flywheel synchronization

简明释义

飞轮同步

英英释义

例句

1.The team focused on improving flywheel synchronization 飞轮同步 to enhance the overall performance of the hybrid vehicle.

团队专注于改善飞轮同步 飞轮同步 以提高混合动力汽车的整体性能。

2.Proper flywheel synchronization 飞轮同步 is critical for maintaining the stability of the power grid during peak loads.

在高峰负载期间，适当的飞轮同步 飞轮同步 对于维持电网的稳定性至关重要。

3.The engineers conducted a test to ensure the flywheel synchronization 飞轮同步 was functioning correctly before launching the new engine.

工程师们进行了测试，以确保新的发动机在启动前飞轮同步 飞轮同步 正常运行。

4.In wind turbines, flywheel synchronization 飞轮同步 helps to smooth out fluctuations in energy production.

在风力涡轮机中，飞轮同步 飞轮同步 有助于平滑能源生产中的波动。

5.The software update included algorithms to optimize flywheel synchronization 飞轮同步 for better efficiency.

软件更新包含优化飞轮同步 飞轮同步 的算法，以提高效率。

作文

In the world of engineering and mechanics, the concept of a flywheel is pivotal. A flywheel is a mechanical device that stores rotational energy. It is typically used to maintain consistent energy output in engines and other machinery. One of the most critical aspects of utilizing a flywheel effectively is achieving flywheel synchronization, which refers to the process of aligning the rotational speeds and phases of multiple flywheels within a system. This synchronization is essential for optimizing performance and efficiency in various applications.The importance of flywheel synchronization cannot be overstated. In industrial settings, machines often rely on multiple flywheels to manage energy supply and demand. When these flywheels are synchronized, they can work together seamlessly, reducing vibrations and improving stability. This not only enhances the lifespan of the machinery but also ensures that energy is used efficiently, minimizing waste.Moreover, flywheel synchronization plays a crucial role in renewable energy systems, such as wind turbines and solar power plants. These systems often incorporate flywheels to store excess energy generated during peak production times. By synchronizing the flywheels, operators can ensure that energy is released smoothly and consistently, matching the grid's demand. This capability is vital for maintaining a stable energy supply, especially when dealing with the intermittent nature of renewable resources.In the automotive industry, flywheel synchronization is integral to hybrid and electric vehicles. These vehicles utilize flywheels to capture and store energy during braking, which can then be released to assist with acceleration. For optimal performance, the flywheels must be synchronized with the vehicle's electric motor and battery system. This synchronization allows for a smoother transition between energy sources, improving fuel efficiency and reducing emissions.Achieving flywheel synchronization involves sophisticated control systems and algorithms that monitor the speed and position of each flywheel in real-time. Engineers use advanced sensors and feedback mechanisms to ensure that all flywheels operate in harmony. This technology is continually evolving, with innovations aimed at enhancing precision and responsiveness in synchronization processes.In conclusion, flywheel synchronization is a fundamental principle in various engineering applications, from industrial machinery to renewable energy systems and automotive technology. Its significance lies in its ability to optimize energy efficiency, enhance stability, and improve overall performance. As technology progresses, the methods and systems for achieving synchronization will likely become even more advanced, paving the way for more efficient and sustainable energy solutions across multiple industries.

在工程和机械的世界中，飞轮的概念至关重要。飞轮是一种储存旋转能量的机械装置，通常用于维持发动机和其他机械的稳定能量输出。实现飞轮同步的过程，即对多个飞轮的旋转速度和相位进行对齐，是有效利用飞轮的关键方面。这种同步对于优化各种应用中的性能和效率至关重要。飞轮同步的重要性不容小觑。在工业环境中，机器往往依赖多个飞轮来管理能量的供需。当这些飞轮同步时，它们能够无缝协作，减少振动并改善稳定性。这不仅增强了机械的使用寿命，还确保能量的高效利用，最小化浪费。此外，飞轮同步在可再生能源系统中也发挥着至关重要的作用，例如风力涡轮机和太阳能发电厂。这些系统通常结合飞轮来储存在高峰生产期间产生的多余能量。通过同步飞轮，操作人员可以确保能量平稳、一致地释放，以匹配电网的需求。这种能力对于维持稳定的能源供应至关重要，尤其是在处理可再生资源间歇性特性的情况下。在汽车行业中，飞轮同步是混合动力和电动车辆的核心。此类车辆利用飞轮在制动过程中捕获和储存能量，然后在加速时释放。为了实现最佳性能，飞轮必须与车辆的电动机和电池系统同步。这种同步允许在能源源之间实现更平滑的过渡，从而提高燃油效率并减少排放。实现飞轮同步需要复杂的控制系统和算法，实时监测每个飞轮的速度和位置。工程师使用先进的传感器和反馈机制，以确保所有飞轮和谐运转。这项技术正在不断发展，创新旨在提高同步过程中的精度和响应能力。总之，飞轮同步是各种工程应用中的基本原则，从工业机械到可再生能源系统，再到汽车技术。其重要性在于其优化能效、增强稳定性和改善整体性能的能力。随着技术的进步，实现同步的方法和系统可能会变得更加先进，为多个行业提供更高效和可持续的能源解决方案。