Systems and methods for rotating coalescers maintaining positive recirculation through a dynamic seal

What is claimed is: 1. A crankcase ventilation system, comprising: a housing; an inlet configured to receive blowby gases from an internal combustion engine and to provide the blowby gases to the housing; an outlet configured to provide filtered blowby gases from the housing and to at least one of an intake of the internal combustion engine and a surrounding ambient; a rotating coalescer positioned within the housing such that a gap exists between the rotating coalescer and the housing, D 0 is an inside diameter of a rotating portion of the rotating coalescer, the rotating portion representing an outer diameter of the gap, the rotating coalescer including: a first endcap, a filter media, wherein the gap permits gas flow between a clean side of the filter media and a dirty side of the filter media, and a frame surrounding an outside surface of the filter media, the frame comprising a plurality of vanes disposed radially outward of the filter media; and a central shaft coupled to the rotating coalescer, the central shaft rotatable such that when the central shaft rotates, the rotating coalescer rotates and creates a pumping pressure that causes a high pressure within the housing on the clean side of the filter media and a low pressure on the dirty side of the filter media and at an inlet in the gap at the inside diameter D 0 , thereby causing a positive recirculation of the blowby gases in which a portion of already filtered blowby gas from the clean side of the filter media returns through the gap to the dirty side of the filter media. 2. The crankcase ventilation system of claim 1 , wherein the filter media is non-pleated. 3. The crankcase ventilation system of claim 2 , wherein the filter media is selected such that π · κ · ω 2 · h · ( D 3 2 - D 0 2 ) 4 · Q · v · ln ⁡ ( D 2 D 1 ) > 1 is satisfied, where: ω is the rotational speed of the rotating coalescer in rad/s, h is a media height of the filter media in m, D 1 is an inner diameter of the filter media in m, D 2 is an outer diameter of the filter media in m, D 3 is an outer diameter of the filter element in m, v is a kinematic viscosity of the blowby gases in m 2 /s, Q is a flowrate of the blowby gases in m 3 /s, and κ is a permeability of the filter media in m 2 . 4. The crankcase ventilation system of claim 2 , wherein the filter media possesses a value of N hyd of less than or equal to 3000, where N hyd = t κ , κ being a permeability of the filter media in m 2 and t being a thickness of the filter media in m. 5. The crankcase ventilation system of claim 4 , wherein the filter media has a thickness of less than 0.0005 m and possesses a value of N hyd of 75 to 500. 6. The crankcase ventilation system of claim 4 , wherein the filter media has a thickness between 0.0005 m and 0.001 m and possesses a value of N hyd of 100 to 700. 7. The crankcase ventilation system of claim 4 , wherein the filter media has a thickness between 0.001 m and 0.002 m and possesses a value of N hyd of 130 to 1000. 8. The crankcase ventilation system of claim 4 , wherein the filter media has a thickness between 0.002 m and 0.004 m and possesses a value of N hyd of 160 to 1300. 9. The crankcase ventilation system of claim 4 , wherein the filter media has a thickness between 0.004 m and 0.008 m and possesses a value of N hyd of 200 to 1800. 10. The crankcase ventilation system of claim 4 , wherein the filter media has a thickness between 0.008 m and 0.015 m and possesses a value of N hyd of 300 to 2200. 11. The crankcase ventilation system of claim 4 , wherein the filter media has a thickness between 0.015 m and 0.03 m and possesses a value of N hyd of 400 to 3000. 12. The crankcase ventilation system of claim 1 , wherein the filter media is pleated. 13. The crankcase ventilation system of claim 12 , wherein the filter media is selected such that κ · N · h · ( D 2 2 - 2 ⁢ D 1 ⁢ D 2 ⁢ cos ⁡ ( κ N ) + D 1 2 ) 1 2 · ω 2 · ( D 3 2 - D 0