Selecting the right IGBT module is critical for optimizing performance and efficiency in power electronics applications. Here, we compare the Mitsubishi PM100CSD060 and PM150RSD060 to help you make an informed choice.
Technical Specifications
| Parameter |
PM100CSD060 |
PM150RSD060 |
| Manufacturer |
Mitsubishi |
Mitsubishi |
| Collector-Emitter Voltage |
600V |
600V |
| Collector Current |
100A |
150A |
| Configuration |
Three-phase bridge |
Three-phase bridge |
| Package |
Module |
Module |
| Operating Temperature |
-40°C to 150°C |
-20°C to 150°C |
| Insulation Voltage |
2500V |
3400V |
| Gate Trigger Voltage |
±20V |
±20V |
| On-State Voltage |
2.2V |
1.7V |
| Power Dissipation |
410W |
416W |
| Dimensions |
100 × 50 × 20 mm |
110 × 50 × 25 mm |
Key Differences
Collector Current
- PM100CSD060: Handles a collector current of 100A, making it suitable for moderate power applications.
- PM150RSD060: Supports a higher collector current of 150A, ideal for more demanding power applications.
On-State Voltage
- PM100CSD060: On-state voltage is 2.2V.
- PM150RSD060: Features a lower on-state voltage of 1.7V, which reduces conduction losses and improves efficiency.
Insulation Voltage
- PM100CSD060: Offers an insulation voltage of 2500V.
- PM150RSD060: Higher insulation voltage of 3400V, providing better isolation and safety in high-voltage environments.
Power Dissipation
- PM100CSD060: Has a power dissipation of 410W.
- PM150RSD060: Slightly higher power dissipation at 416W, accommodating more power-intensive applications.
Application Considerations
1. Current and Power Requirements:
- Choose the PM100CSD060 for applications with up to 100A current requirements.
- Opt for the PM150RSD060 for applications needing up to 150A, offering more headroom for power-intensive operations.
2. Efficiency Needs:
- The PM150RSD060’s lower on-state voltage can improve efficiency, reducing overall power losses.
3. Environmental Conditions:
- Both modules operate within a wide temperature range, but the PM150RSD060 offers better isolation voltage, making it preferable for high-voltage environments.
