Abstract

The transport capacity of the slurry pipelines is related to the internal roughness of the pipe. Thus, the application of corrosion protection methods is of fundamental importance, both in the operational phase and in times of temporary shutdown. In addition, corrosion also affects the service life of the duct. The studied pipeline was hibernated with nitrogen using the ABNT NBR 15280-2 standard as a reference and remained hibernated for 3.5 years. Chemical, mineralogical, and microstructural analyses were carried out on samples of materials removed from the pipeline interior during the hibernation period. The most striking phase found was magnetite, with botrioidal morphology, formed by the oxidation of steel in the pipeline. After reactivation, the pipeline was inspected by smart pigs with ultrasound and MFL technologies. It was found that the corroded regions are more concentrated in the initial kilometers of the sections, where important depths of corrosion were also observed, as well as higher rates of corrosion and erosion, which show the influence of the operational phase in the development of the pipeline corrosive process and wear. Thus, the application of the nitrogen hibernation process in long-distance pipelines proved to be feasible for long periods of time. However, improvements are suggested in this article to make the process more robust.

Keywords:
corrosion; pipeline; hibernation; nitrogen

1. Introduction

Buried pipelines are subjected to external and internal corrosion. External corrosion can be corrosion induced by microorganisms (Liu et al., 2021LIU, B.; SUN, M.; LU, F.; DU, C; LI, X. Study of biofilm-influenced corrosion on X80 pipeline steel by a nitrate-reducing bacterium, Bacillus cereus, in artificial Beijing soil. Colloids and Surfaces B: biointerfaces, v. 197,111356,2021.), generated by stray currents (Peng et al., 2020PENG, X.; HUANG, Z.; CHEN, B.; LIU, D.; LI, H. On the interference mechanism of stray current generated by DC tram on pipeline corrosion. Engineering Failure Analysis, v. 116, 104760, 2020.), or induced by other aggressive factors (Liu et al., 2019LIU, A.; CHEN, K.; HUANG, X.; CHEN, J.; JIANFENG ZHOU, J.; XU, W. Corrosion failure probability analysis of buried gas pipelines based on subset simulation. Journal of Loss Prevention in the Process Industries, v. 57, p. 25-33, 2019.). Considering the internal corrosion, the transports capacity of pipelines is related to the internal pipe roughness (Mattioli et al., 2018MATTIOLI, G. G.; MARTINS, A. F.; LINS, V. F. C; BRANDÃO, P. R. G.; TORRES, A. S. G. Evaluation of internal corrosion in a Brazilian iron ore slurry pipeline based on the characterization of scales and tubercles. REM -International Engineering Journal, v.71, n. 2, p. 203-208, 2018. http://dx.DOI.org/10.1590/0370-44672017710073
http://dx.DOI.org/10.1590/0370-446720177... ). In this sense, the internal corrosion of the ducts plays an important role since it increases the roughness and reduces the capacity of the system, by increasing the friction factor (Taylor etal, 2006TAYLOR, J. B.; CARRANO, A. L.; KANDLIKAR, S. G. Characterization of the effect of surface roughness and texture on fluid flow-past, present, and future. International Journal of Thermal Sciences, v. 45, p. 962-968, 2006. DOI:10.1016/j.ijthermalsci.2006.01.004
https://doi.org/10.1016/j.ijthermalsci.2... ; Díaz-Damacillo & Plascencia, 2019DÍAZ-DAMACILLO, L.; PLASCENCIA, G. A new six parameter model to estimate the friction factor. American Institute of Chemical Engineers Journal, v. 65, p. 1144-1148, 2019. DOI:10.1002/aic.l6535
https://doi.org/10.1002/aic.l6535... ). In addition to the reduction in transport capacity, corrosion also affects the life cycle of the pipelines due to the reduction in the wall thickness of the tubes. The potential for damage that corrosion causes to the pipeline is increased by synergism with the erosion caused by the slurry displacement (Islam & Farhat, 2017ISLAM, Md. A.; FARHAT, Z. N. Erosion-corrosion mechanism and comparison of erosion-corrosion performance of API steels. Wear, v. 376-377, p. 533-541, 2017 http://dx.DOI.Org/10.1016/j.wear.2016.12.058
http://dx.DOI.Org/10.1016/j.wear.2016.12... ; Elemuren et al., 2018ELEMUREN, R.; EVITTS,R.; OGUOCHA, I.; KENNELL, G.; GERSPACHER, B. R.; ODESHIA, A. Slurry erosion-corrosion of 90° AISI 1018 steel elbow in saturated potash brine containing abrasive silica particles. Wear, v. 410-411, p. 149-155, 2018. https://DOI.Org/10.1016/j.wear.2018.06.010
https://DOI.Org/10.1016/j.wear.2018.06.0... ; Aguirre & Walczak, 2018AGUIRRE, J.; WALCZAK, M. Multifactorial study of erosion-corrosion wear of a X65 steel by slurry of simulated copper tailing. Tribology International, v. 126, p. 177-185, 2018. https://DOI.Org/10.1016/j.triboint.2018.04.029
https://DOI.Org/10.1016/j.triboint.2018.... ). At certain times during the operational phase, the temporary shutdown of a pipeline may be necessary for legal or strategic reasons. To minimize internal corrosion in the stopped lines, two hibernation methodologies can be applied: filling the duct with water treated with inhibitors and biocides; and filling the duct with nitrogen gas (Lins et al., 2016LINS, V. F. C; LAGE, F. C; CASTRO, M. M. R.; COSTA, C. G. F.; MATENCIO, T. Strategies for corrosion inhibition of slurry pipelines prior to commissioning. REM - International Engineering Journal, v. 69, n. 2, p. 161-166, 2016. http://dx.DOI.org/10.1590/0370-44672015690084.
http://dx.DOI.org/10.1590/0370-446720156... ). Studies on the hibernation process in slurry pipelines that have already operated are scarce in literature. Hibernation studies with treated water before the start operations have already been carried out (Lins et al., 2016LINS, V. F. C; LAGE, F. C; CASTRO, M. M. R.; COSTA, C. G. F.; MATENCIO, T. Strategies for corrosion inhibition of slurry pipelines prior to commissioning. REM - International Engineering Journal, v. 69, n. 2, p. 161-166, 2016. http://dx.DOI.org/10.1590/0370-44672015690084.
http://dx.DOI.org/10.1590/0370-446720156... ). In the case of the hibernation process with nitrogen injection, in the oil and gas industries, there are Brazilian regulations for conditioning the pipelines during the construction and assembly phase (ABNT NBR 15280-2:2015ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. ABNT NBR 15280-2: onshore pipeline, parte 2: construction and installation. 2015. 96 p. ISBN 978-85-07-05935-6.). Both techniques have already been applied to a mining company in Brazil. The choice of each methodology was carried out according to risk and environmental analyses. In the case of nitrogen hibernation, the choice considers that a possible leak of the gas into the environment would not result in significant environmental impacts, being the most environmentally friendly method. This article aims to present a case study on the application of nitrogen hibernation in a long-distance pipeline, with approximately 400 kilometers in length, which transports iron ore slurry. To our best knowledge, there is no report in literature on this topic.

