NUMERICAL-ANALYSIS OF THE FLUIDELASTIC VIBRATION OF A STEAM-GENERATOR TUBE WITH LOOSE SUPPORTS

被引：31

作者：

FRICKER, AJ

机构：

[1] National Power, Technology and Environmental Centre, Leatherhead

来源：

JOURNAL OF FLUIDS AND STRUCTURES | 1992年 / 6卷 / 01期

关键词：

D O I：

10.1016/0889-9746(92)90057-A

中图分类号：

TH [机械、仪表工业];

学科分类号：

0802 ;

摘要：

The vibration and wear of U-tubes has been observed in PWR steam generators, especially in the U-bend region where the tubes experience two-phase cross-flow. In this region the tubes are supported by anti-vibration bars (AVBs); however, clearances can exist between the tubes and AVBs so that flow-induced vibration can cause impacting and sliding to occur between the two components, leading to fretting wear. A method is described for analyzing the impacting behaviour of a steam generator tube which has one or more loose supports and is fluidelastically unstable. The method uses a fluidelastic instability model to predict the damping (positive or negative) of all the modes of vibration of the tube and uses this information in a nonlinear transient analysis computer code, which includes the effects of impacting at loose supports. A comparison is made between numerical predictions and experimental results obtained from a cantilever tube array in cross-fly. The predicted changes in frequency of vibration with flow velocity agree well with the experimental values, giving some confidence in the accuracy of the method. The method is then used to analyze the fluid-elastic vibration of a steam generator U-tube with a single loose AVB support point. © 1992.

引用

页码：85 / 107

页数：23

共 14 条

[1] Antunes, Axisa, Vento, Experiments on vibro-impact dynamics under fluidelastic instability, ASME PVP Vol. 189 ‘Flow Induced Vibration—1990’, pp. 127-138, (1990)
[2] Axisa, Antunes, Villard, Overview of numerical methods for predicting flow-induced vibration, ASME Journal of Pressure Vessel Technology, 110, pp. 6-16, (1988)
[3] Chen, A general theory for dynamic instability of tube arrays in cross flow, Journal of Fluids and Structures, 1, pp. 35-53, (1987)
[4] Connors, Fluidelastic vibration of heat exchanger tube arrays, Journal of Mechanical Design, 100, pp. 347-353, (1978)
[5] De Langre, Doveil, Porcher, Axisa, Chaotic and periodic motion of a non-linear oscillator in relation with flow-induced vibrations of loosely supported tubes, ASME PVP Vol. 189 ‘Flow Induced Vibration—1990’, pp. 119-125, (1990)
[6] Frick, Sobek, Reavis, Overview on the development and implementation of methodologies to compute vibration and wear in steam generator tubes, Symposium on Flow-Induced Vibrations: Vol. 3: Vibration in Heat Exchangers, pp. 149-161, (1984)
[7] Fricker, The analysis of impacts in vibrating structures containing clearances between components, International Conference on Numerical Methods for Transient and Coupled Problems, (1984)
[8] Nigam, Jennings, Calculation of response spectra from strong-motion earthquake records, Bulletin of the Seismic Society of America, 59, pp. 909-922, (1969)
[9] Rao, Gupta, Eisinger, Hibbitt, Steininger, Computer modelling of vibration and wear of multispan tubes with clearances at tube supports, International Conference on Flow Induced Vibrations, pp. 449-466, (1987)
[10] Rogers, Pick, On the dynamic spatial response of a heat exchanger tube with intermittent baffle contacts, Nuclear Engineering and Design, 36, pp. 81-90, (1976)

← 1 2 →