wall temperature

简明释义

壁温

英英释义

例句

1.During the test, we recorded the wall temperature 墙面温度 at various points in the room.

在测试过程中，我们在房间的不同点记录了墙面温度 wall temperature。

2.We need to monitor the wall temperature 墙面温度 to prevent mold growth in humid conditions.

我们需要监测墙面温度 wall temperature以防止潮湿条件下的霉菌生长。

3.Excessive wall temperature 墙面温度 can lead to structural damage over time.

过高的墙面温度 wall temperature可能会导致结构损坏。

4.The HVAC system is designed to maintain a constant wall temperature 墙面温度 for optimal comfort.

HVAC系统设计用于保持恒定的墙面温度 wall temperature以获得最佳舒适度。

5.The engineer measured the wall temperature 墙面温度 to ensure the building materials were safe.

工程师测量了墙面温度 wall temperature以确保建筑材料的安全性。

作文

In the field of engineering and physics, understanding the concept of wall temperature is crucial for various applications, especially in thermal analysis. The term wall temperature refers to the temperature of a surface or boundary that separates two different mediums, such as the wall of a container holding a fluid or the surface of an object exposed to the environment. This temperature plays a significant role in heat transfer processes, as it influences how heat is exchanged between the wall and the adjacent fluid or air.For instance, in the design of heating systems, engineers must carefully consider the wall temperature to ensure efficient heat distribution. If the wall temperature is too low, the heating system may not effectively warm the space, leading to discomfort and increased energy costs. Conversely, if the wall temperature is excessively high, it could pose safety risks or damage surrounding materials.Moreover, in the context of building construction, the wall temperature can significantly affect energy efficiency. Insulation materials are often selected based on their ability to maintain a stable wall temperature, preventing heat loss in winter and minimizing heat gain in summer. By optimizing the wall temperature, buildings can achieve better thermal performance, ultimately leading to reduced energy consumption and lower utility bills.Another important application of wall temperature is in the field of electronics. Electronic devices generate heat during operation, and managing this heat is essential to ensure their longevity and reliability. Engineers monitor the wall temperature of circuit boards and other components to prevent overheating, which can lead to malfunctions or even catastrophic failures. Effective cooling solutions, such as heat sinks and fans, are designed with the wall temperature in mind to maintain optimal operating conditions.In addition to practical applications, the concept of wall temperature also has theoretical implications. In fluid dynamics, for example, the wall temperature affects the behavior of boundary layers, which are thin regions near the wall where fluid velocity changes from zero (at the wall) to the free stream value. Understanding how the wall temperature influences these layers is essential for predicting flow patterns and heat transfer rates.In conclusion, the significance of wall temperature cannot be overstated. It is a fundamental parameter that impacts various fields, including engineering, architecture, and electronics. By comprehensively understanding and effectively managing wall temperature, we can enhance energy efficiency, improve safety, and ensure the reliability of systems and structures. As technology continues to advance, the study of wall temperature will remain a vital area of research, contributing to the development of more efficient and sustainable solutions in our increasingly complex world.

在工程和物理学领域，理解墙面温度的概念对于各种应用至关重要，尤其是在热分析方面。术语墙面温度指的是分隔两个不同介质的表面或边界的温度，例如盛有流体的容器的墙壁或暴露于环境中的物体的表面。这一温度在热传递过程中起着重要作用，因为它影响着墙壁与相邻流体或空气之间的热交换。例如，在供暖系统的设计中，工程师必须仔细考虑墙面温度以确保有效的热分布。如果墙面温度过低，供暖系统可能无法有效加热空间，导致不适和能源成本增加。相反，如果墙面温度过高，可能会带来安全风险或损坏周围材料。此外，在建筑施工的背景下，墙面温度可以显著影响能源效率。绝缘材料的选择通常基于其维持稳定墙面温度的能力，以防止冬季的热量损失和夏季的热量增益。通过优化墙面温度，建筑物可以实现更好的热性能，最终减少能源消耗和降低公用事业费用。墙面温度的另一个重要应用是在电子领域。电子设备在运行过程中会产生热量，管理这些热量对于确保其耐用性和可靠性至关重要。工程师监测电路板和其他组件的墙面温度以防止过热，这可能导致故障甚至灾难性故障。有效的冷却解决方案，如散热器和风扇，是根据墙面温度进行设计的，以保持最佳操作条件。除了实际应用外，墙面温度的概念也具有理论意义。在流体动力学中，例如，墙面温度影响边界层的行为，边界层是靠近墙壁的薄区域，其中流体速度从零（在墙壁上）变化到自由流值。了解墙面温度如何影响这些层对于预测流动模式和热传递速率至关重要。总之，墙面温度的重要性不容小觑。它是影响多个领域的基本参数，包括工程、建筑和电子。通过全面理解和有效管理墙面温度，我们可以提高能源效率、改善安全性，并确保系统和结构的可靠性。随着技术的不断进步，墙面温度的研究将仍然是一个重要的研究领域，为我们日益复杂的世界的发展提供更高效和可持续的解决方案。