Gas-liquid separator for separating at least one liquid component from a gaseous component

What is claimed is: 1. A gas-liquid separator ( 2 ) for separating at least one liquid component from a gaseous component, the gas-liquid separator having at least one container ( 6 ) to which a medium is conveyed via an inlet ( 16 ), wherein a separation at least of the liquid component of the medium takes place in the at least one container ( 6 ), wherein the separated component of the medium is discharged from the at least one container ( 6 ) via a discharge valve ( 46 ) and the remaining gaseous component of the medium is guided back into an outflow line ( 5 ) via a first outlet ( 18 ), characterized in that, in addition to the liquid component, a gaseous component N 2 is separated from the medium by the gas-liquid separator ( 2 ), characterized in that the at least one container ( 6 ) has a container wall ( 17 ), a separating wall ( 8 ), a separating edge ( 15 ), a stabilization chamber ( 12 ), a reservoir ( 14 ) and an outlet channel ( 20 ), wherein the separating wall ( 8 ) has a nozzle tip ( 13 ) on the side facing the container wall ( 17 ), and the container wall ( 17 ) has a curved region ( 23 ). 2. The gas-liquid separator ( 2 ) as claimed in claim 1 , wherein the liquid component is H 2 O and the gaseous component is H 2 , and wherein the components H 2 O and N 2 are separated from the component H 2 of the medium, by the centrifugal principle. 3. The gas-liquid separator ( 2 ) as claimed in claim 2 , characterized in that the medium coming from the stabilization chamber ( 12 ), as the medium flows past the curved region ( 23 ) and/or the nozzle tip ( 13 ) in a flow direction V, experiences a deflection such that the components H 2 O and N 2 , owing to their size, experience a less pronounced deflection and the light component H 2 , owing to its size, experiences a greater deflection. 4. The gas-liquid separator ( 2 ) as claimed in claim 3 , characterized in that the medium, after flowing past the curved region ( 23 ) and/or the nozzle tip ( 13 ), meets the separating edge ( 15 ), wherein the light component H 2 is deflected in a flow direction VII to the outlet channel ( 20 ) and the components H 2 O and N 2 are deflected in a flow direction VI to the reservoir ( 14 ). 5. A gas-liquid separator ( 2 ) for separating at least one liquid component from a gaseous component, the gas-liquid separator having at least one container ( 6 ) to which a medium is conveyed via an inlet ( 16 ), wherein a separation at least of the liquid component of the medium takes place in the at least one container ( 6 ), wherein the separated component of the medium is discharged from the at least one container ( 6 ) via a discharge valve ( 46 ) and the remaining gaseous component of the medium is guided back into an outflow line ( 5 ) via a first outlet ( 18 ), characterized in that, in addition to the liquid component, a gaseous component N 2 is separated from the medium by the gas-liquid separator ( 2 ), wherein the gas-liquid separator has multiple containers ( 6 a, b ), wherein a first container ( 6 a ) has the inlet ( 16 ), at least one pipe ( 35 ) and a stabilization chamber ( 12 ), wherein the pipe ( 35 ) is arranged inside the first container ( 6 a ), wherein a second container ( 6 b ) has a reservoir ( 14 ) and a sensor system ( 22 ), and wherein the pipe ( 35 ) is fluidically connected to the inlet ( 16 ) of the first container ( 6 a ) and to the reservoir ( 14 ) of the second container ( 6 b ), wherein the liquid component is H 2 O and the gaseous component is H 2 , wherein the pipe ( 35 ) forms a pipe wall ( 36 ), wherein the pipe wall ( 36 ) is in the form of a membrane ( 34 ), wherein the membrane ( 34 ) is permeable to the component H 2 of the medium and wherein the membrane ( 34 ) is impermeable to the components H 2 O and N 2 of the medium. 6. The gas-liquid separator ( 2 ) as claimed in claim 5 , characterized in that a movement of component H 2 of the medium out of the pipe ( 35 ) into the stabilization chamber ( 12 ) takes place, while a movement of the components H 2 O and N 2 of the medium out of the pipe ( 35 ) is prevented. 7. The gas-liquid separator ( 2 ) as claimed in claim 6 , characterized in that there is a pressure difference between the inner region and the outer region of the pipe ( 35 ), whereby a movement of the component H 2 of the medium out of the pipe ( 35 ) into the stabilization chamber ( 12 ) is assisted. 8. The gas-liquid separator ( 2 ) as claimed in claim 6 , characterized in that at least two pipes ( 35 ) are combined to form a pipe bundle ( 37 ), wherein the pipes ( 35 ) are each fluidically connected to the inlet ( 16 ) of the first container ( 6 a ) and to the reservoir ( 14 ) of the second container ( 6 b ). 9. A fuel cell arrangement comprising a gas-liquid separator ( 2 ) as claimed in claim 1 , for controlling a hydrogen supply to and/or hydrogen discharge from a fuel cell ( 30 ). 10. The gas-liquid separator ( 2 ) as claimed in claim 1 , wherein the liquid component is H 2 O and the gaseous component is H 2 . 11. The gas-liquid separator ( 2 ) as claimed in claim 5 , wherein the liquid component is H 2 O and the gaseous component is H 2 , wherein the pipe ( 35 ) forms a pipe wall ( 36 ), wherein the pipe wall ( 36 ) is in the form of a semi-permeable membrane ( 34 ), wherein the membrane ( 34 ) is permeable to the component H 2 of the medium and wherein the membrane ( 34 ) is impermeable to the components H 2 O and N 2 of the medium owing to the molecule size of the respective component. 12. The gas-liquid separator ( 2 ) as claimed in claim 11 , characterized in that a movement of component H 2 of the medium out of the pipe ( 35 ) through the pipe wall ( 36 ) and into the stabilization chamber ( 12 ) takes place, while a movement of the components H 2 O and N 2 of the medium out of the pipe ( 35 ) through the pipe wall ( 36 ) is prevented. 13. The gas-liquid separator ( 2 ) as claimed in claim 12 , characterized in that there is a pressure difference between the inner region and the outer region of the pipe ( 35 ), whereby a movement of the component H 2 of the medium out of the pipe ( 35 ) through the pipe wall ( 36 ) and into the stabilization chamber ( 12 ) is assisted. 14. A gas-liquid separator ( 2 ) for separating at least one liquid component from a gaseous component, the gas-liquid separator comprising at least one container ( 6 ), an inlet ( 16 ) for conveying a medium to the container, means for separating into a separated component at least the liquid component of the medium in the container ( 6 ), means for discharging the separated component of the medium from the at least one container ( 6 ) via a discharge valve ( 46 ), means for guiding a remaining gaseous component of the medium back into an outflow line ( 5 ) via a first outlet ( 18 ), and means for separating, in addition to the liquid component, a gaseous component N 2 from the medium, characterized in that the at least one container ( 6 ) has a container wall ( 17 ), a separating wall ( 8 ), a separating edge ( 15 ), a stabilization chamber ( 12 ), a reservoir ( 14 ) and an outlet channel ( 20 ), wherein the separating wall ( 8 ) has a nozzle tip ( 13 ) on the side facing the container wall ( 17 ), and the container wall ( 17 ) has a curved region ( 23 ). 15. A method for operating the gas-liquid separator ( 2 ) as claimed in claim 14 , the method comprising conveying the medium to the container ( 6 ), separating into the separated component at least the liquid component of the medium in the container ( 6 ), discharging the separated component of the medium from the container ( 6 ), guidin