0000000001069472

AUTHOR

Toivo Kuokkanen

showing 2 related works from this author

Sulphate Removal from Water by Carbon Residue from Biomass Gasification: Effect of Chemical Modification Methods on Sulphate Removal Efficiency

2016

Sulphate removal from mine water is a problem because traditional chemical precipitation does not remove all sulphates. In addition, it creates lime sediment as a secondary waste. Therefore, an inexpensive and environmental-friendly sulphate removal method is needed in addition to precipitation. In this study, carbon residues from a wood gasification process were repurposed as precursors to a suitable sorbent for SO42- ion removal. The raw material was modified using ZnCl2, BaCl2, CaCl2, FeCl3, or FeCl2. Carbon residues modified with FeCl3 were selected for further consideration because the removal efficiency toward sulphate was the highest. Batch sorption experiments were performed to eval…

Environmental EngineeringSorbentActivated carbonlcsh:BiotechnologyInorganic chemistryBioengineering02 engineering and technology010501 environmental sciencesengineering.materialRaw material01 natural scienceslcsh:TP248.13-248.65medicineWaste Management and Disposal0105 earth and related environmental sciencesLimeWood gas generatorPrecipitation (chemistry)ChemistryChemical modificationSorption021001 nanoscience & nanotechnologysulphateengineeringCarbon residueSorption0210 nano-technologychemical modificationActivated carbonmedicine.drugBioResources
researchProduct

Electrocoagulation treatment of peat bog drainage water containing humic substances

2015

Abstract Electrocoagulation (EC) treatment of 100 mg/L synthetic wastewater (SWW) containing humic acids was optimized (achieving 90% CODMn and 80% DOC removal efficiencies), after which real peat bog drainage waters (PBDWs) from three northern Finnish peat bogs were also treated. High pollutant removal efficiencies were achieved: Ptot, TS, and color could be removed completely, while Ntot, CODMn, and DOC/TOC removal efficiencies were in the range of 33–41%, 75–90%, and 62–75%, respectively. Al and Fe performed similarly as the anode material. Large scale experiments (1 m3) using cold (T = 10–11 °C) PBDWs were also conducted successfully, with optimal treatment times of 60–120 min (applying…

Environmental EngineeringPeatmedicine.medical_treatmentColorIndustrial WasteWastewaterWaste Disposal FluidElectrolysisElectrocoagulationWater PurificationSoilmedicineDrainageOperational costsWaste Management and DisposalBogFinlandHumic SubstancesWater Science and TechnologyCivil and Structural EngineeringBiological Oxygen Demand AnalysisPollutantgeographygeography.geographical_feature_categoryChemistryEcological ModelingOptimal treatmentEnvironmental engineeringPollutionWastewaterEnvironmental chemistryWater Pollutants ChemicalWater Research
researchProduct