governor deflection

简明释义

调速器偏转

英英释义

例句

1.Engineers need to account for governor deflection 调节器偏移 when designing new machinery.

工程师在设计新机器时需要考虑governor deflection 调节器偏移。

2.During the inspection, we noticed a significant governor deflection 调节器偏移 that could affect speed regulation.

在检查过程中，我们注意到一个显著的governor deflection 调节器偏移，这可能会影响速度调节。

3.The technician measured the governor deflection 调节器偏移 to ensure proper engine performance.

技术人员测量了governor deflection 调节器偏移以确保发动机性能正常。

4.The manual provided detailed instructions on how to measure governor deflection 调节器偏移 accurately.

手册提供了关于如何准确测量governor deflection 调节器偏移的详细说明。

5.Adjusting the governor deflection 调节器偏移 can help improve fuel efficiency in older engines.

调整governor deflection 调节器偏移可以帮助提高旧款发动机的燃油效率。

作文

The concept of governor deflection is integral to understanding how various mechanical systems operate, particularly in engines and turbines. In essence, governor deflection refers to the movement or adjustment of a governor mechanism, which is designed to regulate the speed of an engine or machine. This regulation is crucial for maintaining optimal performance and preventing damage due to excessive speeds. In many industrial applications, the efficiency and safety of machinery heavily depend on accurate governor deflection. To illustrate, consider a steam engine, where the governor plays a vital role in controlling the flow of steam to the engine's cylinders. As the engine speed increases, the centrifugal force acting on the governor's weights causes it to move outward, leading to a corresponding governor deflection. This deflection adjusts the throttle valve, reducing the steam flow and consequently slowing down the engine. Conversely, if the engine speed decreases, the governor's weights move inward, allowing more steam to enter the cylinders and increasing the engine speed. Thus, the balance maintained by governor deflection ensures that the engine operates within its safe limits.In modern applications, governor deflection is not limited to mechanical systems alone. It has found relevance in electronic control systems as well. For instance, in electronic governors used in automotive engines, sensors detect changes in engine speed and send signals to adjust fuel injection rates. The principle remains the same: the system needs to respond to variations in speed to maintain stability and performance. The governor deflection in these systems is often instantaneous, allowing for real-time adjustments that enhance fuel efficiency and reduce emissions.Moreover, understanding governor deflection can also provide insights into the importance of feedback mechanisms in engineering. Feedback loops are essential for maintaining stability in any dynamic system. The governor acts as a feedback controller, continuously monitoring the output (engine speed) and making necessary adjustments to keep that output within desired parameters. This concept extends beyond engineering; it can be applied in fields such as economics, biology, and even social sciences, where systems need to adapt to changing conditions.In conclusion, governor deflection is a critical concept in both mechanical and electronic systems, highlighting the importance of regulation and feedback in maintaining operational stability. Whether in traditional steam engines or modern automotive technologies, the principles governing governor deflection remain relevant. Understanding this concept allows engineers and technicians to design more efficient and safer machines, ultimately contributing to advancements in technology and industry. As we continue to innovate, the lessons learned from governor deflection will undoubtedly shape the future of engineering practices and applications.

“调速器偏移”这一概念对于理解各种机械系统的运作至关重要，尤其是在发动机和涡轮机中。简单来说，调速器偏移是指调速器机制的运动或调整，该机制旨在调节发动机或机器的速度。这种调节对于保持最佳性能和防止因过快速度而造成的损坏至关重要。在许多工业应用中，机器的效率和安全性在很大程度上依赖于准确的调速器偏移。以蒸汽机为例，调速器在控制蒸汽流向发动机气缸方面发挥着重要作用。随着发动机速度的增加，作用于调速器重物的离心力使其向外移动，从而导致相应的调速器偏移。这种偏移会调整节流阀，减少蒸汽流量，从而减慢发动机速度。反之，如果发动机速度降低，调速器重物则向内移动，允许更多蒸汽进入气缸，从而提高发动机速度。因此，调速器偏移所维持的平衡确保了发动机在安全范围内运行。在现代应用中，调速器偏移不仅限于机械系统。它在电子控制系统中也找到了相关性。例如，在汽车发动机中使用的电子调速器，传感器检测发动机速度的变化并发送信号以调整燃油喷射率。这一原理保持不变：系统需要响应速度的变化，以维持稳定性和性能。这些系统中的调速器偏移通常是瞬时的，允许实时调整，从而提高燃油效率并减少排放。此外，理解调速器偏移还可以提供对工程中反馈机制重要性的洞察。反馈回路对于维持任何动态系统的稳定性至关重要。调速器作为反馈控制器，持续监控输出（发动机速度），并进行必要的调整，以保持该输出在期望参数内。这一概念超越了工程领域；它可以应用于经济学、生物学甚至社会科学等领域，在这些领域中，系统需要适应变化的条件。总之，调速器偏移是机械和电子系统中的关键概念，突显了调节和反馈在维持操作稳定性方面的重要性。无论是在传统的蒸汽机还是现代汽车技术中，支配调速器偏移的原则仍然适用。理解这一概念使工程师和技术人员能够设计出更高效、更安全的机器，最终促进技术和工业的进步。随着我们不断创新，从调速器偏移中获得的经验教训无疑将塑造未来的工程实践和应用。