Top Power Electronics Projects Ideas

The functioning of solid-state electronics for the controlling and translation of electric power is named as Power electronics. It also refers to an area of research & discussion in electrical engineering which contracts with designing, controlling, calculation, and incorporation of non-linear, span altering energy processing electronic structures with speedy dynamics. With the advantages of electronics, power electric & electronic engineering students are required to submit their case study & this aids them in constructing an innovative design, thereby formulating their studies more interesting. We have laid a few best power electronics project ideas here to give you a better understanding of the same.

Top Power Electronics Projects Ideas for Engineering Students:

The following are some of the top power electronics project ideas for engineering students.

1. Nuclear Radiation Detection and Tracking through Motes for Preventing from Nuclear Terrorism Project:

Nuclear Radiation Detection
Nuclear Radiation Detection

Nuclear Radiation Detection and Tracking project’s key proposal is to put into practice an application which can aid armed forces or police to follow terrorist attacks caused by Nuclear Radiation. This project brings into play sensors, GSM technology, and Zigbee protocol. Creating this type of prototype application is extremely economical. Zigbee is a wireless protocol that is open-sourced & can be downloaded free of charge and we employ this wireless application in this project. And GSM is also employed as another wireless technology for communication. Small computers are also coupled in an ad-hoc network wirelessly; these computers are known as Motes. As semiconductor- Carbon diode is employed.

2. Inter-Integrated Circuit:

The foremost goal of the Inter-Integrated Circuit Mini Project is to edge with hosts such as EEPROM and that keep an eye on the parameters such as- humidity, temperature, etc. It is employed in embedded systems to edge with real-time timepieces and it includes a unique benefit that we can add or delete the peripherals while the system is working, which creates this system as inactive for hot substitution. Inter-Integrated Circuit functions on 2 lines, firstly SDA line and secondly SCL line. This integrated circuit functions at a frequency of 400 kHz. One of the major benefits of this protocol is one can employ several slaves aligned to a solo master chip. This circuit functions on master-slave methods where the master will always have a look & check for the aligned slaves.

3. RF Based Servo and DC Motor Controller System for Spy Plane Embedded Based Robotics Projects:

RF Link Based DC Motor Control
RF Link Based DC Motor Control

RF Based Robotics Project’s key proposal is to put into practice an embedded system based robot which functions distantly on Radio Frequency. The motion of the Robot is administered by bringing into play a DC motor. Making use of a remote control system we can control the activities of the robots and sensors are linked to the robots which will detect hurdles or obstacles that may come in front of the robot and transmits the information to the microcontroller and microcontroller takes the decisions over the information received and employs motor controlling methods and again send indications to the DC motor.

4. SMS Based Electric Billing System Projects:

This SMS based project’s main proposal is to put into practice an efficient method of distributing electricity bills to consumers by using the remote system with the help of GSM technology as support in the form of an SMS (text messages). As we make out automatic reading from the electricity meter is one of the forthcoming technology for studying various types of bills via remote application where there is no necessity of any human interference. Similarly, with this technology electric billing system based on SMS can be employed for distributing the bills which will accumulate time as well as work will be accomplished in a short period. In the present system, the physical process is employed for the billing system. An authorized person will visit every residence and issue bill based on the reading from the meter of the house. With this process, there is a requirement of a huge amount of manpower.


5. IUPQC (Interline Unified Power Quality Conditioner) Project:

The main aim of this IUPQC project is to control the voltage of one feeder while regulating the voltage all across a sensitive load in other feeders. For this reason, the name IUPQC is given.  By altering the voltage across various loads in other feeders, this will help in supplying quality of power supply devoid of any troubles. In this project, we have employed a series of voltage source interpreters that are coupled to each other via dc bus. In this project, we elucidate how these gadgets are linked together to aim different feeders to control the voltage supply of various feeders and give quality uniform power.

6. A Loss-Adaptive Self-Oscillating Buck Converter for LED Driving:

A loss-adaptive self-oscillating project is anticipated for the highest efficiency at low cost LED driving. It includes a self-oscillating component made of BJTs (bipolar junction transistors) and loss-adaptive bipolar junction transistors driving element and a coffee-loss high current sensor. In this project, its function theory comprises of a loss-adaptive bipolar junction transistors driving system and an occasional-loss high current sensor technique is launched. For experiment authentication, a model LED driver was applied with some economical parts and gadgets for a 24Volts lighting scheme to go up to 6 LEDs. The results of the experiment show that the model LED driver may successfully startup itself and function extremely competently in a stable state. To perk up the functioning of the projected buck interpreter, a supportive PWM (pulse-width modulation) LED softening function is stated for the extensive study.

