Volume 17 Preprint 41


Corrosion Behavior of Rust DH36 Offshore Platform Steel in Seawater

J.G. Liu, Z.L. Li, Y.T. Li and B. R. Hou

Keywords: marine corrosion; rust; cementite

Abstract:
The metals exposed in offshore environment would suffer from serious corrosion. Rusts were formed with the DH36 steel immersing in the seawater for different days. Then the corrosion behavior of the rust steels was studied using polarization curves and electrochemical impedance spectroscopy. The corrosion morphologies and corrosion products of the rust samples were characterized by scanning electron microscopy and X-ray diffraction. The inner layer of the rust steel was bent flaky while the outer layer was packing flaky with cracks. The product identified in the inner layer was cementite mainly while the outer layer was lepidocrocite mainly. With metal dissolved, cementite, detected in inner rust, left on the metal and formed the no protective inner layer and lead to increasing corrosion rate in the test time.

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Corrosion Behavior of Rust DH36 Offshore Platform Steel in Seawater J. G. Liu1, Z. L. Li1, Y. T. Li2 and B. R. Hou2 Qingdao Key Laboratory of Circle Sea Oil & Gas Storage and Transportation Technology, College of pipeline and civil Engineering, China University of Petroleum, Qingdao, China 2 Institute of Oceanology, Chinese Academy of Sciences, Qingdao, China 1 Correspondence should be addressed to J. G. Liu: jgliu83@163.com Abstract The metals exposed in offshore environment would suffer from serious corrosion. Rusts were formed with the DH36 steel immersing in the seawater for different days. Then the corrosion behavior of the rust steels was studied using polarization curves and electrochemical impedance spectroscopy. The corrosion morphologies and corrosion products of the rust samples were characterized by scanning electron microscopy and Xray diffraction. The inner layer of the rust steel was bent flaky while the outer layer was packing flaky with cracks. The product identified in the inner layer was cementite mainly while the outer layer was lepidocrocite mainly. With metal dissolved, cementite, detected in inner rust, left on the metal and formed the no protective inner layer and lead to increasing corrosion rate in the test time. Keywords: marine corrosion; rust; cementite Introduction With the development of ocean resources, steel structures, such as offshore oil platforms, dolphin, are constructed and put used in marine environment. The offshore environment is one of the most corrosive natural occurring environments. Corrosion of steel structures in marine environment is a big problem that has to be considered [1-10]. Due to the complexity of the marine environment, steel structures exposed to this environment will seriously corrode [11-19]. Not only the simple electrochemical corrosion, but also electrochemical and mechanical function corrosion, biological corrosion would happen in this area. Because of the complexity of the seawater, it is still a subject of great interest to know the corrosion behavior of DH36 steel. The DH36 steel shows good mechanical properties and 1 corrosion resistance, and it is commonly used for offshore oil platform in China. However, literature revealed that studies have not been made so far about the use of DH36 steel for offshore oil platform exposed in marine environment. The corrosion process of DH36 steel in seawater was studied using electrochemical tests while the morphologies and rusts of the steel samples were characterized by scanning electron microscopy (SEM) and X-ray diffraction (XRD). Materials and Methods Specimens DH36 steel was used with chemical compositions (in wt-%) of 0.15C, 0.33Si, 1.40Mn, 0.015P, 0.005S, 0.06Cr, 0.07Ni, 0.15Cu, 0.035Al and balance Fe. The material was machined into size of 10 mm in diameter and left 0.7854 cm2 work area. And it cut into test specimens of size 20 mm× 20 mm× 12 mm for rusts characterization. The specimens were wet ground down to the 1200 grit and cleaned with distilled water, ethanol and acetone [20]. Then they were immersed into Qingdao seawater for 30 days, 90 days and 180 days respectively. After removed, they were used for the tests. Electrochemical tests The electrochemical test was measured with 2273 Potentiostat used and performed in a typical three-electrode cell. The working electrode was the rusted steel after immersion. Pt counter electrode and a saturated calomel reference electrode were used. Electrochemical impedance spectroscopy (EIS) measurement was performed in the frequency range of 100 kHz to 10 mHz, with a sinusoidal potential signal of 10 mV around the open circuit potential[21, 22]. The scan rate of polarization curves were 0.5 mV/s and the range was OCP −200 to +200mV [14]. Characterization of rust samples The images of outer and inner rust layers were characterized with scanning electron microscopy (SEM) [23, 24]. The corrosion products of the rust samples were characterized by X-ray diffraction. The XRD conditions were 6kW intensity using a Cu target [22, 25]. 