A smart off grid renewable power management system for an isolated island

A smart off grid renewable power management system for an isolated island.

Problem statement. Remote or isolated islands at present have: No or little access to the main grid for the electricity and existing power plants they have utilize only traditional energy resources for their operation like diesel generator, coal, and gas to justify the load demand which results in the high-cost electricity generation along with the environmental degradation. Being located far away from the main grid, association of long-distance results in the higher transmission losses, high operational and maintenance cost for expanded network. Problem justification: This problem needs to be addressed because the traditional energy resources are polluting the environment and despite charging more to those living in remote areas, energy providers are unable to justify the load demand in a sustainable and reliable way..

Deliverables of the project. The main deliverables of the project is as follows: Designing of off grid renewable power management system for an isolated island Identify the other alternative renewable energy resources. Simulation Results..

Site selection: North Shell island. Solar radiation in the north shell island is on average= 6.20 kWh/sq m/day Humidity= 58% Air temperature= 23 degree C Earth temperature= 25 degree C Source[1] Australian bureau of meteorological department.

Solar irradiance. Graphical user interface Description automatically generated.

Wind Speed. Graphical user interface, application, table, website Description automatically generated.

Load Demand Data. A screenshot of a computer Description automatically generated.

Design 1: PV, Diesel and battery storage system(HOMER).

Comparison to achieve the best case. Graphical user interface, chart, application Description automatically generated with medium confidence.

Electricity production. A picture containing graphical user interface Description automatically generated.

Emissions. Graphical user interface, text, application Description automatically generated.

Design 2: Wind, Diesel and battery storage system(HOMER).

Comparison. Graphical user interface, application Description automatically generated.

Electricity produce. Graphical user interface, application Description automatically generated.

Emission. Graphical user interface Description automatically generated with medium confidence.

Summary of contributions. Team member Major contribution Significance Hours spent in Iteration (1) Hamza Asif Designing of PV diesel and battery storage system To achieve the best optimal design which can helps us to achieve the goal 55 hours Ahsan Zaka Hafiz Designing of PV diesel and battery storage system To identifies the best case scenario to get the goals 54 hours.

Plan for next iteration. The plan for the next iteration is as follows: Get the simulation results on MATLAB Achieve all the goals that are related to our project Project closure..

Project Risks. The risks of the project is as follows: Unacceptability of the simulation base project from contactors. The increasing of time allocated to the project. Unexpected risks. Synchronization of the renewable resources. Risks related to software simulation The mitigation of the risks is as follows: We also take help from the project sponsor and library resources regarding the software. We use the MATLAB trouble shoot to make the error free model. We use the critical path to verify that the project is on time. Different technical skills to synchronize the model..

Thank you. Smiling Face with No Fill.