Information from Omicron
Circuit breakers are indispensable in any electrical power system. They are the only pieces of equipment switch can switch under normal load, as well as under fault conditions and must be able to reliably disconnect a faulty section from the grid as quickly as possible.
Circuit breakers must be able to meet this requirement even after they have been in-service for a long time. Their reliability is essential for the prevention of consequential power system failures and the safety of the electrical power supply. Typical tests include measurements of operating times and the static contact resistance.
A more extensive condition assessment is possible when further measurements are performed, such as motion/contact travel measurements, or the measurement of the motor current signature.
For circuit breakers that are equipped with an under-voltage release or an over-current release, testing these features further increases the available information that can be used during the condition assessment of the circuit breaker.
Medium voltage circuit breakers
While old medium voltage (MV) circuit breakers often used oil as an interrupting medium, more modern types almost exclusively use vacuum. Essential elements of a breaker include the interrupter unit, the mechanical linkage, and the operating mechanism with an energy storage system. The energy needed to operate a circuit breaker is high, and it must be made available within a few milliseconds, i.e., almost instantaneously.
Springs are used in most cases because they are simple and reliable. Two separate springs allow the energy for the opening and the closing operation to be stored. To release the energy stored in the springs, two coils are needed to control the springs remotely. The opening spring is charged during the closing operation of the breaker, and the closing spring is charged by a motor.
Testing of medium voltage circuit breakers
The following is a brief overview of the most important medium voltage circuit breaker measurement methods.
Off-service measurement methods
• Timing: Timing measurements according to the IEC 62271-100 standard are used to determine operation time and belong to the most common tests. The timing test uses a resistance or voltage threshold to determine the state of the main contacts.
• Static contact resistance: This test verifies whether the resistance of the main contacts allows the current to flow with minimal losses.
• Dynamic contact resistance: This records the contact resistance during the operation of the breaker and delivers information about wear-related problems with main and arcing contacts, while also determining timing results.
• Motion or contact travel: This checks the operating mechanism and mechanical linkage and indicates potential mechanical wear.
• Coil current: The current signature curve of the command coils during breaker operation is recorded during a timing test. Deviations show possible electrical or mechanical defects of the trip or close control components. According to the IEC, the trip coil shall work between 70 and 110% of nominal voltage and the close coil shall work between 85% and 110 % of nominal voltage.
• Motor current: The motor current analysis records the inrush and steady-state currents as well as the spring charging time. According to the IEC, the motor shall work between 85 and 110% of nominal voltage.
• Minimum pick-up: Determines the minimum voltage necessary to trip and close the breaker and verifies whether it can reliably operate in the event of a low DC supply.
• Under-voltage release test: Determines the trip voltage of the under-voltage coil.
• Overcurrent release test: Used to determine the current which trips the breaker. Overcurrent releases are commonly used together with self-powered overcurrent protection relays.
In-service measurement methods
• First-trip test: The first trip test is carried out while the breaker is still in-service and has been in-service for a long time. Connections are made at the trip coil and at the current transformer’s (CT’s) secondary side. The opening times are measured by monitoring the CTs’ secondary current.
• Voltage-based timing measurement (VTM): VTM is the only measurement method available to measure the timing of a medium-voltage GIS, since the main contacts are sealed and cannot be accessed. It can be applied to all circuit breakers with a voltage detection system (VDS) that makes the main voltages accessible.
Purpose of under-voltage release
Circuit breakers are equipped with an under-voltage release if the related protection system has no supply voltage backup. For instance, a protection relay is powered by a battery, but the battery voltage is not monitored. If the battery voltage falls below 70% of its nominal voltage (for details see IEC 62271-1:2017), so that it is not able to operate the protection relay anymore, any failure (e.g., an overcurrent) would no longer be discovered.
The under-voltage release is often found in industry grids, as it is a relatively cheap solution to make sure the breaker is opened when a battery failure occurs. An under-voltage release may operate when supply voltage is between 35 and 70% of the nominal voltage and must operate when the supply voltage drops below 35%. In addition, the Under-voltage release prevents closing when the release has operated i.e. after opening the circuit breaker.
Under-voltage release test
The under-voltage coil is supplied, after which the breaker is closed. Then the voltage is ramped in steps from the nominal voltage down, until the voltage level is reached when the under-voltage release trips. This is the trip voltage. Then the voltage ramp ends.
Purpose of overcurrent releases
Current transformer releases are used on circuit breakers in substations where no grid independent supply voltage is available. These are low-cost stations with basic functionality. Quite often they do not have any remote-control feature and the breakers do not have a close coil. Such substations are common in distribution grids where the downstream infrastructure is not critical, like in residential areas.
Overcurrent releases are activated by a current. The current comes from the tripping transformer which usually has a nominal value of 0,5, 1,0 or 5 A AC. An overcurrent relay feeds the current flow from the tripping transformer to the circuit breaker. The tripping transformer and the overcurrent relay (self-powered overcurrent relay) are usually powered by the secondary side of the CTs.
In the event of an overcurrent, the relay switches the current of the tripping transformer to the circuit breaker and thus causes it to open the main contacts and isolate the faulty grid part.
Overcurrent release test
With the breaker in closed position, a current is ramped up in steps until the breaker trips. This is the trip current. Then the ramp ends.
• IEC 62271-100: Indirect current release
• ABB: Transformer-operated release
• Siemens: Current transformer operated release
• Also in use: Indirect over-current release
Closing time calculation for circuit breakers without a close coil
All breakers should have at least a trip coil so that faults can be isolated. Some old breakers or breakers with overcurrent release does not have any close coil. These breakers are closed manually. According to IEC 62271-100, the closing time is the time from the moment the close coil is energised until the contacts touch in all poles.
For circuit breakers without a close coil the closing time calculation according to IEC standard cannot be applied. Therefore, an alternative approach must be used. The closing time can be the time when the circuit breaker main contacts begin to move until the contacts touch in all poles.
Contact Alexander Dierks, Alectrix, Tel 021 790-1665, email@example.com