SIST EN 13103-1:2018

SLOVENSKI STANDARD
oSIST prEN 13103-1:2015
01-september-2015
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Railway applications - Wheelsets and bogies - Part 1: Design guide for axles with
external journals
Bahnanwendungen - Radsätze und Drehgestelle - Teil 1: Konstruktionsleitfaden für
außengelagerte Radsatzwellen
Applications ferroviaires - Essieux montés et bogies - Partie 1: Méthode de conception
des essieux-axes avec fusées extérieures
Ta slovenski standard je istoveten z: prEN 13103-1
ICS:
45.040 Materiali in deli za železniško Materials and components
tehniko for railway engineering
oSIST prEN 13103-1:2015 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN 13103-1:2015

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oSIST prEN 13103-1:2015

EUROPEAN STANDARD
DRAFT
prEN 13103-1
NORME EUROPÉENNE

EUROPÄISCHE NORM

May 2015
ICS 45.040 Will supersede EN 13103:2009+A2:2012, EN
13104:2009+A2:2012
English Version
Railway applications - Wheelsets and bogies - Part 1: Design
guide for axles with external journals
Applications ferroviaires - Essieux montés et bogies - Partie Bahnanwendungen - Radsätze und Drehgestelle - Teil 1:
1: Méthode de conception des essieux-axes avec fusées Konstruktionsleitfaden für außengelagerte Radsatzwellen
extérieures
This draft European Standard is submitted to CEN members for enquiry. It has been drawn up by the Technical Committee CEN/TC 256.

If this draft becomes a European Standard, CEN 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 CEN in three official versions (English, French, German). A version in any other language
made by translation under the responsibility of a CEN member into its own language and notified to the CEN-CENELEC Management
Centre has the same status as the official versions.

CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia,
Finland, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania,
Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and 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 STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION

EUROPÄISCHES KOMITEE FÜR NORMUNG

CEN-CENELEC Management Centre: Avenue Marnix 17, B-1000 Brussels
© 2015 CEN All rights of exploitation in any form and by any means reserved Ref. No. prEN 13103-1:2015 E
worldwide for CEN national Members.

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Contents Page
Foreword .4
Introduction .5
1 Scope .6
2 Normative references .7
3 Terms and definitions .7
4 Symbols and abbreviations .8
5 General .9
6 Forces and moments to be taken into consideration . 10
6.1 Types of forces . 10
6.2 Effects due to masses in motion . 10
6.3 Effects due to braking . 15
6.4 Effects due to curving and wheel geometry . 19
6.5 Influence of traction. 19
6.6 Calculation of the resultant moment . 20
7 Determination of geometric characteristics of the various parts of the axle . 21
7.1 Stresses in the various sections of the axle . 21
7.2 Determination of the diameter of journals and axle bodies . 24
7.3 Determination of the diameter of the various seats from the diameter of the axle body or from
the journals . 24
7.3.1 Collar bearing surface . 24
7.3.2 Transition between collar bearing surface and wheel seat . 26
7.3.3 Wheel seat in the absence of an adjacent seat . 26
7.3.4 Case of two adjacent wheel seats . 27
7.3.5 Configuration of the wheel seats . 28
8 Maximum permissible stresses . 28
8.1 General . 28
8.2 Steel grade EA1N and EA1T . 28
8.3 Steel grades other than EA1N and EA1T . 30
Annex A (informative) Model of axle calculation sheet . 34
Annex B (informative) Procedure for the calculation of the load coefficient for tilting vehicles . 35
Annex C (informative) Values of forces to take into consideration for wheelsets for reduced gauge
track (metric or close to a metre) . 37
Annex D (normative) Method for determination of full-scale fatigue limits for new materials . 38
D.1 Scope . 38
D.2 General requirements for the test pieces . 38
D.3 General requirements for test apparatus . 38
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D.4 Axle body fatigue limit ("F1") . 38
D.4.1 Geometry . 38
D.4.2 Verification of the applied stress . 39
D.4.3 End of test criterion . 40
D.4.4 Determination of the fatigue limit . 40
D.5 Axle bore fatigue limit ("F2") . 40
D.5.1 Geometry . 40
D.5.2 Verification of the applied stress . 41
D.5.3 End of test criterion . 41
D.5.4 Determination of the fatigue limit . 41
D.6 Wheel seat fatigue limit ("F3 and F4") . 41
D.6.1 Geometry . 41
D.6.2 Verification of the applied stress . 43
D.6.3 End of test criterion . 43
D.6.4 Determination of the fatigue limit . 43
D.7 Content of the test report. 43
Annex ZA (informative) Relationship between this European Standard and the Essential
Requirements of EU Directive 2008/57/EC . 45
Bibliography . 47




