A Multi-Cell 21-Level Hybrid Multilevel Inverter synthesizes a reduced number of components with Voltage Boosting Property

ABSTRACT:

A multi-cell hybrid 21-Level multilevel inverter is proposed in this paper. The proposed topology includes two-unit; an H-bridge is cascaded with a modified K-type unit to generate an output voltage waveform with 21 levels based only on two unequal DC suppliers. The proposed topology's advantage lies in the fine and clear output voltage waveforms with high output efficiency. Meanwhile, the high number of output voltage waveform levels generates a low level of distortion and reduces the level of an electromagnetic interface (EMI). Moreover, it reduces the voltage stress on the switching devices and gives it a long lifetime. Also, the reduction in the number of components has a noticeable role in saving size and cost. Regarding the capacitors charging, the proposed topology presents an online method for charging and balancing the capacitor's voltage without any auxiliary circuits. The proposed topology can upgrade to a high number of output steps through the cascading connection. Undoubtedly this cascading will increase the power level to medium and high levels and reduce the harmonics content to a neglectable rate. The proposed system has been tested through the simulation results, and an experimental prototype based on the controller dSPACE (DS-1103) hardware unit used to support the simulation results.

KEYWORDS:

1.      21-Level Multilevel Inverter (MLI)

2.      Hybridization

3.      Modified K-type inverter

4.      Online charging

5.      Self-balancing

6.      Voltage boosting inverter

7.      Total Harmonic Distortion (THD)

SOFTWARE: MATLAB/SIMULINK

CONCLUSION:

The work in this paper presented a hybrid multilevel inverter that consisted of a series connection between two units (an HB unit with a modified K-Type unit). This combination generates an output voltage waveform with 21 steps. This high number steps in the output voltage help in reducing the level of noises in the output voltage and reduced the stress in the switching devices, which on the one hand generating fine and clear waveforms and on the other hand reduces the harmonic content in the waveforms to a deficient level (satisfying the harmonics standard IEEE519). Economically, the structure of the proposed topology presented an optimal design in terms of reducing the number of switches and DC sources which in turn enhancing the system reliability by reducing the inverter cost. For the capacitors charging process, the paper presents an online method for charging and balancing the capacitor voltages without any auxiliary circuits for that. This helps in the continuous operation of the charging and discharging process for the capacitor without disturbing the process of generating the output voltage. The proposed topology supports the modularity process in order to maximize the range of output power to the medium and high level, and the paper presented two scenarios for the series connection 2HB+K and HB+2K both the cases raise the level of the output power and enhances the system performance to achieve high efficiency. Due to the dependence on multi DC sources, this topology is suitable for renewable energy applications; DC sources are abundant. The hybrid renewable energy sources application will be more appropriate between all the renewable energy applications because the proposed topology-based mainly on two unequal DC suppliers, which will be available easily in the hybrid renewable energy sources.

REFERENCES:

[1] F. Z. Peng, W. Qian, and D. Cao, "Recent advances in multilevel converter/inverter topologies and applications," in The 2010 International Power Electronics Conference-ECCE ASIA-, 2010, pp. 492-501.

[2] J. Rodriguez, J.-S. Lai, and F. Z. Peng, "Multilevel inverters: a survey of topologies, controls, and applications," IEEE Transactions on Industrial Electronics, vol. 49, pp. 724-738, 2002.

[3] L. M. Tolbert and X. Shi, "Multilevel power converters," in Power Electronics Handbook, ed: Elsevier, 2018, pp. 385-416.

[4] K. K. Gupta, A. Ranjan, P. Bhatnagar, L. K. Sahu, and S. Jain, "Multilevel inverter topologies with reduced device count: A review," IEEE transactions on power electronics, vol. 31, pp. 135-151, 2015.

[5] P. Omer, J. Kumar, and B. S. Surjan, "A Review on Reduced Switch Count Multilevel Inverter Topologies," IEEE Access, vol. 8, pp. 22281-22302, 2020.  

