marine power plant manoeuvrability

简明释义

船用动力装置操纵性

英英释义

例句

1.In naval exercises, marine power plant manoeuvrability 海洋动力厂的机动性 is crucial for evading enemy detection.

在海军演习中，海洋动力厂的机动性 对于躲避敌方侦测至关重要。

2.Engineers are focusing on improving the marine power plant manoeuvrability 海洋动力厂的机动性 for better performance during storms.

工程师们正专注于提高海洋动力厂的机动性 以便在风暴中获得更好的性能。

3.The new propulsion system significantly boosts the marine power plant manoeuvrability 海洋动力厂的机动性 of the ship.

新型推进系统显著增强了船只的海洋动力厂的机动性。

4.The research team is studying how to enhance marine power plant manoeuvrability 海洋动力厂的机动性 through advanced algorithms.

研究小组正在研究如何通过先进算法增强海洋动力厂的机动性。

5.The design of the vessel greatly enhances its marine power plant manoeuvrability 海洋动力厂的机动性 in tight harbors.

该船只的设计极大地提高了其海洋动力厂的机动性 在狭窄港口中的操作能力。

作文

The concept of marine power plant manoeuvrability is essential in the field of naval engineering and maritime operations. It refers to the ability of a marine power plant, which typically includes engines and propulsion systems, to effectively maneuver a vessel in various sea conditions. The significance of this concept cannot be overstated as it directly impacts the safety, efficiency, and operational capabilities of ships. In modern maritime activities, where vessels are often required to navigate through congested ports or challenging weather conditions, the marine power plant manoeuvrability becomes a critical factor in ensuring successful voyages.To understand marine power plant manoeuvrability, we must first consider the components that contribute to it. The propulsion system, including propellers, thrusters, and rudders, plays a pivotal role in determining how well a ship can turn, stop, or change direction. Advanced technologies, such as azimuth thrusters and dynamic positioning systems, have revolutionized the way vessels operate, allowing for greater precision and control. These innovations enhance the marine power plant manoeuvrability by providing operators with more options for maneuvering their ships, especially in tight spaces.Moreover, the design of the hull also influences the marine power plant manoeuvrability. A well-designed hull can reduce drag and improve stability, making it easier for the ship to respond to steering inputs. Engineers must consider factors such as weight distribution, center of gravity, and hydrodynamic shape when designing vessels to optimize their maneuverability. This interplay between design and technology is crucial for achieving superior marine power plant manoeuvrability.In addition to technical aspects, training and experience of crew members are vital for maximizing marine power plant manoeuvrability. Skilled operators who understand the intricacies of their vessel's systems can make informed decisions during maneuvers, enhancing safety and efficiency. Simulation training programs are increasingly being used to prepare crews for real-world scenarios, allowing them to practice maneuvers in a controlled environment before facing the unpredictability of the open sea.Furthermore, environmental factors such as wind, currents, and waves also affect marine power plant manoeuvrability. Navigating through rough seas requires not only a capable power plant but also an understanding of how these external forces interact with the vessel. Captains and crew must be adept at adjusting their strategies based on changing conditions, ensuring that they can maintain control and steer the ship safely.In conclusion, marine power plant manoeuvrability is a multifaceted concept that encompasses engineering, design, training, and environmental awareness. As maritime operations continue to evolve, the importance of enhancing this capability will only grow. Innovations in technology and design, combined with rigorous training for personnel, will lead to safer and more efficient marine operations. Ultimately, the ability to maneuver effectively is not just about moving a vessel; it is about ensuring the safety of the crew, cargo, and the marine environment itself. Therefore, investing in improving marine power plant manoeuvrability should be a priority for all stakeholders in the maritime industry.

“海洋动力厂机动性”的概念在海军工程和海事作业领域至关重要。它指的是海洋动力厂（通常包括发动机和推进系统）在各种海况下有效操控船舶的能力。这个概念的重要性不容小觑，因为它直接影响到船舶的安全、效率和操作能力。在现代海事活动中，船舶常常需要在拥挤的港口或恶劣的天气条件下航行，因此“海洋动力厂机动性”成为确保成功航行的关键因素。要理解“海洋动力厂机动性”，我们首先必须考虑影响它的组成部分。推进系统，包括螺旋桨、推进器和舵，发挥着决定船舶如何转向、停止或改变方向的关键作用。先进的技术，如旋转推进器和动态定位系统，已经彻底改变了船舶的操作方式，使其能够实现更高的精确度和控制。这些创新通过为操作员提供更多的操控选择，增强了“海洋动力厂机动性”，尤其是在狭窄空间内。此外，船体的设计也会影响“海洋动力厂机动性”。设计良好的船体可以减少阻力，提高稳定性，使船舶更容易响应操纵输入。工程师在设计船舶时必须考虑重量分布、重心和水动力形状等因素，以优化其机动性。这种设计与技术之间的相互作用对于实现卓越的“海洋动力厂机动性”至关重要。除了技术方面，船员的培训和经验对于最大化“海洋动力厂机动性”也是至关重要的。熟练的操作员了解其船舶系统的复杂性，可以在操控过程中做出明智的决策，从而提高安全性和效率。模拟训练程序越来越多地被用于准备船员应对现实世界的情景，使他们能够在受控环境中练习操控，在面对开放海域的不可预测性之前。此外，风、洋流和波浪等环境因素也会影响“海洋动力厂机动性”。在恶劣海况下航行不仅需要一个有能力的动力厂，还需要了解这些外部力量如何与船舶相互作用。船长和船员必须善于根据变化的条件调整他们的策略，确保他们能够保持控制并安全驾驶船舶。总之，“海洋动力厂机动性”是一个多方面的概念，涵盖了工程、设计、培训和环境意识。随着海事作业的不断发展，提高这一能力的重要性只会增加。技术和设计的创新，加上对人员的严格培训，将导致更安全、更高效的海洋操作。最终，有效的机动能力不仅仅是关于移动船舶；它关乎确保船员、货物和海洋环境本身的安全。因此，投资于改善“海洋动力厂机动性”应该成为海事行业所有利益相关者的优先事项。