Nonlinear frequency response analysis of nonisothermal adsorption controlled by macropore diffusion
Abstract
In this work, a nonlinear frequency response (NFR) approach is used for a theoretical study of nonisothermal adsorption controlled by macropore diffusion (NMD). Based on the nonlinear mathematical model on the particle scale for spherical geometry, the theoretical frequency response functions (FRFs) up to the second order have been derived, using the concept of higher-order FRFs. The FRFs for isothermal macropore diffusion model have also been derived for comparison. For the NMD model two series of FRFs define the process: one which relates the sorbate concentration in the particle to the pressure (F) and the other which relates the particle temperature to the pressure (Z). The obtained FRFs were simulated for seven different sets of parameters. The second-order F function exhibits specific bimodal pattern, which enables separation of the diffusional and heat-transfer time constant. The high-frequency asymptotic features of the second-order F function discriminates the NMD mechanism fr...om micropore-macropore diffusion control. Based on the characteristic of the first- and second-order F and Z functions, the new procedure for direct estimation of the diffusional and heat-transfer time constants is proposed. Additionally, some equilibrium parameters, as well as the heat of adsorption, can also be estimated. The NFR approach shows significant advantages regarding analysis of NMD compared to the linear FR method.
Keywords:
Nonlinear frequency response / Gas adsorption / Nonisothermal macropore diffusion / Parameter estimationSource:
Chemical Engineering Science, 2014, 118, 141-153Publisher:
- Pergamon-Elsevier Science Ltd, Oxford
Funding / projects:
DOI: 10.1016/j.ces.2014.07.033
ISSN: 0009-2509
WoS: 000341412000014
Scopus: 2-s2.0-84905695934
Institution/Community
Tehnološko-metalurški fakultetTY - JOUR AU - Brzić, Danica AU - Petkovska, Menka PY - 2014 UR - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2659 AB - In this work, a nonlinear frequency response (NFR) approach is used for a theoretical study of nonisothermal adsorption controlled by macropore diffusion (NMD). Based on the nonlinear mathematical model on the particle scale for spherical geometry, the theoretical frequency response functions (FRFs) up to the second order have been derived, using the concept of higher-order FRFs. The FRFs for isothermal macropore diffusion model have also been derived for comparison. For the NMD model two series of FRFs define the process: one which relates the sorbate concentration in the particle to the pressure (F) and the other which relates the particle temperature to the pressure (Z). The obtained FRFs were simulated for seven different sets of parameters. The second-order F function exhibits specific bimodal pattern, which enables separation of the diffusional and heat-transfer time constant. The high-frequency asymptotic features of the second-order F function discriminates the NMD mechanism from micropore-macropore diffusion control. Based on the characteristic of the first- and second-order F and Z functions, the new procedure for direct estimation of the diffusional and heat-transfer time constants is proposed. Additionally, some equilibrium parameters, as well as the heat of adsorption, can also be estimated. The NFR approach shows significant advantages regarding analysis of NMD compared to the linear FR method. PB - Pergamon-Elsevier Science Ltd, Oxford T2 - Chemical Engineering Science T1 - Nonlinear frequency response analysis of nonisothermal adsorption controlled by macropore diffusion EP - 153 SP - 141 VL - 118 DO - 10.1016/j.ces.2014.07.033 ER -
@article{ author = "Brzić, Danica and Petkovska, Menka", year = "2014", abstract = "In this work, a nonlinear frequency response (NFR) approach is used for a theoretical study of nonisothermal adsorption controlled by macropore diffusion (NMD). Based on the nonlinear mathematical model on the particle scale for spherical geometry, the theoretical frequency response functions (FRFs) up to the second order have been derived, using the concept of higher-order FRFs. The FRFs for isothermal macropore diffusion model have also been derived for comparison. For the NMD model two series of FRFs define the process: one which relates the sorbate concentration in the particle to the pressure (F) and the other which relates the particle temperature to the pressure (Z). The obtained FRFs were simulated for seven different sets of parameters. The second-order F function exhibits specific bimodal pattern, which enables separation of the diffusional and heat-transfer time constant. The high-frequency asymptotic features of the second-order F function discriminates the NMD mechanism from micropore-macropore diffusion control. Based on the characteristic of the first- and second-order F and Z functions, the new procedure for direct estimation of the diffusional and heat-transfer time constants is proposed. Additionally, some equilibrium parameters, as well as the heat of adsorption, can also be estimated. The NFR approach shows significant advantages regarding analysis of NMD compared to the linear FR method.", publisher = "Pergamon-Elsevier Science Ltd, Oxford", journal = "Chemical Engineering Science", title = "Nonlinear frequency response analysis of nonisothermal adsorption controlled by macropore diffusion", pages = "153-141", volume = "118", doi = "10.1016/j.ces.2014.07.033" }
Brzić, D.,& Petkovska, M.. (2014). Nonlinear frequency response analysis of nonisothermal adsorption controlled by macropore diffusion. in Chemical Engineering Science Pergamon-Elsevier Science Ltd, Oxford., 118, 141-153. https://doi.org/10.1016/j.ces.2014.07.033
Brzić D, Petkovska M. Nonlinear frequency response analysis of nonisothermal adsorption controlled by macropore diffusion. in Chemical Engineering Science. 2014;118:141-153. doi:10.1016/j.ces.2014.07.033 .
Brzić, Danica, Petkovska, Menka, "Nonlinear frequency response analysis of nonisothermal adsorption controlled by macropore diffusion" in Chemical Engineering Science, 118 (2014):141-153, https://doi.org/10.1016/j.ces.2014.07.033 . .