Filter element, oil separator, and method for controlling prevailing pressure in crankcase ventilation system

What is claimed is: 1. A filter element for an oil separator of a crankcase ventilation system, the filter element comprising: at least one filter medium surrounding a central axis, the at least one filter medium configured to separate oil from aerosol, the at least one filter medium having an axial end surface forming a covering surface extending in a radial direction relative to the central axis; and a cover element formed as an annular end plate, fixed onto and fully covering the covering surface of the at least one filter medium; wherein the cover element forms a tubular projection on an axially outer surface of the cover element, the tubular projection projecting axially outwardly away from the at least one filter medium, the tubular projection having an open interior which opens through the cover element into an interior of the at least one filter medium, wherein the tubular projection is a clean fluid discharge element configured to remove cleaned fluid from an interior of the filter element; wherein an axially outer end of the tubular projection of the filter element has an annular sealing surface forming a valve seat; wherein the tubular projection is configured as a clean fluid discharge element that extends away from the filter element and is configured to remove cleaned fluid from an interior of the filter element to the valve seat of the cover element; wherein the valve seat of the cover element is configured as a sealing surface for a pressure control valve body of the crankcase ventilation system to sealably close against. 2. The filter element according to claim 1 , wherein the filter element is oval-cylindrical; and wherein the filter element has a cavity in the interior of the at least one filter medium; wherein the fluid to be filtered flows from the outer surface of the filter medium to the cavity; and wherein the cavity is connected directly to the clean fluid discharge element in order to remove the cleaned fluid. 3. The filter element according to claim 1 , wherein the clean fluid discharge element and/or the annular sealing surface is formed of at least one mechanically fixed and/or rigid material; wherein the at least one mechanically fixed and/or rigid material is a moldable material selected from the set consisting of: polyurethane, polyamide, or polyamide formed from polyamide 66 with 35% glass fiber (PA 66 GF 35). 4. The filter element according to claim 1 , wherein the annular sealing surface, the clean fluid discharge element, and the cover element are integrally formed as a unitary one-piece component. 5. The filter element according to claim 1 , wherein the at least one filter medium is a multi-layered non-woven wrap. 6. The filter element according to claim 1 , wherein the cover element and clean fluid discharge element are continuously closed. 7. An oil separator for a crankcase ventilation system, comprising: an oil separator housing including: a first housing part; and a second housing part secured to the first housing part and enclosing a chamber therein; a filter element according to claim 1 arranged in the chamber of the oil separator housing; wherein the first housing part includes at least one oil separator clean fluid outlet configured to remove the cleaned fluid the pressure control valve is configured to limit the negative pressure applied in the crankcase ventilation system, the pressure control valve formed in combination by: the valve seat of the filter element; and a valve closing body accommodated in the first housing part that operates in conjunction with and sealably closes against the valve seat; wherein the sealing surface of the tubular projection of the cover element of the filter element forms the valve seat against which the valve closing body sealably closes when the pressure control valve is in a closed state. 8. The oil separator according to claim 7 , wherein the valve closing body comprises at least one elastic valve closing body sealing element, at least on a region thereof arranged to contact with the valve seat of the filter element; and wherein the at least on a region of the at least one valve closing body is surrounded by an elastic valve closing body sealing element on the region thereof that is arranged to contact with the valve seat of the filter element. 9. The oil separator according to claim 8 , wherein the valve closing body sealing element is formed out of at least one elastomer; wherein the at least one elastomer are selected from the set: ethylene acrylate rubber (EAR) and/or from acrylate rubber and/or from hydrogenated nitrile rubber (H)NBR. 10. The oil separator according to claim 7 , wherein the valve closing body sealing element is connected fixedly, non-releaseably to the valve closing body; wherein the valve closing body sealing element is applied onto the valve closing body by a spray process. 11. The oil separator according to claim 7 , wherein the valve closing body is flat or level on the region thereof that faces the valve seat and contacts with the valve seat of the filter element. 12. The filter element according to claim 1 , wherein the annular sealing surface of the tubular projection is circular, substantially flat and free of burrs. 13. The filter element according to claim 1 , wherein a circumferential edge of the annular sealing surface of the tubular projection is rounded. 14. A method for limiting the crankcase vacuum of a crankcase ventilation system to a predetermined value, comprising: providing an oil separator housing enclosing a chamber therein; providing a filter element configured to separate oil from fluid, including: at least one filter medium surrounding a central axis, the at least one filter medium configured to separate oil from aerosol, the at least one filter medium having an axial end surface forming a covering surface extending in a radial direction relative to the central axis; and a cover element formed as an annular end plate, fixed onto and fully covering the covering surface of the at least one filter medium; wherein the cover element forms a tubular projection on an axially outer surface of the cover element, the tubular projection projecting axially outwardly away from the at least one filter medium, the tubular projection having an open interior which opens through the cover element into an interior of the at least one filter medium, wherein the tubular projection is a clean fluid discharge element configured to remove cleaned fluid from an interior of the filter element; wherein an axially outer end of the tubular projection of the filter element has an annular sealing surface forming a valve seat; wherein the tubular projection is configured as a clean fluid discharge element that extends away from the filter element and is configured to remove cleaned fluid from an interior of the filter element to the valve seat of the cover element; wherein the valve seat of the cover element is configured as a sealing surface for a pressure control valve closing body of the crankcase ventilation system to sealably close against; and providing the pressure control valve configured to limit the negative pressure applied in the crankcase ventilation system, the pressure control valve formed in combination by: a valve closing body that operates in conjunction with valve seat of the cover element; wherein the sealing surface of the filter element forms the valve seat against which the valve body closes; arranging the filter element replaceably in the chamber of the oil separator housing; arranging the valve closing body of the pressure control