Railway applications - Fixed installations - Electrical safety, earthing and the return circuit - Part 2: Provisions against the effects of stray currents caused by DC traction systems

This document specifies requirements for protective provisions against the effects of stray currents, which result from the operation of DC electric traction power supply systems. As several decades' experience has not shown evident corrosion effects from AC electric traction power supply systems, this document only deals with stray currents flowing from a DC electric traction power sup-ply system. This document applies to all metallic fixed installations which form part of the traction system, and also to any other metallic components located in any position in the earth, which can carry stray currents resulting from the operation of the railway system. This document applies to all new DC lines and to all major revisions to existing DC lines. The principles can also be applied to existing electrified transportation systems where it is necessary to consider the effects of stray currents. This document does not specify working rules for maintenance but provides design requirements to allow maintenance. The range of application includes: a) railways, b) guided mass transport systems such as: 1) tramways, 2) elevated and underground railways, 3) mountain railways, 4) magnetically levitated systems, which use a contact line system, and 5) trolleybus systems, c) material transportation systems. This document does not apply to d) electric traction power supply systems in underground mines, e) cranes, transportable platforms and similar transportation equipment on rails, temporary structures (e.g. exhibition structures) in so far as these are not supplied directly from the contact line system and are not endangered by the electric traction power supply system, f) suspended cable cars, g) funicular railways. This document does not specify working rules for maintenance.

Bahnanwendungen - Ortsfeste Anlagen - Elektrische Sicherheit, Erdung und Rückleitung - Teil 2: Schutzmaßnahmen gegen Streustromwirkungen durch Gleichstrombahnen

Applications ferroviaires - Installations fixes - Sécurité électrique, mise à la terre et circuit de retour - Partie 2: Mesures de protection contre les effets des courants vagabonds issus de la traction électrique à courant continu

Le présent document spécifie les exigences relatives aux dispositions de protection contre les effets des courants vagabonds dus au fonctionnement des systèmes d’alimentation de traction électrique en courant continu. Plusieurs décennies d'expérience n'ayant pas démontré d'effets corrosifs évidents dus aux systèmes d'ali-mentation de traction électrique en courant alternatif, le présent document traite uniquement des courants vagabonds issus des systèmes d'alimentation de traction électrique en courant continu. Le présent document s'applique à toutes les installations fixes métalliques qui font partie du système de traction ainsi qu'à tout autre composant métallique se trouvant dans le sol, quelle que soit sa position, et qui peut transporter des courants vagabonds issus de l'exploitation du réseau ferroviaire. Le présent document s'applique à l'ensemble des lignes nouvelles en courant continu, ainsi qu'aux rénova-tions majeures des lignes en courant continu existantes. Ces principes peuvent également s'appliquer aux systèmes de transport électrifiés existants lorsqu'il est nécessaire de tenir compte des effets des courants vagabonds. Le présent document ne spécifie pas les règles de travail pour la maintenance, mais définit des exigences de conception pour permettre la maintenance. Le présent document s'applique aux applications suivantes : a) les réseaux ferroviaires ; b) les réseaux de transport en commun guidés tels que : 1) les tramways ; 2) les voies ferroviaires aériennes et souterraines ; 3) les voies ferroviaires de montagne ; 4) les systèmes à sustentation magnétique, qui utilisent un système de ligne de contact, et 5) les systèmes de trolleybus ; c) les systèmes de transport de matériaux. Le présent document ne s'applique pas aux : d) systèmes d’alimentation de traction électrique des mines souterraines ; e) grues, plateformes transportables et autres matériels de transport similaires sur rails, structures tempo-raires (dans les foires et expositions, par exemple) lorsqu'ils ne sont pas alimentés par les lignes aé-riennes de contact, directement, ni affectés par le système d'alimentation électrique de traction ; f) téléphériques, télécabines ; g) funiculaires à câbles. Le présent document ne spécifie pas les règles de travail pour la maintenance.

