turbine oupput

简明释义

涡轮机功率

英英释义

例句

1.A sudden drop in turbine output 涡轮机输出 can indicate a mechanical failure.

涡轮机输出的突然下降可能表明机械故障。

2.Regular maintenance is essential to maintain stable turbine output 涡轮机输出 levels.

定期维护对于保持稳定的turbine output 涡轮机输出水平至关重要。

3.The engineer monitored the turbine output 涡轮机输出 to ensure it met the required specifications.

工程师监控了turbine output 涡轮机输出以确保其符合所需规格。

4.During testing, the team recorded the turbine output 涡轮机输出 at various speeds.

在测试期间，团队记录了不同速度下的turbine output 涡轮机输出。

5.The power plant's turbine output 涡轮机输出 was optimized for maximum efficiency.

发电厂的turbine output 涡轮机输出已优化以达到最大效率。

作文

The efficiency of energy production in modern power plants is often measured by the turbine output, which refers to the amount of electrical power generated by a turbine. In essence, the turbine output is crucial for determining how effectively a power plant converts mechanical energy into electrical energy. This process typically involves converting steam, water, or gas into rotational energy that spins the turbine blades. As the blades turn, they drive a generator that produces electricity, making the turbine output a key factor in the overall performance of the plant.One of the primary factors affecting turbine output is the type of fuel used. For instance, natural gas turbines tend to have higher efficiencies compared to coal-fired turbines. This is due to the cleaner combustion process and the ability to achieve higher operating temperatures in gas turbines. Additionally, advancements in technology have led to the development of combined cycle power plants, where the waste heat from gas turbines is used to generate steam for steam turbines, thus increasing the overall turbine output of the facility.Moreover, environmental considerations have also influenced the design and operation of turbines. Regulations aimed at reducing carbon emissions have prompted many power plants to invest in more efficient turbine technologies. For example, the implementation of carbon capture and storage (CCS) systems can help mitigate the environmental impact while maintaining a substantial turbine output. These innovations not only contribute to sustainability but also ensure that power plants remain competitive in an increasingly eco-conscious market.In addition to fuel type and technological advancements, operational practices play a significant role in maximizing turbine output. Regular maintenance and monitoring of turbine performance are essential to prevent inefficiencies caused by wear and tear. Operators must ensure that all components, such as bearings and seals, are functioning optimally to maintain high levels of output. Furthermore, predictive maintenance using data analytics can help identify potential issues before they lead to failures, thus ensuring consistent turbine output over time.As the world moves towards renewable energy sources, the concept of turbine output is also evolving. Wind and hydroelectric power generation rely heavily on turbines, and understanding their output is vital for integrating these sources into the broader energy grid. For instance, wind turbines must be strategically placed to maximize their turbine output based on wind patterns and geographic conditions. Similarly, hydroelectric plants must consider water flow rates and reservoir levels to optimize their output.In conclusion, the turbine output is a fundamental aspect of energy production that encompasses various factors, including fuel type, technology, operational practices, and renewable energy integration. As energy demands continue to rise, optimizing turbine output will be crucial for ensuring reliable and sustainable power generation. The future of energy production will likely see continued innovations aimed at enhancing turbine output, allowing us to meet our energy needs while minimizing environmental impacts.

现代发电厂的能量生产效率通常通过涡轮输出来衡量，指的是涡轮发电的电力数量。实际上，涡轮输出对于确定发电厂将机械能转化为电能的有效性至关重要。这个过程通常涉及将蒸汽、水或气体转化为旋转能量，旋转涡轮叶片。当叶片旋转时，它们驱动发电机产生电力，因此，涡轮输出是整个工厂性能的关键因素。影响涡轮输出的主要因素之一是所使用的燃料类型。例如，天然气涡轮的效率往往高于煤炭涡轮。这是由于更清洁的燃烧过程和在燃气涡轮中能够达到更高的操作温度。此外，技术的进步导致了联合循环发电厂的发展，其中燃气涡轮的废热被用来产生蒸汽以驱动蒸汽涡轮，从而提高设施的整体涡轮输出。此外，环境考虑也影响了涡轮的设计和运行。旨在减少碳排放的法规促使许多发电厂投资于更高效的涡轮技术。例如，实施碳捕集与储存（CCS）系统可以帮助减轻环境影响，同时保持可观的涡轮输出。这些创新不仅有助于可持续发展，还确保发电厂在日益关注生态的市场中保持竞争力。除了燃料类型和技术进步，操作实践在最大化涡轮输出方面也发挥着重要作用。定期维护和监测涡轮性能对于防止因磨损造成的低效率至关重要。操作人员必须确保所有组件，如轴承和密封件，正常运作，以维持高水平的输出。此外，利用数据分析进行预测性维护可以帮助在问题导致故障之前识别潜在问题，从而确保持续的涡轮输出。随着世界向可再生能源来源转型，涡轮输出的概念也在不断演变。风能和水电发电在很大程度上依赖涡轮，理解它们的输出对于将这些来源整合到更广泛的能源网络中至关重要。例如，风力涡轮必须根据风的模式和地理条件战略性地布置，以最大化其涡轮输出。同样，水电厂必须考虑水流速和水库水位，以优化其输出。总之，涡轮输出是能源生产的基本方面，涵盖了多种因素，包括燃料类型、技术、操作实践和可再生能源整合。随着能源需求的持续增长，优化涡轮输出对于确保可靠和可持续的电力生产至关重要。未来的能源生产可能会继续看到旨在增强涡轮输出的创新，使我们能够满足能源需求，同时最小化环境影响。