Material processing machines and methods of use

The invention claimed is: 1. A material processing machine comprising: an enclosure comprising a fluid inlet and a channel fluidically connected to the fluid inlet; and a cutting assembly within the enclosure, the cutting assembly comprising a cutting head surrounding an impeller adapted for rotation within the cutting head about an axis thereof, the cutting head comprising a support ring that surrounds the impeller and knives disposed below the support ring, the support ring comprising multiple first passages that are fluidically connected to the channel of the enclosure to receive therefrom a liquid flowing in the channel and configured to conduct the liquid along a perimeter of the cutting head, through the support ring, and onto portions of the cutting head that are below the support ring and surround the impeller. 2. The material processing machine according to claim 1 , wherein the enclosure comprises a distribution ring having at least one passage therein that fluidically connects the channel of the enclosure and the first passage in the support ring of the cutting head. 3. The material processing machine according to claim 2 , wherein the distribution ring and the support ring are annular shaped and axially abut each other. 4. The material processing machine according to claim 1 , wherein the first passage in the support ring of the cutting head intersects a first axial surface of the support ring and intersects a peripheral surface of the support ring. 5. The material processing machine according to claim 4 , wherein the first passage of the support ring is configured such that the liquid flowing therethrough cascades around the knives of the cutting head in an axial direction of the cutting head. 6. The material processing machine according to claim 4 , further comprising at least a second passage in the support ring of the cutting head that is fluidically connected to the first passage and intersects a second axial surface of the support ring oppositely disposed from the first axial surface thereof, and the second passage is configured such that the liquid flowing therethrough cascades around the knives of the cutting head in an axial direction of the cutting head. 7. The material processing machine according to claim 6 , wherein the second passage of the support ring is configured such that the liquid flowing therethrough cascades around the knives of the cutting head in an axial direction of the cutting head. 8. The material processing machine according to claim 4 , wherein the support ring further comprises a plurality of second passages that are spaced around a perimeter of the cutting head, fluidically connected to the first passages, and intersect a second axial surface of the support ring oppositely disposed from the first axial surface thereof, and the second passages are configured such that the liquid flowing therethrough cascades around the knives of the cutting head in an axial direction of the cutting head. 9. The material processing machine according to claim 1 , wherein the knives are comminution knives that have a radial and axial orientation relative to the cutting head. 10. A method of reducing the size of a solid material using the material processing machine of claim 1 , the method comprising: introducing the material to the impeller while rotating the impeller to comminute the material with the knives of the cutting head and cause the comminuted material to flow radially outward through gaps between the knives; and introducing a liquid into the channel via the fluid inlet of the enclosure, the liquid flowing through the first passage of the support ring and cascading around the knives of the cutting head in an axial direction of the cutting head. 11. The method according to claim 10 , wherein the method produces a suspension, sol, gel, slurry, or paste. 12. The method according to claim 10 , wherein the method produces a polymer-water suspension and the method further comprises using the polymer-water suspension to displace oil in enhanced oil recovery (EOR) and oil sands tailings treatment applications. 13. The method according to claim 12 , wherein the material is polymer particles, the liquid is water, and the material processing machine simultaneously mixes, disperses, and dissolves the comminuted polymer particles in the water. 14. A method of processing a solid material by reducing the size of the material and dispersing the material in a liquid, the method comprising: cutting the material with knives located along a perimeter of an annular-shaped cutting head and causing the cut material to flow radially outward from the annular-shaped cutting head through gaps between the knives; and flowing a liquid through multiple first passages in the annular-shaped cutting head to conduct the liquid along the perimeter of the annular-shaped cutting head, through the annular-shaped cutting head, and onto the knives of the annular-shaped cutting head in an axial direction of the annular-shaped cutting head. 15. The method according to claim 14 , wherein the annular-shaped cutting head is within an enclosure, the knives are located along the perimeter of the annular-shaped cutting head by a support ring thereof, the passages are located in the support ring, the cutting step comprises rotating an impeller within the annular-shaped cutting head, and the flowing step comprises delivering the liquid to the passages in the support ring through a channel of the enclosure. 16. The method according to claim 14 , wherein the method produces a suspension, sol, gel, slurry, or paste. 17. The method according to claim 14 , wherein the method produces a polymer-water suspension and the method further comprises using the polymer-water suspension to displace oil in enhanced oil recovery (EOR) and oil sands tailings treatment applications. 18. The method according to claim 17 , wherein the material is polymer particles, the liquid is water, and the material processing machine dissolves the comminuted polymer particles in the water.