change of displacement per inchtrim

简明释义

每英寸纵倾排水量变化

英英释义

例句

1.The technician measured the change of displacement per inch trim to ensure the machinery operated within safe limits.

技术员测量了每英寸修整位移变化以确保机器在安全范围内运行。

2.Understanding the change of displacement per inch trim is crucial for optimizing the performance of the hydraulic system.

理解每英寸修整位移变化对于优化液压系统的性能至关重要。

3.The report highlighted the change of displacement per inch trim as a key factor in the machinery's efficiency.

报告强调了每英寸修整位移变化作为机器效率的关键因素。

4.During the calibration process, we observed a change of displacement per inch trim that required further adjustments.

在校准过程中，我们观察到每英寸修整位移变化，需要进一步调整。

5.The engineer noted a significant change of displacement per inch trim during the testing phase, which indicated potential issues in the design.

工程师注意到测试阶段有显著的每英寸修整位移变化，这表明设计可能存在问题。

作文

In the field of engineering and physics, understanding various parameters is crucial for effective design and analysis. One such parameter that often comes into play is the change of displacement per inch trim. This phrase refers to the amount of displacement or movement that occurs in a system for every inch of adjustment made to its trim settings. Trim, in this context, usually pertains to the adjustments made to the balance or orientation of an object, especially in fields like aerodynamics or marine engineering.To comprehend the importance of the change of displacement per inch trim, let us consider an example involving an aircraft. When pilots adjust the trim of an aircraft, they are essentially modifying the aerodynamic forces acting on the wings and tail. This adjustment can significantly affect the aircraft's stability and control. The change of displacement per inch trim provides a quantifiable measure of how much the aircraft's position changes in response to these adjustments. A higher value indicates that even a small trim change can lead to significant displacement, which might be critical during flight operations.Similarly, in marine engineering, the concept plays a vital role in the design of boats and ships. When a vessel is trimmed, it alters its angle relative to the water surface, affecting its speed, fuel efficiency, and overall performance. Knowing the change of displacement per inch trim helps engineers predict how the vessel will behave under different loading conditions and sea states. This information is essential for ensuring safety and optimizing the vessel's performance.Moreover, the change of displacement per inch trim becomes particularly relevant in the context of performance tuning. Engineers and designers use this metric to fine-tune systems, ensuring that they respond appropriately to input adjustments. For instance, in automotive engineering, the suspension system's responsiveness can be analyzed through this parameter, allowing for improved handling and ride quality.Understanding the change of displacement per inch trim also requires a grasp of related concepts such as moment arms and leverage. These principles help explain why certain adjustments yield more substantial effects than others. For example, if an adjustment is made further away from the pivot point, it will result in a greater displacement compared to an adjustment made closer to the pivot. Thus, engineers must carefully consider the geometry of their designs when analyzing the implications of trim adjustments.In conclusion, the change of displacement per inch trim is a critical concept in various engineering disciplines, serving as a foundational element for understanding how systems respond to adjustments. Whether in aviation, marine engineering, or automotive design, this metric allows for the optimization of performance and safety. As technology advances and systems become more complex, the importance of mastering such parameters will only grow, underscoring the need for engineers to be well-versed in these fundamental concepts.

在工程和物理领域，理解各种参数对有效的设计和分析至关重要。其中一个经常出现的参数是每英寸修整位移变化。这个短语指的是在系统的修整设置每调整一英寸时发生的位移或移动量。在这个上下文中，修整通常涉及对物体的平衡或方向进行的调整，特别是在气动学或海洋工程等领域。为了理解每英寸修整位移变化的重要性，让我们考虑一个涉及飞机的例子。当飞行员调整飞机的修整时，他们实际上是在修改作用于机翼和尾部的气动力。这种调整可以显著影响飞机的稳定性和控制。每英寸修整位移变化提供了一个可量化的度量，说明飞机在这些调整下位置变化的程度。较高的值表明，即使是小的修整变化也可能导致显著的位移，这在飞行操作中可能至关重要。同样，在海洋工程中，这个概念在船只和舰艇的设计中发挥着重要作用。当船只被修整时，它会改变相对于水面的位置角度，影响其速度、燃油效率和整体性能。了解每英寸修整位移变化有助于工程师预测船只在不同装载条件和海况下的表现。这些信息对于确保安全和优化船只性能至关重要。此外，每英寸修整位移变化在性能调优的背景下尤其相关。工程师和设计师利用这一指标对系统进行微调，以确保它们对输入调整作出适当反应。例如，在汽车工程中，悬挂系统的响应能力可以通过该参数进行分析，从而改善操控性和乘坐质量。理解每英寸修整位移变化还需要掌握相关概念，如力矩臂和杠杆原理。这些原理帮助解释为什么某些调整产生的效果比其他调整更大。例如，如果在离支点更远的地方进行调整，相比于在离支点更近的地方进行调整，将导致更大的位移。因此，工程师在分析修整调整的影响时，必须仔细考虑设计的几何形状。总之，每英寸修整位移变化是各个工程学科中的一个关键概念，作为理解系统如何响应调整的基础元素。无论是在航空、海洋工程还是汽车设计中，这一指标都有助于优化性能和安全。随着技术的进步和系统的复杂性增加，掌握这些参数的重要性将愈加突出，这强调了工程师在这些基本概念上需具备扎实的知识。