laminated yoke

简明释义

叠片磁轭

英英释义

例句

1.To achieve better magnetic properties, the team opted for a laminated yoke design.

为了获得更好的磁性特性，团队选择了层压轭设计。

2.The use of a laminated yoke in this application helps to minimize magnetic hysteresis.

在这个应用中使用层压轭有助于最小化磁滞现象。

3.The engineer designed a new motor using a laminated yoke to reduce eddy current losses.

工程师设计了一种新电机，使用了层压轭以减少涡流损失。

4.Our latest model features a laminated yoke that improves performance in high-frequency operations.

我们最新的型号采用了层压轭，在高频操作中提高了性能。

5.In electric transformers, a laminated yoke is essential for enhancing efficiency.

在电力变压器中，层压轭对于提高效率至关重要。

作文

In the field of engineering and manufacturing, the term laminated yoke refers to a specific component used in electromagnetic devices. This component is crucial for enhancing the performance and efficiency of machines such as motors and transformers. A laminated yoke is constructed by stacking multiple thin layers of magnetic material, which are insulated from each other. This design minimizes energy losses due to eddy currents, which can occur in solid metal components when subjected to changing magnetic fields.The advantages of using a laminated yoke are clear. By reducing eddy current losses, these laminated structures allow for better energy efficiency and improved thermal management within the device. For instance, in electric motors, the use of a laminated yoke can lead to a significant reduction in heat generation, which not only enhances the motor's lifespan but also its overall performance. As industries shift towards more sustainable practices, the demand for efficient components like the laminated yoke has grown dramatically.Moreover, the manufacturing process of a laminated yoke involves precision engineering. Engineers must carefully select the materials and thickness of each layer to ensure optimal performance characteristics. The choice of materials, often silicon steel, is critical as it possesses desirable magnetic properties that contribute to the yoke's effectiveness. Additionally, the insulation between layers is essential to prevent unwanted electrical conduction, which could negate the benefits of lamination.In applications such as transformers, the laminated yoke plays a pivotal role in directing magnetic flux. The design allows for a more controlled flow of magnetic lines, thereby increasing the efficiency of power transfer from one coil to another. This capability is vital in the context of high-voltage transformers, where efficiency is paramount to prevent energy losses that can be costly.The evolution of technology has also influenced the design and application of the laminated yoke. With advancements in materials science, new types of magnetic materials are being developed that offer even lower losses and higher performance. This progress is particularly important in the context of renewable energy systems, where efficient electrical components are essential for harnessing and converting energy from sources like wind and solar.In conclusion, the laminated yoke is a fundamental component in many electromagnetic devices, contributing significantly to their efficiency and performance. Its design, which incorporates multiple layers of magnetic material, serves to minimize energy losses and enhance thermal management. As technology continues to advance, the importance of innovations such as the laminated yoke will only increase, paving the way for more efficient and sustainable engineering solutions in the future.

在工程和制造领域，术语层压轭指的是用于电磁设备的特定组件。这个组件对于提高电机和变压器等机器的性能和效率至关重要。层压轭是通过堆叠多层薄的磁性材料构成的，这些材料彼此之间是绝缘的。这个设计最小化了由于涡流导致的能量损失，当固体金属组件受到变化的磁场时，涡流可能会发生。使用层压轭的优点显而易见。通过减少涡流损失，这些层压结构允许更好的能量效率和改善设备内部的热管理。例如，在电动机中，使用层压轭可以显著减少热量产生，这不仅增强了电机的使用寿命，还提高了其整体性能。随着行业向更可持续的实践转变，对像层压轭这样的高效组件的需求急剧增长。此外，层压轭的制造过程涉及精密工程。工程师必须仔细选择每层的材料和厚度，以确保最佳的性能特征。材料的选择，通常是硅钢，是关键，因为它具有有利的磁性特性，有助于轭的有效性。此外，层间绝缘对防止不必要的电导是必不可少的，这可能会抵消层压的好处。在变压器等应用中，层压轭在引导磁通方面发挥着关键作用。该设计允许更受控的磁线流动，从而提高从一个线圈到另一个线圈的功率传输效率。这种能力在高压变压器的背景下尤为重要，在那里效率至关重要，以防止可能昂贵的能量损失。技术的演变也影响了层压轭的设计和应用。随着材料科学的进步，新型磁性材料正在开发，这些材料提供更低的损耗和更高的性能。这一进展在可再生能源系统的背景下尤为重要，因为高效的电气组件对从风能和太阳能等来源获取和转换能量至关重要。总之，层压轭是许多电磁设备中的基本组件，对其效率和性能贡献重大。其设计包含多层磁性材料，有助于最小化能量损失并改善热管理。随着技术的不断进步，像层压轭这样的创新的重要性只会增加，为未来更高效和可持续的工程解决方案铺平道路。