Železniške naprave - Stabilne naprave električne vleke - Električna varnost, ozemljitev in povratni tokokrog - 2. del: Zaščitni ukrepi proti učinkom blodečih tokov, ki jih povzročajo enosmerni sistemi vleke

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Current Stage
5020 - Vote circulated
Due Date
19-Nov-2020

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SLOVENSKI STANDARD
oSIST prEN 50122-2:2021
01-januar-2021
Železniške naprave - Stabilne naprave električne vleke - Električna varnost,
ozemljitev in povratni tokokrog - 2. del: Zaščitni ukrepi proti učinkom blodečih
tokov, ki jih povzročajo enosmerni sistemi vleke

Railway applications - Fixed installations - Electrical safety, earthing and the return circuit

- Part 2: Provisions against the effects of stray currents caused by DC traction systems

Bahnanwendungen - Ortsfeste Anlagen - Elektrische Sicherheit, Erdung und Rückleitung

- Teil 2: Schutzmaßnahmen gegen Streustromwirkungen durch Gleichstrombahnen

Applications ferroviaires - Installations fixes - Sécurité électrique, mise à la terre et circuit

de retour - Partie 2: Mesures de protection contre les effets des courants vagabonds

issus de la traction électrique à courant continu
Ta slovenski standard je istoveten z: prEN 50122-2
ICS:
29.120.50 Varovalke in druga Fuses and other overcurrent
nadtokovna zaščita protection devices
29.280 Električna vlečna oprema Electric traction equipment
oSIST prEN 50122-2:2021 en

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN 50122-2:2021
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oSIST prEN 50122-2:2021
EUROPEAN STANDARD DRAFT
prEN 50122-2
NORME EUROPÉENNE
EUROPÄISCHE NORM
November 2020
ICS 29.120.50; 29.280 Will supersede EN 50122-2:2010 and all of its
amendments and corrigenda (if any)
English Version
Railway applications - Fixed installations - Electrical safety,
earthing and the return circuit - Part 2: Provisions against the
effects of stray currents caused by DC traction systems

Applications ferroviaires - Installations fixes - Sécurité Bahnanwendungen - Ortsfeste Anlagen - Elektrische

électrique, mise à la terre et circuit de retour - Partie 2: Sicherheit, Erdung und Rückleitung - Teil 2:

Mesures de protection contre les effets des courants Schutzmaßnahmen gegen Streustromwirkungen durch

vagabonds issus de la traction électrique à courant continu Gleichstrombahnen
This draft European Standard is submitted to CENELEC members for enquiry.
Deadline for CENELEC: 2021-02-19.
It has been drawn up by CLC/SC 9XC.

If this draft becomes a European Standard, CENELEC members are bound to comply with the CEN/CENELEC Internal Regulations which

stipulate the conditions for giving this European Standard the status of a national standard without any alteration.

This draft European Standard was established by CENELEC 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 versions.

CENELEC members are the national electrotechnical committees of Austria, Belgium, Bulgaria, Croatia, Cyprus, the Czech Republic,

Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, the

Netherlands, Norway, Poland, Portugal, Republic of North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland,

Turkey and the United Kingdom.

Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are aware and to

provide supporting documentation.

Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without notice and

shall not be referred to as a European Standard.
European Committee for Electrotechnical Standardization
Comité Européen de Normalisation Electrotechnique
Europäisches Komitee für Elektrotechnische Normung
CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels

© 2020 CENELEC All rights of exploitation in any form and by any means reserved worldwide for CENELEC Members.

Project: 68105 Ref. No. prEN 50122-2 E
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oSIST prEN 50122-2:2021
prEN 50122-2:2020 (E)
1 Contents

2 1 Scope ..................................................................................................................................................... 5

3 2 Normative references ........................................................................................................................... 5

4 3 Terms and definitions .......................................................................................................................... 6

5 4 Identification of hazards and risks ..................................................................................................... 6

6 5 Criteria for stray current assessment and acceptance .................................................................... 7

7 5.1 General .................................................................................................................................................. 7

8 5.2 Criteria for the protection of the tracks ............................................................................................. 7

9 5.3 Criteria for systems with metal reinforced concrete or metallic structures .................................. 8

10 5.4 Specific investigations and measures ............................................................................................... 9

11 6 Design provisions ................................................................................................................................ 9

12 6.1 General .................................................................................................................................................. 9

13 6.2 Return circuit ........................................................................................................................................ 9

14 6.2.1 General ............................................................................................................................................... 9

