Apparatus and method for measuring a gas volume fraction of an aerated fluid in a reactor

The invention claimed is: 1. A submersible system ( 19 ) for measuring a gas volume fraction in a aerated fluid inside a reactor ( 1 ) where the aerated fluid comprises a dispersed gas in the form of bubbles ( 3 ) in a fluid in a liquid form, a mixture of multiple liquids, a suspension of solids in a liquid, or a combination thereof, CHARACTERIZED in that said system comprises: an open and pass-through gas exclusion device ( 20 ) with a variable cross section, said open and pass-through gas exclusion device ( 20 ) defining an opening inlet and an outlet opening, whereby the fluid without gas bubbles enters the opening inlet, and exits through the outlet opening, said pass-through bubble exclusion device ( 20 ) has a diameter greater than the outlet opening wherein the outlet opening abuts with an inlet pipe ( 23 ); a flow meter-contain chamber ( 24 ) defining an inlet ( 27 ) and an outlet ( 28 ) and containing at least one flow meter that allows measuring velocity of the fluid without gas, when the fluid without gas is circulating between the inlet ( 27 ) and the outlet ( 28 ) of said flow meter-containing chamber ( 24 ), wherein said inlet ( 27 ) is coupled to said inlet pipe ( 23 ) and wherein said outlet ( 28 ) is coupled to an outlet pipe ( 26 ) for discharging the fluid without gas towards the reactor ( 1 ); a flow transmitter ( 29 ) connected to the flow meter, located inside or outside of said sealed camera ( 24 ), wherein said flow transmitter ( 29 ) generates an output signal proportional to the velocity of the fluid without gas through the gas exclusion device ( 20 ); and a processing unit ( 30 ) generating an output signal ( 31 ) proportional to a gas volume fraction in the aerated fluid. 2. The submersible system ( 19 ) for measuring the gas volume fraction in an aerated fluid, according to claim 1 , CHARACTERIZED in that said open and pass-through gas exclusion device ( 20 ) comprises a cylindrical tube ( 21 ) of a constant straight diameter and a diameter reducing section ( 22 ) wherein the greatest diameter of the diameter reducing section ( 22 ) is equal to the diameter of the cylindrical tube ( 21 ) and the smallest diameter is equal to the diameter of the inlet pipe ( 23 ). 3. The submersible system ( 19 ) for measuring the gas volume fraction in an aerated fluid, according to claim 2 , CHARACTERIZED in that said open and pass-through gas exclusion device ( 20 ) comprises only one diameter reducing section ( 22 ). 4. The submersible system ( 19 ) for measuring the gas volume fraction in an aerated fluid, according to claim 3 , CHARACTERIZED in that said diameter reducing section ( 22 ) is an inverted cone. 5. The submersible system ( 19 ) for measuring the gas volume fraction in an aerated fluid according to claim 4 , CHARACTERIZED in that said open and pass-through gas exclusion device ( 20 ) is vertically installed in the aerated fluid inside the reactor ( 1 ). 6. The submersible system ( 19 ) for measuring the gas volume fraction in an aerated fluid, according to claim 1 , CHARACTERIZED in that said flow transmitter ( 29 ) is placed inside the reactor ( 1 ). 7. The submersible system ( 19 ) for measuring the gas volume fraction in an aerated fluid, according to claim 1 , CHARACTERIZED in that said flow transmitter ( 29 ) is placed outside the reactor ( 1 ). 8. The submersible system ( 19 )) for measuring the gas volume fraction in an aerated fluid, according to claim 1 , CHARACTERIZED in that said flow meter-containing chamber ( 24 ) comprises a camera, and said flow meter and said transmitter ( 29 ) are part of a flow measurement means. 9. The submersible system ( 19 ) for measuring the gas volume fraction in an aerated fluid according to claim 1 , CHARACTERIZED in that said processing unit ( 30 ) is selected from the group consisting of a computer; a programmable logic controller (PLC); a microprocessor; and a distributed control system (DCS).