full admission turbine

简明释义

全部进气透平

英英释义

例句

1.Using a full admission turbine can significantly reduce operational costs in energy production.

使用全进气涡轮可以显著降低能源生产中的运营成本。

2.The full admission turbine is often used in large-scale hydroelectric projects.

在大型水电项目中，常常使用全进气涡轮。

3.Engineers are studying the performance of the full admission turbine under varying load conditions.

工程师正在研究在不同负载条件下的全进气涡轮性能。

4.The design of the full admission turbine allows for maximum efficiency in power generation.

设计的全进气涡轮允许在发电中达到最大效率。

5.The efficiency of the full admission turbine makes it a popular choice for renewable energy applications.

由于全进气涡轮的高效率，它在可再生能源应用中非常受欢迎。

作文

The concept of a full admission turbine is pivotal in the field of fluid mechanics and thermodynamics, particularly in applications involving turbines and engines. To understand this term better, we must first explore what a turbine does. A turbine is a device that converts kinetic energy from a fluid into mechanical energy. This conversion process is essential in various industries, including power generation, aviation, and marine propulsion. A full admission turbine refers to a specific design where the entire flow area of the turbine is utilized for the incoming fluid, allowing for maximum efficiency and performance.In a typical turbine, the fluid enters through an inlet and passes through a series of blades that rotate to produce energy. However, not all turbine designs utilize the incoming fluid flow effectively. Some turbines may have restrictions or partial admission areas that limit the amount of fluid that can enter the turbine at once. This can lead to a decrease in efficiency and overall performance. In contrast, a full admission turbine is designed to allow the fluid to enter the turbine without any restrictions, ensuring that the maximum possible amount of energy is extracted from the fluid.One of the primary advantages of a full admission turbine is its ability to handle varying flow rates. In many applications, the fluid flow can fluctuate due to changes in operating conditions or demand. A turbine that can accommodate these variations without losing efficiency is highly desirable. The full admission design allows for a more uniform distribution of fluid across the blades, which helps maintain optimal performance even under changing conditions.Moreover, full admission turbines are often more resilient to cavitation, a phenomenon that occurs when vapor bubbles form in the fluid due to rapid changes in pressure. Cavitation can cause significant damage to turbine blades and reduce operational lifespan. By utilizing the full flow area, these turbines minimize the risk of cavitation, enhancing their durability and reliability.In addition to their mechanical advantages, full admission turbines also contribute to improved energy efficiency. In the context of energy production, maximizing the efficiency of turbines is crucial for reducing operational costs and environmental impact. By ensuring that the turbine operates at optimal conditions, energy losses can be minimized, leading to a more sustainable operation.Furthermore, the application of full admission turbine technology is not limited to traditional power generation. It has found its place in renewable energy sectors, such as wind and hydroelectric power. The principles of full admission design can be applied to enhance the performance of wind turbines and hydraulic turbines, making them more efficient and effective in harnessing natural energy sources.In conclusion, understanding the concept of a full admission turbine is essential for professionals in engineering and energy sectors. Its design allows for maximum fluid utilization, improved efficiency, and enhanced durability, making it a valuable asset in various applications. As the world continues to seek more efficient energy solutions, the role of full admission turbines will undoubtedly grow, paving the way for advancements in technology and sustainability.

“全进气涡轮”的概念在流体力学和热力学领域中至关重要，特别是在涉及涡轮机和发动机的应用中。要更好地理解这个术语，我们首先必须探索涡轮的作用。涡轮是一种将流体的动能转化为机械能的装置。这种转化过程在发电、航空和海洋推进等各种行业中都是必不可少的。“全进气涡轮”指的是一种特定设计，其中涡轮的整个流动区域都被用于进入的流体，从而实现最大的效率和性能。在典型的涡轮中，流体通过入口进入，并经过一系列旋转的叶片以产生能量。然而，并不是所有的涡轮设计都有效利用进入的流体流动。一些涡轮可能存在限制或部分进气区域，这限制了可以同时进入涡轮的流体量。这会导致效率和整体性能的降低。相比之下，“全进气涡轮”设计允许流体无任何限制地进入涡轮，确保从流体中提取最大可能的能量。“全进气涡轮”的主要优点之一是其处理变化流量的能力。在许多应用中，由于操作条件或需求的变化，流体流动可能会波动。能够在不降低效率的情况下适应这些变化的涡轮是非常理想的。全进气设计允许流体在叶片上均匀分布，这有助于在变化条件下保持最佳性能。此外，“全进气涡轮”通常对气蚀现象更具韧性，气蚀现象发生在由于压力快速变化而导致流体中形成蒸汽气泡时。气蚀会对涡轮叶片造成重大损害并减少操作寿命。通过利用整个流动区域，这些涡轮最小化了气蚀的风险，从而增强了它们的耐用性和可靠性。除了机械优势外，“全进气涡轮”还提高了能源效率。在能源生产的背景下，最大限度地提高涡轮效率对于降低运营成本和环境影响至关重要。通过确保涡轮在最佳条件下运行，可以最小化能源损失，从而实现更可持续的操作。此外，“全进气涡轮”技术的应用并不限于传统发电。它在可再生能源领域，如风能和水电，也找到了自己的位置。全进气设计的原理可以应用于提高风力涡轮和水力涡轮的性能，使它们在利用自然能源方面更加高效和有效。总之，理解“全进气涡轮”的概念对于工程和能源领域的专业人士至关重要。其设计允许最大流体利用、提高效率和增强耐用性，使其在各种应用中成为宝贵的资产。随着世界继续寻求更高效的能源解决方案，“全进气涡轮”的作用无疑会增长，为技术和可持续性的发展铺平道路。