heat absorption capacity

简明释义

吸热量

英英释义

例句

1.The new building materials have a higher heat absorption capacity than traditional ones, making them more energy-efficient.

新型建筑材料的热吸收能力比传统材料更高，使其更加节能。

2.Materials with low heat absorption capacity can help keep buildings cooler in hot climates.

低热吸收能力的材料可以帮助在炎热气候中保持建筑物凉爽。

3.The heat absorption capacity of water is crucial for regulating the climate in coastal areas.

水的热吸收能力对调节沿海地区的气候至关重要。

4.Researchers are studying the heat absorption capacity of different surfaces to improve urban heat management.

研究人员正在研究不同表面的热吸收能力以改善城市热管理。

5.In solar energy applications, maximizing the heat absorption capacity of panels is essential for efficiency.

在太阳能应用中，最大化面板的热吸收能力对提高效率至关重要。

作文

The concept of heat absorption capacity is crucial in various fields, including engineering, environmental science, and materials science. It refers to the ability of a material to absorb heat energy from its surroundings. Understanding this property is essential for designing efficient thermal systems, such as heating and cooling systems, as well as for evaluating the thermal performance of building materials. For instance, materials with high heat absorption capacity can store more heat, making them ideal for applications where thermal regulation is necessary.In the context of climate change and global warming, the heat absorption capacity of different surfaces, such as urban areas versus natural landscapes, plays a significant role in determining local temperatures. Urban heat islands, which are areas that experience significantly warmer temperatures than their rural surroundings, are often a result of the high heat absorption capacity of concrete and asphalt. These materials absorb and retain heat during the day and release it slowly at night, leading to elevated nighttime temperatures.Moreover, the heat absorption capacity of materials affects energy consumption in buildings. For example, using materials with high heat absorption capacity in walls and roofs can help maintain a stable indoor temperature, reducing the need for air conditioning and heating. This not only lowers energy bills but also contributes to a more sustainable environment by decreasing the overall carbon footprint.In addition to its implications for energy efficiency, the heat absorption capacity of materials can influence the comfort levels of occupants in a space. Materials that absorb and release heat effectively can create a more pleasant indoor climate, enhancing the overall quality of life. Therefore, architects and builders must consider this property when selecting materials for construction projects.Furthermore, the heat absorption capacity is also relevant in the field of renewable energy. Solar panels, for instance, rely on materials with specific heat absorption capacity characteristics to maximize energy conversion. By optimizing the materials used in solar technology, engineers can improve the efficiency of these systems, making them more viable alternatives to fossil fuels.In conclusion, the heat absorption capacity is a vital property that influences many aspects of our built environment and energy systems. From mitigating urban heat islands to enhancing energy efficiency in buildings and improving renewable energy technologies, understanding and harnessing this property is essential for creating a sustainable future. As we continue to face the challenges posed by climate change, recognizing the importance of heat absorption capacity will be key in developing innovative solutions that benefit both people and the planet.

“热吸收能力”这一概念在工程、环境科学和材料科学等多个领域中至关重要。它指的是材料从其周围环境中吸收热能的能力。理解这一特性对于设计高效的热系统（如供暖和制冷系统）以及评估建筑材料的热性能至关重要。例如，具有高“热吸收能力”的材料可以储存更多的热量，使其在需要热调节的应用中理想。在气候变化和全球变暖的背景下，不同表面（如城市区域与自然景观）的“热吸收能力”在决定局部温度方面发挥着重要作用。城市热岛现象，即某些地区的温度显著高于周围农村地区，通常是由于混凝土和沥青等材料的高“热吸收能力”。这些材料在白天吸收和保持热量，晚上缓慢释放，从而导致夜间温度升高。此外，材料的“热吸收能力”还会影响建筑物的能耗。例如，在墙壁和屋顶使用具有高“热吸收能力”的材料可以帮助维持稳定的室内温度，从而减少空调和供暖的需求。这不仅降低了能源费用，还有助于通过减少整体碳足迹来创造更可持续的环境。除了对能源效率的影响外，材料的“热吸收能力”还会影响空间内居住者的舒适度。能够有效吸收和释放热量的材料可以营造更宜人的室内气候，提高整体生活质量。因此，建筑师和施工者在选择建筑项目的材料时必须考虑这一特性。此外，“热吸收能力”在可再生能源领域也具有相关性。例如，太阳能电池板依赖于具有特定“热吸收能力”特征的材料，以最大化能量转换。通过优化太阳能技术中使用的材料，工程师可以提高这些系统的效率，使其成为化石燃料的更可行替代品。总之，“热吸收能力”是影响我们建筑环境和能源系统许多方面的重要特性。从减轻城市热岛效应到提高建筑物的能源效率，再到改善可再生能源技术，理解和利用这一特性对于创造可持续的未来至关重要。在我们继续面临气候变化带来的挑战时，认识到“热吸收能力”的重要性将是开发有利于人类和地球的创新解决方案的关键。