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Common faults of high-frequency switching power supply

2025-03-17
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The common faults and troubleshooting methods of high-frequency switching power supplies are as follows:

1、 Startup fault

The power indicator light is not on

Phenomenon: After turning on, the power indicator light does not light up and the device cannot be started.

Reason: The power supply is not connected, there is a phase loss, or the circuit breaker is not closed; The input rectifier diode or high-voltage filter capacitor is damaged.

Solution: Check the power connection status; Replace damaged rectifier diodes or filter capacitors.

Abnormal work indicator light

Phenomenon: The power indicator light is normal, but the working indicator light is not on.

Reason: The start switch is not placed in the start position; The communication between the monitoring module is abnormal.

Solution: Reset the startup switch; Check the operation status and communication lines of the monitoring module.

2、 Output abnormal faults

No DC output or unstable voltage

Phenomenon: No output or voltage fluctuation under load state.

Reason: breakdown of high-frequency rectifier diode, leakage of filtering capacitor; Overvoltage/overcurrent protection triggered; Feedback loop or control chip malfunction.

Solution: Replace damaged diodes/capacitors; Check the protective circuit; Detect the output signals of chips such as TL494 and UC3842.

Output voltage too high/too low

Phenomenon: The output voltage deviates from the set value.

Reason: Feedback loop resistor/capacitor failure; PWM control chip abnormality; Load mutation.

Processing: Calibration feedback loop; Replace the control chip; Test the output status under different loads.

3、 Abnormal work malfunction

Power supply overheating

Phenomenon: Abnormal temperature rise during device operation.

Reason: Damage to the switch tube or rectifier tube leads to a decrease in efficiency; Poor heat dissipation or overload load.

Solution: Optimize heat dissipation design (such as increasing copper foil area); Replace faulty components; Control the load within the rated power.

High operating noise

Phenomenon: Accompanied by high-frequency whistling or vibration sounds during work.

Reason: Loose transformer/inductor coil; Filter capacitor failure; Insufficient electromagnetic shielding.

Processing: Welding of reinforced magnetic components; Replace the filtering capacitor; Strengthen electromagnetic compatibility design.

4、 Hardware damage type malfunction

The fuse is blown

Phenomenon: The fuse burns out immediately after turning on the machine.

Reason: Short circuit on the input side (such as rectifier bridge breakdown); Switch tube or filter capacitor breakdown.

Solution: Check for short circuit points; Replace damaged switch tubes, capacitors, or rectifier diodes.

Power device damage

Phenomenon: The switch tube or rectifier tube is burnt out.

Reason: Transformer saturation leads to current spikes; Insufficient heat dissipation or overvoltage breakdown.

Solution: Optimize the turns ratio of the transformer; Add soft start circuit; Strengthen heat dissipation.

5、 System level malfunction

Monitoring module abnormality

Phenomenon: The alarm light is constantly on or communication is interrupted.

Reason: Signal acquisition board malfunction; Control parameter setting error.

Solution: Restart the monitoring module; Check the connection status of the signal acquisition board.

Loop stability issue

Phenomenon: Output voltage oscillation or response delay.

Reason: The feedback loop gain design is unreasonable.

Processing: Adjust differential/integral gain; Optimize compensation network parameters.

Summary and Suggestions

Troubleshooting sequence: Prioritize checking high-voltage side components such as input power supply, fuses, rectifier circuits, etc., and then gradually troubleshoot control circuits and output terminals.

Design optimization: In response to high-frequency interference and heat dissipation issues, attention should be paid to PCB layout, electromagnetic shielding, and heat dissipation system design.


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