Analysis of feedstock requirement for the expansion of a biomass-fed district heating system considering daily variations in heat demand and biomass quality

•Evaluated biomass feedstock requirement for expanding a district heating system in an urban area.•Considered daily variations in heat demand and feedstock quality characteristics.•Developed a Microsoft Excel-based simulation model with one year planning horizon.•The expansion could have a potential to reduce 11,000 tons of CO2.•Utilizing energy dense feedstock could increase total fuel cost by 60–80%. Evaluating the feedstock requirement of biomass-fed district heating systems is important when planning their installation or expansion. Public acceptance, which favors or deters the utilization of biomass, could be impacted by feedstock supply logistics. Feedstock requirement of district heating plants depends on the heat demand from the consumer and biomass quality characteristics, which vary over time. Previous studies on utilizing biomass for district heating mostly assumed average feedstock quality characteristics and aggregated heat demand values without considering their daily variations. While using average quality characteristics provides the average feedstock requirement of the plant, the actual requirement may vary significantly from the average value when daily variations in quality characteristics are considered. Not including these variations could lead to infeasibilities in meeting the heat demand of the plant. This study assesses the feedstock requirement of expanding a district heating plant considering daily variations in biomass quality characteristics and heat demand. A Microsoft Excel-based simulation model with one-year planning horizon and daily time steps is developed for the assessment. The costs and CO2-eq emissions of using different feedstock types are evaluated with and without trucking limitations. The developed model is applied to a real biomass-fed district heating plant at the University of British Columbia, Canada. The capacity of the heating plant is planned to be expanded from 6 MW to 18 MW. Three feedstock types, namely, wood residues, pellets and briquettes, and a mix of them are assessed. The results suggest that when enough trucking capacity is available, the plant would receive 2–9 truckloads of wood residues or 1–3 truckloads of pellets/briquettes. The expansion could reduce the total CO2 emissions by about 11,000 tonnes compared to those emitted by the 6 MW (current) biomass-fed heating capacity and natural gas (for a total of 18 MW) when sufficient biomass is available to the plant. However, when trucking is limite