Prediction of instantaneous yield of bio-oil in fluidized biomass pyrolysis using long short-term memory network based on computational fluid dynamics data
Prediction of instantaneous yield of bio-oil in fluidized biomass pyrolysis using long short-term memory network based on computational fluid dynamics data
Computational fluid dynamics (CFD) is an effective tool to investigate biomass fast pyrolysis in fluidized bed reactor for bio-oil production, while it requires huge computational time when optimizing operating conditions or simulating large/industrial units. Machine learning (ML) is a promising approach to achieving both accuracy and efficiency. In this work, a reduced-order model including long short-term memory (LSTM) layer, pooling layer, and fully connected layer was established to predict future mass flow rates by training the historical CFD data. Unsteady mass flow rates, which are normally used to determine product yields, were treated as data of time series in ML. Influencing factors, such as sequence length, number of neurons, learning rate, subsequences order (shuffle or not), number of LSTM layers, and ratio of testing set, were evaluated to obtain their optimal values. The developed LSTM model framework and training process showed good applicability for the dataset of different species and temperatures. Product yields predicted by the derived LSTM were in good agreement with those obtained by CFD, while nearly 30% computational effort was saved. Thus, it is clearly seen that the well-predicted fluctuating characteristics and final product yields are helpful to improve accuracy of process simulation for digitalizing key reactors and building smart factories.
Bio-oil, Biomass fast pyrolysis, CFD, Fluidized bed, LSTM, Machine learning
Zhong, Hanbin
7e19a19c-8690-4700-b7b3-db3af6bd0ae2
Wei, Zhenyu
a6a4a2a9-fc55-4e7b-ac77-44271d2981d0
Man, Yi
14a8341d-7458-45a6-aa0f-1964efa59795
Pan, Shaowei
a95af862-7f96-4e23-aa5c-0a2a48ee238a
Zhang, Juntao
bbf6972c-70f1-4af3-81fd-21df1a7c302c
Niu, Ben
bfe1a069-138b-4141-aed4-d3f5b466d4fe
Yu, Xi
7e4f553f-cc11-4c6e-ad6d-9fb5c3c07a60
Ouyang, Yi
fb782fc3-faf5-4db8-8edc-e30f50cb08f7
Xiong, Qingang
ee66c6e3-4c7f-482e-ab6a-b4751bd74399
10 March 2023
Zhong, Hanbin
7e19a19c-8690-4700-b7b3-db3af6bd0ae2
Wei, Zhenyu
a6a4a2a9-fc55-4e7b-ac77-44271d2981d0
Man, Yi
14a8341d-7458-45a6-aa0f-1964efa59795
Pan, Shaowei
a95af862-7f96-4e23-aa5c-0a2a48ee238a
Zhang, Juntao
bbf6972c-70f1-4af3-81fd-21df1a7c302c
Niu, Ben
bfe1a069-138b-4141-aed4-d3f5b466d4fe
Yu, Xi
7e4f553f-cc11-4c6e-ad6d-9fb5c3c07a60
Ouyang, Yi
fb782fc3-faf5-4db8-8edc-e30f50cb08f7
Xiong, Qingang
ee66c6e3-4c7f-482e-ab6a-b4751bd74399
Zhong, Hanbin, Wei, Zhenyu, Man, Yi, Pan, Shaowei, Zhang, Juntao, Niu, Ben, Yu, Xi, Ouyang, Yi and Xiong, Qingang
(2023)
Prediction of instantaneous yield of bio-oil in fluidized biomass pyrolysis using long short-term memory network based on computational fluid dynamics data.
Journal of Cleaner Production, 391, [136192].
(doi:10.1016/j.jclepro.2023.136192).
Abstract
Computational fluid dynamics (CFD) is an effective tool to investigate biomass fast pyrolysis in fluidized bed reactor for bio-oil production, while it requires huge computational time when optimizing operating conditions or simulating large/industrial units. Machine learning (ML) is a promising approach to achieving both accuracy and efficiency. In this work, a reduced-order model including long short-term memory (LSTM) layer, pooling layer, and fully connected layer was established to predict future mass flow rates by training the historical CFD data. Unsteady mass flow rates, which are normally used to determine product yields, were treated as data of time series in ML. Influencing factors, such as sequence length, number of neurons, learning rate, subsequences order (shuffle or not), number of LSTM layers, and ratio of testing set, were evaluated to obtain their optimal values. The developed LSTM model framework and training process showed good applicability for the dataset of different species and temperatures. Product yields predicted by the derived LSTM were in good agreement with those obtained by CFD, while nearly 30% computational effort was saved. Thus, it is clearly seen that the well-predicted fluctuating characteristics and final product yields are helpful to improve accuracy of process simulation for digitalizing key reactors and building smart factories.
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Accepted/In Press date: 23 January 2023
e-pub ahead of print date: 27 January 2023
Published date: 10 March 2023
Additional Information:
Funding Information:
Financial supports from the Natural Science Basic Research Program of Shaanxi (Program No. 2023-JC-YB-119 ), the National Natural Science Foundation of China (No. 22178123 ), and the Postgraduate Innovation and Practice Ability Development Fund of Xi'an Shiyou University ( YCS21211039 ) were greatly appreciated.
Keywords:
Bio-oil, Biomass fast pyrolysis, CFD, Fluidized bed, LSTM, Machine learning
Identifiers
Local EPrints ID: 481567
URI: http://eprints.soton.ac.uk/id/eprint/481567
ISSN: 0959-6526
PURE UUID: 7a3e33b3-9831-40dd-bcf3-c7fface89c6d
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Date deposited: 01 Sep 2023 17:15
Last modified: 18 Mar 2024 04:14
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Contributors
Author:
Hanbin Zhong
Author:
Zhenyu Wei
Author:
Yi Man
Author:
Shaowei Pan
Author:
Juntao Zhang
Author:
Ben Niu
Author:
Xi Yu
Author:
Yi Ouyang
Author:
Qingang Xiong
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