magnetic yoke

简明释义

磁轭磁偏角系统

英英释义

例句

1.In construction, a magnetic yoke can help to lift heavy steel beams easily.

在建筑中，磁性架可以帮助轻松提升重型钢梁。

2.When performing non-destructive testing, the inspector utilized a magnetic yoke to detect surface cracks.

在进行无损检测时，检查员利用磁性架检测表面裂纹。

3.A magnetic yoke is essential for ensuring proper alignment of components in assembly lines.

磁性架对于确保装配线组件的正确对齐至关重要。

4.The magnetic yoke was designed to provide a strong magnetic field for lifting ferrous materials.

磁性架的设计旨在提供强大的磁场以提升铁磁材料。

5.The technician used a magnetic yoke to hold the metal pieces in place during the welding process.

技术员使用磁性架在焊接过程中将金属件固定到位。

作文

In the world of physics and engineering, the term magnetic yoke refers to a device that is used to concentrate magnetic fields. It is commonly employed in various applications, including electromagnetic devices, sensors, and magnetic circuits. The magnetic yoke is essentially a piece of ferromagnetic material that provides a path for magnetic flux, allowing for the efficient transmission of magnetic fields. This property makes it an essential component in many technological advancements. Understanding the function of a magnetic yoke can enhance our appreciation of how magnetic fields operate in everyday devices. For instance, in electric motors, the magnetic yoke helps to create a strong magnetic field that is necessary for the motor's operation. By guiding the magnetic lines of force, the yoke ensures that the motor runs smoothly and efficiently. Without such a component, the performance of electric motors would be significantly compromised. Moreover, the magnetic yoke plays a crucial role in magnetic resonance imaging (MRI) machines. In these medical devices, the yoke is used to generate stable and uniform magnetic fields, which are vital for producing clear images of the human body. The precision provided by the magnetic yoke in MRI technology illustrates its importance in the field of medicine, where accurate diagnostics are essential for patient care. The design and material selection for a magnetic yoke are critical factors that influence its effectiveness. Engineers often choose materials with high permeability to optimize the magnetic circuit. Common materials include soft iron and silicon steel, which help to minimize energy losses due to hysteresis and eddy currents. The shape of the yoke can also affect its performance; for instance, a closed-loop design is often preferred to reduce magnetic leakage. In addition to its industrial applications, the concept of a magnetic yoke can also be explored in educational settings. Science teachers frequently use demonstrations involving magnetic yokes to illustrate fundamental principles of magnetism to students. These demonstrations can help students visualize how magnetic fields interact with different materials, fostering a deeper understanding of physics. Furthermore, the principles behind a magnetic yoke can be applied in various innovative projects. For example, hobbyists and engineers alike can create simple electromagnetic devices using a magnetic yoke. Such projects not only enhance practical skills but also encourage creativity and problem-solving abilities. As technology continues to evolve, the significance of magnetic yoke will likely expand, paving the way for new applications in emerging fields such as renewable energy and robotics. In conclusion, the magnetic yoke is a fundamental component in many technological systems, playing a vital role in enhancing the efficiency and effectiveness of magnetic applications. By concentrating magnetic fields, it enables the smooth functioning of various devices, from electric motors to MRI machines. Understanding the importance of the magnetic yoke not only enriches our knowledge of physics and engineering but also inspires future innovations in technology. As we continue to explore the frontiers of science, the magnetic yoke will undoubtedly remain a key player in the development of advanced technologies.

在物理和工程的世界中，术语magnetic yoke指的是一种用于集中磁场的装置。它通常应用于各种领域，包括电磁设备、传感器和磁电路。magnetic yoke本质上是一种铁磁材料，提供了磁通的路径，从而允许高效地传输磁场。这一特性使其成为许多技术进步中不可或缺的组成部分。理解magnetic yoke的功能可以增强我们对日常设备中磁场运作方式的欣赏。例如，在电动机中，magnetic yoke有助于产生电动机运行所需的强磁场。通过引导磁力线，yoke确保电动机平稳高效地运行。如果没有这样的组件，电动机的性能将受到显著影响。此外，magnetic yoke在磁共振成像（MRI）机器中也发挥着至关重要的作用。在这些医疗设备中，yoke用于生成稳定且均匀的磁场，这对于产生清晰的人体图像至关重要。magnetic yoke在MRI技术中提供的精确性说明了其在医学领域的重要性，在这里，准确的诊断对患者护理至关重要。magnetic yoke的设计和材料选择是影响其有效性的关键因素。工程师们通常选择高磁导率的材料以优化磁电路。常用材料包括软铁和硅钢，这有助于最小化由于滞后和涡流造成的能量损失。yoke的形状也会影响其性能；例如，通常优选闭环设计以减少磁泄漏。除了工业应用外，magnetic yoke的概念也可以在教育环境中进行探索。科学教师经常使用涉及magnetic yoke的演示来向学生说明磁性基本原理。这些演示可以帮助学生可视化磁场如何与不同材料相互作用，从而加深对物理学的理解。此外，magnetic yoke背后的原理可以应用于各种创新项目。例如，爱好者和工程师都可以使用magnetic yoke创建简单的电磁设备。这类项目不仅提高了实践技能，还鼓励创造力和解决问题的能力。随着技术的不断发展，magnetic yoke的重要性可能会扩大，为可再生能源和机器人等新兴领域的新应用铺平道路。总之，magnetic yoke是许多技术系统中的基本组成部分，在提高磁性应用的效率和有效性方面发挥着至关重要的作用。通过集中磁场，它使各种设备的平稳运行成为可能，从电动机到MRI机器。理解magnetic yoke的重要性不仅丰富了我们对物理学和工程学的知识，还激励了未来技术的创新。随着我们继续探索科学的前沿，magnetic yoke无疑将在先进技术的发展中继续扮演关键角色。