GreenShift’s portfolio of currently available technologies includes over a dozen ‘killer-app’ clean technologies that we strongly believe are capable of facilitating tremendous gains in productivity and the state of our environment:
 Recover up to 75% of the oil from your distillers dry grain for cost-effective conversion into biodiesel with our patent-pending Corn Oil Extraction System™. |
| » Learn More |
|
|
 Reduce your disposal of dissolved air flotation sludges by over 80% with our proprietary DAF Recycling System™. |
| » Learn More |
|
|
 Make money reducing your greenhouse gas emissions by recirculating exhaust CO2 into ethanol and biodiesel with algae in our patented CO2 BioReactor. |
| » Learn More |
|
|
 Harness the natural dynamics of a contained tornado to instantly grind, flash desiccate and atomize liquids and solids into micron sized powders. |
| » Learn More |
|
|
 Our fire-hydrant sized device can generate 25 gallons of pure water per hour from a variety of dirty water input sources at a cost of approximately $0.004 per gallon, or about 1.2% of the cost of traditional distillation methods. |
| » Coming Soon |
|
|
 We use high intensity ultrasonic energies to synthesize clean burning fuels including hydrogen out of organic industrial wastes, plastics, cellulosic biomass, and septic wastes, as well as other organic feedstocks. |
| » Coming Soon |
|
|
 The exceptional conductivity, very high porosity, and extremely high surface areas enable carbon aerogels to have broad potential in a number of clean technologies, including construction products, emissions control, hydrogen purification and storage, and solar power applications. |
| » Coming Soon |
|
|
 Developed by Argonne National Laboratory under a contract with the U.S. Department of Energy, this technology cost-effectively and preferentially separates targeted plastics from a mixed plastics stream to enhance the value of recycled plastics. |
| » Coming Soon |
|
|
 An advanced form of chemical precipitation based on the ability of several compounds to form strong complexes with a wide variety of metal ions in liquid wastes. The technology preferentially targets di- and trivalent metal ions to form stable complexes across a relatively broad pH range. Complexed metals are extracted in concentrations in excess of virgin ore and are readily amenable to smelting and refining. |
| » Coming Soon |
|
|
|
|
