Integrated oxygen probe in submersible oxygenation device

The invention claimed is: 1. A device ( 1 ) for dissolving a gas (G) in water (W), comprising: a housing ( 100 ) configured to be submerged into the water (W), the housing ( 100 ) including at least one water inlet ( 101 ), a gas inlet ( 102 ) and at least one water outlet ( 103 ) for discharging gas enriched water (W′) out of the housing; a pump ( 5 ) in fluid communication with the at least one water inlet ( 101 ) for sucking water (W) from a surrounding of the housing ( 100 ), the pump configured to generate a main water stream (W′); means ( 200 ) for injecting the gas (G) supplied from the gas inlet ( 102 ) into the main water stream (W′); and a probe ( 6 ) configured to measure a concentration of the gas dissolved in the water, the probe arranged in the housing ( 100 ) of the device ( 1 ) wherein the probe ( 6 ) comprises an oxygen probe configured to measure a concentration of dissolved oxygen in the water, and wherein the probe ( 6 ) comprises a measuring surface ( 6 a ) at a tip of the probe for measuring the concentration of the gas dissolved in the water; and wherein the device ( 1 ) is configured to direct a side water stream (S′) of the main water stream (W′) along the measuring surface ( 6 a ). 2. The device according to claim 1 , further comprising a first orifice (O) at a junction (J) between a pump outlet pipe ( 8 ) and the gas injecting means ( 200 ) of the device ( 1 ) for injecting the gas (G), such that the side water stream (S′) is forced through the first orifice, flushed over the measuring surface ( 6 a ), and led through a second orifice (O′) out of the housing ( 100 ) for generating the side water stream (S′). 3. The device of claim 2 , further comprising a recess ( 7 ) in the housing ( 100 ) in which the probe ( 6 ) is removably arranged, and the measuring surface ( 6 a ) is arranged downstream of the first orifice (O) and upstream of the second orifice (O′) such that the side water stream (S′) can be flushed over the measuring surface ( 6 a ). 4. The device of claim 3 , further comprising closure means configured to be arranged in a form fitting manner in the recess ( 7 ) when the probe ( 6 ) has been removed from the recess, the closure means closing off the first orifice (O) when the closure means is arranged in the recess such that the side water stream (S′) is not generated. 5. A method for dissolving a gas (G) in water (W), with a device ( 1 ) including a housing ( 100 ) configured to be submerged into the water (W), the housing ( 100 ) including at least one water inlet ( 101 ), a gas inlet ( 102 ) and at least one water outlet ( 103 ) for discharging gas enriched water (W′) out of the housing, a pump ( 5 ) in fluid communication with the at least one water inlet ( 101 ) for sucking water (W) from a surrounding of the housing ( 100 ), the pump configured to generate a main water stream (W′), means ( 200 ) for injecting the gas (G) supplied from the gas inlet ( 102 ) into the main water stream (W′), and a probe ( 6 ) configured to measure a concentration of the gas dissolved in the water, the probe arranged in the housing ( 100 ) of the device ( 1 ), wherein the probe ( 6 ) comprises an oxygen probe configured to measure a concentration of dissolved oxygen in the water, and wherein the probe ( 6 ) comprises a measuring surface ( 6 a ) at a tip of the probe for measuring the concentration of the gas dissolved in the water; and wherein the device ( 1 ) is configured to direct a side water stream (S′) of the main water stream (W′) along the measuring surface ( 6 a ), the method comprising: submerging the device ( 1 ) in the water (W); injecting the gas (G) into the main water stream (W′); and discharging gas enriched water (W′) into the water (W) surrounding the device ( 1 ). 6. The method of claim 5 , further comprising controlling the flow rate of the gas (G) injected into the main water stream (W′) depending upon the concentration of the gas dissolved in the water (W) measured with the probe ( 6 ). 7. The method of claim 5 , wherein the water (W) in which the device ( 1 ) is submerged is selected from the group consisting of waste water, and a stretch of water. 8. The method of claim 5 , wherein the water (W) in which the device ( 1 ) is submerged is selected from the group consisting of water in a cage, water in an open sea cage (S), water in a sealed sea cage, water in a partly sealed sea cage, water in a container, and water in a pond. 9. The method of claim 5 , wherein the gas (G) comprises oxygen.