Abstract
Erosion causes substantial damage in many industrial equipment such as pump components, valves, elbows, and plugged tees. In most cases, erosion is coupled with corrosion, resulting in major financial loss (nearly 3.4% of the global gross domestic product) as evidenced in oil and gas industries. In most cases, the erosion occurs in a submerged water medium. In this paper, erosion characteristics of stainless steel 316 were investigated computationally in a water-submerged jet impingement setup. The erosion profiles and patterns were obtained for various parameters over ranges of inlet velocities (3 to 16 m/s), nozzle diameters (5 to 10 mm), nozzle–target distances (5 to 20 mm), nozzle shapes (circular, elliptical, square, and rectangular), impingement angles (60° to 90°), and particle sizes (50 to 300 µm). The range of Reynolds number studied based on nozzle diameters is 21,000–120,000. The Eulerian–Lagrangian approach was used for flow field prediction and particle tracking considering one-way coupling for the particle–fluid interaction. The Finnie erosion model was implemented in ANSYS-Fluent 19.2 and used for erosion prediction. The computational model was validated against experimental data and the distributions of the erosion depth as well as the locations of the of maximum and minimum erosion points are well matched. As expected, the results indicate an increase in loss of material thickness with increasing jet velocity. Increasing the nozzle diameter caused a reduction in the maximum depth of eroded material due to decreasing the particle impact density. At a fixed fluid inlet velocity, the maximum thickness loss increases as the separation distance between the nozzle outlet and target increases, aspect ratio of nozzle shape decreases, and impingement angle increases. The erosion patterns showed that the region of substantial thickness loss increases as nozzle size/stand-off height increases and as particle size decreases. In addition, increasing the aspect ratio and impingement angle creates skewed erosion patterns.
Highlights
Solid particle erosion is a common phenomenon in industrial processes that transport fluid-laden particles
A numerical study of the erosion characteristics of solid–particle erosion of stainless steel 316 in a water-submerged jet impingement geometry was conducted to investigate the effects of various flow and geometric parameters, including the inlet velocity, particle size, nozzle shape and size, nozzle–target distance, and impingement angles
Erosion prediction was achieved through flow characteristics and particle tracking using the Eulerian–Lagrangian approach together with one-way coupling and erosion calculations us
Summary
Solid particle erosion is a common phenomenon in industrial processes that transport fluid-laden particles. Aponte et al [24] demonstrated the implementation of CFD in erosion prediction of materials commonly used in hydraulic machines They studied the effects of solid particle sizes (30, 100, and 300 μm) on erosion characteristics of 13Cr–4Ni stainless steel plate at various impact angles (15◦ –90◦ ). The effects of different parameters, namely nozzle–target distance, nozzle size, nozzle shape, nozzle inlet velocity, particle size, and jet impingement angle, on erosion characteristics are investigated. The study of these factors is important in industrial applications such as shell and tube heat exchangers where crossflow over the tubes causes major erosion when the fluid has erosive particles such as sand.
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