revolving field type

简明释义

旋转磁场式

英英释义

例句

1.By implementing a revolving field type, we can ensure that our records are always up to date.

通过实施循环字段类型，我们可以确保记录始终是最新的。

2.The revolving field type enables the system to adapt to changing data requirements.

循环字段类型使系统能够适应不断变化的数据需求。

3.The project manager suggested using a revolving field type for better data management.

项目经理建议使用循环字段类型以更好地管理数据。

4.In our application, we utilize a revolving field type to manage user preferences efficiently.

在我们的应用程序中，我们利用循环字段类型高效管理用户偏好。

5.The database was designed with a revolving field type to allow for dynamic updates.

数据库设计采用了循环字段类型，以便允许动态更新。

作文

In the realm of technology and engineering, various concepts and terminologies are frequently used to describe specific systems or methodologies. One such term that has gained attention in recent years is the revolving field type. This concept is particularly significant in the context of electric machines, especially in generators and motors. The revolving field type refers to a system where the magnetic field rotates around a stationary armature, creating an efficient means of generating electricity or converting electrical energy into mechanical energy. Understanding the mechanics behind the revolving field type requires a basic grasp of electromagnetic principles. In essence, when an electric current passes through a coil of wire, it generates a magnetic field. When this coil is placed within a larger magnetic field, the interaction between the two fields can induce motion. This principle is the foundation of many modern electrical devices, including alternators and synchronous motors. The advantages of using the revolving field type design are numerous. First and foremost, it allows for greater efficiency in energy conversion. Since the magnetic field is rotating, it can continuously interact with the armature, leading to a more consistent output of power. This is particularly important in applications where stable energy supply is critical, such as in industrial machinery and power generation facilities. Moreover, the revolving field type can be scaled to various sizes, making it versatile for different applications. Small-scale versions can be found in household appliances, while larger models are used in power plants to generate electricity for entire cities. This adaptability is one of the key reasons why the revolving field type remains a popular choice among engineers and designers. However, like any technology, the revolving field type does have its drawbacks. The complexity of the design can lead to higher manufacturing costs, which may deter some companies from adopting this technology. Additionally, the maintenance of such systems can be more challenging compared to simpler designs, requiring specialized knowledge and skills. Despite these challenges, the importance of the revolving field type cannot be overstated. As we move towards a future that increasingly relies on renewable energy sources, understanding and improving upon existing technologies will be crucial. The revolving field type offers a pathway to more efficient and sustainable energy solutions, aligning with global efforts to reduce carbon footprints and promote eco-friendly practices. In conclusion, the revolving field type is a fundamental concept in the field of electrical engineering that plays a vital role in the operation of many machines we rely on today. Its ability to efficiently convert energy forms makes it indispensable in both industrial and consumer applications. As we continue to innovate and seek out new energy solutions, the principles behind the revolving field type will undoubtedly remain relevant and influential in shaping the future of technology.

在技术和工程领域，许多概念和术语被频繁使用，以描述特定的系统或方法。其中一个近年来受到关注的术语是旋转场类型。这个概念在电机，特别是发电机和电动机的背景下尤为重要。旋转场类型指的是一种系统，其中磁场围绕静止的电枢旋转，从而创建一种高效的发电或将电能转化为机械能的方式。理解旋转场类型背后的机制需要对电磁原理有基本的了解。本质上，当电流通过一组导线圈时，它会产生一个磁场。当这个线圈放置在一个更大的磁场中时，两个磁场之间的相互作用可以引起运动。这一原理是许多现代电气设备的基础，包括交流发电机和同步电动机。使用旋转场类型设计的优点是众多的。首先，它允许在能量转换中实现更高的效率。由于磁场在旋转，它可以持续与电枢相互作用，从而导致更稳定的功率输出。这在工业机械和发电设施等对稳定能源供应至关重要的应用中尤其重要。此外，旋转场类型可以根据不同的应用进行规模化，使其具有多样性。小型版本可以在家用电器中找到，而大型模型则用于发电厂为整个城市发电。这种适应性是旋转场类型仍然受到工程师和设计师欢迎的关键原因之一。然而，与任何技术一样，旋转场类型也有其缺点。设计的复杂性可能导致更高的制造成本，这可能使一些公司不愿采用这项技术。此外，与较简单的设计相比，这种系统的维护可能更加困难，需要专业的知识和技能。尽管存在这些挑战，但旋转场类型的重要性不可低估。随着我们朝着越来越依赖可再生能源的未来迈进，理解和改进现有技术将至关重要。旋转场类型提供了一条通向更高效和可持续能源解决方案的道路，与全球减少碳足迹和促进环保实践的努力保持一致。总之，旋转场类型是电气工程领域的一个基本概念，在我们今天依赖的许多机器的运行中发挥着至关重要的作用。它高效地转换能量形式的能力使其在工业和消费者应用中不可或缺。随着我们继续创新并寻求新的能源解决方案，旋转场类型背后的原理无疑将继续在塑造技术的未来中保持相关性和影响力。