Effect of combined surface treatment on quality and electrochemical corrosion properties of manganese phosphate on hsla steel domex 700

Open access

Abstract

The actual industrial trend is focused on weight reduction of constructions while preserving strength properties. For this purpose, conventional steel are replaced by high strength steels.. The aim of this study was to evaluate the effects of mechanical surface pre-treatment on corrosion resistance of high strength low alloy steel Domex 700 before and after surface treatment by manganese phosphating. Tested environment was 0,1M NaCl solution. Evaluation of mechanical pre-treatment and phosphating effects on corrosion resistance was realized by electrochemical measurements: potentiodynamic polarization measurements (Tafel analysis) and electrochemical impedance spectroscopy (equivalent circuits). From resulsts it is possible to conclude, that creation of manganese phosphate layer on ground and shot peened steel surface significantly increases the corrosion resistance of Domex 700 steel.

If the inline PDF is not rendering correctly, you can download the PDF file here.

  • 1. Hong-Liang D.; Hao-Jie J.; Ting D.; Wei-Li X.; Ai-Hiu L. Investigation on the influence of damage to springback of U-shape HSLA steel plates. Journal of Alloys and Compounds 2017 708 575-586.

  • 2. Mohrbacher H. Green and Sustainable Manufacturing of Advanced Material Chapter 6 - High-Performance Steels for Sustainable Manufacturing of Vehicles pp. 135-163. Schilde (in Belgium) 2016. ISBN: 978-0-12-411497-5.

  • 3. Zhenyu L.; Raymundo O. O.; Yinkai L.; Calixto I. G.; Guofeg W. Microstructural characterization and recrystallization kinetics modeling of annealing cold-rolled vanadium microalloyed HSLA steel. Journal of Alloys and Compounds 2016 679 293-301.

  • 4. Gao C. Y.; Lu W. R.; Zhang L. C.; Yan H. Y. A constitutive description of the thermo-viscoplastic behavior of body-centered cubic metals. Materials and Design 2012 36 671-678.

  • 5. Xizhang Ch.; Yuming H. Hot deformation behavior of HSLA steel Q690 and phase transformation during compression. Jorunal of Alloys and Compounds 2015 619 564-571.

  • 6. Xizhang Ch.; Yuming H.; Yucheng L. Microstructure and properties of 700 MPa grade HSLA steel during high temperature deformation. Journal of Alloys and Compounds 2015 631 225-231.

  • 7. Neslušan M.; Mičieta B.; Mičietová A.; Čiliková M.; Mrkvica I. Detection of tool breakage during hard turning through acoustic emission at low removal rates. Measurement 2015 70 1-13.

  • 8. Mhaede M.; Pastorek F.; Hadzima B. Influence of shot peening on corrosion properties of biocompatible magnesium alloy AZ31 coated by dicalcium phosphate dihydrate (DCPD). Materials Science and Engineering C 2014 39 330-335.

  • 9. Trško L.; Guagliano M.; Bokůvka O.; Nový F. Fatigue life of AW 7075 Aluminium Alloy after severe shote peening treatment with different intensities. Procedia Engineering 2014 74 246-252.

  • 10. Trško L.; Bokůvka O.; Nový F.; Guagliano M. Effect of severe shot peening on ultra-high-cycle fatigue of a lowalloy steel. Mareials and Design 2014 57 103-113.

  • 11. Miková K.; Bagherifard S.; Bokůvka O.; Guagliano M.; Trško L. Fatigue behavior of X70 microalloyed steel after severe shot peening. International Journal of Fagitue 2013 55 33-42.

  • 12. Banczek E. P.; Rodrigues P. R. P.; Costa I. The effects ofniobium and nickel on the corrosion resistance of the zinc phosphate layers. Surface and Coatings Technology 2008 202 (10) 2008-2014.

  • 13. Díaz B.; Freire L.; Mojío M.; Nóvoa X. R. Optimization of conversion coatings based on zinc phosphate on high strength steels with enhanced barrier properties. Journal of Electroanalytical Chemistry 2015 737 174-183.

  • 14. Galvan-Reyes C.; Salinas-Rodríguez A.; Fuentes-Aceituno J. C. Degradation and crystalline reorganization of hurealite crystals during the manganese phosphating of a high strength steel. Surface and Coatings Technology 2015 275 10-20.

  • 15. Wang Ch.; Liau H.; Tsai W. Effects of temperature and applied potential on the microstructure and electrochemical behavior of manganese phosphate coating. Surface and Coatings Technology 2006 201 (6) 2994-3001.

  • 16. Wang Ch.; Liau H.; Tsai W. Effect of heat treatment on the microstructure and electrochemical behavior of manganese phospate coating. Materials Chemistry and Physics 2007 102 (2-3) 207-213.

  • 17. Bogi J.; Macmillan R. Phosphate conversion coatings on steel. Journal of Materials Science 1977 12 (11) 2235-2240.

  • 18. Werner R. Phosphating of Metals. Finishing Publications Ltd & ASM International; 2nd edition. 1990. ISBN 978-0904477115.

  • 19. Jegannathan S.; Sankara Narayanan T. S. N.; Ravichandran K.; Rajeswari S. Preformance of zinc phosphate coatings obtained by cathodic electrochemical treatment in accelerated corrosion tests. Electrochemica Acta 2005 51 (2) 247-256.

  • 20. Kozlowski A. Dry friction of manganese phosphate coatings on steel and cast iron. Electrodeposition and Surface Treatment 1974 2 (2) 109-122.

  • 21. Perry J.; Eyre S. T. The effect of phosphating on the friction and wear properties of grey cast iron. Wear 1977 43 (2) 185-197.

  • 22. Galvan-Reyes C.; Salinas-Rodríguez A.; Fuentes-Aceituno J. C. The role of alkalizing agent on the manganese phosphating of a high strength steel part 1: The individual effect of NaOH and NH4OH. Surface and Coatings Technology 2016 291 179-188.

  • 23. Galvan-Reyes C.; Salinas-Rodríguez A.; Fuentes-Aceituno J. C. The role of alkalizing agent on the manganese phosphating of a high strength steel part 2: The combined effect of NaOH and the amino group (NH4OH monoethanolamine and NH4NO3) on the degradation stage of the phosphating mechanism. Surface and Coatings Technology 2016 299 113-122.

  • 24. Ghali I. E.; Potvin A. J. R. The mechanism of phosphating of steel. Corrosion Science 1972 12 (7) 583-594.

  • 25. Pastorek F.; Borko K.; Dundeková S.; Fintová S.; Hadzima B.: Elektrochemické korózne charakteristiky fosfátovanej ocele S355J2 v prostredí síranov - Electrochemical corrosion characteristics of phosphated S355J2 steel in sulfate environment. Koroze a ochrana materiálu 2016 60 (4) 107-113.

  • 26. Borko K.; Pastorek F.; Hadzima B.: Elektrochemické korózne charakteristiky vysokopevnej ocele Domex 700 po mechanických úpravách v prostredí chloridov - Electrochemical corrosion characteristics of high strength low alloy Domex 700 steel after mechanical surface treatment in chloride environment. Koroze a a materiálu 2017 61 (5) 162-168.

Search
Journal information
Impact Factor


CiteScore 2018: 0.25

SCImago Journal Rank (SJR) 2018: 0.164
Source Normalized Impact per Paper (SNIP) 2018: 0.286

Cited By
Metrics
All Time Past Year Past 30 Days
Abstract Views 0 0 0
Full Text Views 248 95 2
PDF Downloads 136 84 6