초록 ▼

Disclosed herein are systems and methods for removing fine particulate matter from a fluid, comprising a separator that separates an inflow fluid stream into an overflow fluid path and an underflow fluid path, where the underflow fluid path is treated with a tethering material that attaches to the c

Disclosed herein are systems and methods for removing fine particulate matter from a fluid, comprising a separator that separates an inflow fluid stream into an overflow fluid path and an underflow fluid path, where the underflow fluid path is treated with a tethering material that attaches to the coarse particulate matter to form tether-bearing anchor particles and where the overflow fluid path is treated with an activating material so that the activating material interacts with the fine particulate matter to form activated particles. After these treatments, the underflow fluid path containing the tether-bearing anchor particles is commingled with the overflow fluid path containing the activated particles, so that a removable complex is produced that can be removed in a settling facility, thereby removing the fine particulate matter from the fluid. The systems and methods are particularly advantageous for removing particulate matter from a fluid waste stream following mining or ore processing operations, such as oil sands mining or processing.

대표청구항 ▼

1. A method for removing fine particulate matter from a fluid, comprising: separating an inflow fluid stream comprising fine particulate matter and coarse particulate matter suspended therein into an overflow fluid path comprising the suspended fine particulate matter and an underflow fluid path com

1. A method for removing fine particulate matter from a fluid, comprising: separating an inflow fluid stream comprising fine particulate matter and coarse particulate matter suspended therein into an overflow fluid path comprising the suspended fine particulate matter and an underflow fluid path comprising the suspended coarse particulate matter;introducing into the underflow path a tethering polymer to form a treated underflow path, wherein the tethering polymer affixes to the coarse particulate matter to form tether-bearing coarse particulate matter suspended in the treated underflow path, wherein the tethering polymer is an anionic polymer or a cationic polymer;admixing the overflow fluid path with the treated underflow path to form a conjoined fluid stream;introducing into the conjoined fluid stream an activating polymer that affixes to the fine particulate matter to form activated particles, wherein the activating polymer of said activated particles interacts with the tethering polymer of said tether-bearing coarse particulate matter to form removable complexes comprising the fine particulate matter and the coarse particulate matter; andseparating the removable complexes from the conjoined fluid stream, thereby removing the fine particulate matter from the fluid,wherein when the tethering polymer is an anionic polymer, the activating polymer is a cationic polymer, and when the tethering polymer is a cationic polymer, the activating polymer is an anionic polymer. 2. The method of claim 1, further comprising adding an additional activating polymer to the overflow fluid path before admixing the overflow fluid path with the treated underflow path. 3. The method of claim 2, wherein the activating polymer introduced into the conjoined fluid stream and the additional activating polymer are the same. 4. The method of claim 1, wherein the inflow fluid stream is separated into an overflow path and an underflow path using a hydrocyclone. 5. The method of claim 1, wherein the conjoined fluid stream is transported to another location before introducing the activating polymer into the conjoined fluid stream. 6. The method of claim 1, wherein the fine particulate matter is generated from a mining operation. 7. The method of claim 1, wherein the underflow fluid path is split into a plurality of underflow fluid subpaths. 8. The method of claim 7, wherein a first underflow subpath contains untreated cyclone underflow fluid. 9. The method of claim 7, wherein a second underflow subpath is directed to a second separator that produces cyclone overflow and cyclone underflow. 10. The method of claim 9, wherein the second separator is a hydrocyclone. 11. The method of claim 9, wherein the cyclone underflow from the second separator is treated with the tethering polymer. 12. The method of claim 7, wherein one of the plurality of underflow subpaths is treated with the tethering polymer. 13. A method for removing fine particulate matter from a fluid comprising: separating an inflow fluid stream into an overflow fluid path containing suspended fine particulate matter, and an underflow fluid path;introducing tether polymer-bearing anchor particles into the underflow fluid path to form a treated underflow fluid path, wherein the tether polymer-bearing anchor particles are anchor particles to which tethering polymer is affixed and wherein the tethering polymer is an anionic polymer or a cationic polymer;introducing a first activator polymer into the overflow fluid path to form a treated overflow fluid path, wherein the first activator polymer complexes with the fine particulate matter to form a first set of activated particles;admixing the treated underflow fluid path and the treated overflow fluid path to form a conjoined fluid stream;introducing a second activator polymer into the conjoined fluid stream, wherein the second activator polymer complexes with fine particulate matter to form a second set of activated particles, wherein the tethering polymer of the tether polymer-bearing anchor particles interact with the first and second sets of activator polymers of the activated particles to form removable complexes comprising the fine particulate matter and the anchor particles; andseparating the removable complexes from the conjoined treated fluid stream, thereby removing fine particulate matter from the fluid,wherein when the tethering polymer is an anionic polymer, the first and second activator polymers are cationic, and when the tethering polymer is a cationic polymer, the first and second activator polymers are anionic. 14. The method of claim 13, wherein the first activator polymer and the second activator polymer are the same. 15. The method of claim 13, wherein the conjoined fluid stream is transported to another location before introducing the second activating polymer into the conjoined fluid stream. 16. The method of claim 13, wherein the fine particulate matter is generated from a mining operation.