A Generalized Multilevel Inverter Topology with Reduction of Total Standing Voltage

ABSTRACT:

  This paper presents a new multilevel inverter topology with reduced active switches and total standing voltage. The proposed topology can generate a high number of voltage levels in the symmetric configuration. This topology intuitively generates positive and negative cycles without an additional H-bridge unit, which considerably reduces the total standing voltage of the inverter. A cascaded structure is developed from the proposed topology to create higher voltage levels. To show the novelty of the proposed topology, a thorough comparison between the available and the proposed topologies in terms of the number of switches, standing voltages, and dc-sources is presented. Furthermore, the power loss analysis is carried out for various load values. The feasibility of the proposed nine-level inverter is verified with simulation and experimental results.

KEYWORDS:

1.      Multilevel inverter

2.       Inverter

3.      Locking voltage

4.      Cascaded structure

5.      Reduced power components

SOFTWARE: MATLAB/SIMULINK

CONCLUSION:

The proposed topology used lower number of power electronics components and reduced dc-sources. Further, the maximum voltage stress on the switch is reduced to 4Vdc for any number of voltage levels in symmetric configuration which is more suitable for medium voltage applications. The simulated and experimental results are presented for various load values. The sudden load changes and modulation index variations are applied to the proposed topology and it corresponding results are given. Further, the power loss and efficiency of propose topology presented for various load power. It is confirming that the proposed topology is more suitable various load changing applications like AC drives, grid connected PV system etc.

REFERENCES:

[1] S. A. Teston, M. Mezaroba, and C. Rech, “Anpc inverter with integrated secondary bidirectional dc port for ess connection,” IEEE Transactions on Industry Applications, vol. 55, no. 6, pp. 7358–7367, 2019.

[2] Jing Huang and K. A. Corzine, “Extended operation of flying capacitor multilevel inverters,” IEEE Transactions on Power Electronics, vol. 21, no. 1, pp. 140–147, 2006.

[3] S. P. Gautam, “Novel h-bridge-based topology of multilevel inverter with reduced number of devices,” IEEE Journal of Emerging and Selected Topics in Power Electronics, vol. 7, no. 4, pp. 2323–2332, 2019.

[4] S. A. A. Ibrahim, A. Palanimuthu, and M. A. J. Sathik, “Symmetric switched diode multilevel inverter structure with minimised switch count,” The Journal of Engineering, vol. 2017, no. 8, pp. 469–478, 2017.

[5] S. S. Lee, M. Sidorov, N. R. N. Idris, and Y. E. Heng, “A symmetrical cascaded compact-module multilevel inverter (ccm-mli) with pulsewidth modulation,” IEEE Transactions on Industrial Electronics, vol. 65, no. 6, pp. 4631–4639, 2018. 

Power Quality Improvement in Solar Fed Cascaded Multilevel Inverter with Output Voltage Regulation Techniques

ABSTRACT:

The presence of harmonics in solar Photo Voltaic (PV) energy conversion system results in deterioration of power quality. To address such issue, this paper aims to investigate the elimination of harmonics in a solar fed cascaded fifteen level inverter with aid of Proportional Integral (PI), Artificial Neural Network (ANN) and Fuzzy Logic (FL) based controllers. Unlike other techniques, the proposed FLC based approach helps in obtaining reduced harmonic distortions that intend to an enhancement in power quality. In addition to the power quality improvement, this paper also proposed to provide output voltage regulation in terms of maintaining voltage and frequency at the inverter output end in compatible with the grid connection requirements. The simulations are performed in the MATLAB / Simulink environment for solar fed cascaded 15 level inverter incorporating PI, ANN and FL based controllers. To exhibit the proposed technique, a 3 kWp photovoltaic plant coupled to multilevel inverter is designed and hardware is demonstrated. All the three techniques are experimentally investigated with the measurement of power quality metrics along with establishing output voltage regulation.

