Crankcase ventilation apparatus

The invention claimed is: 1. A vehicle, comprising: an internal combustion engine including a crankcase and a supercharging apparatus; a crankcase ventilation apparatus including at least one inertia-based oil-separating apparatus, the at least one inertia-based oil-separating apparatus including at least one inertia-based oil separator; an oil return communicating separated oil from the crankcase ventilation apparatus to the crankcase; an ejector pump driven via a compressed air flow of the supercharging apparatus and configured to generate an underpressure for driving a blow-by gas; the crankcase ventilation apparatus further including a pump control valve configured to at least one of regulate and control the compressed air flow through the ejector pump, the pump control valve including a closure part arranged force-loaded against a valve seat via a biasing force, wherein the closure part is displaced away from the valve seat counter to the biasing force to open the pump control valve in response to at least one of a pressure difference between a valve inlet and a valve outlet exceeding a pressure difference threshold and an inlet-side pressure of the ejector pump exceeding an inlet-side pressure threshold; and wherein the pump control valve is an own-medium-actuated valve where a medium to be controlled is the same as the medium controlling the pump control valve. 2. The vehicle according to claim 1 , wherein the biasing force is at least one of a spring force, a magnetic force and a pneumatic pressure force. 3. The vehicle according to claim 1 , wherein the pump control valve is configured as a proportional valve adjustable between a closed position closing the pump control valve and a passage position opening the pump control valve. 4. The vehicle according to claim 1 , wherein the oil-separating apparatus includes a plurality of work areas, the plurality of work areas including: a first work area where a flow cross section of the oil-separating apparatus is constant; a second work area where a flow cross section of the oil-separating apparatus increases with increasing pressure difference between an inlet and an outlet of the oil-separating apparatus; and a third work area where a flow cross section of the oil-separating apparatus increases less sharply with increasing pressure difference than in the second work area. 5. The vehicle according to claim 1 , wherein the oil-separating apparatus includes at least two inertia-based oil separators and a control apparatus configured to switch between the at least two oil separators in response to a power output of the ejector pump. 6. The vehicle according to claim 1 , wherein at least one of: the at least one oil separator is configured as an impactor, and the at least one oil separator is configured as a cyclone. 7. The vehicle according to claim 1 , wherein the at least one oil separator includes a poppet valve loaded via a reference pressure forcing the poppet valve in a closing direction. 8. The vehicle according to claim 7 , wherein the reference pressure is one of an ambient pressure, a boost pressure of the supercharging apparatus, and a pressure on an inlet-side of the ejector pump. 9. The vehicle according to claim 1 , wherein the pump control valve is controlled via a control apparatus. 10. The vehicle according to claim 1 , wherein the crankcase ventilation apparatus further includes a throttle valve configured to throttle the blow-by gas. 11. A vehicle, comprising: an internal combustion engine including a crankcase and a supercharging apparatus; a crankcase ventilation apparatus including at least one inertia-based oil-separating apparatus, the at least one inertia-based oil-separating apparatus including at least one inertia-based oil separator; an oil return communicating separated oil from the crankcase ventilation apparatus to the crankcase; an ejector pump driven via a compressed air flow of the supercharging apparatus and configured to generate an underpressure for driving a blow-by gas; the crankcase ventilation apparatus further including a pump control valve configured to at least one of regulate and control the compressed air flow through the ejector pump, the pump control valve including a closure part arranged force-loaded against a valve seat via a biasing force, wherein the closure part is displaced away from the valve seat counter to the biasing force to open the pump control valve in response to at least one of a pressure difference between a valve inlet and a valve outlet exceeding a pressure difference threshold and an inlet-side pressure of the ejector pump exceeding an inlet-side pressure threshold; and wherein the at least one inertia-based oil separator includes a poppet valve loaded via a reference pressure forcing the poppet valve in a closing direction and a membrane against which the reference pressure bears, and wherein the poppet valve is loaded via the reference pressure bearing against the membrane. 12. The vehicle according to claim 11 , wherein the reference pressure is a boost pressure of the supercharging apparatus. 13. The vehicle according to claim 11 , wherein the reference pressure is an ambient pressure. 14. The vehicle according to claim 11 , wherein the reference pressure is a pressure on an inlet-side of the ejector pump. 15. A vehicle, comprising: an internal combustion engine including a crankcase and a supercharging apparatus; a crankcase ventilation apparatus including at least one inertia-based oil-separating apparatus, the at least one inertia-based oil-separating apparatus including at least one inertia-based oil separator; an oil return communicating separated oil from the crankcase ventilation apparatus to the crankcase; an ejector pump driven via a compressed air flow of the supercharging apparatus and configured to generate an underpressure for driving a blow-by gas; the crankcase ventilation apparatus further including a pump control valve configured to at least one of regulate and control the compressed air flow through the ejector pump, the pump control valve including a closure part arranged force-loaded against a valve seat via a biasing force, wherein the closure part is displaced away from the valve seat counter to the biasing force to open the pump control valve in response to at least one of a pressure difference between a valve inlet and a valve outlet exceeding a pressure difference threshold and an inlet-side pressure of the ejector pump exceeding an inlet-side pressure threshold; and wherein the crankcase ventilation apparatus further includes a throttle valve configured to throttle the blow-by gas. 16. The vehicle according to claim 15 , wherein the throttle valve is arranged in a flow path of the blow-by gas between the crankcase and the at least one inertia-based oil-separating apparatus. 17. The vehicle according to claim 15 , wherein the throttle valve is arranged in a flow path of the blow-by gas between the at least one inertia-based oil-separating apparatus and the ejector pump. 18. A vehicle, comprising: an internal combustion engine including a crankcase and a supercharging apparatus; a crankcase ventilation apparatus including at least one inertia-based oil-separating apparatus, the at least one inertia-based oil-separating apparatus including at least two inertia-based oil separators; an oil return communicating separated oil from the crankcase ventilation apparatus to the crankcase; an ejector pump driven via a compressed air flow of the supercharging apparatus and configured to generate a