Proposed paper dealt with the modelling and analysis of induction motor based on the mathematical expression using the graphical programming environment of Laboratory Virtual Instrument Engineering Workbench (LabVIEW). Induction motor modelling with the mathematical expression enables the motor to be simulated with the various required parameters. Owing to the invention of variable speed drives study about the induction motor characteristics became complex. In this simulation motor internal parameter such as stator resistance and reactance, rotor resistance and reactance, phase voltage, frequency and losses will be given as input. By varying the speed of motor corresponding parameters can be obtained they are input power, output power, efficiency, torque induced, slip and current.
[1] R. K. Rajput, “Electrical Machines,” first edition, New York: McGraw-
Hill, 1993, pp. 352-353.
[2] R. Krishnan, “Electric Motor Drives Modeling, Analysis and Control”,
first edition, Prentice-Hall International, Inc. Upper Saddle River, New
Jersey 07458, 2001, pp 400 - 415.
[3] R. Gunabalan, S. Immanuel Prabakaran, J. Reegan, and S. Ganesh
“Simulation of inverter fed induction motor drive with LabVIEW”
International Journal of Electrical, Robotics Electronics and
Communications Engineering vol:8, no:1, pp:91-95, 2014.
[4] Gentian dume “Synchronous generator model based on LabVIEW
software”, WSEAS Transactions on Advances in Engineering Education
vol:10 pp: 101-112, 2013.
[5] R. A. Jabbar, Azah Mohamed, M.A. Hannan, Muhammad Junaid, M.
Mansoor, A. Latif and H. Noor, Simulation of electrical machines
laboratory using LabVIEW”, International Conference on Computer,
Electrical, and Systems Science, and Engineering, World Academy of
Science Engineering and Technology pp:29-31, 2010.
[6] Abdenour Soualhi, Guy Clerc, and Hubert Razik, “Detection and
diagnosis of faults in induction motor using an improved artificial ANT
clustering technique” IEEE Transactions on Industrial Electronics, Vol.
60, pp: 4053 – 4062, 2013.
[7] M. Aderiano da Silva, J. Richard Povinelli, and A.O Nabeel Demerdash
“Rotor bar fault monitoring method based on analysis of air-gap torques
of induction motors” IEEE Transactions on Industrial Informatics, Vol.
9, pp: 2274 – 2283, 2013.
[8] Bogdan Virlan, Seifeddine Benelghali, Alecsandru Simion, Leonard
Livadaru, Rachid Outbib, and Adrian Munteanu, “Induction motor with
outer rotor and ring stator winding for multispeed applications” IEEE
Transactions on Energy Conversion, Vol. 28, pp: 999 – 1007, 2013.
[9] L. Daniel Ransom and Randy Hamilton, “Extending motor life with
updated thermal model overload protection” IEEE Transactions on
Industry Applications, Vol. 49, pp: 2471 – 2477, 2013.
[10] Gianmario Pellegrino, Alfredo Vagati, Barbara Boazzo, and Paolo
Guglielmi, “Comparison of induction and pm synchronous motor drives
for ev application including design examples”, IEEE Transactions on
Industry Applications, vol. 48, pp: 2322 – 2332, 2012.
[11] N. Konstantinos Gyftakis, V. Dionysios Spyropoulos, C. Joya Kappatou
and D. Epaminondas Mitronikas, “A novel approach for broken bar fault
diagnosis in induction motors through torque monitoring” IEEE
Transactions on Energy Conversion, vol. 28, pp: 267 – 277, 2013.
[12] Lu´ıs Alberto Pereira, C´esar Cataldo Scharlau, Lu´ıs Fernando Alves
Pereira, and S´ergio Haffner, “Influence of saturation on the airgap
induction waveform of five-phase induction machines” IEEE
Transactions on energy Conversion, vol. 27,pp: 29 – 41, 2012.
[13] Pinjia Zhang, Yi Du, G. Thomas Habetler, and Bin Lu, “A nonintrusive
winding heating method for induction motor using soft starter for
preventing moisture condensation” IEEE Transactions on Industry
Applications, vol. 48, pp: 117 – 123, 2012.
[14] E.Ramprasath, P.Manojkumar, Modelling and Analysis of Induction
Motor using LabVIEW, International Journal of Power Electronics and
Drive System (IJPEDS) Vol. 5, No. 3, February 2015, pp. 344~354.
[1] R. K. Rajput, “Electrical Machines,” first edition, New York: McGraw-
Hill, 1993, pp. 352-353.