15 6.2.2 Resistance of running rails ............................................................................................................ 10

16 6.2.3 Track system ................................................................................................................................... 10

17 6.2.4 Return conductors .......................................................................................................................... 10

18 6.2.5 Return cables ................................................................................................................................... 10

19 6.2.6 Electrical separation between the return circuit and system parts with earth-

20 electrode effect ................................................................................................................................ 11

21 6.2.7 Rail-to-rail and track-to-track cross bonds .................................................................................. 11

22 6.3 Non-traction related electrical equipment ....................................................................................... 11

23 6.4 Tracks of other traction systems ...................................................................................................... 11

24 6.5 Return busbar in the substation ....................................................................................................... 11

25 6.6 Level crossings .................................................................................................................................. 11

26 6.7 Common power supply for tram and trolleybus ............................................................................. 12

27 6.8 Changeover from the mainline to depot and workshop areas ...................................................... 12

28 7 Provisions for influenced metallic structures ................................................................................. 12

29 7.1 General ................................................................................................................................................ 12

30 7.2 Conductive civil structures ............................................................................................................... 12

31 7.2.1 Basic proceeding ............................................................................................................................ 12

32 7.2.2 Longitudinal interconnection ......................................................................................................... 12

33 7.2.3 Sectionalized reinforcement .......................................................................................................... 13

34 7.2.4 External conductive parts .............................................................................................................. 13

35 7.2.5 Cables, pipework and power supply from outside ...................................................................... 13

36 7.3 Adjacent pipes or cables ................................................................................................................... 13

37 7.4 Voltage limiting devices .................................................................................................................... 14

38 8 Protective provisions applied to metallic structures ..................................................................... 14

39 9 Depots and workshops ...................................................................................................................... 14

40 10 Tests and measurements .................................................................................................................. 14

41 10.1 Principles ............................................................................................................................................ 14

42 10.2 Supervision of the rail insulation...................................................................................................... 15

43 10.2.1 Continuous monitoring of the rail potential ................................................................................. 15

44 10.2.2 Repetitive monitoring ..................................................................................................................... 15

45 Annex A (informative) Measurement of track characteristics .................................................................. 16

46 Annex B (informative) Stray current assessment — Rail insulation assessment using rail

47 potential ............................................................................................................................................... 23

48 Annex C (informative) Estimation of stray current and impact on metallic structures ......................... 25

49 Annex D (informative) Laboratory testing of materials for the insulation of rails .................................. 28

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50 Annex E (informative) Fastening systems .................................................................................................. 29

51 Bibliography .................................................................................................................................................... 30

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53 European foreword

54 This document (prEN 50122-2:2020) has been prepared by CLC/SC 9XC “Electric supply and earthing sys-

55 tems for public transport equipment and ancillary apparatus (Fixed installations)”.

56 This document is currently submitted to the Enquiry.
57 The following dates are proposed:
• latest date by which the existence of this docu- (doa) dor + 6 months
ment has to be announced at national level
• latest date by which this document has to be (dop) dor + 12 months
implemented at national level by publication of
an identical national standard or by endorse-
ment
• latest date by which the national standards (dow) dor + 36 months
conflicting with this document have to be with- (to be confirmed or
drawn modified when voting)

58 This document will supersede EN 50122-2:2010 and all of its amendments and corrigenda (if any).

59 prEN 50122-2:2020 includes the following significant technical changes with respect to EN 50122-2:2010:

60 — harmonization with prEN 50122-1:2020;
61 — references from EN 50162 moved to ISO/FDIS 21857:2020;
62 — improvement of measurement specification in Annex A;
63 — new Annex D “Laboratory testing of materials for the insulation of rails”.
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64 1 Scope

65 This document specifies requirements for protective provisions against the effects of stray currents, which

66 result from the operation of DC traction systems.

67 As several decades' experience has not shown evident corrosion effects from AC traction systems and actual

68 investigations are not completed, this document only deals with stray currents flowing from a DC traction sys-

69 tem.

70 This document applies to all metallic fixed installations which form part of the traction system, and also to any

71 other metallic components located in any position in the earth, which can carry stray currents resulting from

72 the operation of the railway system.

