Generally speaking, a solar cell with such a small area as you mentioned cannot drive a motor, because the power of the motor is very large and the required current is also large. First of all, you need to know the output power that the solar cell can have, and then analyze whether it can drive the motor. The circuit is as follows: First use the voltage range of a multimeter to measure the voltage value at the positive and negative terminals of the solar cell? Then use an ammeter in series with an adjustable resistor to measure the current value the battery can produce. Once you know the output voltage and current, you can roughly estimate how much power the solar cell can generate and how much power the battery can drive the motor.
In search of the principle of the Mendocino engine
The advantages of theClean, pollution-free and low-cost solar energy are obvious. As long as the surface area of the solar panel is large enough to power a 3000 watt motor, there will be no problem. The problem is that its power output is unstable. Therefore, changes in the power supplied to the motor will affect the power output of the motor. The engine sometimes speeds up and sometimes slows down. For reference only. THANKS.
First, we need to understand from the structure of the Mendocino rotor that it will continue to rotate even without magnetic levitation. Domencino is a solar panel that generates a magnetic field for the coil when exposed to light. After turning a certain angle, the power weakens and the magnetism disappears, and the solar panel on the other side continues to generate electricity to generate a magnetic field. It will continue to rotate due to inertia. The four-part Domencino consists ofe two opposing solar cells connected in series to power a set of coils. After a 90 degree rotation, the power is turned off and the solar cell on the other side provides kinetic energy to continue cutting the magnetic field lines. Suppose A1A2 is the opposite surface and B1B2 is the opposite surface. A1 lighting causes the coil to generate a magnetic field and rotate 90 degrees. Light shift (power fade) is caused by lighting B1 and rotating it continuously 90 degrees. And so on. Light in the opposite direction will rotate in the opposite direction, because the lighting sequence changes. I wonder if everyone can understand? If it does not turn, the direction of the spool may be wrong. Simply reverse the polarity of one of the coils to change the direction of the magnetic field.