terminal pressure

简明释义

端压力

英英释义

例句

1.In fluid dynamics, the concept of terminal pressure 终端压力 helps in understanding how fluids behave under different conditions.

在流体动力学中，终端压力 终端压力的概念有助于理解流体在不同条件下的行为。

2.The terminal pressure 终端压力 at which the engine operates determines its efficiency and thrust output.

发动机运行的终端压力 终端压力决定了其效率和推力输出。

3.Understanding terminal pressure 终端压力 is crucial for aerospace engineers when designing atmospheric entry vehicles.

理解终端压力 终端压力对航空航天工程师在设计大气进入飞行器时至关重要。

4.During the final phase of the flight, engineers monitor the terminal pressure 终端压力 to predict the vehicle's performance.

在飞行的最后阶段，工程师监测终端压力 终端压力以预测飞行器的性能。

5.The design of the rocket engine must account for the terminal pressure 终端压力 to ensure it can operate efficiently in space.

火箭发动机的设计必须考虑到终端压力 终端压力，以确保其在太空中有效运行。

作文

In the field of physics and engineering, the term terminal pressure is often used to describe the pressure at which a system reaches its final state during a process. This concept is particularly important in thermodynamics, fluid dynamics, and various applications involving gas and liquid systems. Understanding terminal pressure is crucial for engineers and scientists as it helps them predict the behavior of fluids under different conditions. For instance, in the design of aircraft, knowing the terminal pressure can inform engineers about the performance of the aircraft at high altitudes, where the atmospheric pressure is significantly lower than at sea level.When an aircraft ascends, the pressure around it decreases, which affects the performance of engines and the lift generated by the wings. Engineers must calculate the terminal pressure to ensure that the aircraft can operate efficiently and safely at cruising altitude. If the terminal pressure is not accurately determined, it could lead to catastrophic failures or inefficiencies that compromise the safety of the flight.Similarly, in the context of fluid flow in pipes, the terminal pressure is essential for understanding how fluids behave under various conditions. For example, when designing a pipeline system, engineers need to account for factors such as friction, elevation changes, and temperature variations that can all influence the terminal pressure within the system. If the terminal pressure is too low, it could result in insufficient flow rates, leading to inadequate supply for consumers or processes relying on that fluid.The concept of terminal pressure also extends to various scientific experiments, particularly those involving gases. For instance, when conducting experiments in a controlled environment, researchers must consider the terminal pressure of the gas being studied. This is especially true in studies related to chemical reactions, where the pressure can significantly affect reaction rates and product yields. By understanding the terminal pressure, scientists can manipulate experimental conditions to achieve desired outcomes.Moreover, terminal pressure plays a vital role in the field of environmental science, particularly in studying the effects of climate change. As global temperatures rise, the behavior of gases in the atmosphere changes, leading to fluctuations in terminal pressure. This, in turn, can affect weather patterns, precipitation, and the overall health of ecosystems. Environmental scientists must monitor these changes to develop effective strategies for mitigating the impacts of climate change.In conclusion, the term terminal pressure encompasses a wide range of applications across various fields, from aerospace engineering to environmental science. Its significance lies in the ability to predict and understand the behavior of fluids and gases under different conditions. By mastering the concept of terminal pressure, professionals in these fields can ensure the safety, efficiency, and sustainability of their designs and experiments. As technology continues to advance, the importance of accurately determining terminal pressure will only become more critical in addressing the challenges faced by modern society.

在物理和工程领域，术语终端压力通常用于描述系统在过程中达到最终状态时的压力。这个概念在热力学、流体动力学以及涉及气体和液体系统的各种应用中尤其重要。理解终端压力对工程师和科学家至关重要，因为它帮助他们预测流体在不同条件下的行为。例如，在飞机设计中，了解终端压力可以告知工程师关于飞机在高空飞行时的性能，因为那时大气压力显著低于海平面。当飞机上升时，周围的压力下降，这会影响发动机的性能和机翼产生的升力。工程师必须计算终端压力以确保飞机在巡航高度能够高效、安全地运行。如果没有准确确定终端压力，可能导致灾难性的故障或效率低下，从而危及飞行安全。同样，在管道内流体流动的背景下，终端压力对于理解流体在各种条件下的行为至关重要。例如，在设计管道系统时，工程师需要考虑摩擦、海拔变化和温度变化等因素，这些因素都会影响系统内的终端压力。如果终端压力过低，可能导致流速不足，从而导致依赖该流体的消费者或过程供应不足。终端压力的概念还扩展到各种科学实验，特别是那些涉及气体的实验。例如，在受控环境中进行实验时，研究人员必须考虑所研究气体的终端压力。在与化学反应相关的研究中，这一点尤其重要，因为压力会显著影响反应速率和产品产量。通过理解终端压力，科学家可以操控实验条件，以实现预期结果。此外，终端压力在环境科学领域也发挥着重要作用，特别是在研究气候变化的影响时。随着全球气温上升，气体在大气中的行为发生变化，从而导致终端压力的波动。这又会影响天气模式、降水和生态系统的整体健康。环境科学家必须监测这些变化，以制定有效的策略来减轻气候变化的影响。总之，术语终端压力涵盖了各个领域的广泛应用，从航空航天工程到环境科学。其重要性在于能够预测和理解流体和气体在不同条件下的行为。通过掌握终端压力的概念，这些领域的专业人士可以确保其设计和实验的安全性、效率和可持续性。随着技术的不断进步，准确确定终端压力的重要性只会在应对现代社会面临的挑战中变得更加关键。