residual maximum stability lever

简明释义

临界吃水critical draft剩余稳性最大值

英英释义

例句

1.By fine-tuning the residual maximum stability lever, the team was able to enhance the overall system reliability.

通过微调剩余最大稳定杠杆，团队能够提高整体系统的可靠性。

2.Operators must be trained to manipulate the residual maximum stability lever for optimal machine operation.

操作员必须接受培训，以操控剩余最大稳定杠杆以实现最佳机器操作。

3.The residual maximum stability lever plays a crucial role in maintaining the balance of the aircraft during turbulence.

在颠簸期间，剩余最大稳定杠杆在保持飞机平衡方面发挥着至关重要的作用。

4.In the latest simulation, the residual maximum stability lever was adjusted to test the limits of the design.

在最新的模拟中，调整了剩余最大稳定杠杆以测试设计的极限。

5.To ensure the structure remains safe under extreme conditions, engineers adjusted the residual maximum stability lever to optimize performance.

为了确保结构在极端条件下保持安全，工程师调整了剩余最大稳定杠杆以优化性能。

作文

In the realm of engineering and mechanics, understanding concepts that govern stability is crucial for ensuring safety and efficiency. One such concept is the residual maximum stability lever, which plays a significant role in various applications, from structural engineering to aerospace dynamics. The term itself can be dissected into three components: residual, maximum, and stability lever. Each of these elements contributes to a comprehensive understanding of how systems maintain balance and resist external forces.The word 'residual' refers to what remains after a process has taken place. In our context, it signifies the leftover forces or moments acting on a structure or system after accounting for all applied loads. The 'maximum' aspect indicates the peak level of stability that can be achieved under specific conditions. Finally, the term 'stability lever' embodies the idea of a mechanical advantage or a point of leverage that helps maintain equilibrium.When we combine these terms, the residual maximum stability lever can be understood as a measure of the remaining stability that a system can utilize to counteract destabilizing forces. This concept is particularly important in fields like civil engineering, where structures must withstand various loads, including wind, earthquakes, and other dynamic forces. Engineers often calculate the residual maximum stability lever to ensure that buildings and bridges can endure unexpected stresses without collapsing.Moreover, in the field of aerospace engineering, the residual maximum stability lever is vital for aircraft design. Pilots need to understand how their aircraft will respond to turbulence and other environmental factors. By analyzing the residual maximum stability lever, engineers can create aircraft that not only perform well under normal conditions but also retain control and stability during adverse situations.Understanding the residual maximum stability lever is not just an academic exercise; it has real-world implications. For instance, consider a scenario where a bridge is subjected to heavy traffic and strong winds. Engineers must assess the residual maximum stability lever to determine whether the bridge can safely accommodate the additional stress without risking structural failure. Failure to account for this could lead to catastrophic consequences, underscoring the importance of this concept in practical applications.In conclusion, the residual maximum stability lever is a critical concept in engineering that encapsulates the idea of maintaining stability in the face of external forces. By understanding and applying this principle, engineers can design safer structures and systems that not only meet but exceed safety standards. As technology advances and new materials are developed, the relevance of the residual maximum stability lever will continue to grow, ensuring that we build a more resilient future. Knowledge of such concepts empowers engineers and designers to innovate while prioritizing safety and stability in their creations.

在工程和力学领域，理解控制稳定性的概念对于确保安全和效率至关重要。其中一个重要的概念是剩余最大稳定杠杆，它在从结构工程到航空动力学的各种应用中发挥着重要作用。这个术语本身可以分解为三个组成部分：剩余、最大和稳定杠杆。这些元素共同构成了对系统如何保持平衡和抵御外部力量的全面理解。“剩余”一词指的是经过某个过程后所剩下的部分。在我们的上下文中，它表示在考虑所有施加负载后作用于结构或系统的剩余力或力矩。“最大”的方面表明在特定条件下可以实现的稳定性峰值。最后，“稳定杠杆”一词体现了机械优势或帮助维持平衡的支点的概念。当我们将这些术语结合起来时，剩余最大稳定杠杆可以理解为系统利用的剩余稳定性的度量，以抵消不稳定的力量。这个概念在土木工程等领域尤为重要，因为结构必须承受包括风、地震和其他动态力量在内的各种负载。工程师通常计算剩余最大稳定杠杆以确保建筑物和桥梁能够承受意外压力而不发生倒塌。此外，在航空航天工程领域，剩余最大稳定杠杆对于飞机设计至关重要。飞行员需要了解他们的飞机如何应对湍流和其他环境因素。通过分析剩余最大稳定杠杆，工程师可以制造出在正常条件下表现良好，但在不利情况下仍能保持控制和稳定的飞机。理解剩余最大稳定杠杆不仅仅是一种学术练习；它具有现实世界的影响。例如，考虑一个桥梁在重型交通和强风的作用下的场景。工程师必须评估剩余最大稳定杠杆以确定桥梁是否能够安全地承受额外的压力，而不冒着结构失效的风险。未能考虑这一点可能导致灾难性的后果，突显了这一概念在实际应用中的重要性。总之，剩余最大稳定杠杆是工程中的一个关键概念，它概括了在外部力量面前保持稳定的思想。通过理解和应用这一原理，工程师可以设计出更安全的结构和系统，不仅满足而且超越安全标准。随着技术的进步和新材料的发展，剩余最大稳定杠杆的相关性将继续增长，确保我们建立一个更具韧性的未来。对这些概念的了解使工程师和设计师能够在优先考虑安全和稳定的同时进行创新。