asokatechnologies@gmail.com 09347143789/09949240245

Search This Blog

Monday, 6 August 2018

Research Paper Writing Service


Research Paper Writing Service
(Electrical and Electronics Engineering)

We at Asoka Technologies strive to give you the basics of your research writing specialized in Electrical and Electronics Engineering. We have been operating on various electrical projects crosswise over India.

Our group of very prepared experts with varied foundations can assist you with all the stages engaged in the making of a publishable research paper.
Just send us your research requirement overview and we will answer you back with the format of your research.
Regardless of what sort of paper you require, we'll get it composed. Get your paper writing at reasonable costs.


We Provide:
           Responsive all time support
           Total secrecy
           Unique papers
           No concealed charges
           First rate quality
           Affordable costs
           On-time conveyance
           Skilled Writers
           Less Plagiarism

Friday, 27 July 2018

Ensuring Power Quality and Stability in Industrial and Medium Voltage Public Grids




ABSTRACT:

Until recently, most of the power system equipment in industrial grids has been operating with deviations from the nominal voltage and frequency supplied by the utility. However, power electronics based equipment is vulnerable to such deviations and might get damaged in case of possible grid faults. This paper addresses this issue by proposing a stabilizing device that can be connected between the public grid and the industrial grid which provides not only power quality and security of supply during fault for the industrial grid but also ensuring the power quality for the public grid.

KEYWORDS:

1.      Public grid
2.      Industrial grid
3.      Power quality
4.      Security of supply
5.       Grid stability


SOFTWARE:MATLAB/SIMULINK


 BLOCK DIAGRAM:







Fig. 1. Device representation

 EXPECTED SIMULATION RESULTS:




Fig. 2. Harmonic current injection and compensation



Fig. 3. Individual harmonic distortion voltage for different Sk
’’

Fig. 4. THDu for different Sk’’

Fig. 5. Voltage behavior during load switching with and without Netz-Patron unit


Fig. 6. Voltage behavior during motor starting with and without Netz-Patron unit



Fig. 7. Voltage behavior during three phase fault with and without Netz-Patron unit


CONCLUSION:
The paper presents the different functionalities of the Netz-Patron unit that is designed to provide different support functionalities like harmonic compensation and voltage support in case of disturbed grid operation. In order to analyze the effectiveness of the Netz-Patron unit, a simulation model has been developed within the DIgSILENT PowerFactory software environment. The different scenarios and their simulation results are shown in this paper and the behavior of different functionalities has been analyzed. A brief summary of the main findings is given in the following. A 900 kVA active filter has been considered to provide harmonic compensation from the AC/DC converter for Sk ’’ greater than 50 MVA.
In this paper, the study has been carried out by considering a class 2 type of load with injected harmonics of 10 minutes average value (long term). The harmonic values considered for the study are not measured values, but typical values observed in practice. Real laboratory tests are planned to be performed to check the harmonics injected by th
load before designing the Netz-Patron unit to provide harmonic compensation. The effectiveness of the voltage support function provided by the Netz-Patron unit in case of any disturbance registered at the PCC has also been analyzed in this paper.
Future work is planned to focus on a multimaster      concept which implies the analysis of the parallel operation of several Netz-Patron units connected at the PCC of different industrial grids or same industrial grid in the medium voltage network.

REFERENCES:

[1] EPRI PEAC Corporation, "C. E. Commission:, Power Quality Solutions for Industrial Customers," August 2000.
[2] R.C.Dugan, M.F.McGranaghan, S.Santoso and H.W.Beaty, Electrical Power Systems Quality, second edition, McGraw- Hill, 2004.
[3] W. Reid, "Power Quality Issues - Standards and Guidelines," in IEEE Transactions of Industry Applications Vol.32,No.3, 1996.
[4] DIN EN 61000-2-4: Electromagnetic compatibility (EMC) Part 2-4: Environment – Compatibility levels in industrial plants for low-frequency conducted disturbances, VDEVerlag GmbH, 2002-06.
[5] DIN EN 61000-4-11: Electromagnetic compatibility (EMC) Part 4-11: Environment – Testing and measurement techniques – Voltage dips, short interruptions and voltage variations immunity tests for equipment with input current less than 16 A per phase, February 2005.

