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为研究无限大流体约束的孔隙圆柱中周向导波的传播规律, 分析孔隙参数对导波传播特性的影响, 建立了无限流体中孔隙介质圆柱的理论模型, 利用孔隙介质弹性波动理论, 建立了周向导波频散方程, 通过数值模拟计算得到无限流体中孔隙介质圆柱的频散曲线, 探讨了圆柱半径和孔隙参数对导波传播特性的影响, 并对导波的衰减特性进行了分析; 通过数值计算, 得到了周向导波的时域波形, 讨论了孔隙参数对波形的影响. 结果表明, 孔隙介质圆柱半径的改变影响圆柱尺度, 孔隙度的改变影响孔隙介质中体声波的波速, 都对周向导波频散曲线产生一定的影响, 所得到的频散曲线特征及衰减曲线与时域波形吻合. 研究结果对开展无限流体中孔隙介质圆柱的超声无损评价提供了一定的理论参考.Underground water, gas and oil all exist in the fractured or porous strata. Waves that propagate through porous cylinder immersed in infinite fluid are of considerable interest in the estimation of porous parameter, such as an underwater concrete column may present pore characteristics after a long time water immersion. Compared with longitudinal guided wave, circumferential guided wave has its advantages in the ultrasonic nondestructive inspection of porous cylinder. In order to investigate the propagation characteristics of guided waves in a porous cylinder immersed in infinite fluid and analyze the effects of the porous medium parameters on the dispersion characteristic, a model of porous cylinder surrounded by fluid is built. Based on the elastic-dynamic theory and modified liquid-saturated porous theory, the characteristic equation of guided wave is established, and the dispersion curves are obtained numerically. The effects of cylindrical radius and pore parameters on the propagation characteristics of guided waves are discussed; the attenuation characteristics of guided waves are also analyzed; the time domain waveforms of the guided circumferential waves are obtained by numerical inversion, and the influence of porous parameters on waveforms is simulated. It is found that the dispersion curves are similar to that of elastic cylinder in the fluid, there exist multiple mode guided waves and approximate shear velocity of medium for higher modes, and higher order modes are more affected by the radius, but it does not change the tendency of curve. The phase velocity decreases with porosity increasing at the same frequency and the effect of porosity on higher order modes is greater than that on mode 1; due to the dissipation in the medium, the attenuation increases porosity increasing. It can be seen from the transient responses that the wave packets move backward and the displacement amplitude decreases with the porosity increasing. The characteristics of the inversed transient response are in good agreement with theoretical dispersion and attenuation. The results show that the propagation of guided circumferential wave is affected by the pore parameters, especially for porosity, which can provide a theoretical reference for the non-destructive evaluation of the porous cylinder surrounded by infinite fluid.
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Keywords:
- guided circumferential waves /
- porous media /
- dispersion
[1] 韩庆邦, 徐杉, 谢祖峰, 葛蕤, 王茜, 赵胜永, 朱昌平 2013 物理学报 62 194301Google Scholar
Han Q B, Xu B, Xie Z F, Ge R, Wang X, Zhao S Y, Zhu C P 2013 Acta Phys. Sin. 62 194301Google Scholar
[2] Edelman I, Wilmanski K 2002 Continuum Mech. Thermodyan. 14 25Google Scholar
[3] Yan S G, Xie F L, Li C Z, Zhang B X 2016 Appl. Geophys. 13 333Google Scholar
[4] Ding H R, Liu J X, Cui Z W 2017 Chin. Phys. B 26 124301Google Scholar
[5] Han Q B, Qi L H, Shan M L, Yin, C, Zhu C P 2017 Ultrasonics 81 73Google Scholar
[6] 董庆德, 王克协, 许吉庆 1985 地球物理学报 28 208Google Scholar
Dong Q D, Wang K X, Xu J Q 1985 Chin. J. Geophys. 28 208Google Scholar
[7] Zhang S G, Hu W X 2008 Chin. Phys. Lett. 25 4314Google Scholar
[8] 郭文杰, 李天匀, 朱翔, 屈凯旸 2018 物理学报 67 084302Google Scholar
Guo W J, Li T Y, Zhu X, Qu K S 2018 Acta Phys. Sin. 67 084302Google Scholar
[9] Valle C, Qu J, Jacobs L J 1999 Int. J. Eng. Sci. 37 1369Google Scholar
[10] Yang W, Fung T C, Chian K S, Chong C K 2007 J. Biomech. 40 481Google Scholar
[11] 高广健, 邓明晰, 李明亮, 刘畅 2015 物理学报 64 224301Google Scholar
Gao G J, Deng M X, Li M L, Liu C 2015 Acta Phys. Sin. 64 224301Google Scholar
[12] 许洲琛, 韩庆邦, 童紫薇, 齐立华, 王鹏, 单鸣雷, 朱昌平 2018 声学学报 43 52
Xu Z C, Han Q B, Tong Z W, Qi L H, Wang P, Shan M L, Zhu C P 2018 Acta Acust. 43 52
[13] Biot M A 1956 J. Acoust. Soc. Am. 28 167
[14] Ogushwitz P R 1985 J. Acoust. Soc. Am. 77 441Google Scholar
[15] Johnson D L 1987 J. Fluid Mech. 176 379Google Scholar
[16] Zheng P, Ding B Y, Zhao S X 2014 Acta Mech. Sin. 30 206Google Scholar
[17] Biot M A 1957 J. Appl. Mech. 15 594
[18] Butt H S U, Xue P, Jiang T Z, Wang B 2015 Int. J. Mech. Sci. 91 46Google Scholar
[19] Biot M A 1962 J. Appl. Phys. 33 1482Google Scholar
[20] 邵广周, 李庆春, 梁志强 2007 地球物理学报 50 915Google Scholar
Shao G Z, Li Q C, Liang Z Q 2007 Chin. J. Geophys. 50 915Google Scholar
[21] Feng S, Johnson D L 1983 J. Acoust. Soc. Am. 74 906Google Scholar
[22] Deresiewicz H, Skalak R 1963 Bull. Seismol. Soc. Am. 53 783
[23] 崔寒茵, 师芳芳, 籍顺心, 张碧星 2010 声学学报 35 446
Cui H Y, Shi F F, Ji S X, Zhang B X 2010 Acta Acust. 35 446
[24] 王婷, 崔志文, 刘金霞, 王克协 2018 物理学报 67 114301Google Scholar
Wang T, Cui Z W, Liu J X, Wang K X 2018 Acta Phys. Sin. 67 114301Google Scholar
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表 1 模型材料参数表
Table 1. Material parameters.
