buoyancy chamber

简明释义

浮力柜

英英释义

例句

1.The lifeboat is equipped with a buoyancy chamber to ensure it stays afloat in rough waters.

救生艇配备了一个浮力舱，以确保在恶劣水域中保持漂浮。

2.If the buoyancy chamber is damaged, the boat may sink.

如果浮力舱受损，船可能会沉没。

3.The engineer explained how the buoyancy chamber works to keep submarines stable underwater.

工程师解释了浮力舱如何保持潜艇在水下的稳定。

4.During the safety drill, we learned how to check the integrity of the buoyancy chamber in our life jackets.

在安全演习中，我们学习了如何检查救生衣中浮力舱的完整性。

5.The design of the kayak includes a buoyancy chamber to prevent it from capsizing.

这款皮划艇的设计包括一个浮力舱，以防止翻船。

作文

The concept of a buoyancy chamber plays a crucial role in various fields, especially in marine engineering and underwater exploration. A buoyancy chamber is essentially a compartment designed to provide buoyancy to a vessel or device, allowing it to float or remain stable in water. This principle is fundamental for submarines, life rafts, and even some types of fishing gear. Understanding how a buoyancy chamber works can help us appreciate the intricacies of design and functionality in aquatic environments.In marine engineering, the design of a buoyancy chamber is critical for ensuring that vessels can navigate safely through water. For example, submarines are equipped with multiple buoyancy chambers that can be filled with air or water. When the submarine needs to dive, the buoyancy chambers are flooded with water, increasing its weight and allowing it to sink. Conversely, when it needs to surface, air is pumped back into the buoyancy chambers, reducing the overall weight and enabling the submarine to rise. This delicate balance of buoyancy is what allows submarines to travel beneath the waves without losing control.Similarly, life rafts utilize buoyancy chambers to keep individuals afloat in emergency situations. These inflatable rafts contain air-filled buoyancy chambers that provide the necessary lift to support several people. In the event of a maritime disaster, such as a ship sinking, these life rafts can mean the difference between life and death. The design of these buoyancy chambers is meticulously calculated to ensure they can withstand the weight of multiple occupants while remaining stable in choppy waters.Moreover, the fishing industry also benefits from the use of buoyancy chambers. Certain fishing devices, like floats and nets, incorporate buoyancy chambers to keep them at the desired depth in the water. By adjusting the size and volume of the buoyancy chambers, fishers can control how deep their nets are submerged, which is essential for catching specific types of fish. This application highlights the versatility of buoyancy chambers beyond just large vessels and demonstrates their importance in everyday activities.Understanding the physics behind a buoyancy chamber involves grasping Archimedes' principle, which states that an object submerged in a fluid experiences an upward force equal to the weight of the fluid displaced by the object. This principle is what makes the buoyancy chamber effective in providing lift. Engineers must carefully consider the materials and dimensions of the buoyancy chambers they design to optimize performance and safety.In conclusion, the buoyancy chamber is a fascinating and essential component in various marine applications. Its ability to provide stability and support in water is invaluable, whether in the context of submarines, life-saving devices, or fishing equipment. As technology continues to advance, the design and functionality of buoyancy chambers will likely evolve, further enhancing our capabilities in aquatic environments. Understanding this concept not only enriches our knowledge of marine engineering but also emphasizes the importance of innovation in creating safer and more efficient watercraft and devices.

“浮力舱”的概念在多个领域中发挥着至关重要的作用，尤其是在海洋工程和水下探索中。“浮力舱”本质上是一个旨在为船只或设备提供浮力的隔间，使其能够漂浮或在水中保持稳定。这一原理对于潜艇、救生筏乃至某些类型的渔具都是基础。理解“浮力舱”的工作原理可以帮助我们欣赏水域环境中设计和功能的复杂性。在海洋工程中，“浮力舱”的设计对于确保船只能够安全航行至关重要。例如，潜艇配备了多个“浮力舱”，这些舱室可以充满空气或水。当潜艇需要下潜时，“浮力舱”被灌入水，增加其重量，使其下沉。相反，当它需要浮出水面时，空气被泵回“浮力舱”，减少整体重量，使潜艇上升。这种浮力的微妙平衡使潜艇能够在波浪下航行而不失控。同样，救生筏利用“浮力舱”使个人在紧急情况下漂浮。这些充气筏子含有充满空气的“浮力舱”，提供必要的升力以支持多人。在海上灾难发生时，例如船只沉没，这些救生筏可能意味着生与死的区别。这些“浮力舱”的设计经过精心计算，以确保它们能够承受多名乘员的重量，同时在波涛汹涌的水中保持稳定。此外，渔业也受益于使用“浮力舱”。某些渔具，例如浮子和渔网，结合了“浮力舱”，以保持它们在水中的所需深度。通过调整“浮力舱”的大小和体积，渔民可以控制他们的渔网浸没的深度，这对于捕捉特定类型的鱼至关重要。这一应用突显了“浮力舱”在大型船只之外的多功能性，并展示了它们在日常活动中的重要性。理解“浮力舱”背后的物理学涉及掌握阿基米德原理，该原理指出，浸没在流体中的物体会经历一个向上的力，该力等于物体所排开的流体的重量。这一原理使得“浮力舱”能够有效地提供升力。工程师必须仔细考虑他们设计的“浮力舱”的材料和尺寸，以优化性能和安全性。总之，“浮力舱”是各种海洋应用中一个引人入胜且必不可少的组成部分。它在水中提供稳定性和支持的能力是无价的，无论是在潜艇、救生设备还是渔具的背景下。随着技术的不断进步，“浮力舱”的设计和功能可能会不断演变，进一步增强我们在水域环境中的能力。理解这一概念不仅丰富了我们对海洋工程的知识，也强调了创新在创造更安全、更高效的水上交通工具和设备中的重要性。