abstraction of heat

简明释义

散热

英英释义

例句

1.The HVAC system relies on the abstraction of heat 热量抽取 to regulate indoor temperatures effectively.

HVAC系统依赖于热量抽取 abstraction of heat 来有效调节室内温度。

2.The engineer explained that the abstraction of heat 热量抽取 is crucial for maintaining optimal performance in the cooling system.

工程师解释说，热量抽取 abstraction of heat 对于维持冷却系统的最佳性能至关重要。

3.Proper insulation helps in the abstraction of heat 热量抽取 from buildings, making them more energy-efficient.

适当的绝缘有助于从建筑物中进行热量抽取 abstraction of heat，使其更节能。

4.In the process of refrigeration, the abstraction of heat 热量抽取 allows the temperature inside the fridge to drop significantly.

在制冷过程中，热量抽取 abstraction of heat 使冰箱内部温度显著下降。

5.During the experiment, we measured the abstraction of heat 热量抽取 from the chemical reaction to determine its efficiency.

在实验中，我们测量了化学反应中的热量抽取 abstraction of heat 以确定其效率。

作文

The concept of abstraction of heat is fundamental in understanding various physical processes that occur in our environment. This term refers to the process of removing or dissipating heat from a system, which can lead to significant changes in temperature and energy states. In everyday life, we encounter numerous examples where the abstraction of heat plays a crucial role. For instance, when we use ice to cool a drink, the heat from the liquid is absorbed by the ice, leading to the melting of the ice and a decrease in the drink's temperature. This simple act illustrates how heat can be abstracted from one substance to another, demonstrating the principles of thermodynamics in action.In the field of engineering, the abstraction of heat is an essential consideration in designing systems for heating and cooling. For example, air conditioning units function by extracting heat from indoor air and transferring it outside, effectively lowering the indoor temperature. This process involves the circulation of refrigerants, which absorb heat from the air inside a building and release it outside, showcasing a practical application of the abstraction of heat principle.Moreover, the abstraction of heat is not limited to mechanical systems; it is also a vital component in natural phenomena. The Earth's climate system relies on the balance of heat absorption and abstraction to maintain stable temperatures. The oceans play a significant role in this process, absorbing heat from the sun during the day and releasing it at night, which helps regulate global temperatures. Understanding how the abstraction of heat works in this context is crucial for climate scientists as they study patterns and changes in weather systems.Furthermore, the abstraction of heat has implications in the field of materials science. Certain materials are designed to either retain or release heat efficiently, which is critical in applications ranging from thermal insulation to electronic devices. For instance, insulating materials are engineered to minimize the abstraction of heat, keeping warmth in during winter months and out during summer months. Conversely, heat sinks in electronics are designed to maximize the abstraction of heat, ensuring that devices do not overheat during operation.In conclusion, the abstraction of heat is a versatile concept that permeates various aspects of science and daily life. From cooling beverages to regulating the climate and enhancing technological performance, the ability to manage heat effectively is vital. As we continue to explore and innovate, a deeper understanding of the abstraction of heat will undoubtedly lead to more efficient systems and a better grasp of our environment. Ultimately, mastering this concept allows us to harness energy more wisely and sustainably, paving the way for advancements in multiple fields.

“热的抽象”这一概念对于理解我们环境中发生的各种物理过程至关重要。这个术语指的是从系统中去除或散发热量的过程，这可能导致温度和能量状态的显著变化。在日常生活中，我们遇到许多例子，其中“热的抽象”发挥着关键作用。例如，当我们用冰来冷却饮料时，液体的热量被冰吸收，导致冰的融化和饮料温度的降低。这一简单的行为展示了热量如何从一种物质抽象到另一种物质，体现了热力学原理的实际应用。在工程领域，“热的抽象”是设计加热和冷却系统时的重要考虑因素。例如，空调设备通过从室内空气中提取热量并将其转移到室外，从而有效降低室内温度。这个过程涉及制冷剂的循环，它们从建筑物内部的空气中吸收热量，并在外部释放，展示了“热的抽象”原理的实际应用。此外，“热的抽象”不仅限于机械系统；它也是自然现象中的一个重要组成部分。地球的气候系统依赖于热量吸收和抽象的平衡，以维持稳定的温度。海洋在这一过程中发挥着重要作用，白天吸收太阳的热量，晚上释放，从而帮助调节全球温度。理解“热的抽象”在这一背景下的工作原理对于气候科学家研究天气系统的模式和变化至关重要。此外，“热的抽象”在材料科学领域也具有重要意义。某些材料被设计成能够有效地保留或释放热量，这在从热绝缘到电子设备的应用中至关重要。例如，绝缘材料的工程设计旨在最小化“热的抽象”，在冬季保持温暖，在夏季保持凉爽。相反，电子设备中的散热器则设计为最大化“热的抽象”，确保设备在运行过程中不会过热。总之，“热的抽象”是一个多功能的概念，渗透到科学和日常生活的各个方面。从冷却饮料到调节气候以及提高技术性能，有效管理热量的能力至关重要。随着我们不断探索和创新，对“热的抽象”的更深入理解无疑将导致更高效的系统和对我们环境的更好把握。最终，掌握这一概念使我们能够更明智和可持续地利用能源，为多个领域的进步铺平道路。