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N „£lcP (5.2) '_ RT Where: NG,I = number of moles in gas phase in cell {mol} Vc = cell volume {m3} If we assume an incremental change in pressure dP, the change in gas phase moles will be: Where: eVc dP RT (c o) dNci = incremental change in gas phase moles {mol} The total number of moles in the adsorbed phase is found by adding the two isotherm equations: _kA-y,P-(l-e)Vc ; kB-(\-yi)P-(l-e)Vc ( 5 A ) AD,i Rj, RT Where: NAD,I = moles stored in adsorbed phase {mol} The incremental change in adsorbed phase moles due to a change in mole fraction or pressure is seen in Equation (5.5). dN, =(AZ§TLlk*d(y'P)+k°dP-k°*M (5'5) AD 131PDF Image | Energy Efficiency of Gas Separation Pressure Swing Adsorption
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