Application the Geometric Modeling Methods and Systems in Design Engineering and Manufacturing on Example of Agriculture Engineering

AbstractThis paper presents the geometric modeling methods based on the class and shape function transformation (CST) technique for the hypersonic vehicle. First, the typical waverider configuration is considered to be the basic shape for the hypersonic vehicle, and then the CST method is applied to describe and build the improved geometric shape. On this basis, the aerodynamic forces and thrust are estimated according to the shock wave and Rayleigh flow theory. Furthermore, the model dynamic features using the CST method are analyzed in comparison to the basic shape. Finally, the simulation results show the effectiveness of this method for the hypersonic vehicle.

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Geometric Modeling Methods for Cross-Sectional Profile of Welds in Tailored Blank Laser Welding

Laser & Optoelectronics Progress ◽

10.3788/lop54.091402 ◽

2017 ◽

Vol 54 (9) ◽

pp. 091402

Author(s):

邹媛媛 Zou Yuanyuan ◽

左克铸 Zuo Kezhu ◽

李鹏飞 Li Pengfei ◽

蔡尚 Cai Shang

Keyword(s):

Laser Welding ◽

Geometric Modeling ◽

Cross Sectional ◽

Modeling Methods ◽

Tailored Blank ◽

Cross Sectional Profile ◽

Sectional Profile

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Incremental Geometric Modeling and Mask Synthesis for Surface Micromachined MEMS

Volume 1A: 34th Computers and Information in Engineering Conference ◽

10.1115/detc2014-35558 ◽

2014 ◽

Author(s):

Jianhua Li ◽

Hao Ling ◽

Zhengchun Du

Keyword(s):

Geometric Modeling ◽

Process Model ◽

Microelectromechanical Systems ◽

Geometric Model ◽

Test Results ◽

Surface Micromachining ◽

Modeling Methods ◽

Variation Propagation ◽

Mems Device ◽

3D Geometric Model

In the design of surface micromachined microelectromechanical systems (MEMS), there is a lack of effective modeling methods to refine the geometry of a MEMS device. This paper presents a method of incremental geometric modeling and mask synthesis for surface micromachined MEMS. In this method, propagation-mapping graphs are introduced to label all the affected entities in one variation operation, according to the characteristic of surface micromachining. Based on the propagation-mapping graphs constructed from a 3D geometric model and its process model, variation propagation and mapping are used to update these models. In order to keep manufacturability of these models, four manufacturability problems caused by variation propagation are analyzed and a manufacturability maintenance method is discussed. Variation propagation and mapping achieve incremental modeling for the geometric model and process model of a MEMS device. This method enables designers to modify a MEMS device in a quick and intuitive way. Finally the method is implemented and some test results are given.

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Quasi-Newtonian methods for modeling of plan curve

Physico-mathematical modelling and informational technologies ◽

10.15407/fmmit2021.33.062 ◽

2021 ◽

pp. 62-67

Author(s):

Alla Nesterenko ◽

Oleksandr Duchenko

Keyword(s):

Numerical Modeling ◽

Geometric Modeling ◽

Input Data ◽

Extreme Points ◽

Distribution Coefficients ◽

Plane Curves ◽

Computer Implementation ◽

Nonlinear Integral Equations ◽

Modeling Methods ◽

Curvature Distribution

The paper is devoted to the methods of geometric modeling of plane curves given in the natural parameterization. The paper considers numerical modeling methods that make it possible to find the equation of curvature of the desired curve for different cases of the input data. The unknown curvature distribution coefficients of the required curve are determined by solving a system of nonlinear integral equations. Various numerical methods are considered to solve this nonlinear system. The results of computer implementation of the proposed methods for modeling two curvilinear contours with different initial data are presented. For the first curve, the input data are the coordinates of three points, the angles of inclination of the tangents at the extreme points and the linear law of curvature distribution. The second example considers an S-shaped curve with a quadratic law of curvature distributi.

