surface unsinkability
简明释义
水上抗沉性
英英释义
例句
1.In maritime training, students learn about the importance of surface unsinkability in ship design.
在海事培训中,学生学习船舶设计中表面不沉性的重要性。
2.The safety features of this vessel include advanced surface unsinkability technology.
该船的安全特性包括先进的表面不沉性技术。
3.The design of the new yacht emphasizes surface unsinkability, ensuring that it remains afloat even in rough waters.
新游艇的设计强调了表面不沉性,确保即使在恶劣水域中也能保持漂浮。
4.The innovative materials used in the construction provide excellent surface unsinkability for the raft.
用于建造的创新材料为筏子提供了出色的表面不沉性。
5.Engineers tested the boat's surface unsinkability by simulating various emergency scenarios.
工程师通过模拟各种紧急情况来测试船只的表面不沉性。
作文
The concept of surface unsinkability refers to the ability of a vessel or object to remain afloat on the surface of water, even under adverse conditions. This term is particularly relevant in maritime engineering and design, where ensuring the safety and stability of ships is paramount. To illustrate this concept, we can look at various examples from history and modern technology that highlight the importance of surface unsinkability.One of the most famous historical examples of surface unsinkability is the Titanic. Despite being touted as "unsinkable," the Titanic sank on its maiden voyage after hitting an iceberg. This tragedy underscored the importance of robust design and the need for realistic assessments of a ship's buoyancy and stability. The Titanic was designed with multiple watertight compartments, which were intended to provide surface unsinkability. However, the impact of the iceberg compromised too many of these compartments, leading to the ship's eventual sinking.In contrast, modern ships are designed with advanced technologies that enhance their surface unsinkability. Engineers utilize computer simulations and sophisticated materials to create vessels that can withstand harsh conditions at sea. For instance, the incorporation of double-hulled designs has become a standard practice in the construction of oil tankers. This design feature not only improves the vessel's surface unsinkability but also reduces the risk of oil spills, contributing to environmental protection.Moreover, the concept of surface unsinkability extends beyond traditional ships. In recent years, the development of personal watercraft and recreational boats has also focused on enhancing buoyancy. Manufacturers employ lightweight materials and innovative designs to ensure that these vessels remain afloat, even if they take on water. This focus on surface unsinkability is crucial for the safety of individuals who engage in water sports or leisure activities.Additionally, the principles of surface unsinkability are applicable to other industries, such as aerospace and automotive engineering. For example, aircraft are designed to remain airborne under various conditions, and car manufacturers prioritize stability and traction to prevent vehicles from flipping over during sharp turns. While these fields may not directly relate to water, the underlying principle of maintaining stability and safety can be seen as an extension of the idea of surface unsinkability.In conclusion, the notion of surface unsinkability plays a critical role in various domains, particularly in maritime engineering. It serves as a reminder of the importance of safety, design integrity, and technological advancement. By understanding and applying the principles associated with surface unsinkability, engineers and designers can create safer and more reliable vessels and vehicles, ultimately protecting lives and the environment. As we continue to innovate and improve our designs, the lessons learned from past failures will guide us toward achieving greater levels of surface unsinkability in the future.
“表面不沉性”这一概念指的是一个船只或物体在水面上保持漂浮的能力,即使在不利条件下也是如此。这个术语在海洋工程和设计中尤为重要,因为确保船只的安全性和稳定性至关重要。为了说明这个概念,我们可以看看历史和现代技术中的各种例子,这些例子突显了“表面不沉性”的重要性。最著名的“表面不沉性”历史案例是泰坦尼克号。尽管被称为“永不沉没”,但泰坦尼克号在首次航行中撞上冰山后沉没。这场悲剧强调了坚固设计的重要性,以及对船只浮力和稳定性进行现实评估的必要性。泰坦尼克号的设计采用了多个防水舱,旨在提供“表面不沉性”。然而,冰山的撞击损坏了太多的这些舱室,导致船只最终沉没。相比之下,现代船只的设计采用了先进的技术,以增强它们的“表面不沉性”。工程师利用计算机模拟和复杂材料来创建能够承受恶劣海况的船只。例如,双壳体设计的引入已成为油轮建造的标准实践。这一设计特征不仅提高了船只的“表面不沉性”,还降低了石油泄漏的风险,有助于环境保护。此外,“表面不沉性”的概念超越了传统船只。近年来,个人水上交通工具和休闲船只的发展也专注于增强浮力。制造商采用轻质材料和创新设计,确保这些船只即使进水也能保持漂浮。这种对“表面不沉性”的关注对于参与水上运动或休闲活动的人们的安全至关重要。此外,“表面不沉性”的原则也适用于其他行业,如航空航天和汽车工程。例如,飞机设计为在各种条件下保持飞行,汽车制造商优先考虑稳定性和牵引力,以防止车辆在急转弯时翻覆。虽然这些领域可能与水没有直接关系,但保持稳定性和安全性的基本原则可以被视为“表面不沉性”概念的延伸。总之,“表面不沉性”的概念在各个领域中发挥着关键作用,尤其是在海洋工程中。它提醒我们安全、设计完整性和技术进步的重要性。通过理解和应用与“表面不沉性”相关的原则,工程师和设计师可以创造出更安全、更可靠的船只和车辆,最终保护生命和环境。随着我们继续创新和改进设计,从过去失败中吸取的教训将指导我们在未来实现更高水平的“表面不沉性”。