2. Materials and methods

The nitrogen hibernation method was applied to the slurry pipeline. Corrosion products removed from the inside of the duct were submitted to laboratory analysis. After the nitrogen hibernation period, in-line inspections were performed with smart pigs to detect corrosions. Using the results of the smart pig inspections, it was possible to evaluate the corrosive process during the nitrogen hibernation period.

The inside of the pipeline was hibernated with injected nitrogen gas, remaining in this condition for 3.5 years. The criteria for considering a duct hibernated with nitrogen were taken from the Brazilian standard ABNT NBR 15280-2, highlighting the following items: dew point temperature in 0°C (1 atm); oxygen content less than 5%; and gas pressure larger than or equal to 49 kPa.

Material samples were removed from inside the pipeline by smart pigs, and were analyzed in order to access their chemical and mineralogical compositions. The overall sample had a particle size between 0.038 mm and 0.85 mm. The chemical analysis was made by the wet method through the dichromatometry technique for Fe₂O₃, while FeO; CaO, SiO₂, Al₂O₃, P and MnO₂ were analyzed by atomic emission spectroscopy with inductive coupled plasma (ICPAES). The atomic emission spectrometer used was the Ciros, CCD model. Iron contents were converted from Fe to Fe₂O₃. Loss on ignition (LOI) was determined by calcination in an oven and the consequent weight difference. Polished sections were prepared for microscopic studies, using impregnation with epoxy resin. Only diamond pastes were used in the final polishing step with loose abrasives. Samples were pulverized in a pot mill and then analyzed by X-ray diffraction and X-ray fluorescence spectrometry. The X-ray diffractometer used was Philips (Panalytical) for powder samples, with an X'Pert-APD system, PW 3710/31 controller, with a Cu anode. The X-ray fluorescence spectrometer used was Philips (Panalytical), PW 2400 model, having an Rh anode. The microstructure studies were carried out by scanning electron microscopy (SEM) dual, with field emission gun (FEG) from FEI, Dual-FIB Quanta 3D model, with energy-dispersive X-ray spectrometry (EDS) from BRUKER, Nano X Flash Detector 5010 model, software Esprit. Backscattered electrons (BSE) images are always shown in this study. A very thin film of carbon was deposited on the polished samples to promote the surface's electrical conduction.

