A Comparative Investigation of the Corrosion Resistance and HIC Suceptibility of API 5L X65 and API 5L X80 Steels

Quispe-Avilés, Janeth Marlene; Hincapie-Ladino, Duberney; Falleiros, Neusa Alonso; Melo, Hercílio Gomes de

doi:10.1590/1980-5373-MR-2018-0191

Abstract

High strength low alloy (HSLA) steels are used for the construction of pipelines for oil and natural gas transportation. For such applications pipelines must exhibit mechanical resistance and resistance to corrosion and hydrogen induced cracking (HIC). API 5L X65 steels are the main materials used for this purpose. However, for economic reasons, the use of steels of superior grades would be of interest. This work presents a comparative study of the corrosion and HIC resistances of an API 5L X65 and an API 5L X80 steel in deaerated solution A of NACE TM0284 standard. Electrochemical impedance spectroscopy (EIS) and potentiodynamic polarization experiments were performed in non-sour and sour (H₂S-saturated) media, and HIC resistance tests were carried out in the sour medium. Scanning electron microscopy (SEM) and optical microscopy (OM) characterizations of polished and corroded samples were also done. Electrochemical tests showed that the API 5L X80 steel is slightly more susceptible to surface corrosion, which can be probably linked to its higher inclusion content and smaller grain sizes, it was also susceptible to HIC. Mn and S-rich inclusions found in the crack path indicate that this microstructural feature may play a key role in crack propagation and HIC susceptibility

Keywords:
Microalloyed Steels; API 5L steels; EIS; Corrosion Resistance; NH₂S; HIC

1. Introduction

Oil and natural gas are the main sources of energy in the world and the demand and consumption of their derivatives are constantly growing. In this context, there is an increase in the safety requirements for extraction and transportation of these inputs, as failures can result in severe economic losses and environmental damages. ¹1 Trench CJ, Kiefner JF; The U.S. Oil Pipeline Industry's Safety Performance. Oil Pipeline Characteristics and Risk Factors: Illustrations from the Decade of Construction. Washington: American Petroleum Institute; 2001: 54 p.^-²2 API - American Petroleum Institute. API 5L. Specification for Line Pipe. Washington: American Petroleum Institute; 2012. 12 p. For this reason, to build equipment for the oil and gas industry, it is necessary to use materials that respond satisfactorily to the harsh conditions of the petroleum extraction and transportation network. Among the desired properties, we can list: high mechanical resistance to withstand the high operating pressures, fracture toughness, weldability and resistances to corrosion and hydrogen induced damages in acidic environments. ³3 Koo JY, Luton MJ, Bangaru NV, Petkovic RA, Fairchild DP, Petersen CW, et al. Metallurgical Design of Ultra High-strength Steels for Gas Pipelines. International Journal of Offshore and Polar Engineering. 2004;14(1):2-10.^-⁴4 Hashemi SH. Strength-hardness statistical correlation in API X65 steel. Materials Science and Engineering: A. 2011;528(3):1648-1655.

H₂S and CO₂, normally present in oil fields, in the presence of water, create an extremely aggressive environment, generally referred as sour gas. In such environment, high strength steels may become prone to Hydrogen Induced Cracking (HIC).⁵5 Siciliano F, Stalheim DG, Gray MJ. Modern High Strength Steels for Oil and Gas Transmission Pipelines. In: Proceedings of the 2008 7th International Pipeline Conference; 2008 Sep 29 - Oct 3; Calgary, AB, Canada. p. 187-195.^-⁶6 Kawashima A, Hashimoto K, Shimodaira S. Hydrogen Electrode Reaction and Hydrogen Embrittlement of Mild Steel in Hydrogen Sulfide Solutions. Corrosion. 1976;32(8):321-331. The problem occurs as a consequence of the diffusion of atomic hydrogen within the steel microstructure, which them are entrapped at specific anchoring sites associated with microstructural defects⁷7 Gray JM, Siciliano F. High Strength Microalloyed Linepipe: Half a Century of Evolution. Houston: Microalloyed Steel Institute; 2009. p. 20-45.

8 Guo Y, Yang S, Shang C, Wang Y, He X. Influence of carbon contend and microstructure on corrosion behavior of low alloy steels in Cl- containing environment. Corrosion Science. 2009;51(2):242-251.^-⁹9 Haq AJ, Muzaka K, Dunne DP, Calka A, Pereloma EV. Effect of microstructure and composition on hydrogen permeation in X70 pipeline steels. International Journal of Hydrogen Energy. 2013;38(5):2544-2556., the recombination of these atoms generates H₂ gas leading to pressure build up, which, ultimately, can result in failures due to HIC.¹⁰10 Dong CF, Liu ZY, Li XG, Cheng YF. Effects of hydrogen-charging on the susceptibility on X100 pipeline steel to hydrogen-induced cracking. International Journal of Hydrogen Energy. 2009;34(24):9879-9884. Atomic hydrogen results from corrosion, and its diffusion into the material microstructure is favored by the presence of H₂S in the electrolyte and also by the existence of sulfide rich inclusions in the material microstructure.¹¹11 Barbosa GL, Cândido LC, Toffolo VR, Soares BLE. Microstructure and Mechanical Properties of Two Api Steels for Iron Ore Pipelines. Rede Temática em Engenharia de Materiais - REDEMAT Universidade Federal de Ouro Preto. 2014;17(1):114-120.^-¹²12 Fallahmohammadi E, Bolzoni F, Fumagalli G, Re G, Benassi G, Lazzari L. Hydrogen diffusion into three metallurgical microstructures of a C-Mn X65 and low alloy F22 sour service steel pipelines. International Journal of Hydrogen Energy. 2014;39(25):13300-13313.In the presence of such chemicals and microstructural features, the surface recombination of atomic H into H₂ is hampered¹³13 Kim SJ, Kim KY. A Review of Corrosion and Hydrogen Diffusion Behaviors of High Strength Pipeline Steel in Sour Environment. Journal of Welding and Joining. 2014;32(5):13-20.^-¹⁴14 Mohtadi-Bonab MA, Eskandari M, Rahman KMM, Ouellet R, Szpunar JA. An extensive study of hydrogen-induced cracking susceptibility in an API X60 sour service pipeline steel. International Journal of Hydrogen Energy. 2016;41(7):4185-4197., thus enhancing the diffusion to the metal microstructure and the occurrence of HIC failures.

High-strength low alloy (HSLA) steels are characterized by their superior mechanical properties when compared to other steels with similar compositions, which are achieved by means of controlled addition of microalloying elements and rigorous production procedures. ¹⁴14 Mohtadi-Bonab MA, Eskandari M, Rahman KMM, Ouellet R, Szpunar JA. An extensive study of hydrogen-induced cracking susceptibility in an API X60 sour service pipeline steel. International Journal of Hydrogen Energy. 2016;41(7):4185-4197.

15 Prasad K, Dwivedi DK. Some investigations on microstructure and mechanical properties of submerged arc welded HSLA steel joints. The International Journal of Advanced Manufacturing Technology. 2008;36(5-6):475-483.^-¹⁶16 Qi YM, Luo HY, Zheng SQ, Chen CF, Wang DN. Effect of immersion time on the hydrogen content and tensile properties of A350LF2 steel exposed to hydrogen sulphide environments. Corrosion Science. 2013;69:164-174.However, to be used in the oil and gas transportation network they must meet the requirements of the API 5L specification regarding equivalent carbon control, shear boundary (MPa), yield strength (MPa). ¹⁷17 API - American Petroleum Institute. Specifications for Line Pipe ANSI/API 5L. Washington: American Petroleum Institute; 2007. 153 p.^-¹⁸18 Qi YM, Luo HY, Zheng SQ, Chen CF, Lv ZG, Xiong MX. Comparision of tensile and impact behavior of carbon steel in H2S environments. Materials & Design. 2014;58:234-241.Currently, the API 5L X65 is the highest grade approved for sour gas application.¹⁹19 Davani RKZ, Miresmaelli R, Soltanmohammadi M. Effect of thermomechanical parameters on mechanical properties of base metal and heat affected zone of X65 pipeline steel weld in the presence of hydrogen. Materials Science and Engineering: A. 2018;718:135-146.^-²⁰20 Zhao W, Yang M, Zhang T, Deng Q, Jiang W, Jiang W. Study on hydrogen enrichment in X80 steel spiral welded pipe. Corrosion Science. 2018;133:251-260.However, there are high expectations of using higher grades API 5L steels, such as X70 and X80, which exhibit superior mechanical strength. This would allow the fabrication of pipelines with thinner walls, resulting in relevant savings. ²¹21 Liu Q, Zhou Q, Venezuela J, Zhang M, Atrens A. The role of the microstructure on the influence of hydrogen on some advanced high-strength steels. Materials Science & Engineering A. 2018;715:370-378.Therefore, in recent years, the interest in studying the resistance to HIC of API steels of higher grades has increased with the purpose of using them for pipeline application.

