PROGRESSES IN RESEARCH ON COUPLED ANALYSIS TECHNOLOGY FOR SPACE VEHICLE AND LAUNCH VEHICLES

QIU Jibao; ZHANG Zhengping; LI Haibo

doi:10.6052/1000-0992-11-203

Volume 42 Issue 4

Jul. 2012

Turn off MathJax

Article Contents

Article Navigation > Advances in Mechanics > 2012 > 42(4): 416-436

QIU Jibao, ZHANG Zhengping, LI Haibo. PROGRESSES IN RESEARCH ON COUPLED ANALYSIS TECHNOLOGY FOR SPACE VEHICLE AND LAUNCH VEHICLES[J]. Advances in Mechanics, 2012, 42(4): 416-436. doi: 10.6052/1000-0992-11-203

Citation:

QIU Jibao, ZHANG Zhengping, LI Haibo. PROGRESSES IN RESEARCH ON COUPLED ANALYSIS TECHNOLOGY FOR SPACE VEHICLE AND LAUNCH VEHICLES[J]. Advances in Mechanics, 2012, 42(4): 416-436. doi: 10.6052/1000-0992-11-203

Citation:

PDF( 6092 KB)

PROGRESSES IN RESEARCH ON COUPLED ANALYSIS TECHNOLOGY FOR SPACE VEHICLE AND LAUNCH VEHICLES

doi: 10.6052/1000-0992-11-203

Science and Technology on Reliability and Environment Engineering Laboratory, Beijing Institute of Structure and Environment Engineering, Beijing 100076, China

Funds: The project was supported by the Major Project of Chinese National Programs for Fundamental Research and the National Natural Science Foundation of China (11172046).

More Information

Corresponding author: QIU Jibao
Received Date: 2011-03-02
Rev Recd Date: 2011-12-28
Publish Date: 2012-07-25

Abstract

Abstract

With focus laid on loads analysis, some progresses of structural dynamics in the field of space vehicle design are summarized. The paper first presented some fundamental ideas of load analysis which has been applied in space vehicle / launch vehicle coupling systems. And then load analysis methods were explored in the following three directions:1) Approximate initial load analysis methods by means of basis excitation theory in which coupling effects of the space vehicle / launch vehicles are neglected;2) A branch modes synthesis method for the coupled space vehicle / launch vehicle system with the coupling effects taken into account. Based on the interface acceleration of constraint modes mass, the load estimation of the space vehicle / launch vehicle coupled system was derived analytically. Furthermore, if only static constraints modes mass is considered, the reduced equation (as a special case of this method) is actually identical to the equation derived by Chen using FEM. Furthermore, a new technique for space vehicle load transient analysis was also established. With the technique, previous analyzing results of space vehicle / launch vehicle coupling systems can be extended to new coupling systems between the same launch vehicle and a new space vehicles;3) A modal synthesis method for the space launch / launch vehicle coupled systems. Several modal synthesis methods were studied, the fixed-interface modal synthesis method was first presented，and the method was applied to Ariane-5 launch vehicle dynamic response analysis, a new method for deriving dynamic response of the space launch / launch vehicle system was then given based on coupling interface synthesis;Finally, verification techniques of the load analysis methods were elucidated. After a brief discussion of the importance of the verification techniques, a new technology of structure dynamic test simulation is proposed to combine the experimental results with the theoretical analyzing results. This is a set of new techniques for updating mathematics model, which is named as synthesis techniques based on the substructure experimental modeling. The approach has been applied to the modeling of such complex structures as a large strap-on launch vehicle Long March 2E (LM-2E) and a 40 T shaker system.The proposed techniques were demonstrated with LM-2E as follows: the predicted modes were derived before the modal test of real full scale LM-2E launch vehicle; and the modes were then compared with actual test results obtained thereafter. The two results turned out to be highly consistent between each other. The experiment proves that the modal parameters of the LM-2E had been successfully reproduced by the proposed modal test simulation techniques，and the reliability of the proposed techniques is thus verified. The vibration test simulation techniques of a 40 T shaker were also discussed. Key simulation techniques for the vibration test are summarized, including the modification technique for the shaker FEA mathematics model; the simulation technique of the table-board control for vibrating tests of a 40 T shaker system and the simulation technique of D satellite shaker vibration tests.
- structural dynamics,
- modal synthesis method,
- coupled load analysis,
- verification techniques of the load analysis,
- technology of test simulation

FullText(HTML)

References(65)

References

1 胡海昌. 加快从静态设计到动态设计的过渡. 宇航学报,1980, 1(2): 103-106

2 马兴瑞, 于登云, 韩增尧, 等. 星箭力学环境分析与试验技术研究进展. 宇航学报, 2006, 27(3): 323-331

3 马兴瑞, 韩增尧, 邹元杰, 等, 航天器力学环境分析与条件设计研究进展, 宇航学报, 2012, 33(1): 1-12

4 Thomas P S, Poti G D. Simplifying the structural verification process to accommodate responsive Launch. AIAARS52007-5003. In: 5th Responsive Space Conference, Los Angeles, CA, 2007. 23-26

