athwartships magnetism

简明释义

横向磁场

英英释义

例句

1.During the testing phase, we observed significant athwartships magnetism impacting navigation accuracy.

在测试阶段，我们观察到显著的横向磁力影响了导航精度。

2.Captains need to be aware of athwartships magnetism when planning their routes in magnetic waters.

船长在规划航线时需要注意横向磁力，尤其是在磁性水域中。

3.The phenomenon of athwartships magnetism can lead to challenges in maneuverability for large vessels.

对于大型船只来说，横向磁力现象可能会导致操控上的挑战。

4.Engineers must account for athwartships magnetism when designing the hull to ensure balance.

工程师在设计船体时必须考虑横向磁力以确保平衡。

5.The ship's stability was affected by the athwartships magnetism, which caused unexpected tilting.

船的稳定性受到了横向磁力的影响，导致意外倾斜。

作文

In the realm of physics and engineering, understanding the principles of magnetism is crucial, especially when it comes to marine applications. One term that often arises in discussions about ship design and stability is athwartships magnetism. This concept refers to the magnetic forces that act across the width of a vessel, influencing its behavior and stability in water. The importance of athwartships magnetism cannot be overstated, as it plays a significant role in ensuring that ships remain balanced and maneuverable while navigating through various conditions.When a ship is constructed, it is essential to consider the materials used in its hull and structure. Different metals have varying magnetic properties, which can contribute to the overall athwartships magnetism of the vessel. For instance, steel, commonly used in shipbuilding, has a high magnetic permeability, meaning it can easily become magnetized. This magnetization can lead to unwanted effects, such as attracting ferrous objects or causing navigation errors due to interference with compasses and other sensitive instruments.Moreover, the positioning of equipment and cargo within a ship also affects athwartships magnetism. Uneven distribution of weight can create an imbalance, leading to excessive listing or rolling. Engineers must carefully plan the layout of the ship to ensure that any magnetic fields generated do not interfere with its stability. This is particularly important for naval vessels and submarines, where stealth and precision are paramount.The impact of athwartships magnetism extends beyond the physical characteristics of the vessel. It also influences the crew's ability to operate the ship effectively. A well-balanced ship allows for smoother handling and reduces the strain on the crew, who must manage the vessel's movements during challenging conditions. Conversely, if athwartships magnetism is not adequately addressed, it can lead to increased fatigue among the crew and a higher likelihood of accidents.Furthermore, the interaction between athwartships magnetism and environmental factors such as ocean currents and wind can complicate navigation. Ships that are magnetically imbalanced may struggle to maintain their course, requiring the crew to make constant adjustments. This can be particularly dangerous in congested waterways or during adverse weather conditions, where precision is vital for safety.To mitigate the effects of athwartships magnetism, modern shipbuilders employ various techniques. One approach is to use non-magnetic materials in specific areas of the ship to counterbalance the magnetic forces generated by ferrous components. Additionally, advanced modeling and simulation software allow engineers to predict how athwartships magnetism will affect a ship's performance, enabling them to make informed design choices.In conclusion, athwartships magnetism is a critical factor in ship design and operation. By understanding its implications, engineers and naval architects can create vessels that are not only efficient but also safe and reliable. As technology continues to advance, the ability to measure and control athwartships magnetism will undoubtedly improve, leading to further innovations in maritime engineering and navigation. The importance of this concept highlights the intricate relationship between physics and practical applications in the maritime industry, showcasing the need for continuous research and development in this field.

在物理和工程领域，理解磁学原理至关重要，尤其是在海洋应用中。一个常常出现在船舶设计和稳定性讨论中的术语是athwartships magnetism。这个概念指的是作用于船只宽度上的磁力，影响其在水中的行为和稳定性。athwartships magnetism的重要性不容小觑，因为它在确保船舶在各种条件下保持平衡和可操控性方面发挥着重要作用。当一艘船被建造时，必须考虑所用材料的特性。不同金属具有不同的磁性，这可能会影响船只的整体athwartships magnetism。例如，钢铁是船舶建造中常用的材料，它具有较高的磁导率，意味着它很容易被磁化。这种磁化可能导致不必要的影响，例如吸引铁磁物体或因干扰指南针和其他敏感仪器而导致导航错误。此外，船内设备和货物的放置也会影响athwartships magnetism。重量的不均匀分布可能会造成不平衡，导致过度倾斜或滚动。工程师必须仔细规划船舶的布局，以确保产生的任何磁场不会干扰其稳定性。这对于海军舰艇和潜艇尤为重要，因为隐身和精准至关重要。athwartships magnetism的影响不仅限于船舶的物理特性。它还影响船员有效操作船舶的能力。一艘平衡良好的船可以实现更平稳的操控，减少船员的负担，而他们必须在恶劣条件下管理船舶的运动。相反，如果athwartships magnetism没有得到妥善处理，可能会导致船员疲劳加重，事故发生的可能性增加。此外，athwartships magnetism与海洋潮流和风等环境因素之间的相互作用可能会使导航变得复杂。磁性失衡的船只可能难以维持航向，要求船员进行不断的调整。这在拥挤的水道或恶劣天气条件下尤其危险，因为安全需要精确。为了减轻athwartships magnetism的影响，现代船舶制造商采用各种技术。一种方法是在船舶的特定区域使用非磁性材料，以抵消由铁磁部件产生的磁力。此外，先进的建模和模拟软件使工程师能够预测athwartships magnetism将如何影响船舶的性能，从而使他们能够做出明智的设计选择。总之，athwartships magnetism是船舶设计和操作中的关键因素。通过理解其影响，工程师和海军建筑师可以创造出不仅高效而且安全可靠的船舶。随着技术的不断进步，测量和控制athwartships magnetism的能力无疑会提高，从而推动海事工程和导航领域的进一步创新。这个概念的重要性突显了物理学与海洋工业实际应用之间的复杂关系，展示了在这一领域持续研究和发展的必要性。