induced circuit

简明释义

感应电路

英英释义

例句

1.The induced circuit 感应电路 plays a vital role in the operation of induction cooktops.

感应电路在电磁炉的运行中起着至关重要的作用。

2.In a transformer, the primary coil creates a magnetic field that induces current in the secondary coil, forming an induced circuit 感应电路.

在变压器中，初级线圈产生的磁场在次级线圈中感应出电流，形成一个感应电路。

3.The design of the induced circuit 感应电路 is crucial for efficient energy transfer in wireless charging systems.

无线充电系统中，感应电路的设计对高效能量传输至关重要。

4.Engineers often analyze the induced circuit 感应电路 to improve the performance of electric motors.

工程师们经常分析感应电路以提高电动机的性能。

5.Understanding the principles behind the induced circuit 感应电路 can help in designing better sensors.

理解感应电路背后的原理有助于设计更好的传感器。

作文

In the realm of electrical engineering, the concept of an induced circuit is crucial for understanding how electromagnetic fields can influence the behavior of electrical circuits. An induced circuit refers to a circuit that experiences a change in voltage or current due to the presence of a changing magnetic field nearby. This phenomenon is rooted in Faraday's law of electromagnetic induction, which states that a changing magnetic field within a closed loop of wire induces an electromotive force (EMF) in the wire. To illustrate this concept, consider a simple scenario involving two coils of wire, known as primary and secondary coils. When an alternating current flows through the primary coil, it creates a varying magnetic field around it. This changing magnetic field then penetrates the secondary coil, inducing a voltage across it. The induced voltage can be harnessed for various applications, such as in transformers, where it is used to step up or step down voltages for efficient power transmission.The practical implications of induced circuits are vast. For instance, in wireless charging systems, the principle of induction is employed to transfer energy from a charging pad to an electronic device without physical connectors. This technology relies on the creation of an induced circuit between the transmitter and receiver coils, allowing for seamless energy transfer.Moreover, the concept of induced circuits extends beyond just transformers and wireless charging. In electric generators, mechanical energy is converted into electrical energy through the rotation of coils within a magnetic field, effectively creating an induced circuit. The generator's operation is based on the continuous induction of EMF as the coils move through the magnetic field, demonstrating the fundamental relationship between motion and electricity.In addition to their practical applications, induced circuits also pose challenges in certain scenarios. For example, in power lines, unwanted inductive coupling can lead to interference and energy losses. Engineers must carefully design circuits to minimize these effects and ensure efficient operation. Furthermore, the concept of induced circuits is vital in understanding electromagnetic compatibility (EMC), as it helps engineers predict and mitigate potential issues arising from electromagnetic interference (EMI).In conclusion, the study of induced circuits is essential for anyone involved in electrical engineering or related fields. Understanding how changing magnetic fields can induce voltage and current in nearby circuits opens the door to numerous technological advancements. From transformers to wireless charging and electric generators, the applications of induced circuits are integral to modern electrical systems. As technology continues to evolve, so too will our understanding and utilization of this fundamental principle, paving the way for innovative solutions to meet the demands of our increasingly electrified world. The Chinese translation of induced circuit is "感应电路", which captures the essence of how these circuits operate under the influence of external magnetic fields. As we delve deeper into the principles of electromagnetism, the significance of induced circuits will undoubtedly become even more pronounced in both theoretical and practical contexts.

在电气工程领域，感应电路的概念对于理解电磁场如何影响电路的行为至关重要。感应电路是指由于附近存在变化的磁场而经历电压或电流变化的电路。这一现象根植于法拉第电磁感应定律，该定律指出，在闭合导线环内变化的磁场会在导线中感应出电动势（EMF）。为了说明这一概念，考虑一个简单的场景，涉及两圈导线，称为初级线圈和次级线圈。当交流电流通过初级线圈时，会在其周围产生一个变化的磁场。这个变化的磁场穿透次级线圈，在其上感应出电压。感应出的电压可以用于各种应用，例如在变压器中，它用于高效电力传输的升压或降压。感应电路的实际意义是广泛的。例如，在无线充电系统中，利用感应原理将能量从充电垫传输到电子设备，而无需物理连接。这项技术依赖于发射器和接收器线圈之间创建的感应电路，实现无缝的能量转移。此外，感应电路的概念不仅限于变压器和无线充电。在电动发电机中，机械能通过线圈在磁场中旋转转化为电能，有效地创建了一个感应电路。发电机的工作基于线圈在磁场中移动时持续感应出电动势，展示了运动与电力之间的基本关系。除了它们的实际应用，感应电路在某些情况下也带来了挑战。例如，在电力线中，不必要的感应耦合可能导致干扰和能量损失。工程师必须仔细设计电路，以最小化这些影响，确保高效运行。此外，感应电路的概念在理解电磁兼容性（EMC）方面至关重要，因为它帮助工程师预测和减轻由电磁干扰（EMI）引起的潜在问题。总之，研究感应电路对于任何参与电气工程或相关领域的人来说都是必不可少的。了解变化的磁场如何在附近电路中感应出电压和电流，为众多技术进步打开了大门。从变压器到无线充电和电动发电机，感应电路的应用对现代电气系统至关重要。随着技术的不断发展，我们对这一基本原理的理解和利用也将不断深化，为满足我们日益电气化世界的需求铺平道路。感应电路的中文翻译是"感应电路"，它捕捉了这些电路在外部磁场影响下如何运作的本质。当我们深入探讨电磁学原理时，感应电路的重要性无疑将在理论和实践背景中变得更加突出。