L293d Motor Driver Circuit Pdf
H Bridge Motor Control Circuit Using L293d IC H-Bridge Circuit A H bridge is an electronic circuit that allows a voltage to be applied across a load in any direction. H-bridge circuits are frequently used in robotics and many other applications to allow DC motors to run forward & backward.
Although the SGS Thompson L293D can take logic motor voltage of up to 36 volts, we don’t recommend running both beyond 12 volts. The VccL line really only needs 5 volts to run the “brains” of the chip. Beyond that, you start consuming the valuable power-handling ability of the chip for just powering the IC’s brains.
These motor control circuits are mostly used in different converters like DC-DC, DC-AC, AC-AC converters and many other types of. In specific, a bipolar stepper motor is always driven by a motor controller having two H-bridges H-Bridge Circuit A H-bridge is fabricated with like S1, S2, S3 and S4. When the S1 and S4 switches are closed, then a +ve voltage will be applied across the motor. By opening the switches S1 and S4 and closing the switches S2 and S3, this voltage is inverted, allowing invert operation of the motor. Generally, the H-bridge motor driver circuit is used to reverse the direction of the motor and also to break the motor.
When the motor comes to a sudden stop, as the terminals of the motor are shorted. Or let the motor run free to a stop, when the motor is detached from the circuit. The table below gives the different operations with the four switches corresponding to the above circuit. Operation of the H-Bridge L293D Motor Driver IC L293D IC is a typical Motor Driver IC which allows the to drive on any direction. This IC consists of 16-pins which are used to control a set of two DC motors instantaneously in any direction. It means, by using a L293D IC we can control two DC motors. As well, this IC can drive small and quiet big motors.
This L293D IC works on the basic principle of H-bridge, this circuit allows the voltage to be flowing in any direction. As we know that the voltage must be change the direction of being able to rotate the DC motor in both the directions. Hence, H-bridge circuit using L293D ICs are perfect for driving a motor. Single L293D IC consists of two H-bridge circuits inside which can rotate two DC motors separately. Generally, these circuits are used in robotics due to its size for controlling DC motors. Pin Diagram of a L293D Motor Driver IC Controller L293D IC Pin Configuration.
Pin-1 (Enable 1-2): When the enable pin is high, then the left part of the IC will work otherwise it won’t work. This pin is also called as a master control pin. Pin-2 (Input-1): When the input pin is high, then the flow of current will be through output 1. Pin-3 (Output-1): This output-1 pin must be connected to one of the terminals of the motor. Pin4 &5: These pins are ground pins.
Pin-6 (Output-2): This pin must be connected to one of the terminals of the motor. Cheque printing software free download india with crack. Pin-7 (Input-2): When this pin is HIGH then the flow of current will be though output 2.
Pin-8 (Vcc2): This is the voltage pin which is used to supply the voltage to the motor. Pin-16 (Vss): This pin is the power source to the integrated circuit. Pin-15 (Input-4): When this pin is high, then the flow of current will be through output-4. Pin-14 (Output-4): This pin must be connected to one of the terminals of the motor. Pin-12 & 13: These pins are ground pins. Pin-11 (Output-3): This pin must be connected to one of the terminals of the motor.
Pin-10 (Input-3): When this pin is high, then the flow of current will through output-3. Pin-9 (Enable3-4): When this pin is high, then the right part of the IC will work & when it is low the right part of the IC won’t work.
This pin is also called as a master control pin for the right part of the IC. H Bridge Motor Control Circuit Using L293d IC The IC LM293D consists of 4-i/p pins where, pin2 and 7 on the left side of the IC and Pin 10 and 15 on the right side of the IC. Left input pins on the IC will control the rotation of a motor. Here, the motor is connected across side and right i/p for the motor on the right hand side. This motor rotates based on the i/ps we provided across the input pins as Logic 0 and Logic 1. H-bridge Motor Circuit with L293D IC Let’s consider, when a motor is connected to the o/p pins 3 and 6 on the left side of the IC. For rotating of the motor in clockwise direction, then the i/p pins have to be provided with Logic 0 and Logic 1.
When Pin-2= logic 1 & pin-7 = logic 0, then it rotates in clockwise direction. Pin-2=logic 0 & Pin7=logic 1, then it rotates in anti clock direction Pin-2= logic 0 & Pin7=logic 0, then it is idle (high impedance state) Pin-2= logic 1 & Pin7=logic 1, then it is idle In a similar way the motor can also operate across input pin-15 and pin-10 for the motor on the right hand side. The L4293D motor driver IC deals with huge currents, due to this reason, this circuit uses a heat sink to decrease the heat. Therefore, there are 4-ground pins on the L293D IC.
When we solder these pins on the PCB (printed circuit board), then we can get a huge metallic area between the ground pins where the heat can be produced. This is all about Using L293d IC. These ICs are generally used in robotics. We hope that you have got a better understanding about the concept of H-bridge.
Furthermore, any queries regarding H bridge motor driver IC l293d or, please give your feedback in the comment section below. Here is a question for you, what is the purpose of moor driver IC?
What Is Motor Driver IC? A motor driver IC is an integrated circuit chip which is usually used to control motors in autonomous robots. Motor driver ICs act as an interface between microprocessors in robots and the motors in the robot.
