non-integral-slot winding

简明释义

非整数槽绕组

英英释义

例句

1.Researchers found that non-integral-slot winding (非整数槽绕组) helps in minimizing losses during operation.

研究人员发现，非整数槽绕组 (非整数槽绕组)有助于在运行过程中最小化损耗。

2.The non-integral-slot winding (非整数槽绕组) technique can reduce cogging torque in electric machines.

使用非整数槽绕组 (非整数槽绕组)技术可以减少电动机中的齿槽转矩。

3.The application of non-integral-slot winding (非整数槽绕组) can lead to a more compact motor design.

应用非整数槽绕组 (非整数槽绕组)可以导致更紧凑的电机设计。

4.Manufacturers are exploring non-integral-slot winding (非整数槽绕组) designs for improved thermal performance.

制造商正在探索非整数槽绕组 (非整数槽绕组)设计，以改善热性能。

5.In designing high-efficiency motors, engineers often consider using non-integral-slot winding (非整数槽绕组) to optimize performance.

在设计高效电机时，工程师通常考虑使用非整数槽绕组 (非整数槽绕组)以优化性能。

作文

The world of electrical engineering is filled with complex concepts and terminologies that can often be overwhelming. One such term that stands out is non-integral-slot winding, which refers to a specific type of winding arrangement used in electric machines. To fully appreciate the significance of non-integral-slot winding, it is essential to understand its role in the design and functionality of motors and generators.In traditional winding configurations, integral slot windings are commonly employed. These involve winding the coils into slots that are designed to fit perfectly within the stator or rotor of the machine. However, non-integral-slot winding takes a different approach by allowing for a more flexible arrangement of the windings. This method does not restrict the coils to the physical dimensions of the slots, thus enabling engineers to optimize the performance of the machine based on specific requirements.One of the primary advantages of non-integral-slot winding is its ability to minimize harmonic distortion in the generated electromagnetic fields. By carefully designing the winding layout, engineers can achieve a smoother magnetic field distribution, which translates into improved efficiency and reduced noise during operation. This is particularly beneficial in applications where precision and quiet operation are paramount, such as in electric vehicles or high-performance industrial motors.Moreover, non-integral-slot winding allows for greater flexibility in the design process. Engineers can experiment with various configurations to find the optimal arrangement that meets their performance criteria. This adaptability is crucial in modern engineering, where the demands for efficiency and sustainability are ever-increasing. As a result, many manufacturers are now incorporating non-integral-slot winding into their designs to stay competitive in the market.Another significant aspect of non-integral-slot winding is its impact on thermal management within electric machines. The unique arrangement of the windings can lead to better heat dissipation properties, allowing the machine to operate at higher temperatures without compromising performance. This is especially important in high-power applications where overheating can lead to catastrophic failures.Despite its advantages, non-integral-slot winding is not without its challenges. The complexity of the winding arrangement can lead to increased manufacturing costs and longer production times. Additionally, the design and analysis of these windings require advanced computational tools and expertise, which may not be readily available to all manufacturers.In conclusion, non-integral-slot winding represents a significant advancement in the field of electrical engineering. Its ability to enhance performance, reduce harmonic distortion, and improve thermal management makes it an attractive option for modern electric machines. As technology continues to evolve, it is likely that we will see even more innovative applications of non-integral-slot winding in various industries. Understanding this concept is crucial for anyone involved in the design and manufacturing of electric machines, as it opens up new possibilities for efficiency and performance optimization. Ultimately, the future of electric machines may very well depend on the continued exploration and implementation of non-integral-slot winding techniques.

电气工程的世界充满了复杂的概念和术语，这些内容常常让人感到不知所措。其中一个突出的术语是非整槽绕组，它指的是在电动机和发电机中使用的一种特定绕组排列方式。要充分理解非整槽绕组的重要性，必须了解其在电机设计和功能中的作用。在传统的绕组配置中，通常采用整槽绕组。这些绕组将线圈缠绕在设计得完美适合机器定子或转子的槽内。然而，非整槽绕组采取了不同的方法，允许绕组以更灵活的方式排列。这种方法并不限制线圈的物理尺寸，因此使工程师能够根据特定要求优化机器的性能。非整槽绕组的主要优点之一是能够最小化产生的电磁场中的谐波失真。通过精心设计绕组布局，工程师可以实现更平滑的磁场分布，这转化为提高效率和降低操作噪音。这在对精度和安静操作要求较高的应用中尤为有利，例如电动车辆或高性能工业电动机。此外，非整槽绕组还允许设计过程中的更大灵活性。工程师可以尝试各种配置，以找到满足其性能标准的最佳排列。这种适应性在现代工程中至关重要，因为对效率和可持续性的需求日益增加。因此，许多制造商现在将非整槽绕组纳入他们的设计中，以在市场上保持竞争力。非整槽绕组的另一个重要方面是其对电动机内部热管理的影响。绕组的独特排列可以导致更好的散热性能，使机器能够在更高温度下运行而不妨碍性能。这在高功率应用中尤其重要，因为过热可能导致灾难性的故障。尽管有其优点，非整槽绕组也并非没有挑战。绕组排列的复杂性可能导致制造成本增加和生产时间延长。此外，这些绕组的设计和分析需要先进的计算工具和专业知识，而这些可能并不是所有制造商都能轻易获得的。总之，非整槽绕组代表了电气工程领域的一项重大进展。其增强性能、减少谐波失真和改善热管理的能力，使其成为现代电动机的一个有吸引力的选择。随着技术的不断发展，我们可能会在各个行业看到非整槽绕组的更多创新应用。理解这一概念对于任何参与电动机设计和制造的人来说都是至关重要的，因为它为效率和性能优化开辟了新的可能性。最终，电动机的未来可能在很大程度上取决于对非整槽绕组技术的持续探索和实施。