(226f) Design and Operation of a Renewable Polygeneration Energy System with Unit Commitment-Based Power Planning: A Deterministic Modelling Approach
AIChE Annual Meeting
2023
2023 AIChE Annual Meeting
Environmental Division
Design and Optimization of Integrated Energy Systems
Tuesday, November 7, 2023 - 5:00pm to 5:18pm
The approach taken in this model development paves a different path away from past polygeneration modelling studies, by using a network constrained Unit Commitment (UC) model that is well established in the domain of power systems engineering, to optimally schedule the power planning and power flow. First, the design and operation of a power generation planning model is developed to showcase how the power system responds to the intermittency of wind in the form of wind scenarios. This model was extended to show a storage mechanism in the form of a typical hydrogen electrolysis system and fuel cell. Mixed-Integer Linear Programming (MILP) models are then developed for the chemical production of methanol and integrated with the power planning model as a multi-scale (design and operation) model of a renewable polygeneration energy system (RPES) with chemical storage. To showcase the design and operation of the proposed RPES, the model is solved in a deterministic manner, to capture the integrated model as a snapshot. The total RPES system cost, based on real world wind power data and load demand data, was found to be USD 2317.93 million. The chemical production block had a cost of USD 138.51 million when integrated as a part of the RPES and the power generation planning block had a cost of USD 2179.42 million. The integrated model resulted in costs for the chemical production block that were much lower than the stand-alone plant while the RPES model also showed how excess intermittent wind power could be used for driving the chemical production. A key contribution to this work is also the implementation of machine learning methods, like K-Means clustering to help with the modelâs solution tractability and representation of a full yearâs hourly wind data and load demand. The MILP models have been developed using the General Algebraic Modeling System (GAMS) software and solved using state of the art optimization solvers BARON and CPLEX. Future work is planned in this topic that takes advantage of stochastic optimization with recourse to further study the RPESâs flexibility under increased uncertainty.