Abstract
Lignocellulosic biomass derived fuels and chemicals are a promising and sustainable supplement for petroleum-based products. Currently, the lignocellulosic biofuel industry relies on a conventional system where feedstock is harvested, baled, stored locally, and then delivered in a low-density format to the biorefinery. However, the conventional supply chain system causes operational disruptions at the biorefinery mainly due to seasonal availability, handling problems, and quality variability in biomass feedstock. Operational disruptions decrease facility uptime, production efficiencies, and increase maintenance costs. For a low-value high-volume product where margins are very tight, system disruptions are especially problematic. In this work we evaluate an advanced system strategy in which a network of biomass processing centers (depots) are utilized for storing and preprocessing biomass into stable, dense, and uniform material to reduce feedstock supply disruptions, and facility downtime in order to boost economic returns to the bioenergy industry. A database centric discrete event supply chain simulation model was developed, and the impact of operational disruptions on supply chain cost, inventory and production levels, farm metrics and facility metrics were evaluated. Three scenarios were evaluated for a 7-year time-period: (1) bale-delivery scenario with biorefinery uptime varying from 20 to 85%; (2) pellet-delivery scenario with depot uptime varying from 20 to 85% and biorefinery uptime at 85%; and (3) pellet-delivery scenario with depot and biorefinery uptime at 85%. In scenarios 1 and 2, tonnage discarded at the field edge could be reduced by increasing uptime at facility, contracting fewer farms at the beginning and subsequently increasing contracts as facility uptime increases, or determining alternative corn stover markets. Harvest cost was the biggest contributor to the average delivered costs and inventory levels were dependent on facility uptimes. We found a cascading effect of failure propagating through the system from depot to biorefinery. Therefore, mitigating risk at a facility level is not enough and conducting a system-level reliability simulation incorporating failure dependencies among subsystems is critical.
| Original language | English |
|---|---|
| Article number | 100 |
| Journal | Frontiers in Energy Research |
| Volume | 6 |
| DOIs | |
| State | Published - Sep 25 2018 |
Funding
This project was funded by United States Department of Energy, Bioenergy Technologies Office. We thank Dr. Mahmood Ebadian (Biomass and Bioenergy Supply Chain Specialist), Magen E. Shedden (Post-masters: Biomass logistics), Devita D. Amal (Ph.D. Candidate: Biomass supply risk) in the Environmental Sciences Division, Oak Ridge National Laboratory and Amit Khanchi (Post-doctoral Research Associate: Biomass post-harvest), Iowa State University for their scientific guidance and reviewing the manuscript. Funding. This material is based upon work supported by the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, Bioenergy Technologies Office. This project was funded by United States Department of Energy, Bioenergy Technologies Office. We thank Dr. Mahmood Ebadian (Biomass and Bioenergy Supply Chain Specialist), Magen E. Shedden (Post-masters: Biomass logistics), Devita D. Amal (Ph.D. Candidate: Biomass supply risk) in the Environmental Sciences Division, Oak Ridge National Laboratory and Amit Khanchi (Post-doctoral Research Associate: Biomass postharvest), Iowa State University for their scientific guidance and reviewing the manuscript. This material is based upon work supported by the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, Bioenergy Technologies Office.
Keywords
- biomass
- biorefinery
- depots
- operational disruptions
- pre-processing
- simulation