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Friday, 31 May 2019

Solar Powered Based Water Pumping System Using Perturb and Observation MPPT Technique



ABSTRACT:

This paper concentrates on solar photovoltaic(PV) water pumping system using perturb and observation maximum power point tracking(MPPT) technique. This whole system is divided into two stages. In the first stage, an arrangement of PV modules is made which is a combination of number PV cells in series or parallel to extract the solar energy and convert into electricity. To maximize the power output of PV module, perturb and observation (P&O) MPPT technique has been used. In its second stage, direct torque and flux control(DTFC) with space vector modulation(SVM) is used to control switching pulses of the voltage source inverter(VSI). The speed of induction motor drive is controlled by DTFC technique. The whole system is developed in MATLAB and outputs are observed.

KEYWORDS:

1.      Solar PV array
2.      MPPT
3.      P&O Algorithm
4.      DC-DC Boost converter
5.      DTFC-SVM
6.      Induction motor

SOFTWARE: MATLAB/SIMULINK

BLOCK DIAGRAM:






Fig-1: Solar Water Pumping System


 EXPECTED SIMULATION RESULTS:



Fig. 2. DC link voltage (output voltage of the boost converter)



Fig. 3. output waveform of IMD under no load


 Fig. 4. Waveforms under loading condition


CONCLUSION:

In this paper control methods which regulates the flow rate of water supply of solar powered based water pumping systen using IMD is illustrated. From the simulation results it can be concluded that this system has good performance. As per view of irrigation system , the SPV array has been operated under standard enviromental conditions. The system is operated on maximum power by using P&O MPPT algorithm. Water flow rate and stator current of motor is controlled by the speed PI controller.

 REFERENCES:

[1] U. Sharma, S. Kumar, and B. Singh, “Solar array fed water pumping system using induction motor drive,” 1st IEEE Int. Conf. Power Electron. Intell. Control Energy Syst. ICPEICES 2016, 2017.
[2] M. A. G. De Brito, L. P. Sampaio, L. G. Jr, G. A. Melo, and C. A. Canesin, “Comparative Analysis of MPPT Techniques for PV Applications,” pp. 99–104, 2011.
[3] D. P. Hohm, “Comparative Study of Maximum Power Point Tracking Algorithms Using an Experimental, Programmable, Maximum Power Point Tracking Test Bed,” 2000.
[4] S. Member, “A Comparative study of different MPPT techniques using different dc-dc converters in a standalone PV system,” pp. 1690–1695, 2016.
[5] Z. Ben Mahmoud, M. Ramouda, and A. Khedher, “A Comparative Study of Four Widely-Adopted MPPT Techniques for PV Power Systems,” no. 1, pp. 16–18, 2016.

Solar Power Based Three-Level Neutral Clamped Inverter Fed DTFC-SVM of an IM Drive



 ABSTRACT:

This paper presents a solar power based three-level neutral clamped inverter (3LNCI) fed induction motor drive (IMD) with space vector modulation based direct torque and flux control (DTFC-SVM) for the water pumping applications. Due to the robustness and the flexible operating characteristics, induction motor is most suitable for water pump system. A DC/DC boost converter along with perturb and observe method of maximum power point tracking (MPPT) control technique is employed to draw sophisticated power from the solar photovoltaic (PV) array. The DTFC-SVM of an IMD using 3LNCI is proposed for improving performance and reducing the ripple contents of torque, flux and stator currents. The proposed method is simulated in MATLAB/SIMULINK environment and simulated results are presented under various operating conditions.
KEYWORDS:

1.      Direct torque and flux control
2.      Induction motor drive
3.      Space vector modulation
4.      Three-level diode clamped inverter
5.      Photovoltaic array

SOFTWARE: MATLAB/SIMULINK

 BLOCK DIAGRAM:




Fig. 1. Schematic model of DTFC-SVM of IMD



 EXPECTED SIMULATION RESULTS:



Fig.2. Results under no-load torque operating condition using (a) 2LI and (b)
3LNCI: Plot (from top to bottom): (i) Torque, (ii) stator current, (iii) speed,
(iv) stator flux qd-components in stationary reference frame.



Fig.3. Loading performance at 1400rpm using (a) 2LI and (b) 3LNCI: (i)
Torque, (ii) speed, (iii) stator current and (iv) error speed.



Fig.4. Reversal speed Performance using (a) 2LI and (b) 3LNCI: (i) Torque,
(ii) speed, (iii) stator current and (iv) stator flux qd-components.


