TY - JOUR
T1 - Process Intensification via Structured Catalysts: Production of Sugar Alcohols
AU - Salmi, Tapio
AU - Barahona, German Araujo
AU - Najarnezhadmashhadi, Ali
AU - Braz, Catarina
AU - Torres, Alberto Goicoechea
AU - Ciaramella, Maria
AU - Ares, Emilia
AU - Russo, Vincenzo
AU - Serna, Juan Garcia
AU - Eränen, Kari
AU - Wärnå, Johan
AU - Matos, Henri
AU - Murzin, Dmitry
PY - 2024/12
Y1 - 2024/12
N2 - With the aid of structured catalysts and reactors, such as monoliths, solid foams, and 3D printed structures, the limitations of conventional slurry and packed‐bed reactors can be surmounted. Multiphase mathematical models were presented for solid foam structures and the models were verified for the hydrogenation of arabinose, galactose, and xylose to the corresponding sugar alcohols. High product selectivities were obtained in batch and continuous experiments. Three kinetic models were considered: a competitive adsorption model, a semi‐competitive adsorption model as well as a non‐competitive adsorption model for sugar monomers and hydrogen. The models gave a good reproduction of the data, but the semi‐competitive adsorption model was the most plausible one because of the size difference between adsorbed sugar and hydrogen molecules.
AB - With the aid of structured catalysts and reactors, such as monoliths, solid foams, and 3D printed structures, the limitations of conventional slurry and packed‐bed reactors can be surmounted. Multiphase mathematical models were presented for solid foam structures and the models were verified for the hydrogenation of arabinose, galactose, and xylose to the corresponding sugar alcohols. High product selectivities were obtained in batch and continuous experiments. Three kinetic models were considered: a competitive adsorption model, a semi‐competitive adsorption model as well as a non‐competitive adsorption model for sugar monomers and hydrogen. The models gave a good reproduction of the data, but the semi‐competitive adsorption model was the most plausible one because of the size difference between adsorbed sugar and hydrogen molecules.
U2 - 10.1002/cite.202400087
DO - 10.1002/cite.202400087
M3 - Article
SN - 0009-286X
VL - 96
JO - Chemie Ingenieur Technik
JF - Chemie Ingenieur Technik
IS - 12
ER -