5 Kabe M, Kim M C, Spiekermann C E. Loads analysis for national security space missions. Rocket Science, 2004,5(1):

6 Clough R W, Penzien J. Dynamics of Structures. New York: McGraw -Hill Inc, 1975

7 Craig R R, Bampton M C. Coupling of substructures for dynamic analysis. AIAA Journal, 1968, 6: 1313-1319

8 Kammer D C, Triller M J. Ranking the dynamic importance of fixed interface modes using a generalization of effective mass. International Journal of Analytical and Experimental Modal Analysis, 1994, 9(2): 77-98

9 Kammer D C, Triller M J. Selection of component modes for Craig-Bampton substructure representations. Journal of Vibration and Acoustics, 1996, 118: 264-270

10 Jaap Wijker. Mechanical vibrations in spacecraft design. New York: Springer, 2003. 110-119

11 邱吉宝, 张正平, 黄波, 等. 基础激励结构动力学问题求解新方法. 结构动力学专业委员会2007 年研讨会, 2007. 46-60

12 Qiu J B, Ying Z G, Williams F W. Exact modal synthesis techniques using residual constraint modes. Int. J. Num. Met. Eng., 1997, 40: 2475-2492

13 Qiu J B, Williams F W, Qiu R X. An exact substructure method using mixed modes. Journal of Sound and Vibration, 2003, 266: 737-757

14 邱吉宝, 向树红, 张正平. 计算结构动力学. 合肥: 中国科学技术大学出版社, 2009

15 Chen J C, Garba J A, Wadat B K. Estimation of payload loads using rigid-body interface accelerations. J. Spacecr,1979, 16(2): 76-80

16 Gladwell M L. Branch mode analysis of vibrating systems. J. Sound Vibration, 1960, 1: 41-59

17 邱吉宝, 张正平, 李海波, 等. 运载火箭/航天器耦合分支模态综合法(上). 强度与环境, 2011, 38(6): 24-33

18 邱吉宝, 张正平, 李海波, 等. 运载火箭/航天器耦合分支模态综合法(下). 强度与环境, 2012, 39(1): 1-11

19 邱吉宝, 张正平, 李海波, 等. 星箭耦合动态响应分析新方法研究. 强度与环境, 2011, 38(3):1-9

20 Chen J C, Zagzebski K P, Garbat J A. Recovered transient load analysis for payload structural systems. J. Space- craft, 1980, 18(4)：374-379

21 胡海昌. 多自由度结构固有振动理论. 北京: 科学出版社,1987

22 Hurty W C. Vibration of structure systems by component mode synthesis. Jour. Engr. Div., ASCE, 1960, 86: 51-59

23 Leung A T. An accurate method of dynamic condensation in structural analysis. Int. J. Numer. Methods Eng.,1978, 12: 1705-1715

24 Leung A T. An accurate method of dynamic substructuring with simplified computation. Int. J. Numer. Methods Eng., 1979, 14: 1241-1256

25 胡海昌. 很多自由度体系的固有振动问题(约束模态法). 航空学报, 1980, 2: 28-36.

26 Qiu J B, Tan Z Y. Residual modes substructure synthesis techniques. In: Proceedings of the International Conference on Vibration Engineering, Beijing, 1994, 51-56

27 应祖光, 邱吉宝, 谭志勇. 确精剩余模态及其综合技术. 振动工程学报, 1996, 9(1): 38-46

28 Hou S N. Review of modal synthesis techniques and a new approach. Shock and Vibration Bulletin, 1969, 40(4): 25-39

29 MacNeal R H. A hybrid method of component mode synthesis. Computers & Structures, 1971, 1: 581-601

30 Rubin S. Improved component-mode representation for structural dynamic analysis. AIAA Journal, 1975, 13:995-1006

31 Craig R R, Chang C J. Free-interface methods of substructure coupling for dynamic analysis. AIAA Journal, 1976,14: 1633-1635

32 王文亮, 杜作润, 陈康元. 模态综合技术短评和一种新的改进. 航空学报, 1979, 3: 32-51

33 Hurty W C, Du Z R, Chen K Y. Dynamic analysis of structural systems using component modes. AIAA Jour- nal, 1965, 3: 678-685

34 Suarez L E, Suarez M P. Improved fixed interface method for modal synthesis. AIAA Journal, 1992, 30: 2952-2958

35 Kubomura. A theory of substructure modal synthesis. Journal of Applied Mechanics, 1982, 49: 903-909

36 Qiu J B, Ying Z G, Yam L H. New modal synthesis technique using mixed modes. AIAA Journal, 1997, 35: 1869-1875

37 向树红, 邱吉宝, 王大钧. 模态分析与动态子结构方法新进展. 力学进展, 2004, 34(3): 289-303

38 Craig R R, Ni Z H. Component mode synthesis for model order reduction of non-classically damped systems. Jour- nal of Guidance Control and Dynamics, 1989, 12(4): 577-584

