cooling grid

简明释义

冷却栅

英英释义

例句

1.The new data center is equipped with a state-of-the-art cooling grid to manage heat efficiently.

新的数据中心配备了先进的冷却网格以高效管理热量。

2.We need to ensure that the cooling grid is functioning properly during peak hours.

我们需要确保在高峰时段冷却网格正常运行。

3.The engineers designed a cooling grid that optimizes airflow throughout the building.

工程师们设计了一个优化整个建筑空气流通的冷却网格。

4.This cooling grid uses innovative technology to reduce energy consumption.

这个冷却网格使用创新技术来减少能耗。

5.A malfunction in the cooling grid could lead to overheating of critical equipment.

在冷却网格中的故障可能导致关键设备过热。

作文

In recent years, the concept of sustainable energy has gained significant traction, particularly in urban planning and infrastructure development. One innovative solution that has emerged is the use of a cooling grid, which refers to a network designed to distribute cooling energy efficiently across buildings and public spaces. This system not only addresses the rising temperatures associated with climate change but also enhances the overall energy efficiency of cities. The idea behind a cooling grid is relatively simple: instead of each building relying on its own air conditioning units, a centralized system can provide cooling to multiple structures simultaneously. This approach can significantly reduce energy consumption and lower greenhouse gas emissions. For instance, in densely populated areas, a cooling grid can utilize chilled water or other cooling mediums that circulate through pipes, providing a more efficient means of temperature regulation than traditional methods. One of the primary benefits of implementing a cooling grid is the reduction in energy costs. By sharing resources, buildings can access cooling without the need for individual, high-capacity air conditioning systems. This not only saves money for building owners but also decreases the peak demand for electricity during hot weather, which can strain local power grids. Furthermore, the cooling grid can be powered by renewable energy sources, such as solar or wind, further reducing its carbon footprint. Additionally, a cooling grid can improve urban resilience against heatwaves, which are becoming increasingly common due to climate change. Cities are often referred to as 'heat islands' because of the extensive use of concrete and asphalt, which absorb and retain heat. By providing a reliable source of cooling, a cooling grid can help mitigate the effects of extreme heat, protecting vulnerable populations and improving overall public health. Moreover, the implementation of a cooling grid can foster community engagement and collaboration. As neighborhoods work together to establish these networks, residents become more invested in their local environment and sustainability efforts. This sense of community can lead to greater awareness of energy consumption and encourage individuals to adopt more environmentally friendly practices in their daily lives. However, the establishment of a cooling grid is not without its challenges. Initial setup costs can be high, and there may be logistical hurdles in integrating existing infrastructure with new systems. Additionally, regulatory frameworks must adapt to accommodate this innovative approach to cooling. Governments and city planners need to collaborate closely with engineers and environmental scientists to develop effective strategies for implementing cooling grids in urban areas. In conclusion, the concept of a cooling grid presents a promising solution to some of the pressing challenges posed by climate change and urbanization. By centralizing cooling efforts, cities can enhance energy efficiency, reduce costs, and improve public health. As we look towards a more sustainable future, embracing innovative solutions like the cooling grid will be crucial in creating resilient urban environments that can thrive in the face of climate adversity.

近年来，可持续能源的概念在城市规划和基础设施发展中获得了显著关注。其中一个新兴的创新解决方案是使用冷却网，指的是一个旨在有效分配冷却能量到建筑物和公共空间的网络。该系统不仅解决了与气候变化相关的温度上升问题，还增强了城市的整体能效。

冷却网的理念相对简单：而不是每栋建筑依赖自己的空调单元，一个集中系统可以同时为多个建筑提供冷却。这种方法可以显著减少能源消耗并降低温室气体排放。例如，在人口稠密的地区，冷却网可以利用冷却水或其他冷却介质，通过管道循环，为温度调节提供比传统方法更有效的手段。

实施冷却网的主要好处之一是降低能源成本。通过共享资源，建筑物可以在不需要单独高容量空调系统的情况下获得冷却。这不仅为建筑所有者节省了资金，还减少了炎热天气期间对电力的峰值需求，从而减轻了当地电网的压力。此外，冷却网可以由可再生能源（如太阳能或风能）供电，进一步降低其碳足迹。

此外，冷却网可以提高城市对热浪的韧性，而热浪由于气候变化而变得越来越普遍。由于广泛使用混凝土和沥青，城市常被称为“热岛”，因为它们吸收和保持热量。通过提供可靠的冷却源，冷却网可以帮助缓解极端高温的影响，保护脆弱人群并改善整体公共健康。

此外，实施冷却网可以促进社区参与和协作。随着邻里共同努力建立这些网络，居民对当地环境和可持续发展努力的投资感增强。这种社区意识可以导致对能源消耗的更大关注，并鼓励个人在日常生活中采取更环保的做法。

然而，建立冷却网并非没有挑战。初始设置成本可能很高，并且在将现有基础设施与新系统集成时可能会遇到后勤障碍。此外，监管框架必须适应以适应这种创新的冷却方法。政府和城市规划者需要与工程师和环境科学家密切合作，以制定有效的策略，在城市地区实施冷却网。

总之，冷却网的概念为应对气候变化和城市化带来的紧迫挑战提供了一种有希望的解决方案。通过集中冷却工作，城市可以提高能效，降低成本，改善公共健康。展望更可持续的未来，接受像冷却网这样的创新解决方案对于创造能够在气候逆境中蓬勃发展的韧性城市环境至关重要。