seakeeping theory

简明释义

适航理论

英英释义

例句

1.The design of the new research vessel was heavily influenced by seakeeping theory (航行稳定性理论) to ensure it can operate in rough seas.

新研究船的设计受到航行稳定性理论的深刻影响，以确保它能够在恶劣海况下运行。

2.Engineers used seakeeping theory (航行稳定性理论) to predict how the ship would respond to wave action.

工程师们利用航行稳定性理论预测船只对波浪作用的反应。

3.By applying seakeeping theory (航行稳定性理论), the team improved the performance of the catamaran significantly.

通过应用航行稳定性理论，团队显著提高了双体船的性能。

4.The seakeeping theory (航行稳定性理论) helps to minimize the impact of waves on passenger comfort.

航行稳定性理论有助于减少波浪对乘客舒适度的影响。

5.Understanding seakeeping theory (航行稳定性理论) is essential for naval architects when designing vessels.

理解航行稳定性理论对于船舶设计师在设计船只时至关重要。

作文

The term seakeeping theory refers to the study of a vessel's ability to operate effectively in the marine environment, particularly regarding its performance in waves and rough seas. Understanding this theory is crucial for naval architects and engineers who design ships and boats intended for various maritime operations. The seakeeping theory encompasses various aspects, including stability, maneuverability, and comfort for passengers and crew. As vessels encounter waves, they experience forces that can affect their motion and safety, making it imperative to apply seakeeping theory in the design process.One of the primary components of seakeeping theory is the analysis of wave patterns and their impact on a vessel's behavior. Ships are subjected to different types of waves, which can vary in height, frequency, and direction. By studying these factors, engineers can predict how a ship will respond under various conditions. For instance, a vessel designed with a deep hull may perform better in rough seas compared to a flat-bottomed boat, which could struggle in similar conditions. Thus, the application of seakeeping theory helps in optimizing hull designs to enhance performance and safety.Moreover, seakeeping theory also addresses the comfort of those onboard. When a ship navigates through turbulent waters, passengers may experience discomfort due to excessive rolling or pitching. Engineers strive to minimize these motions by incorporating stabilizing systems and designing hull forms that reduce the impact of waves. This aspect of seakeeping theory is particularly important for passenger ferries and cruise ships, where the comfort of travelers is paramount.In addition to stability and comfort, seakeeping theory plays a vital role in the operational efficiency of vessels. A ship that can maintain a steady course and speed in adverse conditions is more likely to reach its destination on time and with reduced fuel consumption. This efficiency is not only beneficial for commercial shipping but also for military operations, where mission success can depend on a vessel's ability to navigate through challenging environments.Furthermore, advancements in technology have significantly enhanced the application of seakeeping theory. Computational fluid dynamics (CFD) and simulation tools allow engineers to model and analyze the behavior of ships in virtual environments before construction begins. This capability enables more accurate predictions of how a vessel will perform in real-world conditions, leading to better design choices and improved safety standards.In conclusion, the importance of seakeeping theory cannot be overstated. It is essential for ensuring that vessels are designed to withstand the challenges posed by the marine environment while providing safety and comfort to those onboard. As maritime activities continue to grow, the application of seakeeping theory will remain a critical area of research and development in the field of naval architecture. By understanding and applying the principles of seakeeping theory, we can create vessels that are not only efficient and safe but also capable of navigating the unpredictable nature of the seas with confidence.

“海洋保持理论”这个术语指的是研究船舶在海洋环境中有效操作的能力，特别是关于其在波浪和恶劣海况下的表现。理解这一理论对设计用于各种海事操作的船只的海军建筑师和工程师至关重要。“海洋保持理论”涵盖了多个方面，包括稳定性、机动性以及乘客和船员的舒适度。当船只遇到波浪时，会受到影响其运动和安全的力，因此在设计过程中应用“海洋保持理论”是必要的。“海洋保持理论”的一个主要组成部分是分析波浪模式及其对船舶行为的影响。船舶会受到不同类型波浪的影响，这些波浪的高度、频率和方向可能各不相同。通过研究这些因素，工程师可以预测船舶在各种条件下的反应。例如，设计有深船体的船舶可能在恶劣海况下表现得比平底船更好，而后者在类似条件下可能会挣扎。因此，应用“海洋保持理论”有助于优化船体设计，以增强性能和安全性。此外，“海洋保持理论”还涉及到船上人员的舒适度。当船舶在动荡水域航行时，乘客可能会因过度的滚动或俯仰而感到不适。工程师努力通过引入稳定系统和设计能够减少波浪影响的船体形式来最小化这些运动。“海洋保持理论”的这一方面对客运渡轮和邮轮特别重要，因为旅客的舒适度至关重要。除了稳定性和舒适性外，“海洋保持理论”在船舶的运营效率中也起着重要作用。一艘能够在不利条件下保持稳定航向和速度的船舶更有可能按时到达目的地，并减少燃料消耗。这种效率不仅对商业航运有利，而且对军事行动也至关重要，因为任务的成功可能依赖于船舶在挑战性环境中的航行能力。此外，科技的进步极大地增强了“海洋保持理论”的应用。计算流体动力学（CFD）和模拟工具使工程师能够在建造之前对船舶在虚拟环境中的行为进行建模和分析。这种能力使得对船舶在现实条件下表现的更准确预测成为可能，从而导致更好的设计选择和改善的安全标准。总之，“海洋保持理论”的重要性不可低估。它对于确保船舶设计能够承受海洋环境所带来的挑战，同时为船上人员提供安全和舒适至关重要。随着海事活动的不断增长，“海洋保持理论”的应用将继续成为海军建筑领域研究和发展的关键领域。通过理解和应用“海洋保持理论”的原则，我们可以创建不仅高效、安全，而且能够自信地穿越海洋不可预测特性的船舶。