total heating surface

简明释义

总受热面

英英释义

例句

1.In this design, we have maximized the total heating surface to improve energy transfer.

在这个设计中，我们最大化了总加热面积以改善能量传递。

2.Increasing the total heating surface can lead to better thermal efficiency in industrial processes.

增加总加热面积可以提高工业过程中的热效率。

3.To optimize performance, engineers must calculate the total heating surface of the heat exchanger accurately.

为了优化性能，工程师必须准确计算热交换器的总加热面积。

4.The total heating surface is crucial for ensuring that steam generation meets production demands.

确保蒸汽生成满足生产需求的关键是总加热面积。

5.The efficiency of the boiler is determined by its total heating surface, which refers to the area available for heat transfer.

锅炉的效率取决于其总加热面积，即可用于热传递的面积。

作文

In the world of engineering and thermodynamics, understanding the concept of total heating surface is crucial for the design and efficiency of various heating systems. The total heating surface refers to the entire area of a heating element that is available for transferring heat to a fluid or gas. This measurement plays a significant role in determining how effectively a heating system can operate, particularly in applications such as boilers, heat exchangers, and other thermal devices.To elaborate on the importance of the total heating surface, let's consider a practical example involving a steam boiler. In such a system, the goal is to generate steam efficiently by heating water. The more extensive the total heating surface, the greater the amount of heat that can be transferred from the hot gases produced during combustion to the water inside the boiler. This efficient heat transfer is vital because it directly impacts the overall performance and efficiency of the boiler.Moreover, when designing a heating system, engineers must carefully calculate the total heating surface to ensure that the system meets the required specifications for heat output. If the total heating surface is too small, the system may not produce enough heat, leading to inadequate performance and potentially increased operational costs. Conversely, an excessively large total heating surface can result in unnecessary material expenses and could lead to inefficiencies in the system due to lower temperatures and slower heat transfer rates.Another aspect to consider is the relationship between the total heating surface and the type of fuel used in the heating process. Different fuels have varying combustion characteristics, which can affect the temperature and flow of gases. Engineers must take these factors into account when designing the total heating surface to optimize the heat exchange process. For instance, using a fuel that burns hotter may allow for a smaller total heating surface, while a cooler-burning fuel would necessitate a larger area to achieve the same heating effect.Furthermore, the total heating surface is also influenced by the materials used in the construction of the heating elements. Materials with high thermal conductivity will enhance the efficiency of heat transfer, allowing for a more effective use of the total heating surface. Therefore, selecting appropriate materials is essential for maximizing the performance of any heating system.In conclusion, the concept of total heating surface is integral to the field of thermal engineering. It not only determines the efficiency of heat transfer but also affects the overall design and cost-effectiveness of heating systems. As industries continue to evolve and demand more efficient heating solutions, a thorough understanding of the total heating surface will remain a fundamental aspect of engineering practice. By optimizing this parameter, engineers can contribute to more sustainable and economically viable heating technologies, ultimately benefiting both the environment and society as a whole.

在工程和热力学的世界中，理解总加热表面的概念对于各种加热系统的设计和效率至关重要。总加热表面是指可用于将热量传递给流体或气体的加热元件的整个面积。这个测量在确定加热系统的有效运行中扮演着重要角色，特别是在锅炉、热交换器和其他热设备等应用中。为了详细说明总加热表面的重要性，我们考虑一个涉及蒸汽锅炉的实际例子。在这样的系统中，目标是通过加热水高效地产生蒸汽。总加热表面越大，从燃烧过程中产生的热气体向锅炉内的水转移的热量就越多。这种高效的热量转移至关重要，因为它直接影响锅炉的整体性能和效率。此外，在设计加热系统时，工程师必须仔细计算总加热表面，以确保系统满足所需的热输出规格。如果总加热表面太小，系统可能无法产生足够的热量，导致性能不足并可能增加运营成本。相反，过大的总加热表面会导致不必要的材料费用，并可能由于温度较低和热传递速率较慢而导致系统效率降低。另一个需要考虑的方面是总加热表面与加热过程中使用的燃料类型之间的关系。不同的燃料具有不同的燃烧特性，这可能会影响气体的温度和流动。工程师在设计总加热表面时必须考虑这些因素，以优化热交换过程。例如，使用燃烧温度更高的燃料可能允许较小的总加热表面，而燃烧温度较低的燃料则需要更大的面积才能达到相同的加热效果。此外，总加热表面还受到加热元件制造材料的影响。具有高热导率的材料将提升热量传递的效率，从而更有效地利用总加热表面。因此，选择适当的材料对于最大限度地提高任何加热系统的性能至关重要。总之，总加热表面的概念是热工程领域不可或缺的一部分。它不仅决定了热量传递的效率，还影响着加热系统的整体设计和经济性。随着工业的不断发展，对更高效加热解决方案的需求日益增加，对总加热表面的透彻理解仍将是工程实践的基本方面。通过优化这一参数，工程师可以为更加可持续和经济的加热技术贡献力量，最终使环境和社会整体受益。