impulse blading

简明释义

冲动式叶片组

英英释义

例句

1.The research focused on the advantages of impulse blading 冲击叶片 in steam turbines.

研究集中在impulse blading 冲击叶片在蒸汽涡轮中的优势。

2.In the design phase, we considered impulse blading 冲击叶片 for better performance in high-speed applications.

在设计阶段，我们考虑了impulse blading 冲击叶片以便在高速应用中获得更好的性能。

3.The engineer explained how impulse blading 冲击叶片 improves turbine efficiency.

工程师解释了如何通过impulse blading 冲击叶片来提高涡轮效率。

4.Manufacturers are increasingly adopting impulse blading 冲击叶片 technology to enhance energy conversion.

制造商越来越多地采用impulse blading 冲击叶片技术以增强能量转换。

5.The efficiency gains from impulse blading 冲击叶片 can significantly reduce operational costs.

来自impulse blading 冲击叶片的效率提升可以显著降低运营成本。

作文

In the field of engineering, particularly in the design of turbines and other fluid machinery, the concept of impulse blading plays a crucial role. Impulse blading refers to a method used in turbines where the fluid, usually steam or water, is directed onto blades that convert the fluid's kinetic energy into mechanical energy. This process is essential for the efficient operation of machines like steam turbines, gas turbines, and hydraulic turbines.The principle behind impulse blading is relatively straightforward. When high-speed fluid strikes the blades, it causes them to rotate, which in turn drives a generator or performs mechanical work. The design of these blades is critical; they must be shaped to maximize the conversion of fluid energy while minimizing losses due to turbulence and friction. Engineers often utilize computational fluid dynamics (CFD) simulations to optimize blade shapes and angles, ensuring that they can handle the pressures and velocities involved without failing.One of the key advantages of impulse blading is its ability to operate efficiently across a range of conditions. For example, in steam turbines, the steam expands as it passes through the turbine stages, and the impulse blades are designed to take advantage of this expansion. As the steam moves through the turbine, it loses pressure and temperature, but the impulse blading system ensures that the mechanical energy extracted remains high. This adaptability makes impulse blading an essential consideration for engineers working on renewable energy projects, such as hydroelectric dams, where water flow can vary significantly.Moreover, impulse blading is not limited to large-scale power generation. It is also applicable in smaller systems, such as micro-turbines used in residential applications. These smaller systems benefit from the same principles of efficiency and energy conversion that larger turbines utilize. As the demand for sustainable energy solutions grows, understanding and applying impulse blading technology becomes increasingly important.In summary, impulse blading is a fundamental concept in turbine design and fluid mechanics. It allows for the efficient conversion of fluid energy into mechanical energy, with applications ranging from large power plants to small residential systems. As technology advances and the need for efficient energy solutions grows, the significance of impulse blading will continue to expand, highlighting the importance of engineering innovation in our quest for sustainable energy sources.

在工程领域，特别是在涡轮机和其他流体机械的设计中，冲击叶片的概念起着至关重要的作用。冲击叶片指的是一种用于涡轮机的方法，其中流体（通常是蒸汽或水）被引导到叶片上，这些叶片将流体的动能转化为机械能。这个过程对于蒸汽涡轮、燃气涡轮和水力涡轮等机器的高效运行至关重要。冲击叶片背后的原理相对简单。当高速流体撞击叶片时，会导致它们旋转，从而驱动发电机或执行机械工作。这些叶片的设计至关重要；它们必须被塑造成最大限度地提高流体能量的转化，同时最小化由于湍流和摩擦造成的损失。工程师通常利用计算流体动力学（CFD）模拟来优化叶片的形状和角度，确保它们能够承受涉及的压力和速度而不会失效。冲击叶片的一个主要优点是它能够在各种条件下高效运行。例如，在蒸汽涡轮中，蒸汽在通过涡轮阶段时会膨胀，而冲击叶片则设计成利用这种膨胀。随着蒸汽通过涡轮流动，它会失去压力和温度，但冲击叶片系统确保提取的机械能保持较高。这种适应性使得冲击叶片成为工程师在可再生能源项目（如水电大坝）中考虑的重要因素，因为水流可能会有显著变化。此外，冲击叶片不仅限于大规模发电。它也适用于较小的系统，例如用于住宅应用的微型涡轮。这些较小的系统受益于与大型涡轮相同的效率和能量转化原理。随着对可持续能源解决方案需求的增长，理解和应用冲击叶片技术变得越来越重要。总之，冲击叶片是涡轮设计和流体力学中的一个基本概念。它允许有效地将流体能量转化为机械能，应用范围从大型发电厂到小型住宅系统。随着技术进步和对高效能源解决方案需求的增长，冲击叶片的重要性将继续扩大，突显出工程创新在我们追求可持续能源源过程中的重要性。