controlled-buoyancy system
简明释义
浮力控制系统
英英释义
例句
1.Our prototype features an advanced controlled-buoyancy system that enhances stability underwater.
我们的原型具有先进的控制浮力系统,可以增强水下稳定性。
2.The controlled-buoyancy system allows for precise adjustments in oceanographic studies.
该控制浮力系统允许在海洋学研究中进行精确调整。
3.The underwater drone utilizes a controlled-buoyancy system to navigate complex environments.
这款水下无人机利用控制浮力系统在复杂环境中导航。
4.The research team developed a new controlled-buoyancy system to assist in underwater exploration.
研究团队开发了一种新的控制浮力系统来协助水下探测。
5.Using a controlled-buoyancy system, divers can maintain their position while conducting surveys.
使用控制浮力系统,潜水员可以在进行调查时保持他们的位置。
作文
In the realm of engineering and underwater exploration, the concept of a controlled-buoyancy system plays a crucial role. This innovative technology allows for precise manipulation of an object's buoyancy, enabling it to ascend, descend, or remain suspended in water at a desired depth. The fundamental principle behind a controlled-buoyancy system is Archimedes' principle, which states that an object submerged in a fluid experiences an upward force equal to the weight of the fluid it displaces. By adjusting the amount of buoyant force acting on an object, engineers can achieve specific operational goals, particularly in submersible vehicles and underwater robotics.One of the most significant applications of a controlled-buoyancy system is in remotely operated vehicles (ROVs) used for deep-sea exploration. These vehicles are often deployed to investigate underwater ecosystems, conduct geological surveys, or assist in underwater construction projects. The controlled-buoyancy system enables ROVs to navigate through varying depths with ease. By altering their buoyancy, these vehicles can hover above the seafloor, move vertically, or even ascend to the surface when their mission is complete.Moreover, the design of a controlled-buoyancy system typically involves the integration of ballast tanks that can be filled with water or air. When the ballast tanks are filled with water, the vehicle becomes heavier and sinks. Conversely, when air is pumped into the tanks, the vehicle becomes lighter and rises. This dynamic adjustment allows for real-time control over the vehicle's position, making it a vital feature for any underwater operation.In addition to ROVs, submarines also utilize controlled-buoyancy systems to maneuver through the ocean depths. Submarines operate by changing their buoyancy to dive or surface, a process that is essential for stealth operations and navigation. The ability to maintain a stable position underwater is critical for various military and research missions, where precision is paramount.Furthermore, advancements in technology have led to the development of more sophisticated controlled-buoyancy systems. Modern systems can incorporate sensors and automation, allowing for autonomous adjustments based on environmental conditions. For instance, if a submersible encounters strong currents, the controlled-buoyancy system can automatically compensate to maintain its depth and orientation. This level of sophistication not only enhances operational efficiency but also improves safety during underwater missions.The implications of controlled-buoyancy systems extend beyond exploration; they are also pivotal in environmental monitoring and conservation efforts. For example, researchers can deploy buoyant sensors equipped with controlled-buoyancy systems to collect data on ocean temperatures, salinity, and marine life without disturbing the ecosystem. Such technologies enable scientists to gain insights into climate change and its effects on marine biodiversity.In conclusion, the controlled-buoyancy system is an essential component of modern underwater technology, facilitating a wide range of applications from exploration to environmental monitoring. Its ability to manipulate buoyancy with precision has revolutionized how we interact with underwater environments. As technology continues to advance, we can expect even more innovative uses for controlled-buoyancy systems, further expanding our understanding of the oceans and enhancing our capabilities in underwater operations.
在工程和水下探索领域,控制浮力系统的概念发挥着至关重要的作用。这项创新技术允许对物体的浮力进行精确操控,使其能够上升、下降或在所需深度保持悬浮。控制浮力系统背后的基本原理是阿基米德原理,该原理指出,沉浸在流体中的物体会受到一个向上的力,该力等于它排开的流体的重量。通过调整作用于物体的浮力大小,工程师可以实现特定的操作目标,特别是在潜水器和水下机器人中。控制浮力系统最重要的应用之一是在用于深海探索的遥控潜水器(ROV)中。这些车辆通常被部署来调查水下生态系统、进行地质勘测或协助水下施工项目。控制浮力系统使ROV能够轻松导航通过不同的深度。通过改变它们的浮力,这些车辆可以悬停在海底上方、垂直移动,甚至在任务完成后上升到水面。此外,控制浮力系统的设计通常涉及集成可以充水或充气的压载舱。当压载舱充满水时,车辆变得更重并下沉。相反,当空气被抽入舱内时,车辆变得更轻并上升。这种动态调整使得对车辆位置的实时控制成为可能,使其成为任何水下操作的重要特征。除了ROV,潜艇也利用控制浮力系统在海洋深处机动。潜艇通过改变其浮力来潜水或浮出水面,这一过程对于隐蔽行动和导航至关重要。在水下维持稳定位置对于各种军事和研究任务至关重要,在这些任务中,精确性是首要任务。此外,技术的进步导致了更复杂的控制浮力系统的发展。现代系统可以集成传感器和自动化技术,使其能够根据环境条件进行自主调整。例如,如果潜水器遇到强流,控制浮力系统可以自动补偿,以保持其深度和方向。这种复杂程度不仅提高了操作效率,还改善了水下任务的安全性。控制浮力系统的影响超越了探索;它们在环境监测和保护工作中也至关重要。例如,研究人员可以部署配备控制浮力系统的浮动传感器,以收集关于海洋温度、盐度和海洋生物的数据,而不会干扰生态系统。这些技术使科学家能够深入了解气候变化及其对海洋生物多样性的影响。总之,控制浮力系统是现代水下技术的一个基本组成部分,促进了从探索到环境监测的广泛应用。其精确操控浮力的能力彻底改变了我们与水下环境的互动方式。随着技术的不断进步,我们可以期待控制浮力系统有更多创新的用途,进一步扩展我们对海洋的理解,并增强我们在水下操作中的能力。
