swinging strut

简明释义

旋转支柱

英英释义

例句

1.During the dance performance, the dancers incorporated a swinging strut to enhance their movements.

在舞蹈表演中，舞者们加入了摆动支杆来增强他们的动作。

2.The artist used a swinging strut as part of her installation to symbolize freedom and movement.

艺术家将摆动支杆作为她装置的一部分，以象征自由和运动。

3.The engineer designed a new bridge with a swinging strut to allow for better flexibility during high winds.

工程师设计了一座新桥，采用了摆动支杆以在强风中提供更好的灵活性。

4.The mechanic explained how the swinging strut in the suspension system affects the car's handling.

机械师解释了悬挂系统中的摆动支杆如何影响汽车的操控性。

5.In the amusement park, the ride featured a swinging strut mechanism that created thrilling motions.

在游乐园，游乐设施采用了摆动支杆机制，创造出刺激的运动效果。

作文

In the world of engineering and design, components often need to work in harmony to achieve the desired function. One such component that plays a crucial role in various mechanical systems is the swinging strut（摆动支杆）. This term refers to a structural element that can pivot or swing around a fixed point, allowing for movement while maintaining stability. The swinging strut is commonly found in applications ranging from automotive suspensions to architectural frameworks, where flexibility and strength are paramount.The importance of the swinging strut cannot be overstated. In vehicles, for example, it helps absorb shocks from the road, providing a smoother ride for passengers. When a car hits a bump, the swinging strut allows the wheel to move up and down, which in turn maintains contact with the road surface. This not only enhances comfort but also improves safety by ensuring better traction and control.In architecture, the swinging strut serves a different yet equally important purpose. It can be used to support structures like awnings or roofs, allowing them to withstand wind loads while still being able to flex under pressure. This flexibility is essential in regions prone to high winds or earthquakes, where rigid structures may fail. By incorporating a swinging strut, architects can design buildings that are both aesthetically pleasing and structurally sound.The mechanics behind the swinging strut are fascinating. Typically, it consists of a rod or beam that is connected to a pivot point. As forces are applied, the swinging strut rotates around this pivot, distributing the load evenly. This rotational motion is what makes the swinging strut so effective; it can adapt to varying conditions without compromising its integrity. Engineers must carefully calculate the dimensions and materials used for the swinging strut to ensure it can handle the expected loads without failure.Moreover, advancements in materials science have led to the development of stronger and lighter components, making the swinging strut even more efficient. Modern materials such as carbon fiber and advanced alloys not only reduce weight but also enhance performance. This has opened new avenues for innovation in both automotive and architectural designs, allowing for more daring and creative structures that were previously thought impossible.In conclusion, the swinging strut（摆动支杆） is an essential component in many fields, providing the necessary balance between flexibility and strength. Its ability to adapt to dynamic forces while maintaining structural integrity makes it invaluable in both vehicles and buildings. As technology continues to evolve, we can expect to see even more sophisticated applications of the swinging strut in the future, pushing the boundaries of what is possible in engineering and design. Understanding the role of the swinging strut helps us appreciate the intricate dance of mechanics that keeps our world moving smoothly and safely.

在工程和设计的世界中，各个组件往往需要协调工作以实现所需的功能。一个在各种机械系统中发挥关键作用的组件是摆动支杆。这个术语指的是一种可以围绕固定点旋转或摆动的结构元素，允许运动的同时保持稳定。摆动支杆通常出现在从汽车悬挂到建筑框架的应用中，其中灵活性和强度至关重要。摆动支杆的重要性不容小觑。例如，在车辆中，它有助于吸收来自路面的冲击，为乘客提供更平稳的乘坐体验。当一辆车遇到颠簸时，摆动支杆允许车轮上下移动，从而保持与路面接触。这不仅增强了舒适性，还通过确保更好的牵引力和控制提高了安全性。在建筑中，摆动支杆则起着不同但同样重要的作用。它可以用来支撑遮阳篷或屋顶等结构，使其能够承受风荷载，同时仍然能够在压力下弯曲。这种灵活性在高风或地震多发地区至关重要，因为刚性结构可能会失效。通过结合摆动支杆，建筑师可以设计出既美观又结构坚固的建筑。摆动支杆背后的机械原理令人着迷。通常，它由一个连接到支点的杆或梁组成。当施加力量时，摆动支杆围绕这个支点旋转，均匀分配负载。这种旋转运动使得摆动支杆如此有效；它可以适应不同的条件而不妥协其完整性。工程师必须仔细计算摆动支杆的尺寸和材料，以确保其能够承受预期的负载而不发生故障。此外，材料科学的进步使得更强大和更轻便的组件得以开发，使得摆动支杆更加高效。现代材料如碳纤维和先进合金不仅减轻了重量，还增强了性能。这为汽车和建筑设计中的创新开辟了新的途径，使得更大胆和创意的结构成为可能，之前被认为是不可能的。总之，摆动支杆是许多领域中不可或缺的组件，在灵活性和强度之间提供必要的平衡。它能够适应动态力量，同时保持结构完整性，使其在车辆和建筑中都具有无价的价值。随着技术的不断发展，我们可以期待在未来看到摆动支杆的更复杂应用，推动工程和设计领域的可能性边界。理解摆动支杆的作用帮助我们欣赏保持我们世界平稳和安全运行的机械舞蹈。