1、raising standards worldwideNO COPYING WITHOUT BSI PERMISSION EXCEPT AS PERMITTED BY COPYRIGHT LAWBSI Standards PublicationBS EN 50463-2:2012Railway applications Energymeasurement on board trains -Part 2: Energy measuringBS EN 50463-2:2012 BRITISH STANDARDNational forewordThis British Standard is the
2、 UK implementation of EN 50463-2:2012.Together with BS EN 50463-1:2012, BS EN 50463-3:2012, BSEN 50463-4:2012 and BS EN 50463-5:2012 it supersedes BS EN50463:2007, which is withdrawn.The UK participation in its preparation was entrusted to TechnicalCommittee GEL/9, Railway Electrotechnical Applicati
3、ons.A list of organizations represented on this committee can beobtained on request to its secretary.This publication does not purport to include all the necessaryprovisions of a contract. Users are responsible for its correctapplication. The British Standards Institution 2013. Published by BSI Stan
4、dardsLimited 2013ISBN 978 0 580 69930 6ICS 45.060.10Compliance with a British Standard cannot confer immunity fromlegal obligations.This British Standard was published under the authority of theStandards Policy and Strategy Committee on 31 January 2013.Amendments issued since publicationDate Text af
5、fectedBS EN 50463-2:2012EUROPEAN STANDARD EN 50463-2 NORME EUROPENNE EUROPISCHE NORM December 2012 CENELEC European Committee for Electrotechnical Standardization Comit Europen de Normalisation Electrotechnique Europisches Komitee fr Elektrotechnische Normung Management Centre: Avenue Marnix 17, B -
6、 1000 Brussels 2012 CENELEC - All rights of exploitation in any form and by any means reserved worldwide for CENELEC members. Ref. No. EN 50463-2:2012 E ICS 45.060.10 Supersedes EN 50463:2007 (partially) English version Railway applications - Energy measurement on board trains - Part 2: Energy measu
7、ring Applications ferroviaires - Mesure dnergie bord des trains - Partie 2 : Mesure dnergie Bahnanwendungen - Energiemessung auf Bahnfahrzeugen - Teil 2: Energiemessung This European Standard was approved by CENELEC on 2012-10-15. CENELEC members are bound to comply with the CEN/CENELEC Internal Reg
8、ulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references concerning such national standards may be obtained on application to the CEN-CENELEC Management Centre or to any CENELEC
9、 member. This European Standard exists in three official versions (English, French, German). A version in any other language made by translation under the responsibility of a CENELEC member into its own language and notified to the CEN-CENELEC Management Centre has the same status as the official ve
10、rsions. CENELEC members are the national electrotechnical committees of Austria, Belgium, Bulgaria, Croatia, Cyprus, the Czech Republic, Denmark, Estonia, Finland, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta,
11、the Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and the United Kingdom. BS EN 50463-2:2012EN 50463-2:2012 - 2 - Contents Foreword .5 Introduction .6 1 Scope . 8 2 Normative references . 9 3 Terms, definitions, abbreviations and symbols 10 3.
12、1 Terms and definitions . 10 3.2 Abbreviations 13 3.3 Symbols . 14 4 Requirements .14 4.1 General 14 4.2 Energy Measurement Function (EMF) 15 4.3 Sensors 19 4.4 Energy Calculation Function (ECF) 31 5 Conformity assessment .42 5.1 General 42 5.2 Testing framework 43 5.3 Design review . 44 5.4 Type te
13、sting 45 5.5 Routine test 68 Annex A (normative) Test with magnetic induction of external origin 71 Annex B (normative) EMF Configurations .73 B.1 Background 73 B.2 General 73 B.3 EMF with several CMFs in parallel . 73 B.4 EMF with several VMFs connected to one ECF . 74 B.5 EMF with several pairs of
14、 VMF and CMF . 75 B.6 Several EMFs in parallel 75 B.7 One VMF or CMF connected to several ECFs 76 B.8 EMF without VMF . 76 Annex C (informative) Expressing EMF accuracy 77 C.1 Summary 77 C.2 Error limits or uncertainty 77 C.3 Presentation of error limits 78 C.4 Uncertainty calculations 79 Annex D (i
15、nformative) Re-verification and defining of its regime recommendations .84 D.1 Re-verification 84 D.2 Defining re-verification regime recommendations . 85 BS EN 50463-2:2012- 3 - EN 50463-2:2012 Annex E (informative) Durability test .87 E.1 Durability test 87 Annex ZZ (informative) Coverage of Essen
16、tial Requirements of EU Directives 91 Bibliography . 92 Figures Figure 1 EMS functional structure and dataflow diagram .7 Figure 2 EMF functional block diagram .8 Figure 3 Example of energy index value 11 Figure 4 Example of maximum percentage error for a VMF of class 0,5 R and a VMF of class 1,0 R
17、with input signal in the range Umin1 U Umax224 Figure 5 Example of maximum percentage error for a CMF class 1,0 R a.c. with input signals in the range 10 % In I 120 % In, 5 % In I 10 V: 1 VA, 2 VA, 4 VA or 5 VA; b) for rated secondary voltage 10 V: 0,001 VA, 0,01 VA, 0,1 VA or 0,5 VA; c) for current
