Single-Phase Inverter with Energy Buffer and DC-DC Conversion Circuits

ABSTRACT:

This paper proposes a new single-phase inverter topology and describes the control method for the proposed inverter. The inverter consists of an energy buffer circuit, a dc-dc conversion circuit and an H-bridge circuit. The energy buffer circuit and H-bridge circuit enable the proposed inverter to output a multilevel voltage according to the proposed pulse width modulation (PWM) technique. The dc-dc conversion circuit can charge the buffer capacitor continuously because the dc-dc conversion control cooperates with the PWM. Simulation results confirm that the proposed inverter can reduce the voltage harmonics in the output and the dc-dc conversion current in comparison to a conventional inverter consisting of a dc-dc conversion circuit and H-bridge circuit. Experiments demonstrate that the proposed inverter can output currents of low total harmonic distortion and have higher efficiency than the conventional inverter. In addition, it is confirmed that these features of the proposed inverter contribute to the suppression of the circuit volume in spite of the increase in the number of devices in the circuit.

KEYWORDS:

1.      Energy buffer circuit

2.      Single-phase inverter

3.      Dc-dc conversion

4.      Pulse width modulation

SOFTWARE: MATLAB/SIMULINK

CIRCUIT DIAGRAM:

                                           Fig. 1 Configuration of proposed inverter.

 EXPECTED SIMULATION RESULTS:

Fig. 2 Waveforms for (a) proposed inverter and (b) conventional inverter during dc-ac conversion under conditions of P_ac = 500 W, v_s = 90 V, v_b = 70 V and dc link command voltage v_dcc = 160 V. (The scales for v_g, v_b, v_dc and v_o are 80 V/div., and those for i_c and i_o are 4.0 A/div.)

Fig. 3 Waveforms of (a) proposed inverter and (b) conventional inverter during ac-dc conversion under conditions of P_dc = 500 W, v_s = 90 V, v_bc = 70 V and v_dcc = 160 V. (The scales for v_g, v_b, v_dc and v_o are 80 V/div., and those for i_c and i_o are 4.0 A/div.)

Fig. 4 Simulated waveforms of (a) proposed inverter and (b) MEB inverter with a buffer capacitance of 1 mF during dc-ac conversion under conditions of P_ac = 500 W, v_s = 90 V and v_bc = 70 V. (The scales for v_g, v_b and v_o are 80 V/div., and those for i_c and i_o are 4.0 A/div.)

CONCLUSION:

In this paper the most common multilevel inverter topologies were scrutinized to find the more appropriate topology for BESS application. The investigation has been done entitled of quantitative and qualitative studies. The important output parameters of inverter topologies were investigated as quantitative study, while other features such as reliability, modularity and functionality were scrutinized in qualitative study. Also, various inverter topologies have been evaluated in terms of required capacity in the same operating point. The simulation results proved that the ideal BESS power conversion system, among reviewed multi-level topologies, is Cascaded topology. This topology was chosen for three reasons. First, the efficiency and reliability studies were conducted, and the CMLI was found to be the most efficient and reliable topology with minimum amount of power loss compared to other topologies. Second, it subdivides the battery string and increases the high voltage functionality. Finally, capacitor volume, cost and THD studies were again confirmed the effectiveness of this topology in battery energy storage systems.

REFERENCES:

[1] H. Abu-Rub, M. Malinowski, and K. Al-Haddad, Power electronics for renewable energy systems, transportation and industrial applications. John Wiley & Sons, 2014.

[2] T. Soong and P. W. Lehn, “Evaluation of emerging modular multilevel converters for bess applications,” IEEE Transactions on Power Delivery, vol. 29, no. 5, pp. 2086–2094, 2014.

[3] P. Medina, A. Bizuayehu, J. P. Catal˜ao, E. M. Rodrigues, and J. Contreras, “Electrical energy storage systems: Technologies’ state-of-the-art, techno-economic benefits and applications analysis,” in Hawaii IEEE International Conference on System Sciences, 2014, pp. 2295–2304.

[4] E. H. Allen, R. B. Stuart, and T. E. Wiedman, “No light in august: power system restoration following the 2003 north american blackout,” IEEE Power and Energy Magazine, vol. 12, no. 1, pp. 24–33, 2014.

[5] L. Yutian, F. Rui, and V. Terzija, “Power system restoration: a literature review from 2006 to 2016,” Journal of Modern Power Systems and Clean Energy, vol. 4, no. 3, pp. 332–341, 2016.

Single Phase Dynamic Voltage Restorer Topology Based on Five-level Ground point Shifting Inverter

ABSTRACT

A Single Phase Dynamic Voltage Restorer (DVR) based on five-level ground point shifting multilevel inverter topology has been proposed in this paper. The proposed inverter has a floating ground point. Therefore, by shifting the ground point, it is observed that the inverter circuit gives five output voltage levels from single DC voltage source. This configuration uses less number of switches compared to the existing multilevel inverter topologies. A fast sag swell identification technique using d-q reference frame is also discussed in this paper. This proposed topology of the DVR can compensate voltage sag, swell, flicker and maintain the required voltage at the load bus. The detailed simulation study is carried out using MATLAB/Simulink to validate the result.

