Project Specifications
“24/7 waste treatment. 8400 hr/year electricity production”
Considering 2 weeks of maintenance where waste management activities continue without energy recovery.
6400 m2 total on
80m x 80m reinforced concrete basement.
20m tall chimney
3kWA 20kW 60Hz
Internet connection 20MB
Civil use water
No water discharged by process
Certifications
What about emissions?
Step 1
Granule production is entirely mechanical.
There are NO emissions
Step 2
A slow, multi-phase oxidation process controlling exhaust and dust emissions with multiple filtration systems and metal separation.
Resulting in inert ash, filtered solids
& excess heat energy.
Step 3
Turbines use the excess heat to produce electric energy.
A self-sustaining system producing
energy for the grid.
Emissions Monitoring, built in.
Figures
Feedstock / Mixed Waste
Max size: 2.5 x 2 x 1.5 m
5000 kg/m3
13.3 MJ/kg energy
Treatment
ton/day
96 ton MSW
20 ton sludges
2 ton medical
Average low calorific value
Up to 288 MWh per day
13.3 MJ/kg dry
12 MJ/kg 19 per wet
Energy Generation Capacity
3 MW electric generator
600 kW to 3300 kW
Energy Required:
210 kWh / ton of input waste
Hospitals
Recolte Portugal 2012 200 series
Ekiplanet Croatia 2016 200 series
Rebaltus Lithuania 2015 100 series
Ekomedika Montenegro 2013 2000 series
MIT Hospital Kazakhstan 2015 200 series
Brno Hospital (Siemens) 2017 200 series
KolinHospital Czech Republic 2021 200 series
Seed Hospital Pakistan 2017 100 series
Veterans Hospital Russia 2012 200 series
Global Medical Botswana 2018 400 series
National Hospital Panama 2018 200 series
E2M Hospital Indonesia 100 series
E2E Hospital Philippines 2019 100 series
INSTALLATIONS
Grocery / Malls
XMET Group UK 2015 200 series
XMET Group UK 2017 2000 series
Marine / Naval Vessels
Italian Navy 8 ships x 100 series
Italian Navy 60 series
French Navy 4 ships x 100 series
Royal Navy (UK) 8 ships x 100 series
US Hospital ship 60 series
Transfer Sites
Botswana Transfer 2021 2000 series
Kiel Germany 2015 1500 series
Arieco Turkey 5000 series
CRC Petrochemical South Africa 2000 series
Step 1. Waste Processing
Processing of multiple, mixed waste inputs into homogenous granules (N-RDF) for the production of electrical energy.
Step 2: Conversion Process
Step 2 is a multi-phase oxidation method designed to fully oxidate the N-RDF by transforming most of the oxygen, hydrogen, and carbon content of the input in CO2 and H2O, leaving at the end of the process a very low carbon content ash and recovering heat. This is a slow oxidation process in oxygen deficiency, it produces a clean and burnable syngas. The syngas and its latent heat is then fully oxidated in an oxygen excess gas burner to recover the energy content of the N-RDF. The low temperatures used during the first phases of the process and the slowness with which the process is deliberately carried out allows the creation of a very low environmental impact allowing instead an excellent energy recovery. The exhaust gases resulting from the oxidation process after their energy recovery are sent to the filtration system. The non-combustible materials, contained in the loaded NRDF, are rendered inert through their complete oxidation, separated from their metals content and collect inert ash.
Step 3: Electricity Production
The final step of the process involves:
A boiler cools the flue-gases and transfers the heat from the flue-gases from the gases to a thermal oil.
An ORC turbine then uses the heat of the thermal oil to produce electric energy.
Any thermal energy not converted by the ORC turbine is capture through an oil to air heat exchanger to produce on site heat, to enhance the internal plant's treatment processes (210 kWh / ton of input waste is diverted for self sustainment of the process).