power plant maneuverability

简明释义

动力装置操纵性

英英释义

例句

1.Regulatory changes may require improvements in power plant maneuverability to comply with new standards.

监管变化可能要求改善电厂机动性以符合新标准。

2.Engineers are focusing on enhancing power plant maneuverability to better respond to fluctuating energy demands.

工程师们专注于提升电厂机动性，以更好地应对波动的能源需求。

3.The new design improves power plant maneuverability significantly, allowing for quicker adjustments during peak demand.

新设计显著提高了电厂机动性，使得在高峰需求期间可以更快地进行调整。

4.Investing in modern technology enhances power plant maneuverability and increases efficiency.

投资现代技术提升了电厂机动性并提高了效率。

5.The simulation showed that increased power plant maneuverability could reduce operational costs.

模拟显示，增强的电厂机动性可以降低运营成本。

作文

In the modern world, energy production is a vital component of our daily lives. As we continue to rely on various sources of energy, the efficiency and effectiveness of these energy sources become increasingly important. One concept that has emerged in recent years is power plant maneuverability, which refers to the ability of a power plant to adjust its output quickly and efficiently in response to changes in demand or supply conditions. This capability is essential for maintaining grid stability and ensuring a reliable energy supply.The significance of power plant maneuverability can be observed in the context of renewable energy integration. As more countries transition to renewable sources like wind and solar power, the variability of these resources presents challenges for traditional power plants. For instance, solar energy generation peaks during sunny days but drops significantly at night or during cloudy weather. Similarly, wind energy can fluctuate based on weather conditions. Therefore, power plants must possess the flexibility to ramp up or down their output to balance the grid effectively.Moreover, power plant maneuverability plays a crucial role in reducing greenhouse gas emissions. By enabling power plants to respond swiftly to fluctuations in renewable energy generation, we can minimize the need for fossil fuel-based backup generation. This adaptability allows for a cleaner energy mix and contributes to global efforts aimed at combating climate change. In this sense, enhancing the maneuverability of power plants is not just an operational concern but also an environmental imperative.Technological advancements have significantly improved the power plant maneuverability of both traditional and renewable energy systems. For example, combined cycle gas turbine (CCGT) plants are designed to operate efficiently at varying loads, making them ideal for supporting intermittent renewable sources. These plants can quickly adjust their output, providing the necessary backup when renewable generation is low. Additionally, advancements in battery storage technology allow for the storage of excess energy generated during peak production times, which can then be released when demand increases, further enhancing the overall maneuverability of the power system.Furthermore, regulatory frameworks and market structures are evolving to support enhanced power plant maneuverability. Many regions are implementing policies that incentivize flexible generation and energy storage solutions. By creating a market environment that values rapid response capabilities, utilities and power producers are encouraged to invest in technologies that enhance their operational flexibility.In conclusion, power plant maneuverability is a critical factor in the future of energy production. As we strive towards a more sustainable energy landscape, the ability of power plants to adapt to changing conditions will determine the reliability and efficiency of our energy systems. With ongoing technological innovations and supportive policies, we can expect to see significant improvements in the maneuverability of power plants, paving the way for a cleaner and more resilient energy future.

在现代世界中，能源生产是我们日常生活的重要组成部分。随着我们继续依赖各种能源来源，这些能源的效率和有效性变得越来越重要。近年来出现的一个概念是电厂机动性，它指的是电厂快速而有效地调整其输出以应对需求或供应条件变化的能力。这种能力对于维护电网稳定性和确保可靠的能源供应至关重要。电厂机动性的重要性可以在可再生能源整合的背景下观察到。随着越来越多的国家过渡到风能和太阳能等可再生能源，这些资源的变异性给传统电厂带来了挑战。例如，太阳能发电在晴天达到峰值，但在夜间或多云天气时显著下降。同样，风能也可能根据天气条件波动。因此，电厂必须具备灵活性，以便有效地提高或降低其输出，以平衡电网。此外，电厂机动性在减少温室气体排放方面也发挥着至关重要的作用。通过使电厂能够快速响应可再生能源发电的波动，我们可以最小化对基于化石燃料的备用发电的需求。这种适应性允许更清洁的能源组合，并有助于全球应对气候变化的努力。从这个意义上说，提高电厂的机动性不仅是一个操作问题，也是一个环境问题。技术进步显著提高了传统和可再生能源系统的电厂机动性。例如，联合循环燃气轮机（CCGT）电厂被设计为在不同负载下高效运行，使其成为支持间歇性可再生能源的理想选择。这些电厂可以迅速调整其输出，在可再生发电低时提供必要的备用。此外，电池储存技术的进步允许在高峰生产时储存多余的能量，然后在需求增加时释放，从而进一步增强整体电力系统的机动性。此外，监管框架和市场结构正在演变，以支持增强的电厂机动性。许多地区正在实施政策，以激励灵活的发电和储能解决方案。通过创建一个重视快速响应能力的市场环境，公用事业和发电商被鼓励投资于提高其运营灵活性的技术。总之，电厂机动性是未来能源生产的关键因素。随着我们朝着更可持续的能源格局迈进，电厂适应变化条件的能力将决定我们能源系统的可靠性和效率。随着技术创新的不断推进和支持性政策的实施，我们可以期待看到电厂机动性的显著改善，为更清洁、更具韧性的能源未来铺平道路。