Modeling and Simulink of Fibonacci Spiral Blade Profiles in Vertical Axis Wind Turbines
Implementation plan:
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Scenario 1: Fibonacci spiral Blade Profile:
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Step 1: Initially, we will construct a Savonius VAWT wind turbine simulink model with Fibonacci spiral.
Step 2: Then, we Simulate Fibonacci spiral blade profile at different wind speeds.
Step 3: Next , we collect the data and preprocess it.
(Data :- Collect Power (P) (through Voltage (V) and current (I)), Torque (T) (Rotational torque), Rotational Speed (ω) (of turbine rotor for each wind speed), and Wind Speed (W))
Step 4: Next, we Calculate tip speed ratio (TSR), power coefficients (Cp), efficiency (η), and torque coefficient (Ct) for each blade profile
Step 5: Finally, we plot performance for the following metrics:
5.1: Tip speed ratio (TSR) vs. Power coefficients (Cp)
5.2: Tip speed ratio (TSR) vs. efficiency (η)
5.3: Tip speed ratio (TSR) vs. torque coefficient (Ct)
Scenario 2: Dürer spiral Blade Profile:
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Step 1: Initially, we will construct a Savonius VAWT wind turbine simulink model with Dürer spiral.
Step 2: Then, we Simulate Dürer spiral blade profile at different wind speeds.
Step 3: Next , we collect the data and preprocess it.
(Data :- Collect Power (P) (through Voltage (V) and current (I)), Torque (T) (Rotational torque), Rotational Speed (ω) (of turbine rotor for each wind speed), and Wind Speed (W))
Step 4: Next, we Calculate tip speed ratio (TSR), power coefficients (Cp), efficiency (η), and torque coefficient (Ct) for each blade profile
Step 5: Finally, we plot performance for the following metrics:
5.1: Tip speed ratio (TSR) vs. Power coefficients (Cp)
5.2: Tip speed ratio (TSR) vs. efficiency (η)
5.3: Tip speed ratio (TSR) vs. torque coefficient (Ct)
Scenario 3: Archimedean spiral Blade Profile:
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Step 1: Initially, we will construct a Savonius VAWT wind turbine simulink model with Archimedean spiral.
Step 2: Then, we Simulate Archimedean spiral blade profile at different wind speeds.
Step 3: Next , we collect the data and preprocess it.
(Data :- Collect Power (P) (through Voltage (V) and current (I)), Torque (T) (Rotational torque), Rotational Speed (ω) (of turbine rotor for each wind speed), and Wind Speed (W))
Step 4: Next, we Calculate tip speed ratio (TSR), power coefficients (Cp), efficiency (η), and torque coefficient (Ct) for each blade profile
Step 5: Finally, we plot performance for the following metrics:
5.1: Tip speed ratio (TSR) vs. Power coefficients (Cp)
5.2: Tip speed ratio (TSR) vs. efficiency (η)
5.3: Tip speed ratio (TSR) vs. torque coefficient (Ct)
Software Requirements:
1. Development Tool: Matlab-R2023a/Simulink and above
2. Operating System: Windows-10 (64-bit) or above
Note:
[1] If the above plan does not satisfy your requirement, please provide the processing details, like the above step-by-step.
[2] Please note that this implementation plan does not include any further steps after it is put into implementation.
[3] Please understand that any modifications made to the confirmed implementation plan will not be made before or after the project development.
[4] If the above plan satisfies your requirement please confirm with us.
