Formation Mechanics and Control Strategy of Surface Color Difference for Hot-rolled Low Carbon DC04 Steel

On-site samples about color difference defect on the surface of hot-rolled low carbon DC04 from steel enterprises were analyzed，and it was determined that the difference of the thickness and the structure of oxide scale between the surfaces in the middle and in the edge was the main reason for the color difference on the surface of hot-rolled strip. The transformation law of microstructure of oxide scale in continuous cooling was simulated and investigated by means of thermogravimetric analysis （TGA） and electron probe microanalysis （EPMA） in order to solve this problem. The results showed that pro-eutectoid Fe3O4 was prior to nucleate at the original Fe3O4 layer. The lamellar eutectoid structure was obtained as the cooling temperature decreased. However， when the cooling rate reached 25 ℃/min， the eutectoid reaction was suppressed in the oxide scale. Industrial trial production was implemented based on the results of laboratory research， the microstructure and thickness of oxide scale were effectively controlled by adjustment of coiling temperature and cooling rate， and the cooling temperature was reduced to the temperature range of eutectoid transformation，and then the color difference defect was basically eliminated.

Keywords: hot rolled strip,  color difference,  oxide scale,  thickness control,  structural transition

ZHANG M. SHAO G. Characterization and properties of oxide scales on hot-rolled strips [J]. Materials Science & Engineering A. 2007.452/453:189-193.

MIN K.kIM K. KIM S K et al. Effects of oxide layers on surface defects during hot ndling processes [j]. Metals & Materials International. 2012.18( 2 ):341 -348.

FUKAGAWA T. OKADA H.MAEHARA Y. Mechanism of red scale defect formation in Si-added hot-rolled steel sheets J .ISIJ International. 1994.34( 11 ):906-911.

OKADA H, FUKAGAWA H. ISHIHARA H,et al. Prevention of red scale formation during hot rolling of steels [J]. ISIJ International, 1995,35( 12):886-891.

TORRESA M, TORRESA. COLAS R. A model for heat conduction through the oxide layer of steel during hot rolling [J]. Journal of Materials Processing Technology. 2000,105( 3): 1483-1490.

YU X L. JIANG Z Y. ZHAO J W,et al. Microstnicture and microtexture evolutions of deformed oxide layers on a hot -rolled microalloyed steel [J]. Corrosion Science. 2015.90:140-152.

SUN W.TIEU A K.JIANG Z Y ,et al. High temperature oxide scale characteristics of low carbon steel in hot rolling [j]. Journal of Materials Processing Technology. 2004.155( 2): 1307-1312.

KAZITO T. TOSHIO N. Preparation of lamellar structured a-Fe/ Fe,04 complex particle by thermal decomposition of WUstite [J]. Scripta Mater.2001.44( 2 ):25-27.

LIU Z Y, YU Y. GUO X B,et al. Techniques of oxide scales control during hot strip rolling [J]. Steel Hulling. 2009.26 ( 1 ):1-5.(In Chinese)

KIAU T. NACATAKI Y. INAZUMI T,et ,d. Effects of chemical composition and oxidation temperature on the adhesion of scale in plain carbon steels [J]. ISIJ International.2001.41 (12): 1494- 1501.

TANEI H.KONDO Y. Effect of initial scale structure on transformation behavior of wtlstite [J]. ISIJ International.2012.52 (1): 105-109.

CHEN R Y, YUEN W Y D. The effects of steel composition on the oxidation kinetics,scale structure,and scale -steel interface adherence of low and ultra -low carbon steels [J]. Materials Science Forum. 2006.522/523:451 -460.