actual skin factor

简明释义

1. 实际表皮因子; 2. 实际表皮系数;

英英释义

例句

1.In reservoir studies, understanding the actual skin factor is crucial for accurate predictions.

在油藏研究中，理解实际皮肤系数对准确预测至关重要。

2.The actual skin factor was found to be higher than expected, leading to lower output.

发现实际皮肤系数高于预期，导致产量降低。

3.The actual skin factor can significantly affect production rates in oil fields.

在油田中，实际皮肤系数可以显著影响产量。

4.We need to adjust our models to account for the actual skin factor observed in the field.

我们需要调整模型以考虑现场观察到的实际皮肤系数。

5.The engineer calculated the actual skin factor to determine the efficiency of the well.

工程师计算了实际皮肤系数以确定井的效率。

作文

Understanding the concept of the actual skin factor is essential in various fields, particularly in engineering and physics. The actual skin factor refers to the effective surface area of a material that is in contact with a fluid or gas. This term is crucial when analyzing heat transfer, mass transfer, and fluid dynamics. In essence, it helps us understand how much of a surface is actually interacting with another substance, which can significantly affect the efficiency of processes such as heat exchangers or chemical reactors.To illustrate this concept, let’s consider a practical example in the field of heat exchangers. A heat exchanger is designed to transfer heat between two or more fluids. The performance of a heat exchanger depends heavily on the actual skin factor. If the surface area that is effectively participating in the heat exchange process is small, the rate of heat transfer will be lower than expected, leading to inefficiencies.Moreover, the actual skin factor can vary due to factors such as fouling, corrosion, or the presence of insulating layers. For instance, if a heat exchanger becomes fouled with deposits, the actual skin factor decreases because the fouling layer acts as an insulator, reducing the effective area available for heat transfer. This highlights the importance of regular maintenance and cleaning to ensure that the actual skin factor remains optimal.In addition to heat exchangers, the actual skin factor is also relevant in chemical engineering processes. During reactions that occur on surfaces, the actual skin factor can influence the reaction rates. A larger effective surface area means more active sites are available for the reaction, which can lead to faster reaction rates. Conversely, if there are barriers or coatings that reduce the actual skin factor, the reaction may proceed more slowly.Furthermore, in environmental engineering, the actual skin factor plays a role in processes like adsorption and filtration. When designing filters or adsorbents, understanding the actual skin factor allows engineers to predict how effectively these systems will remove contaminants from water or air. A higher actual skin factor indicates a greater capacity for adsorption, which is critical for ensuring clean water and air.In conclusion, the actual skin factor is a vital parameter in many scientific and engineering disciplines. It provides insights into the interactions between surfaces and fluids, influencing efficiency and performance in various applications. By understanding and optimizing the actual skin factor, engineers and scientists can enhance the effectiveness of systems ranging from heat exchangers to environmental filtration processes. Therefore, it is crucial to consider the actual skin factor in design and operational strategies to achieve better outcomes.

理解实际表面因子的概念在多个领域中至关重要，尤其是在工程和物理学中。实际表面因子是指与流体或气体接触的材料的有效表面积。这个术语在分析热传递、质量传递和流体动力学时非常关键。实质上，它帮助我们理解一个表面有多少部分实际上与另一种物质相互作用，这可以显著影响诸如热交换器或化学反应器等过程的效率。为了说明这一概念，让我们考虑热交换器领域的一个实际例子。热交换器旨在在两种或多种流体之间转移热量。热交换器的性能在很大程度上依赖于实际表面因子。如果有效参与热交换过程的表面积较小，热传递速率将低于预期，从而导致效率低下。此外，实际表面因子可能由于污垢、腐蚀或绝缘层的存在而有所不同。例如，如果热交换器因沉积物而变得污垢，实际表面因子将减少，因为污垢层充当绝缘体，降低了可用于热传递的有效面积。这突显了定期维护和清洁的重要性，以确保实际表面因子保持最佳。除了热交换器，实际表面因子在化学工程过程中也很相关。在发生在表面上的反应中，实际表面因子会影响反应速率。更大的有效表面积意味着更多的活性位点可供反应使用，这可以导致更快的反应速率。相反，如果存在降低实际表面因子的障碍物或涂层，反应可能会更慢进行。此外，在环境工程中，实际表面因子在吸附和过滤等过程中也起着作用。在设计过滤器或吸附剂时，理解实际表面因子使工程师能够预测这些系统去除水或空气中污染物的效果。较高的实际表面因子表示更大的吸附能力，这对于确保清洁的水和空气至关重要。总之，实际表面因子是许多科学和工程学科中的一个重要参数。它提供了有关表面与流体之间相互作用的见解，影响各种应用中的效率和性能。通过理解和优化实际表面因子，工程师和科学家可以提高从热交换器到环境过滤过程的系统的有效性。因此，在设计和操作策略中考虑实际表面因子以获得更好的结果至关重要。