alternating flux

简明释义

1. 交变通量; 2. 交变磁通;

英英释义

例句

1.The generator produces an alternating flux that changes direction periodically.

发电机产生的交变磁通周期性地改变方向。

2.The concept of alternating flux is essential in understanding electromagnetic induction.

理解电磁感应时，交变磁通的概念至关重要。

3.In transformers, the alternating flux is crucial for energy transfer between coils.

在变压器中，交变磁通对线圈之间的能量传输至关重要。

4.The alternating flux in the circuit affects the overall power consumption.

电路中的交变磁通影响总体功耗。

5.Engineers must calculate the alternating flux to design efficient motors.

工程师必须计算交变磁通以设计高效的电动机。

作文

In the world of physics and engineering, concepts such as electromagnetism play a crucial role in our understanding of how energy behaves. One of the key phenomena associated with electromagnetism is the concept of alternating flux (交变通量). This term refers to the varying magnetic or electric field that changes direction and magnitude over time. Understanding alternating flux is essential for various applications, including the design of electrical devices and systems. To delve deeper into this concept, we can start by looking at its definition. Alternating flux represents the flow of magnetic or electric fields that oscillate, typically in a sinusoidal manner. This oscillation means that the fields are not static; instead, they continuously change, which is vital for the operation of many electrical systems, such as transformers and AC motors. The alternating nature of these fields allows for efficient energy transfer and conversion. One practical application of alternating flux can be seen in the generation of electricity. In power plants, generators use the principle of electromagnetic induction, where a conductor moves through a magnetic field, creating an alternating flux. This process induces an electric current that can be harnessed for power. The efficiency and effectiveness of this energy generation method rely heavily on the properties of alternating flux. Moreover, the phenomenon of alternating flux is not limited to power generation alone. It also plays a critical role in communications technology. For instance, radio waves are transmitted using alternating flux, allowing for the wireless transmission of information over vast distances. The ability to modulate these waves enables the encoding of data, making it possible for us to enjoy modern conveniences such as mobile phones and the internet. In addition to its applications, understanding the behavior of alternating flux is crucial for engineers and scientists. They must consider factors such as frequency, amplitude, and phase when designing systems that rely on this principle. These parameters can significantly affect performance and efficiency, making it imperative to have a thorough grasp of alternating flux dynamics. Furthermore, the study of alternating flux leads to advancements in technology. As researchers explore new materials and methods for manipulating magnetic and electric fields, they uncover innovative ways to enhance the performance of existing systems and develop new technologies. For example, advancements in superconductors have the potential to revolutionize how we manage alternating flux, leading to more efficient power transmission and storage solutions. In conclusion, the concept of alternating flux is integral to our understanding of electromagnetism and its applications in various fields. From electricity generation to communications technology, the implications of alternating flux are vast and significant. As we continue to explore and innovate within this realm, the importance of mastering this concept will only grow, shaping the future of technology and energy solutions. Understanding alternating flux is not just an academic pursuit; it is a key to unlocking the potential of modern science and engineering.

在物理和工程的世界中，电磁学等概念在我们理解能量行为方面发挥着至关重要的作用。与电磁学相关的一个关键现象是交变通量（alternating flux）的概念。这个术语指的是随时间变化的磁场或电场，其方向和幅度不断变化。理解交变通量对于各种应用至关重要，包括电气设备和系统的设计。为了深入探讨这一概念，我们可以从它的定义开始。交变通量代表着以正弦波方式振荡的磁场或电场的流动。这种振荡意味着这些场不是静态的；相反，它们持续变化，这对于许多电气系统的运行至关重要，例如变压器和交流电动机。这些场的交变特性使得能量传输和转换更加高效。交变通量的一个实际应用可以在发电中看到。在发电厂中，发电机利用电磁感应原理，其中导体在磁场中移动，从而产生交变通量。这个过程诱导出可以用于发电的电流。这种能源生成方法的效率和有效性在很大程度上依赖于交变通量的特性。此外，交变通量的现象不仅限于发电。它在通信技术中也发挥着关键作用。例如，无线电波的传输使用交变通量，使得信息能够在广阔的距离上无线传输。调制这些波的能力使得数据编码成为可能，使我们能够享受现代便利，如手机和互联网。除了其应用之外，理解交变通量的行为对工程师和科学家至关重要。他们在设计依赖于这一原理的系统时，必须考虑频率、幅度和相位等因素。这些参数会显著影响性能和效率，因此必须充分掌握交变通量的动态。此外，研究交变通量还推动了技术的进步。当研究人员探索新材料和操纵磁场及电场的方法时，他们发现了增强现有系统性能和开发新技术的创新方法。例如，超导体的进展有可能彻底改变我们管理交变通量的方式，从而带来更高效的电力传输和存储解决方案。总之，交变通量的概念是我们理解电磁学及其在各个领域应用的核心。从电力生成到通信技术，交变通量的影响广泛而深远。随着我们继续在这一领域进行探索和创新，掌握这一概念的重要性只会增加，塑造技术和能源解决方案的未来。理解交变通量不仅仅是一项学术追求；它是开启现代科学和工程潜力的关键。