Single Phase 2.0 AMPS. Glass Passivated Bridge Rectifiers Voltage Range 50 to 1000 Volts Current 2.0 Amperes # Technical Documentation: KBP208 Bridge Rectifier
## 1. Application Scenarios
### 1.1 Typical Use Cases
The KBP208 is a 2A, 800V silicon bridge rectifier commonly employed in AC-to-DC conversion circuits. Its primary function is to convert alternating current (AC) input into pulsating direct current (DC) output through full-wave rectification.
Primary applications include:
- Power Supply Units : Used in linear and switching power supplies up to 2A output current
- Battery Chargers : For lead-acid, NiMH, and Li-ion battery charging circuits
- Motor Drives : In small AC motor control circuits and universal motor speed controllers
- Lighting Systems : LED drivers, fluorescent ballasts, and incandescent lamp dimmers
- Appliance Control : White goods, small kitchen appliances, and power tools
### 1.2 Industry Applications
Consumer Electronics :
- Television power supplies
- Audio amplifier power stages
- Gaming console power adapters
- Set-top box power circuits
Industrial Equipment :
- Control panel power supplies
- Sensor interface circuits
- Relay and solenoid drivers
- PLC input/output modules
Automotive Aftermarket :
- Car audio amplifiers
- LED lighting converters
- Battery maintenance devices
- 12V/24V accessory power supplies
Renewable Energy :
- Small solar charge controllers
- Wind turbine rectification stages
- Micro-inverter circuits
### 1.3 Practical Advantages and Limitations
Advantages:
- Compact Design : Four diodes in single package (KBP package: 10.7mm × 10.7mm × 4.5mm)
- High Voltage Rating : 800V peak reverse voltage suitable for 110V/220V AC mains applications
- Cost-Effective : Lower component count and assembly time compared to discrete diodes
- Thermal Performance : Copper lead frame provides good heat dissipation
- Simplified PCB Design : Reduced layout complexity with single component
Limitations:
- Current Limitation : Maximum 2A average forward current restricts high-power applications
- Thermal Constraints : Requires heatsinking for continuous operation near maximum ratings
- Voltage Drop : Typical 1.1V forward voltage per diode pair reduces efficiency
- Frequency Response : Limited to line frequency (50/60Hz) and low-frequency switching applications
- Non-isolated : Does not provide galvanic isolation; requires transformer for isolated designs
## 2. Design Considerations
### 2.1 Common Design Pitfalls and Solutions
Pitfall 1: Inadequate Thermal Management
- Problem : Overheating leading to reduced lifespan or catastrophic failure
- Solution :
- Calculate power dissipation: P_diss = 2 × V_f × I_avg (typically 2.2W at 2A)
- Use thermal pad or heatsink for continuous operation above 1A
- Maintain 50% derating for improved reliability
Pitfall 2: Voltage Transient Damage
- Problem : Voltage spikes from inductive loads or lightning surges exceeding 800V rating
- Solution :
- Add MOV (Metal Oxide Varistor) across AC input
- Implement RC snubber circuits for inductive loads
- Use TVS diodes for high-energy transient protection
Pitfall 3: Inrush Current Stress
- Problem : High capacitor charging currents exceeding surge rating
- Solution :
- Add NTC thermistor in series with AC input
- Implement soft-start circuits for large filter capacitors
- Use current-limiting resistors for small power supplies
Pitfall 4: Reverse Polarity Connection
- Problem : Incorrect DC output polarity damaging downstream components
