Analysis and Solutions for DC Circuit Breaker System Failures

1.Overview​
DC circuit breakers are critical protection devices in power systems, and their reliable operation is essential for system stability. This article provides systematic solutions for common DC circuit breaker failures, covering four major types: failure to close, failure to trip, false tripping, and false closing.

​2. Solutions for Failure to Close​
​2.1 Electrical System Fault Handling​
• ​Open control circuit or absence of control power​
Use a multimeter to measure the output voltage of the control power supply, check the status of fuses, and test circuit continuity. Replace broken wires immediately and ensure terminal connections are secure.
• ​Closing circuit failure​
Inspect closing circuit fuses (replace with specifications-compliant elements), closing contactors, and coils (resistance values should meet standards). Use specialized equipment to test the performance of the closing coil.
• ​Auxiliary contact and control switch failures​
Clean and adjust the circuit breaker’s auxiliary contacts to ensure reliable contact; check the status of control switch contacts and replace components if necessary.

​2.2 Mechanical Device Fault Handling​
• ​Transmission mechanism failure​
Check the connection status of linkages, re-tighten or reinstall detached components; lubricate mechanical transmission parts to ensure smooth operation.
• ​Closing core jamming​
Disassemble and inspect the closing electromagnet, remove foreign objects, correct deformed components, and ensure smooth movement of the core.
• ​Failure to reset and spring energy storage issues​
Manually operate the mechanism to reset it; inspect the spring energy storage mechanism, and maintain the energy storage motor and gear transmission system.
• ​Latch mechanism adjustment​
Adjust the trip latch hook and four-link mechanism to ensure accurate over-center positioning; test the closing retention performance.

​3. Solutions for Circuit Breaker Failure to Trip​
​3.1 Emergency Procedures​
• ​Emergency handling for upstream tripping​
Immediately cut off the power supply to the faulty unit to prevent damage to main equipment; analyze fault location using protection signals and fault recordings.
• ​System recovery operation​
Disconnect the faulty circuit breaker and restore upstream power supply; perform trial power restoration step by step on branch circuit breakers to locate the fault, isolate it, and restore the system.

​3.2 In-Depth Maintenance Measures​
• ​Comprehensive testing of the trip circuit​
Measure the resistance and insulation resistance of the trip coil; inspect the status of relays, contacts, and wiring in the trip circuit.
• ​Protection device calibration​
Test the characteristics of protection relays, calibrate settings, and verify the polarity and connection correctness of CT/PT circuits.

​4. Solutions for False Tripping of Circuit Breakers​
​4.1 Handling Electrical Causes​
• ​Improving secondary circuit insulation​
Use a 1000V megohmmeter to test the insulation of the DC system, locate and eliminate grounding fault points; enhance waterproofing measures in cable trenches.
• ​Protection device anti-interference modifications​
Check the reliability of protection device grounding, add filtering devices; review the rationality of settings.

​4.2 Handling Mechanical Causes​
• ​Seal maintenance for hydraulic mechanisms​
Replace seals of the first-stage trip valve and check valve; test the cleanliness of hydraulic oil; adjust oil pressure alarm settings.
• ​Mechanical retention performance testing​
Test the reliability of the closing retention mechanism, including the mechanical strength of the support and latch.

​5. Solutions for False Closing of Circuit Breakers​
• ​DC system insulation monitoring​
Install DC system insulation monitoring devices to continuously monitor and alert for insulation degradation.
• ​Reclosing device calibration​
Test the operating voltage and return value of automatic reclosing relay contacts to prevent maloperation.
• ​Standardization of closing contactors​
Replace contactors with coils that do not meet resistance requirements; ensure operating voltage is within 30%–65% of the rated value.
• ​Anti-maloperation improvements for spring mechanisms​
Add mechanical anti-vibration devices to improve latch reliability; conduct regular vibration tests.

​6. Preventive Maintenance Recommendations​
Establish a regular maintenance system, including:
• Semi-annual inspection of operational mechanism flexibility
• Annual calibration of protection device settings
• Periodic testing of DC system insulation
• Maintaining fault records for trend analysis

​7. Conclusion​
DC circuit breaker failures require comprehensive electrical and mechanical analysis and handling. Through systematic testing methods, standardized maintenance procedures, and regular maintenance systems, the operational reliability of circuit breakers can be significantly improved, ensuring the stable operation of the power system.

​Note:​​ All maintenance operations must strictly adhere to safety regulations, including isolation, voltage verification, and grounding measures.