residual flux

简明释义

残油

英英释义

例句

1.Engineers often analyze the residual flux to improve the efficiency of the thermal systems.

工程师们常常分析残余通量以提高热系统的效率。

2.The measurement of the residual flux in the system indicated that there was still some energy loss.

系统中对残余通量的测量表明仍然存在一些能量损失。

3.Monitoring the residual flux helps in determining the health of the electrical circuit.

监测残余通量有助于确定电路的健康状况。

4.In magnetic materials, the residual flux can affect the overall performance of the device.

在磁性材料中，残余通量会影响设备的整体性能。

5.A high level of residual flux can lead to increased operational costs in industrial processes.

高水平的残余通量可能导致工业过程中的运营成本增加。

作文

In the realm of physics and engineering, the concept of residual flux plays a crucial role in understanding various phenomena, particularly in the fields of magnetism and fluid dynamics. Essentially, residual flux refers to the magnetic or fluid flow that remains in a system after the primary driving forces have been removed. This residual effect can significantly influence the behavior of materials and systems, making it an important factor to consider in both theoretical studies and practical applications.To illustrate the significance of residual flux, let us consider its application in magnetic materials. When a ferromagnetic material is subjected to an external magnetic field, it becomes magnetized. However, even after the external field is removed, the material retains some magnetization due to residual flux. This phenomenon is known as hysteresis, and it is critical in the design of magnetic storage devices, transformers, and electric motors. The presence of residual flux can lead to energy losses in these devices, which engineers must account for to enhance efficiency and performance.In fluid dynamics, residual flux can be observed in systems where fluid flow is interrupted. For example, when a pump is turned off, the fluid within the system may continue to flow for a short period due to residual flux. This behavior is essential for understanding the dynamics of fluid systems, particularly in hydraulic engineering and the design of piping systems. Engineers must consider residual flux to prevent issues such as water hammer or pressure surges that could damage infrastructure.Moreover, the study of residual flux is not limited to just physical systems; it extends into the realm of environmental science as well. For instance, in the context of pollutant dispersion in bodies of water, residual flux can describe the lingering effects of contaminants even after the source has been eliminated. Understanding this residual effect is vital for developing effective cleanup strategies and ensuring the long-term health of aquatic ecosystems.In conclusion, the term residual flux encapsulates a significant aspect of various scientific and engineering disciplines. Its implications stretch from the microscopic interactions of magnetic materials to the macroscopic behaviors of fluids and environmental systems. By recognizing and studying residual flux, researchers and engineers can better predict system behaviors, enhance designs, and implement more effective solutions to complex problems. As technology continues to advance, the importance of understanding residual flux will only grow, underscoring the need for continued research and innovation in this vital area.

在物理和工程领域，residual flux（剩余通量）这一概念在理解各种现象方面发挥着至关重要的作用，特别是在磁学和流体动力学领域。基本上，residual flux指的是在主要驱动力被移除后，系统中残留的磁通量或流体流动。这种残余效应可以显著影响材料和系统的行为，因此在理论研究和实际应用中都是一个重要的考虑因素。为了说明residual flux的重要性，让我们考虑它在磁性材料中的应用。当铁磁材料受到外部磁场的作用时，它会被磁化。然而，即使在外部磁场被移除后，由于residual flux，材料仍然保持一定的磁化状态。这种现象被称为滞后现象，它在磁存储设备、变压器和电动机的设计中至关重要。residual flux的存在可能导致这些设备中的能量损失，工程师必须对此加以考虑，以提高效率和性能。在流体动力学中，residual flux可以在流动被中断的系统中观察到。例如，当泵关闭时，系统内的流体可能由于residual flux而继续流动一段时间。这种行为对于理解流体系统的动态特性至关重要，特别是在水利工程和管道系统的设计中。工程师必须考虑residual flux以防止如水锤或压力冲击等问题，这些问题可能会损坏基础设施。此外，residual flux的研究不仅限于物理系统；它还扩展到环境科学的领域。例如，在水体中污染物扩散的背景下，residual flux可以描述在源头被消除后污染物的持续影响。理解这种残余效应对于制定有效的清理策略和确保水生生态系统的长期健康至关重要。总之，术语residual flux概括了各种科学和工程学科的重要方面。其影响从磁性材料的微观相互作用扩展到流体和环境系统的宏观行为。通过认识和研究residual flux，研究人员和工程师可以更好地预测系统行为，增强设计，并对复杂问题实施更有效的解决方案。随着技术的不断进步，理解residual flux的重要性只会增加，这突显了在这一重要领域持续研究和创新的必要性。