wall conductance ratio

简明释义

壁电导率

英英释义

例句

1.To improve energy efficiency, we need to adjust the wall conductance ratio 墙导热率比 in our insulation design.

为了提高能效，我们需要调整我们的绝缘设计中的墙导热率比 wall conductance ratio。

2.Architects must consider the wall conductance ratio 墙导热率比 when designing energy-efficient homes.

建筑师在设计节能住宅时必须考虑墙导热率比 wall conductance ratio。

3.A high wall conductance ratio 墙导热率比 indicates poor insulation and can lead to increased heating costs.

高墙导热率比 wall conductance ratio表示绝缘效果差，可能导致取暖成本增加。

4.The study focused on the impact of the wall conductance ratio 墙导热率比 on indoor climate control.

这项研究集中于墙导热率比 wall conductance ratio对室内气候控制的影响。

5.The engineer calculated the wall conductance ratio 墙导热率比 to optimize the thermal performance of the building.

工程师计算了墙导热率比 wall conductance ratio以优化建筑的热性能。

作文

In the field of thermal engineering, understanding heat transfer is crucial for designing efficient systems. One important concept that engineers must grasp is the wall conductance ratio, which refers to the proportion of heat transfer through a wall compared to the heat transfer through other components in a thermal system. The wall conductance ratio can significantly influence the overall energy efficiency of buildings and industrial processes. The wall conductance ratio is determined by the materials used in the walls, their thickness, and the temperature difference across them. For instance, a wall made of highly conductive materials such as metals will have a higher wall conductance ratio compared to a wall made of insulating materials like wood or foam. This means that more heat will flow through the metal wall than through the insulated wall, impacting the heating and cooling requirements of a building. When analyzing energy losses in a building, architects and engineers often calculate the wall conductance ratio to identify areas where improvements can be made. By improving insulation or using materials with lower thermal conductivity, they can reduce the wall conductance ratio, thereby minimizing heat loss during winter and heat gain during summer. This not only enhances comfort but also leads to significant energy savings, which is increasingly important in today's world where energy costs are rising and environmental concerns are paramount. In addition to residential buildings, the wall conductance ratio plays a vital role in industrial applications. For example, in manufacturing processes that involve high temperatures, engineers must carefully consider the wall conductance ratio of furnaces and reactors to ensure optimal thermal management. A properly designed system that accounts for the wall conductance ratio can lead to increased productivity and reduced operational costs. Moreover, advancements in technology have allowed for the development of materials that can alter the wall conductance ratio. Smart materials that respond to temperature changes can be used to create dynamic insulation systems. These systems can adjust their properties based on external conditions, effectively optimizing the wall conductance ratio and enhancing energy efficiency. In conclusion, the wall conductance ratio is a fundamental concept in thermal engineering that affects energy efficiency in both residential and industrial settings. Understanding and optimizing this ratio can lead to better thermal management, cost savings, and improved environmental sustainability. As we continue to innovate and seek ways to reduce our carbon footprint, the significance of the wall conductance ratio will only grow, making it an essential topic for engineers and architects alike.

在热工程领域，理解热传递对于设计高效系统至关重要。工程师必须掌握的一个重要概念是墙体导热比，它指的是通过墙体的热传递与通过热系统中其他组件的热传递的比例。墙体导热比可以显著影响建筑物和工业过程的整体能效。墙体导热比由墙体所用材料、厚度以及它们之间的温差决定。例如，采用金属等高导热材料制成的墙体，其墙体导热比将高于由木材或泡沫等绝缘材料制成的墙体。这意味着，热量会通过金属墙体流动得更多，而不是通过绝缘墙体，从而影响建筑物的供暖和制冷需求。在分析建筑物的能量损失时，建筑师和工程师通常会计算墙体导热比以识别可以改进的区域。通过改善绝缘或使用导热性较低的材料，他们可以降低墙体导热比，从而在冬季减少热量损失，在夏季减少热量增益。这不仅提高了舒适度，还带来了显著的能源节约，这在当今能源成本上升、环境问题日益严重的世界中变得越来越重要。除了住宅建筑外，墙体导热比在工业应用中也发挥着至关重要的作用。例如，在涉及高温的制造过程中，工程师必须仔细考虑炉子和反应器的墙体导热比，以确保最佳的热管理。一个合理设计的系统，如果考虑到墙体导热比，可以提高生产率并降低运营成本。此外，技术的进步使得开发能够改变墙体导热比的材料成为可能。响应温度变化的智能材料可用于创建动态绝缘系统。这些系统可以根据外部条件调整其特性，有效优化墙体导热比，提升能效。总之，墙体导热比是热工程中的一个基本概念，它影响着住宅和工业环境中的能效。理解和优化这一比率可以实现更好的热管理、成本节约和改善环境可持续性。随着我们继续创新，寻求减少碳足迹的方法，墙体导热比的重要性只会增加，使其成为工程师和建筑师共同关注的主题。