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Foreword
This document (prEN 13103-1:2015) has been prepared by Technical Committee CEN/TC 256 “Railway
applications”, the secretariat of which is held by DIN.
This document is currently submitted for CEN comment.
This document is intended to replace EN 13103:2009+ A2:2012 and EN 13104:2009+A2:2012.
This document has been prepared under a mandate given to CEN/CENELEC/ETSI by the European Commission
and the European Free Trade Association, and supports essential requirements of EU Directive 2008/57/EC.
For relationship with EU Directive 2008/57/EC, see informative Annex ZA, which is an integral part of this document.
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Introduction
Railway axles were among the first train components to give rise to fatigue problems.
Many years ago, specific methods were developed in order to design these axles. They were based on a feedback
process from the service behaviour of axles combined with the examination of failures and on fatigue tests
conducted in the laboratory, so as to characterize and optimize the design and materials used for axles.
1
A European working group under the aegis of UIC started to harmonize these methods at the beginning of the
2
1970s. This led to an ORE document applicable to the design of trailer stock axles, subsequently incorporated into
national standards (French, German, Italian) and consequently converted into a UIC leaflet.
The method is based on the calculation of nominal stresses using beam theory. It was developed at a time when
the calculation method per finished item had yet to be established. Fatigue limit values were obtained from tests,
and the level of stress on the test pieces was calculated using beam theory. In addition, fatigue correlation
coefficients were determined in the same way, using the experimental results from test pieces of different
diameters and transition radii.
The following three elements:
— calculation method;
— correlation coefficient values;
— fatigue limit values;
are closely linked, with the values of the two latter parameters being dependent on the calculation method.
The bibliography lists the relevant documents used for reference purposes. The method described therein is largely
based on conventional loadings (now deduced from the definition of the masses declined in EN 15663). The
outcome is validated by many years of operations on the various railway systems.
This standard is based largely on this method which has been improved and its scope enlarged.
In order to simplify the maintenance of axle design standardization, it was decided to merge two previous
documents, EN 13103 and EN 13104, into a single standard, in the form of this document.
Furthermore, this standard makes reference to mass standard EN 15663 to define the loads used in the
calculations.

1
UIC : Union Internationale des Chemins de fer.
2
ORE: Office de Recherches et d'Essais de l'UIC.
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1 Scope
This European standard:
— defines the forces and moments to be taken into account with reference to masses and braking conditions;
— gives the stress calculation method for axles with outside axle journals;
— specifies the maximum permissible stresses to be assumed in calculations for steel grade EA1N defined in EN
13261;
— describes the method for determination of the maximum permissible stresses for other steel grades;
— determines the diameters for the various sections of the axle and recommends the preferred shapes and
transitions to ensure adequate service performance.
This European Standard applies to:
— axles defined in EN 13261;
3
— all gauges .
The design method for powered axles for described in this European Standard applies:
— to solid or hollow powered axles for railway vehicles;
— to solid or hollow non-powered axles for motor bogies;
— to solid or hollow non-powered axles for locomotives.
The design method for non-powered axles described in this European Standard applies:
— to solid or hollow axles for railway vehicles intended for the transportation of passengers or freight and that
does not appear in the previous list.
This European Standard is applicable to axles fitted to rolling stock intended to run under normal European
conditions. Before using this European Standard, if there is any doubt as to whether the railway operating
conditions are normal, it is necessary to determine whether an additional design factor has to be applied to the
maximum permissible stresses. The calculation of wheelsets for special applications (e.g. tamping/lining/levelling
machines) may be made according to this European Standard only for the load cases of free-running and running
in train formation. This European Standard does not apply to workload cases. They are calculated separately.
This method may be used for light rail and tramway applications.


