岩土力学 ›› 2025, Vol. 46 ›› Issue (1): 303-314.doi: 10.16285/j.rsm.2024.0388

• 数值分析 • 上一篇    下一篇

热黏弹性介质中波的传播特性研究

马强1, 2,杨奕琪1,周凤玺3,邵帅2   

  1. 1.青海大学 土木水利学院,青海 西宁 810016;2.西安理工大学 岩土工程研究所,陕西 西安 710048; 3.兰州理工大学 土木工程学院,甘肃 兰州 730050
  • 收稿日期:2024-04-01 接受日期:2024-06-20 出版日期:2025-01-10 发布日期:2025-01-04
  • 通讯作者: 周凤玺,男,1979年生,博士,教授,主要从事岩土工程方面的教学与研究。E-mail: geolut@163.com
  • 作者简介:马强,男,1990年生,博士,副教授,主要从事土动力学与岩土工程抗震方面的研究工作。E-mail: maqiang0104@163.com
  • 基金资助:
    国家自然科学基金项目(No.52168053,No.52108342);青海省自然科学基金面上基金(No.2024-ZJ-922);西安理工大学博士启动金(No.107-451122001)。

Characterization of wave propagation in thermo-viscoelastic media

MA Qiang1, 2, YANG Yi-qi1, ZHOU Feng-xi3, SHAO Shuai2   

  1. 1. School of Civil Engineering and Water Resources, Qinghai University, Xining, Qinghai 810016, China; 2. Institute of Geotechnical Engineering, Xi’an University of Technology, Xi’an, Shaanxi 710048, China; 3. School of Civil Engineering, Lanzhou University of Technology, Lanzhou, Gansu 730050, China
  • Received:2024-04-01 Accepted:2024-06-20 Online:2025-01-10 Published:2025-01-04
  • Supported by:
    This work was supported by the National Natural Science Foundation of China (52168053,52108342), the Qinghai Province Science and Technology Department Project (2024-ZJ-922) and the Doctoral Initial Funding of Xi’an University of Technology (107-451122001).

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摘要: 基于弹性介质的波动理论,考虑了土体的黏性和热效应的影响,利用Kelvin-Voigt黏弹性模型、黏弹性介质的运动方程以及广义热弹性理论,建立了热黏弹性介质的波动方程。通过引入固相介质的位移势函数,进一步推导得到了热黏弹性介质中体波的弥散特征方程。采用数值计算分析了热膨胀系数、介质温度和松弛时间等热物性参数对热弹性波的波速和衰减系数的影响规律。研究结果表明:弹性理论、热弹性理论和热黏弹性理论3种理论模型下所得到的热弹性体波的波速和衰减系数有着明显差异;松弛时间每增加0.5×10−3 s,P波的波速和衰减系数最大增加了5.18%和34.67%,S波的波速和衰减系数最大增加了9.27%和34.60%,而T波的波速和衰减系数最大减小了2.18%和2.24%;随着频率的增大,各类热弹性波的波速和衰减系数均逐渐增大;介质温度的增大会造成P波和T波的波速增大以及P波衰减系数的增大,温度每增加20 K,P波的波速和衰减系数分别增加约3%和2%,但对 S波的传播特性以及T波的衰减系数不产生影响;热膨胀系数的增大将引起P波的波速增大和T波的波速减小,同时也会对P波和T波的衰减系数产生显著影响。此外,热通量和温度梯度相位延迟时间仅对T波的波速和衰减系数有较大影响。

关键词: 黏弹性介质, 热效应, 体波, 波速, 衰减系数

Abstract: Based on the fluctuation theory of elastic medium, the fluctuation equation of thermoviscoelastic medium is established by using the Kelvin-Voigt viscoelastic model, the equation of motion of viscoelastic medium and the generalized thermoelasticity theory. This approach considers soil viscosity and thermal effects. Then the dispersive characteristic equation of the body wave in the thermoviscoelastic medium is derived by introducing the displacement potential function of the solid-phase medium. Numerical calculations were performed to analyze the influence of thermophysical parameters, such as thermal expansion coefficient, medium temperature and relaxation time on the wave velocity and attenuation coefficient of thermoelastic waves. The results indicate significant differences in the wave velocity and attenuation coefficient of thermal elastomer waves under the three theoretical models: elastic theory, thermoelastic theory, and thermoviscoelastic theory. For each 0.5×10−3 s increase in relaxation time, the P-wave speed and attenuation coefficient increased by up to 5.18% and 34.67%, respectively; the S-wave speed and attenuation coefficient increased by up to 9.27% and 34.6%, respectively; and the T-wave speed and attenuation coefficient decreased by up to 2.18% and 2.24%, respectively. As frequency increases, the wave velocity and attenuation coefficient of each thermoelastic wave gradually increase. An increase in medium temperature results in higher P-wave and T-wave speeds and a higher P-wave attenuation coefficient. Specifically, for every 20 K increase in temperature, the P-wave speed and attenuation coefficient increase by approximately 3% and 2%, respectively. However, temperature changes do not affect the S-wave propagation characteristics and the T-wave attenuation coefficient. An increase in the thermal expansion coefficient leads to an increase in P-wave velocity and a decrease in T-wave velocity, significantly affecting the attenuation coefficients of both P-wave and T-wave. Additionally, heat flux and the phase delay time of the temperature gradient significantly influence the wave velocity and attenuation coefficient of the T-wave.

Key words: viscoelastic media, thermal effects, bulk waves, wave velocity, attenuation coefficient

中图分类号: TD 435
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