METHODOLOGY : In our present study planning to develop a hybrid power generation model consists of Rain water power(hydro), Solar PV and Wind energy, the process of working and installation as below: Rainwater harvesting is the accumulation and deposition of rainwater for reuse before it reaches the aquifer. In this technique, we channel the water falling on roof tops of buildings and homes, and open spaces to a storage tank through a filter. Excess water is directed to a well or pit through which water seeps in earth to increase water table. The generated power is converted and collected using power electronics and power systems devices respectively. OBJECTIVES : To install Solar PV technology in order to trap solar radiation for converting into electrical energy. To install the wind turbine for converting wind energy into electrical energy to pump the water for hydro-plant. Integrate the complete system composed of hydro, solar, wind energy Assess the performance of the system.

1. JSS ACADEMY OF TECHNICAL EDUCATION, NOIDA
DEPARTMENT OF ELECTRICAL ENGINEERING
Supervisor
(Dr. Abhinav Saxena)
(Asst. Professor)
1. Varun Sharma(EE)
2. Sarvesh Kumar Maurya(EE)
3. Himanshu Kumar(EE)
4. Sangram Singh(EE)
5. Shivansh Pandey(EE)
‘DEVELOPMENT OF HYBRID POWER GENERATION
MODEL USING RAIN-WATER, SOLAR & WIND ENERGY’
GROUP PROJECT

2. CONTENTS/OUTLINE OF PRESENTATION
1) Objectives
2) Methodology
3) Timeline/Progress
4) Block Diagram
5) Topology For Proposed Topic
6) Conclusion
7) References

3. OBJECTIVES
1) To install Solar PV technology in order to trap solar radiation for converting into
electrical energy.
2) To install the wind turbine for converting wind energy into electrical energy to pump
the water for hydro-plant.
3) Integrate the complete system composed of hydro, solar, wind energy
4) Assess the performance of the system in different environmental condition & different
loading condition.

4. METHODOLOGY
• In our present study planning to develop a hybrid power generation model consists of Rain
water power(hydro), Solar PV and Wind energy, the process of working and installation as
below:
• Rainwater harvesting is the accumulation and deposition of rainwater for reuse before it
reaches the aquifer.
• In this technique, we channel the water falling on roof tops of buildings and homes, and
open spaces to a storage tank through a filter. Excess water is directed to a well or pit
through which water seeps in earth to increase water table.
• The generated power is converted and collected using power electronics and power systems
devices respectively.

5. TIMELINE
• MINOR PROJECT- The literature review & design of hybrid power generation
system is simulated on SIMULINK/MATLAB.(Task for the month of November &
December) - COMPLETED
• MAJOR PROJECT- In this we will analyze the working of fundamental components
through designing & implementing i.e. Hybrid Power Generation Model & validate
the results obtained from simulation(Task for the month from January to april)
• Our proposed hybrid model will optimize the energy requirement using non-
conventional energy resources and will be vital for progress of any nation.

6. Block Diagram of the Hybrid power System model

7. Architectural Diagram of the Hybrid power System model

8. SIMULINK MODEL

9. SOLAR WAVEFORM

10. BATTERY & SOLAR WAVEFORM

11. Mathematical equations which controls the photovoltaic
characteristics

12. Constants and variables used:

13. WIND WAVEFORM

14. WIND OUTPUT

15. HYDRO DC WAVEFORM

16. HYDRO DC VOLTAGE OUTPUT

17. OUTPUT SUPPLY VOLTAGE

18. CONCLUSION
• A complete hybrid power system of this nature may be too expensive and too labor intensive for many
Industrial Technology Departments.
• Besides being pollution free, they are free recurring costs.
• They also offer power supply solutions for remote areas, not accessible by the grid supply.
• Hybrid systems can address limitations in terms of –
Fuel Flexibility, Efficiency, Reliability, Emissions, Economics
Hybrid power systems can also be used to reduce energy storage requirements.
By integrating and optimizing the solar photovoltaic and wind systems, the reliability of the systems
can be improved and the unit cost of power can be minimized.
In India the Solar-Wind Hybrid power plants are technically approved by the Ministry of New and
Renewable Energy (MNRE).

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