Introducing a new formula based on an artificial neural network for prediction of droplet size in venturi scrubbers

Abstract: -Droplet size is a fundamental parameter for Venturi scrubber performance. For many years, the correlations proposed by Nukiyama and Tanasawa (1938) and Boll et al. (1974) were used for calculating mean droplet size in Venturi scrubbers with limited operating parameters. This study proposes an alternative approach on the basis of artificial neural networks (ANNs) to determine the mean droplet size in Venturi scrubbers, in a wide range of operating parameters. Experimental data were used to design the ANNs. A n… Show more

“…The values in the top 10 cases (Figure 17d) were −1.23 to −1.22 and there was no significant difference in the values of the 10 cases, but the shaft deformation prediction (Figure 17a) did not converge beyond a certain level. Based on these results, various margins of error may occur in the shaft assembly stage depending on the sag tolerance of the engine bed plate, the deviation of the center of the MBs, and the tendency of the operator when the shaft installation is inclined compared to the design [12]. Owing to the above characteristics of the shaft, the fact that the reaction force and bending moment values in the shaft deformation prediction converged to similar values while filtering from all cases to the top 10 cases means that all shaft deformation predictions of the top 10 cases were valid.…”

“…The structure of the deep neural network mimics the human brain and neural network. This technique can perform complex nonlinear analysis that is difficult to achieve with an equation for variables without prior definition [12]. RL changes to the "next state" by selecting an "action" from the "state" based on the content learned through trial and error to obtain a "reward," and an action or action pattern is selected that maximizes the sum of the rewards.…”

Application of Deep Reinforcement Learning to Predict Shaft Deformation Considering Hull Deformation of Medium-Sized Oil/Chemical Tanker

“…The values in the top 10 cases (Figure 17d) were −1.23 to −1.22 and there was no significant difference in the values of the 10 cases, but the shaft deformation prediction (Figure 17a) did not converge beyond a certain level. Based on these results, various margins of error may occur in the shaft assembly stage depending on the sag tolerance of the engine bed plate, the deviation of the center of the MBs, and the tendency of the operator when the shaft installation is inclined compared to the design [12]. Owing to the above characteristics of the shaft, the fact that the reaction force and bending moment values in the shaft deformation prediction converged to similar values while filtering from all cases to the top 10 cases means that all shaft deformation predictions of the top 10 cases were valid.…”

“…The structure of the deep neural network mimics the human brain and neural network. This technique can perform complex nonlinear analysis that is difficult to achieve with an equation for variables without prior definition [12]. RL changes to the "next state" by selecting an "action" from the "state" based on the content learned through trial and error to obtain a "reward," and an action or action pattern is selected that maximizes the sum of the rewards.…”

Application of Deep Reinforcement Learning to Predict Shaft Deformation Considering Hull Deformation of Medium-Sized Oil/Chemical Tanker

“…The learning algorithms used in the following are part of MATLAB toolbox of neural networks [18]. One of the indicators, that show the quality of the training operation, is the mean square error [19]- [21]. As shown in the following Figure 4, the mean square error gets the value 7.8488x10 -3 at 73 epochs, which shows that the training operation has worked well, which means that the MLP outputs will converge to the desired outputs perfectly in the three phases of training, testing and model validation [22]- [25].…”

Integration of artificial neural networks for multi-source energy management in a smart grid

Comparison of Three Machine Learning Approaches in Determining Total Organic Carbon (TOC): A Case Study from Marcellus Shale Formation, New York State