介质 纵波波速/m·s–1 横波波速/m·s–1 密度/kg·m–3 弹性圆柱 5370 3100 2700 孔隙介质 固体基质 5370 3100 2700 孔隙流体 1483 998 外部流体 1483 998 表 2 孔隙介质圆柱参数表
Table 2. Material parameters of porous medium.
孔隙度β/% 孔隙弯曲度a∞ 静态渗透率κ0/m2 黏滞系数n/kg·s–1·m–1 10 5.5 10–12 0.001 固体颗粒体积模量Ks/GPa 流体体积模量Kf/GPa 固体骨架体积模量Kb/GPa 固体骨架剪切模量N/GPa 43.33 2.19 33.70 20.86 表 3 不同孔隙度时孔隙介质圆柱中体声波的波速
Table 3. Velocity of body sound waves in porous media with different porosity.
孔隙度 快纵波波速/km·s–1 慢纵波波速/km·s–1 横波波速/km·s–1 0.1 4.9690 0.3694 2.8712 0.2 4.4811 0.6748 2.5794 0.3 3.8662 0.8579 2.2006 -
[1] 韩庆邦, 徐杉, 谢祖峰, 葛蕤, 王茜, 赵胜永, 朱昌平 2013 物理学报 62 194301Google Scholar
Han Q B, Xu B, Xie Z F, Ge R, Wang X, Zhao S Y, Zhu C P 2013 Acta Phys. Sin. 62 194301Google Scholar
[2] Edelman I, Wilmanski K 2002 Continuum Mech. Thermodyan. 14 25Google Scholar
[3] Yan S G, Xie F L, Li C Z, Zhang B X 2016 Appl. Geophys. 13 333Google Scholar
[4] Ding H R, Liu J X, Cui Z W 2017 Chin. Phys. B 26 124301Google Scholar
[5] Han Q B, Qi L H, Shan M L, Yin, C, Zhu C P 2017 Ultrasonics 81 73Google Scholar
[6] 董庆德, 王克协, 许吉庆 1985 地球物理学报 28 208Google Scholar
Dong Q D, Wang K X, Xu J Q 1985 Chin. J. Geophys. 28 208Google Scholar
[7] Zhang S G, Hu W X 2008 Chin. Phys. Lett. 25 4314Google Scholar
[8] 郭文杰, 李天匀, 朱翔, 屈凯旸 2018 物理学报 67 084302Google Scholar
Guo W J, Li T Y, Zhu X, Qu K S 2018 Acta Phys. Sin. 67 084302Google Scholar
[9] Valle C, Qu J, Jacobs L J 1999 Int. J. Eng. Sci. 37 1369Google Scholar
[10] Yang W, Fung T C, Chian K S, Chong C K 2007 J. Biomech. 40 481Google Scholar
[11] 高广健, 邓明晰, 李明亮, 刘畅 2015 物理学报 64 224301Google Scholar
Gao G J, Deng M X, Li M L, Liu C 2015 Acta Phys. Sin. 64 224301Google Scholar
[12] 许洲琛, 韩庆邦, 童紫薇, 齐立华, 王鹏, 单鸣雷, 朱昌平 2018 声学学报 43 52
Xu Z C, Han Q B, Tong Z W, Qi L H, Wang P, Shan M L, Zhu C P 2018 Acta Acust. 43 52
[13] Biot M A 1956 J. Acoust. Soc. Am. 28 167
[14] Ogushwitz P R 1985 J. Acoust. Soc. Am. 77 441Google Scholar
[15] Johnson D L 1987 J. Fluid Mech. 176 379Google Scholar
[16] Zheng P, Ding B Y, Zhao S X 2014 Acta Mech. Sin. 30 206Google Scholar
[17] Biot M A 1957 J. Appl. Mech. 15 594
[18] Butt H S U, Xue P, Jiang T Z, Wang B 2015 Int. J. Mech. Sci. 91 46Google Scholar
[19] Biot M A 1962 J. Appl. Phys. 33 1482Google Scholar
[20] 邵广周, 李庆春, 梁志强 2007 地球物理学报 50 915Google Scholar
Shao G Z, Li Q C, Liang Z Q 2007 Chin. J. Geophys. 50 915Google Scholar
[21] Feng S, Johnson D L 1983 J. Acoust. Soc. Am. 74 906Google Scholar
[22] Deresiewicz H, Skalak R 1963 Bull. Seismol. Soc. Am. 53 783
[23] 崔寒茵, 师芳芳, 籍顺心, 张碧星 2010 声学学报 35 446
Cui H Y, Shi F F, Ji S X, Zhang B X 2010 Acta Acust. 35 446
[24] 王婷, 崔志文, 刘金霞, 王克协 2018 物理学报 67 114301Google Scholar
Wang T, Cui Z W, Liu J X, Wang K X 2018 Acta Phys. Sin. 67 114301Google Scholar
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