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                                                              A. De Iorio et alii, Frattura ed Integrità Strutturale, 30 (2014) 593-601; DOI: 10.3221/IGF-ESIS.30.70 
 

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Transverse strength of railway tracks: part 3.  
Multiple scenarios test field 
 
 
Antonio De Iorio 
Polytechnic School of Basic Sciences, Federico II University, Naples, Italy 
 
Marzio Grasso, Francesco Penta, Giovanni Pio Pucillo, Vincenzo Rosiello 
DII - Department of Industrial Engineering, Federico II University, Naples, Italy 
 
Stefano Lisi, Stefano Rossi, Mario Testa 
RFI - Italian State Railways, Rome, Italy 
 

 
ABSTRACT. In the present paper the design and construction choices of a test field for the ballast lateral 
resistance measurement, in order to produce data useful for the development of a numerical model able to 
simulate the service critical conditions of a continuous welded rail track, are described. Some construction 
details described herein allow to better understand the methodological approach followed in the design of 
experiments, the tests management philosophy as well as of the accuracy achieved in their implementation. 
  
KEYWORDS. Ballast resistance; Track stability; Full scale test; CWR track; Railway track; Railway scenarios 
simulation; Test field. 
 
 
 
INTRODUCTION  
 

he analytical and/or numerical determination of the resistance opposed by the ballast to the track displacement 
due to mechanical and/or thermal loading transmitted or induced by the Continuous Welded Rail (CWR) is a 
quite complex task. Also, it is necessary to have more reliable data of such resistance for the determination of the 

service critical conditions of railway lines. Thus, in order to achieve the aforementioned objectives, the use of full scale 
experimentation, in line or in laboratory, using track sections is unavoidable. Usually, the ballast overall resistance is 
intended or evaluated as the sum of the three components along the track main directions, both for practical reasons and 
their easily applicability to any scenario, as well as because sometimes one or more components are used for partial or 
specific characterizations of the track. In most cases the following constituents are reported in literature: - vertical 
resistance or bearing capacity; - longitudinal resistance; - lateral displacement resistance. The attention is mainly focused 
on this latter, due to the role played by the scenarios having the purpose to ensure the stability of the track in making the 
design choices. 
It is well known that the track is composed by: rail, rail fastening system, sleeper, ballast bed and substructures. Among 
the above elements, it has been proved that an important safety margin is offered by the ballast lateral resistance [1-3], 
which is the weakest element of the track, since it is the first to fail under the action of the loads acting on the rails. The 
lateral resistance is mainly due to the friction between the lower face of the sleeper and the ballast. However, significant 

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A. De Iorio et alii, Frattura ed Integrità Strutturale, 30 (2014) 593-601; DOI: 10.3221/IGF-ESIS.30.70                                                                
 

