在工业聚合反应器中应用多目标神经网络算法,降低能源成本,最大限度提高生产率

IF 3 Q2 ENGINEERING, CHEMICAL
Fakhrony Sholahudin Rohman , Sharifah Rafidah Wan Alwi , Dinie Muhammad , Ashraf Azmi , Zainuddin Abd Manan , Jeng Shiun Lim , Hong An Er , Siti Nor Azreen Ahmad Termizi
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引用次数: 0

摘要

工业规模的优化是一项复杂的任务,涉及对大型系统和应用程序的性能进行微调,使其更加高效和有效。由于工作量不断增加、系统复杂性不断提高以及需要保持最佳性能,这一过程极具挑战性。由于压缩需要大量电力,而反应物材料成本高昂,因此需要优化低密度聚乙烯(LDPE)生产,在降低能源成本的同时实现最高生产率。然而,这并不是一个简单的过程,因为低密度聚乙烯管式反应器的优化问题由相互冲突的目标函数组成。多目标神经网络算法(MONNA)是一种元启发式优化方法,为解决复杂、目标矛盾和多样化的优化问题提供了一种通用而稳健的方法,它不依赖于问题的特定数学属性。它的灵感来源于生物神经网络的结构和信息处理能力。MONNA 可以迭代地提出解决方案、评估性能并根据反馈调整方法,从而避免了复杂的数学公式。在这项工作中,我们在低密度聚乙烯管式反应器中实现了多目标优化神经网络算法(MONNA),以最大化生产率、转化率和最小化能源成本为目标,对三个问题进行了优化,即第一个问题(P1)最大化生产率并降低能源成本;第二个问题(P2)提高转化率并降低能源成本;第三个问题(P3)提高生产率并减少副产品。结果表明,最高生产率、最高转化率和最低能耗分别为 545.1 百万林吉特/年、0.31 百万林吉特/年和 0.31 百万林吉特/年。RM/年、0.314 和 0.672 mil.马币/年。各种双目标情况下的帕累托前沿(PF)极值点为从业人员选择最佳运营战略权衡提供了有用的信息。决策者可以根据自己的偏好,利用得出的帕累托前沿来决定最可接受的替代方案。决策变量图显示,反应区中的两个启动者都对最佳解决方案产生了很大影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Application of multi-objective neural network algorithm in industrial polymerization reactors for reducing energy cost and maximising productivity

Optimization on an industrial scale is a complex task that involves fine-tuning the performance of large-scale systems and applications to make them more efficient and effective. This process can be challenging due to the increasing volume of work, growing system complexity, and the need to maintain optimal performance. Due to the significant power required for compression and the high costs of reactant materials, optimizing low-density polyethylene (LDPE) production to provide maximum productivity with a reduction of energy cost is required. However, it is not a simple process because the optimization problem of the LDPE tubular reactor consists of conflicting objective functions. Multi-objective neural network algorithm (MONNA) is a metaheuristic optimization method that provides a versatile and robust approach for solving complex, contradictory targets and diverse optimization problems that do not rely on specific mathematical properties of the problem. It is inspired by the structure and information-processing capabilities of biological neural networks. MONNA iteratively proposes solutions, evaluates its performance, and adjusts its approach based on feedback, which avoids complex mathematical formulations. In this work, we implement Multi-objective optimization neural network algorithm (MONNA) in LDPE tubular reactor for maximising productivity, conversion and minimising energy costs with three scenario of problem optimization, i.e. maximising productivity and reducing energy cost for the first problem (P1); increasing conversion and reducing energy costs for the second problem (P2); and increasing productivity and reducing by-products for the third problem (P3). The results show that the highest productivity, highest conversion, and lowest energy are 545.1 mil. RM/year, 0.314, and 0.672 mil. RM/year. The extreme points in the Pareto Front (PF) for various bi-objective situations provide practitioners with helpful information for selecting the best trade-off for the operational strategy. According to their preferences, decision-makers can use the resulting Pareto to decide on the most acceptable alternative. The decision variable plots show that both initiators in the reacting zone highly affected the optimal solution with the opposite action.

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