Corrosion resistance of stainless steel in drinking water treatment plants and water storage units

1. Rakness, K. L., Ozone in drinking water treatment: process design, operation, and optimization. American Water Works Association: 2011.Search in Google Scholar

2. Novák, P., Korozní inženýrství. Vysoká škola chemickotechnologická v Praze, Ústav kovových materiálů a korozního inženýrství: 2002.Search in Google Scholar

3. Standard Test Methods for Pitting and Crevice Corrosion Resistance of Stainless Steels and Related Alloys by Use of Ferric Chloride Solution. ASTM International 2009.Search in Google Scholar

4. Rashid, M. W. A., et al., Formation of Cr₂₃C₆ during the sensitization of AISI 304 stainless steel and its effect to pitting corrosion. Int. J. Electrochem. Sci.2012, 7 (10), 9465-9477.10.1016/S1452-3981(23)16211-0Search in Google Scholar

5. Holzworth, M., et al., The Mechanism of Knife-Line Attack In Welded Type 347 Stainless Steel. Corrosion1951, 7 (12), 441-449.10.5006/0010-9312-7.12.441Search in Google Scholar

6. Číhal, V.; Ježek, J., Corrosion of Stainless Steels in the Immediate Vicinity of the Weld Metal. British Corrosion Journal1972, 7 (2), 76-86.10.1179/000705972798323215Search in Google Scholar

7. Outokumpu Corrosion Handbook. 9 ed.; Outokumpu Stainless Steel Oy: 2004.Search in Google Scholar

8. Lu, H.; Duquette, D., The Effect of Dissolved Ozone on the Corrosion Behavior of Cu-30Ni and Type 304L Stainless Steel in 0.5 N NaCl Solutions. Corrosion1990, 46 (10), 843-852.10.5006/1.3585043Search in Google Scholar

9. Viera, M., et al., Comparative study of the effect of oxygen and oxygen/ozone mixtures on the electrochemical behaviour of different metals. Journal of Applied Electrochemistry2001, 31 (5), 591-598.Search in Google Scholar

10. Ratnayaka, D. D., et al., 11.22 Production of Ozone. In Twort’s Water Supply (6^th Edition), Elsevier.Search in Google Scholar

11. Lee, W., et al., Corrosion problems caused by bromine formation in additive dosed MSF desalination plants. Desalination1983, 44 (1-3), 209-221.10.1016/0011-9164(83)87120-3Search in Google Scholar

12. Weil, I.; Morris, J. C., Kinetic studies on the chloramines. I. The rates of formation of monochloramine, N-chlormethylamine and N-chlordimethylamine. Journal of the American Chemical Society1949, 71 (5), 1664-1671.10.1021/ja01173a033Search in Google Scholar

13. Vikesland, P. J., et al., Effect of natural organic matter on monochloramine decomposition: pathway elucidation through the use of mass and redox balances. Environmental Science and Technology1998, 32 (10), 1409-1416.10.1021/es970589aSearch in Google Scholar

14. Prošek, T., et al., Low-temperature stress corrosion cracking of stainless steels in the atmosphere in the presence of chloride deposits. Corrosion2009, 65 (2), 105-117.10.5006/1.3319115Search in Google Scholar

15. Prošek, T., et al., Low-temperature stress corrosion cracking of austenitic and duplex stainless steels under chloride deposits. Corrosion2014, 70 (10), 1052-1063.10.5006/1242Search in Google Scholar

16. Bystrianský, J., et al., Influence of surface state of high alloyed creep resistant steels on their oxidation resistance. Koroze a ochrana materiálů2014, 58 (1), 19-30.10.2478/kom-2014-0003Search in Google Scholar

17. Bystrianský, J., et al., Causes of reduced corrosion resistance of stainless steels and alloys. Koroze a ochrana materiálů2000, 44, 2-6.Search in Google Scholar

18. Guzanová, A., et al., Determination corrosion rate of welded joints realised by MAG technology. Koroze a ochrana materiálů2017, 61 (1), 19-24.10.1515/kom-2017-0002Search in Google Scholar

19. Outokumpu Welding Handbook. 1 ed.; Outokumpu Stainless Steel Oy: 2010.Search in Google Scholar

20. Váňa, P., et al., Vliv redukční taveniny na moření korozivzdorných ocelí. Koroze a ochrana materiálů2011, 55 (3), 114-120.Search in Google Scholar

21. Rudasová, P., Moření a pasivace nádrže mazacího oleje turbogenerátoru. Koroze a ochrana materiálů2010, 54 (4), 192-195.Search in Google Scholar