High-Temperature Steam Gasification of Agricultural and MSW and Conversion to Energy System 02/21/2012 TAG meeting
INTRODUCTION
Background Increasing MSW Generation Rates Disadvantage of Partial Oxygen Gasification or Incineration Lower temperature gasifier produces low-quality syngas that contains undesirable char, tar and soot Harmful emissions due to the air-breathing combustion
Objective Define the critical parameters affecting product yields Develop optimal conditions for thermal-chemical conversions Develop cost-effective method for the production of hydrogen fuel Agricultural Wastes MSW High Temperature Steam Gasification
Team Members PI Skip Ingley, Department of Mechanical and Aerospace Engineering, University of Florida. - Tel Jacob N. Chung, Department of Mechanical and Aerospace Engineering, University of Florida. - Tel Members Name Atish Shah Graduate student Billy Allen Samuel Mammo Stephen Belser Uisung Lee Andrew Hatcher Undergraduate student Thomas Lunden
Team Members Hinkley Center Project Manager Tim Vinson TAG Members Tim Townsend, Professor, Environmental Engineering Sciences, University of Florida John Anderson, CEO Quantera Energy Resourse, Inc. Brent Wainwright, Principal, Green Team Ventures, LLC John Kuhn, Assistant Professor, Department of Chemical and Biomedical Engineering, University of South Florida
MSW CHARACTERIZATION
MSW Characterization Typical MSW composition by material Total MSW composition by material before recycling, 2009 [data from EPA]
MSW samples Experimental Feedstock Composition MaterialComposition Paper Corrugated boxes Newspaper Office type paper 22.8% 6.5% 4.5% Food scrap Dog food Additional water (moisture content compensation) 5.3% 11.7% Woodsawdust7.8% Yard TrimmingGrass, Leaves, Brush trimming16.5% Plastics (1)PET (2)HDPE (3)PVC (4)LDPE (5)PP (6)PS 2.4% 3.6% 0.8% 4.3% 3.8% 1.7% Rubber and leather 3.7% Textiles 6.3% Total100.0% MSW sample
Proximate and Ultimate Analysis Keystone Materials Testing, Inc.
EXPERIMENTAL SYSTEM DESIGN
Previous system Supply the high temperature steam via combustion of hydrogen and oxygen Batch type
Current Experimental Setup Schematic
Steam Generator / Superheater Steam Generator Superheater PumpControler
Gasifier & Cooler Condensate Collector Syngas Cooler Exhaust Sampling Gasifier Steam Injector
Gasifier & Cooler Steam Injector Ceramic Honeycomb Condensate Collector Feedstock
Steam Injector
FLUENT Simulation Steam injection profile Velocity Temperature improvement scheme
Feeder Ball Valve Argon Purging Gas Inlet/Outlet Piston
Heating Tape Preheater for the feedstock Electric Heating Tape
Experimental Equipment Steam generator Superheater Gasifier Feeder Syngas Cooler Argon Cylinder Gas Sampling Exhaust Condensate Collector
Steam Injector and Base Module
Ceramic Honeycomb Discs
SIMULATION RESULTS
Equilibrium Model exist C (s) ? 3 independent reactions Predicted syngas composition : CO, CO 2, CH 4, H 2, N 2 and H 2 O 2 independent reactions yes. 7 species no. 6 species C (s) + CO 2 ↔ 2CO C (s) + H 2 O ↔ H 2 + CO C (s) + 2H 2 ↔ CH 4 CH 4 + H 2 O ↔ CO + 3H 2 CO + H 2 O ↔ CO 2 + H 2 Setup the Global Gasification Reaction Assume there would be C (s)
Equilibrium Model Solve equations with numerical method Equilibrium Constant Solve equations with numerical method Equilibrium Constant yes End no
Results Gas composition
Result
CURRENT ISSUES
Current Issues Conduct Steam Temperature Tests and Measure Temperature Profiles in Gasifier Finalize Arrangements for Syngas Sampling Steam to Biomass Ratio Tests with Woody Biomass Conduct Gasification Runs with MSW, MSW Components and Farm Wastes
Questions andDiscussion ?