E-L6207D

Product Overview

Category

E-L6207D belongs to the category of motor driver integrated circuits.

Use

It is primarily used for driving and controlling stepper motors.

Characteristics

• High voltage capability
• Low quiescent current
• Microstepping resolution
• Thermal shutdown protection
• Overcurrent detection and protection

Package

E-L6207D is available in a compact and industry-standard PowerSO package.

Essence

The essence of E-L6207D lies in its ability to provide efficient and precise control over stepper motors, enabling smooth and accurate motion in various applications.

Packaging/Quantity

E-L6207D is typically packaged in reels or tubes, with a quantity of 250 units per reel/tube.

Specifications

• Supply voltage range: 8V to 52V
• Output current: up to 2.8A per phase
• Maximum power dissipation: 1.5W
• Operating temperature range: -40°C to +150°C
• Step modes: full, half, quarter, eighth, sixteenth

Detailed Pin Configuration

E-L6207D features a total of 28 pins, each serving a specific function. The detailed pin configuration is as follows:

1. VCP - Charge pump capacitor connection
2. CP1 - Charge pump capacitor connection
3. CP2 - Charge pump capacitor connection
4. GND - Ground reference
5. VCP - Charge pump voltage supply
6. VREF - Reference voltage output
7. REF - Reference voltage input
8. OUT1A - Phase A output
9. OUT1B - Phase A output
10. OUT2A - Phase B output
11. OUT2B - Phase B output
12. OUT3A - Phase C output
13. OUT3B - Phase C output
14. OUT4A - Phase D output
15. OUT4B - Phase D output
16. VCC - Logic supply voltage
17. IN1 - Input 1
18. IN2 - Input 2
19. IN3 - Input 3
20. IN4 - Input 4
21. EN/INH - Enable/Inhibit input
22. REF - Reference voltage input
23. GND - Ground reference
24. VCP - Charge pump voltage supply
25. CP2 - Charge pump capacitor connection
26. CP1 - Charge pump capacitor connection
27. VCP - Charge pump capacitor connection
28. VCP - Charge pump capacitor connection

Functional Features

• Microstepping control for smooth motor operation
• Overcurrent detection and protection for motor safety
• Thermal shutdown protection to prevent overheating
• High voltage capability for driving a wide range of stepper motors
• Low quiescent current for energy efficiency

Advantages and Disadvantages

Advantages

• Precise control over stepper motors
• Versatile microstepping resolution options
• Robust protection features for motor safety
• Wide operating temperature range
• Suitable for various applications

Disadvantages

• Relatively high power dissipation
• Limited maximum output current compared to some other models

Working Principles

E-L6207D operates by receiving control signals from an external microcontroller or driver circuit. These signals determine the desired motion and speed of the connected stepper motor. The integrated circuit then generates the necessary current waveforms to drive the motor coils, enabling precise positioning and movement.

Detailed Application Field Plans

E-L6207D finds extensive application in various fields, including:

1. Robotics: Used for controlling robotic arms, joints, and other motorized components.
2. CNC Machines: Enables accurate movement control in computer numerical control machines.
3. 3D Printers: Provides precise motor control for layer-by-layer printing.
4. Automated Systems: Used in automated assembly lines and industrial machinery.
5. Telescope Mounts: Enables smooth and accurate tracking of celestial objects.

Detailed and Complete Alternative Models

1. A4988: Another popular motor driver IC with similar features and capabilities.
2. DRV8825: Offers higher current handling and advanced microstepping options.
3. TB6600: Suitable for driving larger stepper motors with higher power requirements.
4. L293D: Dual H-bridge motor driver IC, suitable for controlling DC motors as well.

These alternative models provide different specifications and features, allowing users to choose the most suitable option based on their specific requirements.

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