«Previous Article|Table of Contents|Next Article»

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V]

Issue:

2018年03期

Page:

16-22

Research Field:

研究与设计

Publishing date:

Info

Title:

Failure analysis and dynamics optimization of pipeline for liquid rocket engine

Author(s):

DU Dahua¹;  2;  MU Penggang²;  TIAN Chuan³;  ZHOU Jian²;  CHENG Xiaohui²

1. College of Aeronautics, Northwestern Polytechnical University, Xi'an 710072, China; 2. Science and Technology on Liquid Rocket Engine Laboratory, Xi'an 710100, China; 3. Military Representative Bureau of Air Force Ordnance Equipment, Xi'an 710072, China

Keywords:

pipeline failure;  optimization design;  liquid rocket engine;  failure analysis

PACS:

V434.2-34

DOI:

-

Abstract:

The safety and reliability of pipeline system for liquid rocket engine are the key issues to safe operation of engine. Aiming at the fracture failure of rocket engine pipeline, a newfailure analysis method and dynamic optimization design of the pipeline are proposed. Firstly, the vibration control measures were put forward based on the mechanism analysis and fault recurrence. Then the front and rear chamfers of the failure pipe joint were treated as design variables, while the minimum dynamic stress at the two chamfers was served as the objective function. The dynamics optimization model design and dynamic strength optimization design based on shape optimization were conducted by using the structure frequency restricted zone as a constraint. Lastly, the damage quantitative analysis of random vibration fatigue of the structure under base-excitation was carried out for the joint structure. In addition, the improved approach was validated by fatigue test. It is concluded from the research that the dynamics optimization of pipeline structure can improve the mechanical environment adaptability and structuralrelia bility, and the effectiveness of improvement measures is verified. The established methods of structural failure analysis and dynamics optimization design provide technical support for the project development.

References:

[1] BACHSCHMID N, PENNACCHI P, VANIA A, et al. Case studies of fault identification in power plant large rotating machinery [C]// 6^th IFToMM-Conference on Rotor Dynamics, Austrilia:Sydney, 2002:191-200.
[2] 权凌霄, 孔祥东. 液压管路流固耦合振动机理及控制研究现状与发展[J]. 机械工程学报, 2015, 51(18):175-183.
[3] 张立翔, 黄文虎. 输流管道流固耦合振动研究进展[J]. 水动力学研究与进展, 2000, 15(3):366-379.
[4] 徐云飞, 李锋. 液体火箭发动机充液导管流固耦合动力学特性[J]. 航空动力学报, 2017, 32(6):1523-1529.
[5] 陈香林, 周文禄. 压力管道流固耦合振动特性分析[J]. 火箭推进, 2007, 33(5):27-31.
CHEN Xianglin, ZHOU Wenlu. Vibration characteristic analysis of pressure pipes with fluid-structure interaction [J]. Journal of rocket propulsion, 2007, 33(5): 27-31.
[6] 尹志勇, 钟荣. 管路系统振动噪声控制技术研究现状与展望[J]. 舰船科学技术, 2006, 28(2):23-29.
[7] 梁向东. 船舶管路中高频振动成因分析及控制策略研究[J]. 噪声与振动控制, 2009(3):101-103.
[8] 卢金丽, 黄超广. 飞机液压燃油管路系统振动故障模式、机理及排除方法[J]. 振动工程学报, 2008, 21(S):78-82.
[9] 李会娜, 高庆. 发动机长悬壁管路动力学特性优化及试验验证[J]. 航天器环境工程, 2015, 32(4):400-403.
[10] LI Z J, LIAO H T, COIT D W. A two-stage approach for multi-objective decision making with application to system reliability optimization [J]. Reliability engineering and system safety, 2009, 94:1585-1592.
[11] EAMON C, RAIS-ROHANI M. Integrated reliability and sizing optimization of a large composite structure [J]. Marine structure, 2009, 22: 315-334.
[12] VALDEBENITO M A, SCHUELLER G I. Reliability-based optimization considering design variables of discrete size. Engineering Structure, 2010, 32: 2919-2930.
[13] 李士杰. 1Cr18Ni9Ti钢的低周疲劳特性研究[J]. 核动力工程, 1991, 12(2):34-37.
[14] CALVI A, AGLIET G, ALBUS J, et al. ECSS-E-HB-32-26A space engineering spacecraft mechanical loads analysis handbook [M]. [S.l.]: ECSS Secretariat ESA-ESTEC, 2013.

Memo

Memo:

-

Common functions

Last Update: 2018-06-30