Based on the reasons aforementioned, this article presents a comparative study of the corrosion resistance and HIC susceptibility of two API 5L steels: one of the X65 and the other of the X80 grade.

2. Materials and Methods

2.1 Materials

API 5L X65 and X80 grades steels provided as tubes by partner companies were used. Their characteristics and chemical compositions are presented, respectively, in Tables 1 and 2.

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Table 1
Characteristics of the API 5L steel tubes.

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Table 2
Chemical composition of the API 5L X65 and X80 steel (wt.%).

2.2 Microstructural characterization

For inclusions analyses, samples were cut parallel to the rolling direction, whereas the microstructural analyses were performed from the rolling cross-section according to ASTM E112 (2013)²²22 ASTM International. ASTM E112-13 - Standard Test Methods for Determining Average Grain Size. West Conshohocken: ASTM International; 2013.. The samples were embedded in bakelite (AKA Resin Epoxi 8010), sequentially ground (Sultrade-Struers) with silicon carbide emery paper up to #1200 grit, and then polished (Sultrade-Struers) with diamond paste up to 1µm. Between each ground and polishing step samples were thoroughly washed with distilled and demineralized water, and at the end they were washed with ethanol, dried in a hot air stream and stored in a desiccator.

The characterizations were performed by means of optical microscopy (OM) (Olympus BX60M) and Scanning Electron Microscopy (SEM) (Olympus Philips XL-30) from polished and from polished and Nital 2% (HNO₃ 2% + 100 ml ethanol, 10 s) etched samples.

For inclusions classification the ASTM International E45 standard (2013) ²³23 ASTM International. ASTM E45-13 - Standard Test Methods for Determining the Inclusion Content of Steel. West Conshohocken: ASTM International; 2013. was used, whereas grains sizes determination were performed according to the recommendations of ASTM International E112-113 standard (2013) ²²22 ASTM International. ASTM E112-13 - Standard Test Methods for Determining Average Grain Size. West Conshohocken: ASTM International; 2013. using the software IMAGEJ as analytical tool.

SEM images were also acquired form corroded samples.

2.3 Electrochemical tests and corrosion morphology evaluation

All electrochemical tests were carried out in solution A of NACE TM0284-11 ²⁵25 NACE International. NACE Standard TM0284-2011- Evaluation of Pipeline and Pressure Vessel Steels for Resistance to Hydrogen-Induced Cracking. Houston: NACE International; 2011., which is composed of 0.5 wt % acetic acid + 5.0 wt% NaCl. Before corrosion test, the electrolyte was purged with N₂ (Fume Hood CVD100 Vidy) in a separated recipient during 1h, then this solution was poured into the electrochemical cell (already with the electrodes positioned) and further degassed for 15 min. Thereafter, H₂S gas was bubbled (Fume Hood CVD100 Vidy) at a rate of approximately 200 ml per minute during 1h. Experiments without H₂S saturation were also performed.

The working electrodes (WE) were cut from the cross-section of the tubes (ASTM G106 -89 (2004) standard²⁴24 ASTM International. ASTM G106-89(2010) - Standard Practice for Verification of Algorithm and Equipment for Electrochemical Impedance Measurements. West Conshohocken: ASTM International; 2010.), embedded in bakelite (exposed area 1 cm²) and them ground (Sultrade-Struers) up to # 1200 with silicon carbide emery paper.

The experiments were carried out using two different methodologies. In the first one, denominated when necessary as Procedure 1 (P1), performed either in deaerated or in H₂S saturated solution, initially, the open circuit potential (OCP) was monitored for 1 h, period necessary to acquire a constant value, followed by the electrochemical impedance spectroscopy (EIS) and potentiodynamic polarization (PDP) tests, this latter after supplementary 15 minutes stabilization of the OCP. Due to the deaeration procedure, in the experiments performed in the deaerated solution the OCP monitoring was initiated after 15 minutes immersion of the WE in the test solution (after the supplementary 15 min N₂ purging), whereas in the H₂S saturated solution the previous immersion period was 75 minutes, as N₂ purging was followed by 1 h H₂S bubbling.

In the second procedure, performed only in H₂S saturated solution and designated, when necessary, as Procedure 2 (P2), after degassing as described in the previous paragraph, the electrodes remained immersed in the test solution for 24h, during which the OCP and the EIS behavior were monitored, some samples were submitted to PDP experiments as the final step. SEM and OM observations after corrosion were performed only in these electrodes.

The EIS experiments were carried out using a perturbation amplitude of 10 mV (rms) in the frequency range from 10⁵5 Siciliano F, Stalheim DG, Gray MJ. Modern High Strength Steels for Oil and Gas Transmission Pipelines. In: Proceedings of the 2008 7th International Pipeline Conference; 2008 Sep 29 - Oct 3; Calgary, AB, Canada. p. 187-195. to 10^-2 Hz. The acquisition rate was 10 points per decade. The PDP tests were performed from - 250 mV vs OCP to + 250 mV vs OCP at a scan rate of 1 mV/s. A minimum of three tests was performed for each condition.

All the experiments were accomplished with a µAUTOLAB type II potentiostat equipped with a frequency response analyzer (FRA2) module using a conventional three electrode system, with a Saturated Calomel Electrode (SCE) as reference, a platinum wire counter electrode and the X65 and X80 steel as WE.

2.4 Hydrogen Induced Cracking (HIC) experiments

These tests were carried out in H₂S-saturated A solution (0.5% acetic acid (wt) + 5.0% NaCl (wt)) and followed the recommendations of NACE TM0284-11²⁵25 NACE International. NACE Standard TM0284-2011- Evaluation of Pipeline and Pressure Vessel Steels for Resistance to Hydrogen-Induced Cracking. Houston: NACE International; 2011.. Samples were extracted from the rolling direction with (100 ± 1) mm length and (20 ± 1) mm width, whereas the thicknesses corresponded to those of the original pipelines. Before testing, the samples were machined with a milling machine and ground (#320 - Aerotex Aropol 2V) using water as lubricant until completely flat surfaces were obtained. Then, they were thoroughly washed with ethanol dried in a hot air stream and placed in the test vessel so that the specimens did not touch either each other or the vessel walls, according to the NACE TM0284-11²⁶26 Stern M, Geary AL. Electrochemical Polarization I. A Theoretical Analysis of the Shape of Polarization Curves. Journal of the Electrochemical Society. 1957;104(1):56-63. recomendations.

To perform the test, the electrolyte was initially degassed with N₂ during one hour and then poured (5L) into the testing vessel, where the samples were already positioned. Then supplementary N₂ degassing (15 min) was performed followed by 1h H₂S saturation (200 ml/min/L ²⁶26 Stern M, Geary AL. Electrochemical Polarization I. A Theoretical Analysis of the Shape of Polarization Curves. Journal of the Electrochemical Society. 1957;104(1):56-63.). The total test duration was 96 h ((25 ± 3) ºC) computed immediately after the 60-minute H₂S injection period.¹⁹19 Davani RKZ, Miresmaelli R, Soltanmohammadi M. Effect of thermomechanical parameters on mechanical properties of base metal and heat affected zone of X65 pipeline steel weld in the presence of hydrogen. Materials Science and Engineering: A. 2018;718:135-146.

After the HIC test, the samples were withdrawn from the vessel, thoroughly washed with soap and water, washed with ethanol, dried in a hot air stream and sectioned with an ISOMET precision cutter with diamond. Afterwards, the sections were embedded in bakelite with the cross sections facing upwards, ground up to #1200 emery paper (Arotec Aropol 2V), polished with diamond paste down to 1 µm (Sultrade, Struers) and then observed for crack initiation and propagation by OM (Olympus BX60M) and SEM (Olympus Philips XL-30) without and with Nital (HNO₃ 2% + 100 ml ethanol, 10 s) etching.