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contributions are also given by the ballast at the sleeper head and at lateral sleeper surfaces. Besides, the magnitude of 
such resistance depends on several factors, such as: sleeper weight; sleeper width; sleeper length; twin-block sleeper; 
friction on the lower sleeper surface; increase of ballast grain size; other ballast constituents; increase of lateral shoulder 
height; ballast shoulder broadening; ballast bed height below the sleeper; ballast height reduction between sleepers; 
narrower sleeper spacing; rails moment of inertia; track grid torsion-rigidity; track lifting; tamping; dynamic track 
stabilization; train speeds; increased axle loads; temperature, sleeper anchors and Under Sleeper Pad (USP). 
Therefore, owing to the excessive number of samples to be designed, prepared and tested, the experimental evaluation of 
the contribution related to each one of these parameters in scenarios which are different among them just for one 
parameter value becomes practically prohibitive.  
Several Institutions have conducted studies regarding the contribution to the resistance provided by the geometric 
parameters of the track and their evaluation [1, 4-6]. Unfortunately, the great part of these studies is incomplete: 
frequently, the experimental program wasn’t completed [1] or some variables have been estimated rather than measured. 
Also, the tests are rarely repeated; even when they are, the number of repetitions is low and often defined a priori. 
Sometimes, the results are partially withheld (See e.g. [4]). Moreover, the data are generally referred to uniform ballast, 
even if the presence of water pockets [1] or irregularities of any kind alter their behaviour. At the same time, on the basis 
of these data various models have been developed and numerous software have been implemented to supply with 
deterministic or probabilistic predictions of the CWR buckling (See e.g. : [2-4, 7-11]). Moreover, these data have also been 
used to establish a buckling probabilistic risk [7, 12-14] by means of Risk Based Approach, which considers, in addition to 
an event likelihood, the seriousness of its consequences [7]. As a consequence, the models proposed until now are not 
very robust, if not even negatively affected by the quality of the data used either as input or for their validation. 
These considerations induced RFI  to develop together with the DII  a research programme regarding the track stability 
having as main goal the development of a FE model of the track, which is able to identify the critical service conditions of 
the continuous welded rail of a pre-defined scenario, on the basis of experimental data to be produced by means of full-
scale tests carried out on track sections reproducing a remarkable number of real scenarios [15]. The loading systems and 
the facilities, which were used during the experimental activities, have been designed and manufactured ad hoc [16] in 
order to achieve a good reliability of the results. 
In the present paper, the preliminary activity of the aforementioned programme, developed during the design and 
construction of a multiple scenarios test field, is described. The multiple scenarios test field is intended as a test campaign 
on a track composed of predefined scenarios arranged according to a given sequence. This latter has to be compatible 
with the operative requirements to be used for their construction as well as with the requirements of the test system and 
the facilities to be used. 
 
 
SCENARIOS DEFINITION  
 

efore defining the layout of the test field, it was necessary to establish a construction criterion to be used to 
identify a standard scenario which allows to represent the corresponding real scenario also providing the widest 
number of useful and reliable data. 

First of all, it was decided to evaluate the ballast resistance referring to the single sleeper. Each test should be repeated at 
least three or four times under the same conditions, in order to reduce the uncertainty of the result obtained with a test 
carried out on a single sleeper. Moreover, in order to reduce the test duration, it was decided to run all together the three 
or four equivalent tests, as it is practically done using the Discrete Cut Panel Pull Test (DCPPT). However, the difference 
with the DCPPT is in using a number of independent actuators equal to the number of the sleepers by which the scenario 
under testing is composed [16]. Besides, different scenarios arranged in series, having in common the same short rails 
were built. This choice was due to economize materials and labour as well as reducing the construction and the operating 
machines time. To be sure that, during the tests, the displacement of the ballast in the scenario under testing doesn’t alter 
the compaction of the neighbouring scenario not yet tested, it was decided to insert between two adjacent scenarios one 
or two “neutral” or “buffer” sleepers, which are not involved in the test. 
The guidelines useful to define the types of test and their numerousness, needed to evaluate the selected parameters range, 
have been drawn from the analysis of the data needed to identify the critical service conditions of the track typologies 
described in the Technical Specification drawn on purpose by RFI [17] as well as those found in literature 
The selected parameters are: 
 Type of sleeper; 
 Ballast consolidation; 

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                                                              A. De Iorio et alii, Frattura ed Integrità Strutturale, 30 (2014) 593-601; DOI: 10.3221/IGF-ESIS.30.70 
 

