Abstract: In the biobased industry, where biomass serves as a raw material, there are numerous pathways to achieve polymer end products, and the possibilities expand even more when nanotechnology is incorporated in the production process. In this complex landscape, the challenge is to find the optimal value chain path, considering economic and environmental impacts. The BIOMAC project tackles this challenge with a Decision Support Tool (DST) that strategically evaluates sustainability and feasibility across different value chains, guiding users throughout.
The web-based DST displays a user-friendly interface fostering efficient communication with computational tools in the backend. The backend integrates customized data repositories and optimization models considering various biobased processes with their mass and energy balances along with techno-economic and environmental factors.
This tool allows for key operations. In the "Step-by-Step" mode, users can construct value chains towards biopolymers gradually, understanding the impacts of each process. The "Optimal Path" feature allows a systemic review of the entire value chain tree, enabling the user to adjust variables and perform optimizations subjected to single or multiple criteria.
Case studies explore the utilization of alternative types of biomass (e.g., beechwood sawdust and Miscanthus Giganteus) in producing the project’s five final products (PU-based automotive parts, PLA-based barrier coatings, PU-based bridge modules, and PE-based agriculture applications). The optimization model prioritizes environmental and economic factors, and identifies the most efficient production path through biomass fractionation, nanocomposite production (nanolignin, nanofibrilated cellulose, nanocellulose), downstream processing, and final polymer formulation. Users can assess various options (different biomasses, alternative processes), conduct hypothetical studies (market fluctuations, biomass availability, product demand), and identify the most beneficial paths tailored to their specific requirements.
The DST strives to empower stakeholders to navigate the challenging landscape of nano-enabled biopolymers. Its user-friendly interface allows for easy and accessible studies, without requiring expertise in optimization or data collection, enabling decision-making in this field.