2017 INMR WORLD CONGRESS SITGES-BARCELONA, INSULATOR REQUERIMENTS: DESIGN CRITERIA, OPERATION PARAMETERS AND STANDARDS REVIEW JAVIER GARCÍA TECHNICAL AND PRODUCTION MANAGER
CONTENTS q INTRODUCTION q MECHANICAL CONSIDERATIONS q ELECTRICAL CONSIDERATIONS q SELECTION IN POLLUTED AREAS q POLLUTION TESTS STANDARDS q INSULATORS TESTING STATIONS q INSULATORS CORROSION q OPERATION PARAMETERS q ESTIMATED END OF LIFE q CONCLUSIONS Page 2
INTRODUCTION In the market, it could be found many different types of insulators for OHTL: - Glass or porcelain string insulators, - Long-rog insulators, - Composite insulators. Inside of each insulator type there is a wide range of: - Designs, - Qualities, - Materials, - Prices. Besides the market offers different alternatives to improve the performance of the insulator on polluted areas: - Different profiles: Antipollution, Open-profile, Outerib - Silicone coated insulators. -, 3 Page 3 \
INTRODUCTION What is the best material? What is the best design for a particular environment? What criteria could be taken into account in the selection of the material?, What parameter could be taken into account for service evaluation? How to estimate the end of life of the insulator? THERE IS NO SIMPLE ANSWER TO THESE QUESTIONS. But it is possible, at least, to establish the different steps to be considered for evaluation and comparison of the different solutions. INSULATOR SELECTION OPERATIONS PARAMETERS END OF LIFE STUDIES 4 Page 4 \
MECHANICAL CONSIDERATIONS Loss of leakage distance Consequences of a mechanical failure Conductor fall This depends on the design of the insulator. Specified Mechanical Load (SML) > 2 x maximum working load IEC 60383-1 & IEC 61109 Mechanical test, such as Type & sample test. IEC 60797 stablishes the mechanical residual test methods and acceptance criteria for glass or porcelain string insulators with the dielectric broken part. FUTURE WORK: IEC 60383-1 ongoing revision: Include mechanical residual test, like a type test. 5 Page 5 \
ELECTRICAL CONSIDERATIONS Arcing distance Creepage distance Insulator diameter Shed inclination / Shed diameter / Shed spacing impulse withstand/ flashover and dry power frequency characteristics IEC 60071-1 recommends the associated withstand voltages with the highest voltage for the equipment 6 Page 6 \
SELECTION IN POLLUTED AREAS Last edition of series IEC TS 60815 has developed new techniques for the selection and dimensioning of high voltage insulators in polluted areas. AIM Determinate the most efficient insulation Three approaches recommend to select suitable insulators based on system requirements and environmental conditions: Approach 1: Use past experience Approach 2: Measure and test Approach 3: Measure and design 1 st step. Determination of SPS (Site Pollution Severity) From ESDD & NSDD for type A pollution From SES (Site Equivalent Salinity) for type B pollution 2 nd step. Determination of the Unified Specific Creepage Distance (USCD) reference. The applicability of each approach depends on available data, time and economics involved in the project. 7 Page 7 \
SELECTION IN POLLUTED AREAS Choice of profile glass and porcelain insulators Different types of insulators and even different positions of the same insulator type may accumulate pollution at different rates in the same environment. In addition, variations in the nature of the pollutant may make some shapes of insulators more effective than others. IEC TS 60815-2 - Table 1 shows a brief summary of the principal advantages and disadvantages of the main profile types with respect to pollution performance. 8 Page 8 \
SELECTION IN POLLUTED AREAS Profile suitability glass and porcelain insulators IEC IEC TS 60815-2 - Tables 2 & 3 give simple merit values for porcelain and glass insulator profiles. 9 Page 9 \
SELECTION IN POLLUTED AREAS Choice of profile glass and porcelain insulators IEC TS 60815-2 & IEC TS 60815-3 give profiles parameters to take into account for glass and porcelain, and polymer insulators respectively: Alternating sheds and shed overhang; Creepage distance versus clearances; Minimum distance between sheds; Spacing versus shed overhang; Shed angle; Creepage factor. 10 Page 10 \
POLLUTION TESTS STANDARDS IEC 60507 IEC 61245 Pollution tests on glass and porcelain insulators on a laboratory could be carried out for two main objectives: To obtain information about the pollution performance of insulators (comparison of different insulator types/profiles) To check the performance in a configuration as close as possible to the in-service one. Two categories of pollution test methods are recommended: Salt fog method, in which the insulators are subjected to a defined pollution degree. Solid layer method, in which a fairly uniform layer of a defined solid pollution is deposited on the insulators surface. 11 Page 11 \
POLLUTION TESTS STANDARDS IEC 60507 IEC61245 IMPORTANT: These IEC laboratory standardized pollution test methods are not applicable for: composite (polymeric) or RTV-coated insulators. A proposal for a test method for artificially polluted polymer insulators i s covered by the recent CIGRE TB 555. 12 Page 12 \ In the case of naturally polluted insulators removed from the service, a recent CIGRE TB 691 (WG D1.44) Pollution Test of Naturally and Artificially contaminated insulators summarizes the recent experience with so-called rapid flashover test methods: Rapid Flashover Test (RFO, based on IEC 60507 solid layer test). Quick Flashover (QF, based on IEC 60507 salt fog test).
