swinging strut

简明释义

旋转支架

英英释义

例句

1.The engineer explained how the swinging strut 摆动支杆 helps stabilize the bridge during high winds.

工程师解释了如何使用摆动支杆 swinging strut 在大风中稳定桥梁。

2.In the new roller coaster design, the swinging strut 摆动支杆 allows for greater flexibility and safety.

在新的过山车设计中，摆动支杆 swinging strut 允许更大的灵活性和安全性。

3.The architect included a swinging strut 摆动支杆 in the design to enhance the building's resilience.

建筑师在设计中加入了摆动支杆 swinging strut 以增强建筑的韧性。

4.During the demonstration, the swinging strut 摆动支杆 showcased its ability to absorb shock effectively.

在演示中，摆动支杆 swinging strut 展示了其有效吸收冲击的能力。

5.The mechanic adjusted the swinging strut 摆动支杆 to improve the vehicle's suspension system.

机械师调整了摆动支杆 swinging strut 以改善车辆的悬挂系统。

作文

In the world of engineering and design, the term swinging strut refers to a structural component that plays a crucial role in providing support and stability to various systems. The concept of a swinging strut is particularly relevant in mechanical systems where movement and flexibility are essential. Unlike rigid supports, a swinging strut allows for dynamic motion, making it an ideal choice for applications that require both strength and adaptability.For example, in the construction of bridges, engineers often incorporate swinging struts to accommodate the natural swaying and bending that occurs due to wind and traffic loads. This flexibility helps prevent structural failure by allowing the bridge to absorb and dissipate forces more effectively. Similarly, in the automotive industry, swinging struts are used in suspension systems to enhance vehicle performance and comfort. They enable the wheels to respond to uneven road surfaces while maintaining the overall stability of the vehicle.The design of a swinging strut involves careful consideration of materials and geometry. Engineers must ensure that the strut can withstand the forces it will encounter while still allowing for the necessary range of motion. Common materials used for swinging struts include steel and aluminum, which offer a good balance of strength and weight. Additionally, the angle at which the strut swings can significantly affect its performance, making precise calculations critical during the design phase.In addition to their practical applications, swinging struts also serve as a fascinating example of how engineering principles can be applied to solve complex problems. The ability to combine rigidity with flexibility is a hallmark of innovative design, and swinging struts exemplify this balance perfectly. As technology continues to evolve, the use of swinging struts is likely to expand into new areas, including robotics and aerospace, where adaptable structures are increasingly in demand.In conclusion, the term swinging strut encompasses a wide range of applications across various fields, highlighting the importance of flexibility in structural design. Whether in bridges, vehicles, or advanced machinery, swinging struts provide essential support while allowing for movement, demonstrating the ingenuity of engineers and designers. Understanding the function and significance of swinging struts not only enhances our appreciation of engineering but also inspires future innovations in design and technology.

在工程和设计的世界中，术语摆动支杆指的是一个结构组件，在为各种系统提供支持和稳定性方面发挥着至关重要的作用。摆动支杆的概念在机械系统中尤为相关，因为这些系统需要运动和灵活性。与刚性支撑不同，摆动支杆允许动态运动，使其成为需要强度和适应性的应用的理想选择。例如，在桥梁建设中，工程师通常会将摆动支杆纳入设计，以适应由于风和交通负荷造成的自然摇摆和弯曲。这种灵活性有助于防止结构失效，因为它使桥梁能够更有效地吸收和消散力量。同样，在汽车工业中，摆动支杆被用于悬挂系统，以增强车辆性能和舒适性。它们使车轮能够响应不平坦的路面，同时保持车辆的整体稳定性。摆动支杆的设计涉及对材料和几何形状的仔细考虑。工程师必须确保支杆能够承受它所遇到的力量，同时仍然允许必要的运动范围。用于制造摆动支杆的常见材料包括钢和铝，这些材料在强度和重量之间提供了良好的平衡。此外，支杆摆动的角度会显著影响其性能，因此在设计阶段进行精确计算至关重要。除了实际应用之外，摆动支杆也作为一个引人入胜的例子，展示了如何将工程原理应用于解决复杂问题。将刚性与灵活性结合的能力是创新设计的标志，而摆动支杆完美体现了这种平衡。随着技术的不断发展，摆动支杆的使用可能会扩展到新的领域，包括机器人技术和航空航天领域，在这些领域中，对可适应结构的需求日益增加。总之，术语摆动支杆涵盖了多个领域的广泛应用，突显了结构设计中灵活性的重要性。无论是在桥梁、车辆还是先进机械中，摆动支杆都提供了基本支持，同时允许运动，展示了工程师和设计师的创造力。理解摆动支杆的功能和重要性，不仅增强了我们对工程的欣赏，也激励着未来在设计和技术方面的创新。