swinging link

简明释义

摇杆

英英释义

例句

1.The design of the suspension system includes a swinging link 摆动连接 to absorb shocks.

悬挂系统的设计包括一个 swinging link 摆动连接 来吸收冲击。

2.The engineer explained how the swinging link 摆动连接 in the mechanism allows for greater flexibility.

工程师解释了机制中如何通过 swinging link 摆动连接 实现更大的灵活性。

3.During the test, the swinging link 摆动连接 showed signs of wear and needed replacement.

在测试过程中，swinging link 摆动连接 显示出磨损迹象，需要更换。

4.The bicycle's gear system utilizes a swinging link 摆动连接 to change speeds efficiently.

自行车的齿轮系统利用 swinging link 摆动连接 高效地改变速度。

5.In robotics, a swinging link 摆动连接 can help mimic natural movements.

在机器人技术中，swinging link 摆动连接 可以帮助模拟自然运动。

作文

In the world of mechanical engineering, various components play crucial roles in ensuring the proper functioning of machines. One such component is the swinging link, which is pivotal in many mechanisms, especially in the context of linkages and motion transmission. The swinging link refers to a movable part that can pivot around a fixed point, allowing for a range of motion that is essential in converting linear movement into rotational movement or vice versa. This characteristic makes it an invaluable asset in various applications, from simple mechanical systems to complex machinery.To better understand the significance of the swinging link, consider its application in a simple pendulum system. In this setup, the swinging link acts as the arm of the pendulum, swinging back and forth under the influence of gravity. This motion not only demonstrates the principles of physics but also highlights how the swinging link can be used to measure time accurately. The regular oscillation of the pendulum, facilitated by the swinging link, allows clocks to keep precise time, showcasing the importance of this component in everyday life.Moreover, the swinging link finds its utility in various machines, such as robotic arms and cranes. In these applications, the swinging link enables the manipulation of loads by providing a flexible yet controlled movement. For instance, in a robotic arm, the swinging link allows the arm to reach different positions and angles, thereby increasing the versatility of the robot. This capability is crucial in industries like manufacturing, where precision and flexibility are paramount.In addition to mechanical applications, the concept of the swinging link can be found in other fields, such as biology and architecture. In biology, certain organisms exhibit movements that can be likened to the action of a swinging link. For example, the way birds flap their wings involves a swinging motion that resembles the pivoting action of a swinging link. This natural phenomenon inspires engineers to design more efficient machines that mimic biological movements.Architecturally, the swinging link can be observed in structures that require dynamic movement, such as retractable roofs and bridges. These designs often incorporate elements that allow for smooth transitions and adjustments, much like the function of a swinging link. By enabling parts of a structure to move fluidly, architects can create versatile spaces that adapt to varying environmental conditions.In conclusion, the swinging link is a fundamental component in both mechanical and natural systems. Its ability to facilitate movement and adaptability makes it essential in various applications, from timekeeping devices to advanced robotics and architectural designs. Understanding the function and significance of the swinging link enhances our appreciation of the intricate mechanisms that govern both man-made and natural phenomena. As technology continues to evolve, the principles behind the swinging link will likely inspire further innovations, proving that even the simplest components can have profound impacts on our lives and the world around us.

在机械工程的世界中，各种组件在确保机器正常运行方面发挥着至关重要的作用。其中一个关键组件是摆动连杆，它在许多机制中至关重要，尤其是在连杆和运动传输的背景下。摆动连杆指的是一个可移动的部件，可以围绕固定点进行旋转，从而允许一系列运动，这对于将线性运动转换为旋转运动或反之亦然至关重要。这一特性使其在各种应用中成为无价之宝，从简单的机械系统到复杂的机器。为了更好地理解摆动连杆的重要性，可以考虑它在简单摆锤系统中的应用。在这个设置中，摆动连杆充当摆锤的臂，在重力的影响下来回摆动。这种运动不仅展示了物理学的原理，还突显了摆动连杆在准确测量时间方面的用途。摆锤的规律性摆动，由摆动连杆促进，使时钟能够保持精确的时间，展示了这一组件在日常生活中的重要性。此外，摆动连杆在各种机器中也发挥着作用，例如机器人手臂和起重机。在这些应用中，摆动连杆通过提供灵活但受控的运动来实现对负载的操控。例如，在机器人手臂中，摆动连杆使手臂能够达到不同的位置和角度，从而增加了机器人的多功能性。这种能力在制造等行业中至关重要，在这些行业中，精确性和灵活性是至关重要的。除了机械应用外，摆动连杆的概念还可以在生物学和建筑学等其他领域中找到。在生物学中，某些生物表现出的运动可以与摆动连杆的动作相提并论。例如，鸟类振翅的方式涉及一种摆动运动，类似于摆动连杆的旋转动作。这一自然现象激励工程师设计出更高效的模仿生物运动的机器。在建筑上，摆动连杆可以在需要动态运动的结构中观察到，例如可伸缩屋顶和桥梁。这些设计通常包含允许平滑过渡和调整的元素，就像摆动连杆的功能一样。通过使结构的某些部分能够流畅地移动，建筑师可以创造出适应不同环境条件的多功能空间。总之，摆动连杆是机械和自然系统中的基本组件。它促进运动和适应性的能力使其在各种应用中至关重要，从计时设备到先进的机器人和建筑设计。理解摆动连杆的功能和重要性增强了我们对支配人造和自然现象的复杂机制的欣赏。随着技术的不断发展，摆动连杆背后的原理可能会激励进一步的创新，证明即使是最简单的组件也能对我们的生活和周围世界产生深远的影响。