full-scale deflection

简明释义

满刻度偏转

英英释义

例句

1.To validate the design, the team conducted a full-scale deflection test on the new dam.

为了验证设计，团队对新大坝进行了全尺度偏转测试。

2.Understanding the full-scale deflection is crucial for predicting the performance of the building under extreme weather conditions.

理解全尺度偏转对于预测建筑在极端天气条件下的表现至关重要。

3.During the test, the full-scale deflection was recorded to analyze the structure's response to seismic activity.

在测试过程中，记录了全尺度偏转以分析结构对地震活动的反应。

4.The engineers measured the full-scale deflection of the bridge under heavy load to ensure its safety.

工程师测量了桥梁在重载下的全尺度偏转以确保其安全。

5.The research focused on the full-scale deflection of the aircraft wing during flight simulations.

研究集中在飞行模拟中飞机机翼的全尺度偏转。

作文

In the field of engineering and physics, the term full-scale deflection refers to the maximum displacement or movement that a structure or material can undergo under applied forces. Understanding this concept is crucial for engineers and designers, as it directly impacts the safety, functionality, and durability of various structures, from bridges to buildings. When designing a structure, engineers must take into account the materials used, the loads expected, and the environmental conditions that may affect the structure over time.The significance of full-scale deflection lies in its ability to provide insights into how a structure will behave under stress. For instance, when a bridge is subjected to heavy traffic, it experiences forces that cause it to bend or sway. The full-scale deflection helps engineers predict how much the bridge will deflect and whether it will return to its original shape once the load is removed. If the deflection exceeds acceptable limits, it may indicate potential structural failure, necessitating design modifications or reinforcements.Moreover, the concept of full-scale deflection is not limited to static loads; it also applies to dynamic loads such as wind or seismic activity. Engineers use advanced modeling techniques and simulations to analyze how these forces interact with structures. By understanding the full-scale deflection, they can ensure that buildings are designed to withstand extreme weather conditions or earthquakes, thereby protecting lives and property.In practical applications, measuring full-scale deflection can be achieved through various methods, including sensors and strain gauges. These devices provide real-time data on how much a structure is deflecting under load. This information is invaluable for maintenance and safety inspections, allowing engineers to make informed decisions about repairs or reinforcements needed to enhance the structure's integrity.Furthermore, the concept of full-scale deflection extends beyond traditional engineering applications. In the realm of aerospace, for example, aircraft wings are designed to flex and bend during flight. Understanding the full-scale deflection of these wings ensures that they can handle the aerodynamic forces without compromising safety or performance. Similarly, in automotive engineering, the chassis of a vehicle must be designed to absorb shocks and vibrations while maintaining structural integrity. Here, too, full-scale deflection plays a critical role in ensuring that vehicles can endure the stresses of everyday use.In conclusion, the term full-scale deflection encompasses a vital aspect of engineering design and analysis. It serves as a benchmark for assessing the performance and safety of structures under various loads and conditions. As technology advances, the methods for measuring and analyzing full-scale deflection continue to improve, enabling engineers to create safer, more efficient, and resilient structures. Ultimately, a thorough understanding of full-scale deflection is essential for anyone involved in the design and construction of buildings, bridges, and other critical infrastructure, ensuring that they can withstand the challenges posed by nature and human activity.

在工程和物理学领域，术语全尺度偏转指的是结构或材料在施加力下能够经历的最大位移或运动。理解这个概念对工程师和设计师至关重要，因为它直接影响到各种结构的安全性、功能性和耐用性，从桥梁到建筑物。在设计结构时，工程师必须考虑所用材料、预期负荷以及可能随时间影响结构的环境条件。全尺度偏转的重要性在于它能够提供关于结构在应力下如何表现的见解。例如，当一座桥梁受到重型交通的作用时，它会经历导致其弯曲或摇摆的力量。全尺度偏转帮助工程师预测桥梁将弯曲多少，以及在负载移除后它是否会恢复到原始形状。如果偏转超过可接受的限制，这可能表明潜在的结构故障，需进行设计修改或加固。此外，全尺度偏转的概念不仅限于静态负载；它也适用于风或地震等动态负载。工程师使用先进的建模技术和模拟来分析这些力量如何与结构相互作用。通过理解全尺度偏转，他们可以确保建筑物设计能够抵御极端天气条件或地震，从而保护生命和财产。在实际应用中，测量全尺度偏转可以通过各种方法实现，包括传感器和应变计。这些设备提供了关于结构在负载下偏转多少的实时数据。这些信息对于维护和安全检查至关重要，使工程师能够做出关于修复或加固的明智决策，以增强结构的完整性。此外，全尺度偏转的概念超越了传统的工程应用。例如，在航空航天领域，飞机机翼被设计为在飞行过程中弯曲和屈曲。理解这些机翼的全尺度偏转确保它们能够承受空气动力学力量，而不妨碍安全或性能。类似地，在汽车工程中，车辆的底盘必须设计成能够吸收冲击和振动，同时保持结构完整性。在这里，全尺度偏转同样在确保车辆能够承受日常使用的压力中发挥着关键作用。总之，术语全尺度偏转涵盖了工程设计和分析的一个重要方面。它作为评估结构在各种负载和条件下性能和安全性的基准。随着技术的进步，测量和分析全尺度偏转的方法不断改进，使工程师能够创造更安全、更高效和更具韧性的结构。最终，全面理解全尺度偏转对于任何参与建筑、桥梁和其他关键基础设施设计和施工的人来说都是必不可少的，确保它们能够抵御自然和人类活动带来的挑战。