Megger's effective set of tools for off-line testing and on-line monitoring deliver the dependable data needed to support your technical and financial decisions.
You can count on our easy-to-use equipment for the most complex testing procedures , saving you time, promoting personnel and equipment safety, and providing accurate and reliable results.
Our transformer testing and monitoring solutions are now the go-to choice for industry leaders, prioritising safety, and predictive maintenance. By providing comprehensive data and advanced analytics, we empower you to move away from reactive maintenance strategies.
Our solutions' early identification of potential issues allows for timely interventions and minimises the risk of costly failures, enhancing operational efficiency and reducing downtime.
Maintenance (or replacement) decisions about a transformer should be informed by the unit's insulation condition and expected loading. Adding just a few operational years to the predicted end-of-life for a transformer (or generator, or cable) by optimising its working condition based on reliable diagnostic data means substantial cost savings for the equipment owner. A transformer owner can also use FDS technology to assess the condition and ageing of the insulation in bushings, CTs, VTs, and other components.
Service life of power or distribution transformers starts with a healthy electro-mechanical, electro-magnetic, dielectric, and thermal assessment of the transformer during the factory acceptance test (FAT).
Throughout its service life, a transformer is subjected to several stressing factors that may or may not affect its reliability and operability. Therefore, asset managers and operation managers set specific maintenance and testing strategies to monitor, evaluate and determine the condition of a transformer. A proactive testing and monitoring strategy promotes the longevity of transformers securing safe and continuous operation as well as resilience in the event of unexpected system transient conditions.
Turns ratio is typically the first test performed on a transformer. It is a pass/fail test. If a transformer fails, it is likely there are significant issues that need to be addressed before other tests are performed. If the transformer passes the turns ratio test, winding resistance is logically the next test to verify that the mechanical integrity of connections within the transformer, bushing, and tap changers. A resistance imbalance can lead to faster degradation of the transformer. Always remember to demagnetise the transformer after winding resistance tests! Residual magnetisation can cause large inrush currents when the transformer is energised, leading to time-consuming and costly nuisance tripping of protection systems. Also, residual magnetisation may affect SFRA, ratio and excitation current test results.
A transformer turns ratio test checks the fundamental principle of operation and design of a transformer. It validates the nameplate information and the electro-magnetic energy conversion phenomenal. The test is also known simply as a turns ratio test. A TTR test is performed by a ratio meter (ratio tester). A TTR test should be performed to confirm that the transformer’s capability for automatic voltage regulation at different tap positions of an OLTC (on-load tap changer) and also to confirm that a de-energised tap changer (DETC) is properly positioned and that shorted windings turns do not exist. The ratio meter provides convenient and accurate readings of power transformer ratios and polarities. A transformer turns ratio test works in accordance with the same fundamental electromagnetic phenomena that the transformer operates. The difference is that the TTR test typically uses a low voltage (LV) AC excitation signal (< 250 V AC) on a per-phase base or as a three-phase simultaneous excitation and measures the induced voltage in the opposite winding. When the excitation signal is applied on the HV winding and measurement is carried out in the LV side, the process is called STEP DOWN ratio test. Although, the test can be carried out exciting the LV winding and measuring the induced voltage on the HV winding, this is called STEP UP ratio test.
Moisture that accumulates in the insulating system of a power transformer affects several properties:
Dielectric Frequency Response (DFR a.k.a FDS) is the only reliable method to determine the moisture content in the solid insulation of power and distribution transformers. This test is not invasive and non-destructive. Typically, line-frequency (50 or 60 Hz) tan delta/power factor tests can give misleading results due to temperature effects, and oil analysis is unreliable as moisture mainly resides in the solid insulation.
Megger’s testing and monitoring equipment and solutions for transformers and HV assets guarantee accuracy, reliability, safety and smart investing.
Take a deeper dive into transformer testing instruments through our comprehensive guides.
Explore an application of narrowband dielectric frequency response (NB DFR) on HV CVTs.
A complete protocol of tests, including a 10 kV LF PF test.
Read the case study about the Electric Power Transmission Network in Karbala.
Read our case study on 1 and 500 Hz analysis on bushings.
A heavily used furnace transformer was tested after an operating failure.
