TY - JOUR
T1 - Monolithic fiber/foam-structured catalysts
T2 - beyond honeycombs and micro-channels
AU - Zhao, Guofeng
AU - Moulijn, Jacob A.
AU - Kapteijn, Frederik
AU - Dautzenberg, Frits M.
AU - Xu, Bin
AU - Lu, Yong
N1 - Publisher Copyright:
© 2023 Taylor & Francis Group, LLC.
PY - 2024
Y1 - 2024
N2 - Heterogeneous catalysis plays a pivotal role in the current chemical and energy vectors production. Notably, to fully utilize the intrinsic activity and selectivity of a catalyst, the chemical reactor has to be designed and operated optimally to achieve enhanced heat/mass transfer, well-defined contact time of reactants, uniform flow pattern, and high permeability. Structured catalysts are a promising strategy to overcome the major drawbacks encountered in the traditional packed-bed reactor technology due to the improved hydrodynamics in combination with enhanced heat/mass transfer. Newly emerged fiber/foam-substrates, with an entirely open 3D network structure, bring distinct advantages over the honeycomb and micro-channel contacting methods, including free radial diffusion, eddy-mixing driven heat/mass transfer, large area-to-volume ratio, and high contacting efficiency. However, how to place the nanocatalysts onto the fiber/foam-substrates is a challenging problem because the commercial washcoating method has great limitations such as the nonuniformity and easy exfoliation of coatings. This review discusses the newly developed non-dip-coating methods for the fiber/foam-structured catalysts and their promising applications in the strongly exo-/endo-thermic and/or high throughput reaction processes.
AB - Heterogeneous catalysis plays a pivotal role in the current chemical and energy vectors production. Notably, to fully utilize the intrinsic activity and selectivity of a catalyst, the chemical reactor has to be designed and operated optimally to achieve enhanced heat/mass transfer, well-defined contact time of reactants, uniform flow pattern, and high permeability. Structured catalysts are a promising strategy to overcome the major drawbacks encountered in the traditional packed-bed reactor technology due to the improved hydrodynamics in combination with enhanced heat/mass transfer. Newly emerged fiber/foam-substrates, with an entirely open 3D network structure, bring distinct advantages over the honeycomb and micro-channel contacting methods, including free radial diffusion, eddy-mixing driven heat/mass transfer, large area-to-volume ratio, and high contacting efficiency. However, how to place the nanocatalysts onto the fiber/foam-substrates is a challenging problem because the commercial washcoating method has great limitations such as the nonuniformity and easy exfoliation of coatings. This review discusses the newly developed non-dip-coating methods for the fiber/foam-structured catalysts and their promising applications in the strongly exo-/endo-thermic and/or high throughput reaction processes.
KW - Catalytic distillation
KW - catalytic functionalization
KW - electrocatalysis
KW - environmental protection
KW - fiber
KW - foam
KW - heat/mass transfer
KW - heterogeneous catalysis
KW - hydrogenation
KW - monolithic catalyst
KW - non-dip-coating
KW - oxidation
KW - process intensification
KW - reforming
KW - structured catalyst
KW - supercapacitors
KW - syngas conversion
UR - https://www.scopus.com/pages/publications/85166947961
U2 - 10.1080/01614940.2023.2240661
DO - 10.1080/01614940.2023.2240661
M3 - 文章
AN - SCOPUS:85166947961
SN - 0161-4940
VL - 66
SP - 1870
EP - 1950
JO - Catalysis Reviews - Science and Engineering
JF - Catalysis Reviews - Science and Engineering
IS - 5
ER -