non-salient-pole machine

简明释义

隐极电机

英英释义

例句

1.Many industrial applications rely on non-salient-pole machines 非显著极机 due to their durability.

许多工业应用依赖于非显著极机，因为它们的耐用性。

2.The design of a non-salient-pole machine 非显著极机 allows for better thermal management.

非显著极机的设计允许更好的热管理。

3.In power generation, a non-salient-pole machine 非显著极机 can provide a more consistent output.

在发电中，非显著极机可以提供更稳定的输出。

4.The efficiency of a non-salient-pole machine 非显著极机 is often higher than that of salient-pole machines in certain applications.

在某些应用中，非显著极机的效率通常高于显著极机。

5.Engineers prefer non-salient-pole machines 非显著极机 for their stability in high-speed operations.

工程师更喜欢非显著极机，因为它们在高速操作中的稳定性。

作文

The world of electrical engineering is filled with various types of machines, each designed for specific applications and functionalities. Among these machines, the non-salient-pole machine stands out due to its unique characteristics and operational principles. Understanding what a non-salient-pole machine is, along with its advantages and applications, is crucial for anyone interested in electrical machinery. A non-salient-pole machine, also known as a cylindrical rotor machine, is characterized by its smooth and continuous rotor surface, which lacks any prominent poles. This design allows for a more uniform magnetic field distribution and enables the machine to operate efficiently at high speeds. The absence of salient poles means that the rotor can rotate without experiencing significant variations in torque, making it suitable for applications requiring stable performance. One of the primary advantages of a non-salient-pole machine is its ability to operate at synchronous speeds. This is particularly beneficial in applications such as generators and synchronous motors, where maintaining a constant speed is essential. In power generation, for instance, these machines can provide a steady output, which is vital for the stability of the electrical grid. Additionally, their design allows for reduced losses due to lower resistance and better thermal management, further enhancing their efficiency. The non-salient-pole machine is commonly used in large-scale industrial applications. For example, in hydroelectric power plants, these machines are often employed to convert mechanical energy from flowing water into electrical energy. The consistent performance of a non-salient-pole machine ensures that power generation remains stable, even under varying load conditions. Moreover, they are also found in various transportation systems, such as electric trains, where high-speed operation and reliability are paramount. Despite their many advantages, non-salient-pole machines do have some limitations. One notable drawback is their relatively complex construction, which can lead to higher manufacturing costs compared to other types of machines, such as salient-pole machines. Furthermore, the lack of salient poles can limit their torque production capabilities, making them less suitable for applications that require high starting torque. In conclusion, the non-salient-pole machine plays a significant role in the field of electrical engineering. Its unique design, which features a smooth rotor surface, allows for efficient operation at high speeds and stable performance in various applications. While there are some drawbacks to consider, the benefits of using a non-salient-pole machine in industrial settings cannot be overlooked. As technology continues to advance, the importance of understanding and utilizing these machines will only grow, highlighting their relevance in modern engineering practices.

电气工程的世界充满了各种类型的机器，每种机器都设计用于特定的应用和功能。在这些机器中，非突出极机器因其独特的特性和操作原理而脱颖而出。理解什么是非突出极机器，以及它的优点和应用，对于任何对电气机械感兴趣的人来说都是至关重要的。非突出极机器，也称为圆柱形转子机器，其特点是光滑且连续的转子表面，没有任何明显的极。这种设计允许更均匀的磁场分布，使机器能够在高速下高效运行。由于没有突出极，转子可以旋转而不会经历显著的扭矩变化，这使其适合需要稳定性能的应用。非突出极机器的主要优点之一是其能够以同步速度运行。这在发电机和同步电动机等应用中尤为有利，在这些应用中，保持恒定速度至关重要。例如，在水电站中，这些机器通常被用来将流动水的机械能转化为电能。非突出极机器的一致性能确保了即使在负载条件变化时，发电仍然稳定。此外，它们的设计还允许由于较低的电阻和更好的热管理而减少损失，从而进一步提高效率。非突出极机器通常用于大规模工业应用。例如，在水电站中，这些机器常用于将流动水的机械能转化为电能。非突出极机器的一致性能确保了即使在负载条件变化时，发电仍然稳定。此外，它们也出现在各种交通系统中，如电动火车，在这些系统中，高速运行和可靠性至关重要。尽管有许多优点，非突出极机器确实存在一些局限性。其中一个显著的缺点是其相对复杂的结构，这可能导致制造成本高于其他类型的机器，如突出极机器。此外，缺乏突出极可能限制其扭矩产生能力，使其不太适合需要高起始扭矩的应用。总之，非突出极机器在电气工程领域中发挥着重要作用。其独特的设计，具有光滑的转子表面，使其能够高效地在高速下运行，并在各种应用中保持稳定性能。尽管存在一些需要考虑的缺点，但在工业环境中使用非突出极机器的好处不容忽视。随着技术的不断进步，理解和利用这些机器的重要性只会增加，突显它们在现代工程实践中的相关性。