3
If the gauge is not standard, certain formulae need to be adapted.
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2 Normative references
The following documents are referenced in a normative manner, in part or in full, in this document, and are
indispensable for its application. For dated references, only the edition cited applies. For undated references, the
latest edition of the referenced document (including any amendments) applies.
EN 13260, Railway applications — Wheelsets and bogies — Wheelsets — Product requirements
EN 13261, Railway applications — Wheelsets and bogies — Axles — Product requirements
EN 15313, Railway applications – In-service wheelset operation requirements – In-service and off-vehicle wheelset
maintenance
EN 15663, Railway applications- Definition of the vehicle reference masses
3 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
3.1
powered axle
The following axles shall be considered as powered axles:
— solid or hollow powered axles for railway vehicles;
— solid or hollow non-powered axles for motor bogies;
— solid or hollow non-powered axles for locomotives
3.2
non-powered axle
A solid or hollow axle used for railway vehicles intended for the transportation of passengers or freight and that is
not considered as a powered axle such as defined in paragraph 3.1
3.3
technical specification
A document describing the specific parameters and/or requirements of the product in addition to the requirements
of this standard.
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4 Symbols and abbreviations
For the purposes of this European Standard, the symbols and abbreviations in Table 1 apply:
Table 1 — Symbols and abbreviations
Symbol Unit Description
kg Mass on journals (including bearings and axle boxes)
m
1
m kg Wheelset mass and masses on the wheelset between wheel rolling circles (brake
2
disc, etc.)
kg For the wheelset considered, proportion of the mass of the vehicle on the rails
m  m
1 2
2
g
m/s Acceleration due to gravity
P N
(m  m )g
1 2
Half the vertical force per wheelset on the rail
2
P N m g
0 1
Vertical static force per journal when the wheelset is loaded symmetrically
2
N Vertical force on the more heavily-loaded journal
P
1
N Vertical force on the less heavily-loaded journal
P
2
'
N Proportion of P braked by any mechanical braking system
P
N Wheel/rail horizontal force perpendicular to the rail on the side of the more heavily-
Y
1
loaded journal
Y N Wheel/rail horizontal force perpendicular to the rail on the side of the less heavily-
2
loaded journal
H N
Force balancing the forces Y and Y
1 2
Q N Vertical reaction on the wheel situated on the side of the more heavily-loaded
1
journal
N Vertical reaction on the wheel situated on the side of the less heavily-loaded journal
Q
2
F N Forces exerted by the masses of the unsprung elements situated between the two
i
wheels (brake disc(s) etc.)
N Maximum force input of the brake shoes of the same shoeholder on one wheel or
F
f
interface force of the pads on one disc
Nmm Bending moment due to the masses in motion
M
x
' '
Nmm Bending moments due to braking
,
M M
x z
'
Nmm Torsional moment due to braking
M
y
MX , MZ Nmm Sum of bending moments
MY
Nmm Sum of torsional moments
MR
Nmm Resultant moment
2b
mm Distance between vertical force input points on axle journals
2s mm Distance between wheel rolling circles
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Table 1 (continued)
Symbol Unit Description
mm Height above the axle centreline of vehicle centre of gravity of masses carried by
h
1
the wheelset
mm
y Distance between the rolling circle of one wheel and force F
i i
y
mm
Abscissa for any section of the axle calculated from the section subject to force P
1
 Average friction coefficient between the wheel and the brake shoe or between the
brake pads and the disc
2

