immersed resistance

简明释义

浸水阻力

英英释义

例句

1.In an aquarium, the heater uses immersed resistance 浸没电阻 to maintain a stable temperature for the fish.

在水族箱中，加热器使用浸没电阻 浸没电阻来维持鱼类的稳定温度。

2.The design of the electric kettle incorporates immersed resistance 浸没电阻 to boil water quickly.

电热水壶的设计采用了浸没电阻 浸没电阻以快速煮沸水。

3.Industrial processes often utilize immersed resistance 浸没电阻 for efficient heating of liquids.

工业过程通常利用浸没电阻 浸没电阻高效加热液体。

4.The heating element in the water heater relies on immersed resistance 浸没电阻 to convert electricity into heat efficiently.

水加热器中的加热元件依赖于浸没电阻 浸没电阻有效地将电能转换为热能。

5.When troubleshooting a malfunctioning heater, check the immersed resistance 浸没电阻 for any signs of damage.

在排查故障加热器时，检查浸没电阻 浸没电阻是否有损坏迹象。

作文

In the realm of physics and engineering, the concept of immersed resistance plays a crucial role in understanding the behavior of objects submerged in fluids. This term refers to the resistance encountered by an object when it is immersed in a fluid medium, such as water or air. The immersed resistance can significantly affect the motion of the object, influencing its speed, acceleration, and overall stability. For instance, when a boat moves through water, it experiences immersed resistance due to the friction between the hull and the water molecules. This resistance must be overcome by the engine's power to maintain a steady speed. Understanding immersed resistance is essential for engineers designing various vehicles and structures that interact with fluids. In the case of submarines, for example, engineers must carefully calculate the immersed resistance to ensure that the submarine can move efficiently underwater. Factors such as the shape of the submarine, the materials used in its construction, and the speed at which it travels all contribute to the level of immersed resistance it will face. Moreover, immersed resistance is not limited to large vessels; it also applies to smaller objects, such as swimmers or divers. When a swimmer enters the water, they encounter immersed resistance that can slow them down if they do not streamline their body effectively. This is why competitive swimmers often wear specially designed swimsuits that reduce drag and minimize immersed resistance. The goal is to enhance their performance by allowing them to move more freely through the water. In addition to its applications in transportation and sports, immersed resistance has implications in environmental science as well. For instance, understanding how pollutants disperse in bodies of water involves studying the immersed resistance of various particles. This knowledge can help scientists predict how contaminants spread and develop strategies to mitigate their impact on aquatic ecosystems. Furthermore, the study of immersed resistance extends to the design of underwater structures, such as oil rigs and wind turbines. Engineers must account for the immersed resistance these structures will face due to ocean currents and wave action. By optimizing designs to reduce immersed resistance, they can improve the stability and longevity of these installations. In conclusion, the concept of immersed resistance is vital across multiple fields, from engineering to environmental science. It affects the movement of objects in fluids, influences design considerations, and plays a significant role in performance optimization. By gaining a deeper understanding of immersed resistance, professionals can create more efficient systems, whether they are designing faster boats, improving athletic performance, or protecting our natural resources. As technology continues to advance, the importance of mastering the principles surrounding immersed resistance will only grow, highlighting the need for ongoing research and innovation in this area.

在物理和工程领域，浸入阻力的概念在理解物体在流体中行为时发挥着关键作用。这个术语指的是物体在流体介质（如水或空气）中浸没时所遇到的阻力。浸入阻力可以显著影响物体的运动，影响其速度、加速度和整体稳定性。例如，当一艘船在水中移动时，由于船体与水分子之间的摩擦，它会遭遇浸入阻力。为了保持稳定的速度，必须克服这种阻力。 理解浸入阻力对设计与流体相互作用的各种车辆和结构的工程师至关重要。在潜艇的情况下，工程师必须仔细计算浸入阻力，以确保潜艇能够高效地在水下移动。潜艇的形状、建造材料以及其行驶速度等因素都会影响它所面临的浸入阻力水平。 此外，浸入阻力不仅限于大型船只；它也适用于较小的物体，例如游泳者或潜水员。当游泳者进入水中时，他们会遇到浸入阻力，如果不有效地调整身体姿势，这种阻力会减缓他们的速度。这就是为什么竞技游泳者通常穿着专门设计的泳衣，以减少阻力并最小化浸入阻力的原因。目标是通过让他们更自由地在水中移动来提升表现。 除了在交通和体育方面的应用，浸入阻力在环境科学中也有影响。例如，了解污染物在水体中的扩散涉及研究各种颗粒的浸入阻力。这些知识可以帮助科学家预测污染物的传播方式，并制定减轻其对水生生态系统影响的策略。 此外，浸入阻力的研究还扩展到水下结构的设计，例如石油平台和风力涡轮机。工程师必须考虑这些结构因海洋潮流和波浪作用而面临的浸入阻力。通过优化设计以减少浸入阻力，他们可以提高这些设施的稳定性和耐久性。 总之，浸入阻力的概念在多个领域至关重要，从工程到环境科学。它影响物体在流体中的运动，影响设计考虑，并在性能优化中发挥重要作用。通过深入理解浸入阻力，专业人士可以创造更高效的系统，无论是设计更快的船只、改善运动表现，还是保护我们的自然资源。随着技术的不断进步，掌握浸入阻力相关原则的重要性只会增加，突显出在这一领域持续研究和创新的必要性。