Assessment of Stress-Strain State of Pipelines Based on the Measurements of Magnetic Characteristics in Field Conditions

作者: Myznov K.E.¹, Vasilenko O.N.¹, Kostin V.N.¹, Tronza V.S.², Bondina A.N.², Kukushkin S.S.², Tryakina N.Y.², Salomatin A.S.²
隶属关系:
1. M.N. Mikheev Institute of Metal Physics of Ural Branch of Russian Academy of Sciences
2. Gazprom Transgas Yekaterinburg LLC
期: 编号 12 (2024)
页面: 69-80
栏目: Electromagnetic methods
URL: https://archivog.com/0130-3082/article/view/649291
DOI: https://doi.org/10.31857/S0130308224120068
ID: 649291

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A series of measurements on two pipeline sections made of 17G1S (17Г1С) steel using two measuring devices: magnetic multitester MMT-3 and magnetic analyser of structure KRM-C-K2M (КРМ-Ц-К2М) has been carried out. Maps of coercive force, residual magnetic induction and maximum magnetic induction on the pipes were obtained. The coefficient of loading for different cross-sections of the pipeline was calculated. Dependence of magnetic characteristics averaged over the cross-section on the coefficient of loading is plotted. It is revealed that the most dangerous for destruction cross-sections, in which the coefficient of loading exceeded the critical value of 1,2, correspond to the reduced values of coercive force and residual magnetic induction, obtained in the direction of measurement along the pipeline axis. It is shown that measurement along the axis at the top of the pipeline shows a similar relationship as for the cross-sectional averaged values, which means that in pipeline aerial crossings, measurement only at the top of the pipeline may be sufficient.

关键词

stress-strain state, pipe, pipeline, aerial crossing, magnetic method, nondestructive testing

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作者简介

K. Myznov

M.N. Mikheev Institute of Metal Physics of Ural Branch of Russian Academy of Sciences

编辑信件的主要联系方式.
Email: myznov@imp.uran.ru
俄罗斯联邦, Yekaterinburg

O. Vasilenko

M.N. Mikheev Institute of Metal Physics of Ural Branch of Russian Academy of Sciences

Email: vasilenko@imp.uran.ru
俄罗斯联邦, Yekaterinburg

V. Kostin

M.N. Mikheev Institute of Metal Physics of Ural Branch of Russian Academy of Sciences