KEYWORDS:

1.      Harmonics

2.      Intelligent control

3.      Multilevel inverter

4.      Photovoltaic's

5.      Power quality

6.      Voltage regulation

SOFTWARE: MATLAB/SIMULINK

CONCLUSION:

The voltage regulation topology along with power quality improvement is considered and implemented both in simulation and experimental setup for a solar fed 15 level inverter. While considering the results, it is found that FLC presents better results for VR while considering the variations at the input solar PV. Despite this, FLC is considered for the nine-level by [23], but the implementation is carried out with the DC power supplies without utilizing the solar panels. All the other methods are implemented for low power and lesser levels of MLI topology. Commercial utilization of MLI by providing the constant output voltage is investigated, and the experimental results prove the effectiveness of the proposed system. The method is applicable for the users require grid interaction along with the power quality improvement.

REFERENCES:

[1] S. Karekezi and T. Ranja, Renewable technologies in Africa. London, U.K.: Zed Books, 1997.

[2] S. Karekezi and W. Kithyoma, ``Renewable energy strategies for rural africa: Is a PV-led renewable energy strategy the right approach for providing modern energy to the rural poor of sub-saharan africa?'' Energy Policy, vol. 30, nos. 11_12, pp. 1071_1086, Sep. 2002.

[3] S. Karekezi andW. Kithyoma, ``Renewable energy in Africa: Prospects and limits in Renewable energy development,'' Workshop Afr. Energy Experts Operationalizing NEPAD Energy Initiative, vol. 1, pp. 1_30, 2-4 Jun. 2003. Jun. 2017. [Online]. Available: https://sustainabledevelopment.un. org/content/documents/nepadkarekezi.pdf

[4] D.-R. Thiam, ``Renewable decentralized in developing countries: Appraisal from microgrids project in senegal,'' Renew. Energy, vol. 35, no. 8, pp. 1615_1623, Aug. 2010.

[5] F. Christoph, World Energy Scenarios: Composing energy futures to 2050. London, U.K.: World Energy Council, 2013. 

Three-Phase Five-Level Grid Synchronized PV Inverter with MPPT for Micro-Grid Application

ABSTRACT:

This paper develops an interesting converter for three phase grid interface for photovoltaic panels. Here a new topology having least number of power semiconductor switches in the five level category is used. The converter consists of three basic sections viz. the photovoltaic source, a two phase inverter and a Scott-T transformer that converts the two-phase inverter output to three phases and connects to the grid. The control system is in the d-q reference frame which provides fast dynamic control response. A maximum power point tracking mechanism (MPPT) is used to generate the direct axis current reference in order to inject the maximum available power into the grid for any insolation. The converter has been designed and developed for 1kW. This is also experimentally validated.

KEYWORDS:

1.      Current referenced control

2.      Maximum Power Point

3.      Sine pulse width modulation

4.      Scott-T Transformer

5.      Isolated Grid Tied Inverter

SOFTWARE: MATLAB/SIMULINK

CONCLUSION:

The paper presents a reduced switched method for generating a five level voltage output from a PV system. The whole converter system consists of three stages, the PV system with MPPT control, the 16 switch two-phase converter and finally isolation stage using Scott-T transformer. The converter pumping the current towards the grid is controlled by taking the PV MPP output current and providing it as Id reference for the inverter. This Id reference current controls the Id value of the inverter current control loop. Two-phase 16 switch inverter topology consist of high frequency and low frequency stages. High frequency stage will have a maximum switching stress voltage of Vdd=2 and similarly low frequency unfolding stage will have a maximum stress voltage of Vdd. The inverter has a self-balanced dc link capacitor pairs without any complex control schemes. Proper simulation analysis for the five level inverter sourced from a PV which in turn fed to grid has done which conforms its application on grid tied applications. Hardware implementation for two-phase level is also made and waveforms were verified comparing with the simulation. Further section of hardware is to be done in future in order to detail verification and making a complete prototype model for analysis.

