客户机程序必须对工作进行划分,并将工作单元传递给网格中间件供其处理。
A client program must subdivide the work to be done and pass the pieces to the grid middleware for processing.
将螺旋体分解成螺旋轴和螺旋叶片两部分,建立LS200螺旋体结构的CAD模型,并对其进行有限元网格的划分。
CAD model of LS200 helical structure is established by dividing the helical body into helical axis and helical blade and finite element meshing is performed.
提出了一种对三角网格模型进行自动四边区域划分的算法。
A new algorithm was proposed to partition triangular meshes into quadrangular segmentation automatically.
采用合适的材料性质和实体单元类型对模型进行智能有限元网格划分。
Proper material features and entity unit type were used for intellectual finite element mesh division.
对界面端区域进行了有限元网格单元划分。
The finite mesh elements near the interface edge region are carefully divided.
最后,运用简缩积分单元对计算模型进行网格划分,采用显式积分方法完成计算。
Finally, the grid division of the computational model is completed using the reduced integral unit, and the explicit integral is introduced to complete the calculation.
以三角形靶标的视觉锐度为基准,设计了无缝三角形网格划分算法,对典型识别概率的实测红外目标图像进行了等效三角形划分,确定了目标对应的等效三角形数目;
The infrared target in the real background were closely meshed into many equivalent triangle patterns by considering visual acuity, and the number of triangle pattern was statistically determined.
最后利用该程序对某汽车公司匹卡车的第一横梁和某汽车油杯进行了网格划分,成功地实现了网格划分的参数化。
Finally, the first beam of the Pick-Up car of an automobile company and an oil-cup are meshed parametrically succeed with this program.
分析了单元数量、质量、布局的前提下,用壳单元对整个车身进行网格划分,建立了详细车身有限元模型。
On the pre- mise of analysis of element quantities, quality and distribution, the whole car body is meshed by using shell element in order to establish the detailed model for FEM analysis.
研究了用有限元法对复杂机械结构进行强度分析的方法和步骤,对复杂机械结构的建模方法和网格划分进行了探讨。
The methods of analyzing the strength of complex mechanical structure were studied through the application of the finite element method, and the methods of building model and gridding were discussed.
本文对HSCAE-3DRF6.0的网格处理所涉及的关键技术模块进行了研究,包括输入文件的形式、二维网格的划分、三维实体网格的划分三个部分。
The key technology of the HSCAE-3DRF6.0 in the meshing part has been discussed in this paper including the types of the input file, the mesh of surface and the mesh of solid.
在划分计算网格时,采用了混合网格生成技术,并对细小的结构进行了网格的局部细化。
Mixed gridding technology is applied at gridding drawing process, and the gridding of small structure is minished.
其中,对燃烧器的复杂几何形状没有进行任何简化,实现了包括炉膛的结构化网格划分。
Structured grid is made with no simplification and modification of the complicated structure in the hearth and burner.
最后对有限元分析误差进行评估及原因分析,并得出有限元分析计算时网格划分并不是越细小越好,关键是"适度"的结论。
So a conclusion that the mesh is not the smaller the better when you analyze through FEA is educed, the key point is to choose a proper mesh size.
另一方面,对裂隙单元进行三角形单元的有限元网格划分,运用变分原理导出裂隙单元的渗流有限元求解方程。
On the other hand, the fracture elements are discretized into triangular mesh, and the flow finite element equations are derived based on the variational principle.
首先,构建三维皮卡车模型,确定计算区域,对计算区域进行网格划分。
First, the simplified model of the pick-up truck body and the computational domain ware set up, the grids ware divided accordingly.
第三章对洗舱效果进行评估,结合射流结构参数分析,利用有限单元理论和网格划分技术以及能量守恒定律,得出合理的评估结果。
By techniques of grid plot, grid corresponding and energy conservation law, finished the simulation and the evaluation on effect of tank cleaning.
该算法的优点在于勿需对刀齿进行离散,也不需对工件进行三维网格划分,通用性好。
The advantage of this algorithm is that it does not have to discretize the cutting edge, nor does it need the dimensional gridding of the work piece.
对几种三角网格和四边形网格划分方法进行了较为详细的描述;并分析了方法的优缺点。
Some typical algorithms in triangular meshes and quadrilateral meshes are described in detail, and the advantage and disadvantage of the algorithms were analyzed.
本文对已发表的有限元网格划分方法进行了综述,并对其进行了分类和优缺点分析。
The published mesh generation methods are reviewed. The methods are classified and their advantages and disadvantages are analysed.
通过对ANSYS模型建立和网格划分模块的系统分析,结合巷道支护经验,找出了对U 29型钢可缩性支架进行模拟计算的方法。
Through systematic analysis of ANSYS modelling and meshing module, incorporation roadway design experience, a simulation calculation method on U29-type steel flexible support was found out.
考虑井底附近的渗流特点,对径向网格采用径向等对数划分的方法进行了处理。
In combination with the percolation characteristics in near bottom-hole area, radical grid was treated with logarithmic method.
对物理模型进行了三维有限元网格划分,配备材料特性参数,选用三维块状单元进行有限元计算分析,得到在外力作用下的应力分布和其它相关结果。
After the model is divided into elements by 3D brick unit and input the material parameters, the solution will be done under the restrain conditions and loads.
对物理模型进行了三维有限元网格划分,配备材料特性参数,选用三维块状单元进行有限元计算分析,得到在外力作用下的应力分布和其它相关结果。
After the model is divided into elements by 3D brick unit and input the material parameters, the solution will be done under the restrain conditions and loads.
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