heeling magnet

简明释义

倾差校正磁铁

英英释义

例句

1.The heeling magnet is essential for large yachts that experience significant tilting in rough seas.

对于在恶劣海况中经历显著倾斜的大型游艇来说，倾斜磁铁是必不可少的。

2.The captain explained how the heeling magnet works to new crew members during the orientation.

船长在培训期间向新船员解释了倾斜磁铁的工作原理。

3.During the test, the engineers adjusted the heeling magnet to ensure the vessel remained upright.

在测试过程中，工程师调整了倾斜磁铁以确保船只保持直立。

4.By using a heeling magnet, the crew was able to maintain better control during the storm.

通过使用倾斜磁铁，船员能够在暴风雨中保持更好的控制。

5.The ship's stability was improved by installing a heeling magnet, which helps counteract the effects of strong winds.

通过安装一个倾斜磁铁，船的稳定性得到了改善，有助于抵消强风的影响。

作文

In the world of physics and engineering, there are numerous concepts that play a crucial role in the functioning of various devices and systems. One such concept is the heeling magnet, which is essential in understanding how certain magnetic systems work. The term heeling magnet refers to a type of magnet that is used to stabilize or correct the orientation of a system, particularly in the context of boats and ships. When a vessel is subjected to external forces such as wind or waves, it may tilt or heel to one side. The heeling magnet helps to counteract this tilt by providing a magnetic force that stabilizes the boat's position.The application of heeling magnets can be observed in various maritime technologies. For instance, many modern boats are equipped with electronic stabilization systems that utilize heeling magnets to maintain an upright position. This is particularly important for ensuring the safety and comfort of passengers on board. Without the assistance of heeling magnets, a boat may experience excessive tilting, leading to potential capsizing or loss of control.Moreover, the concept of heeling magnets extends beyond maritime applications. In robotics, for example, heeling magnets can be employed in balancing mechanisms for robotic arms and drones. By adjusting the magnetic forces, engineers can achieve greater stability and control over the movement of these devices. This shows how versatile the application of heeling magnets can be across different fields.Understanding the principles behind heeling magnets requires a grasp of basic magnetic theory. Magnets produce a magnetic field that can exert forces on other magnetic materials. When a heeling magnet is placed strategically within a system, it can influence the overall balance and orientation of that system. This principle is not only limited to physical objects; it also has implications in theoretical physics, where the behavior of particles and fields can be analyzed in terms of magnetic interactions.In conclusion, the heeling magnet is a vital component in various technologies that require stability and control. Its role in maritime applications highlights the importance of maintaining balance in dynamic environments. As technology continues to advance, the use of heeling magnets is likely to expand, offering new solutions for stability in both mechanical and electronic systems. Understanding the function and application of heeling magnets is essential for anyone interested in engineering, physics, or technology, as it opens up new avenues for innovation and design.

在物理和工程的世界中，有许多概念在各种设备和系统的运行中发挥着至关重要的作用。其中一个概念是倾斜磁铁，它对于理解某些磁性系统的工作原理至关重要。术语倾斜磁铁指的是一种用于稳定或校正系统方向的磁铁，特别是在船只和船舶的背景下。当船只受到风或波浪等外力的影响时，它可能会向一侧倾斜。倾斜磁铁通过提供一种磁力来抵消这种倾斜，从而稳定船只的位置。倾斜磁铁的应用可以在各种海洋技术中观察到。例如，许多现代船只配备了利用倾斜磁铁来保持直立位置的电子稳定系统。这对于确保船上乘客的安全和舒适尤其重要。如果没有倾斜磁铁的帮助，船只可能会经历过度倾斜，导致潜在的倾覆或失去控制。此外，倾斜磁铁的概念不仅限于海洋应用。在机器人技术中，例如，倾斜磁铁可以用于机器手臂和无人机的平衡机制。通过调整磁力，工程师可以实现对这些设备运动的更大稳定性和控制。这表明倾斜磁铁在不同领域中的应用是多么的多样化。理解倾斜磁铁背后的原理需要掌握基本的磁性理论。磁铁产生的磁场可以对其他磁性材料施加力量。当倾斜磁铁被战略性地放置在系统中时，它可以影响该系统的整体平衡和方向。这一原理不仅限于物体；它在理论物理中也有意义，在那里粒子和场的行为可以通过磁相互作用进行分析。总之，倾斜磁铁是各种需要稳定性和控制的技术中的重要组成部分。它在海洋应用中的作用突显了在动态环境中保持平衡的重要性。随着技术的不断进步，倾斜磁铁的使用可能会扩大，为机械和电子系统的稳定性提供新的解决方案。理解倾斜磁铁的功能和应用对于任何对工程、物理或技术感兴趣的人来说都是必不可少的，因为它为创新和设计开辟了新的途径。