Title :
Temperature compensation and scalability of hysteretic/anhysteretic magnetic-property sensors
Author :
Lloyd, George M. ; Singh, Varsha ; Wang, Ming L. ; Hovorka, Ondrej
Author_Institution :
Dept. of Civil & Mater. Eng., Univ. of Illinois, Chicago, IL, USA
Abstract :
Non-destructive/noncontact stress sensors based on magnetoelastic principles have numerous applications for monitoring cable stress. However, their widespread use is hampered by problems related to temperature compensation and to scaling of calibration data to large cables, which is the domain of greatest interest. In this paper, experimental magnetic property and thermal response data are obtained and analyzed to address these problems. The magnetic property data include initial curves, major hysteresis loops, and anhysteresis curves, all obtained quasistatically. The thermal response data are presented in the form of a dimensionless correlation which is valid over a range of Reynolds numbers. Comparison of data indicates the feasibility of using absolute magnetic property measurements as the basis for direct calibration of large sensors.
Keywords :
compensation; magnetic hysteresis; magnetic sensors; magnetic variables measurement; magnetoelastic effects; stress measurement; thermal variables measurement; Reynolds numbers; absolute magnetic property measurements; anhysteresis curves; anhysteretic sensors; cable stress monitoring; calibration data scaling; dimensionless correlation; hysteretic sensors; large sensor calibration; magnetic variables measurement; magnetic-property sensors; magnetoelastic principles; magnetoelasticity; major hysteresis loops; noncontact stress sensors; nondestructive stress sensors; scalability; temperature compensation; thermal response data; thermal variables measurement; Cables; Calibration; Magnetic domains; Magnetic hysteresis; Magnetic properties; Magnetic sensors; Monitoring; Scalability; Temperature sensors; Thermal stresses;
Journal_Title :
Sensors Journal, IEEE
DOI :
10.1109/JSEN.2003.820325
