EVALUATION BOARD# AN7824 24V Voltage Regulator Technical Documentation
## 1. Application Scenarios
### Typical Use Cases
The AN7824 is a fixed 24V positive voltage regulator commonly employed in power supply circuits requiring stable 24V DC output from higher input voltages. Typical applications include:
- Industrial Control Systems : Powering PLCs, motor controllers, and industrial automation equipment
- Telecommunications Equipment : Providing regulated 24V for communication devices and network infrastructure
- Automotive Electronics : Supporting 24V systems in commercial vehicles and industrial machinery
- Test and Measurement Equipment : Delivering precise 24V for instrumentation and laboratory equipment
- Consumer Electronics : Powering specialized audio/video equipment requiring 24V rails
### Industry Applications
- Manufacturing : Machine tool controls, robotic systems, and conveyor control systems
- Telecom Infrastructure : Base station power supplies, network switching equipment
- Transportation : Railway signaling systems, commercial vehicle electronics
- Renewable Energy : Solar power inverters, wind turbine control systems
- Medical Equipment : Diagnostic instruments and specialized medical devices
### Practical Advantages and Limitations
Advantages:
- Simple Implementation : Requires minimal external components for basic operation
- Built-in Protection : Features thermal shutdown, current limiting, and safe operating area protection
- Cost-Effective : Economical solution for medium-current 24V applications
- Reliable Performance : Stable output under varying load and line conditions
- Wide Availability : Standard TO-220 package with multiple sourcing options
Limitations:
- Fixed Output : Cannot be adjusted for different voltage requirements
- Dropout Voltage : Requires approximately 2V headroom (26V minimum input)
- Power Dissipation : Limited to 15W without heatsink, requiring thermal management for higher loads
- Efficiency : Linear regulation results in power loss proportional to voltage drop
- Current Capacity : Maximum 1A output current may require parallel devices for higher loads
## 2. Design Considerations
### Common Design Pitfalls and Solutions
Thermal Management Issues:
- Pitfall : Inadequate heatsinking causing thermal shutdown
- Solution : Calculate power dissipation (Pdiss = (Vin - Vout) × Iout) and select appropriate heatsink
- Implementation : Use thermal compound and proper mounting for TO-220 package
Input Voltage Concerns:
- Pitfall : Input voltage exceeding maximum rating (35V) or falling below dropout
- Solution : Implement input overvoltage protection and ensure minimum 26V input
- Implementation : Add transient voltage suppression and input capacitance
Stability Problems:
- Pitfall : Output oscillations due to improper bypassing
- Solution : Use recommended 0.33μF input and 0.1μF output capacitors
- Implementation : Place capacitors close to regulator pins with short traces
### Compatibility Issues with Other Components
Microcontroller Integration:
- Ensure clean 24V supply for analog circuits and motor drivers
- Use additional LDO regulators for lower voltage digital circuits
- Implement proper decoupling between analog and digital sections
Motor and Actuator Compatibility:
- Verify motor starting currents don't exceed 1A limit
- Consider soft-start circuits for inductive loads
- Use flyback diodes for DC motor applications
Sensor Interface Considerations:
- Account for voltage level shifting when interfacing with 5V or 3.3V sensors
- Implement proper filtering for noise-sensitive analog sensors
### PCB Layout Recommendations
Power Routing:
- Use wide traces for input and output connections (minimum 40 mil width for 1A)
- Implement ground planes for improved thermal performance and noise reduction
- Keep high-current paths short and direct
Component Placement:
- Position input and output
