1) I need a complete design like the image that I attached.
2) There are 9 blocks. They are grid block, load block, inverter block, battery block, solar block wind block, fuel cell block, measurement block, control block. (Rectifier block may be added later)…..
3)I will give you all the blocks which would be designed already….you need to adjust the power rating according my requirement and make the network stable..
4) Control system should be work like the following way….
Measure the value from the load
Measure the value from all types of generations
Calculate the power flow
Collect resulting current and voltage from load flow calculation
Supply the power generation according to the load demand. The power supply will depend according to the generation priority. The following generation will get the maximum priority (upper one will get 1st priority) for power supply.
1) Wind Power
2) Solar Cell
3) Fuel cell
4) Battery
5) Grid
When the generation is more than the demand load then calculate the surpassed production
Calculate the amount of surpassed production
Calculate the maximum discharge from the battery
Derive power flow to the Battery unit and calculate it
When the storage unit will be full charged then power flow supply to the battery unit will turned off.
Then the surpassed power will supply to the Grid
During the control design, following points must be consider
o Control P and Q set points for the energy hub (inverter/rectifier system)
o P > 0 the inverter feeds P into the network
o P < 0 the rectifier charges the battery
o And similar for Q
• Depending on the demand (or set point in the energy hub)
o Build small PID – type controllers (or just monitors in the case of wind and PV)
Each controller will have:
• P setpoint (e.g. P_setpoint_battery) – only to curtail for wind and PV
• P measured (e.g. P_measured_battery)
o Depending on the setpoints for the energy hub you will need to adjust the setpoints of the subsystems (like battery, fuel cell, wind and PV) connected to the DC bus.
o Increase simulation to 24h scale
o Simulation matches the time step of the data series.
Here is the power rating......
Energy hub 100kW (with adjustable P/Q) (Inverter/Converter)
Wind power 30kW
Solar 30kW
Battery max power output 75 kW (buck converter or charge
pump)
Battery max charge 60kW (buck converter or charge pump)
Dump load 100kW
Fuel cell 3kW
Electrolyzer 4kW
Load is 500 KW
Grid......500 KW
Can we go ahead , time is quite short now, Regards....................................................................................................................................................................
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Electrical Engineer (Gold-Medalist) from the oldest and the most reputable engineering institute of Pakistan (UET, Lahore). Done my internship @ US based R&D embedded company “Mentor Graphics” and currently working as Professional “Embedded Design Engineer” @ Asia’s #1 ranked R&D company “MicroTech Industries”…
Current Research Project:
Currently researching on MSP430 and Cortex M4 cores in order to find a solution for robust way of “Remote Firmware Up-gradation”. This research project is intended to save time and money needed for manual firmware up-kp;0ogradation. “MicroTech Industries” will be able to save millions of dollars per annum by having this feature embedded into its “Smart Energy Meters”
Other Distinguishing Characteristics:
1. Perfect Academic Record in Electronics+Circuit Design+DSP(A+ in all these subjects) during my BS Electrical Engineering
2. Done immense # of projects in Electronics/Telecomm including:
• Automated Room Temperature control by implementing Closed loop Feedback Controller
• Cellular AGC Design(Active Low pass filter)
• RFID Controlled using Smart Phone
• 2 Port LC Resonator circuit characterization
• DC-DC Flyback converter
• Direct AC-AC Converter
• Cellular CDMA receiver Design
• Score Keeping board with the time left indication (servo motor enabled)
3. Founding director of “AK Electronics Lab” in which I have personally purchased all required testing, debugging and small scale PCB manufacturing facilities