Journal of Engineering Research and Reports

This study explores the intricate relationship between wind speed and structural vibrations, with a particular focus on water cooling systems in oil plants. Water cooling is a vital process in the oil and gas industry, used to dissipate excess heat generated during operations such as refining and petrochemical production. The efficient functioning of these systems is crucial to prevent overheating, which can lead to equipment failure and operational inefficiencies. The research utilizes a comprehensive dataset collected over six months, comprising 8688 observations, to perform a regression analysis that quantifies the impact of wind speed on vibration levels. The findings indicate a significant positive correlation, suggesting that as wind speed increases, so does the vibration within the system. This correlation highlights the influence of wind-induced forces on structural dynamics, potentially exacerbating mechanical wear and risking structural integrity. By understanding these dynamics, engineers can design more robust and resilient cooling systems capable of withstanding external environmental factors like wind. The results of this study provide essential insights for improving the design and maintenance strategies of water cooling systems, ensuring their efficiency and reliability in oil plants, especially in wind-prone regions. To evaluate the system's condition, vibration levels are continuously monitored and analyzed using key criteria such as mechanical stability, vibration intensity, and the system’s ability to maintain operational efficiency under varying wind conditions. These insights help identify critical points where vibrations could compromise the cooling system's performance. This methodology ensures a comprehensive assessment of how wind-induced forces affect system stability.