heat storage capacity

简明释义

热储量

英英释义

例句

1.Improving the heat storage capacity 热储存能力 of building materials can lead to significant energy savings.

提高建筑材料的热储存能力可以带来显著的节能效果。

2.Researchers are developing materials with enhanced heat storage capacity 热储存能力 for more efficient thermal batteries.

研究人员正在开发具有增强热储存能力的新材料，以提高热电池的效率。

3.The heat storage capacity 热储存能力 of water is essential for maintaining stable temperatures in aquaponics.

水的热储存能力对于维持水培系统的稳定温度至关重要。

4.In geothermal systems, the heat storage capacity 热储存能力 of the ground plays a crucial role in efficiency.

在地热系统中，地下的热储存能力对效率起着至关重要的作用。

5.The new solar panels have a high heat storage capacity 热储存能力, allowing them to store energy for longer periods.

新的太阳能电池板具有较高的热储存能力，使其能够更长时间地储存能量。

作文

The concept of heat storage capacity is essential in various fields, particularly in engineering and environmental science. It refers to the ability of a material to absorb and retain heat energy over time. Understanding this property is crucial for designing efficient heating systems, improving energy conservation, and utilizing renewable energy sources effectively. For example, materials with high heat storage capacity can store solar energy during the day and release it at night, providing a sustainable solution for heating buildings. This principle is often applied in passive solar design, where strategic placement of materials allows for maximum heat retention during cold months.In addition to building design, heat storage capacity plays a significant role in thermal energy storage systems. These systems are designed to collect excess heat generated from various sources, such as solar panels or industrial processes, and store it for later use. By utilizing materials with high heat storage capacity, these systems can provide a steady supply of heat, reducing reliance on fossil fuels and minimizing greenhouse gas emissions. For instance, molten salt is commonly used in solar thermal power plants due to its excellent heat storage capacity, allowing the plants to generate electricity even when sunlight is not available.Furthermore, understanding the heat storage capacity of different materials can help in selecting appropriate materials for specific applications. For example, concrete and brick have high heat storage capacity, making them ideal for thermal mass in buildings. On the other hand, materials like wood or insulation foam have lower heat storage capacity, which may be beneficial in certain contexts where rapid temperature changes are desired.In recent years, research has focused on enhancing the heat storage capacity of materials through various techniques, such as incorporating phase change materials (PCMs). These materials can absorb and release large amounts of heat during phase transitions, significantly improving the overall heat storage capacity of a system. This innovation opens up new possibilities for energy-efficient designs and applications, particularly in the context of climate change and the increasing demand for sustainable energy solutions.In conclusion, the heat storage capacity of materials is a fundamental property that impacts numerous aspects of energy management and building design. By leveraging materials with high heat storage capacity, we can create more efficient heating systems, reduce energy consumption, and contribute to a more sustainable future. As technology advances, the exploration of new materials and methods to enhance heat storage capacity will continue to play a vital role in our efforts to combat climate change and promote energy efficiency.

“热储存能力”这一概念在各个领域中都至关重要，特别是在工程和环境科学中。它指的是材料在一段时间内吸收和保持热能的能力。理解这一属性对于设计高效的加热系统、改善能源节约以及有效利用可再生能源至关重要。例如，具有高“热储存能力”的材料可以在白天储存太阳能，并在夜间释放，为建筑物提供可持续的供暖解决方案。这一原理通常应用于被动太阳能设计，通过材料的战略性放置，使其在寒冷的月份实现最大的热量保留。除了建筑设计，“热储存能力”在热能储存系统中也扮演着重要角色。这些系统旨在收集来自各种来源（如太阳能电池板或工业过程）产生的多余热量，并将其储存以便后续使用。通过利用具有高“热储存能力”的材料，这些系统能够提供稳定的热量供应，减少对化石燃料的依赖，并最小化温室气体排放。例如，熔融盐因其出色的“热储存能力”而常用于太阳热能发电厂，使这些工厂即使在没有阳光时也能发电。此外，了解不同材料的“热储存能力”有助于选择适合特定应用的材料。例如，混凝土和砖块具有高“热储存能力”，使它们成为建筑中热质量的理想选择。另一方面，木材或绝缘泡沫等材料的“热储存能力”较低，这在某些需要快速温度变化的情况下可能是有益的。近年来，研究集中在通过各种技术增强材料的“热储存能力”，例如，结合相变材料（PCM）。这些材料可以在相变过程中吸收和释放大量热量，显著提高系统的整体“热储存能力”。这一创新为能源高效设计和应用开辟了新的可能性，特别是在气候变化和日益增长的可持续能源需求背景下。总之，材料的“热储存能力”是影响能源管理和建筑设计众多方面的基本属性。通过利用具有高“热储存能力”的材料，我们可以创建更高效的加热系统，减少能源消耗，并为更加可持续的未来做出贡献。随着技术的进步，探索新材料和增强“热储存能力”的方法将继续在我们应对气候变化和促进能源效率的努力中发挥重要作用。