magnetic inductive capacity

简明释义

导磁率

英英释义

例句

1.The engineer measured the magnetic inductive capacity 磁感应能力 of the new material to determine its suitability for transformer cores.

工程师测量了新材料的磁感应能力 磁感应能力以确定其在变压器核心中的适用性。

2.The magnetic inductive capacity 磁感应能力 of the coil affects its efficiency in energy transfer.

线圈的磁感应能力 磁感应能力影响其能量传输的效率。

3.Understanding the magnetic inductive capacity 磁感应能力 is crucial for designing high-performance inductors.

理解磁感应能力 磁感应能力对于设计高性能电感器至关重要。

4.The testing results showed that the magnetic inductive capacity 磁感应能力 of the sample was higher than expected.

测试结果显示样品的磁感应能力 磁感应能力高于预期。

5.In the lab, we conducted experiments to analyze the magnetic inductive capacity 磁感应能力 of various alloys.

在实验室，我们进行了实验以分析各种合金的磁感应能力 磁感应能力。

作文

Understanding the concept of magnetic inductive capacity is essential for anyone interested in the fields of physics and engineering. This term refers to the ability of a material to store magnetic energy within itself when exposed to an external magnetic field. To grasp this idea better, we need to break down the components involved in magnetic inductive capacity and explore its implications in real-world applications.At its core, magnetic inductive capacity is influenced by the material's permeability, which is a measure of how easily a magnetic field can penetrate the material. Materials with high permeability are often used in applications where efficient magnetic energy storage is crucial, such as in transformers and inductors. For instance, iron is commonly used in transformer cores due to its high permeability, allowing it to effectively channel and store magnetic energy, thus enhancing the transformer's efficiency.Moreover, the concept of magnetic inductive capacity is not limited to just ferromagnetic materials. Even non-magnetic materials can exhibit some level of inductive capacity, albeit to a lesser extent. This is particularly important in designing electrical circuits where varying levels of inductance can affect the overall performance. Engineers must consider magnetic inductive capacity when selecting materials for components that will be subjected to changing magnetic fields.One practical application of magnetic inductive capacity can be found in wireless charging technology. This innovative method uses electromagnetic fields to transfer energy between two objects, usually a charging pad and a device. The efficiency of this energy transfer heavily relies on the magnetic inductive capacity of the materials used in both the charging pad and the device. By optimizing these materials, manufacturers can improve the speed and effectiveness of wireless charging systems.Additionally, understanding magnetic inductive capacity plays a vital role in the development of various electronic devices, including smartphones, electric vehicles, and even medical equipment like MRI machines. In these applications, engineers must ensure that the materials selected for construction have the appropriate magnetic inductive capacity to meet specific performance criteria.In conclusion, the study of magnetic inductive capacity is fundamental in the realm of physics and engineering. It encompasses the ability of materials to store magnetic energy and is critical in various applications ranging from transformers to wireless charging systems. As technology continues to evolve, the importance of understanding and utilizing magnetic inductive capacity will only grow, leading to more efficient designs and innovations in the field. By delving deeper into this concept, we can appreciate its significance in our everyday lives and its potential for future advancements.

理解磁感应能力的概念对于任何对物理和工程领域感兴趣的人来说都是至关重要的。这个术语指的是材料在暴露于外部磁场时存储磁能的能力。为了更好地掌握这个概念，我们需要分解磁感应能力涉及的组成部分，并探索其在现实世界应用中的意义。从根本上说，磁感应能力受到材料磁导率的影响，磁导率是衡量磁场在材料中渗透的容易程度。具有高磁导率的材料通常用于需要高效磁能存储的应用中，例如变压器和电感器。例如，铁常用于变压器的铁芯，因为它具有高磁导率，能够有效地引导和存储磁能，从而提高变压器的效率。此外，磁感应能力的概念并不仅限于铁磁材料。即使是非磁性材料也可以表现出一定程度的感应能力，尽管程度较低。这在设计电路时尤其重要，因为变化的感应水平会影响整体性能。工程师在选择将要受到变化磁场影响的组件材料时，必须考虑磁感应能力。磁感应能力的一个实际应用可以在无线充电技术中找到。这种创新方法利用电磁场在两个物体之间传输能量，通常是充电垫和设备。此能量传输的效率在很大程度上依赖于充电垫和设备所用材料的磁感应能力。通过优化这些材料，制造商可以提高无线充电系统的速度和有效性。此外，理解磁感应能力在各种电子设备的发展中发挥着重要作用，包括智能手机、电动车，甚至医疗设备如MRI机器。在这些应用中，工程师必须确保所选材料具有适当的磁感应能力以满足特定的性能标准。总之，研究磁感应能力在物理和工程领域是基础。它涵盖了材料存储磁能的能力，并在从变压器到无线充电系统等各种应用中至关重要。随着技术的不断发展，理解和利用磁感应能力的重要性只会增加，从而导致更高效的设计和创新。通过深入研究这一概念，我们可以欣赏它在日常生活中的重要性及其对未来进步的潜力。