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Abstract:

The goal of cathodic protection is to prevent corrosion by maintaining buried pipelines at a constant potential with respect to the surrounding soil. In practice, however, the implementation is very complicated since many factors can contribute to the current flowing off the pipe. Design requires characterization of the parameters impacting the corrosion process, such as soil resistivity, size of the pipe and quality of the coating. In the present paper, we have studied the effect of geomagnetic fields on the pipe-induced currents considering it as an additional cause of corrosion. A theoretical method implemented to model the induced currents was tested in a previous work and the effect during disturbed days was quantified. This theoretical model indicated that the intensity of the current induced in a pipeline by the varying geomagnetic field depends on the intensity and rate of change of the field and the electrical resistivity of the soil. This induced current is in equilibrium with the host current and there is no current drainage between the pipeline and the host until, along the length of the pipeline, the host resistivity becomes different. At that point, current must flow between the pipe and host in order to establish a new equilibrium. It is this drainage current, flowing between the pipeline and the host, which causes corrosion problems. Following these results, experimental tests were performed in Tierra del Fuego. In this zone, a geophysical study was made to determine the discontinuities in soil resistivities and simultaneous measurements of the geomagnetic field and the drainage of current were recorded at different sites. The results obtained from the correlation of the data are consistent with the theoretical predictions. (C) 2000 Elsevier Science B.V. All rights reserved. The goal of cathodic protection is to prevent corrosion by maintaining buried pipelines at a constant potential with respect to the surrounding soil. In practice, however, the implementation is very complicated since many factors can contribute to the current flowing off the pipe. Design requires characterization of the parameters impacting the corrosion process, such as soil resistivity, size of the pipe and quality of the coating. In the present paper, we have studied the effect of geomagnetic fields on the pipe-induced currents considering it as an additional cause of corrosion. A theoretical method implemented to model the induced currents was tested in a previous work and the effect during disturbed days was quantified. This theoretical model indicated that the intensity of the current induced in a pipeline by the varying geomagnetic field depends on the intensity and rate of change of the field and the electrical resistivity of the soil. This induced current is in equilibrium with the host current and there is no current drainage between the pipeline and the host until, along the length of the pipeline, the host resistivity becomes different. At that point, current must flow between the pipe and host in order to establish a new equilibrium. It is this drainage current, flowing between the pipeline and the host, which causes corrosion problems. Following these results, experimental tests were performed in Tierra del Fuego. In this zone, a geophysical study was made to determine the discontinuities in soil resistivities and simultaneous measurements of the geomagnetic field and the drainage of current were recorded at different sites. The results obtained from the correlation of the data are consistent with the theoretical predictions.

Registro:

Documento: Artículo
Título:Effects of soil resistivity on currents induced on pipelines
Autor:Osella, A.; Favetto, A.
Ciudad:Amsterdam, Netherlands
Filiación:Departamento de Física, Fac. Cie. Exact. Y Nat., Univ. B., Buenos Aires, Argentina
Palabras clave:Cathodic protection; Corrosion in pipelines; Telluric effects in pipelines; Cathodic protection; Electric conductivity of solids; Geomagnetism; Magnetic field effects; Mathematical models; Pipelines; Telluric effects; Soil mechanics; corrosion control; electric current; pipeline protection; corrosion; electrical conductivity; pipeline protection
Año:2000
Volumen:44
Número:4
Página de inicio:303
Página de fin:312
DOI: http://dx.doi.org/10.1016/S0926-9851(00)00008-2
Título revista:Journal of Applied Geophysics
Título revista abreviado:J. Appl. Geophys.
ISSN:09269851
CODEN:JAGPE
Registro:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09269851_v44_n4_p303_Osella

Referencias:

  • Boteler, D.H., Cookson, M.J., Telluric currents and their effects on pipelines in the Cook Strait region of New Zealand (1986) Mater. Perfom., 25 (3), pp. 27-32
  • Caminos, R., Cordillera Fueguina (1980) Geología Regional Argentina, 2, pp. 1463-1501. , Argentina: Acad. Nac. Cienc. Córdoba
  • Campbell, W.H., An interpretation of induced electric currents in long pipelines caused by natural geomagnetic sources of the upper atmosphere (1986) Surv. Geophys., 8, pp. 239-259
  • Duhau, S., Osella, A.M., Description of the coastal effect at equatorial latitudes with applications to the Peruvian and Nigerian zones (1984) Planet. Space Sci., 32 (7), pp. 845-851
  • D'Yakonov, B.P., The diffraction of electromagnetic waves by a circular cylinder in a homogeneous half-space (1959) Izv., Acad. Sci. URSS Geophys., 9, pp. 950-955
  • Favetto, A., Osella, A., Numerical simulation of currents induced by geomagnetic storms on buried pipelines. An application to the Tierra del Fuego, Argentina, gas transmission route (1999) IEEE Geosci. Remote Sens., 37, 1 (PART 2), pp. 614-619
  • Feliú, S., Andrade, M.C., Corrosión y protección metálicas (1991) C.S.I.S., 1. , Madrid
  • Howard, A.Q., The electromagnetic fields of a subterranean cylindrical inhomogeneity excited by a line source (1972) Geophysics, 37, pp. 975-984
  • Jupp, D.L., Vozoff, K., Stable iterative methods for the inversion of geophysical data (1975) Geophys. J. R. Astron. Soc., 42, pp. 957-976
  • Martin, B.A., Telluric effects on a buried pipeline (1993) Corrosion, 49 (4), pp. 343-350
  • Osella, A., Favetto, A., López, E., Corrosion effects on buried pipelines due to geomagnetic storms (1998) J. Appl. Geophys., 38, pp. 219-233
  • Osella, A., Favetto, A., Martinelli, P., Cernadas, D., Electrical imaging of an alluvial aquifer at the Antinaco-Los Colorados tectonic valley in the Sierras Pampeanas, Argentina (1999) J. Appl. Geophys., 41 (4), pp. 359-368
  • Osella, A., Martinelli, P., Cernadas, D., 2D Geoelectrical Modeling using Rayleigh-Fourier method (2000) IEEE Geosci. Remote Sens., 38, p. 3
  • Wait, J.R., The cylindrical ore body in the presence of a cable carrying an oscillating current (1952) Geophysics, 17, pp. 378-386

Citas:

---------- APA ----------
Osella, A. & Favetto, A. (2000) . Effects of soil resistivity on currents induced on pipelines. Journal of Applied Geophysics, 44(4), 303-312.
http://dx.doi.org/10.1016/S0926-9851(00)00008-2
---------- CHICAGO ----------
Osella, A., Favetto, A. "Effects of soil resistivity on currents induced on pipelines" . Journal of Applied Geophysics 44, no. 4 (2000) : 303-312.
http://dx.doi.org/10.1016/S0926-9851(00)00008-2
---------- MLA ----------
Osella, A., Favetto, A. "Effects of soil resistivity on currents induced on pipelines" . Journal of Applied Geophysics, vol. 44, no. 4, 2000, pp. 303-312.
http://dx.doi.org/10.1016/S0926-9851(00)00008-2
---------- VANCOUVER ----------
Osella, A., Favetto, A. Effects of soil resistivity on currents induced on pipelines. J. Appl. Geophys. 2000;44(4):303-312.
http://dx.doi.org/10.1016/S0926-9851(00)00008-2