turbine governor

简明释义

透平蒂器

英英释义

例句

1.During the test, the turbine governor maintained a steady output despite varying wind speeds.

在测试过程中，涡轮机调速器尽管风速变化，但仍保持稳定的输出。

2.The turbine governor plays a crucial role in regulating the speed of the turbine.

涡轮机调速器在调节涡轮速度方面起着至关重要的作用。

3.A malfunction in the turbine governor can lead to inefficient energy production.

在涡轮机调速器中发生故障可能会导致能量生产效率低下。

4.Engineers often perform routine checks on the turbine governor to ensure its proper functioning.

工程师们经常对涡轮机调速器进行例行检查，以确保其正常运作。

5.The engineer adjusted the turbine governor to optimize the performance of the wind turbine.

工程师调整了涡轮机调速器以优化风力涡轮机的性能。

作文

The concept of a turbine governor is pivotal in the field of mechanical engineering, particularly in the operation and regulation of turbines. A turbine governor is a device that automatically regulates the speed of a turbine by adjusting the flow of fuel or water to it. This mechanism ensures that the turbine operates within its designated speed range, preventing potential damage due to overspeed conditions. In hydroelectric power plants, for instance, the turbine governor plays a crucial role in managing the water flow to the turbines, thereby optimizing electricity generation while maintaining safety standards.Understanding the functionality of a turbine governor requires a grasp of basic principles of physics and engineering. When a turbine generates energy, it converts kinetic energy from a fluid (water, steam, or gas) into mechanical energy. However, fluctuations in the fluid supply can lead to variations in speed. Without a governing system, these fluctuations could cause the turbine to operate too quickly, risking mechanical failure or inefficient energy production. The turbine governor mitigates this risk by continuously monitoring the turbine's rotational speed and making real-time adjustments to the input flow.In modern applications, turbine governors are often equipped with sophisticated electronic control systems that enhance their responsiveness and accuracy. These advanced governors utilize sensors and algorithms to predict changes in turbine load and adjust the input accordingly. For example, if there is an increase in electrical demand, the turbine governor will sense this change and increase the flow to the turbine, ensuring that it meets the demand without exceeding safe operational limits.The importance of a turbine governor extends beyond just performance; it also has significant implications for environmental sustainability. By optimizing the operation of turbines, these governors help reduce waste and improve the efficiency of energy production. In renewable energy systems, such as wind or hydroelectric power, efficient turbine operation is essential for maximizing output while minimizing ecological impact. Thus, the turbine governor not only enhances operational efficiency but also contributes to sustainable energy practices.Furthermore, the design and implementation of turbine governors are integral aspects of engineering education and practice. Aspiring engineers study the principles behind these devices to understand how to design systems that are both effective and reliable. Practical experience with turbine governors can be gained through internships or projects in industries such as power generation, aerospace, and manufacturing. This hands-on experience is invaluable for understanding the complexities involved in turbine operation and control.In conclusion, the turbine governor is a fundamental component in the operation of turbines across various applications. Its ability to regulate speed and optimize performance makes it essential for safe and efficient energy production. As technology advances, the role of the turbine governor will continue to evolve, incorporating new innovations that enhance its functionality and effectiveness. Understanding this device not only provides insight into the workings of turbines but also highlights the broader significance of engineering solutions in addressing contemporary energy challenges.

“涡轮调速器”的概念在机械工程领域中至关重要，特别是在涡轮的操作和调节方面。涡轮调速器是一种自动调节涡轮速度的装置，通过调整供给涡轮的燃料或水流来实现。这一机制确保涡轮在指定的速度范围内运行，防止因超速而造成的潜在损坏。例如，在水电站中，涡轮调速器在管理涡轮的水流方面发挥着关键作用，从而在维持安全标准的同时优化发电。理解涡轮调速器的功能需要掌握基本的物理和工程原理。当涡轮发电时，它将流体（水、蒸汽或气体）的动能转化为机械能。然而，流体供应的波动可能导致速度的变化。如果没有调节系统，这些波动可能会导致涡轮运转过快，从而危及机械安全或降低能量生产效率。涡轮调速器通过持续监测涡轮的转速并实时调整输入流量来减轻这一风险。在现代应用中，涡轮调速器通常配备复杂的电子控制系统，以增强其响应能力和准确性。这些先进的调速器利用传感器和算法预测涡轮负荷的变化，并相应地调整输入。例如，如果电力需求增加，涡轮调速器会感知到这一变化并增加流向涡轮的水流，确保其满足需求而不超过安全操作限制。涡轮调速器的重要性不仅体现在性能方面；它在环境可持续性方面也具有重要意义。通过优化涡轮的运行，这些调节器有助于减少浪费，提高能源生产的效率。在可再生能源系统（如风能或水能）中，高效的涡轮运行对于最大限度地提高产出、最小化生态影响至关重要。因此，涡轮调速器不仅提高了操作效率，还促进了可持续能源实践。此外，涡轮调速器的设计和实施是工程教育和实践的核心内容。未来的工程师学习这些设备背后的原理，以了解如何设计既有效又可靠的系统。通过实习或参与电力生成、航空航天和制造等行业的项目，可以获得与涡轮调速器相关的实践经验。这种实践经验对于理解涡轮操作和控制中的复杂性是非常宝贵的。总之，涡轮调速器是各种应用中涡轮操作的基本组成部分。它调节速度和优化性能的能力使其成为安全和高效能源生产的必要条件。随着技术的进步，涡轮调速器的角色将继续演变，融入增强其功能和有效性的创新。理解这一装置不仅提供了对涡轮工作原理的深入了解，也突显了工程解决方案在应对当代能源挑战中的广泛意义。