NONLINEAR MODELING OF CRUDE PREHEAT TRAIN FOULING RATE VIA NEURAL-NETWORK

Fouling in heat exchangers tend to reduce the overall heat transfer coefficient. Two main impacts of fouling in Crude Preheat Train (CPT) operation are reduced heat recovery and increased pressure drop. Due to the inability of the existing monitoring tools to predict fouling rate, a heat exchanger p...

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Main Authors: H., Zabiri, C. S. , Wah, V. R. , Radhakrishnan, N. , Tahir, N. M. , Ramli, M., Ramasamy
Format: Conference or Workshop Item
Published: 2006
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Online Access:http://eprints.utp.edu.my/3764/1/ISM06_%28019%29__finalized23March.pdf
http://www.aus.edu/conferences/mechatronics_3/program.php
http://eprints.utp.edu.my/3764/
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Institution: Universiti Teknologi Petronas
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spelling my.utp.eprints.37642017-01-19T08:27:23Z NONLINEAR MODELING OF CRUDE PREHEAT TRAIN FOULING RATE VIA NEURAL-NETWORK H., Zabiri C. S. , Wah V. R. , Radhakrishnan N. , Tahir N. M. , Ramli M., Ramasamy TP Chemical technology Fouling in heat exchangers tend to reduce the overall heat transfer coefficient. Two main impacts of fouling in Crude Preheat Train (CPT) operation are reduced heat recovery and increased pressure drop. Due to the inability of the existing monitoring tools to predict fouling rate, a heat exchanger predictive model is to be developed, whereby the predicted outlet temperatures are used to calculate the fouling. The main objectives of this study are, to develop a nonlinear model for CPT heat exchanger in a refinery using Neural-Network (NN) toolbox in MATLAB, and to optimize the model through a step by step strategy. The optimized model comprises 2 day-lagged feedback variables, with the tube integral flow normalized based on the whole range of Date Sets A and B, and Purelin-Logsig-Purelin configuration with 25-15-2 neurons in each layer. This model predicts the heat exchanger outlet temperatures with average Root Mean Square Error (RMSE) of 6.797, average correlation coefficient (R2) of 0.61 and average Correct Directional Change (CDC) of 76.84%. Furthermore, this optimized model shows even better predictive capability before the process drifting whereby the average RMSE is 3.79, average R2 0.7253 and average CDC 72.92%. To address the drift problem, adaptive training of NN is recommended to account for the changes in plant conditions. 2006 Conference or Workshop Item PeerReviewed application/pdf http://eprints.utp.edu.my/3764/1/ISM06_%28019%29__finalized23March.pdf http://www.aus.edu/conferences/mechatronics_3/program.php H., Zabiri and C. S. , Wah and V. R. , Radhakrishnan and N. , Tahir and N. M. , Ramli and M., Ramasamy (2006) NONLINEAR MODELING OF CRUDE PREHEAT TRAIN FOULING RATE VIA NEURAL-NETWORK. In: 3rd International Symposium on Mechatronics, 18-20 April 2006, Sharjah, UAE. http://eprints.utp.edu.my/3764/
institution Universiti Teknologi Petronas
building UTP Resource Centre
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Petronas
content_source UTP Institutional Repository
url_provider http://eprints.utp.edu.my/
topic TP Chemical technology
spellingShingle TP Chemical technology
H., Zabiri
C. S. , Wah
V. R. , Radhakrishnan
N. , Tahir
N. M. , Ramli
M., Ramasamy
NONLINEAR MODELING OF CRUDE PREHEAT TRAIN FOULING RATE VIA NEURAL-NETWORK
description Fouling in heat exchangers tend to reduce the overall heat transfer coefficient. Two main impacts of fouling in Crude Preheat Train (CPT) operation are reduced heat recovery and increased pressure drop. Due to the inability of the existing monitoring tools to predict fouling rate, a heat exchanger predictive model is to be developed, whereby the predicted outlet temperatures are used to calculate the fouling. The main objectives of this study are, to develop a nonlinear model for CPT heat exchanger in a refinery using Neural-Network (NN) toolbox in MATLAB, and to optimize the model through a step by step strategy. The optimized model comprises 2 day-lagged feedback variables, with the tube integral flow normalized based on the whole range of Date Sets A and B, and Purelin-Logsig-Purelin configuration with 25-15-2 neurons in each layer. This model predicts the heat exchanger outlet temperatures with average Root Mean Square Error (RMSE) of 6.797, average correlation coefficient (R2) of 0.61 and average Correct Directional Change (CDC) of 76.84%. Furthermore, this optimized model shows even better predictive capability before the process drifting whereby the average RMSE is 3.79, average R2 0.7253 and average CDC 72.92%. To address the drift problem, adaptive training of NN is recommended to account for the changes in plant conditions.
format Conference or Workshop Item
author H., Zabiri
C. S. , Wah
V. R. , Radhakrishnan
N. , Tahir
N. M. , Ramli
M., Ramasamy
author_facet H., Zabiri
C. S. , Wah
V. R. , Radhakrishnan
N. , Tahir
N. M. , Ramli
M., Ramasamy
author_sort H., Zabiri
title NONLINEAR MODELING OF CRUDE PREHEAT TRAIN FOULING RATE VIA NEURAL-NETWORK
title_short NONLINEAR MODELING OF CRUDE PREHEAT TRAIN FOULING RATE VIA NEURAL-NETWORK
title_full NONLINEAR MODELING OF CRUDE PREHEAT TRAIN FOULING RATE VIA NEURAL-NETWORK
title_fullStr NONLINEAR MODELING OF CRUDE PREHEAT TRAIN FOULING RATE VIA NEURAL-NETWORK
title_full_unstemmed NONLINEAR MODELING OF CRUDE PREHEAT TRAIN FOULING RATE VIA NEURAL-NETWORK
title_sort nonlinear modeling of crude preheat train fouling rate via neural-network
publishDate 2006
url http://eprints.utp.edu.my/3764/1/ISM06_%28019%29__finalized23March.pdf
http://www.aus.edu/conferences/mechatronics_3/program.php
http://eprints.utp.edu.my/3764/
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