"978-80-87294-22-2" . . "RIV/00216305:26210/11:PU92557" . . "Cooling System for Continuous Galvanizing Line"@en . . . "An experimental program was carried out to design an after pot cooling section for Continuous Galvanising Line. The cooling system should reduce an initial temperature of 550C down to about 50 C for the shortest possible distance. Reference thickness of a strip is 1 to 2 mm and expected velocity for a strip 1 mm thick is about 3 m/s. The cooling tower has a vertical configuration and the strip is moving upwards in the first cooling section. A test for the quantity of dropping water from the cooled area was done to minimise the amount of coolant which must be removed by air knifes to protect the galvanising pool. Optimal nozzles were selected in the first stage of the project. Water and mist nozzles of various footprints were tested and finally full cone water nozzles were selected to use in a cooling chamber. A great number of laboratory cooling experiments provided a great deal of information about the cooling intensity for the following spray parameters (nozzle size, coolant pressure and flow rate," . "Cooling System for Continuous Galvanizing Line"@en . . . "6"^^ . . "Cooling System for Continuous Galvanizing Line" . "RIV/00216305:26210/11:PU92557!RIV12-MSM-26210___" . "Cooling System for Continuous Galvanizing Line" . . "Neuveden" . "3"^^ . "[30B0D9DDB8BD]" . . "4"^^ . "Raudensk\u00FD, Miroslav" . . "191972" . "Hn\u00EDzdil, Milan" . "Brno" . . . "Marmonier, Frederic" . "Tanger spol. s.r.o." . "Sborn\u00EDk konference Metal 2011" . "An experimental program was carried out to design an after pot cooling section for Continuous Galvanising Line. The cooling system should reduce an initial temperature of 550C down to about 50 C for the shortest possible distance. Reference thickness of a strip is 1 to 2 mm and expected velocity for a strip 1 mm thick is about 3 m/s. The cooling tower has a vertical configuration and the strip is moving upwards in the first cooling section. A test for the quantity of dropping water from the cooled area was done to minimise the amount of coolant which must be removed by air knifes to protect the galvanising pool. Optimal nozzles were selected in the first stage of the project. Water and mist nozzles of various footprints were tested and finally full cone water nozzles were selected to use in a cooling chamber. A great number of laboratory cooling experiments provided a great deal of information about the cooling intensity for the following spray parameters (nozzle size, coolant pressure and flow rate,"@en . . "S" . . "galvanizing line, cooling unit, heat transfer, spraying"@en . . "Horsk\u00FD, Jaroslav" . . . . "26210" . . "2011-05-18+02:00"^^ .