Wednesday, 18 July 2018

MPPT Schemes for PV System under Normal and Partial Shading Condition: A Review




ABSTRACT:



The photovoltaic system is one of the renewable energy device, which directly converts solar radiation into electricity. The I-V characteristics of PV system are nonlinear in nature and under variable Irradiance and temperature, PV system has a single operating point where the power output is maximum, known as Maximum Power Point (MPP) and the point varies on changes in atmospheric conditions and electrical load. Maximum Power Point Tracker (MPPT) is used to track MPP of solar PV system for maximum efficiency operation. The various MPPT techniques together with implementation are reported in literature. In order to choose the best technique based upon the requirements, comprehensive and comparative study should be available. The aim of this paper is to present a comprehensive review of various MPPT techniques for uniform insolation and partial shading conditions. Furthermore, the comparison of practically accepted and widely used techniques has been made based on features, such as control strategy, type of circuitry, number of control variables and cost. This review work provides a quick analysis and design help for PV systems.
KEYWORDS:

1.      Renewable Energy System
2.       Solar Photovoltaic
3.       Solar Power Conversion
4.       Maximum Power Point Tracking
5.       Partial Shading
6.      Global MPPT


SOFTWARE:MATLAB/SIMULINK

BLOCK DIAGRAM:





 Fig. 1 Current feedback methodology for MPPT tracking


EXPECTED SIMULATION RESULTS:



Fig. 2 Irradiance pattern for the testing of MPPT controller


Fig. 3 Power output response for Voltage Fraction MPPT


Fig. 4 Power output response for the P&O and INC controller

Fig. 5 Power output response for Fuzzy Logic MPPT controller

Fig. 6 The P-V curve for the demonstration of Power slope technique algorithm

Fig. 7 The output power of PV array for the Power Curve Scanning technique

Fig. 8 The output power of PV array for the modified Power Slope Detection GMPPT technique

CONCLUSION:
The prominent techniques of MPPT are discussed in this paper. It may be used as tutorial material on solar MPPT. Also, an attempt has been made to describe the important GMPPT techniques with sufficient details. A comprehensive comparative analysis has been contributed in this paper considering performance, cost, complexity of circuit and other parameters of MPPT. The results of this analysis will be helpful for proper selection of MPPT method. The generated power performance through few MPPT controllers has been illustrated with the help of simulation excercise. This also provides better understanding through numerical comparison. This review work has also presented a brief analysis and comparison of MPPT techniques for partial shading conditions. This paper may be useful for solar PV system manufacturer and solar inverter designer.

REFERENCES:
Abdourraziq, S., & El. Bachtiri Rachid (2014) A perturb and observe method using fuzzy logic control for PV pumping system. International Conference on Multimedia Computation and Systems, Marrakech, 1608-1612.
Adly, M., El-Sherif, H., & Ibrahim, M. (2011) Maximum Power Point Tracker for a PV cell using a fuzzy agent adapted by the Fractional open circuit voltage technique. IEEE International Conference on Fuzzy System, Taipei, 1918-1922.
Ahmad, J. (2010) A fractional open circuit voltage based maximum power point tracker for photovoltaic arrays. International Conference on Soft Technology and Engineering, San Juan, 247-250.
Ahmed, N.A., and Miyatake, M. (2008) A novel maximum power point tracking for photovoltaic applications under partially shaded insolation conditions. Electric Power System Research, 78, 777-784.
Altas, I.H., & Sharaf, A.M. (1996) A novel on-line MPP search algorithm for PV arrays. IEEE Transactions on Energy Conversions, 11 (4), 748-754.

Maximum Power Point Tracking Using Fuzzy Logic Controller under Partial Conditions



 ABSTRACT:

This study proposes a fuzzy system for tracking the maximum power point of a PV system for solar panel. The solar panel and maximum power point tracker have been modeled using MATLAB/Simulink. A simulation model consists of PV panel, boost converter, and maximum power point tack MPPT algorithm is developed. Three different conditions are simulated: 1) Uniform irradiation; 2) Sudden changing; 3) Partial shading. Results showed that fuzzy controller successfully find MPP for all different weather conditions studied. FLC has excellent ability to track MPP in less than 0.01 second when PV is subjected to sudden changes and partial shading in irradiation.

KEYWORDS:

1.      Fuzzy Logic Controller
2.      Maximum Power Point
3.      Photovoltaic System
4.      Partial Shading

SOFTWARE: MATLAB/SIMULINK

 BLOCK DIAGRAM:


 

Figure 1. Schematic diagram of PV system with MPPT.

 EXPECTED SIMULATION RESULTS:




Figure 2. P-V characteristics at different irradiations.

Figure 3. P-V characteristics when partial shading from 1000 to 600 Watt/m2.



Figure 4. Output of fuzzy at1000 Watt/m2.

Figure 5. Output of fuzzy controller. (a) Full shading from 600 to 300 Watt/m2; (b) Full shading from 700 to 400
Watt/m2; (c) Full shading from 900 to 400 Watt/m2; (d) Increasing shading from 300 to 800 Watt/m2.


Figure 6. Comparison between fuzzy and P & O partial shading (partial shading 1000 to 800 Watt/m2).

