Have you ever experienced abnormal behavior or failures in high-voltage (HV) products for reasons unknown? This case study on HV product testing illustrates the partial discharge (PD) issue that is all too common to HV products, and how to detect it.

                Figure 1 Burnout Example                                        Figure 2 Digital Control Circuit of HV Relay

The above figures show a case where the HV output relay control circuit burned out. In cases of common relay failure, contact problems are relatively well-known, but control IC failures or digital interference are less known. In this example, after ruling out possible poor design of the control circuit and abnormal functioning of the chip, the withstand voltage and insulation resistance of the relay were also judged to be within the normal range. There seemingly were no abnormalities! Analysis of the circuit structure, however, pointed at a suspicious abnormal HV discharge from the relay contact to the control coil.

Generally, the HV relay industry only conducts withstand voltage tests according to specifications, without partial discharge (PD) or flashover tests. However, let us take an actual commercial HV relay with indicated withstand voltage specifications of 14kVdc (which implies a 10kVac peak value) as an example. After testing, it was found that the inception point of general products' partial discharge was only about 5kVac. According to tests and analysis of HV relays in some markets, the partial discharge inception voltage (PDIV) is only about half of the withstand voltage, which seems to be the common quality issue for this type of HV relay. Most HV relays typically do not have PDIV specifications. If really used in rated high voltage, most relays will produce continuous partial discharge. In this case, the working voltage of the device was designed as max. 5kVac and the relay specification of the withstand voltage between contact and coil was 14kVdc, which suggests no problems with insufficient margins. However, analysis of the relay that caused the problem found that, at 5kVac, there were abnormal partial discharges of hundreds of pC, much higher than measured in normal products.

Figure 3 General HV Relay PD Volume V.S. Working Voltage Curve

Factors that cause abnormal PD in this type of HV reed relays usually include air gaps or oil marks along the surface of the glass tube, air gaps in the insulation, or conductive impurities that were mixed in. Such deformities cause “partial” withstand problems, making it hard to detect by general DC withstand voltage and insulation resistance tests. Using an AC high-sensitivity PD detector to test products without abnormal PD within the specified voltage is a much more reliable testing strategy.

Figure 4 Basic Structure of Reed Relay

Chroma 19501 series offer built-in AC Hipot testing (10kVac) and PD detection (1pC~2000pC) functions, making it the best solution for abnormal PD detection in high voltage products. Moreover, the abnormality position of this HV relay can be successfully tested by the Chroma 11802-8kV HF HV Tester (10kHz~200kHz) for even faster degradation detection.

Want to learn more about the functions and specifications of the Chroma 19501 Partial Discharge Tester and the Chroma 11802 with A118017 HF HV Tester? Please visit the Chroma website and leave an inquiry. We are happy to be of service!