mean blade width ratio

简明释义

平均叶宽比

英英释义

例句

1.The engineer calculated the mean blade width ratio 刀片平均宽度比 to optimize the turbine's efficiency.

工程师计算了刀片平均宽度比以优化涡轮的效率。

2.In our study, we found that the mean blade width ratio 刀片平均宽度比 significantly affects the airflow.

在我们的研究中，我们发现刀片平均宽度比显著影响气流。

3.A higher mean blade width ratio 刀片平均宽度比 can lead to better performance in cutting operations.

更高的刀片平均宽度比可以提高切割操作的性能。

4.To ensure safety, we must monitor the mean blade width ratio 刀片平均宽度比 during operation.

为了确保安全，我们必须在操作期间监测刀片平均宽度比。

5.The mean blade width ratio 刀片平均宽度比 is crucial for determining the cutting depth in machining.

在加工中，刀片平均宽度比对确定切削深度至关重要。

作文

The efficiency of wind turbines is a crucial factor in harnessing renewable energy. One of the key metrics used to evaluate the performance of a turbine is the mean blade width ratio, which refers to the average width of the blades in relation to their length. This ratio plays a significant role in determining how much wind energy can be captured and converted into electrical energy. A well-designed blade with an optimal mean blade width ratio can maximize the aerodynamic efficiency, allowing the turbine to generate more power even at lower wind speeds.Understanding the mean blade width ratio is essential for engineers and designers who work on improving turbine technology. The ratio affects not only the energy output but also the structural integrity of the blades. If the blades are too wide, they may experience increased drag, leading to inefficiencies. Conversely, if they are too narrow, they may not capture enough wind, resulting in lower energy production. Therefore, finding the right balance is key.In recent years, advancements in materials and design techniques have allowed for more innovative approaches to optimizing the mean blade width ratio. For instance, the use of lightweight composite materials can enable engineers to design blades that are both wider and longer without compromising strength. This innovation has led to significant improvements in turbine performance, making them more competitive with traditional energy sources.Moreover, the mean blade width ratio is not a static value; it can vary depending on the specific application of the wind turbine. For example, offshore turbines, which are exposed to stronger winds and harsher conditions, may require a different blade design compared to onshore turbines. By analyzing the environmental factors and operational needs, engineers can adjust the mean blade width ratio accordingly to optimize performance.In conclusion, the mean blade width ratio is a vital parameter in the design and efficiency of wind turbines. Its influence on energy capture and overall turbine performance cannot be overstated. As the demand for renewable energy continues to grow, understanding and optimizing this ratio will be essential for the future of wind energy technology. Through ongoing research and development, we can look forward to even more efficient and powerful wind turbines that contribute to a sustainable energy future.

风力涡轮机的效率是利用可再生能源的关键因素之一。评估涡轮机性能的关键指标之一是平均叶片宽度比，它指的是叶片的平均宽度与其长度的比例。这个比率在决定能够捕获和转换多少风能为电能方面发挥着重要作用。设计良好的叶片具有最佳的平均叶片宽度比可以最大化空气动力学效率，使涡轮机即使在较低风速下也能产生更多的电力。理解平均叶片宽度比对于从事涡轮机技术改进的工程师和设计师来说至关重要。该比率不仅影响能量输出，还影响叶片的结构完整性。如果叶片太宽，它们可能会经历增加的阻力，从而导致效率降低。相反，如果叶片太窄，它们可能无法捕获足够的风，导致较低的能量生产。因此，找到合适的平衡是关键。近年来，材料和设计技术的进步使得优化平均叶片宽度比的创新方法成为可能。例如，使用轻质复合材料可以使工程师设计出既宽又长的叶片，而不影响强度。这一创新带来了涡轮机性能的显著改善，使其在与传统能源源竞争时更具优势。此外，平均叶片宽度比并不是一个静态值；它可以根据风力涡轮机的具体应用而有所不同。例如，暴露于更强风力和更恶劣条件下的海上涡轮机，可能需要与陆上涡轮机不同的叶片设计。通过分析环境因素和操作需求，工程师可以相应地调整平均叶片宽度比以优化性能。总之，平均叶片宽度比是风力涡轮机设计和效率的一个重要参数。它对能量捕获和涡轮机整体性能的影响不容小觑。随着对可再生能源需求的不断增长，理解和优化这一比率将对未来风能技术的发展至关重要。通过持续的研究和开发，我们可以期待更高效、更强大的风力涡轮机，为可持续能源的未来做出贡献。