Device and method for controlling deposit formation

We claim: 1. A method for controlling deposit ( 60 ) formation in a liquid ( 5 ) bearing system ( 100 ) comprising a main system ( 1 ) and a subsystem ( 2 ), wherein the liquid ( 5 ) is transported inside the main system ( 1 ) and a subsystem ( 2 ), wherein the subsystem ( 2 ) is designed as a bypass, the method comprising the step of altering a property of the liquid ( 5 ) inside the subsystem ( 2 ) such that it differs from the property of the liquid ( 5 ) inside the main system ( 1 ) in a manner that deposit ( 60 ) formation inside the subsystem ( 2 ) is more promoted than inside the main system ( 1 ), wherein a first flow velocity of the water ( 5 ) inside the subsystem ( 2 ) is configured such that the first flow velocity inside the subsystem ( 2 ) is greater than a second flow velocity inside the main system ( 1 ), wherein the first flow velocity inside the subsystem is realized by a pumping device, and wherein the deposit ( 60 ) formation is detected by a detection device ( 8 ) inside the subsystem ( 2 ) and treating the water bearing system ( 100 ) once a deposit ( 60 ) inside the subsystem ( 2 ) is detected. 2. The method according to claim 1 , wherein at least one property of the liquid ( 5 ) inside the subsystem ( 2 ) is manipulated by a manipulation device. 3. The method according to claim 1 , wherein liquid ( 5 ) inside the subsystem ( 2 ) is configured such that a Reynolds number of the liquid ( 5 ) inside the subsystem ( 2 ) is greater than 8,000 and preferably between 10,000 and 20,000. 4. The method according to claim 1 , wherein a first flow velocity of the liquid ( 5 ) inside the subsystem ( 2 ) is configured such that the first flow velocity inside the subsystem ( 2 ) is greater than a second flow velocity inside in the main system ( 1 ). 5. The method according to claim 4 , wherein the first flow velocity inside the subsystem ( 2 ) is mainly realized by a pumping device ( 4 ). 6. The method according to claim 1 , wherein the deposit ( 60 ) formation is detected by means of ultrasound, wherein an ultrasonic signal is emitted and a reflected ultrasonic signal is detected. 7. The method according to claim 1 , wherein the temperature inside the subsystem ( 2 ) is monitored. 8. The method according to claim 1 , wherein the subsystem ( 2 ) comprises a heater ( 80 ). 9. The method according to claim 1 , wherein the liquid bearing system ( 100 ) comprises a device for monitoring the temperature, wherein the device is arranged at a wall of a pipe ( 3 , 3 ′), that guides the liquid ( 5 ), wherein the device for monitoring the temperature at the wall of the pipe ( 3 , 3 ′) comprises a first means ( 81 ) for measuring a first temperature ( 75 ) at a first spot and a second means ( 82 ) for measuring a second temperature ( 74 ) at a second spot, wherein the first spot is spaced from the wall of the pipe by a first distance ( 69 ) and the second spot is spaced from the wall of the pipe by a second distance ( 72 ), wherein the second distance is greater than the first distance and wherein the temperature inside the pipe ( 3 , 3 ′) is approximated based on the first temperature ( 75 ) and the second temperature ( 74 ). 10. The method according to claim 1 , wherein a treatment chemical is fed to the liquid bearing system ( 100 ) as soon as a deposit ( 60 ) inside the subsystem ( 2 ) is detected. 11. The method according to claim 1 , wherein the liquid bearing system ( 100 ) is a cooling water system having an outflow and an inflow, wherein water is transported inside the main system ( 1 ) and a subsystem ( 2 ), wherein the subsystem is designed as a bypass, the method comprising the step of altering a property of the water ( 5 ) inside the bypass ( 2 ) such that it differs from the property of the water ( 5 ) inside the main system ( 1 ) in a manner that scaling ( 60 ) formation inside the subsystem ( 2 ) is more promoted than inside the main system ( 1 ), wherein a first flow velocity of the liquid ( 5 ) inside the subsystem ( 2 ) is greater than a second flow velocity inside the main system ( 1 ), wherein the Reynolds number of the water inside the subsystem ( 2 ) is between 10,000 and 20,000, wherein the scaling formation inside the subsystem ( 2 ) is detected by means of ultrasound, wherein an ultrasonic signal is emitted and a reflected ultrasonic signal is detected. 12. A device for controlling deposit ( 60 ) formation in a liquid ( 5 ) bearing system ( 100 ) comprising a main system ( 1 ) and a subsystem ( 2 ), wherein a liquid ( 5 ) is transportable inside the main system ( 1 ) and subsystem ( 2 ), wherein the device is configured for altering a property of the liquid ( 5 ) such that it differs from the property of the liquid ( 5 ) inside the main system ( 1 ) in a manner that deposit ( 60 ) formation inside the subsystem ( 2 ) is more promoted than inside the main system ( 1 ); and wherein mounted inside the subsystem ( 2 ) is a device configured to detect the formation of a deposit in the subsystem; and wherein treatment chemicals are fed to the water bearing system ( 100 ) once a deposit ( 60 ) inside the subsystem ( 2 ) is detected. 13. An upgrade kit for a liquid ( 5 ) bearing system ( 100 ) comprising a main system ( 1 ) and a subsystem ( 2 ), wherein the subsystem ( 2 ) has access to the liquid ( 5 ) of the main system ( 1 ); and wherein the subsystem ( 2 ) comprises a device is configured to detect the formation of a deposit and altering a property of the liquid ( 5 ) inside the subsystem ( 2 ) such that it differs from the property of the liquid ( 5 ) inside the main system ( 1 ) in a manner that deposit ( 60 ) formation inside the subsystem ( 2 ) is more promoted than inside the main system ( 1 ).