3. Results

3.1 Analysis of inclusions and microstructural characterization

Figure 1 (a) shows an OM image of the surface of the API 5L X65 steel after polishing and without etching. A uniform distribution of round-shaped inclusions was verified (SEM image insert in the Figure), which analyzes by EDS (Figure 1 (b)) showed mainly the presence of Ca, Al, Mg and Ti. Their mean size were between 1.8 and 6.4 µm, allowing to classify them as globular-oxide-sulfide fine series (D-Globular Oxide/Sulfide Type and Thin subcategory) according to ASTM E45 (2013)²³23 ASTM International. ASTM E45-13 - Standard Test Methods for Determining the Inclusion Content of Steel. West Conshohocken: ASTM International; 2013..

Figure 1
Optical microscopy image of the inclusions distribution in the microstructure of the API 5L X65 steel (a), representative EDS spectrum of the inclusions (b), and backscattered SEM image of a round-shaped inclusion (insert in (a))

API 5L X80 steel also presented evenly distributed inclusions, however with higher density (Figure 2 (a)) and several of them with irregular shape (Insert of Figure 2 (a)). Regarding the composition of the inclusions in this material, the EDS analysis (Figure 2 (b)) indicated the presence of Al, O, S and Mn. Their mean size were between 2.8 and 9.2 µm, allowing to classify them as D-globular oxide-sulfide heavy series (D-Globular Oxide/Sulfide Type and Heavy subcategory) according to ASTM E45 (2013) ²³23 ASTM International. ASTM E45-13 - Standard Test Methods for Determining the Inclusion Content of Steel. West Conshohocken: ASTM International; 2013..

Figure 2
Optical microscopy image of the inclusions distribution in the microstructure of the API 5L X80 steel (a), representative EDS spectrum of the inclusions (b), and backscattered SEM image of an irregular-shaped inclusion (insert in (a)).

The analysis of the microstructure of the API 5L X65 steel by OM after etching with 2% Nital reagent (Figure 3 (a)) presented uniform microstructure with refined grains, without the presence of banding. SEM image (Figure 3 (b)) showed a ferritic matrix with pearlite grains (indicated by the arrow) dispersed in the matrix. The mean grain size determined according to ASTM E112-13(2014) ²²22 ASTM International. ASTM E112-13 - Standard Test Methods for Determining Average Grain Size. West Conshohocken: ASTM International; 2013. was 6.5 ± 0.3 µm, with acicular shape.

The microstructure of the API 5L X80 steel is formed by uniform and refined ferrite grains (Figure 4 (a)). SEM analysis (Figure 4 (b)) showed no banding and revealed a ferritic matrix, with minimal presence of M/A (martensite/austenite) microconstituents at the grain boundaries. The average grain size was 4.6 ± 0.3 µm with polygonal grain contours.

Figure 3
(a) Optical microscopy and (b) SEM (secondary electrons) image of the API 5L X65 steel. Images from the central cross-section to the rolling direction. Nital 2% etched.

Figure 4
(a) Optical microscopy and (b) SEM (secondary electrons) image of the API 5L X80 steel. Images from the central cross-section to the rolling direction. Nital 2% etched.

3.2 Electrochemical tests

3.2.1 Electrochemical behavior - deaerated and H₂S saturated solution - Procedure 1

Figure 5 (a) shows the OCP variation of the two steels during 2000s immersion in deaerated solution A without and with saturation with H₂S. For all conditions, a fast potential stabilization was observed, which can be a consequence of the period the samples remained immersed in the test electrolyte during the degassing procedure prior to OCP registration. In addition, for the two steels, there is a decrease of the OCP in the H₂S saturated condition and the OCP of the API 5L X80 steel is always lower when compared with the API 5L X65 one.

Figure 5
OCP variation for the API 5L X65 and API 5L X80 steels in deaerated solution A, NACE TM0284 (2011), without and with H₂S saturation. Experimental Procedure 1.

EIS diagrams (Figure 6) for the two steels in both media are composed of one highly depressed capacitive loop whose corresponding phase angles are quite broad, indicating time constants overlapping. In accordance with published studies²⁶26 Stern M, Geary AL. Electrochemical Polarization I. A Theoretical Analysis of the Shape of Polarization Curves. Journal of the Electrochemical Society. 1957;104(1):56-63.^-²⁷27 Arzola S, Mendoza-Florez J, Duran-Romero R, Genesca J. Electrochemical Behavior of API X70 steel in Hydrogen Sulfide-Containing Solutions. Corrosion. 2006;62(5):433-443., the results show a visible decrease of the impedance in the H₂S saturated medium, confirming its higher aggressiveness. Furthermore, for both conditions, the API 5L X80 steel presented lower impedance values. The characteristics of these diagrams indicate that even though with different kinetics, the corrosion mechanism in both media must be similar.

Figure 6
Nyquist (a) and phase angle (b) diagrams of API 5L X65 and API 5L X80 steels in deaerated solution A, NACE TM0284 (2011), without and with H₂S saturation. Experimental Procedure 1.

The results of the PDP tests (Figure 7) for the two steels show that the anodic and cathodic reactions are controlled by activation. In addition, and in accorddance with the results of the EIS tests, it is observed that the API 5L X80 steel presents, for both conditions, greater susceptibility to corrosion, characterized by more depolarized anodic and cathodic curves and higher corrosion current densities. The data presented in Table 3, obtained by Tafel extrapolation, are consistent with these findings. The corrosion current densities (i_corr mA/cm²) can be sorted in descending order as: X80 with H₂S > X65 with H₂S > X80 without H₂S > X65 without H₂S. For both materials, extrapolated i_corr values were about one order of magnitude higher in the H₂S saturated electrolyte, which is in accordance with the expected higher aggressiveness of the sour medium²⁸28 Lucio-Garcia MA, Gonzalez-Rodriguez JG, Casales M, Martinez L, Chacon-Nava JG, Neri-Flores MA, et al. Effect of heat treatment on H2S corrosion of a micro-alloyed C-Mn steel. Corrosion Science. 2009;51(10):2380-2386.

29 Huang F, Li XG, Liu J, Qu YM, Ji J, Du CW. Hydrogen-induced cracking susceptibility and hydrogen trapping efficiency of different microstructure X80 pipeline steels. Journal of Materials Science. 2011;46(3):715-722.

30 Bolzon G, Boukharouba T, Gabetta G, Elboujdaini M, Mellas M, eds. Integrity of Pipelines Transporting Hydrocarbons - Corrosion Mechanisms Control and Management. Dordrecht: Springer Publishing, 2011.

31 Hladky K, Dawson JL. The measurement of corrosion using electrochemical 1f noise. Corrosion Science. 1982;22(3):231-237.

32 Jin TY, Cheng YF. In-situ characterization by localized electrochemical impedance spectroscopy of the electrochemical activity of microscopic inclusions in an X100 steel. Corrosion Science. 2011;53(2):850-853.^-³³33 Huang H, Shaw WJD, Yen SK, Huang IB. Hydrogen Embrittlement Interactions in Cold-Worked Steel. Corrosion. 1995;51(1):30-36.. On the other hand, for the same electrolyte, the i_corr slightly increased for the X80 steel when comparing with the X65.

Figure 7
Potentiodynamic polarization curves for API 5L X65 and API 5L X80 steels in deaerated solution A, NACE TM0284 (2011), without and with H₂S saturation. Experimental Procedure 1.

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Table 3
Table with information extracted from the polarization curves of . Procedure 1.

3.2.2 Electrochemical behavior in H₂S saturated solution (24h) - sour medium - Procedure 2

For the H₂S-saturated medium, sour medium, the corrosion of the two steels during 24h of immersion was investigated. Figure 8 shows that, for the two steels, the OCP remains stable throughout the test period, indicating that there is no alteration of the interfacial processes. It is also noted that the API 5L X80 steel has lower OCP at any time.

Figure 8
OCP variation for the API 5L X65 and API 5L X80 steels during 24h immersion in deaerated solution A, NACE TM0284 (2011), saturated with H₂S, sour medium. Procedure 2.

In the EIS experiments (Figures 9 and 10) the characteristics of the diagrams remained the same as those observed in the short duration tests, without modifications in their shapes, further indicating that no change in the reactions mechanism take place. However, for both materials, an increase in impedance is observed as a function of immersion time, indicating a decrease in the intensity of the corrosive attack. Random decreases followed by continued increase in the impedance values were observed during the whole test period. The corrosion process of iron and steel in sour medium is generally accompanied by iron sulfide film formation, therefore, the observed behavior can be attributed to film growth until a maximum thickness is reached, when film detachment occurs (confirmed by the presence of a black precipitate deposited at the cell bottom), initiating an intermitent process of growth and detachment. ²⁸28 Lucio-Garcia MA, Gonzalez-Rodriguez JG, Casales M, Martinez L, Chacon-Nava JG, Neri-Flores MA, et al. Effect of heat treatment on H2S corrosion of a micro-alloyed C-Mn steel. Corrosion Science. 2009;51(10):2380-2386.

