maximum waterline beam

简明释义

水线面最大宽度

英英释义

例句

1.The maximum waterline beam (最大水线宽度) affects the boat's cargo capacity significantly.

船只的最大水线宽度会显著影响其货物容量。

2.When calculating the hull's performance, the maximum waterline beam (最大水线宽度) is a critical factor.

在计算船体性能时，最大水线宽度是一个关键因素。

3.The boat's design ensures that the maximum waterline beam (最大水线宽度) provides stability during rough seas.

这艘船的设计确保其最大水线宽度在恶劣海况下提供稳定性。

4.For optimal performance, the yacht must not exceed the maximum waterline beam (最大水线宽度) recommended by the manufacturer.

为了获得最佳性能，游艇不得超过制造商推荐的最大水线宽度。

5.The architect specified a maximum waterline beam (最大水线宽度) to enhance the vessel's speed.

建筑师指定了一个最大水线宽度以提高船只的速度。

作文

Understanding the concept of maximum waterline beam is essential for anyone involved in naval architecture or marine engineering. The term refers to the widest point of a ship's hull that is in contact with the water when the vessel is at its designed load. This measurement plays a crucial role in determining the stability, speed, and overall performance of a ship. In this essay, we will explore the significance of maximum waterline beam and how it impacts various aspects of ship design.The maximum waterline beam is a critical dimension in ship design because it directly influences the ship's stability. A wider beam generally provides greater lateral stability, which helps prevent capsizing in rough seas. This is particularly important for vessels that operate in challenging environments, such as cargo ships and fishing boats. When the beam is optimized, it allows the ship to handle waves and wind more effectively, ensuring the safety of both the crew and the cargo.Moreover, the maximum waterline beam affects the hydrodynamic characteristics of the ship. A wider beam can lead to increased resistance when moving through water, which may impact fuel efficiency. Naval architects must carefully balance the width of the beam with other design elements to achieve an optimal performance. For instance, while a wider beam can enhance stability, it may also require more power to maintain speed, thus increasing operational costs.Another aspect to consider is the relationship between maximum waterline beam and cargo capacity. A ship with a larger beam can typically carry more cargo due to the increased volume available within the hull. This is particularly advantageous for commercial vessels, where maximizing cargo space is essential for profitability. However, this must be weighed against the potential drawbacks, such as reduced speed or increased drag.In addition to stability and cargo capacity, the maximum waterline beam also influences the aesthetic appeal of a vessel. Many shipowners and designers aim for a sleek and elegant profile, which can be affected by the beam's dimensions. A well-proportioned beam contributes to the overall beauty of the ship, making it more attractive to potential buyers or charterers.Furthermore, regulations and standards set by maritime authorities often dictate specific requirements for maximum waterline beam. These guidelines are in place to ensure the safety and seaworthiness of vessels. Designers must adhere to these regulations while also considering the unique operational needs of the ship. This balancing act requires a deep understanding of both engineering principles and regulatory frameworks.In conclusion, the concept of maximum waterline beam is multifaceted, impacting stability, hydrodynamics, cargo capacity, aesthetics, and regulatory compliance. For those involved in ship design and construction, mastering this term is vital for creating vessels that meet performance expectations and safety standards. As the maritime industry continues to evolve, the importance of understanding the maximum waterline beam will remain a cornerstone of effective ship design and operation. By appreciating the complexities associated with this measurement, naval architects can contribute to the development of safer, more efficient, and aesthetically pleasing vessels.

理解最大水线宽度的概念对于任何参与船舶设计或海洋工程的人来说都是至关重要的。这个术语指的是船体在设计载荷下与水接触时的最宽点。这个测量在确定船舶的稳定性、速度和整体性能方面起着关键作用。在这篇文章中，我们将探讨最大水线宽度的重要性以及它如何影响船舶设计的各个方面。最大水线宽度是船舶设计中的一个关键维度，因为它直接影响船舶的稳定性。更宽的船宽通常提供更大的横向稳定性，有助于防止在恶劣海况下翻覆。这对于在挑战性环境中运营的船只，尤其是货船和渔船来说尤为重要。当船宽经过优化时，它能够更有效地应对波浪和风，确保船员和货物的安全。此外，最大水线宽度还影响船舶的水动力特性。更宽的船宽可能导致在水中移动时增加阻力，这可能影响燃油效率。海军建筑师必须仔细平衡船宽与其他设计元素，以实现最佳性能。例如，虽然更宽的船宽可以增强稳定性，但也可能需要更多的动力来维持速度，从而增加运营成本。另一个需要考虑的方面是最大水线宽度与货物容量之间的关系。具有较大船宽的船舶通常可以承载更多的货物，因为船体内可用的体积增加。这对商业船舶尤其有利，在这些船舶中，最大化货物空间对盈利能力至关重要。然而，这必须权衡潜在的缺点，例如降低速度或增加阻力。除了稳定性和货物容量外，最大水线宽度还影响船舶的美观。许多船主和设计师都希望拥有流线型和优雅的轮廓，而这可能会受到船宽尺寸的影响。合适的船宽比例有助于船舶的整体美感，使其对潜在买家或租赁者更具吸引力。此外，海事当局设定的法规和标准通常规定了最大水线宽度的具体要求。这些指导方针旨在确保船舶的安全性和适航性。设计师必须遵循这些法规，同时考虑船舶的独特操作需求。这种平衡需要对工程原理和监管框架有深入的理解。总之，最大水线宽度的概念是多方面的，影响着稳定性、水动力学、货物容量、美学和法规合规性。对于那些参与船舶设计和建造的人来说，掌握这个术语对于创造符合性能期望和安全标准的船舶至关重要。随着海事行业的不断发展，理解最大水线宽度的重要性将继续成为有效船舶设计和操作的基石。通过欣赏与这一测量相关的复杂性，海军建筑师可以为开发更安全、更高效和更具美感的船舶做出贡献。