Abstract
Torrefied empty fruit bunch (EFB) co-firing is a promising technology to reduce emissions from coal-fired power plants. However, co-firing can influence the combustion and heat transfer characteristics in a coal boiler. In order to study the feasibility of co-firing application of torrefied EFB (T-EFB) in boilers, the combustion characteristics, gas emissions and heat flux distribution were analyzed, respectively. First, the kinetic parameters of T-EFB devolatilization and char oxidation were obtained by experimental analysis. Second, the computational fluid dynamics (CFD) analysis was applied to the actual 500 MWe boiler simulation to further evaluate the differences in the co-firing performance parameters (combustion characteristics and emissions) of the T-EFB and the heat transfer characteristics within the boiler. Numerical results show that T-EFB co-firing can improve the ignition characteristics of pulverized coal, reduce the formation of unburned particles. When the blending ratio was increased from 10% to 50%, significantly NOx (oxides of nitrogen) reduction (levels from 170 to 98 ppm at 6% O2) was achieved. At a blending ratio above 40%, boiler combustion efficiency decreases as the total heat flux of the boiler decreases due to an increase in the amount of unburned carbon. In addition, T-EFB co-firing can affect the heat transfer characteristics of the boiler.
Highlights
Issues such as climate change and the depletion of fossil fuels have promoted the development and utilization of biomass renewable energy to reduce the dependence of power plants on fossil fuels [1]
This study analyzed the effects of torrefaction techniques on the properties of R-empty fruit bunch (EFB) and evaluated the feasibility of co-firing torrefied EFB (T-EFB) and coal in large-scale boiler through simulation
The combustion characteristics of boilers under different blending ratio conditions were analyzed by simulation, and it was found that due to the rapid combustion of T-EFB high volatile fractional matter to generate heat, the high temperature zone inside the boiler diffused towards the burner near, but the furnace peak temperature decreased slightly
Summary
Issues such as climate change and the depletion of fossil fuels have promoted the development and utilization of biomass renewable energy to reduce the dependence of power plants on fossil fuels [1]. Demand for palm oil has increased as economic growth that led to large-scale palm cultivation in Indonesia and Malaysia. The other reason is that palm act as the dominant agricultural crop in developing countries and the two mentioned countries produce more than 80% of the global palm oil supplement. According to data released by the Indonesian Ministry of Agriculture, the area under palm cultivation has increased 2.3 times from 2010 to 2020 [3]. The mass production of palm oil generates a large amount of solid waste, including empty fruit bunches (EFB), palm kernel shells (PKS) and palm pressed pericarp fibers [4,5]. Part of the EFB is directly used as fuel to power palm oil processing plants, part as organic fertilizer, and the remaining part is discarded or incinerated
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