lateral thrust

简明释义

横向推力

英英释义

例句

1.In this experiment, we measured the lateral thrust (侧向推力) generated by the moving vehicle.

在这个实验中，我们测量了移动车辆产生的 lateral thrust (侧向推力)。

2.The engineer explained how the lateral thrust (侧向推力) from the wind affected the building's design.

工程师解释了风的 lateral thrust (侧向推力) 如何影响建筑设计。

3.Engineers must consider lateral thrust (侧向推力) when designing bridges.

工程师在设计桥梁时必须考虑 lateral thrust (侧向推力)。

4.The pilot had to adjust for lateral thrust (侧向推力) during the turbulence.

在颠簸期间，飞行员不得不调整以应对 lateral thrust (侧向推力)。

5.The boat capsized due to an unexpected lateral thrust (侧向推力) from the waves.

由于波浪意外产生的 lateral thrust (侧向推力)，船只倾覆了。

作文

In the field of engineering and physics, the concept of lateral thrust plays a crucial role in understanding the forces acting on structures and vehicles. lateral thrust refers to the force that acts horizontally, perpendicular to the direction of motion, and is essential in various applications such as aerospace, civil engineering, and automotive design. This essay will explore the significance of lateral thrust, its applications, and the implications it has on safety and performance.To begin with, lateral thrust is particularly important in the context of aircraft design. When an airplane is in flight, it experiences various forces: lift, weight, thrust, and drag. Among these, lateral thrust becomes significant during maneuvers such as turns. As the aircraft banks to change direction, the wings generate lift that has both vertical and horizontal components. The horizontal component creates a lateral thrust that allows the aircraft to turn effectively. Understanding this force helps engineers design wings and control surfaces that can handle the stresses involved during flight, ensuring both efficiency and safety.Similarly, in civil engineering, lateral thrust is a critical factor when designing structures like bridges and buildings. For instance, when wind blows against a skyscraper, it exerts a horizontal force on the structure. Engineers must account for this lateral thrust to ensure that the building can withstand such forces without collapsing. Failure to consider lateral thrust can lead to catastrophic failures, as seen in some historical cases where buildings were not designed to handle unexpected lateral forces.In the automotive industry, lateral thrust is also vital when considering vehicle dynamics. During a turn, a car experiences forces that push it outward due to inertia. The tires must generate enough friction to counteract this lateral thrust to keep the vehicle on its intended path. Engineers analyze lateral thrust when designing suspension systems and tires, aiming to enhance stability and control. This analysis is crucial for performance cars, where high-speed cornering can generate significant lateral thrust, potentially leading to loss of control if not properly managed.Moreover, the implications of lateral thrust extend beyond just engineering applications. In sports, athletes must understand how lateral thrust affects their movements. For example, a sprinter needs to generate sufficient lateral thrust when changing direction to maintain speed and avoid injury. Coaches and trainers often incorporate drills that focus on improving an athlete's ability to manage and utilize lateral thrust effectively.In conclusion, the concept of lateral thrust is integral to various fields, including aerospace, civil engineering, automotive design, and sports. Its understanding is paramount for ensuring safety, efficiency, and performance. As technology advances, the study of lateral thrust will continue to evolve, leading to better designs and enhanced capabilities across multiple disciplines. By acknowledging the importance of this horizontal force, professionals can make informed decisions that ultimately contribute to safer and more effective systems and practices.

在工程和物理学领域，lateral thrust（侧向推力）的概念在理解作用于结构和车辆的力方面起着至关重要的作用。lateral thrust指的是一种水平作用的力，垂直于运动方向，对于航空航天、土木工程和汽车设计等各种应用至关重要。本文将探讨lateral thrust的重要性、其应用以及对安全性和性能的影响。首先，lateral thrust在飞机设计中尤为重要。当飞机在飞行时，它会经历多种力：升力、重力、推力和阻力。在这些力中，lateral thrust在转弯等机动过程中变得显著。当飞机倾斜以改变方向时，机翼产生的升力具有垂直和水平两个分量。水平分量产生的lateral thrust使飞机能够有效转弯。理解这一力有助于工程师设计能够承受飞行中所涉及应力的机翼和控制面，从而确保效率和安全。同样，在土木工程中，lateral thrust是设计桥梁和建筑物等结构时的关键因素。例如，当风吹向摩天大楼时，它会对结构施加水平力。工程师必须考虑这一lateral thrust，以确保建筑能够承受此类力量而不倒塌。如果不考虑lateral thrust，可能会导致灾难性的失败，正如一些历史案例所示，这些建筑未能设计以应对意外的侧向力。在汽车行业中，lateral thrust在考虑车辆动态时也至关重要。在转弯时，汽车由于惯性会经历向外推的力。轮胎必须产生足够的摩擦力来抵消这种lateral thrust，以保持车辆在预定轨迹上。工程师在设计悬挂系统和轮胎时会分析lateral thrust，旨在提高稳定性和控制能力。这一分析对于高性能汽车尤其重要，因为高速转弯可能会产生显著的lateral thrust，如果管理不当，可能导致失控。此外，lateral thrust的影响不仅限于工程应用。在体育运动中，运动员必须理解lateral thrust如何影响他们的动作。例如，短跑运动员在改变方向时需要产生足够的lateral thrust以维持速度并避免受伤。教练和训练师通常会加入专注于改善运动员管理和有效利用lateral thrust能力的训练。总之，lateral thrust的概念在多个领域中都是不可或缺的，包括航空航天、土木工程、汽车设计和体育运动。理解这一点对于确保安全、效率和性能至关重要。随着技术的进步，lateral thrust的研究将继续发展，从而在多个学科中带来更好的设计和增强的能力。通过承认这一水平力的重要性，专业人员可以做出明智的决策，从而最终有助于更安全、更有效的系统和实践。