hull construction

简明释义

船体构造

英英释义

例句

1.Our team is currently researching advanced techniques for hull construction to improve efficiency.

我们的团队目前正在研究先进的船体结构技术，以提高效率。

2.The choice of materials for hull construction can significantly affect the ship's performance.

用于船体结构的材料选择会显著影响船只的性能。

3.The hull construction of this yacht was designed to minimize drag and enhance speed.

这艘游艇的船体结构设计旨在最小化阻力并提高速度。

4.During the inspection, we found several issues with the hull construction that needed immediate attention.

在检查过程中，我们发现船体结构有几个问题需要立即处理。

5.The engineer explained the importance of hull construction in ensuring the vessel's stability at sea.

工程师解释了船体结构在确保船只在海上稳定性方面的重要性。

作文

The term hull construction refers to the design and assembly of the outer shell of a vessel, which plays a critical role in its overall performance and safety at sea. The hull is essentially the watertight body of the ship that provides buoyancy and stability, allowing it to float and navigate through water. Understanding the intricacies of hull construction is vital for engineers and architects involved in marine design, as it directly impacts the vessel's durability and efficiency.In the field of naval architecture, several materials can be used for hull construction, including steel, aluminum, fiberglass, and wood. Each material has its unique properties that affect the weight, strength, and maintenance of the vessel. For instance, steel is favored for larger ships due to its strength and resistance to harsh marine environments, while fiberglass is often chosen for smaller boats due to its lightweight and ease of repair.The shape of the hull is another crucial aspect of hull construction. Different designs, such as displacement hulls and planing hulls, are tailored for specific types of vessels and their intended use. Displacement hulls are designed to move through the water efficiently at lower speeds, making them ideal for cargo ships and yachts. In contrast, planing hulls are built for speed and are commonly used in racing boats and high-performance vessels. The choice of hull shape significantly influences the vessel's speed, fuel efficiency, and handling characteristics.Moreover, the process of hull construction involves various engineering techniques and technologies. Advanced computer-aided design (CAD) software is often utilized to create precise models and simulations of the hull before actual construction begins. This technology allows designers to optimize the hull's performance and identify potential issues early in the design phase. Additionally, modern manufacturing methods, such as modular construction, enable shipbuilders to assemble hulls more efficiently and with greater accuracy.Safety is another paramount concern in hull construction. The hull must be built to withstand the forces of nature, including waves, wind, and corrosion from saltwater. Engineers conduct rigorous testing and analysis to ensure that the hull can endure these stresses over its lifespan. Furthermore, regulations and standards set by maritime authorities dictate specific requirements for hull design and construction to guarantee the safety of vessels and their crews.In conclusion, hull construction is a multifaceted discipline that encompasses material selection, design principles, engineering techniques, and safety considerations. A well-constructed hull is essential for the performance and longevity of any vessel, whether it be a small recreational boat or a massive cargo ship. As technology continues to evolve, the field of hull construction will undoubtedly advance, leading to safer, more efficient, and environmentally friendly marine vessels. Understanding the complexities of this field is crucial for anyone involved in shipbuilding or marine engineering, as it lays the foundation for successful and innovative maritime endeavors.

“船体结构”这个术语指的是船只外壳的设计和组装，这在船只的整体性能和海上安全中起着至关重要的作用。船体基本上是船只的防水主体，提供浮力和稳定性，使其能够漂浮并在水中航行。理解“船体结构”的复杂性对参与海洋设计的工程师和建筑师至关重要，因为它直接影响到船只的耐用性和效率。在船舶建筑领域，可以使用多种材料进行“船体结构”的建造，包括钢、铝、玻璃纤维和木材。每种材料都有其独特的特性，影响船只的重量、强度和维护。例如，钢因其强度和抵御恶劣海洋环境的能力而被大型船只所青睐，而玻璃纤维则因其轻便和易于修理而常用于小型船只。船体的形状是“船体结构”中的另一个关键方面。不同的设计，如排水船体和滑行船体，针对特定类型的船只及其预期用途量身定制。排水船体旨在以较低的速度有效地穿过水面，适合货船和游艇。而滑行船体则为速度而建，多用于竞赛船和高性能船只。船体形状的选择显著影响船只的速度、燃油效率和操控特性。此外，“船体结构”的过程涉及各种工程技术和技术。先进的计算机辅助设计（CAD）软件通常用于在实际建造开始之前创建精确的模型和模拟。这项技术使设计师能够优化船体的性能，并在设计阶段早期识别潜在问题。此外，现代制造方法，如模块化建造，使造船商能够更高效、更准确地组装船体。安全性是“船体结构”中的另一个重要关注点。船体必须建造得能承受自然力量，包括波浪、风和盐水腐蚀。工程师进行严格的测试和分析，以确保船体在其生命周期内能够承受这些压力。此外，海事当局设定的法规和标准规定了船体设计和建造的具体要求，以保证船只及其船员的安全。总之，“船体结构”是一个多方面的学科，涵盖了材料选择、设计原则、工程技术和安全考虑。良好构建的船体对任何船只的性能和耐用性至关重要，无论是小型休闲船还是大型货船。随着技术的不断发展，“船体结构”领域无疑会不断进步，从而导致更安全、更高效和更环保的海洋船只。理解这一领域的复杂性对于任何参与造船或海洋工程的人来说都至关重要，因为这为成功和创新的海洋事业奠定了基础。