By definition, a circuit breaker timing test is the process of measuring the mechanical operating times with the goal of verifying, analyzing and validating the proper function of the circuit breaker. The importance of timing tests is particularly critical in maintaining the reliability of the transport and distribution network, and also in the safety of the personnel employed to maintain and operate the network protection apparatus. Using test execution and analysis tools, such as the CBA-32P, by Zensol, which is driven by the CBA Win© software, and with the experience acquired in the field, it is possible to determine, with remarkable accuracy, the nature of the problems that affect circuit breaker performance even before disassembling the apparatus. However, timing tests are not limited to tests conducted after the circuit breaker fails (corrective maintenance). In the preventive maintenance strategy, the breaker is subject to regular timing tests to detect trends in the degradation and aging of the equipment, so that corrective action may be applied before the problems become a danger to the network or to the personnel. Timing tests are also useful in the factory to check production quality standards, for reliability testing, to determine the reference parameters, and for field testing after the installation of a new circuit breaker.	Get this article in PDF format!
Consequences of circuit breaker misoperation The potential for damage that a circuit breaker – essentially a protective device – can inflict on a network if its operation is not within specifications are not to be neglected. The economic repercussions can be just as severe: cost of repairs, cost of the failure, interruption of service to customers, etc. If the operation time during a Trip is too long, the short-circuit current being interrupted will persist for much longer, and could damage transformation, transmission and distribution installations. The reduction of the interrupting time can also bring the added benefit of increasing the transportable power because the stable power limit increases in inverse proportion with the tripping time. Also, the contacts themselves are subject to the arc for longer periods, which reduces their useful lifespan. Also, all contacts must be synchronized, within a certain tolerance limit. In three-phase systems, not only must the contacts in a single pole operate simultaneously, but all poles must also operate at the same time. If the contacts in one pole do not operate synchronously, then the slowest contact to close and the quickest to open will absorb the greater part of the load, which will cause the premature wear of the contacts in question. The difference between phases (poles) could generate voltage spikes because of the very nature of the transportation system, long transmission lines with extremities whose state cannot always be predicted: open-ended, loaded, capacitive or inductive load, etc. These factors may cause huge voltage spikes that could potentially damage the network and its equipment. Inoperative insertion resistors will cause premature wear on the main contacts, since they will be subjected to the strongest breaking currents, with the accompanying arc that will be so much more powerful. Voltage surges will also be present which can damage the breaker and surrounding equipment.	Back to top
Troubleshooting breakers The first prerequisite for diagnosing breaker troubles is to know the breaker being analyzed. Knowing the configuration of the suspect apparatus’ innards, it is possible to figure out the nature of the problem by visualizing the mechanical process of the operation, in perspective with the data of the timing test. The same is true of the experienced mechanic who can determine, at a glance, the source of the mechanical problem in a car. He knows not only automobile mechanics as a general subject, but he knows the peculiarities of the model that is brought to him. One also needs precise timing test data, such as those produced by CBA Win© after a timing test conducted with Zensol's CBA-32P. The following examples, showing the curves generated by the faulty apparatus, followed by the analysis, the description of the actions and corrections applied, and the curves generated by the repaired equipment, illustrate how the principles previously explained can be applied in a real-world situation.	Back to top
Conclusion The role played by the high voltage circuit breaker has always been one of the most determining factors of high voltage network reliability. Its main role is to protect the network and installed electric equipment from destructive short-circuit current surges. A high voltage circuit breaker can stay in the closed position for years but is still expected to interrupt a powerful short-circuit current of many thousands of amperes in a fraction of a second. The nature of its operation places it among the most unpredictable equipment on the electric network.	Back to top
PK – Inoperative resistor The insertion resistor does not work. The spring on the moving contact is broken and blocks the piston.	Back to top
PK – Correction Disassembly of the auxiliary moving contact, observe the damage (broken spring), replacement of the spring and reassembly. A timing test shows the return of the resistor’s trace on the second phase (C02).	Back to top
