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相关概念视频

Instantaneous Center of Zero Velocity01:20

Instantaneous Center of Zero Velocity

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General plane motion, often observed in a rolling wheel, refers to a type of movement where the wheel is simultaneously rotating and translating. This complex motion can be understood by breaking it down into individual components.
To analyze this, consider two points on the wheel: point A and point B. The absolute velocity of point B can be expressed as the vector sum of the absolute velocity of point A and the relative velocity of point B with respect to point A. To simplify this analysis,...
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One-Degree-of-Freedom System01:24

One-Degree-of-Freedom System

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In mechanical engineering, one-degree-of-freedom systems form the basis of a wide range of electrical and mechanical components. Using these models, engineers can predict the behavior of various parts in a larger system, which gives them insight into how different forces interact with each other.
A one-degree-of-freedom system is defined by an independent variable that determines its state and behavior. One example of a one-degree-of-freedom system is a simple harmonic oscillator, such as a...
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Energy Diagrams - II01:10

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Energy diagrams are important to understand the dynamics of a system. The topology of an energy diagram helps illustrate the equilibrium points of the system.
The point in the energy diagram at which the system’s potential energy is the lowest is known as the local minima. The system tends to stay in this position indefinitely unless acted upon by a net force. The slope of the potential energy diagram at the local minima is zero, indicating that zero net force is acting on the system. The...
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Beams with Symmetric Loadings01:15

Beams with Symmetric Loadings

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The moment-area method is an analytical tool used in structural engineering to determine the slope and deflection of beams under various loads. Consider a cantilever with a concentrated load and moment at the free end. The first step is constructing a free-body diagram to calculate the reactions at the fixed end. Next, the bending moment diagram is plotted to visualize how the bending moment varies along the beam's length, focusing on points where the bending moment equals zero.
The M/EI...
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Beams with Unsymmetric Loadings01:17

Beams with Unsymmetric Loadings

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Analyzing a supported beam under unsymmetrical loadings is essential in structural engineering to understand how beams respond to varied force distributions. This analysis involves calculating the deflection and identifying points where the slope of the beam is zero, which are crucial for ensuring structural stability and functionality.
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Rolling Resistance: Problem Solving01:17

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Rolling resistance, also known as rolling friction, is the force that resists the motion of a rolling object, such as a wheel, tire, or ball, when it moves over a surface. It is caused by the deformation of the object and the surface in contact with each other, as well as other factors like internal friction, hysteresis, and energy losses within the materials. Rolling resistance opposes the object's motion, requiring additional energy to overcome it and maintain movement. In practical...
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使用零弹性能量模式进行光可转向的机车运动.

Zixuan Deng1, Kai Li2, Arri Priimagi1

  • 1Faculty of Engineering and Natural Sciences, Tampere University, Tampere, Finland.

Nature materials
|October 4, 2024
PubMed
概括
此摘要是机器生成的。

这项研究介绍了一种以光燃料为燃料的液晶弹性体体,能够进行自主,自我维持的运动. 它的运动方向是光学控制的,可在软机器人应用的各种环境中实现敏捷导航.

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科学领域:

  • 软物质物理学 软物质物理学
  • 机器人技术 机器人技术 机器人技术
  • 材料科学是一种材料科学.

背景情况:

  • 从合成材料中实现自主和可引导的机器人运动对于先进的应用至关重要.
  • 分散机制可以使物质失去平衡,从而实现自我维持的运动.
  • 在各种环境中控制敏捷运动仍然是软机器人的重大挑战.

研究的目的:

  • 开发一种轻燃料软材料系统,用于实现自主,自我维持的机器人运动.
  • 在各种环境中展示动态的方向性和敏捷的运动.
  • 探索预先训练的拓结构在失衡软物质机器人技术中的潜力.

主要方法:

  • 液晶弹性体体的制造,具有预先排列的拓结构.
  • 利用恒定的光激发来诱导自我维持的失衡运动.
  • 利用动态摩擦和阻力来进行运动方向的光学控制.

主要成果:

  • 液晶弹性体体在恒定的光激发下表现出自发旋转,这是由于零弹性能量模式.
  • 运动方向在干燥和流体环境中都是光学控制的.
  • 在斯托克斯模式下展示横向和垂直游泳,在三维空间中具有可转向性.

结论:

  • 轻型燃料软液晶弹性体 tori 为自主机器人功能提供了一个新的平台.
  • 预先约束的拓结构是实现可引导,失衡的软物质机器人的关键.
  • 已证明的光学运动控制为先进的软机器人系统开辟了可能性.