residual flux

简明释义

残油

英英释义

例句

1.After the experiment, the scientists measured the residual flux to assess any losses.

实验结束后，科学家测量了剩余通量以评估任何损失。

2.The residual flux in the capacitor affects the overall performance of the circuit.

电容器中的剩余通量影响电路的整体性能。

3.In the study of fluid dynamics, the residual flux can indicate the efficiency of a system.

在流体动力学研究中，剩余通量可以指示系统的效率。

4.The engineer calculated the residual flux to determine the leftover magnetic field after the initial excitation.

工程师计算了剩余通量以确定初始激励后的剩余磁场。

5.Monitoring the residual flux is crucial for maintaining the stability of the magnetic field.

监测剩余通量对于维持磁场的稳定性至关重要。

作文

In the field of physics and engineering, the concept of residual flux plays a crucial role in understanding various phenomena, particularly in electromagnetism and fluid dynamics. The term residual flux refers to the remaining flow of a quantity, such as magnetic field lines or fluid particles, after certain processes have taken place. This concept is essential for analyzing systems where some energy or material remains in a state that influences the overall behavior of the system.For instance, in magnetism, when a magnetic field is applied to a material, it can become magnetized. However, once the external magnetic field is removed, the material may still retain some magnetization. This leftover magnetization is what we refer to as residual flux or residual magnetism. This phenomenon is significant in various applications, including data storage devices like hard drives, where the residual flux can affect the reliability and performance of the device.Moreover, in fluid dynamics, residual flux can describe the leftover flow of fluid after a disturbance or change in conditions. For example, when a valve in a pipeline is closed, the fluid does not stop immediately; instead, a portion of the fluid continues to flow due to inertia. This ongoing movement is an example of residual flux. Understanding this concept is vital for engineers designing systems that involve fluid transport, as it helps predict how fluids behave under various operational scenarios.The implications of residual flux extend beyond theoretical discussions; they have practical consequences in engineering design and safety assessments. In electrical engineering, for instance, knowing the residual flux in transformers and inductors is critical for ensuring that these components operate efficiently and safely. If the residual flux is not properly accounted for, it can lead to overheating or even failure of the equipment.Additionally, in environmental science, the concept of residual flux is used to model the remaining concentrations of pollutants in water bodies after treatment processes. Environmental engineers must consider this residual presence to evaluate the effectiveness of remediation efforts and ensure compliance with regulatory standards.In summary, the term residual flux encompasses a wide range of applications across different scientific disciplines. It represents the leftover flow or influence of a quantity after initial processes have occurred. Whether in the context of magnetism, fluid dynamics, or environmental studies, understanding residual flux is essential for predicting system behavior and making informed decisions in design and analysis. As technology continues to advance, the importance of accurately measuring and interpreting residual flux will only increase, highlighting the need for continued research and education in this area. By grasping the nuances of residual flux, professionals can better navigate the complexities of their respective fields and contribute to innovative solutions that address real-world challenges.

在物理和工程领域，残余通量的概念在理解各种现象中起着至关重要的作用，特别是在电磁学和流体动力学中。术语残余通量指的是在某些过程发生后，剩余的数量流动，例如磁场线或流体颗粒。这一概念对于分析某些能量或材料仍然处于影响系统整体行为状态的系统至关重要。例如，在磁性材料中，当外部磁场施加到材料上时，材料可能会被磁化。然而，一旦外部磁场被移除，材料可能仍会保留一些磁化。这种剩余的磁化就是我们所称的残余通量或残余磁性。这一现象在各种应用中具有重要意义，包括数据存储设备，如硬盘驱动器，其中残余通量可能会影响设备的可靠性和性能。此外，在流体动力学中，残余通量可以描述在干扰或条件变化后流体的剩余流动。例如，当管道中的阀门关闭时，流体并不会立即停止；相反，由于惯性，部分流体会继续流动。这一持续的运动就是残余通量的一个例子。理解这一概念对设计涉及流体运输的系统的工程师至关重要，因为它有助于预测流体在各种操作场景下的行为。残余通量的影响超越了理论讨论；它在工程设计和安全评估中具有实际意义。在电气工程中，例如，了解变压器和电感器中的残余通量对于确保这些组件高效且安全地运行至关重要。如果未能正确考虑残余通量，可能会导致设备过热甚至故障。此外，在环境科学中，残余通量的概念用于建模处理过程后水体中污染物的剩余浓度。环境工程师必须考虑这种残余存在，以评估修复工作的有效性，并确保遵守监管标准。总之，术语残余通量涵盖了不同科学学科中的广泛应用。它表示初始过程发生后剩余的流动或数量影响。无论是在磁性、流体动力学还是环境研究的背景下，理解残余通量对于预测系统行为和在设计与分析中做出明智决定至关重要。随着技术的不断进步，准确测量和解释残余通量的重要性只会增加，突显出在这一领域继续进行研究和教育的必要性。通过掌握残余通量的细微差别，专业人士可以更好地应对各自领域的复杂性，并为解决现实世界挑战做出创新的贡献。