Energetic, economic, and greenhouse gas emissions assessment of biomass and solar photovoltaic systems for an industrial facility
Jamsheed Sajid, Muhammad Sajid, Muhammad Muneeb Ahmad, Muhammad Kamran, Rameen Ayub, Naveed Ahmed, Mariam Mahmood, Akhtar Abbas
Abstract
The industrial sector is responsible for nearly 25% of direct and more than 35% of cumulative global energy-related greenhouse gas (GHG) emissions. This study evaluates the feasibility and comparative analysis of on-site solar photovoltaic (PV) and biomass-fed boilers based on historical energy consumption and demand to reduce dependence on grid-supplied electricity and coal-fired boiler for a rice processing industrial plant. The analysis includes energetic, economic, and GHG emissions assessments and covers (a) Solar PV systems, (b) Biomass fuels, and (c) Co-firing scenarios. Financial analysis of solar PV considers both company-owned and bank-financed systems of fixed and double axis tracking technologies. Biomass fuels include 100% wood, 100% rice husk, and a 50%–50% wood-rice husk mix. Historical energy consumption shows that annual electricity demand is 4,479 MWh, costing $537,480 and producing 2,307 tCO 2 emissions. Feasibility of 1MW, company-owned fixed axis solar PV plant shows a yearly electricity production of 1,544 MWh with 0.031 $/kWh levelized cost and reducing 733 tCO 2 with a payback period of 2.8 years. The base case scenario for boiler operations consists of 3,746 tons of coal burning, costing $427,075 and producing 11,840 tCO 2 emissions. Rice husk fuel study shows a 19% fuel cost savings, a 1.7-year payback period, and 11,612 tCO 2 GHG emission reductions. It is concluded that biomass-based rice husk fuel feedstock is the most suitable renewable energy source (RES) for this industrial facility and can reduce 82% of cumulative annual GHG emissions. Furthermore, energy efficiency improvements and off-site carbon credits provide additional opportunities to achieve net-zero GHG emissions for plant operations.