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 Ballast shoulder length; 
 Ballast wall distance from the sleeper head; 
 Ballast shoulder shape;  
 Sleepers anchor type; 
 Cant effect; 
 Ballast height reduction between sleepers for a 2 m section (1 m each side in respect to the track longitudinal axis); 
 Ballast height under sleeper; 
 Applied load; 
 type of Ballast. 
Indeed, the combination of all these parameters would have lead to define an onerous number of scenarios if a minimum 
of 3÷4 different values were assigned to each parameter. For this reason, it was decided to construct a limited but 
significant number of scenarios by which it would be possible to develop, on the basis of the collected results, numerical 
and mathematical models suitable to effectively simulate all the possible scenarios with the parameters values ranging in 
the respective pre-established variability fields.  
Based on considerations related to either significance or representativeness of given service conditions of the railway 
network, as well as of scale economy, 28 scenarios, of which the main distinguishing parameters are reported in Tab. 1, 
has been chosen. The first four of them are of immediate interpretation: the compaction, where present, is equivalent to a 
80.000 t traffic; the cant is equal to 16 cm; the sleeper anchors are only installed in four scenarios (having 5 sleepers each) 
either on all the sleepers (each sleeper) or every second sleeper; the load, where present, is equal to 2 t/sleeper. All the 
scenarios have in common the ballast material and the ballast shoulder dimension. 
 

Scenario Sleeper 
Height under 
sleeper (cm) 

Ballast 
wall 

Compaction Cant 
Sleeper 
anchors 

Vertical 
load 

01 RFI 230 30 NO NO NO NO NO 

02 RFI 230 30 NO NO NO NO YES 

03 RFI 240 30 NO NO NO NO YES 

04 RFI 240 30 NO NO NO NO NO 

05 RFI 240 30 YES YES NO NO YES 

06 RFI 240 30 YES YES NO NO NO 

07 RFI 240 30 NO YES NO NO NO 

08 RFI 240 30 NO YES NO NO YES 

09 RFI 230 30 NO YES NO NO NO 

10 RFI 230 30 NO YES NO NO YES 

11 RFI 230 60 YES YES NO NO NO 

12 RFI 230 60 YES YES NO NO YES 

13 RFI 230 60 NO YES NO NO NO 

14 RFI 230 60 NO YES NO NO YES 

15 RFI 240 60 NO YES NO NO NO 

16 RFI 240 60 NO YES NO NO YES 

17 RFI 240 60 NO NO NO NO NO 

18 RFI 240 60 NO NO NO NO YES 

19 RFI 230 60 NO NO NO NO NO 

20 RFI 230 60 NO NO NO NO YES 

21 RFI 230 60 NO NO YES NO YES 

22 RFI 230 60 NO NO YES NO NO 

23 RFI 230 60 NO YES YES NO NO 

24 RFI 230 60 NO YES YES NO YES 

25 RFI 230 30 NO YES NO each sleeper YES 

26 RFI 230 30 NO YES NO each sleeper NO 

27 RFI 230 30 NO YES NO every two 
l

NO 

28 RFI 230 30 NO YES NO every two 
l

YES 
 

Table 1: Combination of parameters characterizing the scenarios chosen for the experiment. 



 

A. De Iorio et alii, Frattura ed Integrità Strutturale, 30 (2014) 593-601; DOI: 10.3221/IGF-ESIS.30.70                                                                
 

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In the construction of the test field the sequence shown in Fig. 1, which has been considered the less expensive among 
the possible ones, has been used. 
 
 

Transition zone. 
L=15m

Transitio
n zone. 
L=15m

UL L UL L UL L UL L UL L UL L UL L UL L UL L UL L UL L UL L UL L UL L

R
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UL: Unloaded track panel. L: Loaded track panel (2 t/sleeper).

60 cm ballast thickness

DTS consolidated ballast bed

60 cm 
ballast 
should

er

De-consolidated ballast bed

Canted track with minimum 
ballast thikness of 60 cm 

Ballast 
retaining 

wall 60 cm 
apart from 
the sleeper 

end

Transition ramp 
(L=15m) for 
canted track

60 cm ballast 
shouldern

. 
1
0
 b

u
ff

e
r 

s
le

e
p
e
rs

DTS 
consolidated 
ballast bed

Ballast 
retaining 

wall 60 cm 
apart from 

the 
sleeper 

end

Transition 
ramp. 
L=15m

 60 cm ballast 
shoulder. 

Sleeper anchors 
installed on all 
the sleepers 

60 cm ballast shoulder

Track panel with n. 5 ties

60 cm ballast 
shoulder

 60 cm ballast 
shoulder. 