7. Hybrid Resonant and PWM Converter with High Efficiency and Full Soft-Switching Range:

In this project we have a fresh soft-switching interpreter joining resonant 0.5-bridge and section shifted PWM (pulse width modulation) full-bridge arrangement is projected to make certain that the switches inside the foremost leg working at zero-voltage switching from exact zero-load to full load, and also the buttons inside the covered leg running at zero-current switching with least duty rotation loss and passing transmission loss by considerably minimizing leak or sequence inductance. Results, from the experiment shows- a 3.4 kW hardware model showing that the circuit obtains true complete range soft switching using 98% max power. The hybrid resonant and pulse width modulation converter is attractive for electric automobile battery charger use.

8. Power Electronics Converters for Wind Turbine Systems:

The sturdy expansion of fixed wind power in concert with the up-scaling of the solitary wind turbine power potential has driven the research and development of power interpreters in the direction of full-scale power translation, low priced pr kW, amplified power concreteness, and also the requirement for advanced dependability. In this project, power converter technology is evaluated with a focus on present ones and especially on those that have prospective for amplified power but are not adopted yet cause of the significant risk linked with the high-power trade. The power interpreters are divided into single & multilevel topology, in the final project with concentration to sequence connection & parallel connection whichever electrical or magnetic. It is accomplished that as the level of power boots in windmills, average voltage power interpreters will be a governing power interpreter arrangement, but constantly price and dependability are vital subjects to be tackled.

9. Power Electronics Enabled Self-X Multi-cell Batteries:

A Design toward Smart Batteries – The very old multi-cell battery technique normally utilizes a preset design to fix several cells in sequence and parallel while functioning to achieve the necessary voltage and current. However, this secure design directs to low dependability, low error tolerance, and non-optimal energy translation effectiveness. This project suggests a fresh power electronics-allowed self-X, multi-cell battery device. The projected multi-cell battery will mechanically organize itself reliable with the active load/storage demand and so the situation of each cell. The projected battery can self-repair from a breakdown or unusual function of solo or several cells, self equilibrium from cell condition deviations, and self optimizes to achieve the best possible energy translation effectiveness. These alternatives are attained by a fresh cell switch circuit and a good performance battery administration scheme projected in this project. The projected blueprint is authenticated by activating and experimenting for a 6 by 3 cell polymer lithium-ion battery. The projected approach is common and will be functional to any sort or size of battery cells.

10. Ultra-Low Latency HIL Platform for Rapid Development of Complex Power Electronics Systems:

Ultra low latency HIL
Ultra-low latency HIL

Modeling and authentication of complex PE (power electronics) systems and direct algorithms can be an arduous and prolonged course of action. Even when a rare power hardware prototype is developed, it facilitates only a constrained look into a large number of running points; alterations in structure parameters regularly demanded hardware variations and unendingly there is the possibility of hardware break up. The ultra-low-latency HIL (Hardware-In-the-Loop) podium projected in this project unites the malleability, correctness, and accessibility of up to date simulation packages, with the reaction pace of small power hardware prototypes. In this mode, power electronics systems optimization, code development, and laboratory testing will be pooled into one single step, which noticeably boosts the speed of manufactured goods prototyping. Low power hardware models mutually go through from non-scalability; consequently of few parameters such as electrical engine inertia cannot be appropriately ranged. On the other hand, Hardware-In-the-Loop allows control prototyping that envelops all functional circumstances. To display Hardware-In-the-Loop principally based speedy growth, the authentication of a vigorous wetting algorithm for a PMSG (permanent magnet synchronous generator) flow is carried out. Two aims are set in this project: to authenticate the developed Hardware-In-the-Loop podium by way of evaluation with a low power hardware arrangement and then to follow the genuine, high-power structure to experiment the vigorous wet algorithm.

By using power electronics we can display a wide range of technologies being developed to maximize the production & efficient usage of both old & renewable energy sources. We here help electronic engineering students to get a hold of the most innovative, cost-effective power electronic projects along with this we assist students to address power challenges in down-hole applications.

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Photo Credit

Nuclear Radiation Detection by DVQ
RF Link Based DC Motor Control by 3.imimg
Ultra low latency HIL by powerguru


  1. Mini projects on power electronics

  2. Your website is really helpful to me…so thank you

  3. Gagandeep Singh says:

    Amazing project ideas. Thanx for sharing them. Really informative post…

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