Side channel liquid ring pump and impeller for side channel liquid ring pump

What is claimed is: 1. An impeller for a liquid ring pump comprising: a central hub defining a conical outer surface; a plurality of angularly spaced apart main vanes extending radially outward from the conical outer surface, and wherein the conical outer surface of the impeller has a first end having a first radius and a second end having a second radius, the second radius being greater than the first radius, a reinforcing ring connecting distal end portions of adjacent main vanes; wherein the reinforcing ring being axially positioned between a port side of the main vanes and a back side, opposite the port side of the main vanes of the impeller, and wherein the impeller is positioned in an impeller cavity of a liquid ring pump housing. 2. The impeller of liquid ring pump of claim 1 , wherein the central hub defines a central rotational axis about which the impeller rotates. 3. The impeller of claim 1 , further comprising a plurality of secondary vanes extending axially from the reinforcing ring, the secondary vanes being spaced radially outward from the conical outer surface of the central hub. 4. The impeller of claim 3 , wherein the main vanes and secondary vanes alternate angularly about the central rotational axis such that a secondary vane is positioned angularly between adjacent main vanes. 5. A liquid ring pump comprising: a housing defining an impeller cavity, the impeller cavity has an inlet port and a discharge port; an impeller positioned within the impeller cavity for rotation about a central rotational axis, the impeller including: a central hub defining a conical outer surface; and a plurality of angularly spaced apart main vanes extending radially outward from the conical outer surface relative to the central rotational axis, and wherein the conical outer surface of the impeller has a first radius proximate a port side of the impeller and the conical outer surface of the central hub has a second radius proximate a back side of the impeller, the back side being axially spaced apart from the port side along the central rotational axis, the first radius being smaller than the second radius, a reinforcing ring connecting distal end portions of adjacent main vanes; wherein the reinforcing ring being axially positioned between the port side of the main vanes and the back side, opposite the port side of the main vanes of the impeller. 6. The liquid ring pump of claim 5 , further comprising a plurality of secondary vanes extending axially from the reinforcing ring, the secondary vanes being spaced radially outward from the conical outer surface of the central hub. 7. The liquid ring pump of claim 6 , wherein the main vanes and secondary vanes alternate angularly about the central rotational axis such that a secondary vane is positioned angularly between adjacent main vanes. 8. The liquid ring pump of claim 5 , wherein the inlet and discharge ports are located on a same side of the impeller. 9. The liquid ring pump of claim 8 , wherein the inlet and discharge ports of the impeller housing are located proximate the port side of the impeller and are axially spaced away from the back side of the impeller along the central rotational axis. 10. The liquid ring pump of claim 5 , wherein the impeller housing defines a side channel in a radial periphery thereof. 11. A method of pumping an air/fuel mixture comprising: receiving a fuel and air through an inlet port of an impeller housing of a liquid ring pump; wherein the liquid ring pump has a reinforcing ring; discharging the fluid through a discharge port of the impeller housing; creating a pressure differential along a conical outer surface of a central hub of an impeller located within an impeller cavity of the impeller housing for rotation about a central rotational axis, the impeller cavity being in fluid communication with the inlet port and discharge port, the impeller including a plurality of main vanes extending radially outward from the conical outer surface relative to the central rotational axis, and wherein the conical outer surface of the impeller has a first radius proximate the discharge port and a second radius spaced axially away from the discharge port along the central rotational axis, the second radius being greater than the first radius. 12. The method of claim 11 , wherein the pressure differential reduces in pressure when moving along the conical surface from the second radius toward the first radius. 13. The method of claim 11 , wherein the inlet and discharge ports of the impeller housing are located proximate a port side of the impeller and are axially spaced away from a back side of the impeller along the central rotational axis, the port side being proximate the first radius and the back side being proximate the second radius.