counterfort type powerhouse

简明释义

后扶垛式发电厂

英英释义

例句

1.The design of the counterfort type powerhouse allows for easy maintenance and accessibility.

这座挡土墙型发电厂的设计便于维护和可达性。

2.Our team is researching the environmental impact of a counterfort type powerhouse on local wildlife.

我们的团队正在研究挡土墙型发电厂对当地野生动物的环境影响。

3.During the site visit, we observed the construction of a counterfort type powerhouse that utilizes innovative materials.

在现场考察期间，我们观察到一座正在建设的挡土墙型发电厂，采用了创新材料。

4.The engineers designed a new counterfort type powerhouse to improve the efficiency of the hydroelectric project.

工程师们设计了一座新的挡土墙型发电厂，以提高水电项目的效率。

5.The counterfort type powerhouse is known for its stability and resistance to seismic activity.

这座挡土墙型发电厂以其稳定性和抗震能力而闻名。

作文

In the realm of civil engineering and hydropower generation, the term counterfort type powerhouse refers to a specific design of powerhouses that are integrated into the dam structure. These powerhouses are characterized by their use of counterforts, which are structural elements designed to provide additional support to the walls of the powerhouse. The significance of the counterfort type powerhouse lies in its ability to efficiently harness the energy of flowing water while ensuring stability and durability in construction.One of the primary advantages of a counterfort type powerhouse is its enhanced structural integrity. The counterforts help distribute the loads exerted by the water pressure and the weight of the machinery housed within the powerhouse. This design minimizes the risk of structural failure, making it an ideal choice for sites with high water flow and significant hydrostatic pressure. Engineers often prefer this type of powerhouse when constructing large-scale hydroelectric plants, as it can withstand the forces of nature while optimizing energy production.Moreover, the counterfort type powerhouse is designed to facilitate easy maintenance and operation. The layout allows for better access to turbines and generators, ensuring that any necessary repairs or inspections can be carried out efficiently. This is particularly important in hydropower facilities, where downtime can lead to substantial financial losses. Therefore, the thoughtful design of a counterfort type powerhouse not only enhances safety but also improves operational efficiency.In addition to these practical benefits, the counterfort type powerhouse also has aesthetic implications. Many modern powerhouses are built with a focus on blending into the natural landscape. The use of counterforts can create visually appealing lines and shapes that harmonize with the surrounding environment. This consideration for aesthetics is increasingly important as communities become more environmentally conscious and seek to preserve the beauty of their landscapes.The construction of a counterfort type powerhouse involves meticulous planning and engineering. It requires a comprehensive understanding of hydrodynamics, material science, and structural engineering principles. Engineers must assess various factors, including water flow rates, geological conditions, and environmental impact, before finalizing the design. The integration of counterforts into the powerhouse structure is a critical decision that influences both the performance and longevity of the facility.As the demand for renewable energy sources continues to grow, the role of counterfort type powerhouse designs becomes increasingly significant. They offer a reliable solution for generating clean energy while addressing the challenges posed by climate change and resource scarcity. By investing in such innovative designs, we can work towards a sustainable future that prioritizes both energy production and environmental preservation.In conclusion, the counterfort type powerhouse represents a remarkable achievement in engineering, combining functionality with aesthetic appeal. Its robust design ensures that it can withstand the pressures of water flow while providing efficient energy generation. As we move forward in our quest for sustainable energy solutions, the importance of such structures will undoubtedly continue to grow, paving the way for a greener and more energy-efficient world.

在土木工程和水电发电的领域中，短语counterfort type powerhouse指的是一种集成在大坝结构中的发电厂特定设计。这些发电厂的特点是使用了支撑墙体的结构元素——反撑，这些反撑旨在为发电厂的墙体提供额外支持。counterfort type powerhouse的重要性在于其能够有效利用流动水的能量，同时确保建筑的稳定性和耐久性。counterfort type powerhouse的主要优势之一是其增强的结构完整性。反撑帮助分散水压和发电厂内机械设备重量施加的负荷。这种设计最大限度地降低了结构失效的风险，使其成为高水流和显著水静压力场所的理想选择。工程师们通常在建造大型水电站时更倾向于这种类型的发电厂，因为它能够承受自然力的影响，同时优化能源生产。此外，counterfort type powerhouse的设计也便于维护和操作。该布局允许更好地接触涡轮机和发电机，确保任何必要的维修或检查能够高效进行。在水电设施中，停工时间可能导致巨大的经济损失，因此，counterfort type powerhouse的周到设计不仅增强了安全性，还提高了运营效率。除了这些实用的好处外，counterfort type powerhouse在美学上也有其意义。许多现代发电厂的建设注重与自然景观的融合。反撑的使用可以创造出视觉上吸引人的线条和形状，与周围环境和谐相处。随着社区对环保意识的增强，对保护自然景观之美的追求，这种美学考虑变得越来越重要。counterfort type powerhouse的建设涉及细致的规划和工程设计。它需要全面理解水动力学、材料科学和结构工程原理。工程师必须在最终确定设计之前评估各种因素，包括水流速率、地质条件和环境影响。将反撑整合到发电厂结构中是一个关键决策，这会影响设施的性能和使用寿命。随着对可再生能源需求的持续增长，counterfort type powerhouse设计的角色变得越来越重要。它们为生成清洁能源提供了一种可靠的解决方案，同时应对气候变化和资源稀缺带来的挑战。通过投资于这种创新设计，我们可以朝着优先考虑能源生产和环境保护的可持续未来迈进。总之，counterfort type powerhouse代表了工程领域的一项卓越成就，功能性与美学吸引力相结合。其坚固的设计确保能够承受水流的压力，同时提供高效的能源生成。随着我们在可持续能源解决方案的追求中不断前进，这类结构的重要性无疑将继续增长，为实现一个更绿色、更高效的能源世界铺平道路。