73 This document applies to all new DC lines and to all major revisions to existing DC lines. The principles can

74 also be applied to existing electrified transportation systems where it is necessary to consider the effects of

75 stray currents.

76 This document does not specify working rules for maintenance but provides design requirements to allow

77 maintenance.
78 The range of application includes:
79 a) railways,
80 b) guided mass transport systems such as:
81 1) tramways,
82 2) elevated and underground railways,
83 3) mountain railways,
84 4) trolleybus systems, and
85 5) magnetically levitated systems, which use a contact line system,
86 c) material transportation systems.
87 This document does not apply to
88 d) mine traction systems in underground mines,

89 e) cranes, transportable platforms and similar transportation equipment on rails, temporary structures (e.g.

90 exhibition structures) in so far as these are not supplied directly from the contact line system and are not

91 endangered by the traction power supply system,
92 f) suspended cable cars,
93 g) funicular railways.
94 2 Normative references

95 The following documents are referred to in the text in such a way that some or all of their content constitutes

96 requirements of this document. For dated references, only the edition cited applies. For undated references,

97 the latest edition of the referenced document (including any amendments) applies.

98 EN 50122-1:2020, Railway applications - Fixed installations - Electrical safety, earthing and the return circuit -

99 Part 1: Protective provisions against electric shock

100 EN 50122-3, Railway applications - Fixed installations - Electrical safety, earthing and the return circuit - Part

101 3: Mutual Interaction of AC and DC traction systems
102 EN 50163, Railway applications - Supply voltages of traction systems
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103 ISO/FDIS 21857:2020, Petroleum, petrochemical and natural gas industries — Prevention of corrosion on

104 pipeline systems influenced by stray currents
105 3 Terms and definitions

106 For the purposes of this document, the terms and definitions given in prEN 50122-1:2020 apply.

107 ISO and IEC maintain terminological databases for use in standardization at the following addresses:

108 — ISO Online browsing platform: available at https://www.iso.org/obp
109 — IEC Electropedia: available at http://www.electropedia.org/
110 4 Identification of hazards and risks

111 DC traction systems can cause stray currents which could adversely affect both the railway concerned and/or

112 outside installations, when the return circuit is not sufficiently insulated versus earth.

113 NOTE When not sufficiently insulated versus earth, the feeding circuit could also generate stray currents but its

114 insulation is normally designed, installed and maintained to be strong enough to mitigate electrical safety risks.

115 The major effects of stray currents can be corrosion and subsequent damage of metallic structures, where

116 stray currents leave the metallic structures. There is also the risk of overheating, arcing and fire and subse-

117 quent danger to persons and equipment both inside and outside the DC electric traction power supply system.

118 The following systems, which can produce stray currents, shall be considered:

119 — DC railways using running rails carrying the traction return current including track sections of other traction

120 systems bonded to the tracks of DC railways;

121 — DC trolleybus systems which share the same power supply with a system using the running rails carrying

122 the traction return current;

123 — DC railways not using running rails carrying the traction return current, where DC currents can flow to

124 earth or earthing installations.

125 All components and systems which can be affected by stray currents shall be considered such as

126 — running rails,
127 — metallic pipe work,
128 — cables with metal armour and/or metal shield,
129 — metallic tanks and vessels,
130 — earthing installations,
131 — reinforced concrete structures,
132 — buried metallic structures,
133 — signalling and telecommunication installations,
134 — non-traction AC and DC power supply systems,
135 — cathodic protection installations.

136 Any provisions employed to control the effects of stray currents shall be checked, verified and validated ac-

137 cording to this document.
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138 The system design shall be completed sufficiently early that the results can be taken into account in the es-

139 sential system parameters, which influence the stray current effects, like the spacing of the traction substations

140 and in the design of the civil structures, see also 5.4 and 6.

141 The entity responsible for the design and erection of the railway infrastructure shall make sure that electrical

142 requirements for railway related civil structures are met.

143 In case of major revisions of existing lines, the effects on the stray current situation shall be assessed by

144 calculation and/or by measurements.

145 If stray current provisions affect electrical safety, protective provisions against electric shock according to

146 prEN 50122-1 shall take precedence over provisions against the effects of stray currents.