[2] R. Krishnan, “Electric Motor Drives Modeling, Analysis and Control”,
first edition, Prentice-Hall International, Inc. Upper Saddle River, New
Jersey 07458, 2001, pp 400 - 415.
[3] R. Gunabalan, S. Immanuel Prabakaran, J. Reegan, and S. Ganesh
“Simulation of inverter fed induction motor drive with LabVIEW”
International Journal of Electrical, Robotics Electronics and
Communications Engineering vol:8, no:1, pp:91-95, 2014.
[4] Gentian dume “Synchronous generator model based on LabVIEW
software”, WSEAS Transactions on Advances in Engineering Education
vol:10 pp: 101-112, 2013.
[5] R. A. Jabbar, Azah Mohamed, M.A. Hannan, Muhammad Junaid, M.
Mansoor, A. Latif and H. Noor, Simulation of electrical machines
laboratory using LabVIEW”, International Conference on Computer,
Electrical, and Systems Science, and Engineering, World Academy of
Science Engineering and Technology pp:29-31, 2010.
[6] Abdenour Soualhi, Guy Clerc, and Hubert Razik, “Detection and
diagnosis of faults in induction motor using an improved artificial ANT
clustering technique” IEEE Transactions on Industrial Electronics, Vol.
60, pp: 4053 – 4062, 2013.
[7] M. Aderiano da Silva, J. Richard Povinelli, and A.O Nabeel Demerdash
“Rotor bar fault monitoring method based on analysis of air-gap torques
of induction motors” IEEE Transactions on Industrial Informatics, Vol.
9, pp: 2274 – 2283, 2013.
[8] Bogdan Virlan, Seifeddine Benelghali, Alecsandru Simion, Leonard
Livadaru, Rachid Outbib, and Adrian Munteanu, “Induction motor with
outer rotor and ring stator winding for multispeed applications” IEEE
Transactions on Energy Conversion, Vol. 28, pp: 999 – 1007, 2013.
[9] L. Daniel Ransom and Randy Hamilton, “Extending motor life with
updated thermal model overload protection” IEEE Transactions on
Industry Applications, Vol. 49, pp: 2471 – 2477, 2013.
[10] Gianmario Pellegrino, Alfredo Vagati, Barbara Boazzo, and Paolo
Guglielmi, “Comparison of induction and pm synchronous motor drives
for ev application including design examples”, IEEE Transactions on
Industry Applications, vol. 48, pp: 2322 – 2332, 2012.
[11] N. Konstantinos Gyftakis, V. Dionysios Spyropoulos, C. Joya Kappatou
and D. Epaminondas Mitronikas, “A novel approach for broken bar fault
diagnosis in induction motors through torque monitoring” IEEE
Transactions on Energy Conversion, vol. 28, pp: 267 – 277, 2013.
[12] Lu´ıs Alberto Pereira, C´esar Cataldo Scharlau, Lu´ıs Fernando Alves
Pereira, and S´ergio Haffner, “Influence of saturation on the airgap
induction waveform of five-phase induction machines” IEEE
Transactions on energy Conversion, vol. 27,pp: 29 – 41, 2012.
[13] Pinjia Zhang, Yi Du, G. Thomas Habetler, and Bin Lu, “A nonintrusive
winding heating method for induction motor using soft starter for
preventing moisture condensation” IEEE Transactions on Industry
Applications, vol. 48, pp: 117 – 123, 2012.
[14] E.Ramprasath, P.Manojkumar, Modelling and Analysis of Induction
Motor using LabVIEW, International Journal of Power Electronics and
Drive System (IJPEDS) Vol. 5, No. 3, February 2015, pp. 344~354.
@article{"International Journal of Information, Control and Computer Sciences:69869", author = "E. Ramprasath and P. Manojkumar and P. Veena", title = "Induction Motor Analysis Using LabVIEW", abstract = "Proposed paper dealt with the modelling and analysis of induction motor based on the mathematical expression using the graphical programming environment of Laboratory Virtual Instrument Engineering Workbench (LabVIEW). Induction motor modelling with the mathematical expression enables the motor to be simulated with the various required parameters. Owing to the invention of variable speed drives study about the induction motor characteristics became complex. In this simulation motor internal parameter such as stator resistance and reactance, rotor resistance and reactance, phase voltage, frequency and losses will be given as input. By varying the speed of motor corresponding parameters can be obtained they are input power, output power, efficiency, torque induced, slip and current.
", keywords = "Induction motor, LabVIEW software, modelling and
analysis, electrical and mechanical characteristics of motor.", volume = "9", number = "5", pages = "1158-4", }
