Fluidelastic instability study on a rotated triangular tube array subject to two-phase cross-flow. Part II: Experimental tests and comparison with theoretical results

An experimental study was conducted to investigate damping and fluidelastic instability in tube arrays subjected to two-phase cross-flow. The purpose of this research was to improve our understanding of these phenomena and how they are affected by void fraction and flow regime. The working fluid used was Freon 11, which better models steam-water than air-water mixtures in terms of vapour-liquid mass ratio as well as permitting phase changes due to pressure fluctuations. The damping measurements were obtained by “plucking” the monitored tube from outside the test section using electromagnets. An exponential function was fitted to the tube decay trace, producing consistent damping measurements and minimizing the effect of frequency shifting due to fluid added mass fluctuations. The void fraction was measured using a gamma densitometer, introducing an improvement over the Homogeneous Equilibrium Model (HEM) in terms of density and velocity predictions. It was found that the Capillary number, when combined with the two-phase damping ratio (interfacial damping), shows a well defined behaviour depending on the flow regime. This observation can be used to develop a better methodology to normalize damping results. The fluidelastic results agree with previously presented data when analyzed using the HEM and the half-power bandwidth method. The interfacial velocity is suggested for fluidelastic studies due to its capability for collapsing the fluidelastic data. The interfacial damping was introduced as a tool to include the effects of flow regime into the stability maps.

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DYNAMICS OF AN IN-LINE TUBE ARRAY SUBJECTED TO STEAM–WATER CROSS-FLOW. PART I: TWO-PHASE DAMPING AND ADDED MASS

Journal of Fluids and Structures ◽

10.1006/jfls.2001.0406 ◽

2002 ◽

Vol 16 (2) ◽

pp. 123-136 ◽

Cited By ~ 18

Author(s):

T. NAKAMURA ◽

K. HIROTA ◽

Y. WATANABE ◽

N.W. MUREITHI ◽

T. KUSAKABE ◽

...

Keyword(s):

Cross Flow ◽

Added Mass ◽

Two Phase ◽

Phase Damping ◽

Flow Part

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A Method for Extracting the Time Delay From the Unsteady and Quasi-Steady Fluidelastic Forces in Two-Phase Flow

Volume 4: Fluid-Structure Interaction ◽

10.1115/pvp2013-97437 ◽

2013 ◽

Author(s):

Teguewinde Sawadogo ◽

Njuki Mureithi

Keyword(s):

Time Delay ◽

Two Phase Flow ◽

Phase Flow ◽

Two Phase ◽

Fluid Forces ◽

Void Fractions ◽

Fluidelastic Instability ◽

Measured Time ◽

Unsteady Fluid ◽

Theoretical Results

The time delay is a key parameter for modeling fluidelastic instability, especially the damping controlled mechanism. It can be determined experimentally by measuring directly the time lag between the tube motion and the induced fluid forces. The fluid forces may be obtained by integrating the pressure field around the moving tube. However, this method faces certain difficulties in two-phase flow since the high turbulence and the non-uniformity of the flow may increase the randomness of the measured force. To overcome this difficulty, an innovative method for extracting the time delay inherent to the quasi-steady model for fluidelastic instability is proposed in this study. Firstly, experimental measurements of unsteady and quasi-static fluid forces (in the lift direction) acting on a tube subject to two-phase flow were conducted. The unsteady fluid forces were measured by exciting the tube using a linear motor. These forces were measured for a wide range of void fraction, flow velocities and excitation frequencies. The experimental results showed that the unsteady fluid forces could be represented as single valued function of the reduced velocity (flow velocity reduced by the excitation frequency and the tube diameter). The time delay was determined by equating the unsteady fluid forces with the quasi-static forces. The results given by this innovative method of measuring the time delay in two-phase flow were consistent with theoretical expectations. The time delay could be expressed as a linear function of the convection time and the time delay parameter was determined for void fractions ranging from 60% to 90%. Fluidelastic instability calculations were also performed using the quasi-steady model with the newly measured time delay parameter. Previously conducted stability tests provided the experimental data necessary to validate the theoretical results of the quasi-steady model. The validity of the quasi-steady model for two-phase flow was confirmed by the good agreement between its results and the experimental data. The newly measured time delay parameter has improved significantly the theoretical results, especially for high void fractions (90%). However, the model could not be verified for void fractions lower or equal to 50% due to the limitation of the current experimental setup. Further studies are consequently required to clarify this point. Nevertheless, this model can be used to simulate the flow induced vibrations in steam generators’ tube bundles as their most critical parts operate at high void fractions (≥ 60%).

