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Muscle Contraction01:15

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The torque-free motion refers to the movement of a rigid body in space when no external torques are acting upon it. This type of motion can be observed in environments where there are no external forces or frictions, like in outer space. For example, a rotation of Mars in space is a torque-free motion. Mars is an axisymmetric object, meaning it has an axis of symmetry along which it rotates, designated as the z-axis. The rotating frame of reference is defined such that the center of mass of...
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Mechanical Systems01:22

Mechanical Systems

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Mechanical systems are analogous to to electrical networks where springs and masses play similar roles to inductors and capacitors, respectively. A viscous damper in mechanical systems functions similarly to a resistor in electrical networks, dissipating energy. The forces acting on a mass in such systems include an applied force in the direction of motion, counteracted by forces from the spring, a viscous damper, and the mass's acceleration. This interplay of forces is mathematically...
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When materials are subjected to forces that surpass their yield strength, they undergo a process known as plastic deformation. This results in a permanent alteration or strain in their structure. This concept can be specifically applied to circular shafts, where the deformation leads to a change in its shape. The precise evaluation of this plastic deformation requires understanding the stress distribution within the circular shaft, which is achieved by calculating the maximum shearing stress in...
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One of the distinctive characteristics of circular shafts is their ability to maintain their cross-sectional integrity under torsion. In other words, each cross-section continues to exist as a flat, unaltered entity, simply rotating like a solid, rigid slab. To understand the distribution of shearing stress within such a shaft, consider a cylindrical section inside this circular shaft. This section has a length of L and a radius of R, with one end fixed. The radius of the cylindrical section is...
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Author Spotlight: Advancing Tendon Tissue Engineering with 3D Organoid Models
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建模肌驱动的同心管机器人

Yash Chitalia1, Abdulhamit Donder2, Pierre E Dupont2

  • 1Healthcare Robotics and Telesurgery (HeaRT) Laboratory, University of Louisville, Louisville, Kentucky, USA.

... International Symposium on Medical Robotics. International Symposium on Medical Robotics
|February 15, 2024
PubMed
概括

本研究介绍了一种新的基于机械的混合连续机器人模型,它结合了肌驱动和同心管. 管道之间的相对扭转显著影响机器人的形状,这对于医疗应用至关重要.

科学领域:

  • 机器人技术 机器人技术 机器人技术
  • 机械工程 机械工程
  • 医疗器械设计 医疗器械设计

背景情况:

  • 基于机械的模型存在于肌驱动连续机器人和同心管机器人分别.
  • 现有的模型不涉及混合设计,将肌驱动和同心管结合在一起.
  • 这些混合机器人适用于医疗应用,如内镜和心内手术.

研究的目的:

  • 为混合肌驱动的同心管机器人推出基于机械的模型.
  • 用数值和物理实验来评估模型的准确性.
  • 了解影响这些混合机器人的形状的关键因素.

主要方法:

  • 开发一种基于机械学的新型模型,将肌力量和时刻与同心管配置相结合.
  • 数字模拟用于根据衍生模型预测机器人的形状.
  • 物理实验使用一对肌驱动的管子来验证模型预测.

主要成果:

  • 衍生模型准确地描述了肌驱动的同心管机器人的形状.
  • 数字和物理实验证实了模型的有效性.
  • 肌驱动管之间的相对扭曲被确定为决定机器人的整体形状的关键因素.

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结论:

  • 已经建立了一个经过验证的基于机械的模型,用于混合肌驱动的同心管机器人.
  • 该模型为设计和控制医疗应用中的这些机器人提供了基础.
  • 相对管子扭曲是控制机器人形状的关键设计参数,类似于同心管机器人.