fluid power

简明释义

液力

英英释义

例句

1.The aerospace sector utilizes fluid power 流体动力 for controlling aircraft systems.

航空航天部门利用流体动力来控制飞机系统。

2.In manufacturing, fluid power 流体动力 is used to automate processes and improve efficiency.

在制造业中，流体动力用于自动化流程并提高效率。

3.Pneumatic tools operate using fluid power 流体动力, making them lightweight and easy to handle.

气动工具使用流体动力，使其轻便易于操作。

4.The construction industry heavily relies on fluid power 流体动力 systems for operating heavy machinery.

建筑行业严重依赖于流体动力系统来操作重型机械。

5.Many hydraulic brakes use fluid power 流体动力 to ensure safety in vehicles.

许多液压刹车使用流体动力来确保车辆的安全。

作文

The concept of fluid power refers to the use of fluids, typically liquids or gases, to generate, control, and transmit power. This technology has become an essential part of various industrial applications, from manufacturing to construction. Understanding fluid power is crucial for engineers and technicians as it plays a significant role in the efficiency and effectiveness of machinery. One of the primary advantages of fluid power systems is their ability to transmit large amounts of power through relatively small tubes and hoses. This capability allows for compact designs that can operate in confined spaces, making them ideal for mobile equipment like excavators and forklifts. Additionally, fluid power systems can be easily controlled, allowing for precise movements and adjustments. For instance, hydraulic systems, a subset of fluid power, are commonly used in car repair shops for lifting vehicles. The operator can adjust the pressure to lift the car to the desired height safely and efficiently.Moreover, fluid power systems are known for their reliability and durability. Unlike electrical systems, which can be affected by weather conditions or electrical failures, fluid power systems can continue to operate in harsh environments. This robustness makes them suitable for heavy-duty applications, such as in mining and oil drilling, where equipment is subjected to extreme conditions.However, working with fluid power does come with its challenges. One major concern is the potential for leaks, which can lead to loss of fluid and reduced efficiency. Engineers must design systems with proper seals and maintenance protocols to minimize this risk. Furthermore, understanding the properties of the fluids used in fluid power systems is essential. Different fluids have varying viscosities and compressibility, which can affect system performance.In addition to industrial applications, fluid power is also increasingly being utilized in renewable energy technologies. For example, hydraulic systems can be used to harness energy from wave and tidal movements, providing a sustainable source of power. As society moves towards greener energy solutions, the role of fluid power is likely to expand further, offering innovative ways to meet energy demands.In conclusion, fluid power is a vital technology that underpins many modern machines and processes. Its ability to provide powerful, reliable, and efficient solutions makes it indispensable in various fields. As advancements in technology continue to evolve, the significance of fluid power will only grow, paving the way for new innovations and applications in both industrial and renewable energy sectors.

“流体动力”这一概念指的是利用流体，通常是液体或气体，来生成、控制和传递动力。这项技术已成为各种工业应用的重要组成部分，从制造业到建筑业。理解“流体动力”对工程师和技术人员至关重要，因为它在机械的效率和有效性中发挥着重要作用。“流体动力”系统的一个主要优点是它们能够通过相对较小的管道和软管传输大量的动力。这种能力允许紧凑的设计，可以在狭小的空间中操作，使其非常适合像挖掘机和叉车这样的移动设备。此外，“流体动力”系统可以很容易地进行控制，允许精确的运动和调整。例如，液压系统是“流体动力”的一个子集，通常用于汽车修理厂提升车辆。操作员可以调整压力，将汽车安全高效地提升到所需高度。此外，“流体动力”系统以其可靠性和耐用性而闻名。与可能受到天气条件或电气故障影响的电气系统不同，“流体动力”系统可以在恶劣环境中继续运行。这种坚固性使其适合重型应用，例如在矿业和石油钻探中，设备面临极端条件。然而，使用“流体动力”也存在一些挑战。一个主要问题是潜在的泄漏，这可能导致液体损失和效率降低。工程师必须设计具有适当密封和维护协议的系统，以最小化这一风险。此外，了解“流体动力”系统中使用的流体的特性至关重要。不同的流体具有不同的粘度和可压缩性，这可能会影响系统性能。除了工业应用外，“流体动力”在可再生能源技术中的应用也越来越广泛。例如，液压系统可以用于利用波浪和潮汐运动中的能量，提供可持续的动力来源。随着社会向绿色能源解决方案的转变，“流体动力”的角色可能会进一步扩大，提供创新的方法来满足能源需求。总之，“流体动力”是一项重要的技术，是现代许多机器和过程的基础。它提供强大、可靠和高效的解决方案，使其在各个领域不可或缺。随着技术的不断进步，“流体动力”的重要性只会增加，为工业和可再生能源部门的新创新和应用铺平道路。