isochronous governor

简明释义

同步调节器

英英释义

例句

1.The use of an isochronous governor 恒定速率调节器 can improve the efficiency of steam turbines.

使用恒定速率调节器可以提高蒸汽涡轮的效率。

2.The design of the isochronous governor 恒定速率调节器 allows it to respond quickly to changes in load.

恒定速率调节器的设计使其能够快速响应负载变化。

3.During the test, the isochronous governor 恒定速率调节器 successfully kept the rotational speed constant.

在测试过程中，恒定速率调节器成功地保持了转速恒定。

4.In power plants, an isochronous governor 恒定速率调节器 is crucial for balancing load changes.

在发电厂中，恒定速率调节器对于平衡负载变化至关重要。

5.The engineer explained how the isochronous governor 恒定速率调节器 maintains a steady speed in the engine.

工程师解释了恒定速率调节器是如何在发动机中保持稳定速度的。

作文

In the field of mechanical engineering and control systems, the term isochronous governor refers to a specific type of governor that maintains a constant speed of a machine regardless of the load variations. This concept is particularly crucial in applications where maintaining a steady operational speed is essential for performance and efficiency. The isochronous governor operates by automatically adjusting the fuel or power input to the engine or turbine based on the current load demands. This ensures that even if there are fluctuations in the load, the speed of the machine remains unchanged.The historical development of the isochronous governor can be traced back to the industrial revolution when steam engines were widely used. Engineers recognized the need for a mechanism that could regulate engine speed to enhance productivity and prevent mechanical failures. Traditional governors were often insufficient as they could not react quickly enough to changes in load, leading to inefficiencies and potential damage.The principle behind the isochronous governor lies in its feedback system. It typically uses a combination of mechanical and electronic components to sense speed and adjust the input accordingly. For instance, in a steam engine, if the load increases suddenly due to an additional task, the isochronous governor detects the drop in speed and compensates by increasing the steam flow. This real-time adjustment is what differentiates it from other types of governors that may only respond after a delay.One of the most common applications of the isochronous governor is in electrical power generation. In power plants, maintaining a constant frequency is vital for the stability of the electrical grid. The isochronous governor helps synchronize the output of generators with the demand on the grid, ensuring that supply matches consumption without significant fluctuations. This is critical in preventing blackouts and ensuring reliable power delivery.Moreover, the isochronous governor is also utilized in various transportation systems, including ships and locomotives. In these systems, it ensures that the vehicle maintains a consistent speed, which is essential for safety and efficiency. By providing precise control over engine output, the isochronous governor contributes to smoother operation and improved fuel economy.Despite its advantages, implementing an isochronous governor can be complex and requires careful calibration. Engineers must consider factors such as the type of engine, the range of load variations, and the desired response time. Additionally, modern advancements in technology have introduced digital governors that utilize sophisticated algorithms to enhance the performance of traditional governors. These digital systems can offer even greater precision and adaptability, making them suitable for a wider range of applications.In conclusion, the isochronous governor plays a pivotal role in various mechanical and electrical systems by ensuring a stable operational speed despite changing loads. Its ability to provide real-time adjustments enhances efficiency, safety, and reliability in numerous applications, from power generation to transportation. As technology continues to evolve, the significance of the isochronous governor will likely grow, paving the way for more innovative solutions in the field of control systems.

在机械工程和控制系统领域，术语等时调节器指的是一种特定类型的调节器，它能够在负载变化的情况下保持机器的恒定速度。这个概念在需要保持稳定操作速度以确保性能和效率的应用中尤为重要。等时调节器通过自动调整引擎或涡轮的燃料或电力输入来运行，以适应当前的负载需求。这确保了即使负载波动，机器的速度也保持不变。等时调节器的历史发展可以追溯到工业革命，当时蒸汽机被广泛使用。工程师们意识到需要一种机制来调节引擎速度，以提高生产率并防止机械故障。传统的调节器往往不足，因为它们无法快速响应负载变化，导致效率低下和潜在损坏。等时调节器背后的原理在于其反馈系统。它通常使用机械和电子组件的组合来感知速度并相应地调整输入。例如，在蒸汽机中，如果由于额外任务而负载突然增加，等时调节器会检测到速度的下降，并通过增加蒸汽流量进行补偿。这种实时调整就是它与其他类型调节器的不同之处，后者可能仅在延迟后才做出反应。等时调节器最常见的应用之一是在电力发电中。在发电厂中，保持恒定频率对电网的稳定性至关重要。等时调节器帮助将发电机的输出与电网的需求同步，确保供应与消费之间没有显著波动。这对于防止停电和确保可靠的电力传输至关重要。此外，等时调节器还用于各种运输系统，包括船舶和机车。在这些系统中，它确保车辆保持一致的速度，这对安全和效率至关重要。通过提供对引擎输出的精确控制，等时调节器有助于更平稳的操作和改善的燃油经济性。尽管具有优势，但实施等时调节器可能很复杂，需要仔细校准。工程师必须考虑引擎类型、负载变化范围和所需响应时间等因素。此外，现代技术的进步引入了利用复杂算法增强传统调节器性能的数字调节器。这些数字系统可以提供更大的精度和适应性，使其适合更广泛的应用。总之，等时调节器在各种机械和电气系统中发挥着关键作用，通过确保在负载变化时保持稳定的操作速度。它提供实时调整的能力，提高了许多应用中的效率、安全性和可靠性，从发电到运输。随着技术的不断发展，等时调节器的重要性可能会不断增长，为控制系统领域的更多创新解决方案铺平道路。