Hull/propeller interaction is of great importance for powering performance prediction. The features of hull/propeller interaction of a submarine model with a high-skew five blade propeller in submergence and near surf...Hull/propeller interaction is of great importance for powering performance prediction. The features of hull/propeller interaction of a submarine model with a high-skew five blade propeller in submergence and near surface conditions are numerically simulated. The effect of propeller rotation is simulated by the sliding mesh technique. Free surface is captured by the volume of fluid (VOF) method. Computed results including resistance, thrust, torque and self-propulsion factor are compared with experimental data. It shows fairly good agreement. The resistance and wave pattern of the model at different depths of submergence are computed. And the thrust, torque and self-propulsion factor of the model in submergence and near surface condition are compared to analyze the effect of free surface on self-propulsion performance. The results indicate that free surface has more influence on resistance than that on self-propulsion factors.展开更多
A mesh-less Refined Integral Algorithm (RIA) of Boundary Element Method (BEM) is proposed to accurately solve the Helmholtz Integral Equation (HIE).The convergence behavior and the practicability of the method a...A mesh-less Refined Integral Algorithm (RIA) of Boundary Element Method (BEM) is proposed to accurately solve the Helmholtz Integral Equation (HIE).The convergence behavior and the practicability of the method are validated.Computational Fluid Dynamics (CFD),Finite Element Method (FEM) and RIA are used to predict the propeller excited underwater noise of the submarine hull structure.Firstly the propeller and submarine's flows are independently validated,then the self propulsion of the "submarine+propeller" system is simulated via CFD and the balanced point of the system is determined as well as the self propulsion factors.Secondly,the transient response of the "submarine+ propeller" system is analyzed at the balanced point,and the propeller thrust and torque excitations are calculated.Thirdly the thrust and the torque excitations of the propeller are loaded on the submarine,respectively,to calculate the acoustic response,and the sound power and the main peak frequencies are obtained.Results show that:(1) the thrust mainly excites the submarine axial mode and the high frequency area appears at the two conical-type ends,while the torque mainly excites the circumferential mode and the high frequency area appears at the broadside of the cylindrical section,but with rather smaller sound power and radiation efficiency than the former,(2) the main sound source appears at BPF and 2BPF and comes from the harmonic propeller excitations.So,the main attention should be paid on the thrust excitation control for the sound reduction of the propeller excited submarine structure.展开更多
为研究艇后非均匀流场中大侧斜螺旋桨无空泡负载噪声的分布规律,文章采用"CFD+BEM"法,以SUBOFF潜艇后某大侧斜桨为研究对象,首先稳态计算均匀进流下螺旋桨敞水特性,模拟系数值与实验误差在3%以内,验证了CFD数值计算的可信性...为研究艇后非均匀流场中大侧斜螺旋桨无空泡负载噪声的分布规律,文章采用"CFD+BEM"法,以SUBOFF潜艇后某大侧斜桨为研究对象,首先稳态计算均匀进流下螺旋桨敞水特性,模拟系数值与实验误差在3%以内,验证了CFD数值计算的可信性。然后采用大涡(LES)模拟,对"艇+桨"进行三维非定常数值模拟,计算得到桨表面声偶极子数据后,通过距离加权平均法映射到声网格节点上,将噪声源直接分布在桨叶表面上进行积分来预报螺旋桨的低频线谱噪声。采用边界元法基于扇声源理论通过FW-H声类比方程分别在1 k Hz以内对桨盘面、轴向纵剖面及10倍桨半径球场的噪声进行频域求解。研究表明:桨盘面和轴向纵剖面上声指向均呈8字形,但受螺旋桨自身旋转及大侧斜的存在,指向性不唯一;球场声场显示,轴向声辐射面较大,声辐射强,径向辐射面小且辐射较弱;特征点的计算结果显示,高阶叶频声压级明显比一阶叶频低,这与物理现象相符,将特征点处结果与已发表文献进行对比,吻合性良好,并对存在的差异作出了合理的物理解释。该文为螺旋桨噪声预报介绍了一种可行的新方法。展开更多
文摘Hull/propeller interaction is of great importance for powering performance prediction. The features of hull/propeller interaction of a submarine model with a high-skew five blade propeller in submergence and near surface conditions are numerically simulated. The effect of propeller rotation is simulated by the sliding mesh technique. Free surface is captured by the volume of fluid (VOF) method. Computed results including resistance, thrust, torque and self-propulsion factor are compared with experimental data. It shows fairly good agreement. The resistance and wave pattern of the model at different depths of submergence are computed. And the thrust, torque and self-propulsion factor of the model in submergence and near surface condition are compared to analyze the effect of free surface on self-propulsion performance. The results indicate that free surface has more influence on resistance than that on self-propulsion factors.
文摘A mesh-less Refined Integral Algorithm (RIA) of Boundary Element Method (BEM) is proposed to accurately solve the Helmholtz Integral Equation (HIE).The convergence behavior and the practicability of the method are validated.Computational Fluid Dynamics (CFD),Finite Element Method (FEM) and RIA are used to predict the propeller excited underwater noise of the submarine hull structure.Firstly the propeller and submarine's flows are independently validated,then the self propulsion of the "submarine+propeller" system is simulated via CFD and the balanced point of the system is determined as well as the self propulsion factors.Secondly,the transient response of the "submarine+ propeller" system is analyzed at the balanced point,and the propeller thrust and torque excitations are calculated.Thirdly the thrust and the torque excitations of the propeller are loaded on the submarine,respectively,to calculate the acoustic response,and the sound power and the main peak frequencies are obtained.Results show that:(1) the thrust mainly excites the submarine axial mode and the high frequency area appears at the two conical-type ends,while the torque mainly excites the circumferential mode and the high frequency area appears at the broadside of the cylindrical section,but with rather smaller sound power and radiation efficiency than the former,(2) the main sound source appears at BPF and 2BPF and comes from the harmonic propeller excitations.So,the main attention should be paid on the thrust excitation control for the sound reduction of the propeller excited submarine structure.
基金Supported by National Nature Science Foundation of China(51009144)
文摘为研究艇后非均匀流场中大侧斜螺旋桨无空泡负载噪声的分布规律,文章采用"CFD+BEM"法,以SUBOFF潜艇后某大侧斜桨为研究对象,首先稳态计算均匀进流下螺旋桨敞水特性,模拟系数值与实验误差在3%以内,验证了CFD数值计算的可信性。然后采用大涡(LES)模拟,对"艇+桨"进行三维非定常数值模拟,计算得到桨表面声偶极子数据后,通过距离加权平均法映射到声网格节点上,将噪声源直接分布在桨叶表面上进行积分来预报螺旋桨的低频线谱噪声。采用边界元法基于扇声源理论通过FW-H声类比方程分别在1 k Hz以内对桨盘面、轴向纵剖面及10倍桨半径球场的噪声进行频域求解。研究表明:桨盘面和轴向纵剖面上声指向均呈8字形,但受螺旋桨自身旋转及大侧斜的存在,指向性不唯一;球场声场显示,轴向声辐射面较大,声辐射强,径向辐射面小且辐射较弱;特征点的计算结果显示,高阶叶频声压级明显比一阶叶频低,这与物理现象相符,将特征点处结果与已发表文献进行对比,吻合性良好,并对存在的差异作出了合理的物理解释。该文为螺旋桨噪声预报介绍了一种可行的新方法。