ISO 10605 AMD 1-2014 Road vehicles - Test methods for electrical disturbances from electrostatic discharge Amendment 1《道路车辆 静电放电引起电气干扰的试验方法 修改件1》.pdf

1、 ISO 2014 Road vehicles Test methods for electrical disturbances from electrostatic discharge AMENDMENT 1 Vhicules routiers Mthodes dessai des perturbations lectriques provenant de dcharges lectrostatiques AMENDEMENT 1 INTERNATIONAL STANDARD ISO 10605 Second edition 2008-07-15 Reference number ISO 1

2、0605:2008/Amd.1:2014(E) AMENDMENT 1 2014-04-15 ISO 10605:2008/Amd.1:2014(E)ii ISO 2014 All rights reserved COPYRIGHT PROTECTED DOCUMENT ISO 2014 All rights reserved. Unless otherwise specified, no part of this publication may be reproduced or utilized otherwise in any form or by any means, electroni

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4、 22 749 01 11 Fax + 41 22 749 09 47 E-mail copyrightiso.org Web www.iso.org Published in Switzerland ISO 10605:2008/Amd.1:2014(E) Foreword ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies (ISO member bodies). The work of preparing Intern

5、ational Standards is normally carried out through ISO technical committees. Each member body interested in a subject for which a technical committee has been established has the right to be represented on that committee. International organizations, governmental and non-governmental, in liaison with

6、 ISO, also take part in the work. ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of electrotechnical standardization. The procedures used to develop this document and those intended for its further maintenance are described in the ISO/IEC Directives,

7、 Part 1. In particular the different approval criteria needed for the different types of ISO documents should be noted. This document was drafted in accordance with the editorial rules of the ISO/IEC Directives, Part 2. www.iso.org/directives Attention is drawn to the possibility that some of the el

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10、e to the WTO principles in the Technical Barriers to Trade (TBT) see the following URL: Foreword - Supplementary information The committee responsible for this document is ISO/TC 22, Road vehicles, Subcommittee SC 3, Electric and electronic equipments. ISO 2014 All rights reserved iii Road vehicles

11、Test methods for electrical disturbances from electrostatic discharge AMENDMENT 1 Page 5, Table 2 Replace: “charge voltage” with “test voltage”. Replace Table 2 with the following. Table 2 Contact discharge mode current specifications Typical capaci- tance/ resist- ance values Peak current/ test vol

12、tage A/kV Tolerance % Current at t 1 / test voltage A/kV Tolerance % Current at t 2 / test voltage A/kV Tolerance % 150 pF/330 3,75 10 2 (at t 1= 30 ns) 30 1 (at t 2= 60 ns) 30 330 pF/330 3,75 10 2 (at t 1= 65 ns) 30 1 (at t 2= 130 ns) 30 150 pF/2 000 3,75 0,275 (at t 1= 180 ns) 30 0,15 (at t 2= 360

13、 ns) 50 330 pF/2 000 3,75 0,275 (at t 1= 400 ns) 30 0,15 (at t 2= 800 ns) 50 NOTE 1 The peak current level is taken from the measurement system without any data interpolation. NOTE 2 The target used with this measurement system fulfils the requirements of A.1 and A.2. An example is defined in Annex

14、B. NOTE 3 The measurement times (30 ns, 60 ns, 65 ns, 130 ns, 180 ns, 360 ns, 400 ns and 800 ns) are derived from the resistance-capacitive (RC) time constant 40 % (current t 1 ) and +20 % (current t 2 ), to define two values on the falling slope of the current pulse in accordance with IEC 610004-2.

15、 Pages 19 to 21, Annex A Replace the following in Annex A (see below). In the second sentence of A.2.3.1, replace: “Table A.1” with “Table 1”. At the beginning of the first paragraph of A.2.3.4, add: “The measurement discharge current procedure is shown in Table A.1”. Replace the title of Table A.1:

16、 “Contact discharge verification procedure” with “Contact discharge current waveform verification procedure”. Replace: “output voltage” with “test voltage” and replace: “charge voltage” with “test voltage”. ISO 10605:2008/Amd.1:2014(E) ISO 2014 All rights reserved 1 ISO 10605:2008/Amd.1:2014(E) A.2.

17、3.1 Prior to verifying the discharge current, the amplitude of the ESD generators test voltage should be determined using a high-voltage meter at the electrode tip. The accuracy of the test voltage measurement shall be as specified in Table 1. NOTE The verification of electrode output voltage should

18、 consider electrical structure of ESD generator (e.g. electrical circuit structure) and specification (e.g. input impedance and input stray capacitance) of high-voltage meter for correct measuring. A.2.3.4 The measurement discharge current procedure is shown in Table A.1. The following parameters sh

19、all be measured, or obtained from measured values, in order to verify whether or not the current waveform of an ESD generator is within specifications: I p , the peak value of the discharge current, in A; I 1 , the value of the current at t 1 , in A (from Table 2); I 2 , the value of the current at

20、t 2 , in A (from Table 2); t r , the rise time of the current, in ns.The average value of a parameter X xis indicated by . EXAMPLE I psignifies the average of the peak current values. Table A.1 Contact discharge current waveform verification procedure Step Resistance Explanation 330 2 k Capacitance

