flow oscillation

简明释义

排量波动;

英英释义

例句

1.To minimize flow oscillation 流动振荡, we implemented a damping system in the water treatment plant.

为了减少流动振荡，我们在水处理厂实施了阻尼系统。

2.During the experiment, flow oscillation 流动振荡 was detected at various frequencies.

在实验过程中，检测到不同频率的流动振荡。

3.The engineers observed a significant flow oscillation 流动振荡 in the pipeline during the pressure test.

工程师在压力测试中观察到管道内有显著的流动振荡。

4.The research focused on the effects of flow oscillation 流动振荡 on turbine efficiency.

研究集中在流动振荡对涡轮效率的影响。

5.The control system was adjusted to reduce flow oscillation 流动振荡 in the reactor.

控制系统经过调整，以减少反应器中的流动振荡。

作文

In fluid dynamics, the term flow oscillation refers to the periodic variation in the flow characteristics of a fluid. This phenomenon can occur in various systems, including pipes, rivers, and even atmospheric conditions. Understanding flow oscillation is crucial for engineers and scientists alike, as it can significantly affect the performance and stability of fluid transport systems.To illustrate the importance of flow oscillation, consider a scenario in a pipeline transporting oil. If the flow within the pipeline experiences oscillations, it may lead to pressure fluctuations that could damage the pipeline or reduce its efficiency. Engineers must carefully design systems to mitigate these oscillations, ensuring a steady flow and preventing any potential hazards.Moreover, flow oscillation can also be observed in natural water bodies. For instance, in rivers, the flow may oscillate due to changes in the gradient of the riverbed or the presence of obstacles such as rocks and vegetation. These oscillations can impact sediment transport and aquatic ecosystems. Understanding how flow oscillation works in these environments allows environmentalists to better manage and protect natural resources.Another area where flow oscillation plays a critical role is in aerodynamics. When air flows over an object, such as an airplane wing, it can create oscillatory patterns that may affect lift and drag. Engineers must consider these factors when designing aircraft to ensure safety and efficiency during flight.The study of flow oscillation is not limited to traditional engineering fields; it also extends to various scientific disciplines. For example, in meteorology, researchers analyze oscillatory patterns in wind and temperature to predict weather changes. Similarly, in oceanography, flow oscillation can influence tidal patterns and marine life behavior.In conclusion, flow oscillation is a complex yet fascinating phenomenon that affects many aspects of our world. From engineering applications to natural ecosystems, understanding the principles behind flow oscillation is essential for innovation and sustainability. By studying this concept, we can develop better systems and practices that enhance our ability to manage fluids effectively, whether in industrial settings or natural environments. The implications of flow oscillation are vast, and continued research in this area will undoubtedly lead to new discoveries and advancements in multiple fields.

在流体动力学中，术语流动振荡指的是流体流动特征的周期性变化。这种现象可以发生在各种系统中，包括管道、河流，甚至大气条件。理解流动振荡对于工程师和科学家来说至关重要，因为它可能显著影响流体运输系统的性能和稳定性。为了说明流动振荡的重要性，考虑一个运输石油的管道场景。如果管道内的流动经历振荡，可能导致压力波动，从而损坏管道或降低其效率。工程师必须仔细设计系统以减轻这些振荡，确保流动稳定并防止潜在的危险。此外，流动振荡也可以在自然水体中观察到。例如，在河流中，由于河床的坡度变化或岩石和植被等障碍物的存在，流动可能会振荡。这些振荡可能会影响沉积物运输和水生生态系统。了解流动振荡在这些环境中的工作原理，能够帮助环境保护者更好地管理和保护自然资源。流动振荡在空气动力学中也扮演着关键角色。当空气流过物体（例如飞机机翼）时，可能会产生振荡模式，这可能影响升力和阻力。在设计飞机时，工程师必须考虑这些因素，以确保飞行的安全性和效率。流动振荡的研究不仅限于传统的工程领域；它还扩展到各种科学学科。例如，在气象学中，研究人员分析风和温度中的振荡模式，以预测天气变化。同样，在海洋学中，流动振荡可能会影响潮汐模式和海洋生物行为。总之，流动振荡是一个复杂而迷人的现象，影响着我们世界的许多方面。从工程应用到自然生态系统，理解流动振荡背后的原理对创新和可持续发展至关重要。通过研究这一概念，我们可以开发出更好的系统和实践，提高我们有效管理流体的能力，无论是在工业环境还是自然环境中。流动振荡的影响广泛，继续在这一领域进行研究无疑将导致多个领域的新发现和进展。