IEEE Electrical Projects for BTech/MTech in india

IEEE ELECTRICAL PROJECTS

IEEE Electrical projects The best electrical activities for confirmation understudies for their last year scholastics. Normally electrical recognition ventures are engaged with working force plants in productive way, machines controlling like engines and generators, and taking care of intensity framework supplies, and power electronic convertors, and so on.

ACADEMIC MATLAB SIMULATION PROJECTS FOR
ELECTRICAL AND ELECTRONICs ENGINEERING[EEE]
POWER ELECTRONICs AND DRIVES[PED]
POWER SYSTEMS [PS]….
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AT18-01 An Improved Current-Limiting Strategy for Shunt Active Power Filter (SAPF) Using Particle Swarm Optimization (PSO)

2 AT18-02 Transformerless Z-Source Four-Leg PV Inverter with Leakage Current Reduction

3 AT18-03 Ensuring Power Quality and Stability in Industrial and Medium Voltage Public Grids

4 AT18-04 A BL-CSC Converter Fed BLDC Motor Drive with Power Factor Correction 

5 AT18-05 Dual-Buck AC–AC Converter with Inverting and Non-Inverting Operations 

6 AT18-06 Self-tuned fuzzy-proportional–integral compensated zero/minimum active power algorithm based dynamic voltage restorer

Final Year Academic Electrical Projects for BTech/MTech using Matlab/Simulink

Final Year EEE Projects ideas as many people are searching for this kind of post on internet for many days. So, here we have included various projects in different categories like embedded, electrical, robotics, communication, solar, sensor, etc. I hope these eee projects for final year students would be more helpful for many engineering students in completing their B.Tech successfully.

FINAL YEAR ACAEMIC ELECTRICAL PROJECTS:

Electrical activities covering center electrical tasks, gadgets and inserted electrical are most alluring among the understudy level undertaking work. It gives commonsense presentation on the equipment that are regularly utilized in ventures. Constant modern level activities in machines, transmission lines, control hardware, high voltage and so on are famous as the hypothetical subjects read on the same is connected in functional terms for inside and out comprehension of the same.

Progressed electrical designing subjects, for example, FACTS, UPFC, SVPWM, APFC regularly utilize control gadgets like MOSFET, IGBT, SCR, TRIAC. In this manner, essential things on such power gadgets are a pre-imperative for understanding these undertakings. Rather than equipment based tasks, MATLAB ventures (programming based) give slightest introduction on the constant equipment applications which genuinely restricts openings for work for building understudies in enterprises. Anyway MATLAB is most appropriate for R&D level of work in scholastics

projects ideas in Electrical Projects for EEE Engineering Students

projects ideas

projects ideas The project work provides several opportunities to engineering students to learn some important things that cannot be taught in a laboratory or classroom. To become a full fledged engineer any one should have required additional to subject knowledge, such that analytical skills and Practical knowledge. So an engineering student must obtain more practical knowledge through a pragmatic learning approach by means of PROJECT WORKs such as electrical mini projects and main projects new electrical projects for electrical engineering students.

Electrical and Electronics Engineering involves designing, controlling and maintaining the electrical equipments. Some of the project areas of electrical field are power generation, power system equipment maintenance and handling, industrial control and robotics, power electronics and energy systems.

projects ideas

Best Electrical Projects Ideas for EEE Final Year Engineering Students

best electrical projects ideas

best electrical projects ideas Electrical projects covering core electrical projects, electronics and embedded electrical are most desirable amongst the student level project work. It gives practical exposure on the hardware that are often used in industries. Real time industrial level projects in machines, transmission lines, power electronics, high voltage etc. are popular as the theoretical subjects read on the same is applied in practical terms for in-depth understanding of the same.

