direct-connected turbine

简明释义

直接传动式涡轮机

英英释义

例句

1.In this facility, the direct-connected turbine generates steam directly from the boiler.

在这个设施中，直接连接涡轮机直接从锅炉产生蒸汽。

2.During maintenance, the engineers checked the direct-connected turbine for any wear and tear.

在维护期间，工程师检查了直接连接涡轮机是否有任何磨损。

3.A direct-connected turbine can reduce energy losses compared to belt-driven systems.

与皮带驱动系统相比，直接连接涡轮机可以减少能量损失。

4.The power plant uses a direct-connected turbine to improve efficiency.

该发电厂使用直接连接涡轮机来提高效率。

5.The new design of the direct-connected turbine allows for easier installation.

新设计的直接连接涡轮机便于安装。

作文

The concept of a direct-connected turbine is essential in the field of mechanical engineering and energy production. A direct-connected turbine refers to a turbine that is directly coupled to a generator without the need for intermediate gearing or other mechanical components. This design simplifies the energy conversion process, making it more efficient and reliable. In recent years, the demand for efficient energy solutions has surged, leading to increased interest in technologies like the direct-connected turbine. One of the primary advantages of a direct-connected turbine is its efficiency. By eliminating the need for gears, which can introduce friction and mechanical losses, the system operates more smoothly. This direct connection allows for a higher percentage of the energy generated by the turbine to be converted into electrical energy. Consequently, power plants utilizing direct-connected turbines can achieve better performance metrics compared to traditional setups. Moreover, direct-connected turbines require less maintenance than their geared counterparts. Gears can wear out over time and require regular inspection and replacement, leading to increased operational costs. In contrast, the simpler design of direct-connected turbines reduces the number of moving parts, which inherently decreases the likelihood of mechanical failure. This reliability is particularly crucial in settings where continuous power generation is necessary, such as in hospitals or data centers. In addition to efficiency and maintenance benefits, direct-connected turbines also contribute to a reduction in the overall footprint of power generation systems. With fewer components required for operation, these systems can be more compact and easier to install. This is particularly advantageous in urban areas where space is at a premium. As cities continue to grow and the demand for energy increases, finding ways to generate power in limited spaces becomes increasingly important. Furthermore, the environmental impact of direct-connected turbines is often less than that of conventional turbines. Many direct-connected turbines are designed to operate using renewable energy sources, such as wind or hydroelectric power. By harnessing these sustainable resources, they help reduce reliance on fossil fuels and lower greenhouse gas emissions. This aligns with global efforts to combat climate change and promote cleaner energy alternatives. Despite their numerous advantages, direct-connected turbines are not without challenges. The initial investment for such systems can be significant, especially when considering the integration of advanced technology. However, the long-term savings on maintenance and operational costs, combined with the efficiency gains, often justify the upfront expenditure. Additionally, as technology continues to advance, the costs associated with direct-connected turbines are expected to decrease, making them more accessible to a wider range of applications. In conclusion, the direct-connected turbine represents a significant advancement in the field of energy generation. Its efficiency, reduced maintenance requirements, smaller footprint, and potential for environmental benefits make it an attractive option for modern power plants. As the world seeks to transition to more sustainable energy practices, the role of direct-connected turbines will likely become even more prominent, paving the way for a cleaner and more efficient future in energy production.

直接连接涡轮的概念在机械工程和能源生产领域中至关重要。直接连接涡轮是指与发电机直接耦合的涡轮，而无需中间齿轮或其他机械组件。这种设计简化了能量转换过程，使其更加高效和可靠。近年来，对高效能源解决方案的需求激增，导致对像直接连接涡轮这样的技术产生了更大的兴趣。直接连接涡轮的主要优点之一是其效率。通过消除齿轮的需要，齿轮可能会引入摩擦和机械损失，系统运行更加平稳。这种直接连接使得涡轮产生的能量能够更高比例地转化为电能。因此，利用直接连接涡轮的发电厂可以实现比传统设置更好的性能指标。此外，直接连接涡轮的维护需求低于其齿轮对应物。齿轮可能会随着时间的推移而磨损，需要定期检查和更换，从而增加运营成本。相比之下，直接连接涡轮的简单设计减少了运动部件的数量，从而固有地降低了机械故障的可能性。这种可靠性在需要连续发电的环境中尤为重要，例如医院或数据中心。除了效率和维护优势外，直接连接涡轮还有助于减少发电系统的整体占地面积。由于操作所需的组件较少，这些系统可以更加紧凑，更易于安装。这在城市地区尤其有利，因为空间有限。随着城市的不断发展和对能源的需求增加，在有限的空间内寻找发电方式变得越来越重要。此外，直接连接涡轮的环境影响通常低于传统涡轮。许多直接连接涡轮设计用于使用可再生能源，如风能或水电。通过利用这些可持续资源，它们有助于减少对化石燃料的依赖，并降低温室气体排放。这与全球应对气候变化和促进清洁能源替代品的努力相一致。尽管有众多优点，直接连接涡轮也面临挑战。这类系统的初始投资可能相当可观，特别是在考虑到先进技术的集成时。然而，长期的维护和运营成本节省，加上效率提升，通常可以证明前期支出的合理性。此外，随着技术的不断进步，与直接连接涡轮相关的成本预计将会下降，使其在更广泛的应用中变得更加可及。总之，直接连接涡轮代表了能源生产领域的重要进步。其效率、减少的维护要求、更小的占地面积以及对环境的潜在益处使其成为现代发电厂的一个有吸引力的选择。随着世界寻求向更可持续的能源实践过渡，直接连接涡轮的角色可能会变得更加突出，为未来的清洁和高效能源生产铺平道路。