Industries

Project

Tailor-made ML solution for a hydrocracking plant in a refinery company

Dogwood AI developed the ML model to predict the yield and quality from a hydrocracking plant. The cutting-edge solution is capable of predicting the products within an error margin of less than 1% in real time. This solution was actively collaborated with a partner company to monitor and improve the product prediction in the real field. This solution was validated for 6 months in a Korean refinery to predict products in real time.

Tailor-made ML solution for a hydrocracking plant

Hybrid Simulator based on machine learning and mathematical model for the fine chemical production

Hybrid simulator for a fine chemical plant

Leveraging collaborations with a global platform company, Dogwood AI is developing a Physics-informed data-driven Hybrid AI model that integrates mathematical and ML models. This breakthrough approach addresses the limitations of mathematical modeling in complex industrial settings, as well as the challenges of insufficient data for ML model training. Our mission is to create ML models that complement the shortcomings of each approach, providing tailored solutions for factories facing these challenges. The developed hybrid simulator with less than 0.5 deviation is set to a domestic fine chemical company to predict product quality and yield. Then, it will be applied for designing and constructing the second plant.

Computational Fluid Dynamic models for three-phase reactor in a fine chemical company

This project is to simulate and analyze the flow patterns within a reactor producing solid particles via liquid-gas reaction in a fine chemical company, using advanced computational fluid dynamics models (CFD). By investigating the correlation among the three-phase (gas-liquid-solid) flows as well as the mixing patterns inside the reactor, the optimal impeller design and operating conditions for maintaining the best mixing performance are determined. It will progress further development for CFD-based ML model.

CFD results for the mixing performance of the rector (Gas-Liquid-Solid phases)