18、 outputs, a burden such that the voltage across the burden at maximum input voltage shall not exceed 45 V (a.c. r.m.s. or d.c.). 4.3.3.1.3 Influence of input overvoltage The sensors shall not be damaged by overvoltage of Umax3in accordance with EN 50163:2004, Table A.1. The sensors shall perform cor
19、rectly when returned to initial working conditions. 4.3.3.1.4 Response time (ts,r) Sensors for d.c. measurement shall have a maximum response time of 10 ms. NOTE If the d.c. sensor is to be used in a system where the energy content associated with harmonics is significant, a shorter resonse time may
20、 be appropriate. BS EN 50463-2:2012EN 50463-2:2012 - 22 - 4.3.3.1.5 Bandwidth requirements for electronic sensors The supplier shall provide a curve showing the variation in performance of the sensor for variation in frequency. NOTE 1 This will give an overall view of the frequency performances of t
21、he sensor. For a sensor with digital output, the supplier shall specify the maximum frequency (fa) which can be measured without aliasing. For sensors with a digital output, fais usually half the sampling frequency used. NOTE 2 This will give an overall view of the frequency performances of the sens
22、or. 4.3.3.1.6 Power frequency withstand voltage for earthed terminals Any terminal of the voltage sensors measuring circuit which is intended to be connected to (the traction unit) earth and which is also insulated from the metallic case or other accessible conductive parts of the sensor, shall with
23、stand a rated power frequency short duration withstand voltage of 3 kV (r.m.s.) for 1 min. 4.3.3.2 Short circuit withstand and fault protection for analogue sensors Application of a short circuit to the analogue output or outputs of a sensor shall not damage the sensor. The duration of the short cir
24、cuit shall be 1 s (for passive sensors), or 60 s (for electronic sensors). For electronic sensors, the supplier shall indicate the type of current limiting measures used (if any). For electronic sensors, the supplier shall specify any time delay between removal of the short circuit and the outputs r
25、eturning to within specified accuracy limits. The time delay shall not exceed 5 s. Fault protection for electronic sensors shall be provided in accordance with EN 50155:2007, 7.2.2. 4.3.3.3 Limit of temperature rise Sensors with electrical insulation shall be assigned a thermal class in accordance w
26、ith EN 60085. The permitted temperature limits for other components shall be stated by the supplier. The sensor shall not exceed these limits and shall not be damaged when operating under the following conditions: continuous operation at Umax2and at the rated frequency; maximum applicable ambient te
27、mperature of the temperature class selected in accordance with environmental requirements of EN 50463-1:2012, 4.3.6.2; output conditions which creates the highest temperatures in the sensor; if applicable, the auxiliary power supply which creates the highest temperatures in the sensor. 4.3.3.4 Accur
28、acy requirements The VMF shall be assigned an accuracy class selected from Table 4. BS EN 50463-2:2012- 23 - EN 50463-2:2012 Table 4 Percentage error limits - VMH Accuracy class Maximum percentage voltage (ratio) error at voltage defined in EN 50163 VMF Maximum phase displacement at voltage defined
29、in EN 50163 a.c. VMH (minutes) at rated frequency Umin2 U Umin1Umin1 U Umax2Umin2 U Umin1Umin1 U Umax20,2 R 0,4 0,2 15 10 0,5 R 1,0 0,5 30 20 0,75 R 1,5 0,75 45 30 1,0 R 2,0 1,0 60 40 For traction unit designed for multiple traction supply systems, a single voltage sensor can be used if it achieves
30、the accuracy requirement defined in Table 4 for each rated voltage. 4.3.3.5 Effect of temperature on error limits 4.3.3.5.1 Limits of error including the effects of ambient temperature variation The maximum percentage error, including the effects of temperature variation, shall not exceed the values
31、 given in Table 5. In order to be able to achieve compliance with the maximum error limits specified in Table 5, a VMF of a given class can have its maximum error at reference temperature constrained to a value lower than the maximum allowed by the accuracy class as specified in Table 4. If this is
32、the case, the supplier shall declare this lower maximum error limit at reference temperature and give evidence to demonstrate this lower limit will ensure the maximum limits given in Table 5 are not exceeded. Table 5 Maximum percentage error for a VMF including ambient temperature variation Value of
33、 voltage System type Maximum percentage error limits for a VMF Ambient temperature variation, main range -10 C to +50 C (or +60 C for indoor) Ambient temperature variation, extended range -40 C to 10 C (and +60 C to +75 C for indoor) Umin2 U Umax2a.c. and d.c. Nb+ (0,01 Ta) Nb+ (0,02 Ta) a T is the
