1. bookVolume 52 (2022): Issue 1 (March 2022)
Journal Details
License
Format
Journal
eISSN
2083-4608
First Published
26 Feb 2008
Publication timeframe
4 times per year
Languages
English
access type Open Access

Influence of the Crane Load and Measurement Speed on the Properties of the Magnetic Field of the Girders

Published Online: 13 Apr 2022
Volume & Issue: Volume 52 (2022) - Issue 1 (March 2022)
Page range: 151 - 166
Journal Details
License
Format
Journal
eISSN
2083-4608
First Published
26 Feb 2008
Publication timeframe
4 times per year
Languages
English
Abstract

The girders of the crane or the jib of the crane are situated at high heights, which prevents the free and continuous measurement of their stresses. Unfortunately, these elements are most exposed to high stress and damage during their use. The article presents the research methodology with the use of the magnetic metal memory method of the overhead crane girders. Diagnostic tests utilizing the crane movement mechanisms to move the magnetometric sensor along the tested surface of the girder were proposed to improve and automate measurements. The article attempts to investigate effect of the device load and speed of Hp measurements with a magnetometric sensor.

Keywords

1. Bao S., Fu M., Hu S., Gu Y., Huangjie L.: A review of the metal magnetic memory technique. ASME 2016 35th Busan, South Korea 2016.10.1115/OMAE2016-54269 Search in Google Scholar

2. Bao S., Lou H., Zhao Z.: Evaluation of stress concentration degree of ferromagnetic steels based on residual magnetic field measurements. J Civ Struct Heal Monit. 2020.10.1007/s13349-019-00372-5 Search in Google Scholar

3. Dubov A.A.: Detection of Metallurgical and Production Defects in Engineering Components Using Metal Magnetic Memory. Metallurgist, 2015.10.1007/s11015-015-0078-5 Search in Google Scholar

4. Dubov A., Kolokolnikov S.: Assessment of the material state of oil and gas pipelines based on the metal magnetic memory method. Weld World, 2012.10.1007/BF03321331 Search in Google Scholar

5. Huang H., Yao J., Li Z., Liu Z.: Residual magnetic field variation induced by applied magnetic field and cyclic tensile stress. NDT E Int. 2014.10.1016/j.ndteint.2014.01.003 Search in Google Scholar

6. Juraszek J.: Residual magnetic field non-destructive testing of gantry cranes. Materials. 2019.10.3390/ma12040564641662030769792 Search in Google Scholar

7. Kolokolnikov S.M., Dubov A.A., Marchenkov A.Y.: Determination of mechanical properties of metal of welded joints by strength parameters in the stress concentration zones detected by the metal magnetic memory method. Weld World, 2014.10.1007/s40194-014-0151-x Search in Google Scholar

8. Kosoń A., Szpytko J.: Investigation of the Impact of Loadon the Magnetic Field Strength of the Crane by the Magnetic Metal Memory Technique. Materials, 2020. Search in Google Scholar

9. Kosoń-Schab A., Szpytko J.: Magnetic metal memory in the assessment of the technical condition of crane girders for the needs of safety. Journal of Konbin, Vol. 49, Iss. 4, 2020, DOI 10.2478/jok-2019-0075.10.2478/jok-2019-0075 Search in Google Scholar

10. Kosoń-Schab A., Smoczek J., Szpytko J.: Magnetic Memory Inspection of an Overhead Crane Girder – Experimental Verification. Journal of KONES, 2019.10.2478/kones-2019-0034 Search in Google Scholar

11. Li Z., Dixon S., Cawley P., Jarvis R., Nagy P.B.: Study of metal magnetic memory (MMM) technique using permanently installed magnetic sensor arrays. AIP Conf Proc., 2017.10.1063/1.4974689 Search in Google Scholar

12. Li J., Xu M., Leng J., Xu M.: Modeling plastic deformation effect on magnetization in ferromagnetic materials. J Appl Phys, 2012.10.1063/1.3695460 Search in Google Scholar

13. Liu B., He L-y., Zhang H., Cao Y., Fernandes H.: The axial crack testing model for long distance oil-gas pipeline based on magnetic flux leakage internal inspection method, Measurement, 2017, DOI: 10.1016/j.measurement.2017.02.051.10.1016/j.measurement.2017.02.051 Search in Google Scholar

14. Roskosz M., Bieniek M.: Evaluation of residual stress in ferromagnetic steels based on residual magnetic field measurements. NDT E Int, 2012.10.1016/j.ndteint.2011.09.007 Search in Google Scholar

15. Roskosz M., Gawrilenko P.: Analysis of changes in the residual magnetic field in loaded notched samples. NDT E Int, 2008.10.1016/j.ndteint.2008.04.002 Search in Google Scholar

16. Shi P.: Magneto-mechanical model of ferromagnetic material under a constant weak magnetic field via analytical anhysteresis solution. J Appl Phys, 2020.10.1063/5.0012580 Search in Google Scholar

17. Shi P., Su S., Chen Z.: Overview of Researches on the Nondestructive Testing Method of Metal Magnetic Memory: Status and Challenges. J Nondestruct Eval, 2020.10.1007/s10921-020-00688-z Search in Google Scholar

18. Wang Z.D., Deng B., Yao K.: Physical model of plastic deformation on magnetization in ferromagnetic materials. J Appl Phys, 2011.10.1063/1.3574923 Search in Google Scholar

19. Vlasov V.T., Dubov A.A.: Physical Bases of the Metal Magnetic Memory Method. ZAO “TISSO”, Moscow 2004. Search in Google Scholar

20. Villegas-Saucillo J., Díaz-Carmona J.J., Cerón-Álvarez C.A., et al.: Measurement system of metal magnetic memory method signals around rectangular defects of a ferromagnetic pipe. Appl Sci, 2019.10.3390/app9132695 Search in Google Scholar

21. Zhang K., Zhang J., Jin W., Mao J., Xu Y., Li Q.: Characterization of fatigue crack propagation of pitting-corroded rebars using weak magnetic signals. Eng Fract Mech, 2021.10.1016/j.engfracmech.2021.108033 Search in Google Scholar

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