heat storage capacity

简明释义

蓄热能力

英英释义

例句

1.Researchers are exploring phase change materials to enhance the heat storage capacity 热储存能力 of energy systems.

研究人员正在探索相变材料，以增强能源系统的热储存能力 heat storage capacity。

2.The heat storage capacity 热储存能力 of this building's walls helps to maintain a stable indoor temperature.

这栋建筑墙壁的热储存能力 heat storage capacity有助于维持稳定的室内温度。

3.Engineers are testing materials with high heat storage capacity 热储存能力 for use in thermal energy systems.

工程师正在测试具有高热储存能力 heat storage capacity的材料，以用于热能系统。

4.A higher heat storage capacity 热储存能力 means that the system can provide heat for a longer period without additional energy input.

更高的热储存能力 heat storage capacity意味着该系统可以在没有额外能量输入的情况下提供更长时间的热量。

5.The new solar panels have an improved heat storage capacity 热储存能力 that allows them to store more energy during the day.

新的太阳能电池板具有更好的热储存能力 heat storage capacity，使它们能够在白天储存更多的能量。

作文

The concept of heat storage capacity is crucial in understanding how materials can retain and release heat energy. In essence, heat storage capacity refers to the ability of a substance to absorb heat and store it for later use. This property is particularly important in various fields such as engineering, architecture, and environmental science. For instance, in the construction of buildings, materials with high heat storage capacity can help maintain comfortable indoor temperatures by absorbing heat during the day and releasing it at night. This not only enhances comfort but also reduces energy consumption and reliance on heating systems.In the context of renewable energy, heat storage capacity plays a significant role in solar energy systems. Solar thermal collectors capture sunlight and convert it into heat, which can be used for heating water or spaces. The heat storage capacity of the storage medium, whether it be water, stones, or specialized phase change materials, determines how much energy can be stored and for how long. By optimizing the heat storage capacity, we can ensure that solar energy is available even when the sun is not shining.Moreover, understanding heat storage capacity is essential for improving energy efficiency in industrial processes. Many manufacturing operations generate excess heat, which, if not managed properly, is wasted. By utilizing materials with high heat storage capacity, industries can capture this waste heat and reuse it in other processes, leading to significant cost savings and reduced environmental impact.In addition to practical applications, the study of heat storage capacity also has implications for climate science. Different materials respond to temperature changes in various ways, and their heat storage capacity influences local climates. For example, urban areas with a lot of concrete and asphalt tend to have higher heat storage capacity than rural areas, leading to the urban heat island effect. Understanding these dynamics can help urban planners develop strategies to mitigate heat retention and improve overall city livability.In conclusion, the importance of heat storage capacity cannot be overstated. It is a fundamental property that impacts various aspects of our lives, from building design and renewable energy systems to industrial efficiency and climate regulation. As we continue to seek sustainable solutions to global energy challenges, enhancing our understanding of heat storage capacity will be vital in developing more efficient technologies and practices. By harnessing the potential of materials with optimal heat storage capacity, we can pave the way for a more energy-efficient and environmentally friendly future.

“热储存能力”这一概念对于理解材料如何保持和释放热能至关重要。实际上，“热储存能力”指的是物质吸收热量并为后续使用存储热量的能力。这个特性在工程、建筑和环境科学等多个领域尤为重要。例如，在建筑施工中，具有高“热储存能力”的材料可以通过在白天吸收热量并在夜间释放热量来帮助维持舒适的室内温度。这不仅增强了舒适感，还减少了能源消耗和对供暖系统的依赖。在可再生能源的背景下，“热储存能力”在太阳能系统中发挥着重要作用。太阳热收集器捕获阳光并将其转化为热量，这些热量可以用于加热水或空间。储存介质的“热储存能力”，无论是水、石头还是专门的相变材料，决定了可以存储多少能量以及存储多长时间。通过优化“热储存能力”，我们可以确保即使在阳光不照射的时候也能利用太阳能。此外，理解“热储存能力”对于提高工业过程的能源效率至关重要。许多制造操作会产生过剩热量，如果管理不当，这些热量就会被浪费。通过利用具有高“热储存能力”的材料，工业可以捕获这些废热并在其他过程中重新使用，从而实现显著的成本节约和降低环境影响。除了实际应用外，“热储存能力”的研究对气候科学也有影响。不同材料对温度变化的反应各不相同，它们的“热储存能力”影响着局部气候。例如，拥有大量混凝土和沥青的城市区域往往比乡村地区具有更高的“热储存能力”，导致城市热岛效应。理解这些动态可以帮助城市规划者制定减轻热量滞留并改善整体城市宜居性的策略。总之，“热储存能力”的重要性不容小觑。它是一种基本特性，影响着我们生活的各个方面，从建筑设计和可再生能源系统到工业效率和气候调节。随着我们继续寻求全球能源挑战的可持续解决方案，增强对“热储存能力”的理解将在开发更高效的技术和实践中发挥关键作用。通过利用具有最佳“热储存能力”的材料，我们可以为更加节能和环保的未来铺平道路。