Improvement of soluble coffee aroma using an integrated process of supercritical CO2 extraction with selective removal of the pungent volatiles by adsorption on activates carbon

In this paper a two-step integrated process consisting of CO2 supercritical extraction of volatile coffee compounds (the most valuable) from roasted and milled coffee, and a subsequent step of selective removal of pungent volatiles by adsorption on activated carbon is presented. Some experiments wer...

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Main Authors: S. Lucas, M. J. Cocero
Format: Article
Language:English
Published: Brazilian Society of Chemical Engineering 2006-06-01
Series:Brazilian Journal of Chemical Engineering
Subjects:
Online Access:http://www.scielo.br/scielo.php?script=sci_arttext&pid=S0104-66322006000200006
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spelling doaj-6d3a494c1ce5494481e961bd8610fbc52020-11-24T22:08:42ZengBrazilian Society of Chemical EngineeringBrazilian Journal of Chemical Engineering0104-66321678-43832006-06-0123219720310.1590/S0104-66322006000200006Improvement of soluble coffee aroma using an integrated process of supercritical CO2 extraction with selective removal of the pungent volatiles by adsorption on activates carbonS. LucasM. J. CoceroIn this paper a two-step integrated process consisting of CO2 supercritical extraction of volatile coffee compounds (the most valuable) from roasted and milled coffee, and a subsequent step of selective removal of pungent volatiles by adsorption on activated carbon is presented. Some experiments were carried out with key compounds from roasted coffee aroma in order to study the adsorption step: ethyl acetate as a desirable compound and furfural as a pungent component. Operational parameters such as adsorption pressure and temperature and CO2 flowrate were optimized. Experiments were conducted at adsorption pressures of 12-17 MPa, adsorption temperatures of 35-50ºC and a solvent flow rate of 3-5 kg/h. In all cases, the solute concentration and the activated particle size were kept constant. Results show that low pressures (12 MPa), low temperatures (35ºC) and low CO2 flowrates (3 kg/h) are suitable for removing the undesirable pungent and smell components (e.g. furfural) and retaining the desirable aroma compounds (e.g. ethyl acetate). The later operation with real roasted coffee has corroborated the previous results obtained with the key compounds.http://www.scielo.br/scielo.php?script=sci_arttext&pid=S0104-66322006000200006Coffee aromaSupercritical extractionSupercritical adsorptionActivated carbonSupercritical CO2
collection DOAJ
language English
format Article
sources DOAJ
author S. Lucas
M. J. Cocero
spellingShingle S. Lucas
M. J. Cocero
Improvement of soluble coffee aroma using an integrated process of supercritical CO2 extraction with selective removal of the pungent volatiles by adsorption on activates carbon
Brazilian Journal of Chemical Engineering
Coffee aroma
Supercritical extraction
Supercritical adsorption
Activated carbon
Supercritical CO2
author_facet S. Lucas
M. J. Cocero
author_sort S. Lucas
title Improvement of soluble coffee aroma using an integrated process of supercritical CO2 extraction with selective removal of the pungent volatiles by adsorption on activates carbon
title_short Improvement of soluble coffee aroma using an integrated process of supercritical CO2 extraction with selective removal of the pungent volatiles by adsorption on activates carbon
title_full Improvement of soluble coffee aroma using an integrated process of supercritical CO2 extraction with selective removal of the pungent volatiles by adsorption on activates carbon
title_fullStr Improvement of soluble coffee aroma using an integrated process of supercritical CO2 extraction with selective removal of the pungent volatiles by adsorption on activates carbon
title_full_unstemmed Improvement of soluble coffee aroma using an integrated process of supercritical CO2 extraction with selective removal of the pungent volatiles by adsorption on activates carbon
title_sort improvement of soluble coffee aroma using an integrated process of supercritical co2 extraction with selective removal of the pungent volatiles by adsorption on activates carbon
publisher Brazilian Society of Chemical Engineering
series Brazilian Journal of Chemical Engineering
issn 0104-6632
1678-4383
publishDate 2006-06-01
description In this paper a two-step integrated process consisting of CO2 supercritical extraction of volatile coffee compounds (the most valuable) from roasted and milled coffee, and a subsequent step of selective removal of pungent volatiles by adsorption on activated carbon is presented. Some experiments were carried out with key compounds from roasted coffee aroma in order to study the adsorption step: ethyl acetate as a desirable compound and furfural as a pungent component. Operational parameters such as adsorption pressure and temperature and CO2 flowrate were optimized. Experiments were conducted at adsorption pressures of 12-17 MPa, adsorption temperatures of 35-50ºC and a solvent flow rate of 3-5 kg/h. In all cases, the solute concentration and the activated particle size were kept constant. Results show that low pressures (12 MPa), low temperatures (35ºC) and low CO2 flowrates (3 kg/h) are suitable for removing the undesirable pungent and smell components (e.g. furfural) and retaining the desirable aroma compounds (e.g. ethyl acetate). The later operation with real roasted coffee has corroborated the previous results obtained with the key compounds.
topic Coffee aroma
Supercritical extraction
Supercritical adsorption
Activated carbon
Supercritical CO2
url http://www.scielo.br/scielo.php?script=sci_arttext&pid=S0104-66322006000200006
work_keys_str_mv AT slucas improvementofsolublecoffeearomausinganintegratedprocessofsupercriticalco2extractionwithselectiveremovalofthepungentvolatilesbyadsorptiononactivatescarbon
AT mjcocero improvementofsolublecoffeearomausinganintegratedprocessofsupercriticalco2extractionwithselectiveremovalofthepungentvolatilesbyadsorptiononactivatescarbon
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