Sleeper anchors 
installed every 
second sleeper

De-consolidated 
ballast bed

DTS consolidated ballast bed

Test 
field 

in/out

30 cm ballast thickness

Test 
field 

in/out

n
. 

2
 b

u
ff

e
r 

sl
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e
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rs

60 cm ballast shoulder

 
 

Figure 1: Layout of the test field. 
 
 

TEST FIELD CONSTRUCTION 
 

or the construction of the test field , it has been used an area of the Campi Flegrei Railway Station (Fig. 2) in 
Naples (Italy), removing a section of roughly 200 m of two old adjacent tracks and rebuilding a new one having the 
characteristics defined in the design of the 28 scenarios under testing. 

 

 
 

Figure 2: Top view of the selected site. 
 
Once the permanent way has been removed for roughly 200 m, it has been carried out an excavation to eliminate the 
ballast and the old tracks residuals up to a depth compatible with the level of the new track test which has to be roughly 
10 cm above the level of the adjacent track to be used to create the fixed point for the test system. The excavation width is 
such that there is no interference between the new track profile and the excavation shoulders, neither during the 
construction phase nor in the following experimental activities. 
The subgrade composed by pozzolana has been levelled by the bulldozed and compacted by the roller, checking 
continuously the depth of the entire excavation for the total length (Fig. 3). 
For laying the sleepers, longitudinal references along the test field in the area between the two rails of the new track have 
been used. On the basis of the aforementioned references, the rails have been marked in correspondence of the points 
where to place the buffer sleepers. Once the buffer sleepers were positioned in the said space and in the pre-established 
order, all the other sleepers have been positioned (Fig. 4) according to the layout. 
Once the sleepers were laid and spaced at 60 cm, the two rails have been laid on them, tightening the fastening systems 
(Fig. 5). Tightening has been performed by a hydraulic rail coupling shears, applying a torque equal to 240 mN. 
The sleepers forming the scenarios were equipped with Vossloh W 14 fastening system, while, for the intermediate 
sleepers FS–V–35, the K fastening system have been used. 

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                                                              A. De Iorio et alii, Frattura ed Integrità Strutturale, 30 (2014) 593-601; DOI: 10.3221/IGF-ESIS.30.70 
 

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After the sleepers positioning and the fastening system tightening, the ballast has been laid (Fig. 6, left) and subsequently 
settled using the tamping machine, which lifts the track for packing the ballast under the sleepers. Also, during the lifting, 
the driver controls the position of the rails using the “telescope”, assigning the lateral movement to the rails, which is 
needed in order to ensure the required alignment, by means of a hydraulic system. The final height has been reached by 
lifting the track step by step. 
 

 
 

Figure 3: Excavation for the construction of the test track on the chosen site. 
 

        
 

Figure 4: Positioning of buffer sleepers (left) and other sleepers according to the layout (right). 
 

 
 

Figure 5: Rails fastened on the sleepers. 



 

A. De Iorio et alii, Frattura ed Integrità Strutturale, 30 (2014) 593-601; DOI: 10.3221/IGF-ESIS.30.70                                                                
 

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Figure 6: Deposition of the ballast (left) and removing of the excess (right). 
 
During the ballast deposition and the related increasing of the height of the track, the universal ballast distributing and 
profiling machine with shoulder ploughs has been also used (Fig. 6, right) in order to remove the ballast in excess and 
obtain the desired shoulder shape. 
 

 
 

Figure 7: Construction of scenarios with cant. 
 
The last two scenarios have been constructed with a cant equal to 16 cm in respect to the rail level of all previous 
scenarios (Fig. 7). Later sleeper anchors have been installed on the sleepers (Fig. 8).  
 

     
 

Figure 8: Shovels installed on the sleepers. 
 
At the end of the operations above described, the final settlement and the rails cutting, needed to make independent one 
from the other the different test scenarios, were carried out. Also, the purpose-made planned ballast wall, having 
dimensions not available off-the-shelf, (Fig. 9) were constructed in situ. 