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An unsteady model for fluidelastic instability in an array of flexible tubes in two-phase cross-flow

Nuclear Engineering and Design ◽

10.1016/j.nucengdes.2014.12.032 ◽

2015 ◽

Vol 285 ◽

pp. 58-64 ◽

Cited By ~ 4

Author(s):

Nai-bin Jiang ◽

Bin Chen ◽

Feng-gang Zang ◽

Yi-xiong Zhang

Keyword(s):

Cross Flow ◽

Two Phase ◽

Fluidelastic Instability ◽

Flexible Tubes

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Vibration of a Tube Bundle in Two-Phase Freon Cross-Flow

Journal of Pressure Vessel Technology ◽

10.1115/1.2842130 ◽

1995 ◽

Vol 117 (4) ◽

pp. 321-329 ◽

Cited By ~ 36

Author(s):

M. J. Pettigrew ◽

C. E. Taylor ◽

J. H. Jong ◽

I. G. Currie

Keyword(s):

Two Phase Flow ◽

Tube Bundle ◽

Density Ratio ◽

Cross Flow ◽

Flow Regimes ◽

Phase Flow ◽

Two Phase ◽

Void Fractions ◽

Fluidelastic Instability ◽

First Results

Two-phase cross-flow exists in many shell-and-tube heat exchangers. The U-bend region of nuclear steam generators is a prime example. Testing in two-phase flow simulated by air-water provides useful results inexpensively. However, two-phase flow parameters, in particular surface tension and density ratio, are considerably different in air-water than in steam-water. A reasonable compromise is testing in liquid-vapor Freon, which is much closer to steam-water while much simpler experimentally. This paper presents the first results of a series of tests on the vibration behavior of tube bundles subjected to two-phase Freon cross-flow. A rotated triangular tube bundle of tube-to-diameter ratio of 1.5 was tested over a broad range of void fractions and mass fluxes. Fluidelastic instability, random turbulence excitation, and damping were investigated. Well-defined fluidelastic instabilities were observed in continuous two-phase flow regimes. However, intermittent two-phase flow regimes had a dramatic effect on fluidelastic instability. Generally, random turbulence excitation forces are much lower in Freon than in air-water. Damping is very dependent on void fraction, as expected.

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Investigations of In-Plane Fluidelastic Instability in a Multi-Span U-Bend Tube Bundle: Tests in Air Flow

Volume 4: Fluid-Structure Interaction ◽

10.1115/pvp2017-66068 ◽

2017 ◽

Cited By ~ 1

Author(s):

Paul Feenstra ◽

Teguewinde Sawadogo ◽

Bruce Smith ◽

Victor Janzen ◽

Helen Cothron

Keyword(s):

Steam Generator ◽

Tube Bundle ◽

Air Flow ◽

Cross Flow ◽

Test Rig ◽

Flow Induced Vibration ◽

Two Phase ◽

Fluidelastic Instability ◽

Air Blower ◽

R 134A

The tubes in the U-bend region of a recirculating type of nuclear steam generator are subjected to cross-flow of a two-phase mixture of steam and water. There is a concern that these tubes may experience flow-induced vibration, including the damaging effects of fluidelastic instability. This paper presents an update and results from a series of flow-induced vibration experiments performed by Canadian Nuclear Laboratories for the Electric Power Research Institute (EPRI) using the Multi-Span U-Bend test rig. In the present experiments, the main focus was to investigate fluidelastic instability of the U-tubes subjected to a cross-flow of air. The tube bundle is made of 22 U-tubes of 0.5 in (12.7 mm) diameter, arranged in a rotated triangular configuration with a pitch-over-diameter ratio of 1.5. The test rig could be equipped with variable clearance flat bar supports at two different locations to investigate a variety of tube and support configurations. The primary purpose of the overall project is to study the effect of flat bar supports on ‘in plane’ (‘streamwise’) instability in a U-tube bundle with realistic tube-to-support clearances or preloads, and eventually in two-phase flow conditions. Initially, the test rig was designed for tests in air-flow using an industrial air blower. Tests with two-phase Freon refrigerant (R-134a) will follow. This paper describes the test rig, experimental setup, and the challenges presented by simulating an accurate representation of current steam generator designs. Results from the first series of tests in air flow are described.

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Measurement of Critical Velocities for Fluidelastic Instability Using Vibration Control

Journal of Vibration and Acoustics ◽

10.1115/1.1286206 ◽

2000 ◽

Vol 122 (4) ◽

pp. 341-345 ◽

Cited By ~ 7

Author(s):

S. Caillaud ◽

E. de Langre ◽

P. Piteau

Keyword(s):

Vibration Control ◽

Critical Velocity ◽

Active Vibration Control ◽

Cross Flow ◽

Piezoelectric Actuators ◽

Experimental Tests ◽

Classical Stability ◽

Fluidelastic Instability ◽

Active Vibration ◽

Critical Velocities

Fluidelastic effects may be responsible for instabilities of heat exchanger tubes when the fluid flow reaches the critical velocity. The fluidelastic phenomenon is usually studied on experimental mock-ups, which may display only one critical velocity. In this paper, a method based on active vibration control is proposed in order to derive several critical velocities for fluidelastic instability corresponding to several different values of damping, which is artificially varied on the same mock-up. Experimental tests are performed on a flexible tube equipped with piezoelectric actuators in a rigid array under air-water cross-flow. It is shown that the reduced critical velocities thus obtained fit well in a classical stability map. [S0739-3717(00)01603-2]

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