fluid hull

简明释义

流体壳

英英释义

例句

1.The racing yacht features a sleek fluid hull designed for high performance.

这艘赛车游艇具有流线型的流体船体，旨在实现高性能。

2.Engineers are experimenting with a new fluid hull technology that reduces drag in water.

工程师们正在尝试一种新的流体船体技术，以减少水中的阻力。

3.The design of the ship incorporates a fluid hull to enhance its speed and maneuverability.

这艘船的设计采用了流体船体，以提高其速度和机动性。

4.A fluid hull can significantly improve the energy efficiency of marine vessels.

一种流体船体可以显著提高海洋船舶的能源效率。

5.To achieve optimal performance, the engineers modified the fluid hull shape during testing.

为了达到最佳性能，工程师们在测试期间修改了流体船体的形状。

作文

The concept of a fluid hull is becoming increasingly important in the field of naval architecture and marine engineering. A fluid hull refers to a type of hull design that optimizes the interaction between the vessel and the water it moves through. This innovative approach focuses on reducing drag and enhancing performance by allowing the hull to adapt dynamically to changing water conditions. In essence, a fluid hull utilizes the principles of fluid dynamics to create a more efficient and effective vessel. One of the primary advantages of a fluid hull is its ability to minimize resistance. Traditional hull designs often struggle with turbulence and drag, which can significantly impede a ship's speed and fuel efficiency. By contrast, a fluid hull is engineered to promote smoother water flow around the vessel, resulting in reduced energy consumption and improved overall performance. This is especially critical in today’s world, where environmental concerns and fuel costs are at the forefront of maritime operations. Moreover, the fluid hull design can enhance stability and maneuverability. Ships equipped with this advanced hull technology tend to experience less rolling and pitching in rough waters, providing a more comfortable experience for passengers and crew alike. Additionally, improved maneuverability allows vessels to navigate tighter spaces and respond more effectively to changing sea conditions, which is essential for both commercial and recreational boating. The incorporation of fluid hull technology is not limited to large ships; it can also be applied to smaller vessels such as yachts and fishing boats. For instance, many high-performance racing yachts now feature fluid hull designs that enable them to cut through waves with greater ease, achieving higher speeds while maintaining stability. This has led to a new era of competitive sailing, where the efficiency of the hull can make all the difference in race outcomes. Furthermore, the development of fluid hull technology is closely linked to advancements in materials science. Lightweight, durable materials allow for the construction of hulls that can withstand harsh marine environments while still benefiting from the aerodynamic properties of the design. Innovations in computer-aided design (CAD) and simulation technologies have also played a significant role in refining fluid hull concepts, enabling engineers to test and optimize designs before they are built. In conclusion, the fluid hull represents a significant leap forward in maritime engineering. Its ability to reduce drag, enhance stability, and improve fuel efficiency makes it an attractive option for a wide range of vessels. As the maritime industry continues to evolve, embracing sustainable practices and innovative technologies will be crucial. The adoption of fluid hull designs is just one example of how the industry is adapting to meet these challenges head-on. By investing in research and development of fluid hull technology, we can look forward to a future of more efficient, environmentally friendly, and high-performing vessels on our oceans.

“流体船体”的概念在海洋建筑和海洋工程领域变得越来越重要。流体船体指的是一种船体设计，旨在优化船只与其移动的水之间的相互作用。这种创新的方法专注于减少阻力并增强性能，通过使船体能够动态适应变化的水域条件来实现。本质上，流体船体利用流体动力学原理，创造出更加高效和有效的船只。流体船体的主要优势之一是其能够最小化阻力。传统的船体设计常常面临着湍流和阻力的问题，这会显著妨碍船只的速度和燃油效率。相比之下，流体船体经过工程设计，以促进水流在船只周围的顺畅流动，从而减少能量消耗并提高整体性能。这在当今世界尤为重要，因为环境问题和燃料成本已成为海洋运营的核心关注点。此外，流体船体设计可以增强稳定性和机动性。配备这种先进船体技术的船只在恶劣水域中往往经历更少的摇摆和颠簸，为乘客和船员提供更舒适的体验。此外，改善的机动性使船只能够在狭窄的空间中导航，并更有效地应对变化的海洋条件，这对于商业和休闲航行都是至关重要的。流体船体技术的应用不仅限于大型船只；它也可以应用于小型船只，如游艇和渔船。例如，许多高性能赛车游艇现在采用流体船体设计，使它们能够更轻松地切割波浪，以更高的速度保持稳定。这导致了一个新的竞争帆船时代，船体的效率可能对比赛结果产生重大影响。此外，流体船体技术的发展与材料科学的进步密切相关。轻质、耐用的材料允许建造能够承受恶劣海洋环境的船体，同时仍然受益于设计的空气动力特性。计算机辅助设计（CAD）和仿真技术的创新也在优化流体船体概念方面发挥了重要作用，使工程师能够在建造之前测试和优化设计。总之，流体船体代表了海洋工程的一次重大飞跃。其减少阻力、增强稳定性和改善燃油效率的能力使其成为各种船只的有吸引力的选择。随着海洋行业的不断发展，拥抱可持续实践和创新技术将至关重要。流体船体设计的采用只是行业如何积极应对这些挑战的一个例子。通过投资于流体船体技术的研发，我们可以期待未来在我们的海洋上出现更高效、环保和高性能的船只。