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Geometric Modeling: Methods

Meshing, Geometric Modeling and Numerical Simulation 1 ◽

10.1002/9781119384335.ch7 ◽

2017 ◽

pp. 233-303

Keyword(s):

Geometric Modeling ◽

Modeling Methods

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Computer simulation the moldboard's surface in simplex system

E3S Web of Conferences ◽

10.1051/e3sconf/202126401029 ◽

2021 ◽

Vol 264 ◽

pp. 01029

Author(s):

Тojiddin Juraev ◽

Denis Voloshinov ◽

Rustam Xujakulov ◽

Abdurahim Qahharov ◽

Dilorom Ubaydullayeva

Keyword(s):

Computer Simulation ◽

Educational Research ◽

Geometric Modeling ◽

Simulation Models ◽

Computer Models ◽

Geometric Parameters ◽

Research Results ◽

Modeling Methods ◽

Production Processes ◽

Working Surface

There are considered the tasks of computer simulation of moldboard's surface in the article. The proposed solution is required in educational, research, and production processes. The researches were carried out using the constructive geometric modeling methods and systems. Objects of computer simulation were chosen the computer models of a directory curve, generative lines, and a frontal contour which are elements of the working surface. The geometric models of working surface elements developed based on research results were implemented in AutoCAD and SIMPLEX systems. The proposed simulation models can reduce the design period, simplify the geometric parameters' setting and facilitate the work of designers.

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Shape and Mesh Optimization Using Geometric Modeling Methods

10.2514/6.1990-1006 ◽

1990 ◽

Author(s):

C. FLEURY

Keyword(s):

Geometric Modeling ◽

Mesh Optimization ◽

Modeling Methods

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Generalized periodic surface model and its application in designing fibrous porous media

Engineering Computations ◽

10.1108/ec-03-2013-0085 ◽

2015 ◽

Vol 32 (1) ◽

pp. 7-36 ◽

Cited By ~ 8

Author(s):

Wei Huang ◽

Sima Didari ◽

Yan Wang ◽

Tequila A.L. Harris

Keyword(s):

Porous Media ◽

Geometric Modeling ◽

Cfd Simulation ◽

Three Dimensional ◽

Field Method ◽

Surface Model ◽

Periodic Surface ◽

Content Type ◽

Modeling Methods ◽

Fibrous Porous Media

Purpose – Fibrous porous media have a wide variety of applications in insulation, filtration, acoustics, sensing, and actuation. To design such materials, computational modeling methods are needed to engineer the properties systematically. There is a lack of efficient approaches to build and modify those complex structures in computers. The paper aims to discuss these issues. Design/methodology/approach – In this paper, the authors generalize a previously developed periodic surface (PS) model so that the detailed shapes of fibers in porous media can be modeled. Because of its periodic and implicit nature, the generalized PS model is able to efficiently construct the three-dimensional representative volume element (RVE) of randomly distributed fibers. A physics-based empirical force field method is also developed to model the fiber bending and deformation. Findings – Integrated with computational fluid dynamics (CFD) analysis tools, the proposed approach enables simulation-based design of fibrous porous media. Research limitations/implications – In the future, the authors will investigate robust approaches to export meshes of PS models directly to CFD simulation tools and develop geometric modeling methods for composite materials that include both fibers and resin. Originality/value – The proposed geometric modeling method with implicit surfaces to represent fibers is unique in its capability of modeling bent and deformed fibers in a RVE and supporting design parameter-based modification for global configuration change for the purpose of macroscopic transport property analysis.

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Use of the Magnetostatic Analogue In Electromagnetic Lens Engineering

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100068795 ◽

1970 ◽

Vol 28 ◽

pp. 360-361

Author(s):

John W. Coleman

Keyword(s):

Boundary Conditions ◽

High Performance ◽

Force Fields ◽

Optical Design ◽

Direct Conversion ◽

Design Engineering ◽

Design Data ◽

Scalar Potentials ◽

Geometric Elements ◽

At Will

In the design engineering of high performance electromagnetic lenses, the direct conversion of electron optical design data into drawings for reliable hardware is oftentimes difficult, especially in terms of how to mount parts to each other, how to tolerance dimensions, and how to specify finishes. An answer to this is in the use of magnetostatic analytics, corresponding to boundary conditions for the optical design. With such models, the magnetostatic force on a test pole along the axis may be examined, and in this way one may obtain priority listings for holding dimensions, relieving stresses, etc..The development of magnetostatic models most easily proceeds from the derivation of scalar potentials of separate geometric elements. These potentials can then be conbined at will because of the superposition characteristic of conservative force fields.

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