wing keelson

简明释义

舭内龙骨

英英释义

例句

1.Engineers are considering different materials for the wing keelson to improve performance.

工程师们正在考虑不同的材料来改善翼龙骨的性能。

2.The wing keelson helps to distribute weight evenly across the hull.

这条船的翼龙骨有助于将重量均匀分布到船体上。

3.The design of the sailboat includes a robust wing keelson, which enhances stability during rough weather.

这艘帆船的设计包括一个坚固的翼龙骨，在恶劣天气中增强了稳定性。

4.A well-designed wing keelson can significantly reduce drag while sailing.

设计良好的翼龙骨可以显著减少航行时的阻力。

5.During the inspection, the team found that the wing keelson was damaged and needed repairs.

在检查过程中，团队发现翼龙骨受损，需要修理。

作文

The design and construction of boats and ships have evolved significantly over the centuries, incorporating various innovative features that enhance performance and stability. One such feature is the wing keelson, a term that may not be widely recognized outside of nautical engineering but plays a crucial role in maritime architecture. Understanding the function and advantages of the wing keelson can provide insights into the complexities of vessel design and the importance of hydrodynamics in ensuring safe and efficient navigation.A wing keelson refers to a structural component found in the hull of a ship, specifically designed to improve the vessel's stability and reduce drag while sailing. It is an extension of the keel, which is the backbone of the ship, running along the bottom and providing structural integrity. The wing keelson features lateral 'wings' that extend from the main keel, creating a larger surface area that interacts with the water. This design helps to lower the center of gravity of the vessel, making it less prone to capsizing, especially in rough seas.One of the primary benefits of incorporating a wing keelson is its ability to enhance the overall performance of the ship. By optimizing the underwater profile, it allows for better lift and reduced resistance when moving through water. This means that vessels equipped with a wing keelson can achieve higher speeds with less power, ultimately leading to improved fuel efficiency. This is particularly advantageous for commercial shipping companies looking to minimize operational costs while maximizing cargo capacity.Moreover, the wing keelson contributes to better maneuverability. Ships with this design can navigate tighter turns and respond more effectively to changes in wind and water currents. This agility is essential for both recreational sailors and commercial operators who must frequently adjust their course to avoid obstacles or unfavorable conditions. In competitive sailing, the presence of a wing keelson can be the difference between winning and losing a race, as it provides a significant edge in speed and handling.However, the implementation of a wing keelson is not without its challenges. The design requires careful consideration of weight distribution and the overall balance of the vessel. Engineers must ensure that the added structure does not compromise the ship's integrity or lead to excessive weight that could hinder performance. Additionally, the construction of a wing keelson involves advanced materials and techniques, which can increase production costs.In conclusion, the wing keelson is a remarkable innovation in shipbuilding that exemplifies the intersection of engineering and maritime science. Its ability to enhance stability, performance, and maneuverability makes it a valuable feature in modern vessel design. As the maritime industry continues to advance, the importance of such innovations will only grow, shaping the future of how we navigate our oceans. Understanding terms like wing keelson not only enriches our knowledge of nautical engineering but also highlights the intricate relationship between design and functionality in the world of seafaring.

船舶和船只的设计与建造在几个世纪中经历了显著的发展，融入了各种创新特征，以提高性能和稳定性。其中一个特征是翼龙骨，这个术语可能在海洋工程之外不被广泛认知，但在海事建筑中发挥着至关重要的作用。理解翼龙骨的功能和优势可以深入了解船舶设计的复杂性，以及流体动力学在确保安全和高效导航中的重要性。翼龙骨指的是船体内的一种结构组件，专门设计用于提高船只的稳定性并减少航行时的阻力。它是龙骨的延伸，龙骨是船的脊梁，沿底部延伸并提供结构完整性。翼龙骨具有从主龙骨延伸出的侧翼，形成更大的水下表面，与水的相互作用。这种设计有助于降低船只的重心，使其在恶劣海况下不易倾覆。采用翼龙骨的主要好处之一是能够增强船只的整体性能。通过优化水下轮廓，它可以在水中移动时实现更好的升力和减少阻力。这意味着配备翼龙骨的船只可以以更少的动力达到更高的速度，从而最终提高燃油效率。这对希望在最大化货物容量的同时最小化运营成本的商业航运公司尤其有利。此外，翼龙骨还促进了更好的机动性。配备此设计的船只可以在较紧的转弯中航行，并能更有效地响应风和水流的变化。这种灵活性对于休闲航海者和必须频繁调整航向以避免障碍或不利条件的商业操作员至关重要。在竞争性航海中，配备翼龙骨的船只可能是赢得比赛和失去比赛之间的差异，因为它在速度和操控方面提供了显著的优势。然而，实施翼龙骨并非没有挑战。设计需要仔细考虑重量分布和船只的整体平衡。工程师必须确保新增结构不会妨碍船只的完整性或导致过重，从而影响性能。此外，构建翼龙骨涉及先进的材料和技术，这可能增加生产成本。总之，翼龙骨是船舶建造中的一项卓越创新，体现了工程与海洋科学的交汇。它增强了稳定性、性能和机动性的能力，使其成为现代船舶设计中的有价值特征。随着海事行业的不断发展，这类创新的重要性只会增加，塑造我们如何在海洋中航行的未来。理解像翼龙骨这样的术语不仅丰富了我们对海洋工程的知识，还突显了设计与功能在航海世界中的复杂关系。