 

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Once the elements characterizing the various scenarios have been prepared and before the ballast settlement of the 
sections for which it has been foreseen, the rails have been cut in correspondence of the end sleepers or the transition 
sections among groups of consecutive scenarios different in height and/or in ballast compaction. The sectioning was 
needed in order to reduce the rails free expansion length and to prevent that the temperature variations would alter the 
desired configuration of the test track. In particular, the cuts have been performed by disk saw and have left a clearance of 
roughly 1.0 cm (Fig. 10). 
 

 

     
 

Figure 9: Ballast wall constructed in situ. 
 
 

 
 

Figure 10: Cut performed by disk saw. 
 

These discontinuities don’t limit the movement of the rolling stock on the track, because the underlying sleepers are 
equipped with K fastening systems, which allow restoring the rail continuity by the u-bolt plates tightening (Fig. 10). 
Before rails cutting, needed to create stand-alone scenarios, the edge and the shoulder has been checked and completed as 
well as the distances among the sleepers have been verified. The cuts have been performed according to the locations 
specified in Fig. 11 and the rails have been subsequently drilled (Fig. 12) in correspondence of the loading points of the 
test system.  
A tolerance equal to ± 3 cm has been defined for the distance between the centre-to-centre sleepers in respect to the 60 
cm nominal value, whilst for the total length of each scenarios, which are composed of 4 or 5 sleepers, the tolerance value 
has been chosen equal to ± 4 cm. The dimensions that during the check are found out-of-tolerance have been put into the 
preset limits modifying the position of the sleepers involved.  
The characteristics of the materials and components used to build in a single track all the scenarios to be tested are 
reported in the Tab. 2. 

 

 
 

Figure 11: Location of the rails cuts (c: cutting lines). 



 

A. De Iorio et alii, Frattura ed Integrità Strutturale, 30 (2014) 593-601; DOI: 10.3221/IGF-ESIS.30.70                                                                
 

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Figure 12: Drilling of the rails.  
 

Name Type Reference Standards 

Ballast siliceous 
RFI DTC INC SP IFS 010 

A

Rail 60E1 EN 13674-1 

Fastening 
System 

elastic type
EN 13481-2, EN 13146-

1÷7 
Concrete 
Sleeper 

RFI 230
RFI 240

EN 13230-2:2002 
 

Table 2: Track components. 
 
At the end of all the operations above described, the test field, constructed on the basis of a parametric approach, has 
been tested as scheduled. A wide range of homogeneous and reliable results have been produced. These results represent 
the basis for developing a numerical model useful for the evaluation of the safe service conditions of the continuous 
welded rail track. 
 
 
CONCLUSIONS 
 

uring a wide research programme focusing on the development of a computational model for the study of the 
stability of the continuous welded rail track, a preliminary and substantial experimental activity has been carried 
out on full scale sections of modular scenarios implementing numerous and different track construction and 

service conditions. This activity has required a preliminary design of the test field as well as suitable test system with 
related facilities, in order to produce sufficient and reliable data for the implementation of a numerical model. In this 
paper, for the sake of the length, only the main stages of the design and construction of the test field have been described. 
Moreover, some details have been synthetically discussed in order to provide the reading key of the adopted 
methodological approach and the accuracy achieved during its implementation. N. 28 scenarios composed of n. 14 
different typologies were constructed in a short track of just 180 m, preparing them for the use of a test system designed 
on purpose [16]. The experimental results reported elsewhere [18] confirm, due to their variety, homogeneity, 
numerousness and reliability, the validity of the design choices adopted both in defining the test field and in designing the 
test system. 

D 



 

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[17] Technical Specification, RFI, Rome, (2008). 
[18] De Iorio, A., Grasso, M., Penta, F., Pucillo, G. P., Rosiello, V., Lisi, S., Rossi, S., Testa, M., About Track Resistance 

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