buoyant tank
简明释义
1. 浮罐; 2. 浮筒;
英英释义
A buoyant tank is a type of container designed to float on the surface of a liquid, typically used for storage or transportation of fluids. | 浮力罐是一种设计用于漂浮在液体表面的容器,通常用于储存或运输液体。 |
例句
1.The team installed a buoyant tank to facilitate the deployment of underwater sensors.
团队安装了一个浮力水箱以便于部署水下传感器。
2.The engineer designed a buoyant tank to help the submarine stay at a stable depth underwater.
工程师设计了一个浮力水箱,以帮助潜艇在水下保持稳定的深度。
3.The buoyant tank was filled with helium to ensure it could float above the water surface.
这个浮力水箱充满了氦气,以确保它能够漂浮在水面上。
4.In marine research, a buoyant tank is essential for studying the behavior of aquatic life.
在海洋研究中,浮力水箱对于研究水生生物的行为至关重要。
5.Using a buoyant tank allows engineers to test the stability of structures in water.
使用浮力水箱可以让工程师测试结构在水中的稳定性。
作文
In the realm of engineering and design, the concept of a buoyant tank plays a crucial role in various applications, particularly in marine and civil engineering. A buoyant tank is essentially a structure designed to remain afloat on water while supporting a certain load or volume of material. This unique capability makes it invaluable in numerous scenarios, including the construction of floating platforms, oil rigs, and even aquatic research stations.The principle behind a buoyant tank is based on Archimedes' principle, which states that an object submerged in fluid experiences a buoyant force equal to the weight of the fluid it displaces. This means that for a buoyant tank to function effectively, it must be designed to displace enough water to counterbalance its own weight along with any additional loads it carries. The materials used in constructing a buoyant tank are often lightweight yet strong, such as reinforced plastics or aluminum, to ensure that it can float while maintaining structural integrity.One of the most common uses of buoyant tanks is in the realm of offshore oil drilling. Here, they serve as the foundation for drilling rigs that operate far from shore. These tanks are designed to withstand harsh marine conditions, including high waves and strong currents. Engineers meticulously calculate the dimensions and materials of these buoyant tanks to ensure that they can support the heavy equipment needed for drilling, while also maintaining stability in turbulent waters.Another interesting application of buoyant tanks is in environmental monitoring and research. Scientists utilize these structures to create floating laboratories that can be deployed in oceans, rivers, or lakes. These buoyant tanks allow researchers to study marine life, collect water samples, and monitor environmental changes without the need for permanent installations on land. The mobility provided by buoyant tanks enables scientists to access remote areas that would otherwise be difficult to reach.Furthermore, buoyant tanks are also being explored for use in renewable energy projects. For example, floating wind farms utilize buoyant tanks to anchor wind turbines in deep waters where traditional fixed foundations would be impractical. This innovative approach not only maximizes the potential for harnessing wind energy but also minimizes the environmental impact on coastal ecosystems.In conclusion, the buoyant tank is a fascinating and versatile structure that has significant implications across various fields. Its ability to float and support loads makes it essential for offshore drilling, environmental research, and renewable energy projects. As technology advances, we can expect to see even more innovative applications of buoyant tanks, contributing to sustainable development and efficient resource management. Understanding the mechanics and applications of buoyant tanks is vital for engineers and designers who strive to solve complex challenges in our ever-evolving world.
在工程和设计领域,浮力水箱的概念在各种应用中发挥着至关重要的作用,特别是在海洋和土木工程中。浮力水箱本质上是一种结构,旨在水面上漂浮,同时支撑一定的负载或材料体积。这种独特的能力使其在许多场景中变得不可或缺,包括浮动平台、石油钻井平台甚至水下研究站的建设。浮力水箱的原理基于阿基米德原理,该原理指出,浸没在流体中的物体会经历一个向上的浮力,等于它所排开的流体的重量。这意味着,为了使浮力水箱有效运作,它必须设计成能够排开足够的水,以抵消自身的重量以及任何附加的负载。用于建造浮力水箱的材料通常是轻便而坚固的,例如增强塑料或铝,以确保它能够漂浮,同时保持结构完整性。浮力水箱最常见的用途之一是在海上石油钻探领域。在这里,它们作为远离海岸的钻井平台的基础。这些水箱被设计成能够承受恶劣的海洋条件,包括高波浪和强水流。工程师们仔细计算这些浮力水箱的尺寸和材料,以确保它们能够支撑进行钻探所需的重型设备,同时在动荡的水域中保持稳定。另一个有趣的应用是环境监测和研究。科学家利用这些结构创建可以在海洋、河流或湖泊中部署的浮动实验室。这些浮力水箱使研究人员能够研究海洋生物、收集水样并监测环境变化,而无需在陆地上建立永久性设施。浮力水箱提供的移动性使科学家能够访问那些通常难以到达的偏远地区。此外,浮力水箱也正在被探索用于可再生能源项目。例如,浮动风电场利用浮力水箱将风力涡轮机锚定在深水区,而传统的固定基础在这里将不切实际。这种创新的方法不仅最大化了利用风能的潜力,而且最小化了对沿海生态系统的环境影响。总之,浮力水箱是一种引人入胜且多功能的结构,在各个领域具有重要意义。它的漂浮和支撑负载的能力使其在海上钻探、环境研究和可再生能源项目中至关重要。随着技术的进步,我们可以预期看到浮力水箱的更多创新应用,为可持续发展和资源管理效率做出贡献。理解浮力水箱的机制和应用对于努力解决我们不断发展的世界中的复杂挑战的工程师和设计师来说至关重要。
相关单词