KEYWORDS

1.      Voltage sag

2.      Swell

3.      Ground Point Shifting Multilevel Inverter (GPSMI)

4.      Topology

5.      DVR

SOFTWARE: MATLAB/SIMULINK

BLOCK DIAGRAM

Fig. 1. General structure of the proposed DVR.

 EXPECTED SIMULATION RESULTS

Fig. 2. (a) Grid terminal voltage (vt) and (b) load voltage (vl) during sag

mitigation.

Fig. 3. direct axis value of the d-q reference frame which is used to detect

sag in the system.

Fig. 4. During voltage sag (a) grid terminal voltage (vt), (b) series injected

voltage (vinj) and (c) inverter terminal voltage (vinv).

Fig. 5. FFT analysis of the series injected voltage (vinj).

Fig. 6. (a) Grid terminal voltage and (b) load voltage during Voltage flicker

CONCLUSION

This paper proposes dynamic voltage restorer based on the ground point shifting multilevel Inverter topology (GPSMI). The operation of the multilevel inverter and the power circuit diagram is explained. The inverter topology requires less number of switches than conventional multi-level inverter. In this inverter topology, only two switches are active at any instant of time that reduce switch conduction loss. The passive filter requirement in the DVR topology is reduced by using this multi-level inverter. Proper PWM for this proposed inverter has been explained. Instantaneous sag identification technique using d-q reference frame has also been explained. This proposed DVR can mitigate the power quality problem like sag/swell and voltage flicker.

REFERENCES

[1] IEEE Guide for Voltage Sag Indices,” in IEEE Std 1564-2014 , vol., no., pp.1-59, June 20 2014

[2] IEEE Guide for Identifying and Improving Voltage Quality in Power Systems,” in IEEE Std 1250-2011 (Revision of IEEE Std 1250-1995) , vol., no., pp.1-70, March 31 2011

[3] A. Ghosh and G. Ledwich, ”Structures and control of a dynamic voltage regulator (DVR),” Power Engineering Society Winter Meeting, 2001. IEEE, Columbus, OH, 2001, pp. 1027-1032 vol.3. doi: 10.1109/PESW.2001.917209

[4] Huiwen Liu, Bowen Zheng and Xiong Zhan, ”A comparison of two types of storageless DVR with a passive shunt converter,” 2016 IEEE 8th International Power Electronics and Motion Control Conference (IPEMC-ECCE Asia), Hefei, 2016, pp. 1280-1284.

[5] P. C. Loh, D. M. Vilathgamuwa, S. K. tang, H. L. Long, ”Multilevel dynamic voltage restorer”, IEEE Power Electronic Letters, vol. 2, no. 4, pp. 125-130, Dec. 2004.

Simulation of a Single-Phase Five-Level Cascaded H Bridge Inverter with Multicarrier SPWM B-Spline Based Modulation Techniques

ABSTRACT

Multilevel Power Inverters are now often used to convert DC to AC voltage waveform. This kind of converter allows high power quality with low output harmonics and lower commutation losses with respect to the traditional ones in order to optimize this aspect. This paper presents a novel simulation analysis of the Multicarrier Sinusoidal Pulse Width Modulation (MC SPWM) techniques B-Spline functions based to control the switches of five-level single-phase cascaded H bridge inverter. In order to verify the performance of the converter, the harmonic content of the voltage due to modulation techniques has been taken into account. Results highlight the comparison between different B-Spline functions.

KEYWORDS

1.      Multilevel power converter

2.      Multicarrier modulation techniques

3.      B-spline functions

SOFTWARE: MATLAB/SIMULINK

 CIRCUIT DIAGRAM

Fig. 1: CHBMI single-phase with 2n+ 1 level

 EXPECTED SIMULATION RESULTS

Fig. 2: Comparison of THD% versus reference voltage trend for

Phase Disposition PD carriers: B2(t), B3(t) and B4(t).

Fig. 3: Comparison THD% versus reference voltage trend for

Phase Opposition Disposition POD carriers: B2(t), B3(t) and B4(t).

Fig. 4: Comparison THD% versus reference voltage trend for

Alternative Phase Opposition Disposition APOD carriers: B2(t),

B3(t) and B4(t).

Fig. 5: Comparison THD% versus reference voltage trend for

Phase Shifted PS carriers: B2(t), B3(t) and B4

Fig. 6: Comparison Fundamental Amplitude versus reference

voltage trend for Phase Disposition PD carriers: B2(t), B3(t) and

B4(t).

Fig. 7: Comparison Fundamental Amplitude versus reference

voltage trend for Phase Opposition Disposition POD carriers:

B2(t), B3(t) and B4(t).

