The warm and ice-rich frozen soil is characterized by high unfrozen water content, low shear strength and large compressibility, which is unreliable to meet the stability requirements of engineering infrastructures an...The warm and ice-rich frozen soil is characterized by high unfrozen water content, low shear strength and large compressibility, which is unreliable to meet the stability requirements of engineering infrastructures and foundations in permafrost regions. In this study, a novel approach for stabilizing the warm and ice-rich frozen soil with sulphoaluminate cement was proposed based on chemical stabilization. The mechanical behaviors of the stabilized soil, such as strength and stress-strain relationship, were investigated through a series of triaxial compression tests conducted at -1.0℃, and the mechanism of strength variations of the stabilized soil was also explained based on scanning electron microscope test. The investigations indicated that the strength of stabilized soil to resist failure has been improved, and the linear Mohr-Coulomb criteria can accurately reflect the shear strength of stabilized soil under various applied confining pressure. The increase in both curing age and cement mixing ratio were favorable to the growth of cohesion and internal friction angle. More importantly, the strength improvement mechanism of the stabilized soil is attributed to the formation of structural skeleton and the generation of cementitious hydration products within itself. Therefore, the investigations conducted in this study provide valuable references for chemical stabilization of warm and ice-rich frozen ground, thereby providing a basis for in-situ ground improvement for reinforcing warm and ice-rich permafrost foundations by soil-cement column installation.展开更多
基于CFD分析软件Star CCM+,结合计算气动声学理论,对某汽车空气调节系统(HVAC)离心风机工作过程的流场和气动噪声进行数值模拟分析.采用Reynolds平均数值模拟(RANS)标准k-ε湍流模型模拟稳态流场,利用大涡模拟(LES)湍流模型和FW-H方程...基于CFD分析软件Star CCM+,结合计算气动声学理论,对某汽车空气调节系统(HVAC)离心风机工作过程的流场和气动噪声进行数值模拟分析.采用Reynolds平均数值模拟(RANS)标准k-ε湍流模型模拟稳态流场,利用大涡模拟(LES)湍流模型和FW-H方程分析瞬态气动噪声,通过监测离心风机内部和外部布置点测得压力脉动,并由傅里叶变换得到监测点声压级频谱.结果表明,离心风机主要噪声是叶轮旋转产生的离散噪声(达98 d B),可适当增加叶片数,调整叶片间距,以减小离散噪声.本方法可为其他类型风机的气动噪声数值模拟提供一种有效的分析手段.展开更多
基金supported by the National Natural Science Foundation of China (No. 41471062, No. 41971085, No. 41971086)。
文摘The warm and ice-rich frozen soil is characterized by high unfrozen water content, low shear strength and large compressibility, which is unreliable to meet the stability requirements of engineering infrastructures and foundations in permafrost regions. In this study, a novel approach for stabilizing the warm and ice-rich frozen soil with sulphoaluminate cement was proposed based on chemical stabilization. The mechanical behaviors of the stabilized soil, such as strength and stress-strain relationship, were investigated through a series of triaxial compression tests conducted at -1.0℃, and the mechanism of strength variations of the stabilized soil was also explained based on scanning electron microscope test. The investigations indicated that the strength of stabilized soil to resist failure has been improved, and the linear Mohr-Coulomb criteria can accurately reflect the shear strength of stabilized soil under various applied confining pressure. The increase in both curing age and cement mixing ratio were favorable to the growth of cohesion and internal friction angle. More importantly, the strength improvement mechanism of the stabilized soil is attributed to the formation of structural skeleton and the generation of cementitious hydration products within itself. Therefore, the investigations conducted in this study provide valuable references for chemical stabilization of warm and ice-rich frozen ground, thereby providing a basis for in-situ ground improvement for reinforcing warm and ice-rich permafrost foundations by soil-cement column installation.
文摘基于CFD分析软件Star CCM+,结合计算气动声学理论,对某汽车空气调节系统(HVAC)离心风机工作过程的流场和气动噪声进行数值模拟分析.采用Reynolds平均数值模拟(RANS)标准k-ε湍流模型模拟稳态流场,利用大涡模拟(LES)湍流模型和FW-H方程分析瞬态气动噪声,通过监测离心风机内部和外部布置点测得压力脉动,并由傅里叶变换得到监测点声压级频谱.结果表明,离心风机主要噪声是叶轮旋转产生的离散噪声(达98 d B),可适当增加叶片数,调整叶片间距,以减小离散噪声.本方法可为其他类型风机的气动噪声数值模拟提供一种有效的分析手段.