Multi-objective Bonobo optimisers of industrial low-density polyethylene reactor-Reference-Cited by-同舟云学术

Multi-objective Bonobo optimisers of industrial low-density polyethylene reactor

Published:2024-07-30 Issue:4 Volume:19 Page:631-652
ISSN:1934-2659
Container-title:Chemical Product and Process Modeling
language:en
Short-container-title:

Author:

Rohman Fakhrony Sholahudin¹,Alwi Sharifah Rafidah Wan¹²,Muhammad Dinie²,Zahan Khairul Azly³,Murat Muhamad Nazri⁴,Azmi Ashraf⁵

Affiliation:

1. Process Systems Engineering Centre (UTM-PROSPECT), Research Institute of Sustainable Environment (RISE) , Universiti Teknologi Malaysia , 81310 , Johor Bahru , Malaysia

2. School of Chemical and Energy Engineering, Faculty of Engineering , Universiti Teknologi Malaysia , 81310 UTM , Johor Bahru , Johor , Malaysia

3. Faculty of Engineering Technology , Universiti Tun Hussein Onn Malaysia , Parit Raja 86400 , Batu Pahat , Johor , Malaysia

4. School of Chemical Engineering, Engineering Campus , Universiti Sains Malaysia , 14700 , Nibong Tebal , Penang , Malaysia

5. School of Chemical Engineering, College of Engineering , Universiti Teknologi MARA , 40450 , Shah Alam , Selangor , Malaysia

Abstract

Abstract A multi-objective optimization (MOO) technique to produce a low-density polyethylene (LDPE) is applied to address these two problems: increasing conversion and reducing operating cost (as the first optimization problem, P1) and increasing productivity and reducing operating cost (as the second optimization problem, P2). ASPEN Plus software was utilized for the model-based optimization by executing the MOO algorithm using the tubular reactor model. The multi-objective optimization of multi-objective Bonobo optimisers (MOBO-I, MOBO-II and MOBO-III) are utilised to solve the optimization problem. The performance matrices, including hypervolume, pure diversity, and distance, are used to decide on the best MOO method. An inequality constraint was introduced on the temperature of the reactor to prevent run-away. According to the findings of the study, the MOBO-II for Problems 1 and 2 was the most effective MOO strategy. The reason is that the solution set found represents the most accurate, diversified, and acceptable distribution points alongside the Pareto Front (PF) in terms of homogeneity. The minimum operating cost, the maximum conversion and productivity obtained by MOBO-II are Mil. RM/year 114.3, 31.45 %, Mil. RM/year 545.3, respectively.

Funder

Universiti Teknologi Malaysia

Publisher

Walter de Gruyter GmbH

Link

https://www.degruyter.com/document/doi/10.1515/cppm-2024-0023/pdf

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