floating grid

简明释义

自由栅极

英英释义

例句

1.Using a floating grid layout allows for more flexibility in web design.

使用浮动网格布局可以在网页设计中提供更多灵活性。

2.In the architectural model, the floating grid represents the modular structure of the building.

在建筑模型中，浮动网格代表了建筑的模块化结构。

3.The new design features a floating grid that adapts to different screen sizes.

新设计采用了一个浮动网格，可以适应不同的屏幕尺寸。

4.The app's interface utilizes a floating grid to enhance user experience.

该应用程序的界面利用了浮动网格来增强用户体验。

5.The artist created a visual representation using a floating grid to organize her work.

艺术家使用浮动网格来组织她的作品，创造了一种视觉表现。

作文

In recent years, the concept of a floating grid has gained significant attention in various fields, especially in renewable energy and urban planning. A floating grid refers to a network of interconnected structures or systems that are designed to float on water bodies, providing a sustainable solution for urban development and energy generation. This innovative approach not only maximizes the use of space but also minimizes environmental impact, making it an attractive option for cities facing land scarcity.One of the most compelling applications of a floating grid is in solar energy production. By placing solar panels on floating platforms, we can harness sunlight while utilizing otherwise unused water surfaces. This method not only reduces the need for land-based solar farms, which can disrupt ecosystems and agricultural lands, but also helps in cooling the panels, thereby increasing their efficiency. Researchers have shown that floating solar farms can produce up to 10% more energy than traditional installations due to the cooling effect of the water beneath them.Moreover, a floating grid can be integrated into existing water infrastructure. For instance, reservoirs and lakes can host these floating solar panels, providing dual benefits of energy production and water conservation. This synergy is particularly important in regions where water scarcity is a pressing issue. As cities continue to grow, the demand for clean energy will only increase, and a floating grid offers a viable solution to meet this demand without compromising the environment.In addition to energy generation, floating grids can also play a crucial role in urban planning. With rising sea levels and increased flooding risks due to climate change, traditional land-based developments are becoming more vulnerable. Floating structures can adapt to changing water levels, providing safe and resilient housing options. Cities like Amsterdam and Rotterdam have already begun experimenting with floating homes and commercial spaces, showcasing the potential of floating grids in creating sustainable urban environments.Furthermore, the implementation of a floating grid can enhance biodiversity in aquatic ecosystems. By incorporating green spaces and habitats within these floating structures, we can create new environments for marine life. This approach not only supports local wildlife but also engages communities in conservation efforts, fostering a deeper connection between people and nature.However, despite the numerous advantages of a floating grid, there are challenges that need to be addressed. The construction and maintenance of floating structures require careful planning and consideration of environmental factors. Additionally, the cost of developing a floating grid may initially be higher than traditional methods, which could deter investment. Therefore, it is essential for governments and private sectors to collaborate in research and development, ensuring that the benefits outweigh the costs in the long run.In conclusion, the floating grid presents a transformative approach to addressing some of the most pressing issues of our time, including urbanization, energy production, and climate change. By embracing this innovative concept, we can create sustainable solutions that benefit both humanity and the planet. As we move forward, it is crucial to continue exploring the potential of floating grids and invest in technologies that promote resilience and sustainability for future generations.

近年来，“浮动电网”的概念在各个领域，特别是在可再生能源和城市规划中引起了广泛关注。“浮动电网”是指一组相互连接的结构或系统，旨在漂浮在水体上，提供可持续的城市发展和能源生成解决方案。这种创新方法不仅最大限度地利用空间，还能最小化环境影响，使其成为土地稀缺城市的一个有吸引力的选择。“浮动电网”最引人注目的应用之一是在太阳能生产方面。通过将太阳能电池板放置在漂浮平台上，我们可以在利用水面资源的同时捕捉阳光。这种方法不仅减少了对陆基太阳能农场的需求，这可能会破坏生态系统和农业用地，而且还有助于冷却电池板，从而提高其效率。研究表明，浮动太阳能农场的发电量可以比传统安装高出10%，这是由于水面下的冷却效果。此外，“浮动电网”可以与现有的水基础设施相结合。例如，水库和湖泊可以容纳这些浮动太阳能电池板，提供能源生产和水资源保护的双重好处。这种协同作用在水资源短缺问题突出的地区尤为重要。随着城市的不断发展，对清洁能源的需求只会增加，而“浮动电网”提供了一种在不损害环境的情况下满足这一需求的可行解决方案。除了能源生产外，“浮动电网”在城市规划中也可以发挥至关重要的作用。随着海平面上升和气候变化导致的洪水风险增加，传统的陆基开发变得越来越脆弱。漂浮结构可以适应水位变化，提供安全和韧性的住房选择。阿姆斯特丹和鹿特丹等城市已经开始尝试浮动住宅和商业空间，展示了“浮动电网”在创造可持续城市环境方面的潜力。此外，实施“浮动电网”还可以增强水生生态系统的生物多样性。通过在这些浮动结构中融入绿色空间和栖息地，我们可以为海洋生物创造新的环境。这种方法不仅支持当地野生动物，还使社区参与保护工作，促进人们与自然之间更深的联系。然而，尽管“浮动电网”有众多优势，但仍然存在需要解决的挑战。浮动结构的建造和维护需要仔细规划和考虑环境因素。此外，开发“浮动电网”的成本最初可能高于传统方法，这可能会阻碍投资。因此，政府和私营部门之间的合作在研究和开发中至关重要，以确保长期收益大于成本。总之，“浮动电网”为解决我们时代一些最紧迫的问题提供了一种变革性的方法，包括城市化、能源生产和气候变化。通过接受这一创新概念，我们可以创造出既有利于人类又有利于地球的可持续解决方案。展望未来，继续探索“浮动电网”的潜力并投资于促进未来几代人韧性和可持续性的技术至关重要。