2020 Virtual AIChE Annual Meeting
(399e) Data-Driven Optimization of Manufacturing Systems Under Supply and Demand Volatilities in an Industrial Symbiosis Network
Authors
In contrast to previous studies, this research investigates the application of data-driven optimization by coupling the concepts of machine learning and conventional mathematical optimization (3), to devise a DSS. Specifically, we consider uncertainties associated with the supply of resources and demand â applied to a real-world wood manufacturing company in an IS network. For its production requirements, the company primarily depends on the supply of waste-wood (material resource) from other entities of the IS network, which are highly volatile in terms of quantity and quality. The company also relies on a hybrid power system (energy resource) comprising of solar panels in addition to the main power grid to meet the energy demands, wherein the volatility in weather conditions and time-of-use power pricing significantly impacts the production.
To this aim, based on historical data, we first develop hybrid machine learning (4) models to predict supply of material and energy resources and incorporate the concept of prediction interval (PI) to the outcome of the model to quantify the degree of uncertainty associated with the respective volatile resources. This prediction interval serves as an ambiguity set for an optimization formulation that accounts for the optimal utilization of wood-waste as well as optimal combination of power sources to meet the production demands; with multi-objectives to minimize the overall production cost, emissions and optimize inventory utilization. An optimal DSS based on data-driven optimization framework as described in this study, is computationally less intensive (5) and offers greater flexibility in decision making in the face of uncertainties (5) to aid the overall productivity, profitability and sustainability of individual networks in an IS network.
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