total heating surface

简明释义

总受热面总加热面

英英释义

例句

1.In our new design, we have expanded the total heating surface to enhance the heat transfer rate.

在我们的新设计中，我们扩大了总加热表面以增强热传递速率。

2.The boiler's efficiency is largely determined by its total heating surface, which refers to the overall area available for heat transfer.

锅炉的效率在很大程度上取决于其总加热表面，即可用于热交换的整体面积。

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表面。

4.Increasing the total heating surface can improve the thermal efficiency of the system.

增加总加热表面可以提高系统的热效率。

5.The total heating surface is a critical factor in determining the size of the heating equipment needed.

对于确定所需加热设备的大小来说，总加热表面是一个关键因素。

作文

In the field of thermodynamics and engineering, understanding the concept of total heating surface is essential for designing efficient heating systems. The total heating surface refers to the entire area available for heat transfer in a heating apparatus, such as boilers, heat exchangers, or furnaces. This surface plays a critical role in determining the efficiency of energy conversion processes, as it directly influences how effectively heat can be transferred from one medium to another.When engineers design heating systems, they must consider the total heating surface to ensure optimal performance. A larger total heating surface typically allows for more effective heat transfer, which can lead to increased efficiency and reduced fuel consumption. For example, in a boiler, the total heating surface includes all the surfaces that come into contact with the hot gases produced during combustion. By maximizing this area, engineers can improve the heat exchange process, ultimately resulting in lower operational costs and a smaller environmental footprint.Moreover, the total heating surface can be influenced by various factors, including the design of the heating equipment, the materials used, and the operating conditions. Different designs may offer varying total heating surface areas while maintaining similar functionality. For instance, a finned tube heat exchanger can provide a larger total heating surface compared to a smooth tube, due to the additional surface area created by the fins. This design innovation allows for enhanced heat transfer rates, making it a popular choice in many industrial applications.In addition to improving efficiency, understanding the total heating surface is also crucial for ensuring safety in heating systems. Insufficient heating surface area can lead to overheating and potential failures, which can pose significant risks in industrial settings. Engineers must carefully calculate the required total heating surface based on the specific heat load requirements of the application. This ensures that the system operates within safe limits and reduces the likelihood of accidents.Furthermore, the total heating surface has implications for maintenance and operational longevity. Systems designed with adequate heating surfaces tend to experience less wear and tear, as they operate more efficiently and at lower temperatures. This can extend the lifespan of the equipment and reduce the frequency of maintenance interventions. In contrast, systems with inadequate total heating surface may face more frequent issues, leading to higher costs and downtime.In conclusion, the concept of total heating surface is fundamental in the design and operation of heating systems. It encompasses the entire area available for heat transfer and significantly impacts the efficiency, safety, and longevity of these systems. Engineers must prioritize the optimization of the total heating surface in their designs to achieve better performance and sustainability in energy use. As industries continue to evolve and demand more efficient solutions, the importance of understanding and maximizing the total heating surface will only grow, driving innovation and advancements in engineering practices.

在热力学和工程领域，理解“总加热表面”的概念对于设计高效的加热系统至关重要。“总加热表面”是指加热设备（如锅炉、热交换器或炉子）中可用于热传递的整个区域。这个表面在决定能量转换过程的效率方面起着关键作用，因为它直接影响热量从一种介质传递到另一种介质的效果。当工程师设计加热系统时，他们必须考虑“总加热表面”以确保最佳性能。较大的“总加热表面”通常允许更有效的热传递，这可以导致效率提高和燃料消耗减少。例如，在锅炉中，“总加热表面”包括在燃烧过程中与产生的热气体接触的所有表面。通过最大化这个面积，工程师可以改善热交换过程，最终导致运营成本降低和环境足迹减小。此外，“总加热表面”还受到多种因素的影响，包括加热设备的设计、使用的材料和操作条件。不同的设计可能在保持类似功能的同时提供不同的“总加热表面”面积。例如，带翅片的管式热交换器由于翅片所创造的额外表面积，可以提供比光滑管更大的“总加热表面”，这种设计创新使其在许多工业应用中成为受欢迎的选择。除了提高效率，理解“总加热表面”对于确保加热系统的安全性也至关重要。加热表面不足可能导致过热和潜在故障，这在工业环境中可能构成重大风险。工程师必须根据特定的热负荷要求仔细计算所需的“总加热表面”，以确保系统在安全范围内运行，减少事故发生的可能性。此外，“总加热表面”对维护和操作寿命也有影响。设计有足够加热表面的系统往往会经历更少的磨损，因为它们更有效地在较低的温度下运行。这可以延长设备的使用寿命，并减少维护干预的频率。相比之下，加热表面不足的系统可能面临更频繁的问题，从而导致更高的成本和停机时间。总之，“总加热表面”的概念在加热系统的设计和操作中是基础性的。它涵盖了可用于热传递的整个区域，并对这些系统的效率、安全性和耐用性产生重大影响。工程师必须在设计中优先考虑优化“总加热表面”，以实现更好的性能和可持续的能源使用。随着行业的不断发展和对更高效解决方案的需求增加，理解和最大化“总加热表面”的重要性将日益增长，推动工程实践中的创新和进步。