34、temperature variation in Kelvin between reference temperature 23 C and the ambient temperature. b The term N is the maximum allowable percentage ratio error allowed for the VMF class as specified in Table 4. For example, for a class 0,5 R VMF and input signal in the range Umin1 U Umax2, the formula
35、for the main temperature range becomes 0,5 + (0,01 x T) and for the input signal in the range Umin2 U Umin1the formula becomes 1,0 + (0,01 x T). BS EN 50463-2:2012EN 50463-2:2012 - 24 - NOTE As an example, the maximum percentage error limits with an input signal in the range Umin1 U Umax2for a class
36、 0,5 R and a class 1,0 R VMF over the temperature range in accordance with Table 5 are shown in Figure 4. Figure 4 Example of maximum percentage error for a VMF of class 0,5 R and a VMF of class 1,0 R with input signal in the range Umin1 U Umax2 4.3.3.5.2 Mean temperature coefficient of a VMF In add
37、ition to the requirements in 4.3.3.5.1, the mean temperature coefficient of a VMF shall not exceed the limits specified in Table 6. Table 6 Temperature coefficient for VMF Accuracy class Mean temperature coefficient %/K Umin2 U Umax20,2 R 0,02 0,5 R 0,025 0,75 R 0,03 1,0 R 0,035 The maximum addition
38、al percentage error due to temperature variation specified in Table 5 and the temperature coefficients specified in Table 6 only apply in the range defined by the devices maximum and minimum ambient temperature limits according to the applicable temperature class requirements of EN 50463-1:2012, 4.3
39、.6.2. BS EN 50463-2:2012- 25 - EN 50463-2:2012 4.3.3.6 Limits of additional error due to influence quantities The limit of variation in errors due to changes in an influence quantity with respect to reference conditions, as given in Table 2, shall not exceed the limits for the relevant accuracy clas
40、s given in Table 7. Table 7 Influence quantities for voltage sensors Influence quantity Specified measuring range / measuring points VMF Additional percentage error limits or output offset = Ng Value of voltage aVariations of supply voltage according to EN 50155:2007, 5.1b Umin1 U Umax2 0,2 N Magnet
41、ic induction of external origin c - maximum magnetic induction, as specified by the supplier 0 V Un N/100 x Umin1 0,5 N Fast transient bursts d 0 V for Umin1 0,5 N/100 x Umin1 0,5 N Electromagnetic RF fieldse0 V for Umin1 2,0 N/100 x Umin1 2,0 N aUnis the rated primary voltage of the EMF. bThe test
42、conditions are specified in 5.4.3.6, test a) and b). cThe test conditions are specified in 5.4.3.8. d The test conditions are specified in 5.4.3.9, test c). e The test conditions are specified in 5.4.3.9, test d) and e). f If the sensor response is linear from 0 to maximum value, the test can be per
43、formed without any primary input. If not the test shall be performed with Umin1. g N is the numeric part of the accuracy class designation. BS EN 50463-2:2012EN 50463-2:2012 - 26 - 4.3.4 Current sensors 4.3.4.1 Electrical requirements 4.3.4.1.1 Rated primary current (In,CMF) The sensor rated primary
44、 current input shall be equal to the rated primary current (In,EMF) of the EMF. NOTE It is permitted to test the same CMF for different rated primary currents (In,EMF), in order to reduce the number of different types of CMF 4.3.4.1.2 Rated continuous thermal current (ICMF,cth) The rated continuous
45、thermal current shall be at least 1,2 times the rated primary current unless specifically agreed between the purchaser and the supplier. 4.3.4.1.3 Rated short-time thermal current (ICMF,th) The rated short-time current shall be equal to the maximum fault current for the traction supply system on whi
46、ch the sensor is intended to be used as specified in EN 50388:2005, Table 7. The duration of the short-time current shall be 0,3 s for a.c. and 0,1 s for d.c. NOTE The durations are based on EN 50388:2005, Annex A. The current sensor shall withstand this current without damage. 4.3.4.1.4 Rated dynam
47、ic current (ICMF,dyn) The rated dynamic current shall be at least 2,5 times the rated short-time thermal current for a.c. systems and 1,0 times the rated short-time thermal current for d.c. systems, unless specifically agreed between the purchaser and the supplier. The current sensor shall withstand
48、 this current without damage. 4.3.4.1.5 Rated secondary values The rated secondary values of the sensor output shall be equal to the rated input of the ECF to which it is connected. The value for the secondary output signal shall be agreed between purchaser and supplier. 4.3.4.1.5.1 Rated secondary
49、output signal for analogue sensors The rated output signal, either as a current or a voltage, shall be defined. The preferred values are: a) for sensors with current output: 50 mA, 100 mA, 200 mA, 400 mA, 500 mA, 800 mA, 1 A, 2 A or 5 A; b) for sensors with voltage output: 22,5 mV, 150 mV, 200 mV, 225 mV, 4 V or 10 V. 4.3.4.1.5.2 Rated output power The rated output power shall be defined. For sensors with analogue current output, the preferred v
