BS EN 62475:2010
$215.11
High-current test techniques. Definitions and requirements for test currents and measuring systems
| Published By | Publication Date | Number of Pages |
| BSI | 2010 | 108 |
IEC 62475:2010 is applicable to high-current testing and measurements on both high-voltage and low-voltage equipment. It deals with steady-state and short-time direct current (as e.g. encountered in high-power d.c. testing), steady-state and short-time alternating current (as e.g. encountered in high-power a.c. testing), and impulse-current. In general, currents above 100 A are considered in this International Standard, although currents less than this can occur in tests. This standard also covers fault detection during, for example, lightning impulse testing.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 7 | English CONTENTS |
| 13 | 1 Scope 2 Normative references 3 Terms and definitions |
| 14 | 3.1 Measuring systems 3.2 Components of a measuring system |
| 15 | 3.3 Scale factors |
| 16 | 3.4 Rated values 3.5 Definitions related to the dynamic behaviour |
| 17 | 3.6 Definitions related to uncertainty Figures Figure 1 ā Examples of amplitude frequency responses for limit frequencies (f1; f2) Upper and lower limits frequencies are shown on curve A. Curve B shows a constant response down to direct current |
| 19 | 3.7 Definitions related to tests on measuring systems |
| 20 | 4 Procedures for qualification and use of a measuring system 4.1 General principles 4.2 Schedule of performance tests 4.3 Schedule of performance checks |
| 21 | 4.4 Requirements for the record of performance 4.5 Operating conditions |
| 22 | 4.6 Uncertainty |
| 23 | 5 Tests and test requirements for an approved measuring system 5.1 General requirements 5.2 Calibration ā Determination of the scale factor |
| 25 | FigureĀ 2 ā Calibration by comparison over full assigned measurement range |
| 26 | FigureĀ 3 ā Uncertainty contributions of the calibration (example with the minimum of 5 current levels) |
| 27 | FigureĀ 4 ā Calibration by comparison over a limited current range with a linearity test (see ā5.3) providing extension up to the largest value in the assigned measurement range |
| 28 | 5.3 Linearity test |
| 29 | 5.4 Dynamic behaviour Figure 5 ā Linearity test of the measuring system with a linear device in the extended voltage range |
| 30 | 5.5 Short-term stability |
| 31 | FigureĀ 6 ā Short-term stability test for steady-state current FigureĀ 7 ā Short-term stability test for impulse current and short-time current |
| 32 | 5.6 Long-term stability 5.7 Ambient temperature effect FigureĀ 8 ā Short-term stability test for periodic impulse-current and periodic short-time current |
| 33 | 5.8 Effect of nearby current paths |
| 34 | FigureĀ 9 ā Test circuit for effect of nearby current path for current-converting shunts and current transformers with iron FigureĀ 10 ā Test circuit for effect of nearby current path for inductive measuring systems without iron (Rogowski coils) |
| 35 | 5.9 Software effect 5.10 Uncertainty calculation |
| 37 | 5.11 Uncertainty calculation of time-parameter measurements (impulse currents only) |
| 39 | 5.12 Interference test |
| 40 | FigureĀ 11 ā Principle of interference test circuit FigureĀ 12Ā āĀ Interference test on the measuring system i1(t) based on current converting shunt or current transformer with iron in a typical 3 phase short circuit set up (example) |
| 41 | 5.13 Withstand tests FigureĀ 13 ā Test circuit for interference test for inductive systems without iron |
| 42 | 6 Steady-state direct current 6.1 Application 6.2 Terms and definitions 6.3 Test current |
| 43 | 6.4 Measurement of the test current Tables TableĀ 1 ā Required tests for steady-state direct current |
| 44 | 6.5 Measurement of ripple amplitude |
| 45 | TableĀ 2 ā Required tests for ripple current |
| 46 | 6.6 Test procedures 7 Steady-state alternating current 7.1 Application 7.2 Terms and definitions 7.3 Test current |
| 47 | 7.4 Measurement of the test current |
| 48 | FigureĀ 14 ā Acceptable normalized amplitude-frequency response of an a.c. measuring system intended for a single fundamental frequency fnom |
| 49 | FigureĀ 15 ā Acceptable normalized amplitude-frequency response of an a.c. measuring system intended for a range of fundamental frequencies fnom1 to fnom2 TableĀ 3 ā Required tests for steady-state alternating current |
| 50 | 7.5 Test procedures 8 Short-time direct current 8.1 Application |
| 51 | 8.2 Terms and definitions FigureĀ 16 ā Example of short-time direct current |