REFERENCES:

[1] B. Satish Naik , L. Umanand, K. Gopakumar and B. Subba Reddy, ”A New Two-Phase Five-Level Converter for Three-Phase Isolated Grid-Tied Systems With Inherent Capacitor Balancing and Reduced Component Count” IEEE Journal of Emerging and Selected Topics in Power Electronics., VOL. 6, NO. 3,pp 1325-1335 Sep. 2018

[2] Gautam A. Raiker, L. Umanand and B. Subba Reddy, ”Perturb and Observe with Momentum Term applied to Current Referenced Boost Converter for PV Interface” 2018 IEEE International Conference on Power Electronics, Drives and Energy Systems (PEDES)

[3] Gautam A. Raiker , Subba Reddy B., Praveen C. Ramamurthy, L. Umanand, Abines S. G. and Shama G. Vasisht ”Solar PV interface to Grid-Tie Inverter with Current Referenced Boost Converter” 2018 IEEE 13th International Conference on Industrial and Information Systems(ICIIS)

[4] J. Rodrguez, 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. 724738, Aug. 2002

[5] A. Nabae, I. Takahashi, and H. Akagi, A new neutral-point-clamped PWM inverter, IEEE Trans. Ind. Appl., vol. IA-17, no. 5, pp. 518523, Sep. 1981

Study of a Five-Level PWM Rectifier Fed DC Motor Drive

ABSTRACT:

A simulation of a five-level sinusoidal pulse width modulation (SPWM) rectifier fed D.C motor is proposed. The proposed topology of a five-level rectifier can be regulate the output voltage using (SPWM) to obtain variable speed of a D.C motor with constant load torque. The main advantages of the SPWM rectifier system are to drive a D.C motor with constant and variation load torque, low harmonic distortion in A.C supply side. The PID speed controller is used to make constant speed when load torque increase or decrease about 20% of rated value and to improve the dynamic response of the system. The five-level SPWM rectifier fed separately excited D.C motor are studied and simulated under the MATLAB/SIMULINK program.

KEYWORDS:

1.      Five-level rectifier

2.      D.C motor drive

3.      PID speed controller

4.      SPWM

SOFTWARE: MATLAB/SIMULINK

CONCLUSION:

The paper presents a study and modeling of a five level rectifier with SPWM technique as a DC motor driver. Several researches focused on constructing the circuit of multi-level rectifier with static load (RL). In this study the five level rectifier system has been tested with a dynamic load as a separately excited DC motor. The proposed system investigated in case of open loop system with A disturbance in load torque applied +-20%from rated load torque and that’s lead to dramatic variation in motor speed with respect  to desired speed. Furthermore the effect of THD for input current was considered. PID controller is applied to the proposed system with the same disturbance in load torque and the results shows a constant output speed at desired speed with minimum response percentage error.

REFERENCES:

[1] Muhammad H. Rashid, "Power Electronics Devices, Circuits, and Applications", Fourth Edition, ISBN 978-0-13-312590-0, published by Pearson Education, 2014.

[2] Jun-ichi Itoh, Yuichi Noge, and Taketo Adachi, "A Novel Five-Level Three-Phase PWM Rectifier With Reduced Switch Count", IEEE Transactions On Power Electronics, Vol. 26, No. 8, AUGUST 2011.

[3] N. A. Rahim, J. A. Jalil, "Single-Phase Five-Level PWM Rectifier", Institute of Research Management & Monitoring, University of Malaya.

[4] Omar Turath Tawfeeq, "Single Tuned Passive Harmonics Filters Design For A Buck Type Rectifier D.C Motor Drive Using Fuzzy Controller", International Journal of Engineering and Innovative Technology (IJEIT) Volume 4, Issue 11, May 2015.

[5] Vivek Kumar, AshishPatra, "Application of Ziegler-Nichols method for tuning of PID Controller", International Journal of electrical and Electronic Engineers, Vol. No.8, Issue No. 02, July-Dec. 2016. 