Email: kostin@imp.uran.ru
俄罗斯联邦, Yekaterinburg

V. Tronza

Gazprom Transgas Yekaterinburg LLC

Email: myznov@imp.uran.ru
俄罗斯联邦, Yekaterinburg

A. Bondina

Gazprom Transgas Yekaterinburg LLC

Email: myznov@imp.uran.ru
俄罗斯联邦, Yekaterinburg

S. Kukushkin

Gazprom Transgas Yekaterinburg LLC

Email: myznov@imp.uran.ru
俄罗斯联邦, Yekaterinburg

N. Tryakina

Gazprom Transgas Yekaterinburg LLC

Email: myznov@imp.uran.ru
俄罗斯联邦, Yekaterinburg

A. Salomatin

Gazprom Transgas Yekaterinburg LLC

Email: myznov@imp.uran.ru
俄罗斯联邦, Yekaterinburg

参考

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Recommendations on assessment of strength and stability of operated gas mains and pipelines of compressor stations / Effective as of 24 November 2006. Moscow: Gazprom VNIIGAZ, 2007. 42 p.
SNiP (Building Codes and Regulations) 2.05.06-85. Trunk pipelines, Moscow: FGUP TSPP, 2005, 60 p.
SP (Set of Rules) 36.13330.2012. Trunk pipelines, Moscow: Gosstroy, 2013. 93 p.
Zakharov V.A., Ul'yanov A.I., Gorkunov E.S. Coercive force of ferromagnetic steels under the biaxial symmetrical tension of a material // Russian Journal of Nondestructive Testing. 2011. V. 47. No. 6. P. 359—368.
Bezlyud'ko G.Y., Sirona V.E., Solomakha R.N., Savluk S.V., Siviruk V.L. Coercimetry for stress-stain and fatigue state monitoring of blast furnace shell // NDT World. 2021. V. 24. No. 3. P. 32—35.
Bezlyud'ko G.Y., Muzhitskii V.F., Remezov V.B. Series of portable structuroscope-instruments based on measuring the coercive force // Russian Journal of Nondestructive Testing. 2003. V. 39. No. 4. P. 43—51.
IEC 60404-4 Magnetic materials — Part 4: Methods of measurement of d.c. magnetic properties of magnetically soft materials.
Gorkunov E.S., Mushnikov A.N. Magnetic methods of evaluating elastic stresses in ferromagnetic steels (review) // Testing. Diagnostics. 2020. V. 23. No. 12. P. 4—23.
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Andronov I.N., Aginei R.V., Leonov I.S. Analysis of the plane stress state of steel pipelines by the radar charts of the coercivity // Industrial Laboratory. Diagnostics of Materials. 2013. V. 79. No. 12. P. 50—52.
Stashkov A.N., Schapova E.A., Nichipuruk A.P., Korolev A.V. Magnetic incremental permeability as indicator of compression stress in low-carbon steel // NDT & E International. 2021. V. 118. P. 102398.
Schapova E.A., Stashkov A.N., Tsar'kova T.P., Sazhina E.Y., Kochnev A.V. The comparison of two data processing techniques of magnetic method for elastic compressive stress determination // AIP Conference Proceedings: The VI International Young Researchers Conference Physics, Technologies Innovation, Ekaterinburg, May 20–23, 2019 / Ural Federal University. V. 2174. Ekaterinburg: American Institute of Physics, 2019. P. 020167.
Kostin V.N., Vasilenko O.N., Byzov A.V. DIUS-1.15M Mobile Hardware–Software Structuroscopy System // Russian Journal of Nondestructive Testing. 2018. V. 54. No. 9. P. 654—661.
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2. Fig. 1. Diagram of the elevated crossing ‘A’

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3. Fig. 2. Diagram of the elevated crossing ‘B’

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4. Fig. 3. Simplified diagram of the pipe without showing welds

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5. Fig. 4. MMT-3 magnetic multitester

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6. Fig. 5. KPM-C-K2M magnetic structuroscope

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7. Fig. 6. Distribution (topograms) of the maximum magnetic induction on pipes ‘A’ (a, c) and ‘B’ (b, d) measured along the axis (a, b) and ring (c, d) using MMT-3

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8. Fig. 7. Distribution (topograms) of the coercive force on pipes ‘A’ (a, c) and ‘B’ (b, d) measured along the axis (a, b) and ring (c, d) using MMT-3

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9. Fig. 8. Distribution (topograms) of residual magnetic induction on pipes ‘A’ (a, c) and ‘B’ (b, d) measured along the axis (a, b) and ring (c, d) using MMT-3

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10. Fig. 9. Distribution (topograms) of the coercive force on pipes ‘A’ (a, c) and ‘B’ (b, d) measured along the axis (a, b) and ring (c, d) with the help of KPM-C-K2M

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11. Fig. 10. Dependence of coercive force averaged over four zones in the pipe cross-section measured with MMT-3 along the axis (a) and along the ring (b) on the loading factor

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12. Fig. 11. Dependence of the residual magnetic induction averaged over four zones in the pipe cross-section measured with MMT-3 along the axis (a) and along the ring (b) on the loading factor

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13. Fig. 12. Dependence of the coercive force averaged over four zones in the pipe cross-section, measured by KPM-C-K2M along the axis (a) and along the ring (b), on the loading factor

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14. Fig. 13. Dependence of values of coercive force (a) and residual magnetic induction (b) averaged over four zones in the pipe cross-section, measured with MMT-3 along the axis, on fibre stresses

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15. Fig. 14. Dependence of values of coercive force (a) and residual magnetic induction (b) measured with MMT-3 along the axis in the zones located at 12 h on the loading factor

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16. Fig. 15. Dependence of values of coercive force (a) and residual magnetic induction (b) measured with MMT-3 along the axis in the zones located at 12 h on fibre stresses

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