governor servo-mechanism
简明释义
调速器伺服机构
英英释义
例句
1.The engine's performance improved significantly after we calibrated the governor servo-mechanism.
在我们校准了调速器伺服机制后,发动机的性能显著提高。
2.The governor servo-mechanism is crucial for maintaining speed stability in turbines.
调速器伺服机制对于保持涡轮机的速度稳定至关重要。
3.In our robotics project, we used a governor servo-mechanism to ensure precise movement control.
在我们的机器人项目中,我们使用了调速器伺服机制来确保精确的运动控制。
4.We encountered issues with the governor servo-mechanism that caused fluctuations in power output.
我们遇到了调速器伺服机制的问题,导致输出功率波动。
5.The technician explained how the governor servo-mechanism regulates the engine speed.
技术员解释了调速器伺服机制如何调节发动机速度。
作文
The concept of a governor servo-mechanism is crucial in understanding how various systems maintain stability and control. In engineering, particularly in the fields of mechanical and electrical systems, a governor is a device that automatically regulates the speed of a machine, ensuring that it operates within a designated range. The governor servo-mechanism combines this regulatory function with feedback control, allowing for precise adjustments based on real-time performance data.To comprehend the importance of a governor servo-mechanism, one must first consider its applications. For instance, in steam engines, the governor serves to maintain a constant speed by adjusting the fuel supply based on the engine's output. When the engine speeds up, the governor reduces fuel intake, and when it slows down, it increases fuel flow. This dynamic adjustment is essential for efficient operation and prevents mechanical failure due to excessive speed or load.In modern applications, the governor servo-mechanism is widely used in various industries, including automotive, aerospace, and manufacturing. In an automobile, for example, electronic throttle control systems utilize a governor to manage engine performance, optimizing fuel efficiency and reducing emissions. The servo-mechanism aspect allows for rapid response to changes in driving conditions, enhancing both safety and performance.Moreover, the integration of advanced technologies such as sensors and microcontrollers has transformed traditional governor servo-mechanism designs. These innovations enable more sophisticated feedback loops, where the system can learn from past performance and adjust accordingly. This adaptability is particularly beneficial in complex systems where multiple variables influence performance, such as in unmanned aerial vehicles (UAVs) or robotic systems.Understanding the principles behind a governor servo-mechanism also sheds light on its role in energy management. In power generation, for example, governors are vital in maintaining grid stability. They help balance supply and demand by regulating the output of generators in response to fluctuations in electricity consumption. This function is increasingly important as renewable energy sources, which can be variable and unpredictable, become more integrated into the energy mix.In conclusion, the governor servo-mechanism is a fundamental component in many technological systems, providing the necessary control and stability for efficient operation. Its ability to adapt and respond to changing conditions makes it invaluable across various applications, from traditional machinery to cutting-edge robotics. As technology continues to evolve, the principles behind the governor servo-mechanism will remain integral to future advancements, ensuring that systems operate safely and effectively under diverse conditions.
“调速器伺服机制”的概念在理解各种系统如何维持稳定性和控制方面至关重要。在工程领域,特别是在机械和电气系统中,调速器是一种自动调节机器速度的装置,确保其在指定范围内运行。“调速器伺服机制”将这种调节功能与反馈控制相结合,允许根据实时性能数据进行精确调整。要理解“调速器伺服机制”的重要性,首先必须考虑它的应用。例如,在蒸汽机中,调速器用于通过根据发动机的输出调节燃料供应来保持恒定速度。当发动机加速时,调速器减少燃料摄入;当其减速时,增加燃料流量。这种动态调整对高效运行至关重要,并防止因过速或过载而导致的机械故障。在现代应用中,“调速器伺服机制”广泛用于汽车、航空航天和制造业等各个行业。例如,在汽车中,电子油门控制系统利用调速器来管理发动机性能,优化燃油效率并减少排放。伺服机制的特性使其能够快速响应驾驶条件的变化,从而增强安全性和性能。此外,高级技术如传感器和微控制器的集成已转变了传统的“调速器伺服机制”设计。这些创新使得更复杂的反馈回路成为可能,系统可以从过去的性能中学习并相应调整。这种适应性在多个变量影响性能的复杂系统中尤为有益,例如无人机(UAV)或机器人系统。理解“调速器伺服机制”背后的原理也揭示了其在能源管理中的作用。例如,在发电中,调速器在维持电网稳定性方面至关重要。它们通过根据电力消费波动调节发电机的输出,帮助平衡供需。随着可再生能源来源(这些来源可能是可变和不可预测的)越来越多地融入能源组合,这一功能变得愈发重要。总之,“调速器伺服机制”是许多技术系统中的基本组成部分,为高效运行提供必要的控制和稳定性。它的适应性和对变化条件的响应能力使其在从传统机械到尖端机器人等各种应用中都具有无价之宝。随着技术的不断发展,“调速器伺服机制”背后的原理将继续对未来的进步至关重要,确保系统在多样化条件下安全有效地运行。
