non-salient pole synchronous generator

简明释义

隐极同步发电机

英英释义

例句

1.Engineers often prefer a non-salient pole synchronous generator 无凸极同步发电机 for applications requiring stable voltage output.

工程师们通常更喜欢用于需要稳定电压输出的应用中的无凸极同步发电机。

2.The efficiency of a non-salient pole synchronous generator 无凸极同步发电机 is often higher than that of its salient pole counterparts.

无凸极同步发电机的效率通常高于其凸极发电机的对应物。

3.The design of a non-salient pole synchronous generator 无凸极同步发电机 allows for a more compact and lightweight structure.

无凸极同步发电机的设计允许更紧凑和轻便的结构。

4.The non-salient pole synchronous generator 无凸极同步发电机 operates on the principle of electromagnetic induction.

无凸极同步发电机的工作原理是电磁感应。

5.In hydroelectric power plants, a non-salient pole synchronous generator 无凸极同步发电机 is commonly used due to its ability to handle high speeds.

在水电站中，通常使用无凸极同步发电机，因为它能够处理高速运行。

作文

The world of electrical engineering is filled with various types of machines that play crucial roles in power generation and distribution. One such machine is the non-salient pole synchronous generator, which is widely used in power plants due to its efficiency and reliability. Understanding the workings and applications of this type of generator can provide valuable insights into its significance in modern energy systems.A non-salient pole synchronous generator is characterized by its rotor design, which features smooth cylindrical poles. Unlike salient pole generators, which have projecting poles, the non-salient design allows for a more uniform magnetic field distribution. This design minimizes the effects of armature reaction and results in better performance at high speeds. The rotor of a non-salient pole synchronous generator rotates in synchrony with the stator's magnetic field, which is generated by alternating current (AC) flowing through the stator windings.One of the primary advantages of a non-salient pole synchronous generator is its ability to operate at high speeds, making it suitable for large-scale power generation applications. These generators are commonly used in hydroelectric power stations, thermal power plants, and other industrial settings where consistent and stable power output is essential. Their robust construction and efficient design contribute to their long lifespan and low maintenance requirements, making them a preferred choice for utility companies.Moreover, the non-salient pole synchronous generator plays a significant role in maintaining grid stability. By operating in synchrony with the grid frequency, these generators help regulate voltage levels and improve overall system reliability. They are equipped with automatic voltage regulators (AVRs) that adjust the excitation of the rotor, ensuring that the output voltage remains stable under varying load conditions.In addition to their operational benefits, non-salient pole synchronous generators also have environmental implications. As the demand for renewable energy sources increases, these generators can be integrated with wind turbines and other renewable technologies to provide clean and sustainable power. Their ability to maintain synchronization with the grid makes them an ideal component in hybrid energy systems that combine traditional and renewable energy sources.Despite their many advantages, non-salient pole synchronous generators also face some challenges. For instance, their initial installation costs can be higher compared to other types of generators. Additionally, they require a more complex control system to ensure proper synchronization with the grid. However, the long-term benefits they provide often outweigh these initial hurdles, making them a wise investment for power generation facilities.In conclusion, the non-salient pole synchronous generator is a vital component in the realm of electrical engineering and power generation. Its unique design, operational efficiency, and ability to support grid stability make it an essential tool for meeting the growing energy demands of our society. As we continue to explore innovative ways to harness energy, understanding the role of machines like the non-salient pole synchronous generator will be crucial in shaping a sustainable future for generations to come.

电气工程的世界充满了各种类型的机器，这些机器在发电和配电中发挥着至关重要的作用。其中一种机器是非凸极同步发电机，由于其效率和可靠性，广泛用于发电厂。理解这种类型的发电机的工作原理和应用，可以为我们提供对其在现代能源系统中重要性的宝贵见解。非凸极同步发电机的特点是其转子设计，具有光滑的圆柱形极。与有凸极的发电机不同，非凸极设计允许更均匀的磁场分布。这种设计最小化了电枢反应的影响，并在高速下实现更好的性能。非凸极同步发电机的转子与定子的磁场同步旋转，定子的磁场由流经定子绕组的交流电（AC）产生。非凸极同步发电机的主要优点之一是它能够在高速下运行，使其适合于大规模发电应用。这些发电机通常用于水电站、热电厂和其他工业环境中，在这些地方，稳定和一致的电力输出至关重要。它们坚固的结构和高效的设计有助于延长其使用寿命并降低维护要求，使其成为公用事业公司的首选。非凸极同步发电机在维护电网稳定方面也发挥着重要作用。通过与电网频率同步运行，这些发电机帮助调节电压水平并提高整体系统的可靠性。它们配备了自动电压调节器（AVR），可以调整转子的励磁，确保在负载条件变化时输出电压保持稳定。除了其操作优势外，非凸极同步发电机还具有环境影响。随着对可再生能源源需求的增加，这些发电机可以与风力涡轮机和其他可再生技术集成，以提供清洁和可持续的电力。它们与电网保持同步的能力使其成为结合传统和可再生能源的混合能源系统中的理想组成部分。尽管有许多优点，非凸极同步发电机也面临一些挑战。例如，与其他类型的发电机相比，其初始安装成本可能更高。此外，它们需要更复杂的控制系统，以确保与电网的正确同步。然而，它们所提供的长期利益往往超过这些初始障碍，使其成为发电设施的明智投资。总之，非凸极同步发电机是电气工程和发电领域的重要组成部分。其独特的设计、操作效率和支持电网稳定的能力，使其成为满足我们社会日益增长的能源需求的重要工具。随着我们继续探索利用能源的创新方式，理解像非凸极同步发电机这样的机器的作用，将对塑造可持续的未来至关重要。