N/mm Stress calculated in one section
K Fatigue stress correction factor
R mm Nominal wheel radius (Nominal wheel diameter / 2)
mm Brake radius
R
b
d
mm Diameter for one section of the axle
'
mm Bore diameter of a hollow axle
d
D mm Diameter used for determining K
r mm Radius of transition fillet or groove used to determine K
S Security coefficient
G
Centre of gravity
2 7
N/mm Fatigue limit under rotating bending up to 10 cycles for smooth test pieces
R
fL
2 7
R N/mm Fatigue limit under rotating bending up to 10 cycles for notched test pieces
fE
2
m/s Unbalanced transverse acceleration
a
q
f Thrust factor
q
5 General
The major phases for the design of an axle are:
a) definition of the forces to be taken into account and calculation of the moments on the various sections of the
axle;
b) selection of the diameters of the axle body and journals and - on the basis of these diameters - calculation of
the diameters for the other parts of the axle;
c) the options taken are verified in the following manner:
 stress calculation for each section;
 comparison of these stresses with the maximum permissible stresses.
The maximum permissible stresses are mainly defined by:
 the steel grade;
 whether the axle is solid or hollow.
 the type of drive transmission.
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An example of a data sheet with all these phases is given in Annex A.
6 Forces and moments to be taken into consideration
6.1 Types of forces
Three types of forces are to be taken into consideration as a function:
— of the masses in motion;
— of the braking system.
— traction.
6.2 Effects due to masses in motion
The forces generated by masses in motion are concentrated along the vertical symmetry plane (y, z) (see Figure 1)
intersecting the axle centreline.

Figure 1 — Definition of centrelines
Unless otherwise defined in the technical specification, the masses (m  m ) to be taken into account for the main
1 2
types of rolling stock are defined in Table 2. For particular applications, e.g. suburban vehicles, other definitions for
masses are necessary, in accordance with the specific operating requirements.

Table 2 — Masses to take into account for the main types of rolling stock
Type of rolling stock units Mass (m  m )
1 2
Freight wagons In-service design mass + normal design payload
(maximum payload)
Powered coaches with no accommodation for
In-service design mass and the normal design payload
passengers, luggage or post
are defined in Standard EN 15663
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Coaches and powered coaches including
In-service design mass + 1.2  normal design payload
accommodation for passengers, luggage or post

1 – High-speed or main line vehicles In-service design mass and the normal design payload
are defined in Standard EN 15663
The normal design payload is defined in Standard EN
15663, where standing passengers shall be considered
as:
- 160 kg/m² (2 passengers per m²) in the areas
accessible to standing passengers and in the
restaurant compartments
2 – Passenger vehicles other than high speed or
In-service design mass and the normal design payload
main line
are defined in Standard EN 15663
The normal design payload is defined in Standard EN
15663, where standing passengers shall be considered
as:
- 210 kg/m² (3 passengers per m²) in the corridor
areas;
- 350 kg/m² (5 passengers per m²) on platforms;
the value of 280 kg/m² (4 passengers per m²)
st
may be used in specific cases (e.g. the 1
class compartment) as described in the
technical specification

P P
The bending moment M in any section is calculated from forces , , Q , Q , Y , Y and F as shown in
x 1 2 1 2 1 2 i
Figure 2. It represents the most adverse condition for the axle, i.e.:
 asymmetric distribution of forces;
 the direction of the forces F due to the masses of the unsprung components selected in such a manner that
i
their effect on bending is added to that due to the vertical forces;
 the value of the forces F results from multiplying the mass of each unsprung component by 1 g.
i

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Key
G centre of gravity of vehicle
Figure 2 — Forces to calculate the bending moment
Table 3 shows the values of the forces calculated from m .
1

The formulae coefficient values are applicable to standard gauge axles and classical suspension. For very  dif-
ferent gauges, metric gauge for example, or a new system of suspension, tilting system for example, other values
shall be considered (see Annexes B and C).
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Table 3 — Formulae to calculate forces
a
All axles except guiding axle
P  (0,625 0,075h / b)m g
1 1 1
P  (0,6250,075h / b)m g
2 1 1
Y  0,30m g
1 1
Y  0,15m g
2 1
H  Y Y  0,15m g
1 2 1
a

