This paper presents a Mobile Hall Sensor Array system for the shape detection of ferromagnetic materials that are embedded in walls or floors. The operation of the Mobile Hall Sensor Array system is based on the principle of magnetic flux leakage to describe the shape of the ferromagnetic material. Two permanent magnets are used to generate the magnetic flux flow. The distribution of magnetic flux is perturbed as the ferromagnetic material is brought near the permanent magnets and the changes in magnetic flux distribution are detected by the 1-D array of the Hall sensor array setup. The process for magnetic imaging of the magnetic flux distribution is done by a signal processing unit before it displays the real time images using a netbook. A signal processing application software is developed for the 1-D Hall sensor array signal acquisition and processing to construct a 2-D array matrix. The processed 1-D Hall sensor array signals are later used to construct the magnetic image of ferromagnetic material based on the voltage signal and the magnetic flux distribution. The experimental results illustrate how the shape of specimens such as square, round and triangle shapes is determined through magnetic images based on the voltage signal and magnetic flux distribution of the specimen. In addition, the magnetic images of actual ferromagnetic objects are also illustrated to prove the functionality of Mobile Hall Sensor Array system for actual shape detection. The results prove that the Mobile Hall Sensor Array system is able to perform magnetic imaging in identifying various ferromagnetic materials.
References
[1]
Jun, J.; Choi, M.; Lee, J.; Seo, J.; Shin, K. Nondestructive testing of express train wheel using the linearly integrated Hall sensors array on a curved surface. NDT E Int 2011, 44, 449–455.
[2]
Hwang, J.; Lee, J.; Kwon, S. The application of a differential-type Hall sensors array to the nondestructive testing of express train wheels. NDT E Int 2009, 42, 34–41.
[3]
Donato, P.G.; Ure?a, J.; Mazo, M.; de Marziani, C.; Ochoa, A. Design and signal processing of a magnetic sensor array for train wheel detection. Sens. Actuat. A 2006, 132, 516–525.
[4]
Gasparics, A.; Vertesy, G.; Farkas, T.; Szollosy, J. Magnetic imaging in non-destructive testing. Proceedings of the 2nd International Conference on Mechanical and Electrical Technology (ICMET), Singapore, 10–12 September 2010; pp. 47–49.
[5]
Hwang, J.; Kim, J.; Lee, J. Magnetic image of surface crack on heated specimen using an array-type magnetic camera with high spatial resolution. Proceedings of the International Instrumentation and Measurement Technology Conference (I2MTC), Singapore, 5–7 May 2009; pp. 1546–1551.
[6]
Jun, J.; Hwang, J.; Lee, J. Quantitative non-destructive evaluation of the crack on the austenite stainless steel using the induced eddy current and the Hall sensor array. Proceedings of the Instrumentation and Measurement Technology Conference (IMTC), Warsaw, Poland, 1–3 May 2007; pp. 1–6.
[7]
Lee, J.; Hwang, J.; Jun, J.; Choi, S. Nondestructive testing and crack evaluation of ferromagnetic material by using the linearly integrated Hall sensor array. J. Mech. Sci. Technol 2008, 22, 2310–2317.
[8]
Yang, L.; Liu, G.; Zhang, G.; Gao, S. Sensor development and application on the oil-gas pipeline magnetic flux leakage detection. Proceedings of the 9th International Conference on Electronic Measurement and Instruments (ICEMI), Beijing, China, 16–19 August 2009; pp. 2876–2878.
[9]
Li, X.; Li, X.; Chen, L.; Qin, G.; Feng, P.; Huang, Z. Steel pipeline testing using magnetic flux leakage method. Proceedings of the IEEE International Conference on Industrial Technology (ICIT), Chengdu, China, 21–24 April 2008; pp. 1–4.
[10]
Chen, J.; Li, L.; Xu, B. Magnetic flux leakage testing method for well casing based on gaussian kernel RBF neural network. Proceedings of the International Conference on Advanced Computer Theory and Engineering (ICACTE), Phuket, Thailand, 20–22 December 2008; pp. 228–231.
[11]
Cao, Y.N.; Zhang, D.L.; Wang, C.; Gu, Y.; Xu, D.G. A novel electromagnetic method for local defects inspection of wire rope. Proceedings of the IEEE Region 10 Conference (TENCON), Hong Kong, 14–17 November 2006; pp. 1–4.
[12]
Dimitropoulos, P.D.; Avaritsiotis, J.N. A 2-D ferrous object imaging technique based on magnetic field sensor arrays. Sens. Actuat. A 2003, 106, 336–339.
[13]
Choi, S.D.; Kim, S.W.; Kim, G.W.; Ahn, M.C.; Kim, M.S.; Hwang, D.G.; Lee, S.S. Development of spatial pulse diagnostic apparatus with magnetic sensor array. J. Magn. Magn. Mater 2007, 310, 983–985.
[14]
Norhisam, M.; Norrimah, A.; Wagiran, R.; Sidek, R.M.; Mariun, N.; Wakiwaka, H. Consideration of theoretical equation for output voltage of linear displacement sensor using meander coil and pattern guide. Sens. Actuat. A 2008, 147, 470–473.
[15]
Chen, X.; Ding, T. Flexible eddy current sensor array for proximity sensing. Sens. Actuat. A 2007, 135, 126–130.
[16]
Kim, W.; Kim, J.E.; Kim, Y.Y. Magnet configuration maximizing the sensitivity and linearity of a magnetic rotation sensor. Sens. Actuat. A 2009, 151, 100–106.
[17]
K?hler, S.; Sawitzki, S.; Gratz, A.; Spallek, R.G. Digital Signal Processing with General Purpose Microprocessors, DSP and Reconfigurable Logic, CiteSeerX. 1999, Available online: http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.48.1438 (accessed on 5 September 2011).
[18]
Barkdull, J.N.; Douglas, S.C. General-purpose microprocessor performance for DSP applications. Proceedings of the 30th Asilomar Conference on Signals, Systems and Computer, Pacific Grove, CA, USA, 3–6 November 1996; pp. 912–916.
