Thermal Performance Assessment of Heat Exchangers In An Industrial Ethylene Production Facility
Keywords:
heat-exchanger, heat, performance, energyAbstract
This study provides a comprehensive performance assessment of three critical heat exchanger units (2-H-301, 3-H-601, and 3-H-501) within an industrial Ethylene production facility in Ras Lanuf plant. Steady-state monitoring and direct data acquisition from operational equipment were conducted with subsequent data analysis performed using energy balance equations to quantify key thermal performance parameters. These parameters included overall heat transfer coefficients, heat duties, hot and cold fluid temperature and pressure ranges, capacity ratios, and effectiveness of each exchanger. Results reveal that the 2-H-2301 unit exhibits an overall heat transfer coefficient over 50% below the design specification and a heat duty exceeding 80% of the intended design. In the 3-H-901 unit, both heat duty and overall heat transfer coefficient were observed to fall over 75% below design standards, likely due to fouling, which adversely impacted effectiveness, capacity ratio, and the temperature profile of hot and cold streams. Conversely, performance of the 3-E-401 exchanger was within acceptable limits, with the heat duty, hot-side temperature differential, and capacity ratio aligning closely with design expectations. These findings offer a rigorous qualitative performance evaluation of the heat exchangers, highlighting areas requiring operational optimization to maintain design efficiency within industrial polyethylene processes.
Downloads
References
[1]. B. T. Lebele-Alawa, I. O. Ohia “Performance evaluation of heat exchangers in a polyethylene plant” International Journal of Engineering and Technology Innovation 3(1):49-57; 2013
[2]. F.O.Jegede and G.T. Polly, “Optimum heat exchanger design,” Transactions of the institution of Chemical Engineers 70 (Part A), pp. 133-141, 1992
[3]. M. Kelvin “Increasing Heat Exchanger Performance” Procurement of Bryan Research and Engineering incorporated, Bryan, Texas pp1-13, 2006
[4]. H. U. Zettler, M. Weis, Q. Zhao, H. Muller-Steinhagen. “Influence of surface properties and characteristics on fouling in plate heat exchangers. Heat Transfer Engineering 26(2):3-17; 2005.
[5]. K. H. Othman “Computional Fluid Dynamic simulation of Heat Transfer in Shell and Tube Exchanger” B.Sc project, Faculty of Chemical and Natural Resources Engineering, University of Malaysia, 2009
[6]. E. LAYTON, History of Heat Transfer: Essays in the Honor of the 50th Anniversary of the ASME Heat Transfer Division, date and location unknown.
[7]. Book How Heat Exchangers have evolved over time by Engineer Mehol k Mehta.
[8]. HEAT EXCHANGERS Prepared by Bob Heaslip KESCO For Queens University CHEE 470 –Fall 2007
[9]. Perry, J.H. & D.W Green, Ed., Chemical Engineers Handbook, 7th Ed., McGraw-Hill (1997)Book Co., Inc.
[10]. "Types of Heat Exchangers in Oil & Gas". (2019/10/8).
[11]. Padet, J., EchangeursThermiques, Masson, Paris, France, 1994.
[12]. Tubular Exchanger Manufacturers Association (TEMA), Standards of the Tubular Exchanger Manufacturers Association, 7th ed., New York, 1988.
