円管内等加速度流れの臨界レイノルズ数
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概要
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Experimental investigation has been carried out to understand the transition to turbulence in constant-acceleration pipe flow. A fluid initially at rest in a circular pipe is accelerated at a constant acceleration. The transition to turbulence is judged on the basis of the output signal of a hot-wire anemometer or laser Doppler velocimetry in addition to flow visualization. The critical Reynolds number,<I>Re<SUB>tr</SUB></I>(=<I>u<SUB>m</SUB>D⁄v</I>), is highly increased beyond that of approximately 3000 in steady pipe flows, where <I>u<SUB>m</SUB></I> is the cross-sectional mean velocity, <I>D</I> is the pipe diameter, and <I>v</I> is the kinematic viscosity of fluid. The following empirical equation is proposed for the critical Reynolds number.<I>Re<SUB>tr</SUB></I>=1.33[<I>D(a⁄v</I><SUP>2</SUP>)<SUP>1⁄3</SUP>]<SUP>1.86</SUP> where <I>a</I> is the acceleration.
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日本実験力学会 | 論文
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- 複数縁き裂の応力拡大係数の干渉効果(中央部き裂のKと各き裂のK,K_について)
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- 複数縁き裂の応力拡大係数の干渉効果(中央部き裂のKと各き裂のK,K_について)