29 Huang F, Li XG, Liu J, Qu YM, Ji J, Du CW. Hydrogen-induced cracking susceptibility and hydrogen trapping efficiency of different microstructure X80 pipeline steels. Journal of Materials Science. 2011;46(3):715-722.^-³⁰30 Bolzon G, Boukharouba T, Gabetta G, Elboujdaini M, Mellas M, eds. Integrity of Pipelines Transporting Hydrocarbons - Corrosion Mechanisms Control and Management. Dordrecht: Springer Publishing, 2011.

Figure 9
Nyquist (a) and phase angle (b) diagrams for the API 5L X65 steel during 24h immersion in deaerated solution A, NACE TM0284 (2011), saturated with H₂S, sour medium. Procedure 2.

Figure 10
Nyquist (a) and phase angle (b) diagrams for the API 5L API 5L X80 steel during 24h immersion in deaerated solution A, NACE TM0284 (2011), saturated with H₂S, sour medium. Procedure 2.

The comparison between the EIS diagrams of Figures 9 and 10, presented in the same scale, clearly shows that the API 5L X80 steel (Figure 10) is less corrosion resistant. In addition, for this steel, the phase angle diagrams are slightly more deformed in the high frequency domain, indicating a possible difference in the corrosion mechanism.

In agreement with the other electrochemical tests, the PDP curves obtained after 24h of immersion (Figure 11) presented the same characteristics of those observed after 1h of test, confirming that there is no change in the reaction mechanism. However, for this condition, it turns out clear that the API 5L X80 steel presents higher corrosion current density caused by depolarization of the anodic curve, which is confirmed by the Tafel extrapolation results presented in Table 4 showing a slight higher i_corr for this steel. On the other hand, in accordance with the EIS results, the comparison of the i_corr values in Tables 3 and 4 indicates that there was a slight decrease of the corrosion process.

Figure 11
Potentiodynamic polarization curves for the API 5L X65 and API 5L X80 steels after 24h immersion in deaerated solution A, NACE TM0284 (2011), saturated with H₂S, sour medium. In the diagrams the main anodic and cathodic reactions are indicated. Procedure 2.

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Table 4
Table with information extracted from the polarization curves after 24h of immersion, . Procedure 2.

3.2.3 Microstructural characterization after 24h immersion in H₂S-saturated solution - sour medium - Procedure 2

Figure 12 shows micrographs by OM (Figure 12 (a)) and SEM (Figure 12 (b)) of the surface of the API 5L X65 steel after 24h of immersion in the sour medium. The material presented generalized attack, characterized by the formation of a thick layer of corrosion products, which, nevertheless, was detached during the sample preparation for microscopic observation. Also, localized attacks were observed, which, however, did not develop deep pits. The corrosion products formed in the regions where localized attack took place presented globular shapes (Figure 12 (c)), and their EDS analyzes (Figure 12 (d)) showed the presence of O, Fe, S, and Ca indicating to be associated with the presence of inclusions.

Figure 12
OM (a) and SEM (b) images of the API 5L X65 steel after 24h immersion in deaerated solution A, NACE TM0284 (2011), saturated with H₂S, sour medium. Magnified SEM image of the corrosion products morphology at the localized corrosion sites (c), EDS analysis of the region depicted in (c) (d).

Figure 13 displays the OM (Figure 13(a)) and SEM (Figure 13(b)) micrographs of the API 5L X80 steel after 24h immersion in the sour medium, whereas Figures 13(c) and (d) present, respectively, the magnified SEM images of the corrosion products formed above a localized corrosion site and its EDS analysis. The micrographs and analysis show the same features as already presented for the API 5l X65 steel, with the difference that the localized corrosion is more intense in this material (pits are more numerous and deeper). Also for this sample a thick corrosion product layer was formed, which detached during sample preparation for microscopic analysis.

Figure 13
OM (a) and SEM (b) images of the API 5L X80 steel after 24h immersion in deaerated solution A, NACE TM0284 (2011), saturated with H₂S, sour medium. Magnified SEM image of the corrosion products morphology at the localized corrosion sites (c), EDS analysis of the region depicted in (c) (d).

3.3 Hydrogen Induced Cracking (HIC) tests

HIC tests were performed according to NACE TM 0284-2011¹⁹19 Davani RKZ, Miresmaelli R, Soltanmohammadi M. Effect of thermomechanical parameters on mechanical properties of base metal and heat affected zone of X65 pipeline steel weld in the presence of hydrogen. Materials Science and Engineering: A. 2018;718:135-146. standard using solution A saturated with H₂S. Due to the aggressiveness of the sour medium, H₂ evolution at the samples surface was observed during the whole duration of the test (96 h), indicating intense corrosion. The cross-section observations after polishing of the API 5L X65 steel by OM (Figure 14(a)) and SEM (Figure 14(b)) did not reveal signs of cracks nucleation or propagation. On the other hand, the API 5L X80 steel presented a deep and large cracks in the central section parallel to the rolling direction (OM in Figure 15(a) and SEM in Figure 15(b)), which was further analyzed by SEM after Nital 2% etching. SEM image (Figure 15(c)) shows the presence of an inclusion in the crack propagation path, which EDS analysis (Figure 15(d)) showed the presence of Mn and S.

Figure 14
OM (a) and SEM (backscattered electrons) (b) images of one of the API 5L X65 samples submitted to the HIC test. Polished (1 µm) cross-section to the rolling direction. Exposure time 96h to solution A saturated with H₂S.

Figure 15
OM (a) and SEM (backscattered electrons) (b) images of one of the API 5L X80 samples submitted to the HIC test. Polished (1 µm) cross-section to the rolling direction. Sample after Nital 2% etching (c), EDS analysis of the inclusion indicated in (c) (d). Exposure time 96h to solution A saturated with H₂S.

4. Discussion

4.1 Inclusions analysis and microstructural characterization

The inclusions of the API 5L X65 steel were round-shaped, homogeneously distributed in the matrix and with an average size between 1.8 and 6.4 µm. On the other hand, for the steel API 5L X80, they were also evenly distributed, but in greater quantity, they were larger (between 2.8 and 9.2 µm), and both round-shaped and irregular inclusions with angular appearance were present. These latter were found mainly in the central regions of the sample, which was supplied as a pipe.

The experimental results showed that the API 5L X80 steel is slightly less resistant to corrosion than API 5L X65 and is also susceptible to HIC. It is a consensus in the literature that inclusions play a central role in these two factors. Initially, they constitute microstructural heterogeneities at which, often, the electrochemical activity differs from the matrix, forming galvanic microcells, serving as points for localized corrosion initiation. In an investigation performed with materials with similar composition to those used in the present study, Hincapie et al. ³⁴34 Hincapie-Ladino D, Falleiros NA. Trincamento induzido por hidrogênio em aços microligados. Tecnologia em Metalurgia, Materiais e Mineração. 2015;12(1):82-93. verified that increased number of inclusions resulted in increased corrosion susceptibility.

Regarding the HIC resistance, inclusions with larger size and irregular shape tend to concentrate stresses, serving as preferential sites for hydrogen accumulation. ³⁴34 Hincapie-Ladino D, Falleiros NA. Trincamento induzido por hidrogênio em aços microligados. Tecnologia em Metalurgia, Materiais e Mineração. 2015;12(1):82-93.

35 Koh SU, Kim JS, Yang BY, Kim KY. Effect of Line Pipe Steel Microstructure on Susceptibility to Sulfide Stress Cracking. Corrosion. 2004;60(3):244-253.^-³⁶36 Chen X, Li X, Du C, Liang P. Effects of solution environments on corrosion behaviors of X70 steels under simulated disbonded coating. Journal of Chinese Society for Corrosion and Protection. 2010;30(1):35-40. This relationship between inclusions shape and resistance to HIC of steels is often associated with the existence of microporosities between them and the matrix acting as hydrogen traps ³⁵35 Koh SU, Kim JS, Yang BY, Kim KY. Effect of Line Pipe Steel Microstructure on Susceptibility to Sulfide Stress Cracking. Corrosion. 2004;60(3):244-253.

