turbogenerator

简明释义

英[ˌtɜrboʊˈdʒɛnəˌreɪtər]美[ˌtɜrboʊˈdʒɛnəˌreɪtər]

n. 涡轮式发电机

英英释义

单词用法

同义词

反义词

例句

1.A finite element method is presented for the calculating natural frequency of turbogenerator stator end windings.

本文提出一种计算汽轮发电机定子绕组端部振动固有频率的有限元方法。

2.In this paper a macro-cracking in the medium casing which is a heavy section casting of 261 turbogenerator was investigated by SEM, EDAX and others.

采用扫描电镜断口分析、微区能谱分析等方法研究了261汽轮机中汽缸大型铸件开裂问题。

3.Often serves as the low power water turbogenerator.

常用作小功率水轮发电机。

4.Solid particle erosion may damage the turbogenerator sets.

固体颗粒磨蚀对汽轮机的危害不可忽视。

5.The technique and its principle of high temperature strain measurement are introduced to determine heat sleeve stress about rotor retaining ring of large turbogenerator.

本文简要介绍了高温应变测量原理和技术在大型汽轮发电机转子护环热套应力测试中的成功应用。

6.In the process of torsional vibration analysis for turbogenerator rotors, the material characteristics parameters of shafts are often considered to be constant.

在进行汽轮发电机组轴系扭振分析时，通常假设轴系材料特性参数为常数。

7.The noise level of turbogenerator can be effectively controlled after its vibration level is reduced.

通过对汽轮发电机组进行减振改进后，机组的噪声都得到有效的控制。

8.Nonlinear control method with objective holographic feedbacks (NCOHF) is applied to the coordinated control problem of large turbogenerator set in this paper.

应用目标全息反馈法(NCOHF)来处理大型汽轮发电机组的非线性综合控制问题。

9.In this paper the structure and operation of a static excitation system which was imported form Italy for320MW turbogenerator set are presented.

本文介绍了从意大利引进的320 MW燃煤机组静态励磁系统的结构特点和运行情况。

10.A modern turbogenerator can produce up to 100 megawatts of power.

现代的涡轮发电机可以产生高达100兆瓦的电力。

11.The turbogenerator is essential for generating electricity in hydroelectric plants.

涡轮发电机在水电站中是发电的关键设备。

12.During maintenance, the technicians inspected the turbogenerator for any signs of wear.

在维护期间，技术人员检查了涡轮发电机是否有磨损迹象。

13.The power plant uses a turbogenerator to convert steam energy into electricity.

发电厂使用涡轮发电机将蒸汽能转换为电能。

14.Engineers are optimizing the efficiency of the turbogenerator for better performance.

工程师们正在优化涡轮发电机的效率，以提高性能。

作文

In today's world, where energy demands are constantly rising, the importance of efficient power generation cannot be overstated. One of the key technologies that has significantly contributed to this field is the turbogenerator. A turbogenerator is a device that converts mechanical energy into electrical energy by using a turbine. This technology is widely used in various power plants, including thermal, hydroelectric, and nuclear facilities.The basic principle behind a turbogenerator involves harnessing the kinetic energy from moving fluids, such as steam or water, to rotate a turbine. As the turbine spins, it drives a generator that produces electricity. This process is not only efficient but also scalable, making it suitable for both large power plants and smaller applications.One of the most common types of turbogenerator is found in thermal power plants, where fossil fuels like coal, oil, or natural gas are burned to create steam. The steam then drives the turbine connected to the generator. This method has been the backbone of electricity generation for decades, providing a reliable source of power to millions of households and industries.On the other hand, hydroelectric power plants utilize the potential energy of water stored in reservoirs. When released, this water flows through turbines, effectively converting its gravitational potential into mechanical energy, which is then transformed into electrical energy via a turbogenerator. This renewable energy source is one of the cleanest forms of power generation, contributing to a more sustainable future.Nuclear power plants also rely on turbogenerators to produce electricity. In these facilities, nuclear reactions generate heat, which is used to produce steam. The steam rotates the turbine, just like in thermal and hydroelectric plants. Nuclear energy is known for its low greenhouse gas emissions, making it an attractive option in the fight against climate change.However, while turbogenerators have many advantages, they also come with challenges. For instance, thermal power generation is often criticized for its environmental impact, particularly in terms of carbon emissions and pollution. Additionally, the construction and maintenance of turbogenerator systems can be costly and complex, requiring skilled labor and advanced technology.Despite these challenges, the future of turbogenerators looks promising. Innovations in technology are leading to more efficient designs that minimize waste and maximize output. Furthermore, as the world shifts towards greener energy solutions, the integration of turbogenerators with renewable energy sources, such as wind and solar, is becoming increasingly common. This hybrid approach not only enhances energy security but also reduces reliance on fossil fuels.In conclusion, the turbogenerator plays a vital role in modern power generation. Its ability to efficiently convert mechanical energy into electrical energy has made it an indispensable component of various power plants. As we continue to explore new energy sources and strive for sustainability, the evolution of turbogenerators will undoubtedly remain at the forefront of the energy sector. By embracing advancements in this technology, we can work towards a cleaner, more efficient, and sustainable energy future.

在当今世界，能源需求不断上升，效率高的发电技术显得尤为重要。其中一种显著贡献于这一领域的关键技术就是涡轮发电机。涡轮发电机是一种利用涡轮将机械能转换为电能的设备。这项技术广泛应用于各种发电厂，包括热电、水电和核电设施。涡轮发电机的基本原理是利用流体（如蒸汽或水）的动能来旋转涡轮。当涡轮旋转时，它驱动连接到发电机的装置，从而产生电力。这一过程不仅高效，而且可扩展，适用于大型发电厂和小型应用。在热电厂中，最常见的涡轮发电机是利用煤、石油或天然气等化石燃料燃烧产生蒸汽。蒸汽驱动与发电机连接的涡轮。这种方法数十年来一直是电力生成的支柱，为数百万家庭和工业提供可靠的电力来源。另一方面，水电站利用储存在水库中的水的势能。当水释放时，它通过涡轮流动，有效地将其重力势能转化为机械能，然后通过涡轮发电机转化为电能。这种可再生能源是最清洁的发电形式之一，有助于实现更加可持续的未来。核电厂也依赖于涡轮发电机来发电。在这些设施中，核反应产生的热量用于产生蒸汽。蒸汽旋转涡轮，就像在热电和水电厂中一样。核能以其低温室气体排放而闻名，使其在应对气候变化的斗争中成为一个有吸引力的选择。然而，尽管涡轮发电机有许多优点，但它们也面临挑战。例如，热电发电常因其环境影响而受到批评，尤其是在碳排放和污染方面。此外，涡轮发电机系统的建设和维护可能成本高昂且复杂，需要熟练的劳动力和先进的技术。尽管面临这些挑战，涡轮发电机的未来看起来很有希望。技术创新正在导致更高效的设计，最大限度地减少浪费并提高输出。此外，随着全球向绿色能源解决方案的转变，涡轮发电机与可再生能源（如风能和太阳能）的整合正变得越来越普遍。这种混合方法不仅增强了能源安全性，还减少了对化石燃料的依赖。总之，涡轮发电机在现代发电中发挥着至关重要的作用。它高效地将机械能转换为电能的能力使其成为各种发电厂不可或缺的组成部分。随着我们继续探索新的能源来源并努力实现可持续发展，涡轮发电机的演变无疑将继续处于能源行业的前沿。通过拥抱这一技术的进步，我们可以朝着更清洁、更高效和更可持续的能源未来迈进。