bucking current loop

简明释义

屏蔽电流回路;

英英释义

A bucking current loop refers to a configuration in electrical circuits where the current is manipulated or countered, typically to reduce interference or stabilize the system's performance.

bucking current loop指在电路中通过操控或抵消电流的配置,通常用于减少干扰或稳定系统性能。

例句

1.When troubleshooting the system, we discovered that the bucking current loop 反向电流环 was incorrectly configured.

在排查系统故障时,我们发现bucking current loop 反向电流环配置不正确。

2.In the electrical engineering lab, we learned how to set up a bucking current loop 反向电流环 to cancel out unwanted electromagnetic interference.

在电气工程实验室,我们学习了如何设置一个bucking current loop 反向电流环来消除不必要的电磁干扰。

3.The design of the circuit included a bucking current loop 反向电流环 to enhance signal integrity.

电路的设计包括一个bucking current loop 反向电流环以增强信号完整性。

4.Using a bucking current loop 反向电流环 can significantly reduce noise in audio equipment.

使用bucking current loop 反向电流环可以显著降低音频设备中的噪声。

5.The technician adjusted the bucking current loop 反向电流环 to improve the accuracy of the sensor readings.

技术员调整了bucking current loop 反向电流环以提高传感器读数的准确性。

作文

In the world of electrical engineering, understanding various concepts is crucial for designing effective circuits and systems. One such concept that often comes up in discussions about circuit design is the bucking current loop. This term refers to a specific configuration in which a current loop is designed to counteract or 'buck' against an external electromagnetic field or another current loop. This can be particularly important in applications where interference or noise needs to be minimized, allowing for more stable and reliable operation of electronic devices.The bucking current loop works by creating a magnetic field that opposes the external field. When two current loops are placed in proximity to each other, they can interact in ways that either enhance or diminish the overall magnetic field in the area. By carefully designing the orientation and magnitude of the currents flowing through these loops, engineers can achieve a state where the effects of unwanted fields are effectively canceled out. This principle is often applied in noise-canceling technologies, such as those found in headphones and audio equipment.One of the key benefits of using a bucking current loop is the reduction of electromagnetic interference (EMI). In many electronic devices, EMI can cause significant disruptions, leading to poor performance or even complete failure of the device. By employing a bucking strategy, designers can create systems that are more resilient to such interferences. For instance, in sensitive measurement instruments, implementing a bucking current loop can ensure that accurate readings are maintained despite external disturbances.Moreover, the concept of a bucking current loop is not limited to just noise cancellation. It can also play a role in improving the efficiency of power delivery systems. In power electronics, managing the flow of current is vital for reducing losses and ensuring that devices operate within their optimal ranges. A well-designed bucking loop can help to stabilize the current, thereby enhancing the overall efficiency of the system.To illustrate the practical application of a bucking current loop, consider its use in a wireless charging system. In such systems, coils are used to transfer energy between the charger and the device. If there are any stray magnetic fields present, they can disrupt the energy transfer process. By incorporating a bucking current loop, engineers can mitigate these effects, ensuring that the energy transfer remains efficient and effective.In conclusion, the bucking current loop is a fundamental concept in electrical engineering that provides significant advantages in various applications. Its ability to counteract unwanted electromagnetic fields makes it an essential tool for designers looking to improve the performance and reliability of electronic systems. As technology continues to advance, the importance of understanding and utilizing concepts like the bucking current loop will only become more pronounced, paving the way for innovations that can further enhance our electronic experiences.

在电气工程的世界中,理解各种概念对于设计有效的电路和系统至关重要。一个经常出现在电路设计讨论中的概念是反向电流环。这个术语指的是一种特定的配置,在这种配置中,电流环被设计用来抵消或“反向”外部电磁场或另一个电流环。这在需要最小化干扰或噪声的应用中尤为重要,从而允许电子设备更稳定和可靠地运行。反向电流环通过创建一个与外部场相对的磁场而工作。当两个电流环靠近放置时,它们可以以增强或减弱该区域内整体磁场的方式相互作用。通过仔细设计这些环中流动的电流的方向和大小,工程师可以实现一个状态,使得不必要的场的影响被有效地抵消。这个原理常常应用于降噪技术,例如在耳机和音频设备中发现的那些。使用反向电流环的一个主要好处是减少电磁干扰(EMI)。在许多电子设备中,EMI可能会导致显著的干扰,导致设备性能差甚至完全失效。通过采用反向策略,设计者可以创建更能抵御这种干扰的系统。例如,在敏感的测量仪器中,实施反向电流环可以确保尽管存在外部干扰,仍能保持准确的读数。此外,反向电流环的概念不仅限于噪声取消。它还可以在提高电力传输系统的效率方面发挥作用。在电力电子学中,管理电流的流动对于减少损耗和确保设备在最佳范围内运行至关重要。一个设计良好的反向环可以帮助稳定电流,从而提高系统的整体效率。为了说明反向电流环的实际应用,可以考虑其在无线充电系统中的使用。在这样的系统中,线圈用于在充电器和设备之间传输能量。如果存在任何杂散磁场,它们可能会干扰能量传输过程。通过结合使用反向电流环,工程师可以减轻这些影响,确保能量传输保持高效和有效。总之,反向电流环是电气工程中的一个基本概念,在各种应用中提供了显著的优势。它抵消不必要的电磁场的能力使其成为提高电子系统性能和可靠性的设计者的重要工具。随着技术的不断进步,理解和利用像反向电流环这样的概念的重要性只会变得更加明显,为进一步增强我们电子体验的创新铺平道路。