Evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach
This study aims to use planetary ball-milling as an evaluation tool of material properties and the result is subsequently used to develop a model for the change in particle size distribution (PSD) during fluidization for a range of materials using artificial neural network (ANN) method. It is believ...
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sg-ntu-dr.10356-1522612021-08-05T01:55:43Z Evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach Farizhandi, Amir Abbas Kazemzadeh Zhao, Han Chen, Theodore Lau, Raymond School of Chemical and Biomedical Engineering Engineering::Chemical engineering Particle Size Distribution Rosin-Rammler Distribution This study aims to use planetary ball-milling as an evaluation tool of material properties and the result is subsequently used to develop a model for the change in particle size distribution (PSD) during fluidization for a range of materials using artificial neural network (ANN) method. It is believed that material properties such as hardness, density, brittleness, structure, etc play a crucial role in the particle attrition behavior. Unfortunately, little information on material properties is available, considering the wide variety of materials present. As a result, planetary ball-milling is proposed as a fast assessment technique to identify the properties of different materials. Planetary ball milling devices are readily available in most laboratories and the reduction in PSD can resemble the particle attrition process during fluidization. A Rosin-Rammler (RR) distribution was used to describe the PSD for both fluidization and ball milling processes. National Environmental Agency (NEA) This work is funded by National Environmental Agency (NEA), Singapore ETRP Grant No. 1102 108. 2021-08-05T01:55:43Z 2021-08-05T01:55:43Z 2020 Journal Article Farizhandi, A. A. K., Zhao, H., Chen, T. & Lau, R. (2020). Evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach. Chemical Engineering Science, 215, 115469-. https://dx.doi.org/10.1016/j.ces.2020.115469 0009-2509 https://hdl.handle.net/10356/152261 10.1016/j.ces.2020.115469 2-s2.0-85077661730 215 115469 en 1102108 Chemical Engineering Science © 2020 Elsevier Ltd. All rights reserved. |
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Engineering::Chemical engineering Particle Size Distribution Rosin-Rammler Distribution Farizhandi, Amir Abbas Kazemzadeh Zhao, Han Chen, Theodore Lau, Raymond Evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach |
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This study aims to use planetary ball-milling as an evaluation tool of material properties and the result is subsequently used to develop a model for the change in particle size distribution (PSD) during fluidization for a range of materials using artificial neural network (ANN) method. It is believed that material properties such as hardness, density, brittleness, structure, etc play a crucial role in the particle attrition behavior. Unfortunately, little information on material properties is available, considering the wide variety of materials present. As a result, planetary ball-milling is proposed as a fast assessment technique to identify the properties of different materials. Planetary ball milling devices are readily available in most laboratories and the reduction in PSD can resemble the particle attrition process during fluidization. A Rosin-Rammler (RR) distribution was used to describe the PSD for both fluidization and ball milling processes. |
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School of Chemical and Biomedical Engineering |
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School of Chemical and Biomedical Engineering Farizhandi, Amir Abbas Kazemzadeh Zhao, Han Chen, Theodore Lau, Raymond |
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Article |
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Farizhandi, Amir Abbas Kazemzadeh Zhao, Han Chen, Theodore Lau, Raymond |
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Farizhandi, Amir Abbas Kazemzadeh |
title |
Evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach |
title_short |
Evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach |
title_full |
Evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach |
title_fullStr |
Evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach |
title_full_unstemmed |
Evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach |
title_sort |
evaluation of material properties using planetary ball milling for modeling the change of particle size distribution in a gas-solid fluidized bed using a hybrid artificial neural network-genetic algorithm approach |
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2021 |
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https://hdl.handle.net/10356/152261 |
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1707774594089222144 |