Guiding axle
P  (0,625 0,0875h / b)m g
1 1 1
P  (0,625 0,0875h /b)m g
2 1 1
Y  0,35m g
1 1
Y  0,175m g
2 1
H  Y Y  0,175m g
1 2 1
1
For all axles

Q  Pb s P b sY Y R F2s y 
1 1 2 1 2 i i i
2s
1

Q  P b s Pb sY Y R F y 
2 2 1 1 2 i i i
2s
a
The guiding axle is the axle of the first (i.e. leading) bogie of a coach used at the head of a reversible trainset. If an
axle can be used in both positions (guiding or non-guiding), it is to be considered as a guiding axle.
Table 4 shows the formulae to calculate M for each zone of the axle and the general outline of M variations
x x
along the axle.
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Table 4 — Forces to calculate the bending moment
a
Zone of the axle
M
x


M  P y
x 1

Between loading plane and
running surface

Figure 3a

M = P y – Q (y – b + s) + Y R –  F (y – b + s – y )

x 1 1 1 i i i


Between running surfaces


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F : force(s) on the left of the section considered
i
Figure 3b



General outline of
M
x
variations

Figure 3c
a
For a non-symmetric axle, the calculations shall be carried out after applying the load alternately to the two journals to
determine the worst case.

6.3 Effects due to braking
' ' '
Braking generates moments that can be represented by three components: M , M , M (see Figure 4).
x y z

Figure 4 — Moments due to braking
'
a) the bending component M is due to the vertical forces parallel to the z axis;
x
'
b) the bending component M is due to the horizontal forces parallel to the x axis;
z
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c) the torsional component M is directed along the axle centreline (y axis); it is due to the forces applied
y
tangentially to the wheels.
' ' '
The components M , M and M are shown in Table 5 for each method of braking.
x y z
If several methods of braking are superimposed, the values corresponding to each method shall be added.
NOTE If other methods of braking are used, the forces and moments to be taken into account can be obtained on the basis
'
of the same principles as those shown in Table 5. Special attention should be paid to the calculation of the M component,
x
which is to be added directly to the M component representing masses in motion.
x
Table 5-Formula for the calculation of moments due to braking
Components Method of braking used
M’ , M’ , M’
x z y Friction brake blocks on both sides of each wheel Friction brake block on one side only of each
wheel
Between loading plane Between running Between loading plane Between running
and running surface surfaces and running surface surfaces

M’ = 0,3F  y M’ = 0,3F  (b – s) M’ = F  y M’ = F  (b – s)
x f x f x f x f
a b a b b b

M’
x


Figure 5a Figure 5b

M’ = F (0,3 +  )y M’ = F (0,3 +  )(b – s) M’ = F (1 +  )y M’ = F (1 +  )(b – s)
z f z f z f z f
a a


M’
z

Figure 5c Figure 5d

M’ M’ = 0 M’ = 0,3P’R M’ = 0 M’ = 0,3P’R
y y y y y
c, d  c, d


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Table 5 (continued)
Components Method of braking used
f
M’ , M’ , M’
Two brake discs mounted on the axle Two brake discs attached to the wheel hub
x z y
Between Between Between discs Between loading plane Between running
loading plane running and running surface surfaces
and running surfaces and
surface disc
M’ = F  y M’ = F  (b – s + y ) M’ = F  y M’ = F  (b – s + y )
x f x f i x f x f i
b b b b

M’
x

Figure 5f
Figure 5e

R R R R
b b b b
M’ = F  y M’ = F  (b – s) M’ = F  y M’ = F  (b – s)
z f z f z f z f
R R R R
b b b b


M’
z


Figure 5h
Figure 5g

' '
M’ M’ = 0 M’ = 0,3 P’R M’ = 0 M’ = 0,3 P’R
y y M  0,3P R y y y
y
d e
d,
...