doubly-fed reentrant winding

简明释义

双线线圈

英英释义

例句

1.The doubly-fed reentrant winding design minimizes losses during power generation.

这种双馈再入绕组设计在发电过程中最小化损耗。

2.Engineers often prefer doubly-fed reentrant winding systems for their ability to handle variable speed operations.

工程师通常更喜欢双馈再入绕组系统，因为它们能够处理变速操作。

3.The use of doubly-fed reentrant winding in wind turbines allows for greater efficiency in energy conversion.

在风力涡轮机中使用双馈再入绕组可以提高能量转换的效率。

4.In the context of renewable energy, doubly-fed reentrant winding plays a crucial role in grid stability.

在可再生能源的背景下，双馈再入绕组在电网稳定性中起着关键作用。

5.The doubly-fed reentrant winding configuration allows for better control of reactive power.

这种双馈再入绕组配置允许对无功功率进行更好的控制。

作文

The concept of doubly-fed reentrant winding is a fascinating topic in the field of electrical engineering, particularly in the design and operation of electric machines. This type of winding configuration allows for improved efficiency and control in various applications, especially in renewable energy systems such as wind turbines. Understanding how this technology works can provide insights into its benefits and potential uses.To begin with, let’s break down what doubly-fed reentrant winding actually means. The term 'doubly-fed' refers to the fact that the winding can be supplied with power from two separate sources or circuits. This dual supply enables the winding to operate under different conditions and enhances its performance. The 'reentrant' aspect indicates that the winding loops back on itself, creating a more complex magnetic field that can be manipulated for better efficiency.One of the primary advantages of using doubly-fed reentrant winding is its ability to handle variable speeds. In wind turbines, for instance, the wind speed can fluctuate significantly. Traditional generators may struggle to maintain efficiency under such conditions, but a machine equipped with doubly-fed reentrant winding can adapt quickly, allowing it to optimize energy capture regardless of the wind's intensity. This adaptability not only increases energy output but also contributes to the overall reliability of the system.Furthermore, the design of doubly-fed reentrant winding can lead to reduced losses during operation. By utilizing this winding configuration, engineers can minimize resistive losses and improve the thermal performance of the machine. This is particularly important in applications where heat management is critical, as excessive heat can lead to decreased efficiency and even damage to components.In addition to its technical advantages, doubly-fed reentrant winding also plays a significant role in enhancing the sustainability of energy systems. As the world moves towards greener energy solutions, the demand for efficient and reliable technologies has never been higher. This winding configuration supports the integration of renewable energy sources into the grid, facilitating the transition to a more sustainable energy landscape.Despite its many benefits, the implementation of doubly-fed reentrant winding is not without challenges. Engineers must carefully consider the design and materials used in the winding to ensure optimal performance and longevity. Additionally, the complexity of the system may require advanced control strategies and monitoring systems to manage its operation effectively.In conclusion, the doubly-fed reentrant winding is an innovative solution that addresses many of the challenges faced in modern electrical engineering. Its unique characteristics allow for enhanced efficiency, adaptability to variable conditions, and a contribution to sustainable energy practices. As technology continues to evolve, the importance of understanding and utilizing such advanced winding configurations will only grow, paving the way for a more efficient and environmentally friendly future in energy generation and distribution.

‘双馈再入绕组’这一概念在电气工程领域是一个引人入胜的话题，特别是在电机的设计和运行中。这种绕组配置能够提高效率和控制能力，尤其是在风力涡轮机等可再生能源系统中。理解这一技术的工作原理可以为其优点和潜在用途提供深刻的见解。首先，让我们拆分一下‘双馈再入绕组’的实际含义。“双馈”一词指的是该绕组可以从两个独立的电源或电路供电。这种双重供电使得绕组能够在不同条件下运行，并增强其性能。“再入”方面则表明绕组回路自身形成闭合，创造出更复杂的磁场，可以被操控以提高效率。使用‘双馈再入绕组’的主要优点之一是其处理可变速度的能力。例如，在风力涡轮机中，风速可能会显著波动。传统发电机可能难以在这种情况下保持效率，但配备了‘双馈再入绕组’的机器可以快速适应，从而优化无论风力强度如何的能量捕获。这种适应性不仅增加了能量输出，还提高了系统的整体可靠性。此外，‘双馈再入绕组’的设计可以在运行过程中减少损耗。通过利用这种绕组配置，工程师可以最小化电阻损耗，提高机器的热性能。这在热管理至关重要的应用中尤为重要，因为过多的热量可能导致效率降低甚至对组件造成损害。除了技术优势外，‘双馈再入绕组’在提高能源系统的可持续性方面也发挥着重要作用。随着世界向绿色能源解决方案转型，对高效可靠技术的需求从未如此之高。这种绕组配置支持可再生能源源的网格整合，促进向更可持续的能源格局的转变。尽管有许多好处，但实施‘双馈再入绕组’并非没有挑战。工程师必须仔细考虑绕组的设计和所用材料，以确保最佳性能和耐久性。此外，系统的复杂性可能需要先进的控制策略和监控系统来有效管理其运行。总之，‘双馈再入绕组’是一种创新解决方案，解决了现代电气工程面临的许多挑战。其独特的特性允许增强效率、适应可变条件，并对可持续能源实践做出贡献。随着技术的不断发展，理解和利用这种先进的绕组配置的重要性只会增加，为能源生成和分配的更高效和环保的未来铺平道路。