 CONCLUSION:

It has been concluded that the solar powered three-level neutral clamped inverter fed induction motor drive with DTFCSVM using proportional-integral controller (PIC) quite suitable for the water pumping applications. The solar panel has been operated at the peak values of voltage, current and power by using a simple perturb and observe method of MPPT algorithm, and the required DC output voltage achieved by using DC/DC boost converter. From the simulation results we can conclude that the three-level SVM based IM drives can provide better performance and torque ripple levels are also lowerd in comparision with Two- level SVM based IM drive.

REFERENCES:
[1] G. S Buja and Kazmierkowski. M. P, “DTC of pwm inverter-fed AC motors – A Survey”, IEEE Trans. on Ind. Elec., vol. 54, no. 5, pp. 744 – 757, 2004.
[2] J. Rodriguez, J. S. Lai, and F. Z. Peng, “Multilevel inverters: a survey of topologies, controls, and applications,” IEEE Trans. Ind. Electron., vol.49, no.4, pp.724-738, 2002.
[3] Tejavathu Ramesh, Anup Kumar Panda, and S. Shiva Kumar. "MRAS Speed Estimator Based on Type-1 and Type-2 Fuzzy Logic Controller for the Speed Sensorless DTFC-SVPWM of an Induction Motor Drive." Journal of Power Electr., vol. 15, No. 3, pp. 730-740, 2015.
[4] Rodriguez J, Bernet S, Steimer PK, Lizama IE. A survey on neutralpoint- clamped inverters. IEEE Transactions on Industrial Electronics. 57(7):2219-30, 2010.
[5] M. Hamdi, M. Hamouda, F. Fnaiech, and K. Al-Haddad, "Space vector pulse width modulation of multilevel inverters: A new method for selecting the appropriate small hexagon," 38th Annual Conf. IEEE Industrial Electronics Society (IECON), pp. 774-779, 25-28 Oct. 2012.


Thursday, 30 May 2019

BLDC Motor Driven Solar PV Array Fed WaterPumping System Employing Zeta Converter



 ABSTRACT:

This paper proposes a solar photovoltaic (SPV) array fed water pumping system utilizing a zeta converter as an intermediate DC-DC converter in order to extract the maximum available power from the SPV array. Controlling the zeta converter in an intelligent manner through the incremental conductance maximum power point tracking (INC-MPPT) algorithm offers the soft starting of the brushless DC (BLDC) motor employed to drive a centrifugal water pump coupled to its shaft. Soft starting i.e. the reduced current starting inhibits the harmful effect of the high starting current on the windings of the BLDC motor. A fundamental frequency switching of the voltage source inverter (VSI) is accomplished by the electronic commutation of the BLDC motor, thereby avoiding the VSI losses occurred owing to the high frequency switching. A new design approach for the low valued DC link capacitor of VSI is proposed. The proposed water pumping system is designed and modeled such that the performance is not affected even under the dynamic conditions. Suitability of the proposed system under dynamic conditions is demonstrated by the simulation results using MATLAB/Simulink software.

KEYWORDS:

1.      SPV array
2.      Zeta converter
3.      INC-MPPT
4.      BLDC motor
5.       Electronic commutation

SOFTWARE: MATLAB/SIMULINK

CIRCUIT DIAGRAM:






Fig.1 Configuration of proposed SPV array-Zeta converter fed BLDC motor drive for water pumping system.




EXPECTED SIMULATION RESULTS:




Fig.2 Performances of the proposed SPV array based Zeta converter fed BLDC motor drive for water pumping system (a) SPV array variables, (b) Zeta converter variables, and (c) BLDC motor-pump variables.



CONCLUSION:
The SPV array-zeta converter fed VSI-BLDC motor-pump for water pumping has been proposed and its suitability has been demonstrated by simulated results using MATLAB/Simulink and its sim-power-system toolbox. First, the proposed system has been designed logically to fulfil the various desired objectives and then modelled and simulated to examine the various performances under starting, dynamic and steady state conditions. The performance evaluation has justified the combination of zeta converter and BLDC motor drive for SPV array based water pumping. The system under study availed the various desired functions such as MPP extraction of the SPV array, soft starting of the BLDC motor, fundamental frequency switching of the VSI resulting in a reduced switching losses, reduced stress on IGBT switch and the components of zeta converter by operating it in continuous conduction mode and stable operation. Moreover, the proposed system has operated successfully even under the minimum solar irradiance.

