design for seakeeping

简明释义

耐波性设计

英英释义

例句

1.To improve passenger comfort, we must design for seakeeping in our new ferry line.

为了提高乘客的舒适度，我们必须在新渡轮系列中为航行稳定性设计。

2.The team was tasked with designing for seakeeping to minimize motion sickness among crew members.

团队的任务是为航行稳定性设计，以减少船员的晕船症状。

3.Our latest research focuses on how to effectively design for seakeeping in high-speed crafts.

我们最新的研究集中在如何有效地为航行稳定性设计高速船舶。

4.The naval architect emphasized the need to design for seakeeping to ensure the vessel's stability in rough waters.

海军建筑师强调需要为航行稳定性设计，以确保船只在恶劣水域的稳定性。

5.Incorporating advanced materials allows us to better design for seakeeping in our vessels.

采用先进材料使我们能够更好地为航行稳定性设计我们的船只。

作文

The concept of design for seakeeping is crucial in the field of naval architecture and marine engineering. It refers to the process of designing vessels that can maintain stability and performance in various sea conditions. This aspect of design is particularly important for ships that operate in rough waters, as it directly impacts their safety, efficiency, and overall operational capability.When engineers and designers approach design for seakeeping, they must consider several factors including the vessel's hull shape, weight distribution, and the materials used in construction. A well-designed hull can significantly reduce the effects of waves and turbulence, allowing the ship to cut through water more effectively. For instance, a streamlined hull shape can minimize drag and enhance speed, while also improving stability.Another critical element in design for seakeeping is the assessment of wave patterns and environmental conditions that the vessel will encounter. This involves extensive modeling and simulation to predict how the ship will behave in various scenarios. By analyzing these factors, designers can make informed decisions about the ship’s specifications, such as its length, beam, and draft, which all play a role in its ability to remain stable and maneuverable under challenging conditions.In addition to physical design aspects, design for seakeeping also encompasses the integration of technology. Modern ships often utilize advanced navigation systems and stabilization technologies to enhance their performance in rough seas. These systems can include gyroscopic stabilizers, active fins, and other mechanisms that help counteract the forces of waves and wind, ensuring a smoother ride for passengers and cargo alike.Moreover, the importance of design for seakeeping extends beyond just the technical specifications of the vessel. It also has significant implications for safety and operational costs. Ships that are poorly designed for seakeeping may experience increased rolling and pitching, leading to discomfort for crew and passengers, potential cargo damage, and even accidents at sea. Therefore, investing in proper design for seakeeping not only enhances performance but also reduces long-term operational risks and expenses.Furthermore, regulations and standards set by maritime authorities often require specific seakeeping criteria to be met for different types of vessels. Compliance with these regulations necessitates a thorough understanding of design for seakeeping, ensuring that ships are fit for their intended purpose and capable of operating safely in their designated environments.In conclusion, design for seakeeping is a multifaceted discipline that combines engineering principles, environmental analysis, and technological innovation. As the maritime industry continues to evolve, the need for vessels that can safely navigate unpredictable sea conditions becomes increasingly vital. By prioritizing design for seakeeping, we can enhance the resilience and reliability of our maritime fleet, ultimately contributing to safer and more efficient sea travel and transport.

“设计以适应航行性”的概念在海军建筑和海洋工程领域至关重要。它指的是设计能够在各种海况下保持稳定性和性能的船只的过程。这一设计方面对于在恶劣水域操作的船舶尤为重要，因为它直接影响到船舶的安全性、效率和整体操作能力。当工程师和设计师进行“设计以适应航行性”时，他们必须考虑多个因素，包括船体形状、重量分布以及使用的材料。一个设计良好的船体可以显著减少波浪和湍流的影响，使船只能够更有效地切割水面。例如，流线型的船体形状可以最小化阻力并增强速度，同时改善稳定性。“设计以适应航行性”的另一个关键要素是评估船舶将遇到的波浪模式和环境条件。这涉及广泛的建模和模拟，以预测船舶在各种情况下的表现。通过分析这些因素，设计师可以就船舶的规格做出明智的决定，例如其长度、宽度和吃水，这些都在船舶在挑战性条件下的稳定性和机动性中发挥作用。除了物理设计方面，“设计以适应航行性”还包括技术的整合。现代船舶通常利用先进的导航系统和稳定技术来增强其在恶劣海域的性能。这些系统可以包括陀螺稳定器、主动鳍和其他帮助抵消波浪和风力作用的机制，从而确保乘客和货物的更平稳的航行。此外，“设计以适应航行性”的重要性不仅限于船舶的技术规格。它对安全和运营成本也有重大的影响。设计不当以适应航行性的船舶可能会经历更大的横摇和纵摇，导致船员和乘客的不适、潜在的货物损坏，甚至海上事故。因此，投资于适当的“设计以适应航行性”不仅提升了性能，还减少了长期的运营风险和费用。此外，海事当局设定的法规和标准通常要求不同类型船舶满足特定的航行性标准。遵守这些法规需要对“设计以适应航行性”有透彻的理解，确保船舶适合其预定用途，并能够安全地在指定环境中操作。总之，“设计以适应航行性”是一个多方面的学科，结合了工程原理、环境分析和技术创新。随着海事行业的不断发展，对能够安全航行于不可预测海况的船舶的需求变得愈发重要。通过优先考虑“设计以适应航行性”，我们可以增强海事舰队的韧性和可靠性，最终促进更安全、更高效的海上旅行和运输。