Energy Science and Technology

The use of process systems engineering tools, such as process modeling software enable the alternative generation of more efficient and sustainable processes. This paper presents the simulation of cement process using alternative fuels to replace coal.  The process modeling is performed using Aspen HYSYS. Simulation results revealed that the substitution of fuel oil, natural gas and palm kernel shell for coal had a significant contribution for emission reduction in cement industry. The emissions for the base case scenario found to be 40,317 kg/h CO₂, 806 kg/h NO₂ and 146.8 kg/h SO₂. Utilizing fuel oil mitigated 22% of CO₂ and 92% of NO₂ but increased 232% of SO₂ emissions. Altering coal to palm kernel shell resulted in 46.16% of CO₂, 73% of NO₂ and 68% of SO₂ emission reduction. In the best case 45.64 % reduction of CO₂ emissions was achieved by replacing coal to natural gas and neither NO₂ nor SO₂ was generated.

Key words: Cement plant; Process simulation; Aspen HYSYS; Alternative fuels; Air pollution reduction

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