Why needs EMI Filter?
The function of the EMI Filter
The basic function of the AC power filter is to suppress the conducted radiation (namely noise), generated by the power converter from entering the AC power line. Line filters must be designed to suppress conducted emissions to a level low enough to pass regulatory limits. For example, FCC Part 15. Products that do not meet regulatory requirements will not be allowed on the market.
EMI Filter Classification
EMI Filter can be classified as Passive EMI Filter and Active EMI Filter by function. Their similarities and main differences can be summarized as follows.
Our Products
Power Entry Connector
Power Supply Plug with build-in Active EMI Filter
Active EMI Filter Modules
Active Differential Mode
Active Common Mode
Active Mixed Mode
Applications:
-
Power supply for data center -
Server power supply -
Power supply for gaming PC -
Power adapters -
Portable chargers for power tools -
High power density applications -
Any power supply system that requires high mobility
Electrical Characteristics:
| Symbol | Parameter | Conditions | Min | Typ | Max | Units |
|---|---|---|---|---|---|---|
| High voltage circuit | Hz | |||||
| fLINE_MAX | Max. AC Line Frequency | |VAC_PEAK| ≦ 450V | 60 | Hz | ||
| fLINE_MIN | Min. AC Line Frequency | |VAC_PEAK| ≦ 450V | 50 | V | ||
| VAC_PEAK | Peak AC_Line Voltage | 50Hz ≦ fLINE ≦ 60Hz | 450 | W | ||
| PIN_MAX | Maximum Input Power | VAC_LINE = 220VAC VAC_LINE = 110VAC | 2000
1000 |
W
W |
||
| IIN_MAX | Maximum Input Current | VAC_LINE = 220VAC | 10
10 |
ARMS
ARMS |
||
| RDC_MAX | DC resistance across HV1 and HV2 | 15 | 17 | mΩ | ||
| DC supply | ||||||
| VVCC-MAX | Max. DC supply Voltage | VCC = VV+ – VV- | 15 | V | ||
| VVCC-MIN | Max. DC supply Voltage | VCC = VV+ – VV- | 12 | V | ||
| Iq-VCC | Vcc quiescent Current | VCC = 12V HV1, HV2 and EN pin floating | 18 | TBD | mA | |
| Pq-VCC | Quiescent power consumption | VCC = 12V HV1, HV2 and EN pin floating | 0.22 | TBD | W | |
| Low power shut-down | ||||||
| ISD-VCC | Shut-down Current | VCC = 12V VEN = 0V | 10 | TBD | µA | |
| Pq-VCC | Quiescent power consumption | VCC = 12V VEN = 0V | 120 | TBD | µW | |
| VEN-TH-SD | EN pin voltage threshold for device enable | VCC = 12V VEN rise from 0V | 3 | 3.5 | V | |
| Differential-mode noise suppression | ||||||
| fFILTER-MIN | Minimum frequency of differential mode noise suppression | VCC = 12V EN pin floating | 150 | kHz | ||
| fFILTER-MAX | Maximum frequency of differential mode noise suppression | VCC = 12V EN pin floating | 1 | MH | ||
| GAIN150kHz | Noise Attenuation at 150 kHz | VAC_LINE = 220VAC Line Impedance = 50Ω | TBD | -30 | dB | |
| GAIN1MHz | Noise Attenuation at 1 MHz | VAC_LINE = 220VAC Line Impedance = 50Ω | TBD | TBD | dB |
2000W Active EMI Filter Performance Test:
- 2 PFCs connected to the output of a 2KW Active EMI Filter module
- Two 1000W resistive loads are connected to the output of each PFC
- 220VAC input
- The AEF module is powered by an external 12V battery
| Start Freq | Stop Freq. | Step Size | Res. BW | Mea. Time | RF Atten | Preamp | Input 2 |
|---|---|---|---|---|---|---|---|
| 150kHz | 30MHz | 4kHz | 9kHz | 1ms | Auto | 0dB | INPUT 2 |
Conducted Emission (Live) before turn on AEF
Conducted-Emission-Live-after-turn-on-Active EMI Filter