radiation heating surface

简明释义

辐射受热面

英英释义

例句

1.Engineers must calculate the optimal size of the radiation heating surface 辐射加热表面 for maximum heat transfer.

工程师必须计算最佳的辐射加热表面 辐射加热表面大小以实现最大热传递。

2.The radiation heating surface 辐射加热表面 in this system is made of high-temperature resistant materials.

该系统中的辐射加热表面 辐射加热表面由耐高温材料制成。

3.In solar water heaters, the radiation heating surface 辐射加热表面 captures sunlight to heat the water.

在太阳能热水器中，辐射加热表面 辐射加热表面捕获阳光来加热水。

4.The radiation heating surface 辐射加热表面 in the furnace is critical for maintaining high temperatures.

炉中的辐射加热表面 辐射加热表面对于维持高温至关重要。

5.The design of the boiler includes a large radiation heating surface 辐射加热表面 to improve efficiency.

锅炉的设计包括一个大的辐射加热表面 辐射加热表面以提高效率。

作文

In modern engineering and design, the concept of a radiation heating surface plays a crucial role in various applications, particularly in heating systems and energy efficiency technologies. The radiation heating surface refers to any surface that emits thermal radiation to transfer heat to an adjacent medium, such as air or water. This principle is essential in many fields, including HVAC (heating, ventilation, and air conditioning), industrial processes, and even in everyday appliances like ovens and heaters.The effectiveness of a radiation heating surface can be influenced by several factors, including the material composition, surface texture, and temperature. For instance, materials with high emissivity, such as blackened surfaces, are more effective at radiating heat compared to shiny or reflective materials. This characteristic is vital for engineers who design heating systems, as they must select appropriate materials to maximize energy efficiency and minimize heat loss.Moreover, the size and shape of the radiation heating surface can also affect its performance. A larger surface area allows for more heat transfer, which is why many heating devices are designed with expansive surfaces to increase their heating capabilities. For example, in a radiant floor heating system, pipes carrying hot water are placed beneath the floor surface, effectively turning the entire floor into a radiation heating surface. This design not only provides comfort but also ensures efficient heat distribution throughout the room.Understanding the principles behind a radiation heating surface is also essential for improving energy efficiency in buildings. By optimizing the design and placement of these surfaces, engineers can create systems that require less energy to maintain comfortable temperatures. For instance, using infrared heaters that rely on radiation heating surfaces can reduce energy consumption while providing effective warmth in residential and commercial spaces.In addition to traditional heating systems, the concept of radiation heating surfaces is being explored in innovative technologies, such as solar thermal systems. These systems utilize the sun's energy to heat fluids, which can then be used for space heating or hot water production. The radiation heating surface in this context is typically made of materials that efficiently absorb solar radiation and convert it into heat, demonstrating the versatility and importance of this concept across different applications.Furthermore, advancements in materials science are paving the way for the development of new radiation heating surfaces that can operate at even higher efficiencies. For example, nanotechnology is being utilized to create coatings that enhance the emissivity of surfaces, allowing for better heat transfer and energy savings. As research continues, we can expect to see more innovative designs that leverage the principles of radiation heating surfaces to create sustainable and energy-efficient solutions.In conclusion, the concept of a radiation heating surface is integral to modern heating technologies and energy efficiency strategies. By understanding how these surfaces work and optimizing their design, engineers can develop systems that provide effective heating while minimizing energy consumption. As technology advances, the potential for improved radiation heating surfaces will continue to grow, leading to more sustainable solutions in various industries. The importance of this concept cannot be overstated, as it directly impacts our ability to create comfortable living environments while addressing the challenges of energy conservation and sustainability.

在现代工程和设计中，辐射加热表面的概念在各种应用中发挥着至关重要的作用，特别是在供暖系统和能源效率技术中。辐射加热表面指的是任何发出热辐射以将热量传递给相邻介质（如空气或水）的表面。这一原理在许多领域至关重要，包括HVAC（供暖、通风和空调）、工业过程，甚至在日常电器如烤箱和加热器中。辐射加热表面的有效性可能会受到多个因素的影响，包括材料成分、表面纹理和温度。例如，具有高发射率的材料（如黑色表面）比光滑或反射材料更有效地辐射热量。这一特性对于设计供暖系统的工程师至关重要，因为他们必须选择合适的材料以最大限度地提高能源效率并减少热量损失。此外，辐射加热表面的大小和形状也会影响其性能。较大的表面积允许更多的热量传递，这就是为什么许多加热设备被设计成具有广泛表面的原因，以增加其加热能力。例如，在辐射地板供暖系统中，携带热水的管道被放置在地板表面下，有效地使整个地板成为辐射加热表面。这种设计不仅提供了舒适感，还确保了房间内的热量有效分布。理解辐射加热表面背后的原理对于提高建筑物的能源效率也至关重要。通过优化这些表面的设计和位置，工程师可以创建需要更少能量来维持舒适温度的系统。例如，使用依赖于辐射加热表面的红外加热器可以减少能源消耗，同时在住宅和商业空间中提供有效的温暖。除了传统的供暖系统，辐射加热表面的概念也在创新技术中得到探索，例如太阳能热系统。这些系统利用太阳的能量加热流体，然后用于空间供暖或热水生产。在这种情况下，辐射加热表面通常由能够有效吸收太阳辐射并将其转化为热量的材料制成，展示了这一概念在不同应用中的多样性和重要性。此外，材料科学的进步为开发新的辐射加热表面铺平了道路，这些表面能够在更高的效率下运行。例如，纳米技术正在被用于创建增强表面发射率的涂层，从而实现更好的热传递和节能。随着研究的不断深入，我们可以期待看到更多利用辐射加热表面原理的创新设计，以创造可持续和节能的解决方案。总之，辐射加热表面的概念与现代供暖技术和能源效率战略密切相关。通过理解这些表面的工作原理并优化其设计，工程师可以开发出有效提供加热同时最小化能源消耗的系统。随着技术的进步，改进的辐射加热表面的潜力将继续增长，从而在各个行业中带来更可持续的解决方案。这一概念的重要性不容小觑，因为它直接影响着我们创造舒适生活环境的能力，同时应对能源保护和可持续性挑战。