Boost Your DIY Projects with the Dual H-Bridge Motor Module Kit

The Dual H-Bridge Motor Module Kit is a powerful and versatile tool designed for hobbyists, students, and engineers working on robotics and electronics projects. This all-in-one kit includes 2 L298N motor drive modules, 4 TT motors with strong driving capabilities, and a set of 60 jumper wires, making it ideal for building dynamic and tech-driven DIY projects.

The Dual H-Bridge Motor Module Kit provides the perfect foundation for your robotics projects. With its ability to control two motors simultaneously, you can create complex and dynamic movements. Ready to build? Explore the Dual H-Bridge Motor Module Kit in our online store here! 

• Comprehensive Kit Components:

  • 2 L298N modules.

  • 4 high-quality TT motors with wheels.

  • 20 jumper wires (female to female).

  • 20 jumper wires (male to male).

  • 20 jumper wires (male to female).

Applications of H-Bridge Motor Module Kit

This kit is perfect for various DIY applications, including:

• Building remote-controlled cars.

• Developing robotic arms and electronic toys.

• Powering small electronic machinery and educational projects.

Specifications

TT Motors:

• Reduction ratio: 1:48.

• No-load speed at 6V: 200 RPM (±10%).

• No-load speed at 3V: 90 RPM (±10%).

Ready to get started? Find the L298N Motor Driver Module in our online store here! 

5V Input: Powers the logic circuitry and enables the onboard 5V regulator.

Channel-A Enable: Controls the enable pin for the first H-bridge (Channel A).

Channel-B Enable: Controls the enable pin for the second H-bridge (Channel B).

Logic Input: These pins (In1, In2, In3, In4) determine the direction of the motors.   

Output Pins:

OUT1-OUT4: These are the motor output pins. The H-bridge switches the voltage to these pins to control the motor's direction and speed.

How it Works

• Power Supply: Connect the 12V and 5V power supplies to the module.

• Logic Inputs: The logic inputs (In1, In2, In3, In4) are typically connected to a microcontroller or other logic circuits. By setting the appropriate logic levels on these pins, you can control the direction of the motors.  

• Channel Enables: The enable pins (Channel-A Enable, Channel-B Enable) are used to turn on or off the respective H-bridges.

• Motor Output: The module switches the voltage between the OUT1-OUT4 pins based on the logic inputs and enable signals, controlling the motor's direction and speed.

Typical Connections

• Motor: Connect the motor terminals to the appropriate OUT1-OUT4 pins.

• Power Supply: Connect the 12V and 5V power supplies to the corresponding terminals.

• Logic Control: Connect the logic inputs (In1, In2, In3, In4) to the microcontroller or logic circuit that will generate the control signals.

• Enable Control: Connect the enable pins (Channel-A Enable, Channel-B Enable) to the control signals for enabling or disabling the H-bridges.

Additional Notes:

The L298N module has built-in protection mechanisms like overcurrent and thermal shutdown.   

The module can handle up to 2A per channel, but the actual current capacity depends on the cooling and the specific L298N IC.

It's essential to use appropriate heat sinks on the L298N IC to prevent overheating, especially when driving high-current motors.   

The L298N Motor Driver Module is a versatile and powerful tool for any robotics enthusiast. By following the steps outlined in this blog post, you can easily control your DC motors and bring your projects to life. Ready to get started? Find the L298N Motor Driver Module in our online store here! 

Typical Applications of the DC Motor 

Robotics: Used in wheeled robots for locomotion, such as robot cars, line-following robots, and mobile platforms.

Hobby Projects: Suitable for powering small-scale vehicles, toys, and other DIY projects.   

Educational Purposes: Useful for teaching about motors, gearing, and robotics concepts.

Key Specifications (General)

Voltage: Typically operates on low voltages, such as 3V to 12V DC.   

Speed: The speed depends on the gear ratio and voltage. Geared motors typically have lower speeds compared to direct-drive motors.   

Torque: Geared motors provide higher torque than direct-drive motors, making them suitable for applications requiring more force.

Current Draw: The current draw varies depending on the load and voltage.

Additional Notes

Mounting: The motor  has mounting holes or tabs to facilitate easy attachment to various structures.

Shaft: The motor shaft can be used to directly attach wheels or other components.   

Compatibility: The motor is generally compatible with various electronic components, such as motor drivers, microcontrollers, and batteries.