36 Chen X, Li X, Du C, Liang P. Effects of solution environments on corrosion behaviors of X70 steels under simulated disbonded coating. Journal of Chinese Society for Corrosion and Protection. 2010;30(1):35-40.

37 Wang H, Shaw WJD. Cold work effects on sulfide stress cracking of pipeline steel exposed to sour environments. Corrosion Science. 1993;34(1):61-68.^-³⁸38 Zheng SQ, Qi YM, Chen CF, Li SY. Effect of hydrogen and inclusions on the tensile properties and fracture behaviour of A350LF2 steels after exposure to wet H2S environments. Corrosion Science. 2012; 60:59-68.. Jin, Liu and Cheng³⁶36 Chen X, Li X, Du C, Liang P. Effects of solution environments on corrosion behaviors of X70 steels under simulated disbonded coating. Journal of Chinese Society for Corrosion and Protection. 2010;30(1):35-40. found that the existence of interfacial microporosities between aluminum and silicon oxide inclusions and the matrix of an API 5L X100 steel favored crack nucleation.

The microstructural characterization also showed that the grain size of the API 5L X65 steel was 6.5 ±0.3 µm and that of the API 5L X80 steel of 4.6 ±0.3 µm. The energy associated with the interaction between grain boundaries and atomic hydrogen is relatively low, ³⁶36 Chen X, Li X, Du C, Liang P. Effects of solution environments on corrosion behaviors of X70 steels under simulated disbonded coating. Journal of Chinese Society for Corrosion and Protection. 2010;30(1):35-40.

37 Wang H, Shaw WJD. Cold work effects on sulfide stress cracking of pipeline steel exposed to sour environments. Corrosion Science. 1993;34(1):61-68.

38 Zheng SQ, Qi YM, Chen CF, Li SY. Effect of hydrogen and inclusions on the tensile properties and fracture behaviour of A350LF2 steels after exposure to wet H2S environments. Corrosion Science. 2012; 60:59-68.^-³⁹39 Sourmail T. A review of the effect of cold work on resistance to sulphide stress cracking. In: Proceedings of Corrosion 2007; 2007 Mar 11-15; Nashville, TN, USA. Paper 07104.^therefore, these are considered as reversible traps. As such, they act as temporary sites for atomic hydrogen anchoring, thus serving as a source of hydrogen for irreversible traps.³⁷37 Wang H, Shaw WJD. Cold work effects on sulfide stress cracking of pipeline steel exposed to sour environments. Corrosion Science. 1993;34(1):61-68.^-³⁸38 Zheng SQ, Qi YM, Chen CF, Li SY. Effect of hydrogen and inclusions on the tensile properties and fracture behaviour of A350LF2 steels after exposure to wet H2S environments. Corrosion Science. 2012; 60:59-68.Thus, the smaller grain size of API 5L X80 steel may also contribute to its superior susceptibility to HIC.

4.2 Electrochemical tests and corrosion morphology

The electrochemical tests after short immersion times in deaerated solution A without and with H₂S saturation, procedure 1, showed that the OCP of the two steels in sour medium was less noble, and that in this medium they also presented lower impedance. These results are in agreement with those found by several authors using different electrochemical techniques that showed an increase in the corrosion rate of different API steels grades when H₂S was added to the electrolytes. ²⁷27 Arzola S, Mendoza-Florez J, Duran-Romero R, Genesca J. Electrochemical Behavior of API X70 steel in Hydrogen Sulfide-Containing Solutions. Corrosion. 2006;62(5):433-443.^,²⁸28 Lucio-Garcia MA, Gonzalez-Rodriguez JG, Casales M, Martinez L, Chacon-Nava JG, Neri-Flores MA, et al. Effect of heat treatment on H2S corrosion of a micro-alloyed C-Mn steel. Corrosion Science. 2009;51(10):2380-2386.^,³⁸38 Zheng SQ, Qi YM, Chen CF, Li SY. Effect of hydrogen and inclusions on the tensile properties and fracture behaviour of A350LF2 steels after exposure to wet H2S environments. Corrosion Science. 2012; 60:59-68.^,⁴⁰40 Arzola-Peralta S, Genescá Llongueras J, Palomar-Pardavé M, Romero-Romo M. Study of the electrochemical behaviour of a carbon steel electrode in sodium sulfate aqueous solutions using electrochemical impedance spectroscopy. Journal of Solid State Electrochemistry. 2003;7(5):283-288.^,⁴¹41 Zhang F, Pan J, Lin C. Localized corrosion behavior of reinforcement steel in simulated concrete pore solution. Corrosion Science. 2009;51(9):2130-2138.^,⁴²42 Wang P, Lv Z, Zheng S, Qi Y, Wang J, Zheng Y. Tensile and impact properties of X70 pipeline steel exposed to wet H2S environments. International Journal of Hydrogen Energy. 2015:40(1):11514-11521. For the non-sour and the sour medium, the PDP curves (Figure 7) showed that the anodic and cathodic processes are activation-controlled, indicating that these reactions are, respectively, the oxidation of Fe to Fe²⁺ and the reduction of H⁺ ions. However, the pH of solution A practically did not change with saturation with H₂S (2.7±0.3) indicating that the increase in the corrosion rate is a consequence of the acceleration of the kinetics of the anodic reaction, although this aspect is not evident from the comparison between the curves shown in Figure 7.

For all the investigated conditions the impedance diagrams (Figures 6, 9 and 10) presented a single depressed capacitive loop associated with a wide phase angle. This indicates the overlap of more than one time constant, similar to that found by different authors for HSLA steels in sour media with different compositions.²⁶26 Stern M, Geary AL. Electrochemical Polarization I. A Theoretical Analysis of the Shape of Polarization Curves. Journal of the Electrochemical Society. 1957;104(1):56-63.^,²⁷27 Arzola S, Mendoza-Florez J, Duran-Romero R, Genesca J. Electrochemical Behavior of API X70 steel in Hydrogen Sulfide-Containing Solutions. Corrosion. 2006;62(5):433-443.^,²⁸28 Lucio-Garcia MA, Gonzalez-Rodriguez JG, Casales M, Martinez L, Chacon-Nava JG, Neri-Flores MA, et al. Effect of heat treatment on H2S corrosion of a micro-alloyed C-Mn steel. Corrosion Science. 2009;51(10):2380-2386.^,³⁰30 Bolzon G, Boukharouba T, Gabetta G, Elboujdaini M, Mellas M, eds. Integrity of Pipelines Transporting Hydrocarbons - Corrosion Mechanisms Control and Management. Dordrecht: Springer Publishing, 2011.^,⁴⁰40 Arzola-Peralta S, Genescá Llongueras J, Palomar-Pardavé M, Romero-Romo M. Study of the electrochemical behaviour of a carbon steel electrode in sodium sulfate aqueous solutions using electrochemical impedance spectroscopy. Journal of Solid State Electrochemistry. 2003;7(5):283-288.

The shapes both of the EIS diagrams and of the polarization curves were similar in the deaerated and in the H₂S saturated solution indicating similar corrosion mechanisms. The monitoring of the corrosion behavior as a function of immersion time in the sour medium, which was performed during 24 h (Figure 8), showed that, regardless the steel, the OCP remained very stable throughout the test period, indicating that there were no changes in the corrosion mechanism and that the surface modifications resulting from the corrosive process did not alter the interfacial electrochemical processes. Moreover, throughout the period, the OCP of the API 5L X65 steel was more noble. The results of the EIS tests (Figures 9 and 10) showed increased impedance with immersion time, indicating improved corrosion resistance. As reported by different authors for steels immersed in sour medium ²⁸28 Lucio-Garcia MA, Gonzalez-Rodriguez JG, Casales M, Martinez L, Chacon-Nava JG, Neri-Flores MA, et al. Effect of heat treatment on H2S corrosion of a micro-alloyed C-Mn steel. Corrosion Science. 2009;51(10):2380-2386.^,³⁰30 Bolzon G, Boukharouba T, Gabetta G, Elboujdaini M, Mellas M, eds. Integrity of Pipelines Transporting Hydrocarbons - Corrosion Mechanisms Control and Management. Dordrecht: Springer Publishing, 2011.^,⁴⁰40 Arzola-Peralta S, Genescá Llongueras J, Palomar-Pardavé M, Romero-Romo M. Study of the electrochemical behaviour of a carbon steel electrode in sodium sulfate aqueous solutions using electrochemical impedance spectroscopy. Journal of Solid State Electrochemistry. 2003;7(5):283-288. and also observed in the present study, this behavior can be ascribed to the precipitation of a thick dark-colored film of iron sulfide acting as a barrier against diffusion processes. However, due to its low adhesion properties and the electrolyte aggressiveness, although increasing, the impedances continued to be low. In addition, oscillation in the impedance values were verified, ascribed to the detachment of the corrosion products from the electrodes surface.

