0000000000223627

AUTHOR

Madhawa Jayathilake

0000-0002-5416-8760

showing 3 related works from this author

Hydrothermal liquefaction of wood using a modified multistage shrinking-core model

2020

Abstract Wood liquefaction in hot compressed water is modeled using the hydrolysis of Cellulose, Hemicellulose, and Lignin. These three components are reacted under catalyst-free subcritical conditions in a temperature range from 553 K to 640 K, and the heating rate ranges from 2 K/min to 6 K/min. Using a simplified reaction scheme, water-soluble products 1 (WSP), Biocrude, char, and gas are generated through intermediates with each wood component. A modified multistage shrinking core model is employed to simulate biomass particle degradation. The reaction and kinetic regime of the hydrothermal liquefaction 2 (HTL) process are treated separately for each wood component. Although the lack of…

Materials science020209 energyGeneral Chemical EngineeringEnergy Engineering and Power Technology02 engineering and technologyHydrolysischemistry.chemical_compound020401 chemical engineering0202 electrical engineering electronic engineering information engineeringLigninHemicelluloseChar0204 chemical engineeringCelluloseHydrolysisOrganic ChemistryShrinking-coreLiquefactionWoodHydrothermal liquefactionVDP::Teknologi: 500LiquefactionFuel TechnologychemistryChemical engineeringParticle size
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Characterization and Evaluation of Hydrothermal Liquefaction Char from Alkali Lignin in Subcritical Temperatures.

2021

An evaluation of hydrothermal liquefaction (HTL) char is investigated in this work. Morphological studies, N2 adsorption behavior, FTIR analysis, thermal behavior, and elemental composition are studied. The HTL char yield showed an increase with higher operating temperatures. It increased from 11.02% to 33% when the temperature increased from 573 K to 623 K. At lower temperatures, the residence time showed an impact on the yield, while close to the critical point, residence time became less impactful. Elemental analysis showed that both higher operating temperatures and longer residence times increased the nitrogen content of the chars from 0.32% to 0.51%. FTIR analysis suggested the char b…

Technology020209 energychemistry.chemical_elementlignin02 engineering and technologyResidence time (fluid dynamics)HTL charArticleAdsorptionpores0202 electrical engineering electronic engineering information engineeringGeneral Materials ScienceCharTGAMicroscopyQC120-168.85CarbonizationChemistryTQH201-278.5carbonization021001 nanoscience & nanotechnologyEngineering (General). Civil engineering (General)NitrogenTK1-9971Hydrothermal liquefactionVDP::Teknologi: 500Volume (thermodynamics)Chemical engineeringFTIRDescriptive and experimental mechanicsElemental analysisVDP::Matematikk og Naturvitenskap: 400::Kjemi: 440SEMElectrical engineering. Electronics. Nuclear engineeringTA1-20400210 nano-technologyMaterials (Basel, Switzerland)
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Numerical modeling and validation of hydrothermal liquefaction of a lignin particle for biocrude production

2021

Abstract Lignin liquefaction process under catalyst-free conditions in a temperature range from 573 K to 647 K is investigated with this mathematical model. Based on the theoretical understanding of the physical and chemical processes of the liquefaction process in subcritical temperatures, a comprehensive mathematical model for the decomposition of lignin by hydrolysis reaction pathway is developed on the results of a series of batch experiments. The model consists of four main sections. They are liquefaction of lignin particle, oily film, and inorganic (ash) layer formation behavior during the liquefaction, kinetic model to model further liquefaction process of initial products, and the l…

Materials scienceWater transportAsh layerGeneral Chemical EngineeringDiffusionOrganic ChemistryShrinking-coreEnergy Engineering and Power TechnologyLiquefactionDecompositionLigninOily filmVDP::Teknologi: 500Hydrothermal liquefactionFuel TechnologyChemical engineeringNumerical modellingMass transferParticleDissolutionHydrothermal liquefaction
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