Energy Efficiency of Gas Separation Pressure Swing Adsorption

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Energy Efficiency of Gas Separation Pressure Swing Adsorption ( energy-efficiency-gas-separation-pressure-swing-adsorption )

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Asbefore,wesubstitute inyi=yoandyi=0. US =BA U I = ?A U \ l + (B-l)y Now we calculate the time it takes for the shock wave to travel the length of the bed. Where: 51 time = distance / velocity I L (3.5) us tF = time for the shock wave to travel the length of the bed {s} LB= length of the bed {m} When we substitute in Equation (3.4), we find: PAUI This is the same as Knaebel and Hill's Equation (34). Now we can calculate the volume swept by the first piston during this step. Again, the piston travels at the same speed as the gas entering the bed because its cross- sectional area is equal to the open cross-sectional area of the bed, eA. volume = velocity * area * time VF2 — ux • s A-tF (37) 0 47

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Energy Efficiency of Gas Separation Pressure Swing Adsorption

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