tangential-flow turbine

简明释义

切向流动式涡轮机

英英释义

例句

1.The efficiency of the tangential-flow turbine 切向流涡轮 is significantly higher compared to traditional turbines in certain applications.

在某些应用中，切向流涡轮的效率显著高于传统涡轮。

2.Engineers often prefer using a tangential-flow turbine 切向流涡轮 for water treatment processes due to its effective energy conversion.

工程师通常更喜欢在水处理过程中使用切向流涡轮，因为它有效的能量转换。

3.The design of the tangential-flow turbine 切向流涡轮 allows for better flow characteristics, reducing cavitation risks.

切向流涡轮的设计允许更好的流动特性，从而减少气蚀风险。

4.Research indicates that a tangential-flow turbine 切向流涡轮 can operate efficiently at varying flow rates.

研究表明，切向流涡轮可以在不同流量下高效运行。

5.In hydroelectric plants, the tangential-flow turbine 切向流涡轮 can help maximize power output from low-head sites.

在水电站中，切向流涡轮可以帮助最大化低水头场所的发电量。

作文

The world of renewable energy is constantly evolving, and among the various technologies that have emerged, the tangential-flow turbine stands out as a remarkable innovation. This type of turbine is designed to harness the kinetic energy of flowing fluids, converting it into mechanical energy that can be utilized for various applications. Understanding the tangential-flow turbine is crucial for anyone interested in sustainable energy solutions. Firstly, let us delve into the working principle of the tangential-flow turbine. Unlike traditional turbines that operate on axial flow principles, the tangential-flow turbine utilizes the tangential component of fluid velocity. This means that the fluid enters the turbine at an angle, creating a rotational motion that drives the turbine blades. The design allows for a more efficient energy extraction from the fluid, making it suitable for applications where space is limited or where high flow rates are present. One of the most significant advantages of the tangential-flow turbine is its efficiency in low-head hydroelectric applications. In many regions, particularly in developing countries, there are numerous small rivers and streams that could generate power but lack the height necessary for conventional turbines to function effectively. The tangential-flow turbine can operate efficiently in these low-head scenarios, providing a viable solution for rural electrification and sustainable energy generation. Moreover, the tangential-flow turbine is not only limited to hydroelectric power generation. It has found applications in various industries, including wastewater treatment plants, where it can be used to generate energy from the flow of treated water. By integrating the tangential-flow turbine into existing systems, facilities can reduce their energy costs and minimize their environmental impact. In addition to its versatility, the tangential-flow turbine is relatively easy to maintain. Its simple design means fewer moving parts compared to other types of turbines, which translates to lower maintenance costs and reduced downtime. This aspect is particularly beneficial for remote areas where access to skilled technicians may be limited. However, it is essential to acknowledge the challenges associated with the tangential-flow turbine. While it is efficient in specific applications, its performance can be affected by variations in fluid density and flow rate. Engineers must carefully consider these factors when designing systems that incorporate this technology. In conclusion, the tangential-flow turbine represents a significant advancement in the field of renewable energy. Its ability to efficiently convert the kinetic energy of flowing fluids into usable mechanical energy makes it a valuable asset in both hydroelectric power generation and industrial applications. As we continue to seek sustainable solutions to our energy needs, the tangential-flow turbine will undoubtedly play a critical role in shaping the future of renewable energy technologies.

可再生能源的世界正在不断发展，而在各种新兴技术中，切向流涡轮机作为一项卓越的创新脱颖而出。这种类型的涡轮机旨在利用流体的动能，将其转化为可用于各种应用的机械能。理解切向流涡轮机对于任何对可持续能源解决方案感兴趣的人来说都是至关重要的。首先，让我们深入了解切向流涡轮机的工作原理。与基于轴向流动原理的传统涡轮机不同，切向流涡轮机利用流体速度的切向分量。这意味着流体以一定角度进入涡轮机，产生驱动涡轮叶片的旋转运动。这种设计允许从流体中更有效地提取能量，使其适合于空间有限或流量较大的应用场景。切向流涡轮机最显著的优势之一是它在低水头水电应用中的效率。在许多地区，特别是在发展中国家，有许多小河流和溪流可以发电，但缺乏传统涡轮机有效运作所需的高度。切向流涡轮机能够在这些低水头场景中高效运作，为农村电气化和可持续能源生成提供了可行的解决方案。此外，切向流涡轮机并不仅限于水电发电。它已在各个行业找到应用，包括废水处理厂，在这些地方可以利用处理水的流动来发电。通过将切向流涡轮机集成到现有系统中，设施可以降低能源成本并减少环境影响。除了其多功能性，切向流涡轮机的维护相对简单。它的简单设计意味着相比其他类型的涡轮机，运动部件更少，这转化为更低的维护成本和更少的停机时间。这一点对于偏远地区尤其有利，因为这些地方的技术人员可能难以获得。然而，必须承认与切向流涡轮机相关的挑战。尽管它在特定应用中高效，但其性能可能受到流体密度和流量变化的影响。工程师在设计集成这种技术的系统时必须仔细考虑这些因素。总之，切向流涡轮机代表了可再生能源领域的重要进展。它能够有效地将流动流体的动能转化为可用的机械能，使其在水电发电和工业应用中成为宝贵的资产。随着我们继续寻求可持续的能源解决方案，切向流涡轮机无疑将在塑造可再生能源技术的未来中发挥关键作用。