REFERENCES:
[1] M. Uno and A. Kukita, “Single-Switch Voltage Equalizer Using Multi- Stacked Buck-Boost Converters for Partially-Shaded Photovoltaic Modules,” IEEE Transactions on Power Electronics, no. 99, 2014.
[2] R. Arulmurugan and N. Suthanthiravanitha, “Model and Design of A Fuzzy-Based Hopfield NN Tracking Controller for Standalone PV Applications,” Electr. Power Syst. Res. (2014). Available: http://dx.doi.org/10.1016/j.epsr.2014.05.007
[3] S. Satapathy, K.M. Dash and B.C. Babu, “Variable Step Size MPPT Algorithm for Photo Voltaic Array Using Zeta Converter – A Comparative Analysis,” Students Conference on Engineering and Systems (SCES), pp.1-6, 12-14 April 2013.
[4] A. Trejos, C.A. Ramos-Paja and S. Serna, “Compensation of DC-Link Voltage Oscillations in Grid-Connected PV Systems Based on High Order DC/DC Converters,” IEEE International Symposium on Alternative Energies and Energy Quality (SIFAE), pp.1-6, 25-26 Oct. 2012.
[5] G. K. Dubey, Fundamentals of Electrical Drives, 2nd ed. New Delhi, India: Narosa Publishing House Pvt. Ltd., 2009.

Direct Torque Control using Switching Table for Induction Motor Fed by Quasi Z-Source Inverter


ABSTRACT:

Z-source inverters eliminate the need for front-end DC-DC boost converters in applications with limited DC voltage such as solar PV, fuel cell. Quasi Z-source inverters offer advantages over Z-source inverter, such as continuous source current and lower component ratings. In this paper, switching table based Direct Torque Control (DTC) of induction motor fed by quasi Z-Source Inverter (qZSI) is presented. In the proposed technique, dc link voltage is boosted by incorporating shoot through state into the switching table. This simplifies the implementation of DTC using qZSI. An additional DC link voltage hysteresis controller is included along with torque and flux hysteresis controllers used in conventional DTC. The results validate the boost capability of qZSI and torque response of the DTC.
KEYWORDS:
1.      DTC
2.      QZSI
3.      DC-DC Converter
4.      DC Link Voltage
5.      Hysteresis Controller

SOFTWARE: MATLAB/SIMULINK

 BLOCK DIAGRAM:







Fig. 1: Block Diagram for DTC using qZSI





EXPECTED SIMULATION RESULTS:



Fig.2: Torque vs. Time


Fig. 3: Stator Phase 'a' Current



Fig. 4: Speed vs. Time



Fig. 5: DC Link Voltage




Fig. 6: Capacitor Voltage, VC1


CONCLUSION:

In this paper, direct torque control of induction motor fed by qZSI is presented. Dynamic torque response for step change obtained is 3 ms, which is needed for high performance applications. qZSI provides a single stage solution for drives with variable input DC voItage, instead of DC-DC converter cascaded with 3-leg inverter bridge. This paper presents a solution for drives with lesser DC input voItage availability and also requiring very fast torque response. The results shows that by introducing shoot through state in switching table of direct torque control, DC link voItage in qZSI is boosted. The DC link voItage hysteresis controller uses the input and capacitor voItage for controlling DC link voItage. If there is any disturbance in input voItage, the reference for capacitor voItage will be changed accordingly to maintain the DC link voItage.

 REFERENCES:

[I] 1. Takahashi and Y. Ohmori, "High-performance direct torque control of an induction motor, " IEEE Trans. Ind. Appl., vol. 25, no. 2, pp. 257-264, 1989.
[2] B.-S. Lee and R. Krishnan, "Adaptive stator resistance compensator for high performance direct torque controlled induction motor drives, " in Industry Applications Conference, 1998. Thirty-Third lAS Annual Meeting. The 1998 IEEE, vol. I, Oct 1998, pp. 423-430 voLl.
[3] G. Buja and M. Kazmierkowski, "Direct torque control of pwm inverter-fed ac motors-a survey, " IEEE Trans. Ind. Electron., vol. 51, no. 4, pp. 744-757, Aug 2004.
[4] F. Z. Peng, "Z-source inverter, " IEEE Trans. Ind. Appl., vol. 39, no. 2, pp. 504-510, Mar 2003.
[5] F. Z. Peng, A. Joseph, J. Wang, M. Shen, L. Chen, Z. Pan, E. Ortiz-Rivera, and Y. Huang, "Z-source inverter for motor drives, " IEEE Trans. Power Electron., vol. 20, no. 4, pp. 857-863, July2005.