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Hydrogenation of butynediol to cis‐butenediol catalyzed by Pd‐Zn‐CaCO 3 : Reaction kinetics and modeling of a batch slurry reactor
Author(s) -
Chaudhari R. V.,
Parande M. G.,
Ramachandran P. A.,
Brahme P. H.,
Vadgaonkar H. G.,
Jaganathan R.
Publication year - 1985
Publication title -
aiche journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.958
H-Index - 167
eISSN - 1547-5905
pISSN - 0001-1541
DOI - 10.1002/aic.690311114
Subject(s) - chemistry , slurry , catalysis , batch reactor , kinetics , activation energy , reaction rate , reaction rate constant , thermodynamics , kinetic energy , partial pressure , chemical kinetics , mass transfer , atmospheric temperature range , analytical chemistry (journal) , chromatography , organic chemistry , physics , quantum mechanics , oxygen
An experimental study of the kinetics of hydrogenation of butynediol has been reported using Pd‐Zn‐Ca 3 catalyst in a slurry reactor. The effects of catalyst loading, butynediol concentration, H 2 partial pressure, butenediol (product concentration, temperature, and agitation speed on the rate of hydrogenation have been studied using a stirred pressure reactor). The initial rate data shwoed that the rate is proportional to the square root of H 2 pressure, while increase in butynediol concentration inhibited the reaction. A Langmuir‐Hinshelwood‐type rate model has been proposed based on these data and the kinetic parameters evaluated. The values of the activation energy E and the heat of adsorption of butynediol (−Δ H ) evaluated were 38.30 kJ/mol and –9.87 kJ/mol, respectively. Batch reactor models were derived based on the rate expression obtained from the initial rate data for variable pressure as well as constant pressure conditions. The prediction of the model were compared with experimental data obtained over a wide range of conditions. The predictions of the model were compared with experimental data obtained over a wide range of conditions. The results agreed well within 5–7% error. Use of the pressure vs. time data for evaluation of kinetic and mass transfer parameters is also demonstrated.