21、Capacitance 150 pF 330 pF 150 pF 330 pF Discharge the ESD generator at a given test voltage 10 times, store each resultMultiple measure- ments are taken as the acceptance criteria are given for parameters obtained on the average value by this 10 times discharge data. This is done because there will

22、be some discharge-to-dis- charge variations. Measure I p , I 1 , I 2and t ron each waveform The parameters have to be checked at each test level. Calculate the averages I p , I 1 , I 2 and t rof the measured I p , I 1 , I 2and t rvaluesAverage is taken on the parameters, not by averaging the wavefor

23、ms. This way, any jitter on the trigger will not influ- ence the averaging.2 ISO 2014 All rights reserved ISO 10605:2008/Amd.1:2014(E) Step Resistance Explanation 330 2 k Capacitance Capacitance 150 pF 330 pF 150 pF 330 pF Check: current at t 1 /test voltage (A/kV) Check if I Check if I Check if I C

24、heck if I Again, compliance of the ESD gen- erator is verified on the average of the parameter. Check: current at t 2 /test voltage (A/kV) Check if I Check if I Check if I Check if I Again, compliance of the ESD gen- erator is verified on the average of the parameter. Check: peak current/test voltag

25、e (A/kV) Check if I Check if I % Again, compliance of the ESD gen- erator is verified on the average of the parameter. Check rise time Check if 0,7 ns t r 1 ns Pages 33 to 34, Annex B Add to Figure B.8, key item 6, the following text: “(between attenuator A and network analyser and between attenuato

26、r B and network analyser)”. In B.2.3, in the paragraph following Figure B.8, delete: “(between attenuator and target and between attenuator and target adapter line)”. In B.2.4, in the first list item following Figure B.9, replace: “output voltage” with “voltage”.Table A.1 (continued) ISO 2014 All ri

27、ghts reserved 3 ISO 10605:2008/Amd.1:2014(E) Key 1 network analyser 5 attenuator B 2 ESD current target 6 coaxial cable (between attenuator A and network analyser and between attenuator B and network analyser) 3 50 conical adapter line 7 network analyser output connector 4 attenuator A 8 network ana

28、lyser input connector NOTE The ESD current target, attenuator A and the coaxial cable are the target-attenuator-cable chain, which is verified using this set-up. a Calibrate the network analyser at these points. Figure B.8 Network analyser measurement of the insertion loss of a current target-attenu

29、ator-cable chain The measurement procedure for the insertion loss is to calibrate the network analyser at the verification points shown in Figure B.8. B.2.4 Determining the d.c. transfer resistance of a target-attenuator-cable chain The d.c. system transfer resistance of the target-attenuator-cable

30、chain may be determined by the method below. Inject a current I sysof approximately 1 A into the front side of the current target. The front side is the side to which discharges are made. The current shall be known within 1 %. Larger currents may be used if they do not thermally stress the target be

31、yond its specifications. Measure the test voltage, V, across the precision 50 load. Page 42, E.2 Replace the paragraph following list item c) with the following, replacing “charge voltage” with “test voltage”.4 ISO 2014 All rights reserved ISO 10605:2008/Amd.1:2014(E) Due to the complexity of air di

32、scharge, no satisfactory verification method has been developed. Therefore it was decided not to require an air discharge verification. The operator should be aware that using a fully compliant contact mode generator in the air discharge testing mode can result in a small or very large rate of ESD c

33、urrent change (for the same generator electrode test voltage) between discharges. This is exactly what happens in realistic air discharge ESD events. Pages 45 to 46,Figures F.1 and F.2 Insert the following new Figures F.2 and F.3. Dimensions in millimetres Key 1 field coupling plane 9 artificial net

34、work (AN) (if used) 2 field coupling strip 10 ground reference point for battery and support equipment 3 discharge island 11 DUT local ground (if required) 4 DUT and wiring harness isolation block 12 ground reference point for ESD coupling plane, ESD generator and safety ground connection 5 DUT 13 2

35、 470 k high-voltage resistors to safety ground 6 DUT wiring harness 14 HCP 7 battery 15 ESD generator main unit 8 peripheral or support equipment NOTE The tolerance of dimensions is 5 %. Figure F.2 Test set-up Application of direct discharges ISO 2014 All rights reserved 5 ISO 10605:2008/Amd.1:2014(

36、E) Dimensions in millimetres Key 1 field coupling plane 9 AN (if used) 2 field coupling strip 10 ground reference point for battery and support equipment 3 discharge island 11 DUT local ground (if required) 4 DUT and wiring harness isolation block 12 ground reference point for ESD coupling plane, ES

37、D generator and safety ground connection 5 DUT 13 2 470 k high voltage resistors to safety ground 6 DUT wiring harness 14 HCP 7 battery 15 ESD generator main unit 8 peripheral or support equipment NOTE The tolerance of dimensions is 5 %. Figure F.3 Test set-up Application of indirect discharges6 ISO 2014 All rights reserved ISO 10605:2008/Amd.1:2014(E) ISO 2014 All rights reserved ICS 43.040.10 Price based on 6 pages