exciter set driving motor

简明释义

励磁机组驱动电动机

英英释义

例句

1.During the maintenance check, we found that the exciter set driving motor 励磁机驱动电动机 was overheating and needed immediate attention.

在维护检查过程中，我们发现励磁机驱动电动机 过热，需要立即处理。

2.The engineer explained how the exciter set driving motor 励磁机驱动电动机 plays a crucial role in voltage regulation.

工程师解释了励磁机驱动电动机 在电压调节中所起的重要作用。

3.The technician replaced the faulty component in the exciter set driving motor 励磁机驱动电动机 to restore the generator's functionality.

技术人员更换了励磁机驱动电动机 的故障组件，以恢复发电机的功能。

4.The power plant relies heavily on the efficiency of the exciter set driving motor 励磁机驱动电动机 for optimal performance.

发电厂在最佳性能上严重依赖励磁机驱动电动机 的效率。

5.To troubleshoot the system, we monitored the output of the exciter set driving motor 励磁机驱动电动机 closely.

为了排除系统故障，我们密切监测了励磁机驱动电动机 的输出。

作文

In the world of electrical engineering, various components work together to ensure the efficient operation of machines and systems. One such critical component is the exciter set driving motor, which plays a pivotal role in power generation and distribution. To understand its significance, we must first explore what an exciter is and how it interacts with a driving motor. An exciter is essentially a device that provides the necessary field current to the rotor of a synchronous generator. This current is crucial for establishing the magnetic field required for electricity generation. The exciter set driving motor is responsible for driving the exciter, ensuring that it operates effectively and maintains the generator's performance. The relationship between the exciter and the driving motor is symbiotic. When the driving motor operates, it rotates the exciter, which in turn generates the field current. This process is vital because without the proper excitation, the generator would fail to produce electricity efficiently. The exciter set driving motor thus serves as the backbone of the excitation system, ensuring that the generator remains stable under varying load conditions. Moreover, advancements in technology have led to the development of more efficient and reliable exciter set driving motors. Modern designs incorporate features such as variable speed drives and advanced control systems, which enhance performance and adaptability. These innovations allow for better management of the power output and improve the overall efficiency of power plants. As the demand for electricity continues to rise globally, the importance of efficient excitation systems becomes increasingly evident.In addition to their role in power generation, exciter set driving motors are also used in various industrial applications. For instance, they can be found in manufacturing plants where large motors drive heavy machinery. In these settings, the exciter ensures that the motors operate smoothly and reliably, thereby minimizing downtime and maintenance costs. The versatility of the exciter set driving motor makes it an essential component in multiple sectors, including renewable energy, where it helps optimize the performance of wind turbines and hydroelectric plants.Understanding the function of the exciter set driving motor is crucial for engineers and technicians working in the field of electrical engineering. Proper maintenance and monitoring of this component can prevent costly failures and ensure the longevity of power generation systems. Training programs and workshops often emphasize the importance of this knowledge, equipping professionals with the skills needed to troubleshoot and optimize excitation systems.In conclusion, the exciter set driving motor is a vital element in the realm of electrical engineering, particularly in the context of power generation. Its ability to provide consistent and reliable excitation to generators ensures that electricity can be produced efficiently. As technology continues to evolve, the design and functionality of the exciter set driving motor will undoubtedly advance, further enhancing its importance in modern energy systems. Understanding this component not only aids in the operational efficiency of power plants but also contributes to the broader goal of sustainable energy production for the future.

在电气工程的世界中，各种组件协同工作，以确保机器和系统的高效运行。其中一个关键组件是励磁机驱动电动机，它在发电和配电中发挥着重要作用。要理解其重要性，我们必须首先探讨励磁机是什么以及它如何与驱动电动机相互作用。励磁机本质上是一个为同步发电机转子提供必要场电流的设备。这种电流对于建立发电所需的磁场至关重要。励磁机驱动电动机负责驱动励磁机，确保其有效运行并维持发电机的性能。励磁机与驱动电动机之间的关系是共生的。当驱动电动机运转时，它旋转励磁机，从而产生场电流。这个过程至关重要，因为没有适当的励磁，发电机将无法高效地产生电力。因此，励磁机驱动电动机作为励磁系统的支柱，确保发电机在不同负载条件下保持稳定。此外，技术的进步导致了更高效、更可靠的励磁机驱动电动机的发展。现代设计结合了变速驱动和先进的控制系统，增强了性能和适应性。这些创新使得更好地管理电力输出成为可能，并提高了发电厂的整体效率。随着全球对电力需求的不断上升，高效励磁系统的重要性变得愈加明显。除了在发电中的作用外，励磁机驱动电动机还被广泛应用于各种工业应用中。例如，在大型电动机驱动重型机械的制造厂中，可以找到它们。在这些环境中，励磁机确保电动机平稳可靠地运行，从而减少停机时间和维护成本。励磁机驱动电动机的多功能性使其成为多个行业的基本组件，包括可再生能源领域，在该领域中，它帮助优化风力涡轮机和水电站的性能。理解励磁机驱动电动机的功能对于在电气工程领域工作的工程师和技术人员至关重要。对这一组件的适当维护和监控可以防止昂贵的故障并确保发电系统的使用寿命。培训项目和研讨会通常强调这一知识的重要性，使专业人员具备故障排除和优化励磁系统的技能。总之，励磁机驱动电动机是电气工程领域中一个重要的元素，特别是在发电的背景下。它为发电机提供持续可靠的励磁能力，确保电力能够高效产生。随着技术的不断发展，励磁机驱动电动机的设计和功能无疑将不断进步，进一步增强其在现代能源系统中的重要性。了解这一组件不仅有助于发电厂的操作效率，还有助于实现未来可持续能源生产的更大目标。