transverse thrust

简明释义

侧推力

英英释义

例句

1.Understanding the transverse thrust is essential for optimizing the performance of the racing car.

理解横向推力对于优化赛车性能至关重要。

2.The engineers calculated the transverse thrust to ensure the bridge's stability during high winds.

工程师计算了横向推力以确保桥梁在强风中的稳定性。

3.The architect considered the transverse thrust when designing the cantilevered balcony.

建筑师在设计悬臂阳台时考虑了横向推力。

4.In the design of the aircraft wings, the transverse thrust plays a crucial role in maintaining balance.

在飞机机翼的设计中，横向推力在保持平衡方面起着至关重要的作用。

5.The team used sensors to measure the transverse thrust generated by the turbine during operation.

团队使用传感器测量涡轮在运行期间产生的横向推力。

作文

The concept of transverse thrust is often encountered in various fields of engineering, particularly in structural and mechanical contexts. In simple terms, transverse thrust refers to the force that acts perpendicular to the main axis of an object or structure. This phenomenon can be observed in numerous applications, including bridges, buildings, and even in the design of aircraft wings. Understanding how transverse thrust operates is crucial for engineers and architects to ensure the stability and safety of their designs.One of the most common examples of transverse thrust can be found in the construction of bridges. When vehicles travel across a bridge, they exert loads that create forces acting in different directions. The weight of the vehicles generates vertical loads, while the wind can create lateral forces. These lateral forces manifest as transverse thrust, which the bridge must be designed to withstand. Engineers must calculate the potential transverse thrust that could occur during high winds or seismic activity to ensure that the structure remains stable and does not collapse.In addition to bridges, transverse thrust plays a significant role in the aerospace industry. Aircraft wings are designed to generate lift, but they also experience forces acting perpendicular to their length. This is particularly important during maneuvers such as turns, where the change in direction can create substantial transverse thrust. Engineers must consider these forces when designing wings to ensure that they can handle the stresses without failing. The materials used in wing construction, as well as their shape and size, are all influenced by the need to accommodate transverse thrust.Moreover, transverse thrust is not limited to large structures; it is also relevant in smaller mechanical systems. For instance, in the design of rotating machinery, such as turbines or motors, the forces generated during operation can lead to transverse thrust. If not properly managed, this thrust can cause misalignment or wear in mechanical components, leading to premature failure. Engineers must therefore incorporate features that can absorb or counteract transverse thrust to prolong the lifespan of these machines.In summary, the understanding of transverse thrust is essential across various engineering disciplines. Whether in the context of large infrastructures like bridges or in the design of aircraft wings and rotating machinery, the forces that act perpendicular to the primary axis of an object must be carefully considered. Failure to account for transverse thrust can result in structural failures, safety hazards, and costly repairs. Therefore, engineers must continually study and apply principles related to transverse thrust to develop safe and efficient designs. As technology advances, the methods used to analyze and mitigate transverse thrust will undoubtedly evolve, leading to even more innovative solutions in engineering practices.

‘横向推力’的概念常常出现在各种工程领域，特别是在结构和机械背景下。简单来说，‘横向推力’是指作用于物体或结构主轴垂直方向的力。这种现象可以在许多应用中观察到，包括桥梁、建筑物甚至飞机机翼的设计。理解‘横向推力’的运作对于工程师和建筑师确保其设计的稳定性和安全性至关重要。‘横向推力’最常见的例子可以在桥梁的建造中找到。当车辆通过桥梁时，它们施加的负载会产生不同方向的力。车辆的重量产生垂直负载，而风则可能产生横向力。这些横向力表现为‘横向推力’，桥梁必须设计成能够承受这种推力。工程师必须计算在强风或地震活动期间可能发生的‘横向推力’，以确保结构保持稳定而不坍塌。除了桥梁外，‘横向推力’在航空航天行业也起着重要作用。飞机机翼被设计用来产生升力，但它们也会受到作用于其长度方向的力。这在转弯等机动过程中尤为重要，因为方向的改变会产生相当大的‘横向推力’。工程师在设计机翼时必须考虑这些力，以确保它们能够承受压力而不会失效。机翼的材料、形状和大小都受到需要适应‘横向推力’的影响。此外，‘横向推力’不仅限于大型结构；它在较小的机械系统中也相关。例如，在旋转机械（如涡轮机或电动机）的设计中，操作过程中产生的力可能导致‘横向推力’。如果没有得到妥善管理，这种推力可能导致机械部件的失调或磨损，从而导致过早失效。因此，工程师必须设计出可以吸收或抵消‘横向推力’的特征，以延长这些机器的使用寿命。总之，理解‘横向推力’在各个工程学科中都是至关重要的。无论是在桥梁等大型基础设施的背景下，还是在飞机机翼和旋转机械的设计中，作用于物体主轴垂直方向的力必须得到仔细考虑。如果不考虑‘横向推力’，可能会导致结构失效、安全隐患和昂贵的维修。因此，工程师必须不断研究并应用与‘横向推力’相关的原理，以开发安全高效的设计。随着技术的进步，用于分析和减轻‘横向推力’的方法无疑会不断发展，从而在工程实践中带来更具创新性的解决方案。