2 Results and discussion Electrochemical behaviour Figure 1 shows the polarization curves of DH36 rust steels in seawater of 30 days, 90 days and 180 days. The fitting results are shown in Table 1. -0.3 -0.4 30d 90d 180d E (V vs.SCE) -0.5 -0.6 -0.7 -0.8 -0.9 -1.0 -8 -7 -6 -5 -4 -3 -2 2 log i (A/cm ) Figure 1: Polarization curves of DH36 rust steels in seawater From the polarization curves, the corrosion current density of DH36 rust steels in seawater increased with time. As the immersion time was not enough, there was no perfect protect rust layer on the metal, corrosion rate kept increasing in 180 days. The anodic Tafel parameters (βa) increased while cathodic Tafel parameters (βc) decreased with time in 180 days. It means that corrosion of the rust steel was controlled by anodic reaction gradually with time. Figure 2 shows the EIS and the fitting curves of DH36 rust steels in seawater and the fitting parameters are shown in Table 2. The equivalent circuit of Rs(CoutRout)(Cin(Rin(Q(RctZW)))) was used for rust steel in seawater. Rs is the resistance of the solution, Rout, Cout and Rin, Cin are the resistance and capacitance of outer and inner rust layer, Q is CPE parameter, Rct is charge transfer resistance, ZW is Warburg diffusion impedence. If the rust layer grows 3 uniformly, the resistance increases and capacitance decreases, in proportion to the increase in thickness [26]. 1400 30d 90d 180d Fitting 1200 Z" / ohm 1000 50 0 800 0 50 600 400 200 0 0 500 1000 1500 2000 2500 Z' / ohm Figure 2: EIS of DH36 rust steels in seawater Table 2: EIS fitting parameters of rust steels Cin Rin (F· cm-2) (ohm· cm2) Q Y0 (S· cm-2· s n) 30 day 7.03× 10-4 90 day 10-4 180 day 9.07× 1.36× 10-3 7.50 0.0006632 n 0.6871 Rct W Cout Rout (ohm· cm2) (S· cm-2· s 5) (F· cm-2) (ohm· cm2) 2233 2.94× 10-2 5.29× 10-12 5.412 1015 10-13 13.51 1.11× 10-14 13.67 18.22 0.003354 0.7239 2317 5.01× 6.24 0.01388 0.8239 2406 6.27× 109 7.19× From Table 2, the capacitance of the outer rust layer of DH36 rust steel decreased and the resistance increased with time, it means the thickness of the outer layer increased with time in 180 days. The change of the inner layer showed different behavior, the capacitance increased while the resistance increased at first and then decreased, this means the inner rust was complex in both composition and morphology. Characterization Figure 3 and Figure 4 show the micrographs and XRD patterns of the DH36 rust steels in seawater. 4 a b c d e f Figure 3: Micrographs of (a) outer layer and (b) inner layer in 30 days, (c) outer layer and (d) inner layer in 90 days, (e) outer layer and (f) inner layer in 180 days of rust steels 5 a a -FeOOH b -FeOOH a a Intensity (a.u.) Intensity (a.u.) a b a 20 30 a a b b d c a aa a a 50 60 bc 40 a 70 a 10 ba d b a b a 20 a -FeOOH b -FeOOH 30 40 20 30 40 a a 50 a ba a a a aa a 60 70 c c 20 dc c d b 10 20 b a c 30 a cc b a 40 dd d dd d b c d b 30 40 b 50 c c bb b da b 60 70 a a 50 b -FeOOH a a a bb b b 70 aa a a c b a a a aa 60 a Fe3C Intensity (a.u.) Intensity (a.u.) b a -FeOOH b -FeOOH c -FeOOH d Fe3C f a d 70 2 (degree) c -FeOOH d Green Rust Ⅱ a a a c a 10 a -FeOOH b Fe3O4 a a ab a b a 2 (degree) e d d 60 c b a b Intensity (a.u.) Intensity (a.u.) 10 a a bb 50 d a a bb d d a b d d da 2 (degree) a b d d b a 2 (degree) c c -FeOOH d Fe3C a a 10 a -FeOOH b Fe3O4 b 10 20 30 a a 40 a a a a a b a a 50 60 70 2 (degree) 2 (degree) Figure 4: XRD patterns of (a) outer layer and (b) inner layer in 30 days, (c) outer layer and (d) inner layer in 90 days, (e) outer layer and (f) inner layer in 180 days of DH36 rust steels From the SEM images and XRD results, the outer rust in 30 days was flaky, cluster distributed and not covered entire surface of the matrix. The main phase was γ-FeOOH with a small amount of α-FeOOH. The inner rust layer is dense with cracks, and also with flaky and massive structures adhering. The rust covered almost the entire metal surface. The main ingredient was Fe3C with a small amount of γ-FeOOH, Fe3O4 and α-FeOOH. The outer rust in 90 days was flaky, multilayer and only covered part of the metal surface. The 6 composition of the outer rust was same as that in 30 days. The inner rust layer was bent covered with strip distributed flaky structure. It was composed of γ-FeOOH, Fe3C, α-FeOOH and β-FeOOH. The outer rust in 180 days was packing flaky but not dense. The rust composed of γ-FeOOH and a little of Fe3O4 and α-FeOOH. The presence of Green rust II was also observed. The inner rust was bent flaky with some cracks and composed of Fe3C and a little of β-FeOOH. Discussion The thickness of the rust layer increased with immersion time in seawater. The inner rust layer was bent flaky and composed of Fe3C mainly. The outer layer was flaky with cracks and composed of γ-FeOOH and some α-FeOOH. Large amount of Fe3C was detected in inner rust, which was less reported in seawater corrosion. Fe3C is not corrosion rusts in marine environment, and it is an originally presence in the steel. As the main carbon form, Fe3C played the cathodic rule while iron anodic. With the metal disolved, the carbon form left on the metal forming the inner layer. With the presence of Fe3C, the rust was unable to form a protective layer, resulting in the increased corrosion rate in half a year. β-FeOOH is a typical rust in Cl- contained environment, and it is loose and cannot protect the matrix. In addition, the α-FeOOH in outer rust layer was obtained from γ-FeOOH with time. Conclusions (1) The inner layer of DH36 rust steel was bent flaky while the outer layer was packing flaky with cracks. The inner layer was composed of cementite mainly while the outer layer composed of lepidocrocite mainly. (2) The thickness of the outer layer increased with time in half a year while the inner rust was complex. (3) Lots of cementite was detected in inner rust and played cathodic zone. 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