principle of naval architecture

简明释义

船舶原理

英英释义

例句

1.Students in the maritime engineering program learn the principle of naval architecture to create efficient ship designs.

海事工程专业的学生学习海洋建筑原理以创造高效的船舶设计。

2.The design of the new research vessel was guided by the principle of naval architecture.

新研究船的设计遵循了海洋建筑原理。

3.In our project, we applied the principle of naval architecture to enhance the hull design.

在我们的项目中，我们应用了海洋建筑原理来增强船体设计。

4.The stability of the yacht was evaluated using the principle of naval architecture.

游艇的稳定性是通过使用海洋建筑原理进行评估的。

5.Understanding the principle of naval architecture is essential for any aspiring naval architect.

理解海洋建筑原理对于任何有志于成为海洋建筑师的人来说都是必不可少的。

作文

The field of naval architecture plays a crucial role in the design and construction of ships and marine structures. At the heart of this discipline lies the principle of naval architecture, which encompasses a set of fundamental concepts and methodologies that guide engineers in creating vessels that are not only functional but also safe and efficient. Understanding these principles is essential for anyone aspiring to enter this fascinating field.The principle of naval architecture can be broken down into several key components, including buoyancy, stability, and resistance. Buoyancy refers to the ability of a vessel to float on water, which is determined by the displacement of water equal to the weight of the ship. This principle is governed by Archimedes' principle, which states that an object submerged in a fluid experiences an upward force equal to the weight of the fluid displaced. Naval architects must carefully calculate the buoyancy of their designs to ensure that the vessel remains afloat under various conditions.Stability is another critical aspect covered by the principle of naval architecture. It refers to the vessel's ability to return to an upright position after being tilted by external forces, such as waves or wind. A stable ship is less likely to capsize, making stability calculations vital during the design phase. Naval architects use various methods, including metacentric height calculations, to assess and enhance a vessel's stability.Resistance, on the other hand, relates to the forces that oppose a vessel's movement through water. These forces include frictional resistance, wave-making resistance, and air resistance. The principle of naval architecture requires designers to minimize these resistive forces to improve fuel efficiency and overall performance. By optimizing hull shapes and using advanced materials, naval architects can create vessels that glide smoothly through water, reducing energy consumption.Moreover, the principle of naval architecture extends beyond just the physical aspects of ship design. It also incorporates environmental considerations, such as the impact of marine operations on ecosystems and compliance with regulations. As the world becomes more aware of climate change and environmental protection, naval architects are tasked with designing greener ships that reduce emissions and conserve resources.In recent years, technological advancements have significantly influenced the principle of naval architecture. Computer-aided design (CAD) software and simulation tools allow architects to model and test their designs virtually before constructing them. This not only saves time and resources but also leads to safer and more efficient vessels. Additionally, innovations in materials science have introduced lighter and stronger materials, enabling the construction of faster and more durable ships.In conclusion, the principle of naval architecture is a multifaceted framework that guides the design and construction of marine vessels. By understanding essential concepts such as buoyancy, stability, and resistance, future naval architects can contribute to the advancement of the maritime industry. As we face growing environmental challenges, the importance of sustainable practices within this field cannot be overstated. Embracing technology and innovation will undoubtedly shape the future of naval architecture, leading to safer, more efficient, and environmentally friendly vessels that can navigate the oceans for generations to come.

海洋建筑学领域在船舶和海洋结构的设计与建造中发挥着至关重要的作用。在这一学科的核心是海洋建筑学原理，它包含了一套基本概念和方法论，指导工程师创建不仅功能齐全而且安全高效的船只。理解这些原理对任何希望进入这一迷人领域的人来说都是必不可少的。海洋建筑学原理可以分为几个关键组成部分，包括浮力、稳定性和阻力。浮力是指船舶在水面上漂浮的能力，这由等于船只重量的水的排量决定。这个原理受阿基米德原理的支配，后者指出，沉浸在流体中的物体会受到一个向上的力，这个力等于排开的流体的重量。海洋建筑师必须仔细计算其设计的浮力，以确保船只在各种条件下保持漂浮。稳定性是海洋建筑学原理涵盖的另一个关键方面。它指的是船舶在受到外力（如波浪或风）倾斜后返回直立位置的能力。一艘稳定的船较不容易翻覆，因此在设计阶段进行稳定性计算至关重要。海洋建筑师使用包括重心高度计算在内的各种方法来评估和增强船舶的稳定性。另一方面，阻力与反对船舶在水中运动的力量有关。这些力量包括摩擦阻力、波浪形成阻力和空气阻力。海洋建筑学原理要求设计师最小化这些阻力，以提高燃油效率和整体性能。通过优化船体形状和使用先进材料，海洋建筑师可以创建在水中顺畅滑行的船只，从而减少能耗。此外，海洋建筑学原理不仅限于船舶设计的物理方面。它还包括环境因素，例如海洋作业对生态系统的影响和合规性。随着世界对气候变化和环境保护的关注增加，海洋建筑师被赋予了设计更环保船舶的任务，这些船舶能够减少排放并节约资源。近年来，技术进步显著影响了海洋建筑学原理。计算机辅助设计（CAD）软件和仿真工具使建筑师能够在构建之前虚拟模型和测试其设计。这不仅节省了时间和资源，还导致了更安全、更高效的船只。此外，材料科学的创新引入了更轻、更强的材料，使得建造更快、更耐用的船舶成为可能。总之，海洋建筑学原理是一个多面的框架，指导着海洋船舶的设计与建造。通过理解浮力、稳定性和阻力等基本概念，未来的海洋建筑师可以为海事行业的发展做出贡献。面对日益严峻的环境挑战，这一领域内可持续实践的重要性不容小觑。拥抱技术和创新无疑将塑造海洋建筑学的未来，创造出更安全、更高效、环保的船舶，使其能够在未来的几代人中航行于海洋。