TY - JOUR
T1 - Droplet Size Distribution in Twin Fluid Nozzle for Modern FCC Riser
AU - Kumar, Deepak
AU - Kushari, Abhijit
AU - Kumar, Pramod
AU - Mishra, Hemant
N1 - Publisher Copyright:
© 2024 Authors.
PY - 2024
Y1 - 2024
N2 - This study examines the spray characteristics of a specially designed nozzle tailored for riser applications. Through rigorous experimental analysis, the research aims to pinpoint the optimal operational parameters for the nozzle's design. Extensive experimental evaluations are conducted to gauge the atomizing performance of a twin-fluid injector and its potential integration into contemporary FCC feed systems. The innovative twin-fluid injector incorporates an impactor bolt strategically positioned at varying distances ahead of the liquid jet to enhance mixing dynamics and atomization performance. Using water and compressed air as working fluids, droplet sizes, and velocities are precisely measured by employing a phase Doppler particle analyzer. Results reveal a reduction in droplet size, as evidenced by a decrease in the SMD, attributed to the impactor bolt positioned 5 mm away from the center of the air injection orifice. Furthermore, the displacement of the spray axis, opposite the positioning of the impactor bolt, significantly influences droplet mean velocity. Droplet size diminishes with increasing mixing length, particularly in the core region, signifying improved atomization. Despite variations in slit size, both configurations exhibit a similar trend of decreasing droplet size with increasing mixing length, particularly evident in the core region, suggesting enhanced atomization. Thus, the effect of slit size on outcomes appears to be less significant compared to the impact of mixing length.
AB - This study examines the spray characteristics of a specially designed nozzle tailored for riser applications. Through rigorous experimental analysis, the research aims to pinpoint the optimal operational parameters for the nozzle's design. Extensive experimental evaluations are conducted to gauge the atomizing performance of a twin-fluid injector and its potential integration into contemporary FCC feed systems. The innovative twin-fluid injector incorporates an impactor bolt strategically positioned at varying distances ahead of the liquid jet to enhance mixing dynamics and atomization performance. Using water and compressed air as working fluids, droplet sizes, and velocities are precisely measured by employing a phase Doppler particle analyzer. Results reveal a reduction in droplet size, as evidenced by a decrease in the SMD, attributed to the impactor bolt positioned 5 mm away from the center of the air injection orifice. Furthermore, the displacement of the spray axis, opposite the positioning of the impactor bolt, significantly influences droplet mean velocity. Droplet size diminishes with increasing mixing length, particularly in the core region, signifying improved atomization. Despite variations in slit size, both configurations exhibit a similar trend of decreasing droplet size with increasing mixing length, particularly evident in the core region, suggesting enhanced atomization. Thus, the effect of slit size on outcomes appears to be less significant compared to the impact of mixing length.
KW - Atomization
KW - Fluidized Catalytic Cracking
KW - Impactor bolt
KW - Mixing length
KW - Slit Size
KW - Twin Fluid Injector
UR - http://www.scopus.com/inward/record.url?scp=85210102338&partnerID=8YFLogxK
U2 - 10.11159/jffhmt.2024.036
DO - 10.11159/jffhmt.2024.036
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AN - SCOPUS:85210102338
SN - 2368-6111
VL - 11
SP - 363
EP - 375
JO - Journal of Fluid Flow, Heat and Mass Transfer
JF - Journal of Fluid Flow, Heat and Mass Transfer
ER -