Brizuela-Mendoza, Jorge A.; Sorcia-Vázquez, Felipe D. J.; Rumbo-Morales, Jesse Y.; Ortiz-Torres, Gerardo; Torres-Cantero, Carlos Alberto; Juárez, Mario A.; Zatarain, Omar; Ramos-Martinez, Moises; Sarmiento-Bustos, Estela; Rodríguez-Cerda, Julio C.; Mixteco-Sánchez, Juan Carlos; Buenabad-Arias, Hector Miguel

doi:10.3390/pr11102997

Results

Title: Pressure Swing Adsorption Plant for the Recovery and Production of Biohydrogen: Optimization and Control.
Authors: Brizuela-Mendoza, Jorge A.; Sorcia-Vázquez, Felipe D. J.; Rumbo-Morales, Jesse Y.; Ortiz-Torres, Gerardo; Torres-Cantero, Carlos Alberto; Juárez, Mario A.; Zatarain, Omar; Ramos-Martinez, Moises; Sarmiento-Bustos, Estela; Rodríguez-Cerda, Julio C.; Mixteco-Sánchez, Juan Carlos; Buenabad-Arias, Hector Miguel
Abstract: New biofuels are in demand and necessary to address the climate problems caused by the gases generated by fossil fuels. Biohydrogen, which is a clean biofuel with great potential in terms of energy capacity, is currently impacting our world. However, to produce biohydrogen, it is necessary to implement novel processes, such as Pressure Swing Adsorption (PSA), which raise the purity of biohydrogen to 99.99% and obtain a recovery above 50% using lower energy efficiency. This paper presents a PSA plant to produce biohydrogen and obtain a biofuel meeting international criteria. It focuses on implementing controllers on the PSA plant to maintain the desired purity stable and attenuate disturbances that affect the productivity, recovery, and energy efficiency generated by the biohydrogen-producing PSA plant. Several rigorous tests were carried out to observe the purity behavior in the face of changes in trajectories and combined perturbations by considering a discrete observer-based LQR controller compared with a discrete PID control system. The PSA process controller is designed from a simplified model, evaluating its performance on the real nonlinear plant considering perturbations using specialized software. The results are compared with a conventional PID controller, giving rise to a significant contribution related to a biohydrogen purity stable (above 0.99 in molar fraction) in the presence of disturbances and achieving a recovery of 55% to 60% using an energy efficiency of 0.99% to 7.25%.
Subjects: PRESSURE swing adsorption process; ENERGY consumption; PID controllers; MOLE fraction; FOSSIL fuels; HYDROGEN as fuel
Publication: Processes, 2023, Vol 11, Issue 10, p2997
ISSN: 2227-9717
Publication type: Academic Journal
DOI: 10.3390/pr11102997

Pressure Swing Adsorption Plant for the Recovery and Production of Biohydrogen: Optimization and Control.

PRESSURE swing adsorption process; ENERGY consumption; PID controllers; MOLE fraction; FOSSIL fuels; HYDROGEN as fuel

Processes, 2023, Vol 11, Issue 10, p2997

2227-9717

Academic Journal

10.3390/pr11102997