For all the studied conditions, the electrochemical tests showed that API 5L X80 steel presented lower corrosion resistance than the API 5L X65 steel. Thus, for each specific medium, the impedance modulus was inferior for this former material, which seems to be a consequence of the depolarization of the anodic reaction (Figure 11). However, Tafel extrapolation results, presented in Tables 3 and 4, indicated that, comparing the behavior in the same medium, i_corr is only slightly superior for the X80 steel when compared with the X65. The microstructural characterization (Figures 1 and 2) clearly show higher number of inclusion in the microstructure of the API 5L X80, and this has been already discussed as a source of decreasing corrosion resistance. However, the SEM analysis of the etched microstructures, Figures 3 and 4, revealed the presence of pearlite only in the microstructure of the API 5L X65 steel. It is documented in the literature that a galvanic couple may exist between the cementite (cathodic) and the ferrite (anodic) regions in the lamellar structure of pearlite⁴¹41 Zhang F, Pan J, Lin C. Localized corrosion behavior of reinforcement steel in simulated concrete pore solution. Corrosion Science. 2009;51(9):2130-2138., this would contribute to enhance the corrosion activity of this latter steel. Therefore, it is hypothesized that while increased number of inclusions contributes to decrease the corrosion resistance of the API 5L X80 steel, the presence of pearlite increases the corrosion susceptibility of the API 5L X65 steel, explaining why there is only a slight difference between the corrosion behavior of the two materials. Finally, in agreement with all the other experimental results, the Tafel extrapolation procedure showed that, for the two tested materials, a tenfold increase in i_corr was verified when the electrolyte was saturated with H₂S.

4.3 Hydrogen Induced Cracking (HIC)

HIC tests were performed according to the NACE TM 0284-2011¹⁹19 Davani RKZ, Miresmaelli R, Soltanmohammadi M. Effect of thermomechanical parameters on mechanical properties of base metal and heat affected zone of X65 pipeline steel weld in the presence of hydrogen. Materials Science and Engineering: A. 2018;718:135-146. standard in the solution A saturated with H₂S. The results showed that the API 5L X65 steel is not susceptible to Hydrogen Induced Cracking (HIC) in the sour gas environment. Thus, neither initiation nor propagation of cracks were detected in the samples submitted to the HIC test. On the other hand, samples of the API 5L X80 steel presented severe cracks in all examined internal surfaces, which were deep and relatively wide in the central and lower parts of the pipe thickness (Figure 15).

As verified in the microstructural characterization, the API 5L X80 steel presented inclusions in greater quantity, some of them with irregular shape, rich in S, Mn. Due to their tendency to accumulate hydrogen and to concentrate stress, ⁶6 Kawashima A, Hashimoto K, Shimodaira S. Hydrogen Electrode Reaction and Hydrogen Embrittlement of Mild Steel in Hydrogen Sulfide Solutions. Corrosion. 1976;32(8):321-331.^,⁷7 Gray JM, Siciliano F. High Strength Microalloyed Linepipe: Half a Century of Evolution. Houston: Microalloyed Steel Institute; 2009. p. 20-45.^,⁹9 Haq AJ, Muzaka K, Dunne DP, Calka A, Pereloma EV. Effect of microstructure and composition on hydrogen permeation in X70 pipeline steels. International Journal of Hydrogen Energy. 2013;38(5):2544-2556.^,¹⁰10 Dong CF, Liu ZY, Li XG, Cheng YF. Effects of hydrogen-charging on the susceptibility on X100 pipeline steel to hydrogen-induced cracking. International Journal of Hydrogen Energy. 2009;34(24):9879-9884.^,³⁵35 Koh SU, Kim JS, Yang BY, Kim KY. Effect of Line Pipe Steel Microstructure on Susceptibility to Sulfide Stress Cracking. Corrosion. 2004;60(3):244-253. inclusions with larger size and irregular shape are detrimental to HIC resistance, as they act like irreversible hydrogen traps serving as points for nucleation of cracks. ²⁷27 Arzola S, Mendoza-Florez J, Duran-Romero R, Genesca J. Electrochemical Behavior of API X70 steel in Hydrogen Sulfide-Containing Solutions. Corrosion. 2006;62(5):433-443.

28 Lucio-Garcia MA, Gonzalez-Rodriguez JG, Casales M, Martinez L, Chacon-Nava JG, Neri-Flores MA, et al. Effect of heat treatment on H2S corrosion of a micro-alloyed C-Mn steel. Corrosion Science. 2009;51(10):2380-2386.

29 Huang F, Li XG, Liu J, Qu YM, Ji J, Du CW. Hydrogen-induced cracking susceptibility and hydrogen trapping efficiency of different microstructure X80 pipeline steels. Journal of Materials Science. 2011;46(3):715-722.^-³⁰30 Bolzon G, Boukharouba T, Gabetta G, Elboujdaini M, Mellas M, eds. Integrity of Pipelines Transporting Hydrocarbons - Corrosion Mechanisms Control and Management. Dordrecht: Springer Publishing, 2011. The SEM observation of the crack (Figure 15) showed the presence of a MnS inclusion in its propagation pathway, showing that such inclusions can play an important role in the susceptibility to HIC of the investigated API 5L X80 steel. Therefore, due to the low resistance to HIC in media containing H₂S, X80 steel is still not considered suitable for sour gas application.

5. Conclusions

In the present study, electrochemical techniques and standardized tests (NACE Standard TM 0284-2011) were used to compare the corrosion and HIC resistances of two API 5L steelsone API 5L X65 and the other API 5L X80. The following conclusions can be drawn:

The electrochemical tests showed that the two steels investigated showed low corrosion resistance in solution A (NACE TM0284-2011) (5% sodium chloride (NaCl) and 0.5% acetic acid (CH3COOH)), being the performance worsened in sour gas medium.
The results also showed that the corrosion resistance of the API 5L X80 steel is slightly inferior to that presented by the API 5L X65, which can be ascribed to the higher number of inclusions in its microstructure. However, its refined and more homogeneous microstructure (without pearlite) contributes to leveling its corrosion resistance to that of the API 5L X65 steel.
Impedance tests as a function of immersion time in sour medium pointed to a slight increase in corrosion resistance as the test proceeds, which was associated with the formation of a thick and non-adherent corrosion product layer (Fe and S), which, nevertheless, offers a barrier against the diffusion of aggressive species.
API 5L X80 steel showed susceptibility to HIC, a fact not verified for API 5L X65 steel. The presence of Mn- and S-rich inclusions in the crack propagation pathway confirms that these microstructural features also play an important role in HIC failure in HSLA steels. According to the results of the present investigation this is the main reason why the API 5L X80 steel investigated in this study cannot be recommended for sour application.

6. Acknowlodgements

J.M. Quispe-Avilés and H. G. de Melo are thankful to CBMM for supporting this research through the project: "Pesquisa e Desenvolvimento de Aços ARBL".

