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Download OLPD Testing of 10 kV Motors and Generators Following
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Transcript
OLPD Testing of 10 kV Motors and Generators Following and In-service Failure of a 10 kV Motor CASE STUDY Motors and Generators Oil Processing Facility HFCT/TEV Sensors HVPD Longshot™ Project A gas processing facility based in the North Africa requested on-line partial discharge (OLPD) testing of the two (2) 10 kV Gas Turbine Generators and four (4) process critical 10 kV Motors that had reached 4 years of service. The testing was requested as a result of a recent HV stator insulation failure of 10kV Amine Pump Motor D that had resulted in operational disruption at the facility. Previous baseline OLPD diagnostic testing had been carried out on the rotating HV machines with the HVPD Longshot™ four years earlier, immediately after commissioning. Whilst these baseline tests had shown low levels of OLPD activity on all of the machines tested, they had not been tested since, over 4 years of operation in a harsh desert environment. The stator insulation of the 10kV Amine Pump Motor D had failed where the slot section meets the end winding (the slot-exit section) as shown opposite, this being a common weak point within the HV motor stator insulation system. PD-incepted insulation faults can occur due to insufficient electrical clearances between rotor and stator, the formation of condensation and/or the accumulation of dirt/debritus in this slot-exit area of the stator windings. These factors can produce localised conductive areas on the insulation surfaces producing surface discharges that develop further to tracking and finally a complete HV insulation fault to ground. HV insulation degradation can also be accentuated by a number of operational stresses, including Thermal (e.g. from variable loads), Electrical (e.g from voltage spikes), Ambient (e.g from temp/humidity changes) and Mechanical (e.g from vibration/out of alignment issues), the so-called ‘TEAM’ acronym operational stresses 10 kV Pump Motor Failure on the 10 kV Pump Motor Stator Winding Solution This test project involved the insulation condition evaluation of 10 kV rotating machines on site. Permanent high-current, High Frequency Current Transformer (HFCT) OLPD sensors previously installed in the machine’s cable box (one per phase) were used. Sensor cables were routed through to a Sensor POA Termination Box mounted on the side panel of the generator/motor as shown opposite. The diagnostic OLPD measurements of the in-service rotating HV machines were then made using the HVPD Longshot™ diagnostic OLPD test unit connected to each phase of the machine under test. Permanent Sensor Point of Attachment Box Results At Commissioning – Baseline Tests - the baseline OLPD test results from the commissioning tests shown below showed low levels of PD (< 2.0 nC) detected all of the six (6) newly commissioned rotating HV machines tested. This puts their HV stator insulation of them all in the ‘Excellent/New’ condition category. Plant Reference Gas Turbine Generator A (10 kV) Gas Turbine Generator B (10 kV) Amine Pump Motor C (10 kV) Amine Pump Motor D (10 kV) Amine Pump Motor E (10 kV) CO2 Compressor Motor F (10 kV) PD Peak Level (nC) < 2.0 < 2.0 < 2.0 < 2.0 < 2.0 < 2.0 Condition Assessment ‘New/Excellent’ ‘New/Excellent’ ‘New/Excellent’ ‘New/Excellent’ ‘New/Excellent’ ‘New/Excellent’ At Test – After 4 Years of Service - the second set of OLPD test results from testing after 4 years of service (tested after failure and replacement of Amine Pump Motor D) shown below shows that the PD activity had increased on all machines, apart from Compressor Motor F that remained in the ‘New/Excellent’. The new replacement Amine Pump Motor D had ‘Average’ condition levels of 9.6nC. Plant Reference Gas Turbine Generator A (10 kV) Gas Turbine Generator B (10 kV) Amine Pump Motor C (10 kV) Amine Pump Motor D (10 kV) - replacement after failure of original Motor D stator fault Amine Pump Motor E (10 kV) CO2 Compressor Motor F (10 kV) PD Peak Level (nC) 13.1 20.5 11.7 Condition Assessment ‘Still Acceptable’ ‘Probable Inspection’ ‘Still Acceptable’ 9.6 ‘Average’ 12.1 < 2.0 ‘Still Acceptable’ ‘New/Excellent’ Conclusions and Recommendations The main conclusion to this case study is that leaving 4 years between OLPD tests is too long! Due to the difficulty in mobilising test engineers to remote locations (such as this gas facility in North Africa) an increasing number of facilities in the oil & gas industry are deploying continuous partial discharge monitoring technology such as the HVPD Kronos® to monitor their ‘mission-critical’ rotating HV machines. HVPD Head Office Certificate Number 9329 ISO 9001, ISO 14001, OHSAS 18001 128 Metroplex Business Park Broadway, MediaCityUK Salford, M50 2UW United Kingdom +44 (0)161 877 6142 +44 (0)161 877 6139 [email protected] www.hvpd.co.uk
