We use established segregation and dry AD technology that is based on industry standards and applied in over 100 locations across Europe, Africa & Asia, with a proven track-record of over 20 years.
SusBDe will help start up the installation and provide onsite training to your designated people responsible for the basic functioning of the installation and small maintenance activities like changing filter cartridges.
Elevate Your Standards: Our Dutch-Built Skid-Mounted Components, Compliant with DIN norms, and Certified by Leading Authorities and customized to Your Certification Preferences.
Explore the groundbreaking SusBDe project in Nagpur, India, a model for transforming municipal waste into valuable resources and clean energy. This innovative plant demonstrates a comprehensive solution for sustainable waste management, turning waste into biogas and or also electricity, compost, and other essential resources through advanced sorting and processing techniques.
Watch how this pilot project, the SusBDe blue-print, sets the stage for a larger roll-out across India, driving environmental impact and contributing to a cleaner, more sustainable future.
Our innovative SUS BDE concept revolutionizes waste management by transforming municipal solid waste into valuable resources through a four-step process. This system efficiently handles unsorted waste, extracting maximum value while minimizing environmental impact. From initial segregation to final composting, each step is carefully designed to optimize resource recovery and energy production.
Below, we break down our process into four key stages, each playing a crucial role in our sustainable waste management solution. Discover how we turn waste into a valuable resource, contributing to a cleaner, more sustainable future.
Organic materials form the basis for biogas fermentation. Therefore, the organic matter gets separated from other fractions in the waste, through a segregation system, designed to handle the unsorted MSW waste with high moisture contents and contamination.
The mechanical system comprises of a hopper, a steel slag conveyor, trommel screens, belt conveyors, an air separator, magnets, etc. In case of any escape of small quantity, it will not affect the biogas production as well as compost.
Biogas is generated through the anaerobic digestion process, in which bacteria break down organic materials like solid animal manure, biowaste, and food waste in an oxygen-deprived environment.
This sustainable approach harnesses the potential of these organic resources, transforming them into biogas—a valuable source of energy in the form of gas, as well as beneficial soil products in the form of liquids and solids. Biogas systems leverage anaerobic digestion to efficiently repurpose these organic materials, promoting both environmental conservation and energy production.
During fermentation, biogas is extracted from the resulting mass. This process is closely monitored to allow for optimal gas extraction.
Afterwards, biogas is further purified. The Biogas purification technique is based on Membrane upgrading technology, as this is consistent and delivering of the highest possible methane.
The fourth step is Composting. This is an organic method of producing compost manure by decomposition and stabilization of organic matter. Composting process is a commonly used method and results in the production of stable compost product reduced in size (when compared to initial size) and free from offensive odors.
Composting can be carried out in ways including aerobically, anaerobically, vermi-composting and by any other biological mechanism..
