rudder thicknessratio

简明释义

舵厚度比

英英释义

例句

1.The design of the ship's rudder is critical, and the rudder thickness ratio 舵的厚度比 must be optimized for performance.

船舶舵的设计至关重要，rudder thickness ratio 舵的厚度比 必须为性能优化。

2.Engineers often calculate the rudder thickness ratio 舵的厚度比 to ensure stability during navigation.

工程师通常计算 rudder thickness ratio 舵的厚度比 以确保航行中的稳定性。

3.The rudder thickness ratio 舵的厚度比 should be considered when designing vessels intended for high-speed travel.

在设计用于高速旅行的船只时，应考虑 rudder thickness ratio 舵的厚度比。

4.A higher rudder thickness ratio 舵的厚度比 can improve the durability of the rudder in rough seas.

较高的 rudder thickness ratio 舵的厚度比 可以提高舵在恶劣海况下的耐用性。

5.During the testing phase, we observed how the rudder thickness ratio 舵的厚度比 affects maneuverability.

在测试阶段，我们观察到 rudder thickness ratio 舵的厚度比 如何影响操控性。

作文

The importance of understanding the concept of rudder thickness ratio cannot be overstated, especially in the field of naval architecture and marine engineering. The rudder thickness ratio is defined as the ratio of the thickness of the rudder blade to its chord length. This measurement plays a crucial role in determining the performance and efficiency of a vessel's steering system. A well-designed rudder can significantly enhance a ship's maneuverability, stability, and overall performance at sea.In the design phase of a ship, engineers must carefully consider the rudder thickness ratio. A thicker rudder may provide better strength and durability, but it could also lead to increased drag, which can negatively impact fuel efficiency. Conversely, a thinner rudder might reduce drag but could compromise the structural integrity of the rudder under high-stress conditions. Thus, finding the optimal rudder thickness ratio is essential for balancing these competing factors.Moreover, the rudder thickness ratio affects how a vessel responds to various environmental conditions, such as waves and currents. For instance, a rudder with an inappropriate thickness may struggle to maintain control during rough seas. Engineers often use computational fluid dynamics (CFD) simulations to analyze different designs and their corresponding rudder thickness ratios to predict performance outcomes before physical prototypes are built.In addition to performance considerations, the rudder thickness ratio also has implications for maintenance and repair. Thicker rudders might be more resistant to wear and tear, extending their lifespan and reducing maintenance costs. However, if a rudder is too thick, it may require more extensive repairs or replacements if damaged. Therefore, shipbuilders must weigh the long-term benefits of a certain rudder thickness ratio against immediate performance needs.Another critical aspect of the rudder thickness ratio is its influence on the overall design of the vessel. The rudder's dimensions must harmonize with the hull shape and size to ensure optimal hydrodynamic performance. A poorly designed rudder can lead to increased resistance and reduced efficiency, making it vital for designers to integrate the rudder thickness ratio into their calculations early in the design process.Furthermore, regulations and standards set by maritime authorities often dictate specific requirements for rudder design, including the rudder thickness ratio. Compliance with these regulations ensures that vessels are safe and seaworthy, ultimately protecting both the crew and the environment. As such, understanding the rudder thickness ratio is not only a technical necessity but also a regulatory requirement.In conclusion, the rudder thickness ratio is a fundamental parameter in the design and performance of marine vessels. It influences maneuverability, fuel efficiency, structural integrity, maintenance, and compliance with safety regulations. As technology advances and the maritime industry evolves, continued research and innovation surrounding the rudder thickness ratio will be essential in developing more efficient and sustainable shipping solutions. Therefore, professionals in the field must prioritize a comprehensive understanding of this concept to contribute effectively to the future of naval architecture and marine engineering.

理解和掌握“舵厚度比”这一概念的重要性不言而喻，特别是在海洋建筑和海洋工程领域。“舵厚度比”被定义为舵叶厚度与其弦长的比率。这个参数在决定船舶操纵系统的性能和效率方面发挥着至关重要的作用。设计良好的舵可以显著提高船舶在海上的机动性、稳定性和整体性能。在船舶设计阶段，工程师必须仔细考虑“舵厚度比”。较厚的舵可能提供更好的强度和耐用性，但也可能导致阻力增加，从而对燃油效率产生负面影响。相反，较薄的舵可能减少阻力，但在高应力条件下可能会损害舵的结构完整性。因此，找到最佳的“舵厚度比”对于平衡这些竞争因素至关重要。此外，“舵厚度比”还影响船舶对各种环境条件（如波浪和水流）的响应。例如，厚度不合适的舵在恶劣海况下可能难以保持控制。工程师们通常使用计算流体动力学（CFD）模拟来分析不同设计及其对应的“舵厚度比”，以预测性能结果，然后再制造物理原型。除了性能考虑外，“舵厚度比”还对维护和修理有影响。较厚的舵可能对磨损和撕裂更具抵抗力，从而延长其使用寿命并减少维护成本。然而，如果舵过厚，损坏时可能需要更大规模的修理或更换。因此，造船商必须权衡某一“舵厚度比”的长期益处与即时性能需求。“舵厚度比”的另一个关键方面是其对船舶整体设计的影响。舵的尺寸必须与船体形状和大小协调，以确保最佳的水动力性能。设计不当的舵可能导致阻力增加和效率降低，因此设计人员必须在设计过程的早期将“舵厚度比”纳入计算。此外，海事当局设定的法规和标准通常规定了舵设计的特定要求，包括“舵厚度比”。遵守这些法规确保船舶安全适航，最终保护船员和环境。因此，理解“舵厚度比”不仅是技术上的必要性，也是法规上的要求。总之，“舵厚度比”是海洋船舶设计和性能的基本参数。它影响机动性、燃油效率、结构完整性、维护和遵守安全法规。随着技术的进步和海事行业的发展，围绕“舵厚度比”的持续研究和创新将在开发更高效和可持续的航运解决方案中发挥至关重要的作用。因此，该领域的专业人士必须优先全面理解这一概念，以有效地为海洋建筑和海洋工程的未来做出贡献。