Welcome to the dynamic world of Electrical and Electronics Engineering (EEE) at KR Engineering College! Here, we ignite innovation and empower the next generation of engineers to shape our connected future. Our program delves into the core principles that power everything from smart grids and renewable energy systems to cutting-edge electronics and intelligent automation. Through hands-on labs and expert mentorship, you'll gain practical skills vital for real-world challenges, enabling you to explore, design, and build the technologies that drive progress and transform lives, preparing you for diverse and impactful careers across industries.

The field of Electrical and Electronics Engineering is at the forefront of technological evolution, driving innovations in renewable energy, smart grids, AI-driven automation, and IoT. At KLR Engineering College, we foster a dynamic learning environment where students gain cutting-edge knowledge and practical expertise to excel in this transformative industry. Our industry-aligned curriculum, state-of-the-art labs, and expert faculty prepare graduates to tackle real-world challenges and lead the next wave of sustainable engineering solutions. Step into a future of endless possibilities with a strong foundation in EEE.

Future Horizons EEE

Career Opportunities

Electrical & Electronics Engineering (EEE) unlocks a world of exciting career possibilities across traditional and cutting-edge fields. From power systems and renewable energy to robotics, electric vehicles, and smart grid technologies, EEE graduates are shaping the future of how we live and work. You'll find opportunities in power plants, manufacturing, semiconductor industries, and research organizations, with high demand in both private sector and government PSUs like NTPC and BHEL. The digital transformation has opened new doors in IoT, embedded systems, and industrial automation, while the global push for sustainability creates growing needs in solar, wind, and hybrid energy solutions. At KLR Engineering College, we prepare you for these diverse paths through hands-on training, industry-relevant curriculum, and practical problem-solving skills - equipping you not just for jobs, but for leadership in tomorrow's energy and technology revolutions. Whether you aspire to work with global corporations, pursue research, or launch your own tech venture, an EEE degree from KLR provides the perfect launchpad for a rewarding career at the forefront of innovation.

Academic Timeline

First Two Years:

• Master fundamentals: Circuits, Power Systems, Electronics & Control Theory

• Hands-on labs with industrial-grade equipment

• Workshops on electrical safety and standards

Third Year:

• Specialize in high-demand areas: Renewable Energy, Smart Grids, EV Tech, Industrial Automation

• Work on live industry problems through mini-projects

• Certification courses in PLC/SCADA, Solar Design, etc.

Final Year:

• Capstone project addressing real-world energy challenges

• Dedicated placement training with resume building & mock interviews

• Career guidance for core electrical/IT sectors

Admission Procedure

For 12th Science Students:

1. Take the EAMCET exam (we'll help you prepare)

2. Choose KLR during counseling

3. Start your 1st year of B.Tech EEE.

For Diploma Holders (Lateral Entry):

1. Appear for ECET exam

2. Apply through special counseling

3. Join directly in 2nd year of B.Tech

We keep admissions simple because we'd rather focus on what matters - your future in technology. Our admission team will personally guide you through forms, deadlines and any questions.

Core Curriculum Offerings

Our Electrical and Electronics Engineering (EEE) curriculum is designed to provide a strong foundation in electrical circuits, electronics, power systems, control systems, and renewable energy technologies. The program blends theoretical knowledge with practical application through advanced laboratories, industry-relevant projects, and hands-on workshops. Students gain valuable experience in emerging areas like smart grids, electric vehicles, embedded systems, and automation. With a focus on innovation and problem-solving, the curriculum prepares future-ready engineers capable of addressing global energy challenges and contributing to technological advancement with skill and confidence.

The department features well-equipped laboratories including the DC Machines Lab, AC Machines Lab, Electric Circuits and Devices Lab, Measurement and Instrumentation Lab, Control Systems Lab, Power Electronics Lab, Microprocessor & Microcontroller Lab, and Computer & Simulation Lab. All labs are furnished with modern, industry-standard equipment to support hands-on learning and research. These facilities enable students to apply theoretical knowledge to practical experiments and projects. Regular upgrades ensure our labs stay aligned with evolving technological advancements in electrical engineering

Electrical Circuits Laboratory

An electronic circuit is composed of individual electronic components, such as resistors, transistors, capacitors, inductors and diodes, connected by conductive wires or traces through which electriccurrent can flow. To be referred to as electronic, rather than electrical, generally at least one active component must be present. The combination of components and wires allows various simple and complex operations to be performed: signals can be amplified, computations can be performed, and data can be moved from one place to another

Electronics Lab Practice

The Electronics Laboratory provides students with a practical environment to understand the fundamental principles of electrical and electronic engineering. Through structured experiments, students explore key topics such as current, voltage, resistance, power, and efficiency, along with standard engineering units and notations. The lab emphasizes the application of basic laws, including Ohm’s and Kirchhoff’s, to analyze series, parallel, and combination resistive circuits. This approach supports the reinforcement of theoretical knowledge and lays the groundwork for further studies in electronics.

Power Electronics Lab

The journey of power electronics began with Peter Cooper Hewitt's revolutionary mercury arc rectifier in 1902, which first enabled efficient AC-to-DC conversion. Through the 1920s, researchers advanced the technology by adapting thyratrons and mercury arc valves for power transmission applications, culminating in Uno Lamm's breakthrough high-voltage DC transmission valves featuring grading electrodes. The field took another significant step forward in 1933 with the invention of compact selenium rectifiers, marking crucial milestones in the evolution of power conversion technologies that would ultimately lead to today's sophisticated systems.

Electrical Machine Laboratory