Optimisation and planning of biomass supply chain for new and existing power plants based on carbon reduction targets

The biomass energy sector in most developing countries is not well established due to the high cost of implementation and lack of quantitative planning tools. This paper addresses this issue by presenting a quantitative planning tool used to plan and optimise biomass supply chains based on carbon re...

Full description

Saved in:
Bibliographic Details
Published in:Energy (Oxford) 2021-12, Vol.237, p.121488, Article 121488
Main Authors: Mohd Yahya, Nur Syahira, Ng, Lik Yin, Andiappan, Viknesh
Format: Article
Language:English
Subjects:
Biomass
Biomass energy
Biomass energy production
Carbon
Case studies
CEPA
Co-firing
Developing countries
Emission analysis
Energy conversion
LDCs
Mathematical analysis
Operating costs
Optimization
Planning
Power plants
Quotas
Shapley-Shubik power index
Stakeholder analysis
Supply chain optimisation
Supply chains
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The biomass energy sector in most developing countries is not well established due to the high cost of implementation and lack of quantitative planning tools. This paper addresses this issue by presenting a quantitative planning tool used to plan and optimise biomass supply chains based on carbon reduction targets. The tool proposed in this work centres on three important stages: Carbon Emission Pinch Analysis (CEPA), mathematical optimisation, and multi-stakeholder analysis. CEPA is used to determine the minimum amount of biomass to achieve carbon reductions. Then, mathematical optimisation is used to optimise the biomass supply chain based on the carbon reduction target. The optimisation step considers the use of new biomass power plants and co-firing existing power plants. Following this, the importance of power plants within the optimal biomass supply chain is identified using a multi-stakeholder analysis method known as Shapley-Shubik power index. Shapley-Shubik power index is used to determine the level of power held by each power plant in the biomass supply chain based on the number of times each stakeholder become pivotal in achieving several quotas (i.e., power purchase agreement). A case study comprising a biomass supply chain in Malaysia is solved to demonstrate the presented tool. The case study analyses several scenarios in which the biomass supply chain can be deployed. Case study results indicated that co-firing existing power plants did indeed minimise capital and operating expenditure. Conversely, the cost of transporting biomass may be high depending on the location of these plants. Boiler systems were the most chosen due to their high biomass-to-power conversion rates. The multi-stakeholder analysis determined that a power plant with higher power output, cheaper costs, and superior biomass-to-power conversion rate often appears as the more significant player in the supply chain. •A methodology is developed for optimal biomass supply chain planning based on carbon reduction targets.•Shapley-Shubik power index is used to determine pivotal players in optimal biomass supply chain.•Co-firing opportunities are considered to achieve targets in a cost-effective manner.•Results show co-firing schemes were more preferred compared to new biomass plants due to lower cost.•Plants with higher efficiency and lower cost tend to become pivotal players in optimal supply chains.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2021.121488