The pipeline was inspected with smart pigs assembled with ultrasound and MFL (Magnetic Flux Leakage) tools. Corrosion along the pipeline was evaluated for its distribution, the relationship of these distributions, and the pipeline elavation profile was verified. To carry out the corrosion rate calculations, the design wall thickness and the remaining wall thickness measured with smart pigs were used, since only one pig inspection was performed. The pipeline operated for 7 years before being hibernated. Thus, erosion rate calculations were also performed.

3. Results

The materials removed from the inside of the pipeline were characterized and the results of the chemical analysis are shown in Table 1.

The mineralogical composition was defined with the support of the chemical composition, since it was not possible to quantify the phases identified by X-ray diffraction, since the results using the Rietveld-based method would not be reliable, due to the low degree of crystallinity of all mineral phases. Thus, a conciliation with chemical analysis was not viable, due to insufficiency and redundancy of data. However, the estimation of the abundance of phases, compared with the respective chemical analysis, is reliable, although semiquantitative. In addition to the intensity of the peaks in the diffractograms, the abundance of magnetite is confirmed by the clear degree of magnetism observed in macroscopic samples. Table 2 shows the results obtained by using the X-ray diffraction and X-ray fluorescence spectrometry tests in terms of quantification levels and phase abundance, respectively.

The microstructure results are of typical tubercles, showing individual differences. Figure 1 shows three fragments of tubercles, which present a predominantly botryoidal texture, with moderate presence of large sub-millimeter pores, but with several smaller ones.

Looking in detail at the tubercle fragment at the bottom of the image in Figure 1 (red box region), there is a clear botryoidal fabric in the median region. Virtually all microstructural features are secondary, that is, they are products of corrosion, as can be seen in Figure 2, where Ms and Hs are respectively, regions of magnetite and hematite, both secondary with generally botryoidal morphology, Po is the region of a pore and R is the impregnation resin.

Applying an enlargement of the tubercle in Figure 2 (red box region), parallel concentric bands of magnetite and hematite were identified, both secondary, as shown in Figure 3.

Figures 4 and 5 show details of other analyzed tubercles. Figure 4 shows botrioidal texture, with alternating bands of magnetite and hematite, both secondary, with grains of goethite (Go), also. Figure 5 shows a pore, partially filled with aggregate and containing a calcite grain (Ca). Aggregates are made up of secondary and primary particles cemented by calcite.

The analysis of the corrosion results was carried out separately for the two sections of the pipeline. In this article, only the results for section 1 are presented, as the pattern of results was the same as that observed in section 2. Figure 6 shows the corroded regions and the elevation profile along the pipeline length for section 1.

Figure 7 shows the extension magnitude of corroded regions and the elevation profile along the length of the pipeline for section 1.

Figure 8 shows the o'clock positions of the corroded regions along the length of the pipeline in section 1.

The o'clock positions of 03:00, 06:00, 09:00 and 12:00 hours indicate, respectively, the right, bottom, left and top generatrices of the pipe.

Figure 9 shows the corrosion rates along the pipeline.

Figure 10 shows the erosion rates across the entire pipeline.

The corrosion rate calculation was performed considering the minimum wall thicknesses found for each pipe, and the erosion rate calculation was performed considering the most measured value of wall thickness per pipe.

4. Discussion

Using a microstructural analysis, with the support of chemical and mineralogical analyses by X-ray diffraction, it was found that the most important phase is magnetite, with botrioidal morphology, rarely massive; this phase is the main cause of the ferromagnetic property of the materials removed from the pipeline and examined in this study. This magnetite is formed by the oxidation of steel in the pipeline tube; it should be noted that the natural magnetite, that is, originally present in the transported concentrates, is very seldomly found; thus, almost all the magnetite analyzed comes from corrosion and is called secondary. Hematite is the second phase in abundance. A minor part of the hematite, certainly, comes from the iron ore concentrate (primary); however, in the case of the studied sample, the major fraction of the hematite has originated from the oxidation of the steel, being, therefore, secondary. Only by using microstructural analysis, mainly by the botryoidal morphology, it is possible to distinguish primary from secondary hematite. The mineral goethite shows the same ambiguity of origin as hematite, with the complication that goethite is almost always botryoidal. The main criterion for distinction is using microstructure analysis, by the intimate occurrence of goethite in the structure of the tubercle. The calcite phase is derived entirely from the calcium hydroxide added to the concentrate. A vast majority of the studied particles are composed of tubercles; in the current sample practically all the particles studied are fragments, even in the coarsest particle size fraction. Tubercles are composed essentially of steel corrosion products and include varying amounts of fine ore and usually fine calcite, derived from calcium hydroxide carbonation.

