kinematic link

简明释义

运动链

英英释义

例句

1.In robotics, a robot arm consists of multiple segments connected by a kinematic link 运动链 that allows for movement and manipulation.

在机器人技术中，机器人手臂由多个段组成，这些段通过一个运动链连接，允许移动和操控。

2.A bicycle's pedals and crank are connected through a kinematic link 运动链 that transfers force effectively.

自行车的踏板和曲柄通过一个运动链连接，有效地传递力量。

3.Engineers analyze the kinematic link 运动链 in a mechanical system to predict its behavior under different loads.

工程师分析机械系统中的运动链，以预测其在不同负载下的行为。

4.In animation, a character's limbs can be animated using a kinematic link 运动链 system for more realistic movements.

在动画中，可以使用运动链系统为角色的四肢进行动画处理，以实现更现实的动作。

5.The design of a vehicle's suspension system relies heavily on the kinematic link 运动链 to ensure smooth ride quality.

车辆悬挂系统的设计在很大程度上依赖于运动链，以确保平稳的乘坐质量。

作文

In the field of mechanics and robotics, the term kinematic link refers to a component of a mechanical system that connects two or more parts, allowing for movement between them. Understanding the concept of kinematic link is essential for engineers and designers who work on machines, vehicles, and robotic systems. A kinematic link can be as simple as a rod connecting two gears or as complex as a multi-jointed robotic arm that mimics human motion.The primary function of a kinematic link is to facilitate the transmission of motion and forces within a mechanism. For instance, in a car's suspension system, the kinematic link plays a crucial role in ensuring that the wheels maintain contact with the road surface while absorbing shocks from bumps and potholes. This connection allows for controlled movement and stability, which are vital for safe driving.Moreover, in robotics, the design of a kinematic link is critical for achieving desired movements and tasks. Robotic arms, for example, consist of multiple kinematic links that work together to perform intricate tasks such as assembling products or performing surgeries. Each kinematic link must be precisely calculated to ensure that the arm can reach its target position without colliding with other objects or exceeding its range of motion. This requires a deep understanding of both kinematics and dynamics.The analysis of kinematic links often involves the use of mathematical models and simulations. Engineers utilize these tools to predict how a system will behave under various conditions, allowing them to optimize the design of each kinematic link for maximum efficiency and effectiveness. By simulating different scenarios, they can identify potential issues before physical prototypes are built, saving time and resources in the development process.In addition to their practical applications, kinematic links also have theoretical significance in the study of motion. The principles governing kinematic links are foundational to the broader field of kinematics, which examines how objects move in space without considering the forces that cause the motion. This area of study is fundamental in physics and engineering, providing insights into the behavior of all types of moving systems.As technology continues to advance, the role of kinematic links in innovative designs becomes increasingly important. In the development of autonomous vehicles, for example, the precise control of kinematic links is necessary for navigating complex environments safely. Similarly, in the field of biomechanics, understanding kinematic links can lead to improved prosthetics and rehabilitation devices that enhance mobility for individuals with disabilities.In conclusion, the concept of kinematic link is integral to many fields, including engineering, robotics, and physics. Its ability to connect different components and facilitate movement makes it a vital element in the design and analysis of mechanical systems. As we continue to explore new technologies and applications, the importance of kinematic links will undoubtedly grow, highlighting the need for ongoing research and innovation in this area.

在机械和机器人领域，术语运动连杆指的是机械系统的一个组件，它连接两个或多个部分，允许它们之间的运动。理解运动连杆的概念对从事机器、车辆和机器人系统工作的工程师和设计师至关重要。运动连杆可以简单如连接两个齿轮的杆，也可以复杂如多关节的机器人手臂，模拟人类运动。运动连杆的主要功能是促进机械内部运动和力的传递。例如，在汽车悬挂系统中，运动连杆在确保车轮与路面保持接触的同时吸收颠簸和坑洼带来的冲击方面发挥着关键作用。这种连接允许受控运动和稳定性，这对安全驾驶至关重要。此外，在机器人技术中，运动连杆的设计对实现所需的运动和任务至关重要。例如，机器人手臂由多个运动连杆组成，这些连杆共同工作以执行复杂的任务，如组装产品或进行手术。每个运动连杆必须精确计算，以确保手臂能够到达目标位置，而不会与其他物体发生碰撞或超出其运动范围。这需要对运动学和动力学有深入的理解。运动连杆的分析通常涉及数学模型和模拟的使用。工程师利用这些工具预测系统在各种条件下的行为，从而优化每个运动连杆的设计，以实现最大效率和效果。通过模拟不同的场景，他们可以在物理原型构建之前识别潜在问题，从而节省开发过程中的时间和资源。除了实际应用外，运动连杆在运动研究中也具有理论意义。支配运动连杆的原则是运动学更广泛领域的基础，该领域研究物体在空间中的运动，而不考虑导致运动的力量。这一研究领域是物理学和工程学的基础，为所有类型的运动系统行为提供了见解。随着技术的不断进步，运动连杆在创新设计中的作用变得越来越重要。例如，在自主车辆的开发中，精准控制运动连杆对于安全地导航复杂环境是必要的。同样，在生物力学领域，理解运动连杆可以导致改善假肢和康复设备，从而增强残疾人士的移动能力。总之，运动连杆的概念对于许多领域，包括工程、机器人和物理学，是不可或缺的。它连接不同组件并促进运动的能力使其成为机械系统设计和分析中的重要元素。随着我们继续探索新技术和应用，运动连杆的重要性无疑会增长，突显出在这一领域持续研究和创新的必要性。