thermal element

简明释义

热敏元件

英英释义

例句

1.The thermal element 热元件 used in this device is highly sensitive and accurate.

该设备中使用的热元件非常敏感且准确。

2.The thermal element 热元件 in the oven ensures that food is cooked evenly.

烤箱中的热元件确保食物均匀烹饪。

3.In the laboratory, we tested the thermal element 热元件 for its response to extreme temperatures.

在实验室中，我们测试了热元件对极端温度的反应。

4.To monitor temperature changes, we installed a thermal element 热元件 in the climate control system.

为了监测温度变化，我们在气候控制系统中安装了一个热元件。

5.The engineer designed a new type of thermal element 热元件 to improve energy efficiency in the heating system.

工程师设计了一种新型的热元件来提高供暖系统的能效。

作文

In the field of engineering and physics, the concept of a thermal element is crucial for understanding heat transfer and energy efficiency. A thermal element refers to any component or material that has thermal properties that influence the way heat is absorbed, conducted, or emitted. This can include materials like metals, ceramics, and polymers, which all have different capacities for thermal conductivity. Understanding how these thermal elements behave under various conditions allows engineers to design better systems for heating, cooling, and insulation.For example, in building construction, the choice of thermal elements in walls, roofs, and windows can significantly affect the energy efficiency of a structure. Materials with high thermal resistance, such as insulated panels, can help maintain stable indoor temperatures, reducing the need for heating and cooling systems. This not only saves energy but also contributes to a more sustainable environment.Moreover, in electronics, thermal elements play a vital role in managing heat dissipation from components like processors and power transistors. The effective management of heat in electronic devices ensures their longevity and optimal performance. Engineers often use heat sinks, which are designed as thermal elements, to absorb and disperse heat away from sensitive components. These thermal elements are engineered to maximize surface area and improve airflow, thereby enhancing their cooling efficiency.In the realm of renewable energy, the importance of thermal elements cannot be overstated. Solar thermal collectors, for instance, utilize specific thermal elements to absorb sunlight and convert it into usable heat energy. The efficiency of these systems largely depends on the materials used and their thermal properties. By optimizing the thermal elements within these collectors, developers can increase energy capture and improve overall system performance.Furthermore, the study of thermal elements extends to environmental science, where understanding the thermal properties of different materials can help predict climate change impacts. For example, the thermal conductivity of soil affects how heat is stored and transferred in the ground, influencing local climates and ecosystems. By studying these thermal elements, scientists can better understand and model climate patterns, helping us prepare for future changes.In conclusion, thermal elements are fundamental components in various fields, influencing everything from building designs to electronic device performance and energy systems. Their properties dictate how heat is managed and utilized, making them essential for innovation in technology and sustainability. As we continue to advance in these areas, a deeper understanding of thermal elements will undoubtedly lead to more efficient and environmentally friendly solutions, ultimately benefiting society as a whole.

在工程和物理领域，热元件的概念对于理解热传递和能效至关重要。热元件是指任何具有热性能的组件或材料，它们影响热量的吸收、传导或发射方式。这可以包括金属、陶瓷和聚合物等材料，它们的热导率各不相同。了解这些热元件在各种条件下的行为使工程师能够设计出更好的加热、冷却和绝缘系统。例如，在建筑施工中，墙壁、屋顶和窗户中热元件的选择可以显著影响结构的能效。具有高热阻的材料，如绝缘面板，可以帮助保持室内温度稳定，从而减少对加热和冷却系统的需求。这不仅节省了能源，还为更可持续的环境做出了贡献。此外，在电子设备中，热元件在管理来自处理器和功率晶体管等组件的热量散失方面发挥着至关重要的作用。有效的热管理确保了电子设备的耐用性和最佳性能。工程师通常使用散热器，这些被设计为热元件，以吸收和分散来自敏感组件的热量。这些热元件经过工程设计，以最大化表面积并改善气流，从而提高其冷却效率。在可再生能源领域，热元件的重要性不容小觑。例如，太阳能热收集器利用特定的热元件来吸收阳光并将其转化为可用的热能。这些系统的效率在很大程度上取决于所使用的材料及其热性能。通过优化这些收集器中的热元件，开发人员可以提高能量捕获并改善整体系统性能。此外，热元件的研究扩展到环境科学，其中理解不同材料的热性能可以帮助预测气候变化的影响。例如，土壤的热导率影响热量在地面上的储存和传递，从而影响局部气候和生态系统。通过研究这些热元件，科学家可以更好地理解和模拟气候模式，帮助我们为未来的变化做好准备。总之，热元件是各个领域的基础组件，影响从建筑设计到电子设备性能和能源系统的一切。它们的特性决定了热量的管理和利用，使它们在技术和可持续性创新中至关重要。随着我们在这些领域的不断进步，对热元件的更深入理解无疑会导致更高效和环保的解决方案，最终使整个社会受益。