Abstract
Methanol production via carbon dioxide (CO2) hydrogenation is a green chemical process, which can reduce CO2 emission. The operating conditions for minimum methanol production cost of three configurations were investigated in this work. An artificial neural network with Latin hypercube sampling technique was applied to construct model-represented methanol production. Price sensitivity was performed to study the impacts of the raw materials price on methanol production cost. Price sensitivity results showed that the hydrogen price has a large impact on the methanol production cost. In mathematical modeling using feedforward artificial neural networks, four different numbers of nodes were used to train artificial neural networks. The artificial neural network with eight numbers of nodes showed the most suitable configuration, which yielded the lowest percent error between the actual and predicted methanol production cost. The optimization results showed that the recommended process design among the three studied configurations was the process of methanol production with two reactors in series. The minimum methanol production cost obtained from this configuration was $888.85 per ton produced methanol, which was the lowest methanol production cost among all configurations.
Highlights
Many greenhouse gases (GHGs) are naturally present in the atmosphere
An artificial neural network (ANN) is a mathematical expression consisting of interconnected processing units known as neurons [30]
In the case of an impact of hydrogen price, the results showed that hydrogen price has significant impacted on methanol production costs
Summary
Many greenhouse gases (GHGs) are naturally present in the atmosphere. Carbon dioxide, which causes global warming, is one of the most emitted by anthropogenic. The modification and optimization of the carbon dioxide hydrogenation unit to maximize the amount of produced methanol was investigated using an artificial neural network and verified with industrial plant data [26]. Modelling and optimization of the methanol production process via carbon dioxide hydrogenation, which compares process configurations and optimizes process parameters for a minimum production cost, has not been studied. This work studied methanol production with three different configurations and an applied artificial neural network as an objective function in the optimization problem. The model representation with an artificial neural network was solved to obtain the minimum methanol production cost in a unit per ton of produced methanol and optimal operating conditions.
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