heat storage capacity

简明释义

蓄热量

英英释义

例句

1.The heat storage capacity 热储存能力 of this material makes it ideal for solar energy applications.

这种材料的热储存能力 热储存能力使其非常适合用于太阳能应用。

2.Engineers are studying the heat storage capacity 热储存能力 of different building materials to improve energy efficiency.

工程师正在研究不同建筑材料的热储存能力 热储存能力以提高能源效率。

3.Increasing the heat storage capacity 热储存能力 of batteries can enhance their performance in electric vehicles.

提高电池的热储存能力 热储存能力可以增强其在电动车中的性能。

4.Researchers are developing new materials with higher heat storage capacity 热储存能力 for better thermal regulation.

研究人员正在开发具有更高热储存能力 热储存能力的新材料，以便更好地调节温度。

5.The heat storage capacity 热储存能力 of water is often utilized in thermal management systems.

水的热储存能力 热储存能力通常被用于热管理系统中。

作文

The concept of heat storage capacity is vital in various fields, including engineering, architecture, and environmental science. It refers to the ability of a material to absorb, store, and release heat energy. Understanding this property can significantly impact energy efficiency and sustainability in buildings and other structures. For instance, materials with high heat storage capacity can help maintain comfortable indoor temperatures by absorbing excess heat during the day and releasing it at night. This characteristic is particularly beneficial in regions with significant temperature fluctuations between day and night.In architectural design, the choice of materials plays a crucial role in optimizing heat storage capacity. Traditional materials like brick, stone, and concrete have excellent thermal mass properties, allowing them to store heat effectively. By incorporating these materials into the design of a building, architects can create spaces that are not only aesthetically pleasing but also energy-efficient. This approach reduces the reliance on artificial heating and cooling systems, leading to lower energy bills and a smaller carbon footprint.Moreover, the heat storage capacity of a material can influence the overall comfort of a living space. For example, a house built with high thermal mass materials will feel warmer in winter and cooler in summer compared to a house made with low thermal mass materials. This is because the former can regulate temperature fluctuations more effectively, providing a stable and comfortable environment.In addition to residential buildings, the heat storage capacity is also crucial in industrial applications. Many manufacturing processes require precise temperature control, and materials with high thermal mass can help achieve this by maintaining consistent temperatures. This is essential for ensuring product quality and efficiency in production lines.Furthermore, the concept of heat storage capacity extends to renewable energy systems, such as solar thermal energy. In these systems, solar collectors capture sunlight and convert it into heat, which is then stored in materials with high thermal mass for later use. This process allows for the efficient use of renewable energy, reducing dependence on fossil fuels and contributing to a more sustainable future.In conclusion, the heat storage capacity of materials is a fundamental property that influences energy efficiency, comfort, and sustainability in various applications. By understanding and utilizing this property, we can design better buildings, improve industrial processes, and harness renewable energy more effectively. As we move towards a more sustainable future, the importance of heat storage capacity will only continue to grow, making it an essential consideration in our quest for energy efficiency and environmental stewardship.

“热储存能力”的概念在工程、建筑和环境科学等多个领域都是至关重要的。它指的是材料吸收、储存和释放热能的能力。理解这个特性可以显著影响建筑物和其他结构的能效和可持续性。例如，具有高“热储存能力”的材料可以通过在白天吸收多余的热量并在夜间释放热量来帮助维持舒适的室内温度。这种特性在昼夜温差显著的地区尤其有益。在建筑设计中，材料的选择在优化“热储存能力”方面发挥着关键作用。传统材料如砖、石头和混凝土具有出色的热质量特性，可以有效地储存热量。通过将这些材料纳入建筑设计，建筑师可以创造出既美观又节能的空间。这种方法减少了对人工供暖和制冷系统的依赖，从而降低了能源账单和碳足迹。此外，材料的“热储存能力”还会影响居住空间的整体舒适度。例如，使用高热质量材料建造的房屋在冬季会感觉更温暖，在夏季则会感觉更凉爽，因为前者可以更有效地调节温度波动，提供一个稳定舒适的环境。除了住宅建筑外，“热储存能力”在工业应用中也至关重要。许多制造过程需要精确的温度控制，而具有高热质量的材料可以通过保持一致的温度来实现这一点。这对于确保产品质量和生产线的效率至关重要。此外，“热储存能力”的概念还扩展到可再生能源系统，如太阳能热能。在这些系统中，太阳能收集器捕获阳光并将其转化为热量，然后储存在具有高热质量的材料中以备后用。这个过程使得可再生能源的高效利用成为可能，减少了对化石燃料的依赖，并为更可持续的未来做出了贡献。总之，材料的“热储存能力”是影响各个应用中能效、舒适度和可持续性的基本特性。通过理解和利用这一特性，我们可以设计更好的建筑，改善工业过程，更有效地利用可再生能源。随着我们向更可持续的未来迈进，“热储存能力”的重要性只会不断增长，使其成为我们追求能效和环境管理时必须考虑的重要因素。