undercompound generator

简明释义

欠复励发电机

英英释义

例句

1.Engineers prefer the undercompound generator 欠补偿发电机 for its ability to maintain voltage during transient loads.

工程师们喜欢使用欠补偿发电机，因为它能够在瞬态负载期间保持电压。

2.In a power plant, the undercompound generator 欠补偿发电机 is often used for applications requiring stable voltage.

在发电厂中，欠补偿发电机通常用于需要稳定电压的应用。

3.When designing a new system, consider integrating an undercompound generator 欠补偿发电机 for better voltage regulation.

在设计新系统时，考虑集成欠补偿发电机以获得更好的电压调节。

4.The performance of the undercompound generator 欠补偿发电机 can be enhanced by adjusting its excitation levels.

通过调整其励磁水平，可以提高欠补偿发电机的性能。

5.The undercompound generator 欠补偿发电机 operates efficiently under varying load conditions.

欠补偿发电机在不同负载条件下运行高效。

作文

The concept of an undercompound generator is essential in the field of electrical engineering, particularly when discussing the performance and characteristics of different types of generators. An undercompound generator is a type of DC generator that is designed to provide a voltage output that is lower than the terminal voltage under load conditions. This can be attributed to its unique winding configuration, which affects the generator's ability to maintain voltage levels when the load increases. Understanding this concept is crucial for engineers and technicians who are involved in designing and maintaining electrical systems.In practical terms, an undercompound generator operates with a specific arrangement of windings that results in a weaker magnetic field as the load increases. This means that while the generator can initially provide sufficient voltage when unloaded or lightly loaded, it struggles to maintain that voltage as more current is drawn from it. The primary reason for this behavior lies in the way the field windings are connected in relation to the armature windings. In essence, the field excitation does not increase proportionally with the load, leading to the observed voltage drop.One of the main applications of undercompound generators is in situations where voltage regulation is not critical. For instance, they are often used in smaller power generation systems, such as in some diesel generators or portable generators, where the load may vary significantly. These generators are generally simpler and cheaper to produce, making them an attractive option for certain applications.However, the limitations of an undercompound generator must be acknowledged. Because they do not provide stable voltage under varying load conditions, they are not suitable for applications that require precise voltage regulation, such as in industrial or commercial power systems. In these scenarios, other types of generators, like overcompound or compound generators, may be preferred due to their ability to maintain voltage levels despite changes in load.To illustrate the importance of understanding the undercompound generator, consider a scenario where a factory relies on a generator to power machinery. If the generator is undercompound, the workers may notice that as more machines are turned on, the lights dim, indicating a drop in voltage. This could lead to operational inefficiencies, equipment malfunctions, and even damage to sensitive electronic components. Therefore, engineers must carefully evaluate the type of generator they choose based on the specific requirements of the application.In summary, the undercompound generator serves as a valuable example of how different generator designs can impact performance. While it has its niche applications, understanding its limitations is vital for ensuring reliable and efficient power generation. By recognizing the characteristics of an undercompound generator, professionals in the electrical engineering field can make informed decisions that enhance the overall performance of electrical systems. As technology continues to evolve, ongoing research and development will likely lead to improvements in generator designs, including enhancements to the undercompound generator that could expand its usability in various applications.

“欠复合发电机”的概念在电气工程领域中至关重要，特别是在讨论不同类型发电机的性能和特征时。“欠复合发电机”是一种直流发电机，其设计目的是在负载条件下提供低于端子电压的电压输出。这可以归因于其独特的绕组配置，这影响了发电机在负载增加时维持电压水平的能力。理解这一概念对于参与电气系统设计和维护的工程师和技术人员至关重要。在实际操作中，“欠复合发电机”以特定的绕组排列运行，导致当负载增加时磁场较弱。这意味着虽然发电机在无负载或轻负载时可以初步提供足够的电压，但随着从中抽取的电流增多，它却难以维持该电压。这种行为的主要原因在于场绕组与电枢绕组的连接方式。本质上，场励磁并没有随着负载的增加而成比例地增加，从而导致观察到的电压下降。“欠复合发电机”的主要应用之一是在电压调节并不关键的情况下。例如，它们通常用于一些柴油发电机或便携式发电机等较小的发电系统，这些系统的负载可能会显著变化。这些发电机通常更简单且生产成本更低，使它们成为某些应用的有吸引力的选择。然而，必须承认“欠复合发电机”的局限性。由于它们在不同负载条件下无法提供稳定的电压，因此不适合需要精确电压调节的应用，例如工业或商业电力系统。在这些场景中，其他类型的发电机，如过复合或复合发电机，可能更受欢迎，因为它们能够在负载变化时维持电压水平。为了说明理解“欠复合发电机”的重要性，考虑一个工厂依赖发电机为机器供电的场景。如果发电机是欠复合的，工人们可能会注意到随着更多机器的开启，灯光变暗，表明电压下降。这可能导致操作效率低下、设备故障，甚至对敏感电子元件造成损坏。因此，工程师必须根据应用的具体要求仔细评估他们选择的发电机类型。总之，“欠复合发电机”作为不同发电机设计如何影响性能的宝贵示例。虽然它在某些特定应用中具有其独特的价值，但理解其局限性对于确保可靠和高效的电力生成至关重要。通过认识到“欠复合发电机”的特性，电气工程领域的专业人员可以做出明智的决策，从而提升电气系统的整体性能。随着技术的不断发展，持续的研究和开发可能会导致发电机设计的改进，包括对“欠复合发电机”的增强，这可能扩展其在各种应用中的可用性。