Reliable Biomass Supply Chain Design under Feedstock Seasonality and Probabilistic Facility Disruptions

Liu, Zhixue; Wang, Shukun; Ouyang, Yanfeng

doi:10.3390/en10111895

Cited by 29 publications

(13 citation statements)

References 37 publications

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“…Previously, most researchers consider storage or distribution center disruption risk only (Liu, Wang & Ouyang, 2017;Rayat et al, 2017;Fattahi & Govindan, 2018;Azadeh & Arani 2016;Rabbani, Aliabadi, Heidari & Farrokhi-Asl, 2017). Disruption may also occur in the manufacturing plant.…”

Section: Literature Reviewmentioning

confidence: 99%

An integrated location-inventory model for a spare part’s supply chain considering facility disruption risk and CO2 emission

Karim

Nakade

2021

JIEM

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Purpose: Managing the inventory of spare parts is very difficult because of the stochastic nature of part’s demand. Also, only controlling the inventory of the spare part is not enough; instead, the supply chain of the spare part needs to be managed efficiently. Moreover, every organization now aims to have a resilient and sustainable supply chain to overcome the risk of facility disruption and to ensure environmental sustainability. This paper thus aims to establish a model of inventory-location relating to the resilient supply chain network of spare parts.Design/methodology/approach: First, applying queuing theory, a location-inventory model for a spare parts supply chain facing a facility disruption risk and has a restriction for CO2 emission, is developed. The model is later formulated as a non-linear mixed-integer programming problem and is solved using MATLAB.Findings: The model gives optimal decisions about the location of the warehouse facility and the policy of inventory management of each location selected. The sensitivity analysis shows that the very low probability of facility disruption does not influence controlling the average emission level. However, the average emission level certainly decreases with the increment of the disruption probability when the facility disruption probability is significant.Practical implications: Using this model, based on the cost and emission parameters and the likelihood of facility disruption, the spare part’s manufacturer can optimize the total average cost of the spare part’s supply chain through making a trade-off between productions, warehouse selection, inventory warehousing and demand allocation.Originality/value: Previous research focuses only on developing a framework for designing an efficient spare parts planning and control system. The inventory-location model for spare parts is not addressed in the sense of risk of facilities disturbance and emission. This research first time jointly considered the probabilistic facility disruption risk and carbon emission for modeling the spare part’s supply chain network.

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Section: Literature Reviewmentioning

confidence: 99%

An integrated location-inventory model for a spare part’s supply chain considering facility disruption risk and CO2 emission

Karim

Nakade

2021

JIEM

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“…Several technologies for renewable energy (i.e., solar, wind, hydro, geothermal, and biomass) have been widely analyzed, and by considering the cost-effectiveness and the positive externalities, bioenergy from biomasses could offer a versatile solution, mainly for rural communities where relevant quantities of agricultural biomasses are produced [9,10]. In rural areas, the harnessing of biomass for Hohn et al used GIS data to analyze the spatial distribution and amount of potential biomass feedstock for biomethane production and optimal locations, and also the size and number of biogas plants in southern Finland [34].…”

Section: Introductionmentioning

confidence: 99%

Net Electricity and Heat Generated by Reusing Mediterranean Agro-Industrial By-Products

Valenti

Porto

2019

Energies

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The necessity to investigate suitable alternatives to conventional fossil fuels has increased interest in several renewable energy resources, especially in biomasses that are widely available and make it possible to reach environmental and socio-economic improvements. Among solutions for bioenergy production, anaerobic digestion technology allows biogas production by reusing agricultural residues and agro-industrial by-products. By considering the basic concepts of the Biogasdoneright® method, the objective of this study was to estimate the theoretical potential net electricity and heat production from anaerobic digestion of citrus pulp and olive pomace highly available worldwide. A model was developed and applied in a study area of the Mediterranean basin, where the biogas sector is still very limited despite the importance of both agricultural and agro-industrial activities, especially with regard to citrus and olive cultivation processing. Firstly, the application of a geographical information system (GIS) software tool allowed the estimation of the biogas potentially produced from citrus pulp and olive pomace re-use. Then, the development of a technical assessment demonstrated that 15.9 GWh electricity and 88,000 GJ heat per year could be generated from these by-products, satisfying approximate 17% of the electricity demand of the agricultural sector of the study area (90.2 GWh y−1). The achieved results could be relevant with regard to the intervention priorities established by the European Union related to the planning activities supported by the European Structural and Investment Funds within the Smart Specialisation Strategy.

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“…There have been several studies on modeling Biomass Supply Chain (BSC) compiled in review papers (Sharma et al, 2013;Zandi Atashbar et al, 2017). Initially, BSC models were designed under deterministic settings, but when the dynamic nature of BSC along with its complexity and uncertainty was recognized, researchers incorporated risks in models to improve system resilience and reliability (Bai et al, 2015;Liu et al, 2017). The majority of studies have been based on mathematical programming and heuristics (Atashbar et al, 2016) and some studies involved simulation (Hansen et al, 2015;Wang et al, 2018) modeling.…”

Section: Introductionmentioning

confidence: 99%

“…A few studies have evaluated the impact of storage (Liu et al, 2017), biorefinery characteristics (Bai et al, 2015), and intermodal facilities disruptions (Marufuzzaman et al, 2014) due to flooding, hurricane, and drought, on costs and BSC network design. In the majority of static planning models, the failure probabilities were considered unchanged over time (Liu et al, 2017). To the best of our knowledge, existing approaches focus only on failures at a facility, however, impact of failure at a facility on all the entities in the supply chain is not evaluated and could significantly impact overall reliability of a system.…”

Section: Introductionmentioning

confidence: 99%

Simulation Modeling for Reliable Biomass Supply Chain Design Under Operational Disruptions

Sharma

Clark²,

Hilliard

et al. 2018

Front. Energy Res.

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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.

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Reliable Biomass Supply Chain Design under Feedstock Seasonality and Probabilistic Facility Disruptions

Cited by 29 publications

References 37 publications

An integrated location-inventory model for a spare part’s supply chain considering facility disruption risk and CO2 emission

An integrated location-inventory model for a spare part’s supply chain considering facility disruption risk and CO2 emission

Net Electricity and Heat Generated by Reusing Mediterranean Agro-Industrial By-Products

Simulation Modeling for Reliable Biomass Supply Chain Design Under Operational Disruptions

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