7. References

¹
Trench CJ, Kiefner JF; The U.S. Oil Pipeline Industry's Safety Performance. Oil Pipeline Characteristics and Risk Factors: Illustrations from the Decade of Construction Washington: American Petroleum Institute; 2001: 54 p.
²
API - American Petroleum Institute. API 5L. Specification for Line Pipe Washington: American Petroleum Institute; 2012. 12 p.
³
Koo JY, Luton MJ, Bangaru NV, Petkovic RA, Fairchild DP, Petersen CW, et al. Metallurgical Design of Ultra High-strength Steels for Gas Pipelines. International Journal of Offshore and Polar Engineering 2004;14(1):2-10.
⁴
Hashemi SH. Strength-hardness statistical correlation in API X65 steel. Materials Science and Engineering: A 2011;528(3):1648-1655.
⁵
Siciliano F, Stalheim DG, Gray MJ. Modern High Strength Steels for Oil and Gas Transmission Pipelines In: Proceedings of the 2008 7th International Pipeline Conference; 2008 Sep 29 - Oct 3; Calgary, AB, Canada. p. 187-195.
⁶
Kawashima A, Hashimoto K, Shimodaira S. Hydrogen Electrode Reaction and Hydrogen Embrittlement of Mild Steel in Hydrogen Sulfide Solutions. Corrosion 1976;32(8):321-331.
⁷
Gray JM, Siciliano F. High Strength Microalloyed Linepipe: Half a Century of Evolution Houston: Microalloyed Steel Institute; 2009. p. 20-45.
⁸
Guo Y, Yang S, Shang C, Wang Y, He X. Influence of carbon contend and microstructure on corrosion behavior of low alloy steels in Cl- containing environment. Corrosion Science 2009;51(2):242-251.
⁹
Haq AJ, Muzaka K, Dunne DP, Calka A, Pereloma EV. Effect of microstructure and composition on hydrogen permeation in X70 pipeline steels. International Journal of Hydrogen Energy 2013;38(5):2544-2556.
¹⁰
Dong CF, Liu ZY, Li XG, Cheng YF. Effects of hydrogen-charging on the susceptibility on X100 pipeline steel to hydrogen-induced cracking. International Journal of Hydrogen Energy 2009;34(24):9879-9884.
¹¹
Barbosa GL, Cândido LC, Toffolo VR, Soares BLE. Microstructure and Mechanical Properties of Two Api Steels for Iron Ore Pipelines. Rede Temática em Engenharia de Materiais - REDEMAT Universidade Federal de Ouro Preto 2014;17(1):114-120.
¹²
Fallahmohammadi E, Bolzoni F, Fumagalli G, Re G, Benassi G, Lazzari L. Hydrogen diffusion into three metallurgical microstructures of a C-Mn X65 and low alloy F22 sour service steel pipelines. International Journal of Hydrogen Energy 2014;39(25):13300-13313.
¹³
Kim SJ, Kim KY. A Review of Corrosion and Hydrogen Diffusion Behaviors of High Strength Pipeline Steel in Sour Environment. Journal of Welding and Joining 2014;32(5):13-20.
¹⁴
Mohtadi-Bonab MA, Eskandari M, Rahman KMM, Ouellet R, Szpunar JA. An extensive study of hydrogen-induced cracking susceptibility in an API X60 sour service pipeline steel. International Journal of Hydrogen Energy 2016;41(7):4185-4197.
¹⁵
Prasad K, Dwivedi DK. Some investigations on microstructure and mechanical properties of submerged arc welded HSLA steel joints. The International Journal of Advanced Manufacturing Technology 2008;36(5-6):475-483.
¹⁶
Qi YM, Luo HY, Zheng SQ, Chen CF, Wang DN. Effect of immersion time on the hydrogen content and tensile properties of A350LF2 steel exposed to hydrogen sulphide environments. Corrosion Science 2013;69:164-174.
¹⁷
API - American Petroleum Institute. Specifications for Line Pipe ANSI/API 5L Washington: American Petroleum Institute; 2007. 153 p.
¹⁸
Qi YM, Luo HY, Zheng SQ, Chen CF, Lv ZG, Xiong MX. Comparision of tensile and impact behavior of carbon steel in H2S environments. Materials & Design 2014;58:234-241.
¹⁹
Davani RKZ, Miresmaelli R, Soltanmohammadi M. Effect of thermomechanical parameters on mechanical properties of base metal and heat affected zone of X65 pipeline steel weld in the presence of hydrogen. Materials Science and Engineering: A 2018;718:135-146.
²⁰
Zhao W, Yang M, Zhang T, Deng Q, Jiang W, Jiang W. Study on hydrogen enrichment in X80 steel spiral welded pipe. Corrosion Science 2018;133:251-260.
²¹
Liu Q, Zhou Q, Venezuela J, Zhang M, Atrens A. The role of the microstructure on the influence of hydrogen on some advanced high-strength steels. Materials Science & Engineering A 2018;715:370-378.
²²
ASTM International. ASTM E112-13 - Standard Test Methods for Determining Average Grain Size West Conshohocken: ASTM International; 2013.
²³
ASTM International. ASTM E45-13 - Standard Test Methods for Determining the Inclusion Content of Steel West Conshohocken: ASTM International; 2013.
²⁴
ASTM International. ASTM G106-89(2010) - Standard Practice for Verification of Algorithm and Equipment for Electrochemical Impedance Measurements West Conshohocken: ASTM International; 2010.
²⁵
NACE International. NACE Standard TM0284-2011- Evaluation of Pipeline and Pressure Vessel Steels for Resistance to Hydrogen-Induced Cracking Houston: NACE International; 2011.
²⁶
Stern M, Geary AL. Electrochemical Polarization I. A Theoretical Analysis of the Shape of Polarization Curves. Journal of the Electrochemical Society 1957;104(1):56-63.
²⁷
Arzola S, Mendoza-Florez J, Duran-Romero R, Genesca J. Electrochemical Behavior of API X70 steel in Hydrogen Sulfide-Containing Solutions. Corrosion 2006;62(5):433-443.
²⁸
Lucio-Garcia MA, Gonzalez-Rodriguez JG, Casales M, Martinez L, Chacon-Nava JG, Neri-Flores MA, et al. Effect of heat treatment on H2S corrosion of a micro-alloyed C-Mn steel. Corrosion Science 2009;51(10):2380-2386.
²⁹
Huang F, Li XG, Liu J, Qu YM, Ji J, Du CW. Hydrogen-induced cracking susceptibility and hydrogen trapping efficiency of different microstructure X80 pipeline steels. Journal of Materials Science 2011;46(3):715-722.
³⁰
Bolzon G, Boukharouba T, Gabetta G, Elboujdaini M, Mellas M, eds. Integrity of Pipelines Transporting Hydrocarbons - Corrosion Mechanisms Control and Management Dordrecht: Springer Publishing, 2011.
³¹
Hladky K, Dawson JL. The measurement of corrosion using electrochemical 1f noise. Corrosion Science 1982;22(3):231-237.
³²
Jin TY, Cheng YF. In-situ characterization by localized electrochemical impedance spectroscopy of the electrochemical activity of microscopic inclusions in an X100 steel. Corrosion Science 2011;53(2):850-853.
³³
Huang H, Shaw WJD, Yen SK, Huang IB. Hydrogen Embrittlement Interactions in Cold-Worked Steel. Corrosion 1995;51(1):30-36.
³⁴
Hincapie-Ladino D, Falleiros NA. Trincamento induzido por hidrogênio em aços microligados. Tecnologia em Metalurgia, Materiais e Mineração 2015;12(1):82-93.
³⁵
Koh SU, Kim JS, Yang BY, Kim KY. Effect of Line Pipe Steel Microstructure on Susceptibility to Sulfide Stress Cracking. Corrosion 2004;60(3):244-253.
³⁶
Chen X, Li X, Du C, Liang P. Effects of solution environments on corrosion behaviors of X70 steels under simulated disbonded coating. Journal of Chinese Society for Corrosion and Protection 2010;30(1):35-40.
³⁷
Wang H, Shaw WJD. Cold work effects on sulfide stress cracking of pipeline steel exposed to sour environments. Corrosion Science 1993;34(1):61-68.
³⁸
Zheng SQ, Qi YM, Chen CF, Li SY. Effect of hydrogen and inclusions on the tensile properties and fracture behaviour of A350LF2 steels after exposure to wet H2S environments. Corrosion Science 2012; 60:59-68.
³⁹
Sourmail T. A review of the effect of cold work on resistance to sulphide stress cracking In: Proceedings of Corrosion 2007; 2007 Mar 11-15; Nashville, TN, USA. Paper 07104.
⁴⁰
Arzola-Peralta S, Genescá Llongueras J, Palomar-Pardavé M, Romero-Romo M. Study of the electrochemical behaviour of a carbon steel electrode in sodium sulfate aqueous solutions using electrochemical impedance spectroscopy. Journal of Solid State Electrochemistry 2003;7(5):283-288.
⁴¹
Zhang F, Pan J, Lin C. Localized corrosion behavior of reinforcement steel in simulated concrete pore solution. Corrosion Science 2009;51(9):2130-2138.
⁴²
Wang P, Lv Z, Zheng S, Qi Y, Wang J, Zheng Y. Tensile and impact properties of X70 pipeline steel exposed to wet H2S environments. International Journal of Hydrogen Energy 2015:40(1):11514-11521.

