isochronous governor

简明释义

同时调速器同时调节器

英英释义

例句

1.The engineer explained how the isochronous governor 恒定转速调节器 maintains a steady speed in the generator.

工程师解释了如何使用isochronous governor 恒定转速调节器 来保持发电机的稳定速度。

2.In a steam engine, the isochronous governor 恒定转速调节器 helps regulate the flow of steam to ensure consistent performance.

在蒸汽机中，isochronous governor 恒定转速调节器 帮助调节蒸汽流量以确保一致的性能。

3.The isochronous governor 恒定转速调节器 plays a significant role in ensuring the stability of mechanical systems.

在确保机械系统的稳定性方面，isochronous governor 恒定转速调节器 起着重要作用。

4.The use of an isochronous governor 恒定转速调节器 is crucial for maintaining the frequency in power plants.

在发电厂中，使用isochronous governor 恒定转速调节器 对于维持频率至关重要。

5.By adjusting the settings on the isochronous governor 恒定转速调节器, operators can optimize engine performance.

通过调整isochronous governor 恒定转速调节器上的设置，操作员可以优化发动机性能。

作文

In the realm of mechanical engineering and control systems, the concept of an isochronous governor plays a crucial role in maintaining the stability and efficiency of various machines, particularly in engines and turbines. An isochronous governor is a device that regulates the speed of a machine by adjusting the fuel supply or power input based on the load conditions. The primary feature of this type of governor is its ability to maintain a constant speed regardless of changes in the load. This characteristic is essential for applications where precise speed control is necessary, such as in synchronous generators and steam engines.The operation of an isochronous governor can be understood through its feedback mechanism. When the load on the engine increases, the speed tends to drop. The isochronous governor detects this change in speed and responds by increasing the fuel supply, thereby restoring the engine to its desired speed. Conversely, if the load decreases, the governor reduces the fuel supply to prevent the engine from speeding up excessively. This automatic adjustment ensures that the machine operates smoothly and efficiently under varying load conditions.One of the significant advantages of using an isochronous governor is its ability to improve the performance of power systems. In power generation, maintaining a stable frequency is vital for the reliability of the electrical grid. The isochronous governor helps achieve this by ensuring that the output power matches the demand, thus stabilizing the system frequency. This is especially important in scenarios where multiple generators are operating in parallel, as any deviation in speed can lead to synchronization issues and potential damage to the equipment.Moreover, the implementation of an isochronous governor can lead to enhanced fuel efficiency. By optimizing the fuel supply according to the actual load, these governors help minimize wastage and reduce operational costs. This aspect is particularly beneficial in industries where fuel expenses constitute a significant portion of overall operational costs.However, it is essential to note that the design and tuning of an isochronous governor require careful consideration. If not properly calibrated, the governor may respond too slowly or too aggressively to changes in load, leading to instability or oscillations in speed. Engineers must take into account various factors, including the inertia of the system, the characteristics of the load, and the response time of the governor itself.In conclusion, the isochronous governor is a vital component in many mechanical systems, ensuring consistent performance and efficiency. Its ability to maintain a constant speed under varying load conditions makes it indispensable in applications ranging from power generation to transportation. As technology continues to advance, the development of more sophisticated isochronous governors will likely enhance their effectiveness and broaden their applications, further underscoring their importance in modern engineering practices.

在机械工程和控制系统领域，等时调速器的概念在维护各种机器的稳定性和效率方面发挥着至关重要的作用，特别是在发动机和涡轮机中。等时调速器是一种通过根据负载条件调整燃料供应或功率输入来调节机器速度的装置。这种类型的调速器的主要特征是其能够在负载变化的情况下保持恒定速度。这一特性对于需要精确速度控制的应用至关重要，例如在同步发电机和蒸汽机中。等时调速器的操作可以通过其反馈机制来理解。当发动机上的负载增加时，速度往往会下降。等时调速器检测到这一速度变化后，会通过增加燃料供应来响应，从而使发动机恢复到所需的速度。相反，如果负载减少，调速器会减少燃料供应，以防止发动机过快加速。这种自动调整确保了机器在不同负载条件下平稳高效地运行。使用等时调速器的一个显著优点是能够提高电力系统的性能。在发电过程中，保持稳定的频率对于电网的可靠性至关重要。等时调速器通过确保输出功率与需求相匹配，从而帮助实现这一目标，进而稳定系统频率。这在多个发电机并行运行的情况下尤为重要，因为任何速度偏差都可能导致同步问题和设备潜在损坏。此外，实施等时调速器还可以提高燃料效率。通过根据实际负载优化燃料供应，这些调速器有助于最小化浪费并降低运营成本。这一点在燃料费用占总体运营成本很大一部分的行业中尤其有利。然而，需要注意的是，等时调速器的设计和调试需要仔细考虑。如果没有正确校准，调速器可能对负载变化的响应过慢或过于激烈，从而导致速度的不稳定或振荡。工程师必须考虑各种因素，包括系统的惯性、负载的特性和调速器本身的响应时间。总之，等时调速器是许多机械系统中的重要组成部分，确保一致的性能和效率。它在不同负载条件下保持恒定速度的能力使其在从发电到运输等应用中不可或缺。随着技术的不断进步，更复杂的等时调速器的发展可能会提高其有效性并扩大其应用范围，进一步强调其在现代工程实践中的重要性。