The aim of this study was to determine the effect of the main milling variables, i.e., agitator shaft speed (50, 75 and 100%, which is 25, 37.5 and 50 rpm) and milling time (30, 45 and 60 min) on physical and sensory properties of fat tilling as well as on energy consumption during the production in a laboratory ball mill. Within the response surface method, the face centered central composite design is used. A response surface regression analysis for responses was performed and a full quadratic model was fitted to the experimental data. It is shown that agitator shaft speed had the most significant influence on physical properties (particle size distribution, rheological and textural propertes) and sensory characteristics of fat tilling while the milling energy consumption is highly influenced by milling time with contribution 55.4%, followed by agitator shaft speed (40.04%). The model obtained by regression analyses was used to perform the optimization of processing parameters in ord...er to provide the combination of agitator shaft speed and milling time that cost less energy while at the same time do not compromise the quality of the fat filling. Optimization of production of fat filling in a laboratory ball mill would imply the maximum agitator shaft speed and 30-min milling time.
TY - JOUR
AU - Lončarević, Ivana
AU - Fistes, Aleksandar Z.
AU - Rakić, Dušan Z.
AU - Pajin, Biljana
AU - Petrović, Jovana S.
AU - Torbica, Aleksandra
AU - Zarić, Danica
PY - 2017
UR - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/3584
AB - The aim of this study was to determine the effect of the main milling variables, i.e., agitator shaft speed (50, 75 and 100%, which is 25, 37.5 and 50 rpm) and milling time (30, 45 and 60 min) on physical and sensory properties of fat tilling as well as on energy consumption during the production in a laboratory ball mill. Within the response surface method, the face centered central composite design is used. A response surface regression analysis for responses was performed and a full quadratic model was fitted to the experimental data. It is shown that agitator shaft speed had the most significant influence on physical properties (particle size distribution, rheological and textural propertes) and sensory characteristics of fat tilling while the milling energy consumption is highly influenced by milling time with contribution 55.4%, followed by agitator shaft speed (40.04%). The model obtained by regression analyses was used to perform the optimization of processing parameters in order to provide the combination of agitator shaft speed and milling time that cost less energy while at the same time do not compromise the quality of the fat filling. Optimization of production of fat filling in a laboratory ball mill would imply the maximum agitator shaft speed and 30-min milling time.
PB - Savez hemijskih inženjera, Beograd
T2 - Chemical Industry & Chemical Engineering Quarterly
T1 - Optimization of the ball mill processing parameters in the fat filling production
EP - 206
IS - 2
SP - 197
VL - 23
DO - 10.2298/CICEQ151217031L
ER -
@article{
author = "Lončarević, Ivana and Fistes, Aleksandar Z. and Rakić, Dušan Z. and Pajin, Biljana and Petrović, Jovana S. and Torbica, Aleksandra and Zarić, Danica",
year = "2017",
abstract = "The aim of this study was to determine the effect of the main milling variables, i.e., agitator shaft speed (50, 75 and 100%, which is 25, 37.5 and 50 rpm) and milling time (30, 45 and 60 min) on physical and sensory properties of fat tilling as well as on energy consumption during the production in a laboratory ball mill. Within the response surface method, the face centered central composite design is used. A response surface regression analysis for responses was performed and a full quadratic model was fitted to the experimental data. It is shown that agitator shaft speed had the most significant influence on physical properties (particle size distribution, rheological and textural propertes) and sensory characteristics of fat tilling while the milling energy consumption is highly influenced by milling time with contribution 55.4%, followed by agitator shaft speed (40.04%). The model obtained by regression analyses was used to perform the optimization of processing parameters in order to provide the combination of agitator shaft speed and milling time that cost less energy while at the same time do not compromise the quality of the fat filling. Optimization of production of fat filling in a laboratory ball mill would imply the maximum agitator shaft speed and 30-min milling time.",
publisher = "Savez hemijskih inženjera, Beograd",
journal = "Chemical Industry & Chemical Engineering Quarterly",
title = "Optimization of the ball mill processing parameters in the fat filling production",
pages = "206-197",
number = "2",
volume = "23",
doi = "10.2298/CICEQ151217031L"
}
Lončarević, I., Fistes, A. Z., Rakić, D. Z., Pajin, B., Petrović, J. S., Torbica, A.,& Zarić, D.. (2017). Optimization of the ball mill processing parameters in the fat filling production. in Chemical Industry & Chemical Engineering Quarterly
Savez hemijskih inženjera, Beograd., 23(2), 197-206.
https://doi.org/10.2298/CICEQ151217031L
Lončarević I, Fistes AZ, Rakić DZ, Pajin B, Petrović JS, Torbica A, Zarić D. Optimization of the ball mill processing parameters in the fat filling production. in Chemical Industry & Chemical Engineering Quarterly. 2017;23(2):197-206.
doi:10.2298/CICEQ151217031L .
Lončarević, Ivana, Fistes, Aleksandar Z., Rakić, Dušan Z., Pajin, Biljana, Petrović, Jovana S., Torbica, Aleksandra, Zarić, Danica, "Optimization of the ball mill processing parameters in the fat filling production" in Chemical Industry & Chemical Engineering Quarterly, 23, no. 2 (2017):197-206,
https://doi.org/10.2298/CICEQ151217031L . .
