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相关概念视频

Bending of Curved Members - Neutral Surface01:16

Bending of Curved Members - Neutral Surface

238
In curved beams, unlike straight beams, the stress distribution across the cross-section is not uniform due to the beam's curvature. This non-uniformity arises because the neutral axis, where stress is zero, does not align with the centroid of the section. In a curved beam, the strain varies along the section as a function of the distance from the neutral axis.
Consider the curved member described in the previous lesson. According to Hooke's law, which relates stress to strain within...
238
Design Example: Traverse Angle Computations01:25

Design Example: Traverse Angle Computations

138
Traverse angle computations are a critical component of surveying, used to compute the internal angles within a closed traverse. A traverse consists of a series of connected lines forming a closed loop, often used for land boundary delineation or mapping. Calculating the internal angles ensures accuracy in the traverse geometry and is essential for checking survey data integrity.The process begins with known azimuths and bearings of the traverse sides. Internal angles at each vertex are...
138
Bending of Material: Problem Solving01:09

Bending of Material: Problem Solving

245
In this lesson, determine the ratio of the maximum bending moments applied to two metal pipes, given that both pipes can withstand a maximum stress of 100 MPa. Both pipes have an outer radius of 1.8 cm. Pipe A has an inner radius of 1.5 cm, and Pipe B has an inner radius of 1 cm. The ratio of the maximum bending moment applied to two metallic pipes, each with a different inner and outer radius, is determined by considering their dimensions. The inner radius of the first pipe is 1.5 cm, and for...
245
Design of Prismatic Beams for Bending01:23

Design of Prismatic Beams for Bending

371
The design of prismatic beams, structural elements with a uniform cross-section, focuses on ensuring safety and structural integrity under load. The design process begins by determining the allowable stress, either from material properties tables, or by dividing the material's ultimate strength by a safety factor. This safety factor is essential for accommodating uncertainties, and varies depending on the material—timber, steel, or concrete—with each having unique strength and...
371
Unsymmetric Loading of Thin-Walled Members: Problem Solving01:07

Unsymmetric Loading of Thin-Walled Members: Problem Solving

167
The shear center of a channel section with uniform thickness, height, and width, is determined by computing the shear force in the member and calculating the moments of inertia of the sections.
To compute the shear forces, find the shear flow at a specific distance from the endpoint using the vertical shear and the moment of inertia values. The total shear force on the flange is calculated by integrating the shear flow from one end of the flange to the other.
Next, calculate the moments of...
167
Three-Dimensional Force System:Problem Solving01:30

Three-Dimensional Force System:Problem Solving

860
A three-dimensional force system refers to a scenario in which three forces act simultaneously in three different directions. This type of problem is commonly encountered in physics and engineering, where it is necessary to calculate the resultant force on the system, which can then be used to predict or analyze the behavior of the object or structure under consideration.
To solve a three-dimensional force system, first resolve each force into its respective scalar components. Do this using...
860

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相关实验视频

Updated: Sep 12, 2025

Designing CAD/CAM Surgical Guides for Maxillary Reconstruction Using an In-house Approach
08:01

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使用CAD/CAM应用程序的元启发式方法对GHT-Bézier可开发表面的工程导向形状优化.

Samia BiBi1, Md Yushalify Misro1,2, Muhammad Abbas3

  • 1School of Mathematical Sciences, Universiti Sains Malaysia, 11800, Gelugor, Pulau Pinang, Malaysia.

Scientific reports
|August 5, 2025
PubMed
概括
此摘要是机器生成的。

本研究介绍了改良灰狼优化 (I-GWO) 技术,用于优化GHT-Bézier在CAD/CAM中的可开发表面. 该方法有效地改进了形状控制参数,以提高表面设计和制造.

关键词:
可开发性程度的程度.可以开发的表面.GHT-贝济耶曲线的曲线在I-GWO算法中,形状参数 形状参数

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科学领域:

  • 工程和CAD/CAM的设计.
  • 计算几何学的计算几何学
  • 优化技术 优化技术

背景情况:

  • 优化对于设计自由形表面和制造产品至关重要.
  • 现实世界的工程挑战往往使用客观函数的优化.

研究的目的:

  • 使用改良灰狼优化 (I-GWO) 技术呈现GHT-Bézier可开发表面的形状优化.
  • 为了找到最佳的形状控制参数,以改善表面设计.

主要方法:

  • 使用了改进的灰狼优化 (I-GWO) 的元启发算法.
  • 根据双曲线和插曲曲线的弧长 (AL),最小能量 (En) 和曲率变化能量 (CVEn) 制定了优化模型.
  • 采用代过程来确定最佳的形状控制参数.

主要成果:

  • 成功地应用了I-GWO技术来优化GHT-Bézier可开发表面.
  • 这些表面的构造是使用来自I-GWO的最佳形状参数来制定的.
  • 确定了由此产生的表面的可开发度.

结论:

  • I-GWO技术为GHT-Bézier可开发表面的形状优化提供了一种有效的方法.
  • 拟议的方法增强了工程中的表面设计和制造工艺.
  • 证明了开发方法的实际应用和有效性.