Residential Community Load Management based on Optimal Design of Standalone HRES with Model Predictive Control

ABSTRACT:

Microgrids being an important entity in the distribution system, and to get their full advantages by incorporating maximum distributed generation, standalone hybrid renewable energy systems (HRESs), being environmentally-safe and economically-efficient, are considered as the promising solution to electrify remote areas where the grid power is not available. In this work, a techno-economic investigation with an optimal design of HRES is presented to fulfill the domestic electricity need for a residential area of the Sherani district in the Province of Baluchistan, Pakistan. Nine case studies based on PV/wind/diesel/battery are analyzed based on net present cost (NPC), cost of energy (COE), and emission to decide the feasible solution. HOMER tool is utilized to accomplish modeling and simulation for economic analysis and optimal sizing. Simulation results demonstrated that HRES with PV-wind-battery is the most viable option for the specified area, and the optimal sizing of components are also obtained with $ 28,620 NPC and 0.311 $/kWh COE which shows 81.65% reduction in cost and 100% preserving in toxic emission while fulfilling 100% energy demand with 67.3% of excess energy. Furthermore, MATLAB/Simulink modeling for the optimally designed system is built for technical analysis while its effectiveness is proved by keeping dc and ac buses voltage constant, safe operating range of battery state of charge (SOC) with active power balance between HRES components, as well as efficient ac voltage quality, regardless of generation disturbances and load fluctuations. The output signal has total harmonic distortion (THD) of 0.30% as compared to 5.44% with the conventional control scheme. The novelty lies in the sequential application of both HOMER and MATLAB simulations of the proposed HRES model and validation of the proposition for the studied area; by using and implementing model predictive control (MPC) of a reconfigurable inverter.

SOFTWARE: MATLAB/SIMULINK

CONCLUSION:

Standalone HRES with PV-wind-battery is proposed as the optimal and economically most viable system, as determined by techno-economic studies carried out through HOMER and MATLAB along with FCS-MPC of a reconfigurable inverter, to fulfill the residential electricity requirement of Sherani district in the Province of Baluchistan, Pakistan. Firstly, optimal sizing of HRES components and economic investigation is performed through HOMER, while simulation studies for the suggested area with practical and real data of load profile as well as weather is investigated using different costs (capital, replacement, O&M), operating life, and efficiencies of HRES components, project lifetime, meteorological data assessment, and interest rate as the input parameters; load demand, resources availability, operating reserves, allowable capacity shortage, GHG emission penalties as optimization constraints; and NPC as decision variable. Out of nine possible optimal configurations namely PV-wind-battery, PV-wind-diesel-battery, PV-battery, PV diesel- battery, wind-diesel-battery, PV-wind-diesel, PV diesel, wind-diesel, and diesel-battery, as examined during this work, PV-wind-battery is obtained as the most feasible and economically viable configuration (i.e. winning plan) with minimum NPC ($ 28,620) and COE (0.311 $/kWh) which shows 81.65% reduction in cost and 100% preserving in toxic emission, while fulfilling 100% energy demand with 67.3% of excess energy. The proposed optimal HRES design (winning plan) comprises 13.4 kW PV, 4 kW wind, 3.88 kW converter, and 20 units of 2.37 kWh lead-acid battery. Optimal sizes of HRES components are then used to design a management and control strategy in MATLAB/Simulink with finite control set model predictive control (FCS-MPC) of reconfigurable inverter for technical analysis based on power balance between HRES elements, constant dc and ac voltages, safe operating range of battery SOC, efficient ac voltage quality, during variations of PV irradiance, wind speed, as well as load demand. The results are validated through simulations with total harmonic distortion (THD) of 0.30% which is well below the allowable limit according to IEEE-929 and IEEE-519 standards as compared to 5.44% THD with the conventional PI control scheme.

The presented scheme would be an assessing tool for the governments, energy sector/microgrid planners, model designers, and researchers to investigate suitable policies, mechanisms, effective and efficient design of HRESs. An increasing, unpredictable and abrupt load demand of the society can be handled by integrating more renewable generation in terms of a reliable, economical, and environment-friendly scenarios with an understanding of intermittent generation profile. The future work includes microgrid reconfiguration under inverter and rectification mode to control the voltage and frequency during the standalone mode, and power flow during the grid-connected mode.

REFERENCES:

[1] E. Muh and F. Tabet, “Comparative analysis of hybrid renewable energy systems for off-grid applications in Southern Cameroons,” Renew. Energy, vol. 135, pp. 41–54,2019.

