Dewatering and thickening decanters from GEA are continuously operating horizontal solid bowl centrifuges for efficient sludge treatment and economical volume reduction. The frame is of open design with either gravity or pressure discharge of the clarified phase.
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For clear clarification, liquid separation and solids dewatering in chemical and mineral processing applications. The heavy or light liquid phase is discharged under pressure by use of a centripetal pump while the other liquid phase is discharged by drain tubes. CIP-compatability of the decanter can be assured.
The GEA biosolids Decanter is a continuously operating centrifuge with a horizontal solid-wall bowl designed specifically for (pre)dewatering and thickening of municipal sludge.
Innovative dry-on-demand solution for biosolids treatment.
GEA Intellicant – engineered intelligence to monitor, automate and optimize your sludge dewatering process.
Corrective repairs for your GEA separators and decanters
Is a FAT (Factory Acceptance Test) of your centrifuge not possible on site due to current travel restrictions, a very tight schedule or other urgent reasons? Are you generally looking for ways to make business processes more digital and to sustainably reduce costs and time?
Here, too, we are at your side with the professional quality you are accu...
The innovative process diagnostic and consultant service.
GEA environmental Decanter pro
Mobile Decanter Systems
Nachhaltige Trinkwasserversorgung in Indonesien
The impact of global warming is increasingly apparent all over the world. Towns and cities everywhere face the same challenge: providing their communities with reliable, affordable, sustainably sourced heat. GEA spoke with an expert in the field, Kenneth Hoffmann, Manager, Heat Pumps at GEA Heating & Refrigeration Technologies, about tackling global warming faster.
Something caught Farmer Tom's eye. Instead of another product demo, GEA showcased innovations via AR. That's only the start of GEA's interactive digital farm.
GEA scientists are working with researchers at the Graz University of Technology to configure a homogenization process and technology that turns eucalyptus pulp into 3D-printed, organic structures mimicking human veins, arteries and other tissues.