INSULATORS TESTING STATIONS Many variable environmental parameters which influence an insulator s behavior over its lifetime are difficult to simulate artificially and, moreover, to accelerate. Thus, the validity of laboratory tests is often questioned as the procedures adopted may not take into account significant factors which would be encountered in service or others may be over-emphazised. The evaluation of insulator performance in naturally polluted outdoor test stations is becoming more important and popular - Involving a longer test duration. Requiring care in the correct interpretation of the test data. 13 Page 13 \ + The results tend to be accepted with more confidence. It is also a good tool for new insulation technologies, in which there is yet no technical or normative specifications for its testing or characterization.
INSULATORS TESTING STATIONS - Goals To compare the performance of insulators of different design. To compare the performance of insulators from different manufacturers. To dimension insulators for a particular environment or application. To examine the behavior of insulators of different dielectric materials. To compare the performance of insulators in different orientations. To explore the effects of specific parameters, such as profile geometries or insulators diameters. To identify possible weaknesses or failure mechanisms of an insulator design. To estimate the life expectancy of various insulators. To serve as a qualification test for potential suppliers. To establish the effectiveness and life of insulator treatments, such as washing, greasing, silicone rubber coating, shed extenders, etc. To assess the performance of other outdoor equipment insulation, such as transformer bushings, surge arresters, cable terminations, etc. La Granja Insulators tests - Permanent insulator research station at Martigues 14 Page 14 \
INSULATORS TESTING STATIONS 4 types Research station Simplified, on-line station Monitored: Leakage current activity Climatic effects and Pollution severity are usually Inspection: Visual examination Hydrophobicity In-service test structure Mobile test stations 15 Page 15 \
INSULATORS CORROSION Chapter 26 IEC-60383-1 standardizes the minimum average coating mass for the metal fitting of the insulators: 600g/m2 (85µm). This value could increase until 140µm for insulators to be installed on very high corrosion areas. This permits to increase the estimated end of life. Zinc thickness vs. service live 16 Page 16 \
INSULATORS PIN CORROSION The zinc sleeve is galvanically positive and has a large potential difference from iron. It works like a sacrificial electrode at the cement boundary where the current flows. Pin without zinc sleeve on high corrosion area a8er several years in service FUTURE WORK: IEC 60383-1 ongoing revision : Include Zinc sleeve test similar to current mentioned on IEC 61325 (DC suspension insulators). Bonded area Z i n c purity IEC 61325 requirements 17 Page 17 \ Improved requirements 80% 95% 99,8% 99.95% Zinc sleeve posi1on
OPERATION PARAMETERS DATABASE Type / Sub-type of string; Type of insulation: Glass, porcelain, composite, coated glass, etc. Sub-type of insulator: Standard profile, pollution profile Number of insulators per string; Insulation manufacturer; Insulator traceability data (Production order, production date ) Standard; Installation year; Silicone manufacture / applicator; Estimated end of life Degradation environment: Normal, hard and very hard. MAINTENANCE INDICATORS Number of faults Insulator breakage rate Washing frequency - MAINTENANCE DECISIONS - REPLACEMENT OF THE INSULATION - COMPARISON OF THE DIFFERENT TYPES OF MATERIALS, PROFILES AND MANUFACTURERS QUALITY. 18 Page 18 \
ESTIMATED END OF LIFE GLASS AND PORCELAIN INSULATORS (1) Balanced design parameter Choice of material Control / Mastering of quality & manufacturing processes required to ensure high long term reliability This document stablishes a testing sequence with a number of nondestructive tests as: Visual tests (e.g. degree of corrosion), Dimensional test, Thermal test, Thermal-mechanical tests. These first series of tests are followed by destructive mechanical tests. 19 Page 19 \
ESTIMATED END OF LIFE GLASS AND PORCELAIN INSULATORS (2) A probability diagram based on normal distribution is used to analyze the failing load test results and compare with several reference scenarios The failing load characteristics are represented by: A dashed insulators sample tested when new. A solid line insulators as-received from the line. A dashed/dotted line insulators submitted to the Thermal-Mechanical Test (TMP-test) The SFL (Specified Failing Load) solid vertical line. Example: reference scenario F1 The reductions in strength are not representative of good quality products. Age and TMP-test have only negligible influence on good products. 20 Page 20 \
ESTIMATED END OF LIFE COMPOSITE INSULATORS Different methods, philosophies and tools are describe. They enable a conclusion regarding the residual lifetime of composite insulators of the same age and design family. The document also gives guidelines in case of a failure investigation, a unit recognized as high risk, and the evaluation of units for research. Recommended sequence of tes1ng 21 Page 21 \
CONCLUSIONS The selection of the insulator type is not a simple job, especially if the insulator will be installed in a high polluted area. Numerous documentations (IEC Standards, CIGRE Technical Brochures, papers ) are available to help on the selection of the most appropriate insulator, on the monitoring of the behavior in operation and on the determination of the estimated end of life. Different solutions are available to improve the insulator performance on high corrosion areas. Several factors must be taken into account on the insulator type selection: More effective design/material; Maintenance costs: Inspection cost, cleaning cost, replacement costs, Expected service breakage rate to be guaranteed/certified by the supplier; Severity of consequences in case of failure (mechanical breakage, electrical failure, ); Expected end of life. 22 Page 22 \
2017 INMR WORLD CONGRESS SITGES-BARCELONA, THANK YOU FOR YOUR ATTENTION! JAVIER GARCÍA TECHNICAL AND PRODUCTION MANAGER