CONCLUSION:

In this study, FLC has been developed to track the maximum power point of PV system. PV panel, boost converter with FLC connected to a resistive load has been simulated using Matlab/Simulink. Simulation results have been compared to nominal power values. The proposed system showed its ability to reach MMP under uniform irradiation, sudden changes of irradiation, and partial shading. Simulation results have shown that using FLC has great advantages over conventional methods. It is found that Fuzzy controller always finds the global MPP. It is found that fuzzy logic systems are easily implemented with minimal oscillations with fast convergence around the desired MP


REFERENCES:

[1] Devabhaktuni, V., Alam, M., Reddy Depuru, S.S.S., Green II, R.C., Nims, D. and Near, C. (2013) Solar Energy: Trends and Enabling Technologies. Renewable and Sustainable Energy Reviews, 19, 555-556. http://dx.doi.org/10.1016/j.rser.2012.11.024
[2] Bataineh, K.M. and Dalalah, D. (2012) Optimal Configuration for Design of Stand-Alone PV System. Smart Grid and Renewable Energy, 3, 139-147. http://dx.doi.org/10.4236/sgre.2012.32020
[3] Bataineh, K. and Dalalah, D. (2013) Assessment of Wind Energy Potential for Selected Areas in Jordan. Journal of Renewable Energy, 59, 75-81.
[4] Bataineh, K.M. and Hamzeh, A. (2014) Efficient Maximum Power Point Tracking Algorithm for PV Application under Rapid Changing Weather Condition. ISRN Renewable Energy, 2014, Article ID: 673840. http://dx.doi.org/10.1155/2014/673840
[5] International Energy Agency (2010) Trends in Photovoltaic Applications. Survey Report of Selected IEA Countries between 1992 and 2009. http://www.ieapvps.org/products/download/Trends-in Photovoltaic_2010.pdf


Friday, 13 July 2018

Dynamic voltage restorer employing multilevel cascaded H-bridge inverter



ABSTRACT:
This study presents design and analysis of a dynamic voltage restorer (DVR) which employs a cascaded multilevel inverter with capacitors as energy sources. The multilevel inverter enables the DVR to connect directly to the medium voltage networks, hence, eliminating the series injection transformer. Using zero energy compensation method, the DVR does not need active energy storage systems, such as batteries. Since the energy storage system only includes capacitors, the control system will face some additional challenges compared with other DVR systems. Controlling the voltage of capacitors around a reference voltage and keeping the balance between them, in standby and compensation period, is one of them. A control scheme is presented in this study that overcomes the challenges. Additionally, a fast three-phase estimation method is employed to minimise the delay of DVR and to mitigate the voltage sags as fast as possible. Performance of the control scheme and estimation method is assessed using several simulations in PSCAD/EMTDC and MATLAB/SIMULINK environments, and experiments on a 7-level cascaded H-bridge converter.

SOFTWARE: MATLAB/SIMULINK

 CIRCUIT DIAGRAM:



Fig. 1 DVR strcuctures  a Conventional DVR b CHB-based DVR

EXPECTED SIMULATION RESULTS:




Fig. 2 Three-phase voltage sag
a Network voltage
b Injected voltage by the DVR
c Load-side voltage





Fig. 3 Unbalanced voltage sag (a 20% voltage sag on phase A)
a Source voltage
b Injected voltage by the DVR
c Load-side voltage



Fig. 4 Voltages of the DC link capacitors




Fig. 5 Three-phase 20% voltage sag with voltage harmonics
a Network voltage
b Injected voltage by the DVR
c Load-side voltage

CONCLUSION:

This paper presented design and performance assessment of a DVR based on the voltage sag data collected from MWPI. Using a multilevel converter, the proposed DVR was capable of direct connection to the medium voltage-level network without a series injection transformer. In addition, development of zero active power compensation technique helps to achieve voltage restoration goal just by the capacitors as energy storages. Due to internal losses of H-bridge cells and probable inaccuracies in measurements, voltage of DC link capacitors may become unequal, which prevents proper operation of the converter. A voltage control scheme, comprised of three separate controllers, was proposed in this paper for keeping voltage balance among the DC link capacitors within nominal range. A fast estimation method was also employed for calculation of phase and magnitude terms in an unbalanced three-phase system. This estimation method is able to recognise voltage sags in approximately half a cycle. Several simulations were performed in PSCAD/EMTDC environment to verify the performance of CHB-based DVR. Additionally, a laboratory-scale prototype of the proposed DVR was built and tested. Results of the experimental test also confirmed validity of the proposed control system.
 REFERENCES:
1 Chapman, D.: ‘The cost of poor power quality’ (European Copper Institute, Copper Development Association, 2001), March
2 Radmehr, M., Farhangi, S., Nasiri, A.: ‘Effects of power quality distortions on electrical drives and transformer life in paper industries’, IEEE Ind. Appl. Mag., 2007, 13, (5), pp. 38–48
3 Lamoree, J., Mueller, D., Vinett, P.: ‘Voltage sag analysis case studies’, IEEE Trans. Ind. Appl., 1994, 30, (4), pp. 1083–1089
4 Bollen, M.H.J.: ‘Understanding power quality problems: voltage sags and interruptions’ (New York, Saranarce University of Technology, 2000)
5 Ghosh, A., Ledwich, G.: ‘Power quality enhancement using custom power devices’ (Berlin, Kluwer Academic Publications, 2002)