Publication Dates

Publication in this collection
07 Jan 2019
Date of issue
2019

History

Received
13 Mar 2018
Reviewed
29 Aug 2018
Accepted
14 Nov 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Trench CJ, Kiefner JF; The U.S. Oil Pipeline Industry's Safety Performance. Oil Pipeline Characteristics and Risk Factors: Illustrations from the Decade of Construction Washington: American Petroleum Institute; 2001: 54 p.

[2] ²
API - American Petroleum Institute. API 5L. Specification for Line Pipe Washington: American Petroleum Institute; 2012. 12 p.

[3] ³
Koo JY, Luton MJ, Bangaru NV, Petkovic RA, Fairchild DP, Petersen CW, et al. Metallurgical Design of Ultra High-strength Steels for Gas Pipelines. International Journal of Offshore and Polar Engineering 2004;14(1):2-10.

[4] ⁴
Hashemi SH. Strength-hardness statistical correlation in API X65 steel. Materials Science and Engineering: A 2011;528(3):1648-1655.

[5] ⁵
Siciliano F, Stalheim DG, Gray MJ. Modern High Strength Steels for Oil and Gas Transmission Pipelines In: Proceedings of the 2008 7th International Pipeline Conference; 2008 Sep 29 - Oct 3; Calgary, AB, Canada. p. 187-195.

[6] ⁶
Kawashima A, Hashimoto K, Shimodaira S. Hydrogen Electrode Reaction and Hydrogen Embrittlement of Mild Steel in Hydrogen Sulfide Solutions. Corrosion 1976;32(8):321-331.

[7] ⁷
Gray JM, Siciliano F. High Strength Microalloyed Linepipe: Half a Century of Evolution Houston: Microalloyed Steel Institute; 2009. p. 20-45.

[8] ⁸
Guo Y, Yang S, Shang C, Wang Y, He X. Influence of carbon contend and microstructure on corrosion behavior of low alloy steels in Cl- containing environment. Corrosion Science 2009;51(2):242-251.

[9] ⁹
Haq AJ, Muzaka K, Dunne DP, Calka A, Pereloma EV. Effect of microstructure and composition on hydrogen permeation in X70 pipeline steels. International Journal of Hydrogen Energy 2013;38(5):2544-2556.

[10] ¹⁰
Dong CF, Liu ZY, Li XG, Cheng YF. Effects of hydrogen-charging on the susceptibility on X100 pipeline steel to hydrogen-induced cracking. International Journal of Hydrogen Energy 2009;34(24):9879-9884.

[11] ¹¹
Barbosa GL, Cândido LC, Toffolo VR, Soares BLE. Microstructure and Mechanical Properties of Two Api Steels for Iron Ore Pipelines. Rede Temática em Engenharia de Materiais - REDEMAT Universidade Federal de Ouro Preto 2014;17(1):114-120.

[12] ¹²
Fallahmohammadi E, Bolzoni F, Fumagalli G, Re G, Benassi G, Lazzari L. Hydrogen diffusion into three metallurgical microstructures of a C-Mn X65 and low alloy F22 sour service steel pipelines. International Journal of Hydrogen Energy 2014;39(25):13300-13313.

[13] ¹³
Kim SJ, Kim KY. A Review of Corrosion and Hydrogen Diffusion Behaviors of High Strength Pipeline Steel in Sour Environment. Journal of Welding and Joining 2014;32(5):13-20.

[14] ¹⁴
Mohtadi-Bonab MA, Eskandari M, Rahman KMM, Ouellet R, Szpunar JA. An extensive study of hydrogen-induced cracking susceptibility in an API X60 sour service pipeline steel. International Journal of Hydrogen Energy 2016;41(7):4185-4197.

[15] ¹⁵
Prasad K, Dwivedi DK. Some investigations on microstructure and mechanical properties of submerged arc welded HSLA steel joints. The International Journal of Advanced Manufacturing Technology 2008;36(5-6):475-483.

[16] ¹⁶
Qi YM, Luo HY, Zheng SQ, Chen CF, Wang DN. Effect of immersion time on the hydrogen content and tensile properties of A350LF2 steel exposed to hydrogen sulphide environments. Corrosion Science 2013;69:164-174.

[17] ¹⁷
API - American Petroleum Institute. Specifications for Line Pipe ANSI/API 5L Washington: American Petroleum Institute; 2007. 153 p.

[18] ¹⁸
Qi YM, Luo HY, Zheng SQ, Chen CF, Lv ZG, Xiong MX. Comparision of tensile and impact behavior of carbon steel in H2S environments. Materials & Design 2014;58:234-241.

[19] ¹⁹
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IDENTIFICATION	DIMENSIONS	(mm)	Rockwell
	Diameter	Thickness	Hardness
API 5L X65	813	21	183
API 5L X 80	508	20	294

Steel	C	Mn	Si	S	P	Ni	Cu	Cr	Al	Nb	V + Ti
X65	0.04	1.37	0.35	0.001	0.009	0.06	0.05	0.03	0.04	0.05	0.02
X80	0.07	1.79	0.33	0.001	0.012	0.002	0.013	0.164	0.0035	0.04	0.0017

Material	Condition	EcorrV vs. SCE	ba V dec. ^-1	bc V dec. ^-1	i_corr.(A.cm^-2)
X65 steel	Without H₂S	- 0.623	0.019	0.060	1.17 x 10^-5
X65 steel	With H₂S	- 0.648	0.019	0.060	1.98 x 10^-4
X80 steel	Without H₂S	-0.686	0.019	0.060	2.34 x 10^-5
X80 steel	With H₂S	-0.758	0.019	0.060	2.76 x 10^-4

	Condition	EcorrV vs. SCE	ba V dec. ^-1	bcV dec. ^-1	icorr (A.cm^-2)
X65 steel	With H₂S	- 0.632	0.018	0.059	2.26 x 10^-5
X80 steel	With H₂S	-0.763	0.018	0.059	3.08 x 10^-5

Brasil

Brasil

A Comparative Investigation of the Corrosion Resistance and HIC Suceptibility of API 5L X65 and API 5L X80 Steels

Abstract

1. Introduction

2. Materials and Methods

2.1 Materials

2.2 Microstructural characterization

2.3 Electrochemical tests and corrosion morphology evaluation

2.4 Hydrogen Induced Cracking (HIC) experiments

3. Results

3.1 Analysis of inclusions and microstructural characterization

3.2 Electrochemical tests

3.2.1 Electrochemical behavior - deaerated and H₂S saturated solution - Procedure 1

3.2.2 Electrochemical behavior in H₂S saturated solution (24h) - sour medium - Procedure 2

3.2.3 Microstructural characterization after 24h immersion in H₂S-saturated solution - sour medium - Procedure 2

3.3 Hydrogen Induced Cracking (HIC) tests

4. Discussion

4.1 Inclusions analysis and microstructural characterization

4.2 Electrochemical tests and corrosion morphology

4.3 Hydrogen Induced Cracking (HIC)

5. Conclusions

6. Acknowlodgements

7. References

Publication Dates

History

Brasil

Brasil

A Comparative Investigation of the Corrosion Resistance and HIC Suceptibility of API 5L X65 and API 5L X80 Steels

Abstract

1. Introduction

2. Materials and Methods

2.1 Materials

2.2 Microstructural characterization

2.3 Electrochemical tests and corrosion morphology evaluation

2.4 Hydrogen Induced Cracking (HIC) experiments

3. Results

3.1 Analysis of inclusions and microstructural characterization

3.2 Electrochemical tests

3.2.1 Electrochemical behavior - deaerated and H2S saturated solution - Procedure 1

3.2.2 Electrochemical behavior in H2S saturated solution (24h) - sour medium - Procedure 2

3.2.3 Microstructural characterization after 24h immersion in H2S-saturated solution - sour medium - Procedure 2

3.3 Hydrogen Induced Cracking (HIC) tests

4. Discussion

4.1 Inclusions analysis and microstructural characterization

4.2 Electrochemical tests and corrosion morphology

4.3 Hydrogen Induced Cracking (HIC)

5. Conclusions

6. Acknowlodgements

7. References

Publication Dates

History

3.2.1 Electrochemical behavior - deaerated and H₂S saturated solution - Procedure 1

3.2.2 Electrochemical behavior in H₂S saturated solution (24h) - sour medium - Procedure 2

3.2.3 Microstructural characterization after 24h immersion in H₂S-saturated solution - sour medium - Procedure 2