Corroded regions are more concentrated in the initial kilometers of the sections, as presented in Figure 6, that is, after the pumping stations. A higher percentage of corroded regions was observed in the first 23 kilometers; this amount reduces but is still considerable up to 46 kilometers. At three other points, the quantities of corroded regions can be highlighted, between kilometers 68 and 78 more significantly, between 85 and 109 and between 130 and 140, in lesser quantity. In these three points, a similar behavior is observed. The erosion is in the bottom regions of the profile, which may be an indication that there was an accumulation of moisture in these places, favoring the development of corrosive processes. The extension magnitude of corroded regions along the length of the pipeline was analyzed.

The analysis of the results presented in Figure 7 showed that the extension of the corroded regions, as expected, was higher where there are higher densities of corroded regions. However, it was possible to observe that, in certain kilometers, even with a low density of corroded regions, the extension of the corroded region was higher than expected, showing that the corrosions, individually, affected a larger area. Despite this, it was not possible to establish a direct relationship between the extension magnitude of corroded regions and the elevation profile along the length of the pipeline.

Figure 8 shows that in section 1, the corroded regions are more evenly distributed along the circumference of the pipe at the beginning; as the distance increases, these regions are concentrated around the 3:00 and 9:00 o'clock axes. This happens until approximately km 135, and from then on, the corroded regions become more evenly distributed. The uniform distribution at the beginning of the section can be explained by the large availability of oxygen in the period that the pipeline was in operation. The apparent decrease in density of the corroded regions at the 6 o'clock position is caused by the abrasive action of the slurry in that position. Thus, the erosive process is predominant in relation to the corrosive process.

The results of the corrosion rates presented in Figure 9 shows that the corrosion rates are higher at the beginning of the sections, after the pumping stations at km 0 and km 153, but decreasing along the stretch, showing that the corrosive process is mainly related to oxygen dissolved in the water pumped during the operational phase. At the beginning, the rate is higher and as oxygen is consumed along the pipe, the rates showing a downward trend. This downward trend is more pronounced in the stretch between km 153 and km 274, compared to the stretch between km 0 and km 153.

Analyzing the erosion results, shown in Figure 10, it is observed that the erosion rates are higher at the beginning of the sections, km 0 and km 153, showing a downward trend along the stretch. The rates are considerably higher at the beginning of section 2 (km 153) until close to km 183. In this section, during the operational phase, the largest head losses of the system were recorded, which cause a reduction in the flow rates in the discharge of the pump station located at km 153, since the system is limited in the discharge pressure of the pumps. Thus, the minimum deposit velocity may not be reached, particle deposition may occur and the formation of beds at the bottom of the pipe will be more accentuated. If fixed beds are formed, corrosion may occur under the deposits and, if they are mobile, the erosion process will be favored. This situation could explain the higher erosion rates in this stretch. Another important point regarding the beginning of the sections is the synergistic effect of the corrosive and erosive processes.

5. Conclusions

The application of the nitrogen hibernation process in long-distance pipelines proved to be feasible for long periods of time.

Corroded regions are more concentrated in the initial kilometers of the sections, that is, after the pumping stations, highlighting the influence of the operational phase in the development of the corrosive process, due to the oxygen dissolved in the water, and not because of failures in the process of hibernation with nitrogen. Another factor that corroborates this point of view is that the greatest corrosion depth and corrosion rates, for the most part, are located in these initial kilometers.

It was not possible to establish a correlation between the corroded regions with the elevation profile of the pipe, but a certain pattern of concentration of corroded regions was observed at bottom points of the elevation profile in certain sections of the pipe. Regarding the distributions of the corroded regions along the pipe circumference, at the beginning of the sections, they were uniform and as the distance from the beginning increased, these corroded regions tended to concentrate around the 3 and 9 o'clock axes. The decrease in density of the corroded regions at the 6 o'clock position is caused by the abrasive action of the slurry in that position. Thus, the erosive process is predominant in relation to the corrosive process.

The characterization of the corrosion product by microstructural analysis, with the support of chemical and mineralogical analyses by X-ray diffraction, presents magnetite as the predominant phase, with botrioidal morphology. This magnetite is formed by the oxidation of steel of the pipeline; it should be noted that the natural magnetite, that is, originally present in the transported concentrates, is quite low; thus, almost all the magnetite analyzed comes from corrosion.

The tubercles removed from the inside of the pipeline are composed essentially of corrosion products of steel and include varying amounts of fine ore and generally very fine calcite, derived from the carbonation of calcium hydroxide used in the process.

To ensure quality and efficiency in the application of the nitrogen hibernation process, more monitoring points of the parameters along the pipeline must be defined, in addition to the points located at the ends of the stretches. Acceptance criteria should also be established that consider the moisture values measured directly inside the duct. The possibility of reaching the nitrogen hibernation criteria at the monitoring points was observed, but due to the long distance between these points, pockets of moisture may have been trapped in the pipeline and the parameters were lost very quickly, requiring a gas exchange.

References

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