[2] O. Krishan and S. Suhag, “Techno-economic analysis of a hybrid renewable energy system for an energy poor rural community,” J. Energy Storage, vol. 23, no. November 2018, pp. 305–319, 2019.

[3] J. Kumari, P. Subathra, J. Edwin Moses, and D. Shruthi, “Economic analysis of hybrid energy system for rural electrification using homer,” Proc. IEEE Int. Conf. Innov. Electr. Electron. Instrum. Media Technol. ICIEEIMT 2017, vol. 2017-Janua, no. 978, pp. 151–156, 2017.

[4] W. Ullah, S. Noor, and A. Tariq, “The development of a basic framework for the sustainability of residential buildings in Pakistan,” Sustain. Cities Soc., vol. 40, no. January, pp. 365–371, 2018.

[5] “Greenhouse Gas (GHG) Emissions.” [Online]. Available: https://www.epa.gov/ghgemissions. [Accessed: 14-Dec- 2019]. 

Reliability evaluation of MPPT based interleaved boost converter for PV system

 ABSTRACT:

The demand for power supply and depletion of the conventional energy sources are increasing drastically. So to overcome this problem, the best alternative power generation for conventional fossil fuel is Photovoltaic solar cell  based system because of its advantage of pollution free and its availability in abundance with free of cost. In the MPPT based PV system the converters are the most sensitive part. Therefore to provide uninterrupted power supply without compromising the quality of power, reliability evaluation of interleaved boost converter becomes necessary. MATLAB/Simulink is used for the simulation studies and to determine the power losses of various components of the converter which is used in calculating the failure rates and reliability of the interleaved boost converter. Reliability studies of IBC have not been studied much. However there exists few literature in which reliability expression has been developed using Markov technique which is a more complex method as compare to Reliability Block Diagram (RBD). Therefore this paper proposes reliability modeling and reliability evaluation of Interleaved boost converter in MPPT based photo-voltaic system by using simple RBD method.

KEYWORDS:

1.      Maximum Power Point Tracking (MPPT)

2.      Photovoltaic systems

3.      Reliability

4.      Failure rate

5.      Reliability Block diagram(RBD)

6.      Interleaved Boost Converter (IBC)

SOFTWARE: MATLAB/SIMULINK

CONCLUSION:

The modeling of Interleaved boost converter is discussed stepwise along with its simulation results with the help of MATLAB/SIMULINK. The failure rates of each component of IBC and the whole IBC are determined. The RBD model is developed for a conventional boost converter and IBC and those are a series system and a parallel system respectively. With the help of this RBD the overall reliability evaluation and MTTF calculation are done for the IBC used in grid connected PV system. The interleaved boost converter acts as a power converter and MPP tracker as well because of its high reliable nature. The reliability evaluation can be done for the other topologies of these converters which are implemented in various other power generation system.

REFERENCES:

[1] TRISHAN ESRAM AND PATRICK L. CHAPMAN, “COMPARISON OF Photovoltaic Array Maximum Power Point Techniques”, IEEE Transactions on Energy Conversion, Vol.22, No.2, June, 2007.

[2] A. E. Khosroshahi, M. Abapour, and M. Sabahi, “Reliability evaluation of conventional and interleaved DC-DC boost converters,” IEEE Trans. Power Electron., vol. 30, no. 10, pp. 5821-5828, Oct. 2015.

[3] M.H. Taghvaee, M.A.M. Radzi, S.M. Moosavain, H. Hizam, and M.H. Marhaban, “A current and future study on non-isolated DC-DC converters for photovoltaic applications,” Renew. and Sustain. Energy, vol. 17, pp. 216-227, 2013.

[4] D. Sera, R. Teodorescu, and P. Rodriguez, “PV panel model based on datasheet values,” In Proc .IEEE. ISIE, pp. 2392-2398, Jun. 2007.

[5] M. G. Villalva, J. R. Gazoli, and E. R. Filho, “Comprehensive Approach to Modeling and Simulation of Photovoltaic Arrays,” IEEE Trans. Power Electron., vol. 24, no. 5, May. 2009.