147 5 Criteria for stray current assessment and acceptance
148 5.1 General

149 The amount of stray currents and their effects depend on the overall system design of the traction power

150 supply. Stray currents leaving the return circuit can affect the return circuit itself and neighbouring installations,

151 see Clause 4.

152 Beside to the operating currents, the most important parameters for the magnitude of stray current are:

153 — the conductance per length of the tracks and the other parts of the return circuit,

154 — the distance between traction substations,
155 — the longitudinal resistance of the running rails,
156 — spacing of cross bonds.

157 If the railway system meets the requirements and measures of this document, the railway system is assumed

158 to be acceptable from the stray current point of view.

159 NOTE Third party structures in proximity of the railway system could require additional measures.

160 The most important influencing variable for stray currents leaving the tracks is the combination of the conduct-

161 ance per unit length between track and earth and the rail potential. The corrosion rate is the main aspect for

162 the assessment of risk.

163 Parameters influencing the rail potential are the traction currents, the longitudinal resistance of the running

164 rails, the resistance to earth and the length of the feeding sections. The precondition for this proceeding is that

165 there is no direct electrical connection either accidental or intended to earthing installations and earth.

166 5.2 Criteria for the protection of the tracks

167 Experience over more than three decades has proven that there is no damage in the tracks over this period,

168 if the average stray current per unit length does not exceed the following value:

169 I’ = 2,5 mA/m
max
170 (time averaged stray current leakage per length of a single track line).

171 For a double track line, the value for the maximum average stray current leakage is to be multiplied by two.

172 For more than two tracks the value increases accordingly. For the averaging process, only the total positive

173 parts of the stray current over 24 h or multiples are considered.

174 For stray current considerations the positive rail potential shift ΔU is relevant. This is the difference between

175 the rail potential U occurring during operation and no-operation.

176 NOTE 1 During no-operation a voltage U can be present, which is e.g. caused by the electrochemical series of

177 elements or by an already connected cathodic protection system.
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178 If the following values for the time averaged conductance per length G’ and average rail potential shift ΔU

RE RE

179 are not exceeded during the system life-time, further investigations according to 5.4 do not need to be per-

180 formed.
181 — G’ ≤ 0,5 S/km per track and ΔU ≤ + 5 V for open formation (1)
RE RE
182 — G’ ≤ 2,5 S/km per track and ΔU ≤ + 1 V for closed formation (2)
RE RE

183 For the averaging process, only the total positive parts of rail potential shift ΔU over 24 h or multiples are

184 to be considered. They are then divided by the total number of measurements over the recording time.

185 A guide value for the sampling rate is two per second.

186 If the requirements in Formulae (1) and (2) are not met, an alternative maximum value for G’ shall be cal-

187 culated and used for the design, applying Formula (3).
188 G' = (3)
189 where
I’ 2,5 mA/m per track or the value coming from the investigation in 5.4.

G’ is the conductance per length between rails and earth, in siemens per kilometre (S/km,

whereby 1 S/km = 1/Ωkm);
ΔU average rail potential shift, in volts (V);

190 For tracks in closed formation a time averaged conductance per length of G’ < 0,5 S/km is not practical and

191 recommended because of changing moisture. If this average conductance per length does not allow to fulfil

192 the criteria of I’ = 2,5 mA/m, the traction power supply system should be optimized.

193 For a double track line, the value for the maximum conductance per length is to be multiplied by two. For more

194 than two tracks the factor increases accordingly.

195 As it is not easy to measure the stray currents directly, the measurement of the rail potential is a convenient

196 method. According to Formula (3), the acceptable conductance per length can be calculated for a single track

197 line.

198 NOTE 2 Simulation of the traction power supply for scheduled train operation can provide values for the stray current

199 per length for design purposes. A method of calculating dead-end tracks is given in Clause C.1. This is a conservative

200 method, because the actual values are lower.

201 When the construction phase has been completed, it shall be proven that the permissible conductance per

202 length according to Formulae (1), (2) or (3) is fulfilled. Annex A indicates proven methods for the measurement.

203 During operation, compliance with the limits of conductance per length according to Formulae (1), (2) or (3)

204 shall be maintained.

205 5.3 Criteria for systems with metal reinforced concrete or metallic structures

206 In systems with metal reinforced concrete or metallic structures, like
207 — reinforced track bed,
208 — tunnels or
209 — viaducts,
210 the impact on the structures shall be considered.

