strut-arm angle

简明释义

尾轴架支臂倾角

英英释义

例句

1.The technician adjusted the strut-arm angle to improve the vehicle's handling.

技术人员调整了支撑臂角度以改善车辆的操控性。

2.If the strut-arm angle is too steep, it can affect the suspension performance.

如果支撑臂角度过陡，会影响悬挂性能。

3.A misaligned strut-arm angle can lead to uneven tire wear.

不对齐的支撑臂角度可能导致轮胎磨损不均。

4.During the inspection, we measured the strut-arm angle to ensure it was within specifications.

在检查过程中，我们测量了支撑臂角度以确保其在规格范围内。

5.The mechanic explained how the strut-arm angle influences the ride quality.

机械师解释了支撑臂角度如何影响乘坐质量。

作文

The world of engineering is filled with complex terms and concepts that often require a deep understanding to grasp fully. One such term is the strut-arm angle, which plays a significant role in various mechanical and structural applications. To understand the importance of the strut-arm angle, we must first delve into the components involved in this concept. A strut is a structural element designed to resist longitudinal compression, while an arm typically refers to a lever or a support that extends from a pivot point. The angle formed between these two elements, therefore, is crucial for determining the stability and strength of a structure.In many engineering designs, particularly in automotive and aerospace industries, the strut-arm angle can influence the performance and safety of vehicles. For instance, in suspension systems, the strut-arm angle affects how weight is distributed across the vehicle, impacting handling and ride comfort. An optimal strut-arm angle ensures that the forces acting on the suspension are balanced, allowing for better control and stability during operation.Moreover, the strut-arm angle is not just limited to vehicles; it is also relevant in architectural design. In buildings, the angle at which struts are placed can determine how loads are transferred through the structure, influencing its overall integrity. Engineers must carefully calculate the strut-arm angle to ensure that the building can withstand environmental forces such as wind and earthquakes.Understanding the strut-arm angle also involves recognizing the mathematical principles behind it. The angle can be measured using trigonometry, where the relationships between angles and sides of triangles are explored. By applying these principles, engineers can predict how changes to the strut-arm angle will affect the performance of a system. For example, increasing the angle might enhance stability but could also lead to increased stress on certain components.In conclusion, the strut-arm angle is a vital aspect of engineering that influences the functionality and safety of various structures and mechanisms. Whether in the context of vehicles or buildings, understanding this angle allows engineers to design more effective and reliable systems. As technology continues to evolve, so too will the methods used to analyze and optimize the strut-arm angle, ensuring that our structures remain safe and efficient for years to come.

工程学的世界充满了复杂的术语和概念，这些术语和概念往往需要深入理解才能完全掌握。其中一个术语是支撑臂角度，它在各种机械和结构应用中扮演着重要角色。要理解支撑臂角度的重要性，我们必须首先探讨与此概念相关的组成部分。支撑是一个结构元素，旨在抵抗纵向压缩，而臂通常指的是从支点延伸出的杠杆或支撑。因此，这两个元素之间形成的角度对于确定结构的稳定性和强度至关重要。在许多工程设计中，特别是在汽车和航空航天工业中，支撑臂角度会影响车辆的性能和安全性。例如，在悬架系统中，支撑臂角度会影响车辆的重量分布，从而影响操控和乘坐舒适性。最佳的支撑臂角度确保作用在悬架上的力是平衡的，从而在操作过程中实现更好的控制和稳定性。此外，支撑臂角度不仅限于车辆；它在建筑设计中也很相关。在建筑物中，支撑的放置角度可以决定负载如何通过结构传递，从而影响其整体完整性。工程师必须仔细计算支撑臂角度，以确保建筑物能够承受风和地震等环境力量。理解支撑臂角度还涉及到认识其背后的数学原理。可以使用三角学来测量角度，探索角度与三角形边之间的关系。通过应用这些原理，工程师可以预测对支撑臂角度的变化将如何影响系统的性能。例如，增加角度可能会增强稳定性，但也可能导致某些组件承受更大的压力。总之，支撑臂角度是工程学中一个至关重要的方面，它影响着各种结构和机制的功能和安全性。无论是在车辆还是建筑的背景下，理解这个角度使工程师能够设计出更有效和可靠的系统。随着技术的不断发展，分析和优化支撑臂角度的方法也将不断演变，确保我们的结构在未来多年保持安全和高效。