Advanced electrical engineering topics such as FACTS, UPFC, SVPWM, APFC often use power devices like MOSFET, IGBT, SCR, TRIAC. Therefore, basic fundamentals on such power devices are a pre-requisite for understanding these projects. In contrast to hardware based projects, MATLAB projects (software based) give least exposure on the real time hardware applications which seriously limits job opportunities for engineering students in industries. However MATLAB is best suited for R&D level of work in academics

best electrical projects ideas

Electrical Mini Projects for EEE Students – EEE Projects

electrical mini projects

electrical mini projects We know that in our daily life electrical projects are used in many ways,and these projects require more power than the electronic projects. These projects’ circuits use only passive components such as resistors, capacitors and inductors, etc. As a result, many people would like to get an idea about the working of these electrical projects and they are often unaware of the projects that come under this category. For those people who can’t make a distinction between electrical and electronics projects – we have already published a list of electrical Projects for engineering students, and therefore, they can collect it from different sources for the ease of engineering projects.

Earlier, we have already published a list of electrical projects which are collected from different sources for the convenience of engineering students. So, now we are providing the list of the top electrical mini projects ideas . As many engineering students are searching for the best electrical projects from the 2nd year and 3rd year, we are providing this list of projects. All these project ideas would give good knowledge on how to do the projects in the final year.

AsokaTechnologies projects brings you the most innovative list of well compiled eee mini projects for electrical students with circuit diagram. Get mini projects for eee students with circuit diagram for your study and research. We research and provide innovative mini projects topics for eee research. Implement these top most innovative mini projects ideas for electrical engineering.

electrical mini projects

Readymade BTech and MTech Academic Projects

Readymade Academic Projects

1. A High Gain Input-Parallel Output-Series DC/DC Converter with Dual Coupled Inductors
2. A High Step-Up Converter with Voltage-Multiplier Modules for Sustainable Energy Applications
3. A High Step-Up DC to DC Converter Under Alternating Phase Shift Control for Fuel Cell Power System
4. High-Efficiency MOSFET Transformerless Inverter for Non-isolated Microinverter Applications
5. A Multi-Input Bridgeless Resonant AC-DC Converter for Electromagnetic Energy Harvesting
6. A Novel Control Method for Transformerless H-Bridge Cascaded STATCOM with Star Configuration
7. A Novel High Step-up DC/DC Converter Based on Integrating Coupled Inductor and Switched-Capacitor Techniques for Renewable Energy Applications

Electrical engineering is a field of engineering that generally deals with the study and application of electricity, electronics, and electro magnetism. This field first became an identifiable occupation in the later half of the 19th century after commercialization of the electric telegraph, the telephone, and electric power distribution and use. Subsequently, broad casting and recording media made electronics part of daily life. The invention of the transistor, and later the integrated circuit, brought down the cost of electronics to the point they can be used in almost any household object.

Electrical engineering has now subdivided into a wide range of sub fields including electronics, digital computers, power engineering, tele communications, control systems, radio-frequency engineering, signal processing, instrumentation, and microelectronics. Many of these sub disciplines overlap and also overlap with other engineering branches, spanning a huge number of specializations such as hardware engineering, power electronics, electro magnetics & waves, microwave engineering, nanotechnology, electro chemistry, renewable energies, mechatronics, electrical materials science, and many more.

Electrical engineers typically hold a degree in electrical engineering or electronic engineering. Practicing engineers may have professional certification and be members of a professional body. Such bodies include the Institute of Electrical and Electronics Engineers (IEEE) and the Institution of Engineering and Technology (professional society) (IET).

Electrical engineers work in a very wide range of industries and the skills required are likewise variable. These range from basic circuit theory to the management skills required of a project manager. The tools and equipment that an individual engineer may need are similarly variable, ranging from a simple voltmeter to a top end analyzer to sophisticated design and manufacturing software.

Readymade BTech and MTech Academic Projects

2016-17 IEEE Electrical Projects List

Electrical engineering is a field of engineering that generally deals with the study and application of electricity, electronics, and electro magnetism. This field first became an identifiable occupation in the later half of the 19th century after commercialization of the electric telegraph, the telephone, and electric power distribution and use. Subsequently, broad casting and recording media made electronics part of daily life. The invention of the transistor, and later the integrated circuit, brought down the cost of electronics to the point they can be used in almost any household object.

Electrical engineering has now subdivided into a wide range of sub fields including electronics, digital computers, power engineering, tele communications, control systems, radio-frequency engineering, signal processing, instrumentation, and microelectronics. Many of these sub disciplines overlap and also overlap with other engineering branches, spanning a huge number of specializations such as hardware engineering, power electronics, electro magnetics & waves, microwave engineering, nanotechnology, electro chemistry, renewable energies, mechatronics, electrical materials science, and many more.

