combined flow turbine

简明释义

混流式涡轮机

英英释义

例句

1.The research team published a paper on the advantages of using a combined flow turbine 组合流涡轮机 in tidal energy systems.

研究小组发表了一篇关于在潮汐能源系统中使用组合流涡轮机 combined flow turbine 优势的论文。

2.The combined flow turbine 组合流涡轮机 is ideal for applications where both axial and radial flow are present.

组合流涡轮机 combined flow turbine 非常适合存在轴向和径向流动的应用场景。

3.In offshore wind farms, the combined flow turbine 组合流涡轮机 can capture wind energy more effectively than traditional turbines.

在海上风电场中，组合流涡轮机 combined flow turbine 能比传统涡轮更有效地捕获风能。

4.The efficiency of the combined flow turbine 组合流涡轮机 significantly improves energy production in hydroelectric plants.

在水电站中，组合流涡轮机 combined flow turbine 的效率显著提高了能源生产。

5.Engineers are developing a new model of the combined flow turbine 组合流涡轮机 to enhance performance under varying flow conditions.

工程师们正在开发一种新型号的组合流涡轮机 combined flow turbine，以提高在不同流动条件下的性能。

作文

The development of renewable energy sources has become a critical focus in today's world, as nations strive to reduce their carbon footprints and combat climate change. Among the various technologies emerging in this field, the combined flow turbine stands out due to its efficiency and versatility. A combined flow turbine (复合流涡轮) is a type of turbine that utilizes both axial and radial flow principles to generate power. This innovative design allows for improved performance in a variety of applications, including hydroelectric plants and wind energy systems.One of the primary advantages of the combined flow turbine is its ability to operate effectively across a wide range of flow conditions. Traditional turbines often struggle with variable flow rates, which can lead to inefficiencies and reduced energy output. In contrast, the combined flow turbine is engineered to handle fluctuations in flow, making it an ideal choice for environments where water levels or wind speeds are inconsistent.Additionally, the design of the combined flow turbine allows for a more compact structure compared to conventional turbines. This compactness not only saves space but also reduces installation costs and makes it easier to integrate into existing infrastructures. For example, in urban areas where space is limited, the combined flow turbine can be installed in smaller facilities without compromising energy production capabilities.Another significant benefit of the combined flow turbine is its potential for higher efficiency rates. By harnessing both axial and radial flows, these turbines can extract more energy from the same amount of water or air compared to traditional designs. This increased efficiency translates to lower operational costs and a greater return on investment for energy producers.Moreover, the combined flow turbine is adaptable to various energy sources. Whether it is harnessing the kinetic energy of flowing water in rivers or capturing wind energy in coastal areas, this turbine can be customized to suit different environments and energy needs. This flexibility makes it a valuable asset in the transition towards sustainable energy solutions.However, it is essential to consider the challenges associated with the implementation of combined flow turbines. The initial research and development costs can be high, and there may be technical hurdles to overcome during the manufacturing process. Furthermore, as with any technology, ongoing maintenance and monitoring are crucial to ensure optimal performance and longevity.In conclusion, the combined flow turbine represents a promising advancement in the field of renewable energy. Its ability to efficiently harness energy from variable flow conditions, combined with its compact design and adaptability, positions it as a key player in the future of energy production. As we continue to seek ways to mitigate climate change and promote sustainability, innovations like the combined flow turbine will undoubtedly play a significant role in shaping our energy landscape for years to come.

可再生能源的开发已成为当今世界的关键焦点，各国努力减少碳足迹并应对气候变化。在这个领域中，出现了各种技术，其中复合流涡轮因其高效性和多功能性而脱颖而出。复合流涡轮是一种利用轴向和径向流动原理来发电的涡轮。这种创新设计使其在水电站和风能系统等多种应用中表现出色。复合流涡轮的主要优势之一是其在广泛流动条件下有效运行的能力。传统涡轮通常难以应对可变流速，这可能导致效率低下和能源输出减少。相比之下，复合流涡轮经过工程设计，可以处理流动波动，使其成为水位或风速不一致环境的理想选择。此外，复合流涡轮的设计相较于常规涡轮更加紧凑。这种紧凑性不仅节省空间，还降低了安装成本，并使其更容易集成到现有基础设施中。例如，在城市地区，空间有限的情况下，复合流涡轮可以在较小的设施中安装，而不会妨碍能源生产能力。复合流涡轮的另一个显著好处是其潜在的更高效率。通过同时利用轴向和径向流动，这些涡轮能够从相同数量的水或空气中提取比传统设计更多的能量。这种效率的提高转化为更低的运营成本和更高的投资回报率。此外，复合流涡轮还可以适应各种能源来源。无论是利用河流中流动水的动能，还是捕获沿海地区的风能，这种涡轮都可以根据不同环境和能源需求进行定制。这种灵活性使其成为向可持续能源解决方案过渡中的宝贵资产。然而，实施复合流涡轮时需要考虑相关挑战。初期的研发成本可能较高，在制造过程中也可能面临技术障碍。此外，像任何技术一样，持续的维护和监测对于确保最佳性能和延长使用寿命至关重要。总之，复合流涡轮代表了可再生能源领域的一项有前景的进展。它高效地利用可变流动条件的能力，加上其紧凑的设计和适应性，使其成为未来能源生产的重要参与者。随着我们继续寻求减缓气候变化和促进可持续发展的途径，像复合流涡轮这样的创新无疑将在塑造未来的能源格局中发挥重要作用。