1. Integrated Photovoltaic Power Management
System (IPPMS) :
Name: Umar Maroof FA17-EPE-037
Name: Jawad Ahmed FA17-EPE-027
Name: Usman Sajid FA17-EPE-039
Supervisor:
Engr. Saima Ali
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2. Contents
Problem Statement
Proposed System Introduction
Objective
Block Diagram
Components
Workflow
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3. Problem Statement
Energy we use normally is not renewable and we also
have to depend on different companies for power supply
and most importantly that power is financially
expensive. To resolve this issue we have selected IPPMS.
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4. Objective
This system gives priority to the solar power so that low power is
taken from the grid and provide surplus energy to the grid. As a
result, the net electricity bill will be reduced and accelerate the
electricity production of a country.
Moreover we will have an IOT application which is to be used for
remote monitoring of the proposed system.
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5. Definition
The PV power system can provide a continuous power supply during
the grid blackouts, and it can inject the excess produced power in the
electrical grid during the day periods.
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6. Proposed System Introduction
In this project an intelligent system will be designed to support the
continuous power flow to user by integrating the Instant Power
Supply (IPS) and solar power technologies.
Another benefit of this system is that it can provide surplus energy
back to the grid and save’s consumer from heavy burden of electricity
bills.
Countries like Pakistan where the demand of electricity increasing
day by day, this system can be used very efficiently. People can get rid
from load shedding by using this system.
IOT based remote monitoring with a mobile application using Blynk.
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7. Advantages
Reduced electricity bills.
Benefit for the environment.
Take some pressure off electric grids.
Encourages customers to move towards renewable energy.
Preserves natural energy resources.
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8. Components
Arduino
Ac voltage and current sensor
Relays
Lcd
Charge controller
Battery
Solar panel
Inverter
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9. Arduino
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It is a physical Input/ Output
board with a programmable
integrated Circuit. It also
include Integrated
development Environment(IDE)
for programming.
10. Mobile Application
Widgets to visualize sensor data.
User friendly GUI.
Blynk cloud.
Access with internet anywhere in the world.
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13. Conclusion
Grid Tie System is the simplest and most cost-effective way to
connect PV modules to regular utility power.
Grid-Connected systems can supply solar power to our home and use
utility power as a backup.
As long as there is enough electricity flowing in from our PV system,
no electricity will received from the utility company.
If our system is generating more power than we are using, the excess
will flow back into the grid, turning our meter backwards.
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14. Workflow
Phase 1 Presentation 1:
Idea presentation and
introduction.
Presentation 2:
Literature review and interfacing
of sensors with controller.
Phase 2 Presentation 3:
70 percent completion of
project.
Presentation 4:
Finalization and complete
running.
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15. References
Akindele, D.O.; Rayudu, R.K. Comprehensive techno-economic and
environmental impact study of a localized photovoltaic power system (PPS)
for off-grid communities. Energy Convers. Manag. 2016, 124, 266–279.
[CrossRef] 6. Seaward. Solar Survey Multifunction Solar Irradiance Meters,
2017. Available online: http://
www.seawardsolar.com/downloads/survey_100_and_200r_datasheets_internat
ional_v1.3.pdf (accessed on 14 January 2018).
Zeqiang, B.; Wenhua, L.; Yinzhou, S.; Xiao lei, H.; Wei, C. Research on
performance test method of silicon pyranometer. In Proceedings of the 2013
IEEE 11th
https://blynk.io/en/getting-started
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