capacity of heat transmission

简明释义

热传导能力

英英释义

例句

1.Different metals have varying capacity of heat transmission (热传导能力), which is why copper is often used in heat exchangers.

不同金属具有不同的热传导能力，这就是为什么铜常用于热交换器。

2.The insulation material used in the building directly affects the capacity of heat transmission (热传导能力) through its walls.

建筑中使用的绝缘材料直接影响其墙壁的热传导能力。

3.To improve energy efficiency, it is essential to understand the capacity of heat transmission (热传导能力) of window materials.

为了提高能效，了解窗户材料的热传导能力是至关重要的。

4.Engineers must calculate the capacity of heat transmission (热传导能力) when designing HVAC systems.

工程师在设计暖通空调系统时必须计算热传导能力。

5.The capacity of heat transmission (热传导能力) of fluids can affect the cooling efficiency in industrial processes.

流体的热传导能力会影响工业过程中的冷却效率。

作文

The study of thermal dynamics is crucial in various fields, including engineering, environmental science, and even everyday applications. One fundamental concept in this field is the capacity of heat transmission, which refers to the ability of a material or system to conduct heat from one point to another. Understanding this capacity is essential for designing efficient heating and cooling systems, insulating buildings, and even creating effective cooking appliances. To elaborate, the capacity of heat transmission can be influenced by several factors, including the material's composition, temperature difference, and surface area. For instance, metals like copper and aluminum have high thermal conductivity, which means they possess a high capacity of heat transmission. This property makes them ideal for use in electrical wiring and cookware, where rapid heat transfer is necessary. On the other hand, materials like wood or fiberglass have low thermal conductivity, resulting in a lower capacity of heat transmission. These materials are often used for insulation purposes, as they help to retain heat within a space, making it more energy-efficient.In practical applications, understanding the capacity of heat transmission helps engineers and architects make informed decisions when designing buildings. For example, during the winter months, a building with poor heat transmission capacity will lose warmth quickly, leading to higher energy consumption for heating. By selecting materials with appropriate thermal properties, architects can create structures that maintain comfortable indoor temperatures while minimizing energy costs.Additionally, the capacity of heat transmission plays a significant role in climate control systems. Air conditioners and heaters rely on the principles of heat transfer to regulate indoor temperatures. The efficiency of these systems often depends on how well they can manage the capacity of heat transmission within the environment. For instance, an air conditioning unit that effectively transfers heat out of a building will create a cooler indoor atmosphere more efficiently than one that struggles with heat transfer.Moreover, the capacity of heat transmission is not limited to buildings and appliances; it also has implications in environmental science. Understanding how heat is transferred through different mediums can help scientists predict weather patterns, study climate change, and develop strategies for sustainable energy use. For example, researchers studying ocean currents must consider the capacity of heat transmission in water to understand how heat is distributed across the globe, which ultimately affects climate.In conclusion, the capacity of heat transmission is a vital concept in multiple disciplines, influencing everything from construction practices to environmental studies. By grasping the principles behind heat transfer, we can innovate and improve our technologies, making them more efficient and sustainable. As we continue to face challenges related to energy consumption and climate change, a deeper understanding of the capacity of heat transmission will be essential in developing solutions that benefit both society and the environment.

热力学的研究在工程、环境科学以及日常应用等多个领域都至关重要。其中一个基本概念是热传导能力，它指的是材料或系统从一点到另一点传导热量的能力。理解这一能力对于设计高效的供热和制冷系统、隔热建筑，甚至创造有效的烹饪设备都是必不可少的。具体而言，热传导能力会受到几个因素的影响，包括材料的组成、温度差和表面积。例如，像铜和铝这样的金属具有高热导率，这意味着它们具有较高的热传导能力。这一特性使它们非常适合用于电线和炊具中，在这些应用中，快速的热量转移是必要的。另一方面，像木材或玻璃纤维这样的材料具有低热导率，从而导致较低的热传导能力。这些材料通常用于绝缘目的，因为它们有助于保持空间内的热量，从而提高能效。在实际应用中，理解热传导能力帮助工程师和建筑师在设计建筑时做出明智的决策。例如，在冬季，热传导能力差的建筑会迅速失去温暖，导致供暖的能耗增加。通过选择具有适当热性能的材料，建筑师可以创建能够维持舒适室内温度的结构，同时最大限度地降低能源成本。此外，热传导能力在气候控制系统中也发挥着重要作用。空调和加热器依赖热传递的原理来调节室内温度。这些系统的效率往往取决于它们如何管理环境中的热传导能力。例如，一台能够有效将热量从建筑物中转移出去的空调装置，将比一台在热传输方面表现不佳的空调更高效地创造出凉爽的室内环境。此外，热传导能力不仅限于建筑和设备，它在环境科学中也有重要意义。理解不同介质中的热量如何传递可以帮助科学家预测天气模式、研究气候变化，并制定可持续能源使用的策略。例如，研究海洋洋流的研究人员必须考虑水中的热传导能力，以了解热量如何在全球分布，这最终影响气候。总之，热传导能力是多个学科中的一个重要概念，影响着从建筑实践到环境研究的方方面面。通过掌握热传递背后的原理，我们可以创新并改善我们的技术，使其更加高效和可持续。随着我们继续面临与能源消耗和气候变化相关的挑战，对热传导能力的更深入理解将在开发既惠及社会又保护环境的解决方案中至关重要。