transient exciting current

简明释义

瞬时励磁电流

英英释义

例句

1.The engineer explained how the transient exciting current 瞬态激励电流 can affect the performance of the circuit during a power surge.

工程师解释了如何在电力突 surge 期间，瞬态激励电流 瞬态激励电流 会影响电路的性能。

2.The transient exciting current 瞬态激励电流 generated by the lightning strike was measured to understand its impact on electrical grids.

为了了解其对电网的影响，测量了雷击产生的 瞬态激励电流 瞬态激励电流 。

3.Understanding the transient exciting current 瞬态激励电流 is crucial for designing robust electronic devices.

理解 瞬态激励电流 瞬态激励电流 对于设计稳健的电子设备至关重要。

4.During the test, the transient exciting current 瞬态激励电流 created a spike that triggered the safety mechanisms.

在测试过程中，瞬态激励电流 瞬态激励电流 产生的峰值触发了安全机制。

5.In our experiment, we observed a transient exciting current 瞬态激励电流 that caused unexpected oscillations in the system.

在我们的实验中，我们观察到一个 瞬态激励电流 瞬态激励电流 导致系统出现意外的振荡。

作文

In the realm of physics and electrical engineering, the term transient exciting current refers to a temporary surge of electrical current that occurs when a circuit is energized. This phenomenon can be observed in various applications, from household appliances to large industrial machines. Understanding this concept is crucial for engineers and technicians who work with electrical systems, as it has significant implications for circuit design and safety. When we talk about transient exciting current (瞬态激励电流), we are essentially discussing a current that does not remain constant but rather fluctuates over time. This transient behavior can be caused by several factors, including the sudden application of voltage, changes in load conditions, or the activation of electrical components such as motors or transformers. For instance, consider the moment when you switch on a powerful electric motor. Initially, the motor draws a much higher current than its normal operating level. This initial spike is what we refer to as the transient exciting current (瞬态激励电流). It lasts only for a brief period but can have a substantial impact on the overall performance and longevity of the electrical system. One of the critical aspects of managing transient exciting current (瞬态激励电流) is ensuring that the electrical components can handle these sudden changes without being damaged. Engineers often incorporate protective devices like fuses, circuit breakers, and surge protectors to mitigate the risks associated with these transient currents. By doing so, they can prevent overheating, insulation breakdown, and other failures that might arise from excessive current. Moreover, understanding the characteristics of transient exciting current (瞬态激励电流) is essential for designing circuits that can respond effectively to these temporary surges. For example, capacitors may be used to smooth out the spikes in current, while inductors can help manage the rate of change in current flow. The implications of transient exciting current (瞬态激励电流) extend beyond just electrical engineering; they also play a significant role in fields like telecommunications, automotive technology, and renewable energy systems. In these areas, the ability to predict and control transient behaviors can lead to more efficient and reliable systems.In conclusion, the concept of transient exciting current (瞬态激励电流) is integral to understanding how electrical circuits operate under dynamic conditions. By studying these transient phenomena, engineers can develop better designs that enhance the safety and efficiency of electrical systems. As technology continues to evolve, the knowledge and management of transient exciting current (瞬态激励电流) will remain a vital component of electrical engineering and related disciplines.

在物理和电气工程领域，术语瞬态激励电流指的是当电路通电时发生的暂时电流激增。这种现象可以在各种应用中观察到，从家用电器到大型工业机器。理解这个概念对从事电气系统工作的工程师和技术人员至关重要，因为它对电路设计和安全具有重要影响。当我们谈到瞬态激励电流时，我们实际上是在讨论一种不会保持不变而是随时间波动的电流。这种瞬态行为可能由多个因素引起，包括电压的突然施加、负载条件的变化或电动机或变压器等电气元件的激活。例如，考虑一下你打开一台强大电动机的那一刻。最初，电动机的电流远高于其正常工作水平。这种初始峰值被称为瞬态激励电流。它持续的时间很短，但对整个电气系统的性能和寿命有着巨大的影响。管理瞬态激励电流的一个关键方面是确保电气元件能够承受这些突然变化而不被损坏。工程师通常会使用保护装置，如保险丝、断路器和浪涌保护器，以减轻与这些瞬态电流相关的风险。通过这样做，他们可以防止过热、绝缘破坏和其他可能因电流过大而导致的故障。此外，理解瞬态激励电流的特性对于设计能够有效响应这些临时激增的电路至关重要。例如，电容器可用于平滑电流中的尖峰，而电感器则可以帮助管理电流变化的速率。瞬态激励电流的影响不仅限于电气工程；它们在电信、汽车技术和可再生能源系统等领域也发挥着重要作用。在这些领域，预测和控制瞬态行为的能力可以导致更高效和可靠的系统。总之，瞬态激励电流的概念对于理解电气电路在动态条件下的操作是不可或缺的。通过研究这些瞬态现象，工程师可以开发出更好的设计，从而提高电气系统的安全性和效率。随着技术的不断发展，对瞬态激励电流的知识和管理将继续成为电气工程及相关学科的重要组成部分。