maximum waterplane area

简明释义

最大水线面面积

英英释义

例句

1.The research paper focused on the relationship between hull shape and maximum waterplane area for improving performance.

这篇研究论文集中于船体形状与最大水面面积之间的关系，以提高性能。

2.Engineers calculated the maximum waterplane area to ensure that the vessel could support heavy loads without capsizing.

工程师计算了最大水面面积，以确保船只能够在不倾覆的情况下支撑重载。

3.To improve fuel efficiency, the yacht's designer aimed for a larger maximum waterplane area without compromising speed.

为了提高燃油效率，游艇设计师的目标是在不影响速度的情况下实现更大的最大水面面积。

4.The design of the new ferry was optimized to achieve a maximum waterplane area, which enhances stability during rough seas.

新渡轮的设计经过优化，以实现最大水面面积，这在恶劣海况下提高了稳定性。

5.In naval architecture, increasing the maximum waterplane area can help reduce the roll motion of the ship.

在船舶设计中，增加最大水面面积可以帮助减少船只的横摇运动。

作文

The concept of maximum waterplane area refers to the largest horizontal cross-sectional area of a floating body, such as a ship or a boat, when it is at rest on the water's surface. This measurement is crucial in naval architecture and marine engineering because it directly influences the stability and buoyancy of the vessel. When designing a ship, engineers strive to achieve a maximum waterplane area that allows for optimal performance in various sea conditions. A larger waterplane area generally means better stability; however, it can also lead to increased resistance when moving through water. Understanding the implications of maximum waterplane area is essential for ensuring that a vessel can withstand forces such as waves and wind without capsizing. For instance, a ship with a well-designed hull that maximizes its waterplane area will have a lower center of gravity, making it less likely to tip over. This is particularly important for cargo ships, which need to transport heavy loads safely across oceans. In addition to stability, the maximum waterplane area also affects the speed and maneuverability of a vessel. Ships with a larger waterplane area may experience more drag, which can slow them down. Therefore, naval architects must balance the size of the waterplane area with the desired speed and agility of the ship. This balancing act is often a complex process that requires advanced calculations and simulations.Moreover, the maximum waterplane area is not only relevant to large vessels; it also applies to smaller boats and personal watercraft. Recreational boaters must understand how their boat’s design impacts its performance on the water. For example, a sailboat with a wide beam will have a larger waterplane area, providing greater stability while sailing but potentially sacrificing speed. Conversely, a racing yacht may feature a narrower hull to reduce drag, resulting in a smaller waterplane area but enhanced speed capabilities.Another aspect to consider is the environmental impact of the maximum waterplane area. As we face increasing concerns about marine ecosystems, understanding how vessel design affects water displacement and wave patterns becomes critical. A well-designed ship can minimize its wake and reduce the disturbance it causes to marine life, highlighting the importance of integrating environmental considerations into naval architecture.In conclusion, the maximum waterplane area is a fundamental concept in the design and operation of floating vessels. Whether for commercial shipping or recreational boating, understanding this principle enables designers and operators to create safer, more efficient, and environmentally friendly ships. The challenge lies in finding the right balance between stability, speed, and ecological responsibility, which ultimately shapes the future of marine transportation. As we continue to innovate in this field, the significance of the maximum waterplane area will remain a key factor in our quest for excellence on the water.

“最大水面面积”是指浮动物体（如船舶或小艇）在水面静止时的最大水平横截面积。这个测量在海洋建筑和海洋工程中至关重要，因为它直接影响到船只的稳定性和浮力。在设计船舶时，工程师们努力实现一个允许在各种海洋条件下最佳性能的“最大水面面积”。较大的水面面积通常意味着更好的稳定性；然而，它也可能导致在水中移动时阻力增加。理解“最大水面面积”的影响对于确保船只能够承受波浪和风等力量而不倾覆至关重要。例如，具有良好设计船体的船只能够最大化其水面面积，从而拥有更低的重心，降低翻覆的可能性。这对于需要安全运输重载的货船尤为重要。除了稳定性外，“最大水面面积”还影响船舶的速度和机动性。水面面积较大的船只可能会经历更大的阻力，从而减慢速度。因此，海洋建筑师必须在水面面积的大小与船舶所需的速度和灵活性之间取得平衡。这种平衡往往是一个复杂的过程，需要高级的计算和模拟。此外，“最大水面面积”不仅与大型船舶相关，也适用于小型船只和个人水上交通工具。休闲船员必须理解他们的船只设计如何影响其在水上的性能。例如，具有宽梁的帆船将具有更大的水面面积，在航行时提供更大的稳定性，但可能会牺牲速度。相反，竞赛游艇可能采用更窄的船体以减少阻力，从而导致水面面积较小但增强速度能力。另一个需要考虑的方面是“最大水面面积”的环境影响。随着我们面临日益严重的海洋生态系统问题，理解船舶设计如何影响水的位移和波浪模式变得至关重要。设计良好的船只可以最小化其尾流，减少对海洋生物的干扰，突显出将环境考虑纳入海洋建筑的重要性。总之，“最大水面面积”是浮动船舶设计和操作中的一个基本概念。无论是商业航运还是休闲航行，理解这一原则使设计师和操作者能够创造更安全、更高效和更环保的船只。挑战在于在稳定性、速度和生态责任之间找到合适的平衡，这最终塑造了海洋运输的未来。随着我们在这一领域不断创新，“最大水面面积”的重要性将始终是我们在水上追求卓越的关键因素。