| 52 | 8.3 Test currents 8.4 Measurement of the test current TableĀ 4 ā Tolerance requirement on test-current parameters for short-time direct current |
| 53 | TableĀ 5 ā Required tests for short-time direct current |
| 54 | 8.5 Test procedures 9 Short-time alternating current 9.1 Application |
| 55 | 9.2 Terms and definitions FigureĀ 17 ā Example of short-time alternating current |
| 56 | 9.3 Test current TableĀ 6 ā Tolerance requirements on the short-time alternating current test parameters |
| 57 | 9.4 Measurement of the test current TableĀ 7 ā List of typical tests in a high-power laboratory and required minimum frequency range of the measuring system |
| 58 | TableĀ 8 ā Tolerance requirements on scale factor TableĀ 9 ā Required tests for short-time alternating current |
| 60 | 9.5 Test procedures 10 Impulse currents 10.1 Application 10.2 Terms and definitions |
| 61 | FigureĀ 18 ā Exponential impulse current FigureĀ 19 ā Exponential impulse current ā Oscillating tail |
| 62 | FigureĀ 20 ā Impulse current ā Rectangular, smooth FigureĀ 21 ā Impulse current ā Rectangular with oscillations |
| 64 | 10.3 Test current TableĀ 10 ā Examples of exponential impulse-current types |
| 65 | 10.4 Measurement of the test current |
| 67 | TableĀ 11 ā Required tests for impulse current |
| 68 | 10.5 Test procedures 11 Current measurement in high-voltage dielectric testing 11.1 Application 11.2 Terms and definitions |
| 69 | 11.3 Measurement of the test current TableĀ 12 ā Required tests for impulse current in high-voltage dielectric testing |
| 70 | 11.4 Test procedures 12 Reference measuring systems 12.1 General 12.2 Interval between subsequent calibrations of reference measuring systems |
| 71 | Annex A (informative) Uncertainty of measurement |
| 76 | TableĀ A.1 ā Coverage factor k for effective degrees of freedom Ī½eff (pĀ =Ā 95,45Ā %) |
| 77 | TableĀ A.2 ā Schematic of an uncertainty budget |
| 78 | FigureĀ A.1 ā Normal probability distribution p(x) of a continuous random variable x FigureĀ A.2 ā Rectangular symmetric probability distribution p(x) of the estimate x of an input quantity X |
| 79 | Annex B (informative) Examples of the uncertainty calculation in high-current measurements |
| 81 | Table B.1 ā Result of the comparison measurement TableĀ B.2 ā Result of the comparison measurement |
| 82 | Table B.3 ā Uncertainty budget for calibration of scale factor Fx |
| 83 | TableĀ B.4 ā Result of linearity test |
| 84 | FigureĀ B.1 ā Comparison between the system under calibration X and the reference system N Table B.5 ā Uncertainty budget of scale factor FX,mes |
| 85 | Annex C (informative) Step-response measurements FigureĀ C.1 ā Circuit to generate current step using a coaxial cable FigureĀ C.2 ā Circuit to generate current step using a capacitor |
| 87 | Figure C.3 ā Definition of response parameters with respect to step response |
| 88 | Annex D (informative) Convolution method for estimation of dynamic behaviour from step-response measurements |
| 91 | Annex E (informative) Constraints for certain wave shapes FigureĀ E.1 ā Attainable combinations of time parameters (shaded area) for the 8/20 impulse at maximum 20Ā % undershoot and for 20Ā % tolerance on the time parameters |
| 92 | FigureĀ E.2 ā Locus for limit of attainable time parameters as a function of permissible undershoot for the 8/20 impulse FigureĀ E.3 ā Locus for limit of attainable time parameters as a function of permissible undershoot for the 30/80 impulse |
| 93 | Annex F (informative) Temperature rise of measuring resistors |
| 94 | Annex G (informative) Determination of r.m.s. values of short-time a.c. current FigureĀ G.1 ā Equivalent circuit of short-circuit test |
| 95 | FigureĀ G.2 ā Symmetrical a.c. component of an alternating short-circuit current |
| 96 | Figure G.3 ā Numerical evaluation of r.m.s value showing both instantaneous current and instantaneous squared value of the current |
| 97 | Figure G.4 ā Three-crest method |
| 98 | Figure G.5 ā Evaluation of conventional r.m.s. value of an arc current using the three-crest method |
| 99 | Figure G.6 ā Evaluation of equivalent r.m.s value of a short-time current during a short-circuit test |
| 100 | Figure G.7 ā Relation between peak factor k and power factor cos(q). |
| 101 | Annex H (informative) Examples of IEC standards with high-current tests Table H.1 ā List of typical tests with short-time alternating current |
| 102 | Table H.2 ā List of typical tests with exponential impulse current Table H.3 ā List of typical tests with rectangular impulse current |
| 103 | Bibliography |