PK – Rebounds Abnormal rebounds on an auxiliary (resistive) contact. The head on the semi-mobile contact is loose.	Back to top
PK – Correction Disassembly of the auxiliary moving contact, observe the problem (loose head). Tighten the head and immobilize with Loctite and punching, followed by reassembly. A timing test shows the disappearance of the unusual rebounding on the resistive trace.	Back to top
Dead Tank – Missing main contact Case of an inoperative main contact on one phase (PhB), showing an open circuit on a Close operation.	Back to top
Dead Tank – Correction Disassembly of the internal parts of the defective phase. Observe the damage, a shaft connecting the actuating rod to the moving contact had fallen, causing the contact piston to separate from the actuating rod. Replace the shaft and reassemble. A timing test shows the reappearance of the main contact on the second phase.	Back to top
PK – Valve in wrong position The close control valve on the breaker is in the wrong position. The result is that the closing times on the two chambers connected to this valve are longer than the others.	Back to top
PK – Correction Disassembly of the close control valve. Observe that the body of the valve had been installed at a 90o angle relative to the normal position of the valve body, which caused a delay in the admission of compressed air, producing the observed delays on the signals of contacts A-1 and A-2. Replace the valve in the correct position. A timing test shows that contacts A-1 and A-2 now close within the expected times.	Back to top
SF6 breaker with hydraulic commands - adjustment screw incorrectly set An adjustment screw on the breaker is incorrectly set, creating a 25 millisecond difference on one phase. This problem may produce similar results to those produced by an incorrectly positioned control valve.	Back to top
SF6 breaker with hydraulic commands – Adjustment screw – Correction The adjustment screw was set to obtain similar closing times on all phases and contacts. A timing test shows that the closing time on contacts C03 and C04 are now comparable to those on the other contacts.	Back to top
SF6 breaker with hydraulic actuator – short-circuit time Adjustment of the short-circuit time for a SF6 breaker with hydraulic actuator. Circuit breakers with hydraulic actuators are usually equipped with a signal piston with drives the signaling contacts. These contacts control the minimum short-circuit time of the circuit breaker (trip-free). This example shows all three phases following a Close-Open operation. It may be seen that the short-circuit time of Phase C is longer than the others. This requires adjustment of the restrictions of the command lines of the signal piston.	Back to top
SF6 breaker – Correction of short-circuit time Adjust the admission restriction of the hydraulic command in order to obtain synchronous operation of all phases.	Back to top
Pneumatic breaker, isolation time Air-driven breakers are usually equipped with a pneumatic inverter switch on each phase. The main function of this switch is to prevent the close operation for approximately 250 milliseconds after a trip, so the dielectric medium has time to properly regenerate. The following example shows all three phases after an Open-Close operation (the close order is maintained until the end of the recording). It is clear that the switch on Phase B much quicker than the two other phases, which requires an adjustment.	Back to top
Pneumatic breaker – Correction Adjust the restriction on the inverter switch in order to obtain comparable times between all phases.	Back to top
Shielded breaker Two problems are noted on this breaker. First, the engagement piston doesn't attain its full travel (180 mm). Second, the piston begins moving 30 to 35 milliseconds after the main pistons. The normal delay is about 20 milliseconds.	Back to top
Shielded breaker – Correction To correct the delay problem, the diameter of the appropriate diaphragm orifice is increased by 0.020 inches. The premature reopening of the resistor is due to the main contact closing later. The curve shows that there is also a problem with the upper piston (DpC) of the main contact on Phase C. This piston was overhauled prior to the timing test.	Back to top
Dead Tank – Bad damping The following timing diagram shows a hard rebound at the bottom of the displacement curve, during a Trip operation on a Dead Tank type circuit breaker. This suggests a lack of damping at the end of travel. Excess energy is poorly absorbed and damage may already have occurred.	Back to top
Dead Tank – Correction After examining the internal components, it is observed that damage has indeed occurred on the main rod of the moving contact. The source of the problem is a defective dashpot. After repair, the timing test shows correct damping at the bottom of the travel curve.	Back to top
2. The distribution network At the output of the generating stations, transforming stations step up the production-level voltage to the high voltage necessary to efficiently carry the electricity over longer distances. The power transmission lines are made of conductors such as overhead lines or underground cables. In spite of their apparent simplicity, these conductors conceal important influencing factors to the electricity transmission network.