Electrical engineers typically hold a degree in electrical engineering or electronic engineering. Practicing engineers may have professional certification and be members of a professional body. Such bodies include the Institute of Electrical and Electronics Engineers (IEEE) and the Institution of Engineering and Technology (professional society) (IET).

Electrical engineers work in a very wide range of industries and the skills required are likewise variable. These range from basic circuit theory to the management skills required of a project manager. The tools and equipment that an individual engineer may need are similarly variable, ranging from a simple voltmeter to a top end analyzer to sophisticated design and manufacturing software.

 

2016-17-project-list

2016-17 IEEE Electrical Projects list

A Novel Control Method for Transformerless H-Bridge Cascaded STATCOM with Star Configuration

ABSTRACT

This paper presents a transformerless static synchronous compensator (STATCOM) system based on multilevel H-bridge converter with star configuration. This proposed control methods devote themselves not only to the current loop control but also to the dc capacitor voltage control. With regards to the current loop control, a nonlinear controller based on the passivity-based control (PBC) theory is used in this cascaded structure STATCOM for the first time. As to the dc capacitor voltage control, overall voltage control is realized by adopting a proportional resonant controller. Clustered balancing control is obtained by using an active disturbances rejection controller. Individual balancing control is achieved by shifting the modulation wave vertically which can be easily implemented in a field-programmable gate array. Two actual H-bridge cascaded STATCOMs rated at 10 kV 2 MVA are constructed and a series of verification tests are executed. The experimental results prove that H-bridge cascaded STATCOM with the proposed control methods has excellent dynamic performance and strong robustness. The dc capacitor voltage can be maintained at the given value effectively.

 

KEYWORDS:

Active disturbances rejection controller (ADRC), H-bridge cascaded, passivity-based control (PBC), proportional resonant (PR) controller, shifting modulation wave, static synchronous compensator (STATCOM).

 

SOFTWARE: MATLAB/SIMULINK

 

CONTROL BLOCK DIAGRAM:

image001

Fig. 1. Control block diagram for the 10 kV 2 MVA H-bridge cascaded STATCOM.

 image002

Fig. 2. Block diagram of PBC.

 

EXPERIMENTAL RESULTS:

image003 image004

Fig. 3. Experimental results verify the effect of PBC in steady-state process. (a) Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid. (b) Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid.

 image005

Fig. 4. Experimental results show the dynamic performance of STATCOM in the dynamic process. Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid.

image006 image007

Fig. 5. Experimental results in the startup process and stopping process. (a) Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid. (b) Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid.

 

CONCLUSION

This paper has analyzed the fundamentals of STATCOM based on multilevel H-bridge converter with star configuration. And then, the actual H-bridge cascaded STATCOM rated at 10 kV 2 MVA is constructed and the novel control methods are also proposed in detail. The proposed method has the following characteristics.

1) A PBC theory-based nonlinear controller is first used in STATCOM with this cascaded structure for the current loop control, and the viability is verified by the experimental results.

2) The PR controller is designed for overall voltage control and the experimental result proves that it has better performance in terms of response time and damping profile compared with the PI controller.

3) The ADRC is first used in H-bridge cascaded STATCOM for clustered balancing control and the experimental results verify that it can realize excellent dynamic compensation for the outside disturbance.

4) The individual balancing control method which is realized by shifting the modulation wave vertically can be easily implemented in the FPGA.

The experimental results have confirmed that the proposed methods are feasible and effective. In addition, the findings of this study can be extended to the control of any multilevel voltage source converter, especially those with H-bridge cascaded structure.

 

REFERENCES

[1] B. Gultekin and M. Ermis, “Cascaded multilevel converter-based transmission STATCOM: System design methodology and development of a 12 kV ±12 MVAr power stage,” IEEE Trans. Power Electron., vol. 28, no. 11, pp. 4930–4950, Nov. 2013.

