auxiliary magnet

简明释义

1. 辅磁; 2. 辅助磁铁;

英英释义

例句

1.We used an auxiliary magnet to improve the performance of our experimental setup.

我们使用了一个辅助磁铁来提高实验装置的性能。

2.The auxiliary magnet was crucial for stabilizing the system during operation.

在操作过程中，辅助磁铁对系统的稳定至关重要。

3.The engineer installed an auxiliary magnet to enhance the efficiency of the motor.

工程师安装了一个辅助磁铁以提高电动机的效率。

4.The auxiliary magnet can be adjusted to fine-tune the device's output.

可以调整辅助磁铁来微调设备的输出。

5.In the new design, the auxiliary magnet provides additional support for the main magnetic field.

在新设计中，辅助磁铁为主磁场提供了额外的支持。

作文

In the world of electromagnetism, various components play crucial roles in enhancing the performance and efficiency of magnetic systems. One such component is the auxiliary magnet, which serves as a supportive element in magnetic applications. The auxiliary magnet (辅助磁体) can be used in different contexts, including electrical machines, magnetic resonance imaging (MRI), and particle accelerators. Understanding its function and significance can shed light on its importance in modern technology.The primary purpose of an auxiliary magnet is to provide additional magnetic field strength or to modify the existing field in a controlled manner. For instance, in electric motors, the auxiliary magnet can enhance the overall torque and efficiency by creating a stronger magnetic field that interacts with the rotor. This is particularly important in applications where high performance is required, such as in electric vehicles or industrial machinery. By optimizing the magnetic field, engineers can achieve better energy conversion and reduce losses, leading to more sustainable and efficient systems.In the realm of medical technology, the auxiliary magnet plays a pivotal role in MRI machines. These machines rely on powerful magnets to create detailed images of the human body. An auxiliary magnet can help stabilize the magnetic field and improve the quality of the images produced. By ensuring that the magnetic field remains uniform and stable, the auxiliary magnet contributes to clearer and more accurate diagnostic results. This is essential for healthcare professionals who depend on precise imaging to make informed decisions about patient care.Another significant application of the auxiliary magnet is found in particle accelerators, where it aids in steering and focusing particle beams. In these complex machines, multiple magnets work together to control the paths of charged particles. The auxiliary magnet provides additional guidance, ensuring that particles are directed accurately along their intended trajectories. This is crucial for experiments in high-energy physics, where even the slightest deviation can lead to inaccurate results or failed experiments.Moreover, the design of an auxiliary magnet can vary depending on its specific application. Engineers must consider factors such as size, shape, and material when developing an auxiliary magnet to ensure optimal performance. For example, in compact devices, miniaturized auxiliary magnets may be required, while larger systems might utilize more robust designs. The choice of materials also impacts the strength and efficiency of the auxiliary magnet, making it an essential consideration during the design process.In conclusion, the auxiliary magnet (辅助磁体) is a vital component in many technological applications, enhancing the performance of systems ranging from electric motors to medical imaging devices. Its ability to provide additional magnetic support allows for greater efficiency, accuracy, and reliability in various fields. As technology continues to advance, the role of the auxiliary magnet will likely become even more significant, paving the way for innovations that rely on precise magnetic control. Understanding the intricacies of the auxiliary magnet not only highlights its importance but also inspires further research and development in the field of electromagnetism.

在电磁学的世界中，各种组件在增强磁性系统的性能和效率方面发挥着至关重要的作用。其中一个重要组件是辅助磁体，它作为磁性应用中的支持元素。辅助磁体（auxiliary magnet）可以在不同的背景下使用，包括电气机器、磁共振成像（MRI）和粒子加速器。理解它的功能和重要性可以揭示其在现代技术中的重要性。辅助磁体的主要目的是提供额外的磁场强度或以受控方式修改现有的磁场。例如，在电动机中，辅助磁体可以通过创建一个更强的磁场来增强整体扭矩和效率，从而与转子相互作用。这在电动车辆或工业机械等需要高性能的应用中尤为重要。通过优化磁场，工程师可以实现更好的能量转换，减少损耗，从而导致更可持续和高效的系统。在医疗技术领域，辅助磁体在MRI机器中发挥着关键作用。这些机器依赖强大的磁体来创建人体的详细图像。辅助磁体可以帮助稳定磁场并改善生成图像的质量。通过确保磁场保持均匀和稳定，辅助磁体有助于产生更清晰、更准确的诊断结果。这对于依赖精确成像做出明智决策的医疗专业人员至关重要。辅助磁体的另一个重要应用是在粒子加速器中，它帮助引导和聚焦粒子束。在这些复杂的机器中，多种磁体共同工作以控制带电粒子的路径。辅助磁体提供额外的引导，确保粒子沿其预定轨迹准确地被引导。这对于高能物理实验至关重要，因为即使是最轻微的偏差也可能导致不准确的结果或实验失败。此外，辅助磁体的设计可以根据其特定应用而有所不同。工程师必须考虑尺寸、形状和材料等因素，以确保辅助磁体的最佳性能。例如，在紧凑型设备中，可能需要微型化的辅助磁体，而较大系统则可能利用更坚固的设计。材料的选择也会影响辅助磁体的强度和效率，因此在设计过程中是一个重要的考虑因素。总之，辅助磁体（auxiliary magnet）是许多技术应用中的重要组件，增强了从电动机到医疗成像设备的系统性能。它提供额外的磁性支持，使得在各个领域都能实现更高的效率、准确性和可靠性。随着技术的不断进步，辅助磁体的作用可能会变得更加重要，为依赖精确磁控的创新铺平道路。理解辅助磁体的复杂性不仅突显了其重要性，也激励了电磁学领域进一步的研究和发展。