athwartships magnet

简明释义

横向自差校正磁铁

英英释义

例句

1.The ship's stability was affected by the placement of the athwartships magnet.

船的稳定性受到横向磁铁放置位置的影响。

2.The design included an athwartships magnet for enhanced maneuverability in rough seas.

该设计包括一个横向磁铁，以增强在恶劣海况下的操控性。

3.During the test, the athwartships magnet demonstrated its effectiveness in stabilizing the craft.

在测试过程中，横向磁铁展示了其在稳定船只方面的有效性。

4.To improve the vessel's balance, we adjusted the athwartships magnet position.

为了改善船只的平衡，我们调整了横向磁铁的位置。

5.The engineer recommended using an athwartships magnet to counteract rolling motions.

工程师建议使用横向磁铁来抵消船体的滚动运动。

作文

In the realm of maritime engineering, the term athwartships magnet refers to a specific type of magnetic field orientation that is crucial for various navigational and operational purposes. Understanding this concept is essential for both engineers and sailors alike, as it can significantly impact the performance and safety of a vessel. The term 'athwartships' itself means 'across the width of the ship', which indicates that the magnetic field is aligned perpendicular to the ship's length. This orientation can affect how the ship interacts with external magnetic fields, such as those from the Earth or from other vessels. Magnetic fields play a vital role in navigation, particularly in the use of compasses and electronic navigation systems. A compass relies on the Earth's magnetic field to determine direction, and any interference from an athwartships magnet can lead to inaccuracies. For instance, if a ship has large metallic structures or equipment that generate their own magnetic fields, these can distort the local magnetic environment. When this happens, the compass may point in the wrong direction, leading to navigational errors that could have serious consequences at sea.Moreover, the understanding of athwartships magnet is not only limited to navigation but also extends to the design and construction of ships. Engineers must consider the placement of magnetic materials and equipment within the vessel to minimize any potential interference with navigational instruments. This consideration is particularly important during the design phase, where simulations and calculations are performed to predict how magnetic fields will behave in various situations. By ensuring that the magnetic influences are properly managed, engineers can enhance the reliability of navigational systems.In addition to navigation and engineering concerns, the concept of athwartships magnet also has implications for safety and operational efficiency. For example, if a ship is operating in close proximity to another vessel, the interaction between their respective magnetic fields can create unpredictable conditions. This is especially true in crowded waterways or during complex maneuvers. Understanding how to mitigate these effects can help prevent accidents and ensure smooth operations.Furthermore, modern technology has introduced new challenges and opportunities regarding athwartships magnet. With the advent of advanced sensors and automated navigation systems, the ability to monitor and adjust for magnetic interference has improved dramatically. These technologies allow for real-time adjustments to be made, enhancing the overall safety and efficiency of maritime operations. However, they also require a deeper understanding of magnetic principles and how they apply to contemporary shipping practices.In conclusion, the term athwartships magnet encapsulates a critical aspect of maritime navigation and engineering. Its implications reach far beyond simple definitions, affecting everything from the design of ships to the safety of navigation. As the maritime industry continues to evolve, the importance of understanding and managing magnetic fields will only grow, making it a key area of focus for future innovations and improvements in maritime technology.

在海洋工程领域，术语athwartships magnet指的是一种特定类型的磁场方向，这对于各种导航和操作目的至关重要。理解这一概念对于工程师和水手都是必不可少的，因为它可以显著影响船舶的性能和安全。术语“athwartships”本身的意思是“横跨船的宽度”，这表明磁场是与船的长度垂直对齐的。这种方向可能会影响船舶如何与外部磁场互动，例如来自地球或其他船只的磁场。磁场在导航中扮演着至关重要的角色，特别是在使用指南针和电子导航系统时。指南针依赖地球的磁场来确定方向，任何来自athwartships magnet的干扰都可能导致不准确。例如，如果一艘船有大型金属结构或设备产生自身的磁场，这些会扭曲局部的磁环境。当这种情况发生时，指南针可能会指向错误的方向，从而导致导航错误，这在海上可能会产生严重后果。此外，理解athwartships magnet不仅限于导航，还扩展到船舶的设计和建造。工程师必须考虑在船舶内部放置磁性材料和设备，以尽量减少对导航仪器的潜在干扰。这种考虑在设计阶段尤为重要，在此阶段会进行模拟和计算，以预测磁场在各种情况下的行为。通过确保妥善管理磁性影响，工程师可以增强导航系统的可靠性。除了导航和工程问题外，athwartships magnet的概念还对安全和操作效率产生了影响。例如，如果一艘船在靠近另一艘船的情况下操作，两者各自的磁场之间的相互作用可能会产生不可预测的条件。这在拥挤的水域或复杂的机动过程中尤其如此。理解如何减轻这些影响可以帮助防止事故并确保操作顺利进行。此外，现代技术带来了关于athwartships magnet的新挑战和机遇。随着先进传感器和自动导航系统的出现，监测和调整磁干扰的能力得到了显著改善。这些技术允许实时进行调整，从而提高海事操作的整体安全性和效率。然而，它们也需要对磁性原理及其在当代航运实践中的应用有更深刻的理解。总之，术语athwartships magnet概括了海洋导航和工程的一个关键方面。它的影响远远超出了简单定义，影响着从船舶设计到导航安全的方方面面。随着海洋行业的不断发展，理解和管理磁场的重要性只会增加，使其成为未来海洋技术创新和改进的关键关注领域。