We've already covered in several articles the working principle of the PWM controls which are much better than the linear controls that present losses.

If you want to know more about the working principle of these controls, which is the same from the circuit shown in this article see more articles in this site.

 

How it works

In our circuit, we do is the traditional control, by changing the active cycle of a rectangular signal according to the power that we want to apply to the engine.

Figure 1 shows that in a control by pulses, what matters is the area of ??the figure covered by the graph, as it determines the power applied.

 

 

  Figure 1 - The areas under (A) and (B) are the same, indicating the same power
Figure 1 - The areas under (A) and (B) are the same, indicating the same power

 

 

Thus, to control the applied power, we simply generate a rectangular signal and change the width of the pulses, or their separation, as shown in Figure 2.

 

 

  Figure 2 - Changing the Power
Figure 2 - Changing the Power

 

 

To generate signals with active cycles that can be controlled we use one of the triggering ports of the integrated circuit 4093, as shown in Figure 3.

 

 

  Figure 3 - Changing the active cycle of an oscillator 4093
Figure 3 - Changing the active cycle of an oscillator 4093

 

 

In this circuit, the capacitor charging current is performed by a diode and it determines the time at which the output signal is at high level.

Moreover, the discharge is made by the other diode, which determines the time in which the output is at the low level.

As the resistors are associated with these diodes to determine the time, if one is variable, we can control both the duration of the pulses as the separation.

This is precisely what we do in our circuit by connecting in series with one of them a pot of control, which will be the speed control.

The signal generated by this circuit is digitally amplified and applied to a transistor which switches a LM350T regulator integrated.

This 3-terminal regulator can control currents up to 3 A, and been then digitally modulated by the oscillator.

At the output we have the voltage pulses that can be applied to a load up to 3 A.

 

Assembly

In Figure 4 we have the control of the complete diagram PWM.

 

 

  Figure 4 - Diagram of the PWM control
Figure 4 - Diagram of the PWM control

 

 

In Figure 5 we have a suggested printed circuit board for the assembly.

 

 

  Figure 5 - Suggestion of board for the assembly.
Figure 5 - Suggestion of board for the assembly.

 

 

The LM350T integrated circuit should be provided with an appropriate heat sink.

For other components note the positions of the 4093 integrated circuit, of the transistors and of the diodes.

The resistors are 1/8 W and the pot can be lin or log.

 

Test and Use

To test, connect to the engine output of 6 to 15 V with a maximum current of 3 A.

Power the circuit with the engine rated voltage and adjust P1 to check the speed, refinishing the minimum point P2 (trimpot).

If the motor tends to vibrate too much, which may occur in some cases, change the value of C2, operating in another frequency range.

Proven the operation, you only need to use it, within the circuit current limit.

The circuit can also operate as a dimmer for heating elements and incandescent bulbs or LED sequences with reduced resistors.

 

CI-1-4093 - Integrated circuit

CI-2 - LM350T - Integrated circuit

Q1 - BC548 – general purpose NPN transistor

D1, D3 - 1N4148 - Silicon diodes

D2 - 1N4004 - Silicon diode

P1 - 2M2 Ω - pot

P2 - 10k - A trimpot

R1 – 100 k Ω x 1/8 W - resistor - brown, black, yellow

R2 - 15 k Ω x 1/8 W - resistor - brown, black, green

R4 - 220 Ω x 1/8 W - resistor - red, red, brown

C1 - 220 µF x 25 V - electrolytic

C2 - 47 nF - ceramic capacitor or polyester

Miscellaneous:

A printed circuit board, a radiator for the IC,a box for the assembly, wires, welding, etc.

 

 

 

Datasheets


N° of component