[2] B. Gultekin, C. O. Gerc¸ek, T. Atalik, M. Deniz, N. Bic¸er, M. Ermis, K. Kose, C. Ermis, E. Koc¸, I. C¸ adirci, A. Ac¸ik, Y. Akkaya, H. Toygar, and S. Bideci, “Design and implementation of a 154-kV±50-Mvar transmission STATCOM based on 21-level cascaded multilevel converter,” IEEE Trans. Ind. Appl., vol. 48, no. 3, pp. 1030–1045, May/Jun. 2012.

[3] S. Kouro, M. Malinowski, K. Gopakumar, L. G. Franquelo, J. Pou, J. Rodriguez, B.Wu,M. A. Perez, and J. I. Leon, “Recent advances and industrial applications of multilevel converters,” IEEE Trans. Ind. Electron., vol. 57, no. 8, pp. 2553–2580, Aug. 2010.

[4] F. Z. Peng, J.-S. Lai, J. W. McKeever, and J. VanCoevering, “A multilevel voltage-source inverter with separateDCsources for static var generation,” IEEE Trans. Ind. Appl., vol. 32, no. 5, pp. 1130–1138, Sep./Oct. 1996.

[5] Y. S. Lai and F. S. Shyu, “Topology for hybrid multilevel inverter,” Proc. Inst. Elect. Eng.—Elect. Power Appl., vol. 149, no. 6, pp. 449–458, Nov. 2002.

A Two-Level 24-Pulse Voltage Source Converter with Fundamental Frequency Switching for HVDC System

 ABSTRACT

This paper deals with the performance analysis of a two-level, 24-pulse Voltage Source Converters (VSCs) for High Voltage DC (HVDC) system for power quality improvement. A two level VSC is used to realize a 24-pulse converter with minimum switching loss by operating it at fundamental frequency switching (FFS). The performance of this converter is studied on various issues such as steady state operation, dynamic behavior, reactive power compensation, power factor correction, and harmonics distortion. Simulation results are presented for a two level 24-pulse converter to demonstrate its capability.

 

KEYWORDS

  1. Two-Level Voltage Source Converter
  2. HVDC
  3. Multipulse
  4. Fundamental Frequency Switching
  5. Harmonics

 

SOFTWARE: MATLAB/SIMULINK

 BLOCK DIAGRAM:

 1

 Fig. 1 A 24-Pulse voltage source converter based HVDC system Configuration

EXPECTED SIMULATION RESULTS

 2

Fig. 2 Synthesis of Stepped AC voltage waveform of 24-pulse VSC.

 

3

Fig. 3 Steady state performance of proposed 24-pulse voltage source Converter

4

Fig. 4 Dynamic performance of proposed 24-pulse voltage source converter

 

5

Fig. 5 Waveforms and harmonic spectra of 24-pulse covnerter i) supply voltage ii) supply current (iii) converter voltage

CONCLUSION

A two level, 24-pulse voltage source converter has been designed and its performance has been validated for HVDC system to improve the power quality with fundamental frequency switching. Four identical transformers have been used for phase shift and to realize a 24-pulse converter along with control scheme using a two level voltage source converter topology. The steady state and dynamic performance of the designed converter configuration has been demonstrated the quite satisfactory operation and found suitable for HVDC system. The characteristic harmonics of the converter system has also improved by the proposed converter configuration with minimum switching losses without using extra filtering requirements compared to the conventional 12-pulse thyristor converter.

 REFERENCES

[1] J. Arrillaga, “High Voltage Direct Current Transmission,” 2nd Edition, IEE Power and Energy Series29, London, UK-1998.

[2] J. Arrilaga and M. Villablanca, “24-pulse HVDC conversion,” IEE Proceedings Part-C, vol. 138, no. 1, pp. 57–64, Jan. 1991..

[3] Lars Weimers, “HVDC Light: a New Technology for a better Environment,” IEEE Power Engineering Review, vol.18, no. 8, pp. 1920-1926, 1989.

[4] Vijay K. Sood, “HVDC and FACTS Controller, Applications of Static Converters in Power Systems”, Kluwar Academic Publishers, The Netherlands, 2004.

[5] Gunnar Asplund Kjell Eriksson and kjell Svensson, “DC Transmission based on Voltage Source Converters, in Proc. of CIGRE SC14 Colloquium in South Africa 1997.