centrifugal regulator

简明释义

离心调节器

英英释义

例句

1.The engineer explained how the centrifugal regulator 离心调节器 works in maintaining the speed of the engine.

工程师解释了如何使用 离心调节器 centrifugal regulator 来维持发动机的速度。

2.In a steam engine, the centrifugal regulator 离心调节器 helps to regulate the flow of steam based on the engine's speed.

在蒸汽机中，离心调节器 centrifugal regulator 有助于根据发动机的速度调节蒸汽流量。

3.During the maintenance check, we found that the centrifugal regulator 离心调节器 was malfunctioning and needed replacement.

在维护检查中，我们发现 离心调节器 centrifugal regulator 出现故障，需要更换。

4.The centrifugal regulator 离心调节器 is crucial for ensuring consistent performance in high-speed machinery.

离心调节器 centrifugal regulator 对于确保高速机器的一致性能至关重要。

5.The design of the centrifugal regulator 离心调节器 allows for automatic adjustments in response to changes in load.

离心调节器 centrifugal regulator 的设计允许根据负载变化进行自动调整。

作文

The concept of a centrifugal regulator is essential in understanding how certain mechanical systems maintain stability and efficiency. A centrifugal regulator is a device that uses the principles of centrifugal force to regulate the speed of a machine, ensuring that it operates within a safe and efficient range. This mechanism is commonly found in various applications, including engines, turbines, and even in household appliances like washing machines. To appreciate the functionality of a centrifugal regulator, one must first comprehend the basic principles of centrifugal force. When an object moves in a circular path, it experiences a force directed away from the center of rotation. This force increases with the speed of the object. A centrifugal regulator harnesses this principle by using weights or other mechanisms that respond to changes in rotational speed. As the speed of the machine increases, the centrifugal force acting on these weights causes them to move outward. This movement can then be translated into a regulatory action, such as adjusting the fuel supply in an engine or changing the pitch of blades in a turbine.In practical terms, the implementation of a centrifugal regulator can significantly enhance the performance and safety of machinery. For instance, in steam engines, the centrifugal regulator ensures that the engine does not exceed its maximum speed, which could lead to catastrophic failure. By automatically adjusting the steam intake based on the engine's speed, it maintains a balance that keeps the machine running smoothly. Moreover, the application of a centrifugal regulator is not limited to large industrial machines. In everyday devices, such as washing machines, this technology helps manage the spin cycle. As the drum spins faster, the centrifugal regulator can adjust the speed to prevent excessive vibrations and potential damage to the appliance. The design of a centrifugal regulator can vary widely depending on its intended application. Some regulators are simple mechanical devices, while others may incorporate electronic components for more precise control. Regardless of the design, the fundamental goal remains the same: to provide a reliable means of regulating speed and maintaining operational efficiency. In conclusion, understanding the role of a centrifugal regulator is crucial for anyone involved in mechanical engineering or related fields. Its ability to utilize centrifugal force for speed regulation makes it an invaluable component in many machines. As technology continues to evolve, the principles behind the centrifugal regulator will likely be adapted and improved, leading to even greater efficiencies and innovations in engineering. The study of such devices not only highlights the ingenuity of mechanical design but also emphasizes the importance of safety and reliability in machine operation. Thus, the centrifugal regulator serves as a perfect example of how fundamental scientific principles can be applied to solve real-world problems, making our machines safer and more efficient.

理解离心调节器的概念对于了解某些机械系统如何维持稳定性和效率至关重要。离心调节器是一种利用离心力原理来调节机器速度的装置，确保其在安全且高效的范围内运行。该机制通常应用于各种场合，包括发动机、涡轮机，甚至家用电器，如洗衣机。要欣赏离心调节器的功能，首先必须理解离心力的基本原理。当物体沿圆形路径运动时，它会受到指向旋转中心外侧的力。这个力随着物体速度的增加而增加。离心调节器利用这一原理，通过使用响应旋转速度变化的重物或其他机制。当机器的速度增加时，作用于这些重物的离心力使它们向外移动。这种移动可以转化为调节行动，例如调整发动机的燃料供应或改变涡轮的叶片角度。在实际应用中，实施离心调节器可以显著提高机械的性能和安全性。例如，在蒸汽机中，离心调节器确保发动机不会超过其最大速度，这可能导致灾难性的故障。通过根据发动机的速度自动调整蒸汽进气量，它维持了一种平衡，使机器平稳运行。此外，离心调节器的应用并不局限于大型工业机器。在日常设备中，如洗衣机，这项技术有助于管理脱水循环。当滚筒旋转得更快时，离心调节器可以调整速度，以防止过度振动和对设备的潜在损坏。离心调节器的设计可以根据其预期应用有很大不同。有些调节器是简单的机械装置，而其他调节器可能结合电子元件以实现更精确的控制。无论设计如何，基本目标始终相同：提供可靠的手段来调节速度并维持操作效率。总之，理解离心调节器的作用对于任何参与机械工程或相关领域的人来说都是至关重要的。它利用离心力进行速度调节的能力使其成为许多机器中不可或缺的组件。随着技术的不断发展，离心调节器背后的原理可能会被改编和改进，从而在工程中带来更大的效率和创新。对这些设备的研究不仅突显了机械设计的聪明才智，还强调了机器操作中安全性和可靠性的重要性。因此，离心调节器完美地展示了基础科学原理如何应用于解决现实世界问题，使我们的机器更加安全和高效。