cumulative winding

简明释义

积复励绕组

英英释义

例句

1.In our latest project, we utilized cumulative winding to reduce energy loss.

在我们最新的项目中，我们利用了累积绕组来减少能量损失。

2.The cumulative winding technique is essential for achieving higher torque in electrical machines.

累积绕组技术对于在电机中实现更高的扭矩至关重要。

3.We discussed the benefits of cumulative winding during the engineering meeting.

在工程会议上，我们讨论了累积绕组的好处。

4.The design of the motor includes a feature for cumulative winding, which enhances efficiency.

这款电机的设计包括一个累积绕组特性，从而提高了效率。

5.The cumulative winding method helps to improve the overall performance of the generator.

累积绕组方法有助于提高发电机的整体性能。

作文

The concept of cumulative winding is often encountered in various fields, particularly in engineering and physics. To understand this term better, we should break it down into its components. 'Cumulative' refers to the accumulation of something over time, while 'winding' generally pertains to the action of coiling or twisting. When combined, cumulative winding can be understood as the process of accumulating layers or turns in a winding mechanism, such as in motors or transformers.In electrical engineering, the principle of cumulative winding is critical in the design of inductors and transformers. These devices rely on the creation of magnetic fields through the winding of wire around a core. As more wire is wound, the magnetic field strength increases cumulatively, which enhances the efficiency and performance of the device. This is particularly important in applications where high power levels are necessary, as the cumulative effect of the windings can significantly influence the output.Moreover, cumulative winding is not limited to electrical applications. It can also be observed in mechanical systems, such as springs or coils. In these instances, the cumulative aspect refers to the total amount of energy stored in the system as more coils are added. The more turns a spring has, the greater the potential energy it can store, which is crucial for applications ranging from automotive suspensions to industrial machinery.Understanding cumulative winding also leads us to consider its implications in real-world scenarios. For instance, in the manufacturing of electric motors, engineers must carefully calculate the number of windings needed to achieve desired performance levels. Too few windings may result in insufficient torque, while too many can lead to overheating and inefficiency. Therefore, the concept of cumulative winding becomes a balancing act, requiring precise calculations and considerations.Additionally, the idea of cumulative winding can be applied metaphorically in various disciplines. In education, for example, the cumulative knowledge a student acquires over time can be likened to the winding of wire around a core. Each lesson builds upon the previous one, creating a strong foundation of understanding. Just as in engineering, where the right amount of windings is crucial, students must also find the right balance in their learning processes to ensure they do not become overwhelmed.In conclusion, cumulative winding is a multifaceted concept that spans across different fields, from electrical engineering to education. By recognizing the importance of accumulation in winding processes, we can appreciate the intricacies involved in designing efficient systems and the parallels that exist in our learning journeys. Whether in a technical context or a more abstract application, the principle of cumulative winding serves as a reminder of the power of incremental growth and the importance of balance in achieving optimal outcomes.

“累积绕组”的概念在各个领域中经常出现，尤其是在工程和物理学中。要更好地理解这个术语，我们应该将其分解为两个部分。“累积”是指随着时间的推移而积累的东西，而“绕组”通常涉及卷绕或扭曲的动作。当这两个词结合在一起时，“累积绕组”可以理解为在绕组机制中累积层或圈的过程，例如在电动机或变压器中。在电气工程中，“累积绕组”的原理在电感器和变压器的设计中至关重要。这些设备依赖于通过电线绕在核心周围来创建磁场。随着更多的电线被绕制，磁场强度会累积增加，从而提高设备的效率和性能。这在需要高功率水平的应用中特别重要，因为绕组的累积效应可以显著影响输出。此外，“累积绕组”不仅限于电气应用。在机械系统中，例如弹簧或线圈，也可以观察到这一点。在这些情况下，累积方面指的是随着更多圈的添加而存储在系统中的总能量。弹簧的圈数越多，它可以存储的潜在能量就越大，这对于从汽车悬架到工业机械的应用至关重要。理解“累积绕组”也使我们考虑其在现实世界场景中的影响。例如，在电动机的制造中，工程师必须仔细计算所需的绕组数量，以实现所需的性能水平。绕组过少可能导致扭矩不足，而绕组过多则可能导致过热和低效率。因此，“累积绕组”的概念成为一种平衡行为，需要精确的计算和考虑。此外，“累积绕组”的理念在各个学科中也可以比喻性地应用。例如，在教育中，学生随着时间的推移所获得的累积知识可以比作绕在核心上的电线。每一课都建立在前一课的基础上，创造出坚实的理解基础。就像在工程中，适当数量的绕组至关重要，学生也必须找到学习过程中正确的平衡，以确保他们不会感到不知所措。总之，“累积绕组”是一个跨越不同领域的多面概念，从电气工程到教育。通过认识到绕组过程中累积的重要性，我们可以欣赏到设计高效系统所涉及的复杂性，以及我们学习旅程中存在的相似之处。无论是在技术背景下还是在更抽象的应用中，“累积绕组”的原则都提醒我们逐步增长的力量，以及在实现最佳结果时平衡的重要性。