sliding limb

简明释义

游标尺;星形针

英英释义

例句

1.In the assembly line, the sliding limb helps in adjusting the position of components easily.

在装配线上，滑动肢体有助于轻松调整组件的位置。

2.During the experiment, the sliding limb was crucial for measuring the force applied.

在实验过程中，滑动肢体对于测量施加的力量至关重要。

3.The design of the chair includes a sliding limb mechanism for height adjustment.

椅子的设计包括一个用于高度调节的滑动肢体机制。

4.The sliding limb on the model allowed it to mimic realistic movements.

模型上的滑动肢体使其能够模拟真实的动作。

5.The robot's arm features a sliding limb that allows for greater flexibility in movement.

机器人的手臂具有一个滑动肢体，可以实现更大的运动灵活性。

作文

In the world of mechanics and engineering, the term sliding limb refers to a component that moves linearly along a predetermined path. This concept is crucial in various applications, such as machinery, robotics, and even in everyday objects like sliding doors or windows. The design and functionality of a sliding limb can significantly affect the efficiency and effectiveness of the system it is part of.To better understand the significance of a sliding limb, let us consider its application in robotics. Robots often rely on precise movements to perform tasks, and a well-designed sliding limb can enhance their agility and accuracy. For instance, in robotic arms, the sliding limb allows for smooth transitions between different positions, enabling the robot to grasp, lift, and manipulate objects with ease. This capability is vital in industries like manufacturing, where robots are employed to assemble products quickly and accurately.Moreover, the sliding limb plays a critical role in ensuring safety and reliability in mechanical systems. In many machines, components are designed to slide over one another to reduce friction and wear. This sliding action is essential in preventing breakdowns and prolonging the lifespan of equipment. For example, in automotive engineering, the pistons within an engine operate through a sliding limb mechanism, converting fuel into motion efficiently. If these components did not function correctly, it could lead to catastrophic failures.In addition to its mechanical advantages, the sliding limb concept can also be applied to architecture. Consider sliding glass doors, which provide seamless transitions between indoor and outdoor spaces. The sliding limb mechanism in these doors allows them to open and close effortlessly, enhancing accessibility and flow in a home or commercial space. This design not only maximizes natural light but also improves energy efficiency by minimizing air leaks when closed.Furthermore, the sliding limb has implications in the realm of physics. When studying motion, understanding how objects slide past one another helps scientists and engineers develop more accurate models of movement. Whether it's analyzing the forces acting on a sliding limb or predicting its behavior under different conditions, this knowledge is fundamental in fields such as biomechanics, where researchers study the human body's movements.In conclusion, the term sliding limb encompasses a wide range of applications across various disciplines. From enhancing the functionality of robots to improving architectural designs, the principles behind a sliding limb are integral to advancing technology and design. As we continue to innovate and create new systems, the importance of understanding and optimizing sliding limbs will only grow, driving progress in engineering, mechanics, and beyond.

在机械和工程的世界中，术语滑动肢体指的是沿着预定路径线性移动的组件。这个概念在各种应用中至关重要，比如机械、机器人，甚至在日常物品中，如滑动门或窗户。滑动肢体的设计和功能可以显著影响其所处系统的效率和有效性。为了更好地理解滑动肢体的重要性，让我们考虑它在机器人中的应用。机器人通常依赖精确的运动来执行任务，而设计良好的滑动肢体可以增强它们的灵活性和准确性。例如，在机器人手臂中，滑动肢体允许在不同位置之间平滑过渡，使机器人能够轻松抓取、提升和操作物体。这种能力在制造等行业中至关重要，因为机器人被用来快速而准确地组装产品。此外，滑动肢体在确保机械系统的安全性和可靠性方面也发挥着关键作用。在许多机器中，组件被设计为相互滑动，以减少摩擦和磨损。这种滑动动作对于防止故障和延长设备使用寿命是必不可少的。例如，在汽车工程中，发动机内的活塞通过滑动肢体机制运作，将燃料高效转化为运动。如果这些组件无法正常工作，可能会导致灾难性的故障。除了机械优势之外，滑动肢体的概念还可以应用于建筑学。考虑滑动玻璃门，它们提供了室内和室外空间之间无缝的过渡。这个门中的滑动肢体机制使它们能够轻松开关，提高了家庭或商业空间的可达性和流动性。这种设计不仅最大化了自然光，还通过最小化关闭时的空气泄漏提高了能效。此外，滑动肢体在物理学领域也有影响。在研究运动时，理解物体如何相互滑动有助于科学家和工程师开发更准确的运动模型。无论是分析作用于滑动肢体上的力还是预测其在不同条件下的行为，这些知识对于生物力学等领域至关重要，研究人员在该领域研究人类身体的运动。总之，术语滑动肢体涵盖了多个学科中的广泛应用。从增强机器人的功能到改善建筑设计，滑动肢体背后的原则是推动技术和设计进步的基础。随着我们继续创新和创建新系统，理解和优化滑动肢体的重要性只会增加，推动工程、机械及其他领域的发展。