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相关概念视频

General State of Stress01:21

General State of Stress

736
The general state of stress within a material can be accurately depicted using a stress tensor. This tensor encapsulates the internal forces distributed within a material subjected to external forces or deformations.
Specifically, consider a tetrahedral element where one face, labeled XYZ, is perpendicular to the line OA, and the remaining faces align with the coordinate axes with point O as the origin. At any point, such as point O, the stress tensor can be used to determine the stress...
736
Stress01:20

Stress

8.9K
When a force is applied on a body, it undergoes deformation. In order to restore the body to its original shape and/or size, an opposite or restoring force is generated within the body. This restoring force is equal to the magnitude of the applied force, but acts in the opposite direction. The amount of this restoring force developed per unit area of the body is called stress. Stress is a tensor quantity and has the SI unit pascal. Stress can be separated into four broad categories depending...
8.9K
Components of Stress01:23

Components of Stress

609
Stress analysis under multiple loading conditions is intricate, necessitating a comprehensive grasp of normal and shearing stresses. Consider a small cube at point O, subjected to stress on all six faces, visible or not. Normal stress components σx, σy, σz act perpendicularly to the x, y, and z axes. Shearing stress components τxy and τxz are exerted on faces perpendicular to these axes.
Interestingly, the hidden cube faces also experience these stresses, equal and...
609
Stress: General Loading Conditions01:15

Stress: General Loading Conditions

652
To grasp the intricacy of real-world conditions where multiple loads are applied simultaneously to a structure, one might visualize a section passing through a specific point within a body, aligned parallel to the xy plane. This section is subjected to various forces, including original loads, normal forces, and shearing forces.
The shearing force, possessing potential directionality within the plane of the section, is simplified into two component forces running parallel to the x and y axes....
652
Transformation of Plane Stress01:18

Transformation of Plane Stress

813
Studying stress transformation is essential in understanding how stress components within a material, like a cube under plane stress, change with rotation. This change is analyzed by considering a prismatic element within the cube. As the element rotates, the stress components acting on it—both normal and shearing stresses—change in magnitude and orientation. This change is quantified using trigonometric functions of the rotation angle, relating the forces acting on the rotated element's...
813
Stresses under Combined Loadings01:23

Stresses under Combined Loadings

517
When analyzing a bent tube with a circular cross-section subjected to multiple forces, it is crucial to determine the stress distribution in order to maintain structural integrity under varied load conditions.
The process begins by slicing the tube at critical points and analyzing the internal forces and stress components at these sections, focusing on the centroid. Normal stresses, generated by axial forces and bending moments, are either compressive or tensile and vary across the section from...
517

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Biaxial Mechanical Characterizations of Atrioventricular Heart Valves
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卡西米尔 压力度 压力度

Yuquan Zhou1, Zhuhua Zhang1, Xiaofei Liu1

  • 1Nanjing University of Aeronautics and Astronautics, State Key Laboratory of Mechanics and Control for Aerospace Structures, Key Laboratory for Intelligent Nano Materials and Devices of Ministry of Education, Nanjing, 210016, People's Republic of China.

Physical review letters
|March 13, 2026
PubMed
概括
此摘要是机器生成的。

量子波动产生卡西米尔力,导致纳米级物体运动. 这项研究量化了卡西米尔应力和弹性变形,揭示了重要的几何效应和顶点附近的应力度.

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科学领域:

  • 纳米尺度物理学的物理学
  • 量子力学就是量子力学.
  • 固体机械学 固体机械学

背景情况:

  • 卡西米尔力源于量子波动,并影响纳米级物体.
  • 描述卡西米尔诱导的刚体运动已经确立,但由于不明确的卡西米尔应力,量化弹性变形是很困难的.
  • 了解卡西米尔应力对于预测纳米级弹性变形至关重要.

研究的目的:

  • 推进对卡西米尔压力的理解和量化.
  • 研究几何学对卡西米尔应力和弹性变形的影响.
  • 开发一种计算卡西米尔诱导弹性变形的方法.

主要方法:

  • 开发了一种专门的边界元素方法来计算卡西米尔应力.
  • 使用原型形板系统进行分析.
  • 采用了转换光学分析和正常化的应力分布.

主要成果:

  • 发现卡西米尔应力度与经典力学相似.
  • 一个非接触板缩在顶点附近,对斜坡施加压力,超过了近距离力近似预测.
  • 几何奇点扰乱了麦克斯韦应力轨迹,导致应力度.
  • 观察到卡西米尔应力的尺度不变.

结论:

  • 几何效应显著影响卡西米尔应力.
  • 开发的方法促进了基于卡西米尔的弹性力学.
  • 这项研究为理解纳米尺度变形提供了一个新的框架.