39 Wang W, Kirkhope J. Complex component mode synthesis for damped systems. Journal of Sound and Vibration,1995, 181(5): 781-800

40 Muravyov A, Hutton S G. Component mode synthesis for non-classically damped systems. AIAA Journal, 1996,34(8): 1664-1699

41 Morgan J A, Pierre C, Hulbert G M. Baseband method of component mode synthesis for non-classically damped systems. Mechanical Systems and Signal Processing, 2003,17(3): 589-598

42 Fransen S A. Methodologies for launcher-payload coupled dynamic analysis. European Conference on Space- craft Structures, Materials and Mechanical Testing (2005ESASP), 2005. 46F: 1-13

43 Manuel F P, Sebastiaan H F, et al, Stochastic launchersatellite coupled dynamic analysis. Journal of Spacecraft and Rockets, 2006, 43(6): 1308-1318

44 Fransen S A. Data recovery methodologies for reduced dynamic substructure models with internal loads. AIAA Journal, 2004, 42(10): 2130-2142

45 Fransen S A. An overview and comparison of OTM formulations on the basis of the mode displacement method and the mode acceleration method. Worldwide Aerospace Conf. & Technology Showcase, MSC. Software Corp.,2002, 17

46 Dickens J M, Stroeve A. Modal truncation vectors for reduced dynamic substructure models, AIAA 2000-1578,2000. 1-9

47 Rixen D J. Generalized mode acceleration methods and modal truncation augmentation. In Structures, Structural Dynamics, and Materials Conference, 42nd IAA/ASMBASCE/AHS/ASC, AIAA 2001-1300, 2001

48 朱礼文, 朱斯岩, 与卫星升空状态一致的多自由度振动试验条件, 中国宇航学会2011 年学术年会论文集, 2011

49 邱吉宝. 航天器计算结构动力学展望. 计算结构力学及其应用, 1993, 10(2): 219-227

50 Qiu J B, Wang J M. Dynamic analysis of strap-on launch vehicle. In: Proc. of Asian-Pacific Conference on Aerospace Technology and Science, Hangzhou, 1994. 387-391

51 邱吉宝, 谭志勇. 航天器结构动力学分析技术的一些进展. 西安公路交通大学学报, 1997, 17(SI): 17-28

52 邱吉宝, 谭志勇, 王建民. 运载火箭结构动力学分析的一些新技术(第一部分: 模态综合技术). 导弹与航天运载技术,2001, 2: 29-34

53 邱吉宝, 谭志勇, 王建民. 运载火箭结构动力学分析的一些新技术(第二部分: 运载火箭结构动力学分析). 导弹与航天运载技术, 2001, 4: 16-21

54 Qiu J B, Fu M F, Xiang S H, et al. The research into virtual dynamic test techniques for space vehicles. Proc. CD-ROM of the 6th World Congress on Computational Mechanics, Tsinghua University Press & Springer-Verlag, Beijing, 2004

55 邱吉宝, 王建民. 航天器虚拟动态试验技术研究及展望. 航天器环境工程, 2007, 24(1): 1-14

56 Qiu J B, Wang J M, Zhang Z P. The research into virtual dynamic test techniques for space vehicles. Computational Mechanics ISCM2007, Beijing, China, 2007

57 邱吉宝, 王建民. 运载火箭模态试验仿真技术研究. 宇航学报, 2007, 28(3): 515-521

58 张正平, 邱吉宝, 王建民, 等. 航天器结构虚拟动态试验技术新进展. 振动工程学报, 2008, 31(3): 209-222

59 邱吉宝, 王建民. 用测量模态参数修改数学模型和复杂结构动力学建模技术. 全国模态分析与试验会议论文集, 1991

60 王建民, 邱吉宝. 用测量模态参数修改数学模型的静力等效方法. 全国模态分析与试验会议论文集, 1991

61 邱吉宝, 王建民. 用试验识别模态修改数学模型方法与复杂结构建模技术. 振动与冲击, 1994, (3): 8-14

62 Wada B K, Kuo C P, Glaser R L. Multiply boundary condition test (MBCT) approach to update mathematical models of Flexible structures. SAE Aerospace Technology Conference Exposition, Long Beach, CA, Technical paper,1985. 851-933

63 Wada B K, Kuo C P, Glaser R J. Multiple Boundary Condition Tests(MBCT) for verification of large space structures. AIAA 27th SDM, 1986. 336-341

64 向树红, 晏廷飞, 邱吉宝. 40 吨振动台虚拟试验仿真技术研究. 宇航学报, 2004, 25(4): 375-381

65 Xiang S H, Yan T F, Qiu J B. The research on the virtual vibration test of 40t shaker. In: Proc. CD-ROM of the6th World Congress on Computational Mechanics Press & Springer-Verlag, Beijing, 2004

Relative Articles

Supplements(0)

Cited By

Proportional views