brushless excitation

简明释义

无刷励磁

英英释义

例句

1.We switched to brushless excitation systems to improve reliability in our operations.

我们切换到无刷励磁系统以提高运营的可靠性。

2.Many modern motors feature brushless excitation for better performance.

许多现代电动机采用无刷励磁以提高性能。

3.With brushless excitation, maintenance costs are significantly reduced.

采用无刷励磁后，维护成本显著降低。

4.The advantages of brushless excitation include longer lifespan and reduced wear.

采用无刷励磁的优点包括更长的使用寿命和减少磨损。

5.The new generator utilizes brushless excitation to enhance efficiency.

新发电机利用无刷励磁来提高效率。

作文

In recent years, the advancement of technology has led to significant improvements in various fields, particularly in electrical engineering and power generation. One of the most notable innovations is the introduction of brushless excitation, a method that has transformed the way generators operate. This technique eliminates the need for brushes, which are traditionally used to transfer current to the rotor windings in synchronous machines. The absence of brushes not only enhances the efficiency of these machines but also reduces maintenance costs and increases their lifespan.The principle behind brushless excitation revolves around the use of permanent magnets or electronic controllers to generate the necessary magnetic field. In traditional systems, brushes wear out over time due to friction, leading to frequent replacements and potential failures. However, with brushless excitation, the reliance on mechanical components is significantly diminished, resulting in a more reliable and robust system.One of the primary advantages of brushless excitation is its ability to provide a stable and consistent power output. This stability is crucial for applications that require precise voltage control, such as in data centers and critical infrastructure. By maintaining a steady magnetic field, brushless excitation ensures that the generator can respond quickly to changes in load, thus preventing fluctuations that could potentially damage sensitive equipment.Moreover, brushless excitation systems tend to be more compact and lightweight compared to their brushed counterparts. This reduction in size is particularly beneficial in applications where space is limited, such as in aircraft and marine vessels. The integration of brushless excitation technology allows manufacturers to design smaller, more efficient generators without compromising performance.Another significant benefit of brushless excitation is its environmental impact. Traditional generators that rely on brushes often produce more waste due to the wear and tear of components. In contrast, the longevity of brushless excitation systems means that fewer materials are needed for repairs and replacements, leading to a decrease in overall waste. Additionally, the improved efficiency of these systems translates to lower fuel consumption, contributing to a reduction in greenhouse gas emissions.As industries continue to evolve and seek more sustainable solutions, the adoption of brushless excitation technology is likely to increase. Its ability to improve efficiency, reduce maintenance costs, and minimize environmental impact makes it an attractive option for modern power generation. Engineers and designers are increasingly recognizing the benefits of this innovative approach, and as a result, we can expect to see more widespread implementation of brushless excitation in various applications.In conclusion, brushless excitation represents a significant leap forward in generator technology. By eliminating the need for brushes, this method enhances efficiency, reliability, and environmental sustainability. As the demand for cleaner and more efficient energy solutions grows, the role of brushless excitation will undoubtedly become more prominent in the future of power generation. Understanding and embracing this technology is essential for anyone involved in the field of electrical engineering, as it paves the way for a more efficient and sustainable energy landscape.

近年来，技术的进步在各个领域，特别是电气工程和发电方面，带来了显著的改善。其中最显著的创新之一是引入了无刷励磁，这是一种改变发电机运行方式的方法。这种技术消除了传统上用于将电流传递到同步机器转子绕组的刷子的需要。没有刷子不仅提高了这些机器的效率，还降低了维护成本并延长了它们的使用寿命。无刷励磁的原理围绕使用永磁体或电子控制器来产生所需的磁场。在传统系统中，由于摩擦，刷子会随着时间的推移而磨损，导致频繁更换和潜在故障。然而，使用无刷励磁，对机械部件的依赖显著减少，从而导致一个更可靠和稳健的系统。无刷励磁的主要优点之一是能够提供稳定和一致的电力输出。这种稳定性对于需要精确电压控制的应用至关重要，例如数据中心和关键基础设施。通过保持稳定的磁场，无刷励磁确保发电机能够快速响应负载变化，从而防止可能损坏敏感设备的波动。此外，无刷励磁系统通常比其有刷对应物更紧凑和轻便。这种尺寸的减少在空间有限的应用中尤为有利，例如在飞机和海洋船只中。集成无刷励磁技术使制造商能够设计出更小、更高效的发电机，而不影响性能。无刷励磁的另一个显著好处是其对环境的影响。依赖刷子的传统发电机由于组件的磨损和撕裂，通常会产生更多的废物。相比之下，无刷励磁系统的耐用性意味着维修和更换所需的材料更少，从而减少了整体废物。此外，这些系统的效率提高也意味着燃料消耗降低，有助于减少温室气体排放。随着各行业不断发展并寻求更可持续的解决方案，无刷励磁技术的采用可能会增加。它提高效率、降低维护成本和最小化环境影响的能力，使其成为现代发电的一个有吸引力的选择。工程师和设计师越来越认识到这种创新方法的好处，因此我们可以期待看到无刷励磁在各种应用中的更广泛实施。总之，无刷励磁代表了发电机技术的一次重大飞跃。通过消除对刷子的需求，这种方法提高了效率、可靠性和环境可持续性。随着对更清洁、更高效能源解决方案的需求增长，无刷励磁在未来发电中的角色无疑会变得更加突出。理解和接受这一技术对于任何参与电气工程的人来说都是至关重要的，因为它为更高效和可持续的能源格局铺平了道路。