L'éolienne/en-gb : Différence entre versions

Étape 3 - L'éolienne - Le moteur

Choosing the motor

In general, the more steps the motor has, the lower the speed at constant voltage. Important technical data for the selection of the motor are : - The maximum or nominal voltage (measured in volts): Vmax - The current per phase (measured in amperes / phase): A/ph - Number of steps or step angle (measured in °)

For example, a stepper motor with an angle of 3.6° will have 360/3.6 = 100 steps, a 1.8° motor will have 360/1.8 : 200 steps . If you had to choose between two motors with identical characteristics (Vmax and A/ph), prefer the motor with the highest number of steps (here the 1.8° motor since it has 200 steps), it will require a lower rotation speed to deliver a satisfactory voltage.

The choice of motor will also be conditioned by the maximum voltage (Vmax). A motor characterized at 3V will deliver a much lower power than a motor characterized at 50V at the same rotation speed. Choose your motor (within the limit of the available choice) according to the desired application and the required power.

1 - Cut the 6 wires coming out of the stepper motor, strip and twist them.

From the two possible methods:

Method #1

In order to find out which of the 6 wires has the highest output voltage, all possible motor output torques must be tested and the two highest selected.

2 - Using a screwdriver, a voltmeter set to " AC " and alligator clips, test the pairs of wires. Note the tension for each pair. (picture 1)

3 - Select the two wire pairs with the highest output voltage (here 10V, this may vary depending on the motor). These will then be connected to the electrical circuit of the wind turbine.

* Tip: Mark with colored tape the two selected couples so they don't get mixed up with each other.

Method #2

In fact, stepper motors are schematically made up of two or four coils:

(picture 2)

As described in the picture, in the case of a 6-wire we will not use the mid-point. In fact, we will accumulate two coils to make one and generate more tension.

From this point, it's very simple:

1) Just put your multimeter in ohm meter mode, or even better in contact detection mode (you know when it does "BBIIIIPPPPP !!" when the two probes are touching ).

2) The first step is to separate the two sets of wire for each coil.

For a 4-wire system, it's very simple: you take one wire on one probe, and with the other probe you touch the other wires. When there is one that goes "BBBIIIIIPPPPP!!" or the measured resistance becomes low (it depends on the motor but a wide range would be 1 to 50 ohms) you are good you have found your coil and by elimination the two remaining wires are for the other coil.

For a 6 wire it is hardly more complex: we apply the same method to determine the sets of 3 wires per spool. Then we switch to ohmeter mode and look for which pair of wires per coil gives the highest pllus resistance ==> bingo you have found the right wires for one coil, repeat the operation for the other and you are good.

Note: there are also 8 wires. In fact it is a 6-wire (so 4 coils) but with 4 independent coils (like a 4-wire so ...). So use the 4-wire method but more times.

Étape 4 - The Wind Turbine - Motor Axis

1 - Cutting a metal plate of 80x30 cm. Drill it with 5 holes of diameter 4mm.

* Tip: You can use figure 1 above to cut and drill the plate.

2 - Weld the motor shaft to the central hole of the metal plate (picture 2).

Étape 5 - The Wind Turbine - Blade Preparation

From the formula linking the wind speed, a given surface and the power of the wind on this surface :

This formula can be used to calculate the length of the blades of the wind turbine:

Where:

• L = blade length in m
• P = characteristic power of the motor in W
• V = wind speed in m/s (depending on location)

Under normal conditions, the length of the blade should be 35 cm.

1 - Draw and cut the blades in a PVC tube. (picture 3).

* Tip: You can help yourself from the diagram 2 above to draw the shape of the blades.

Figure 3 shows the cutting direction.

2 - Sand the edges of each of the blades: the leading edge must be rounded, and the trailing edge sharpened.

3 - Drill the blades: the drilling is carried out as close as possible to the trailing edge so that the latter can be fixed flat on the plate that carries the blades. (image 4)

Your blades are ready!

Étape 6 - The Wind Turbine - Fins and Blade Bases

1 - In a wooden board, draw and cut out the fin. (image 5)

* Tip: You can use figure 3 above to draw the shape of the fin.

2 - In the same board, cut out a square the size of your engine (here 80x80cm) which will be used to accommodate the blades previously cut out in order to join them together. (diagram 3 - base of the blades).

3 - On the aileron, mark the location of the motor so that it can be forced into the shape. (diagram 3 - motor)

* Note: The dimensions of this part depend on the size of your motor.

4 - Sand the edges of the aileron for better aerodynamics and better rendering. (frame 5)

Étape 8 - The electrical circuit - Rectifiers

The electrical circuit is as shown in "Figure 4".

At the output of the engine, we get alternating current (AC). However, to charge a battery or light a lamp, it is necessary to have direct current (DC). Two rectifiers are used to transform alternating current into direct current: they "rectify" the voltage at the output of the motor.

Each rectifier has 4 legs: The two central legs are the alternating poles of the capacitor. The two outer legs are the positive and negative poles of the capacitor.

* Tip: on the rectifier head each of these 4 poles are marked

1 - Solder the stepper motor voltage outputs (previously selected) to the alternating inputs of each rectifier: the first torque with the alternating poles of the first rectifier, and the second torque with the alternating poles of the second rectifier.(image 7).

* Tip: It is possible to use heat shrink tubing to cover the connections to protect the system.

2 - Solder the negative outputs of the two rectifiers together, then solder the positive outputs of the two rectifiers together. "(picture 8).

Étape 10 - The electrical circuit - Voltage regulator or voltage booster

The voltage regulator makes it possible to recover a 5V output current.

*Note: Each controller is different, if you want a 12V output, for example, buy your controller accordingly. Here to connect a USB port we'll use a 5V one.

The voltage regulator has 3 different rods : - 1 entry - 1 common - 1 exit

1 - Solder the negative pole of the capacitor with the common of the voltage regulator. Solder the plus of the capacitor to the input of the voltage regulator.(image 10)

Alternative: use a voltage booster that will provide an output voltage of 5V (USB) with an input voltage ranging from 0.9 to 5V.

Étape 11 - The electrical circuit - Connecting the USB port

When you place your connector on a table with the plastic tab facing up, the right tab is your positive terminal, and the left tab is your negative terminal.

1 - Solder a red wire to the positive terminal and a black wire to the negative terminal. These will be the output wires of your wind turbine, to which you can connect a battery, a light bulb, etc, and in this case a USB port. (picture 11)

2 - Solder the red wire to the regulator output and the black wire to the regulator common. (image 12).

Your circuit's ready to go. You can connect a telephone to it, provided there is wind of course.(picture 13)'