. 数值传热学 [M]. 2版. 西安: 西安交通大学出版社, 2005: 2??8. |
| [2] | [6]PANZARELLA C H, KASSEMI M. Self??pressurization of large spherical cryogenic tanks in space [J]. Journal of Spacecraft and Rockets, 2005, 42(2): 299??308. |
| [3] | [7]BARSI S, KASSEMI M. Numerical and experimental comparisons of the self??pressurization behavior of an LH2 tank in normal gravity [J]. Cryogenics, 2008, 48(3): 122??129. |
| [4] | [13]BRACKBILL J U, KOTHE D B, ZEMACH C. A continuum method for modeling surface tension [J]. Journal of Computational Physics, 1992, 100(2): 335??354. |
| [5] | [14]王磊, 厉彦忠, 李翠, 等. 液体火箭贮箱增压排液过程温度场数值研究 [J]. 航空动力学报, 2011, 26(8): 1893??1899. |
| [6] | WANG Lei, LI Yanzhong, LI Cui, et al. Numerical study on temperature distribution of tank pressurization process of liquid rocket during outflow [J]. Journal of Aerospace Power, 2011, 26(8): 1893??1899. |
| [7] | [1]CHATO D J. Cryogenic technology development for explorations missions [C]∥45th AIAA Aerospace Sciences Meeting and Exhibit. Washington, DC, USA: AIAA, 2007: 1??10. |
| [8] | [3]王赞社, 顾兆林, 冯诗愚, 等. 低温推进剂贮箱增压过程的传热传质数学模拟 [J]. 低温工程, 2008(6): 28??31. |
| [9] | WANG Zanshe, GU Zhaolin, FENG Shiyu, et al. Simulation of heat transfer and mass transfer in cryogenic propellant tank pressurization process [J]. Cryogenics, 2008(6): 28??31.[4]PANZARELLA C H, KASSEMI M. On the validity of purely thermodynamic descriptions of two??phase cryogenic fluid storage [J]. Journal of Fluid Mechanics, 2003, 484: 41??68. |
| [10] | [5]PANZARELLA C, PLACHTA D, KASSEMI M. Pressure control of large cryogenic tanks in microgravity [J]. Cryogenics, 2004, 44(6): 475??483. |
| [11] | [11]HIRT C W, NICHOLSB D. Volume of fluid (VOF) method for the dynamics of free boundaries [J]. Journal of Computational Physics, 1981, 39(1): 201??225. |
| [12] | [2]ZILLIAC G, KARABEYOGLU M A. Modeling of propellant tank pressurization [C]∥41th AIAA/ASME/ASEE Joint Propulsion Conference. Washington, DC, USA: AIAA, 2005: 1??25. |
| [13] | [8]GRAYSON G D, LOPEZ A, CHANDLER F O, et al. Cryogenic tank modeling for the Saturn AS??203 experiment [C]∥42nd AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit. Washington, DC, USA: AIAA, 2006: 1??7. |
| [14] | [9]MATTICK S J, LEE C P, HOSANGADI A, et al. Progress in modeling pressurization in propellant tanks [C]∥46th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit. Washington, DC, USA: AIAA, 2010: 1??13. |
| [15] | [10]KARTUZOVA O, KASSEMI M. Modeling interfacial turbulent heat transfer during ventless pressurization of a large scale cryogenic storage tank in microgravity [C]∥47th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit. Washington, DC, USA: AIAA, 2011: 1??18. |
