Flame Stability Analysis of Flame Spray Pyrolysis by Artificial Intelligence

TL;DR

This paper explores the use of machine learning algorithms to monitor and classify flame stability in flame spray pyrolysis in real time, aiming to improve nanoparticle synthesis consistency and process efficiency.

Contribution

It introduces both unsupervised and supervised machine learning methods for real-time flame stability detection in FSP, validated against human expert evaluations.

Findings

Both approaches accurately classify flame stability in real time.

Unsupervised learning enables autonomous data labeling and clustering.

Supervised learning effectively distinguishes multiple flame components.

Abstract

Flame spray pyrolysis (FSP) is a process used to synthesize nanoparticles through the combustion of an atomized precursor solution; this process has applications in catalysts, battery materials, and pigments. Current limitations revolve around understanding how to consistently achieve a stable flame and the reliable production of nanoparticles. Machine learning and artificial intelligence algorithms that detect unstable flame conditions in real time may be a means of streamlining the synthesis process and improving FSP efficiency. In this study, the FSP flame stability is first quantified by analyzing the brightness of the flame's anchor point. This analysis is then used to label data for both unsupervised and supervised machine learning approaches. The unsupervised learning approach allows for autonomous labelling and classification of new data by representing data in a reduced dimensional space and identifying combinations of features that most effectively cluster it. The supervised learning approach, on the other hand, requires human labeling of training and test data, but is able to classify multiple objects of interest (such as the burner and pilot flames) within the video feed. The accuracy of each of these techniques is compared against the evaluations of human experts. Both the unsupervised and supervised approaches can track and classify FSP flame conditions in real time to alert users of unstable flame conditions. This research has the potential to autonomously track and manage flame spray pyrolysis as well as other flame technologies by monitoring and classifying the flame stability.