gas-phase chemical reduction (gpcr)
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Gas-Phase Chemical Reduction
(GPCR)
Status & POPs Application Commercially operated in Australia more than 5
years, treating more than 2,500 t PCB’s, DDT and other POPs. In 1999 a full-scale test on HCB was conducted.
In Japan a semi-mobile GCPR plant for treatment of PCB wastes recently been operated
Participating in ACWA (Army Chemical Weapons Assessment) program for the destruction of chemical warfare agents.
POPs application:Pesticides such as DDT, Aldrin, Dieldrin, HCB’s, PCB’s, dioxins and furans and other POPs
Technology description
Gas-Phase Chemical Reduction (GPCR)Reactor
GasScrubbing
System
Product Gas Compression and Storage
Water
AuxiliaryBurner
Gas
Liquid
Solid
Fuel for Front-end Systems
Recirculation Gas
Mixer
Hydrogen and Steam Preheater
Liquid Waste Injection
Gaseous Waste Injection
Thermal ReductionBatch Processor (TRBP)
Front-End Waste Feed Waste Destruction Output Recovery
Treated Solids
TreatedSolids
Technology description
Reduction of organic compounds by hydrogen and some steam (acts as heat transfer agent + other source of hydrogen) at temperatures of > 850°C.
Organic compounds reduced to methane, hydrogen chloride (if waste is chlorinated), and minor amounts benzene and ethylene. Hydrochloric acid is neutralized by addition of caustic soda during initial cooling of process gas, or can be taken off in acid form for reuse, if desired. Cooled, scrubbed gas from the reactor (“Product Gas”) is compressed and analyzed. Product gas can then be reused as a fuel for plant components, or consumed in a burner
PART I: Adaptation Technology – Country
A. Performance:
1. Minimum pre-treatment:Requirement: gaseous form for reduction in GPCR reactor.
liquid wastes preheated and injected directly into the reactor continuously
solids must first be volatilized from the solid. Bulk solids and drummed chemicals placed in a TRBP, then heated to ca. 650°C in hydrogen-rich (oxygen deficient) atmosphere.
PART I: Adaptation Technology - Country
A. Performance (cont’d):
2. Destruction Efficiency (DE):
PCBs, HCBs and DDT. Here efficiencies of at least 99.9999 % demonstrated
Generally DE’s of 99.999%
PART I: Adaptation Technology - Country
A. Performance:
3. Toxic by-products: complete destruction
4. Uncontrolled releases: None. In an upset event, the system goes into recirculation mode and no untreated waste is released
5. Capacity to treat all POPs: yes
6. Throughput quantity [tons/day, l/day]: Chlorinated Pesticides + PCB oil:
= 840 t/y (semi mobile), 3360 t/y full scale) PCB capacitors:
Semi-Mobile 1400 t/y, Full Scale 5600 t/y
PART I: Adaptation Technology - Country
A. Performance:
POPs throughput : [POPs waste/total waste in %]: Commercial testing Australia: 30.3% DDT, 5.6% DDT, 96%
PCBs (1995/1996) Commercial testing General Motors: 50% PCBs and 30%
chlorobenzenes (1996) Commercial Australia: 84% hexachlorobenzene crystals
(april 1999) Demonstration portable plant Canada: 100%
dichlorofluoromethane gas (2002) Demonstration portable plant Canada: 100% lindane
powder (2003)
PART I: Adaptation Technology - Country
A. Performance:
7. Wastes/residuals:
Secondary waste stream volumes: completely destroyed in the process
Off gas treatment: Permitted to dispose of scrubber water in a variety of ways, including discharge to a local irrigation system, discharge to a surface water body, and discharge to a municipal sewer.
Complete elimination: yes
PART II: Adaption Country – Technology
A. Resource needs: basis 840/3360 t plant (per tonne waste treated)
Power requirement: (peak) demand: 1,000 kW/t, 2.5 Mwh/t Water requirement: steam 1500 kg/t, water 500 m3/t Fuel volumes: Nat gas 600Nm3/t Reagents volumes: N2: 75 m3, Caustic: 1.4 t, H2: 1000 Nm3 Weather tight buildings: Preferable Hazardous waste personnel requirement: Sampling requirements/facilities: Portable lab Peer sampling: Laboratory requirements: Communication systems: Remote access possible
PART II: Adaption Country – Technology
A. Resource needs: basis 840/3360 t/year plant (70 t/m/280 t/month)
Number of (un/skilled) personnel required: intensive
Solid Feed (2 TRBPs)
Liquid/gas Feed (1 TRBP)
Semi mobile: 4 persons/shift Semi mobile: 3 persons/shift
Full scale: 6 persons/shift Full scale: 5 persons/shift
PART II: Adaption Country – Technology
B: Costs for: Semi Mobile 70 t/m, FS: 280 t/m
Installation + commissioning: Semi Mobile: 5 Mio + Site preparation Full Scale: 10.5 mio
Energy & Telecom installation: Compliance: Reporting: Run without waste: Run with waste: Decommissioning: estimate 750.000 Landfilling: Transport residues:
PART II: Adaption Country – Technology
C. Impact & D. Risks Discharges to air:
1.75/7 Mio m3/month 72 % N2, 16 % H2O, 8 % O2, 4 % CO2
Discharges to water: 140 t/ 560 t/month
Discharges to land: very low
Risks reagents applied: Hydrogen intensive procedures
Risks of technology: Operational risks:
extensive process controls
PART II: Adaption Country Technology
E. Constructability & F. Output
Ease of installation & construction of plant Ease of shipping/transit:
Full Scale: 8-10 trailers Semi mobile: 4 trailers Ease of operation: Ease of processing: Generated waste (% of input waste): Deposited waste at landfill (% of input waste):
Waste quality properties (pH, TCLP)
Ecologic Plant in Kwinana, WA
Semi-Mobile Preheater in Japan
Ecologic Plant - Gas Scrubber
Thermal Reduction Batch ProcessorAustralia
Gas Phase Chemical Reduction Reactor
Excellent destruction (>99.9999%) All residues PCB-free
Not cost-effective for low strength wastesCostly to operate
Handles all wastes High power use
Minimum operator exposure Complex and labour intensive
Need for Hydrogen
Strength’s Weaknesses
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