armature iron

简明释义

衔铁

英英释义

例句

1.During the inspection, the engineer checked the placement of the armature iron in the foundation.

在检查过程中，工程师检查了基础中钢筋的放置情况。

2.The construction team used armature iron to reinforce the concrete structure.

施工队使用钢筋来加固混凝土结构。

3.We are sourcing armature iron from a local supplier to reduce transportation costs.

我们正在从当地供应商采购钢筋以降低运输成本。

4.The architect specified that all beams must include armature iron for added strength.

建筑师规定所有梁必须包含钢筋以增加强度。

5.To ensure durability, we need to select high-quality armature iron for this project.

为了确保耐用性，我们需要为这个项目选择高质量的钢筋。

作文

In the world of electrical engineering and electromagnetism, the term armature iron holds significant importance. It refers to a type of iron that is specifically used in the construction of armatures in electric machines such as motors and generators. The armature is a crucial component that carries current and interacts with the magnetic field to produce motion or generate electricity. Understanding the properties and applications of armature iron is essential for anyone involved in designing or working with these machines.One of the primary characteristics of armature iron is its high magnetic permeability. This means that it can easily become magnetized when exposed to a magnetic field, allowing for efficient energy transfer within the machine. The use of armature iron helps to minimize energy losses due to heat and enhances the overall performance of the electric machine. Engineers often select specific grades of armature iron based on their magnetic properties, mechanical strength, and thermal conductivity to optimize the efficiency of the device.Another important aspect of armature iron is its ability to withstand repeated cycles of magnetization and demagnetization. In electric machines, the armature experiences continuous changes in magnetic fields, which can lead to fatigue in materials that are not designed for such conditions. High-quality armature iron is manufactured to endure these stresses, ensuring longevity and reliability in operation.The manufacturing process of armature iron involves the use of specific alloys and treatments that enhance its magnetic properties. For instance, silicon steel is often used in the production of armature iron because it offers improved electrical resistance and lower hysteresis losses. These enhancements contribute to the efficiency of electric machines, making armature iron a critical material in modern technology.In practical applications, armature iron is found in various devices, from small household appliances to large industrial machinery. For example, in a simple electric motor, the armature made of armature iron rotates within a magnetic field, converting electrical energy into mechanical energy. Similarly, in generators, the armature plays a vital role in converting mechanical energy back into electrical energy.Furthermore, advancements in technology continue to influence the development of armature iron. Researchers are exploring new materials and composites that could further enhance the performance of electric machines. Innovations in nanotechnology and advanced metallurgy may lead to the creation of even more efficient armature iron variants, pushing the boundaries of what is possible in electrical engineering.In conclusion, the significance of armature iron in the realm of electrical engineering cannot be overstated. Its unique properties make it indispensable in the construction of electric machines, ensuring efficient energy conversion and reliable performance. As technology continues to evolve, the role of armature iron will likely adapt, paving the way for new innovations in the industry. For students and professionals alike, a solid understanding of armature iron and its applications is crucial for success in the field of electrical engineering.

在电气工程和电磁学的世界中，术语电枢铁具有重要意义。它指的是一种特定用于电动机和发电机等电气机器电枢构造的铁。电枢是一个至关重要的组件，它携带电流并与磁场相互作用以产生运动或发电。理解电枢铁的性质和应用对于任何参与设计或使用这些机器的人来说都是必不可少的。电枢铁的主要特征之一是其高磁导率。这意味着它在暴露于磁场时可以很容易地被磁化，从而实现机器内部的有效能量传递。使用电枢铁有助于最小化由于热量造成的能量损失，并增强电气机器的整体性能。工程师通常根据其磁性、机械强度和热导率选择特定等级的电枢铁，以优化设备的效率。电枢铁的另一个重要方面是其承受重复磁化和去磁循环的能力。在电气机器中，电枢会经历持续的磁场变化，这可能导致不适合这种条件的材料疲劳。高品质的电枢铁经过制造，以承受这些压力，确保操作的耐久性和可靠性。电枢铁的制造过程涉及使用特定合金和处理方法，以增强其磁性。例如，硅钢通常用于生产电枢铁，因为它提供了改善的电阻和较低的滞后损耗。这些增强有助于提高电气机器的效率，使电枢铁成为现代技术中的关键材料。在实际应用中，电枢铁可在各种设备中找到，从小型家用电器到大型工业机械。例如，在简单的电动机中，由电枢铁制成的电枢在磁场中旋转，将电能转换为机械能。同样，在发电机中，电枢在将机械能重新转换为电能方面发挥着至关重要的作用。此外，技术的进步继续影响电枢铁的发展。研究人员正在探索新的材料和复合材料，以进一步增强电气机器的性能。纳米技术和先进冶金学的创新可能导致更高效的电枢铁变体的产生，推动电气工程领域的可能性。总之，电枢铁在电气工程领域的重要性不容小觑。其独特的性质使其在电气机器的构造中不可或缺，确保高效的能量转换和可靠的性能。随着技术的不断发展，电枢铁的角色可能会适应，为工业中的新创新铺平道路。对于学生和专业人士而言，深入理解电枢铁及其应用对于在电气工程领域取得成功至关重要。