Fig. 8: Comparison Fundamental Amplitude versus reference

voltage trend for Alternative Phase Opposition Disposition APOD

carriers: B2(t), B3(t) and B4(t).

Fig. 9: Comparison Fundamental Amplitude versus reference

voltage trend for Phase Shifted PS carriers: B2(t), B3(t) and B4(t).

 CONCLUSION

This paper presents a simulation analysis of the Multicarrier Sinusoidal Pulse Width Modulation techniques B-Spline functions based for five-level single-phase cascaded H-bridge inverter. The multi carrier modulation techniques taken into account are PD, POD, APOD and PS using PB2(t), PB3(t) and PB4(t) as carrier signals. In order to verify the performance of converter and harmonic content of the voltage, the used tool for comparison of different modulation techniques is THD%. The computed THD% values versus reference voltage (peak value) for the phase voltage have been presented and the related results have been compared among different carrier signals used. The minimum value of the THD% has  been obtained by using the PS modulation techniques with PB4(t) as carrier signal.

REFERENCES

[1] A. Takahashi I. Nabe and H. Akagi, A new neutral-point clamped PWM inverter, IEEE Trans. Ind. Appl., 17, 518" 1981.

[2] .T. Rodriguez, .T.-S. Lai, and F. Z. Peng, Multilevel inverters: a survey of topologies, controls, and applications, Industrial Electronics, IEEE Transactions on, vol. 49, no. 4, pp. 724- 738, Aug. 2002.

[3] M. Caruso et al., Design and experimental characteriz.ation of a low-cost, real-time, wireless AC monitoring system based on ATmega 328P-PU microcontroller, 2015 AEIT International Annual Conference (AEIT), Naples, 2015, pp. 1- 6. doi: 1O.1109!AEIT.2015.7415267

[4] M. Caruso, V. Cecconi, A. O. Di Tommaso, and R. Rocha. A Rotor Flux and Speed Observer for Sensorless Single-Phase Induction Motor Applications. International Journal of Rotating Machinery, vol. 2012, no. 276906, p. 13,2012.

[5] M. Caruso, A. O. Di Tommaso, F. Genduso, R. Miceli and G. R. Galluzzo, A DSP-Based Resolver-To-Digital Converter for High-Peiformance Electrical Drive Applications, in IEEE Transactions on Industrial Electronics, vol. 63, no. 7, pp. 4042-4051, July 2016.

Solar Photovoltaic Powered Sailing Boat Using Buck Converter

ABSTRACT

The main objective of this paper is to establish technical and economical aspects of the application of stand-alone photovoltaic (PV) system in sailing boat using a buck converter in order to enhance the power generation and also to minimize the cost. Performance and control of dc-dc converter, suitable for photovoltaic (PV) applications, is presented here. A buck converter is employed here which extracts complete power from the PV source and feeds into the dc load. The power, which is fed into the load, is sufficient to drive a boat. With the help of matlab simulink software PV module and buck model has been designed and simulated and also compared with theoretical predictions.

KEYWORDS

1.      Buck Converter

2.      Ideal Switch

3.      Matlab Simulink

4.      PV

5.      Solar Sailing Boat

SOFTWARE: MATLAB/SIMULINK

 BLOCK DIAGRAM

Figure 1. Schematic Diagram of PV powered Sailing Boat

 EXPECTED SIMULATION RESULTS

Figure 2. Simulation result of maximum voltage, current and power in PV array

Figure 3. Simulation result of Buck converter

Figure 4. Simulation result of PV with Buck

 CONCLUSION

Solar PV powered sailing boat using buck converter is proposed here. The effectiveness of the proposed control scheme is tested. This is a new and innovative application which is fully environmental friendly and is almost polution less. As the upper portion of the boat is unused, solar panels are implemented in that portion quite easily, no extra space is required. Fuel cost is not required in day time due to the presence of sunlight. lastly, energy pay back period will be lesser than diesel run boat.

REFERENCES

[1] P Vorobiev, Yu. Vorobiev. Automatic Sun Tracking Solar Electric Systems for Applications on Transport. 7^th International Conference on Electrical Engineering, Computing Science and Automatic Control. 2010.

[2] Nobuyulu Kasa, Takahiko Iida, Hideo Iwamoto. An inverter using buck-boost type chopper circuits for popular small-scale photovoltaic power system. IEEE. 1999.

[3] Peng Zhang, Wenyuan Li, Sherwin Li, Yang Wang, Weidong Xiao. Reliability assessment of photovoltaic power systems: Review of current status and future perspectives. Applied Energy. 2013; 104(2013): 822–833,

[4] M Nagao, H Horikawa, K Harada. Photovoltaic System using Buck-Boost PWM Inverter. Trans. of IEEJ. 1994; ll4(D): 885-892.

[5] A Zegaoui, M Aillerie, P Petit, JP Sawicki, JP Charles, AW Belarbi. Dynamic behaviour of PV generator trackers under irradiation and temperature changes. Solar Energy. 2011; 85(2011): 2953–2964.