The most commonly used motor driver IC’s are from the L293 series such as L293D, L293NE, etc. These ICs are designed to control 2 DC motors simultaneously. L293D consist of two H-bridge. H-bridge is the simplest circuit for controlling a low current rated motor. For this tutorial we will be referring the motor driver IC as L293D only. L293D has 16 pins, they are comprised as follows: Ground Pins - 4 Input Pins - 4 Output Pins - 4 Enable pins - 2 Voltage Pins - 2 The workings of the individual pins are explained in detail, later in the tutorial. Why We Need Motor Driver IC?
Motor Driver ICs are primarily used in autonomous robotics only. Also most microprocessors operate at low voltages and require a small amount of current to operate while the motors require a relatively higher voltages and current. Thus current cannot be supplied to the motors from the microprocessor. This is the primary need for the motor driver IC. How Motor Driver Operates? The L293D IC receives signals from the microprocessor and transmits the relative signal to the motors. It has two voltage pins, one of which is used to draw current for the working of the L293D and the other is used to apply voltage to the motors.
L293d Motor Driver Board
The L293D switches it output signal according to the input received from the microprocessor. For Example: If the microprocessor sends a 1(digital high) to the Input Pin of L293D, then the L293D transmits a 1(digital high) to the motor from its Output Pin. An important thing to note is that the L293D simply transmits the signal it receives. It does not change the signal in any case. L293D And Its Working The L293D is a 16 pin IC, with eight pins, on each side, dedicated to the controlling of a motor.
There are 2 INPUT pins, 2 OUTPUT pins and 1 ENABLE pin for each motor. L293D consist of two H-bridge. H-bridge is the simplest circuit for controlling a low current rated motor. The Theory for working of a H-bridge is given below. Working Of A H-bridge H-bridge is given this name because it can be modelled as four switches on the corners of ‘H’. The basic diagram of H-bridge is given below: In the given diagram, the arrow on the left points to the higher potential side of the input voltage of the circuit. Now if the switches S1 & S4 are kept in a closed position while the switches S2 & S3 are kept in a open position meaning that the circuit gets shorted across the switches S1 & S4.
This creates a path for the current to flow, starting from the V input to switch S1 to the motor, then to switch S4 and then the exiting from the circuit. This flow of the current would make the motor turn in one direction. The direction of motion of the motor can be clockwise or anti-clockwise, this is because the rotation of the motor depends upon the connection of the terminals of the motor with the switches. For simplicity, lets assume that in this condition the motor rotates in a clockwise direction. Now, when S3 and S2 are closed then and S1 and S4 are kept open then the current flows from the other direction and the motor will now definitely rotates in counter-clockwise direction When S1 and S3 are closed and S2 and S4 are open then the ‘STALL’ condition will occur(The motor will break). Stall Condition: When the motor is applied positive voltage on both sides then the voltage from both the sides brings the motor shaft to a halt L293D Pin Diagram: In the above diagram we can see that, Pin No.
Pin Characteristics 1 Enable 1-2, when this is HIGH the left part of the IC will work and when it is low the left part won’t work. So, this is the Master Control pin for the left part of IC 2 INPUT 1, when this pin is HIGH the current will flow though output 1 3 OUTPUT 1, this pin should be connected to one of the terminal of motor 4,5 GND, ground pins 6 OUTPUT 2, this pin should be connected to one of the terminal of motor 7 INPUT 2, when this pin is HIGH the current will flow though output 2 8 VC, this is the voltage which will be supplied to the motor. So, if you are driving 12 V DC motors then make sure that this pin is supplied with 12 V 16 VSS, this is the power source to the IC. So, this pin should be supplied with 5 V 15 INPUT 4, when this pin is HIGH the current will flow though output 4 14 OUTPUT 4, this pin should be connected to one of the terminal of motor 13,12 GND, ground pins 11 OUTPUT 3, this pin should be connected to one of the terminal of motor 10 INPUT 3, when this pin is HIGH the current will flow though output 3 9 Enable 3-4, when this is HIGH the right part of the IC will work and when it is low the right part won’t work.
So, this is the Master Control pin for the right part of IC Soldering On A PCB Given below is the circuit diagram for how the IC needs to be soldered on a PCB with the connectors. From a six pin relimate INPUT 2, INPUT 1, ENABLE 1-2,ENABLE 3-4,INPUT 3 and INPUT 4 are given.
The inputs to the DC motors are to be given through a two pin relimates whose connectors is shown in the left and right side of the figure. Working Mechanism Now depending upon the values of the Input and Enable the motors will rotate in either clockwise or anticlockwise direction with full speed (when Enable is HIGH) or with less speed (when Enable is provided with PWM). Let us assume for Left Motor when Enable is HIGH and Input 1 and Input 2 are HIGH and LOW respectively then the motor will move in clockwise direction. So the behaviour of the motor depending on the input conditions will be as follows: INPUT 1 INPUT 2 ENABLE 1,2 Result 0 0 1 Stop 0 1 1 Anti-clockwise rotation 1 0 1 Clockwise rotation 1 1 1 Stop 0 1 50% duty cycle Anti-clockwise rotation with half speed 1 0 50% duty cycle Clockwise rotation with half speed Why 4 grounds in the IC? The motor driver IC deals with heavy currents. Due to so much current flow the IC gets heated. So, we need a heat sink to reduce the heating.
Therefore, there are 4 ground pins. When we solder the pins on PCB, we get a huge metalllic area between the grounds where the heat can be released. Why Capacitors? The DC motor is an inductive load. So, it develops a back EMF when supplied by a voltage. There can be fluctuations of voltage while using the motor say when suddenly we take a reverse while the motor was moving in some direction. At this point the fluctuation in voltage is quite high and this can damage the IC.
Thus, we use four capacitors that help to dampen the extreme variation in current.