211 The voltage shift of the structure versus earth is the criterion for assessment.

212 According to ISO/FDIS 21857:2020, there is no cause for concern if the average value of the positive potential

213 shift between the structure and earth does not exceed + 200 mV for steel in concrete structures. A margin may

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214 be added according to the expected possible traffic extension in the future. For buried metal constructions the

215 values depend on soil resistivity and the material. For both requirements refer to ISO/FDIS 21857:2020.

216 NOTE Experience has shown that in case the requirements given in this document are fulfilled, impacts on non-

217 railway installations caused by stray currents are acceptable.

218 In order to avoid inadmissible stray current effects on metal reinforced concrete or metallic structures, the

219 longitudinal voltage between any two points of these interconnected structures should be calculated. The max-

220 imum longitudinal voltage shall be smaller than the permissible positive potential shift. As an example for

221 calculation see Clause C.2. This is a conservative procedure which ensures that the actual values for the

222 structure potential with respect to earth will be lower.
223 5.4 Specific investigations and measures

224 If the requirements stated in 5.2 and 5.3 are not achieved, or if other methods of construction are planned, a

225 study shall be carried out at an early planning stage. The study becomes also necessary in case of major

226 revisions of existing lines, when the stray current situation is likely to become worse.

227 The possible impact of stray current corrosion shall be investigated, where the following aspects are included,

228 such as
229 — insulation from earth of the rails and connected metallic structures,
230 — humidity of the track bed,
231 — longitudinal resistance of the running rails,
232 — number of and distance between the substations,
233 — effects of inequalities in the no load voltages of substations,
234 — substation no-load voltage and source impedance,
235 — timetable and vehicles,
236 — neighbouring metallic structures.
237 Clause 6 and Clause 7 show suitable corrective provisions.
238 6 Design provisions
239 6.1 General

240 Any provisions employed to control the effects of stray currents shall be checked and confirmed according to

241 this document.

242 The system design shall be completed so that the results can be taken into account in the essential system

243 parameters which influence the stray current effects, like the spacing of the traction substations and the design

244 of the civil structures.
245 6.2 Return circuit
246 6.2.1 General

247 In order to minimize stray current caused by a DC electric traction power supply system, the traction return

248 current shall be confined to the intended return circuit as far as possible.

249 As the return circuit in case of DC electric traction power supply systems usually is not connected to earth,

250 safety requirements for the rail potential according to prEN 50122-1:2020, 6.2.2 and Clause 9, shall be fulfilled.

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251 6.2.2 Resistance of running rails

252 The longitudinal resistance of the running rails shall be low. Therefore, rail joints shall be welded or connected

253 by rail joint bonds of low resistance such that the longitudinal resistance of the rails is not increased by more

254 than 5 %. This does not include the insulated rail joints of signalling system.

255 In case of impedance bonds at insulated rail joints, the total resistance may be increased by more than 5 %.

256 The longitudinal resistance can be reduced by the use of rails with greater cross section or cross bonding of

257 the running rails where signalling considerations allow.
258 6.2.3 Track system

259 A high level of insulation from earth of the running rails and of the whole return circuit is required, when the

260 running rails are used as part of the return circuit.

261 The track formation shall be designed in a way that the insulation quality of the rails with respect to earth will

262 not be diminished substantially by water. In order to fulfil the values given in Formulae (1), (2) and (3) of 5.2

263 the water drainage of the substructure of the running rails is essential.

264 The values of conductance per length, specified in 5.2, apply to a track consisting of two running rails with tie

265 bars as well as the attached system parts under dry conditions.
266 NOTE 1 Dry conditions in this context mean at least 24 h without e.g.
267 — rain or
268 — washing water.

269 NOTE 2 After concreting, wait until the concrete has set, this lasts usually at least one month. The setting of concrete

270 is strongly dependent on the environmental conditions.

271 EXAMPLE 1 The following provisions can be made to achieve the required values of the conductance G’ for rails

272 laid in an open formation:
273 — clean ballast;
274 — wooden sleepers or reinforced-concrete sleepers with insulating fastening;
275 — distanc
...

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