Acta Polytechnica


doi:10.14311/AP.2016.56.0455
Acta Polytechnica 56(6):455–461, 2016 © Czech Technical University in Prague, 2016

available online at http://ojs.cvut.cz/ojs/index.php/ap

FINITE ELEMENT MODELLING AND SIMULATION OF VEHICLE
IMPACT ON STEEL SAFETY BARRIERS

Riassa Likhonina∗, Michal Micka

Czech Technical University in Prague, Faculty of Transportation Sciences, Prague, Czech Republic
∗ corresponding author: likhorai@fd.cvut.cz

Abstract. This paper deals with a FEA simulation of the vehicle crash with steel safety barriers in the
ANSYS LS-DYNAr 15.0. Two types of safety barriers are used: the JSNH4/H2 and the JSAM-2/H2.
A geometrical model of the barrier in the Modeler ANSYSr WorkbenchTM 15.0 was created and then it
was transformed into the LS-DYNAr 15.0 to complete the crash test simulation. After a computation
in the solver ANSYS LS-DYNAr 15.0, the results of the simulation such as impact forces, a body
displacement and an integral energy were analyzed.

Keywords: finite element method; crash simulation; ANSYSr WorkbenchTM; LS-DYNAr.

1. Introduction
Currently, all safety barriers for permanent and re-
peated use on the roads have to be tested in real crash
tests. The methods and all corresponding specifica-
tions of preparations and the performance of crash
tests and evaluation of the obtained results are speci-
fied in ČSN EN standards [9]. A numerical simulation
by finite element methods (FEM) is commonly and
widely used in automotive industry [10]. It can distin-
clty help, for example, to define deformation areas of
cars and their safety elements, which would eliminate
fatal injuries when accidents take place. According
to relevant standards, each type of a safety barrier is
required to be tested by several types of crash tests.
Moreover, it should be considered that during real
crash tests it is not possible to take all parameters
and situations that could appear into account. It is
well known that some deviations will always appear.
Therefore, a FEA simulation with an application of
highly sophisticated programs that use a FEM anal-
ysis can present a very powerful tool and be a great
support for performing real crash tests, thus contribut-
ing to a correct and accurate design and construction
of safety barriers.
Due to the advantages the FEA simulation can

bring, the interest in this method is increasing. A
large number of publications, which are really diverse
as far as the subjects of investigation and main ob-
jectives are concerned, exists in this field. Some of
the papers are devoted to the testing of new types of
safety barriers, which are made of a new material and
which are not used on real roads yet [15, 21]. Other
works describe simulation of impacts on bridge barri-
ers or even on rockfall barriers [20]. One of the earliest
publications in this area was a work by Gruber K.,
Herrmann M. and Pitzer M., where, already in 1991,
the authors described a computer simulation of a side
impact. For these purposes they used different types
of mobile barriers. Borovinšek M. in his work uses
simulation for designing optimal reinforcement of a

crash barrier commonly used in Slovenia [6]. Another
example of an application of the FEA simulation is
a publication by Ulker M. B. C. and Rahman M. S.,
“Traffic Barriers under Vehicular Impact from Com-
puter Simulation to Design Guidelines”, where the
problem of a vehicular impact on a portable concrete
barrier is investigated [19]. Borkowski W., Hryciów
Z., Rybak P., Wysocki J. and Wisniewski A. use the
FEA simulation to evaluate the effectiveness of the in-
novative road safety system prototype that has a body
made of plastic filled with reinforced concrete. [5]. In
another interesting work, which was written by Ing.
J. Drozda and doc. Ing. T. Rotter, the numerical
analysis of designing and testing of bridge barriers
is discussed [11]. In his other work, “Methodology
of Validation of FE Model for Simulations of Real
Crash Tests”, Drozda J. tries to determine a method
that leads to a creation of a validated finite element
model before performing the full scale crash test [10].
Similar investigations using FEA simulation are made
all around the world: in Italy [4], in Korea [15], in
China [14], in the USA [7, 8], in Romania [12] and so
on. And the authors of such publications have come
to a similar conclusion that FEA simulation is a very
helpful tool for design and construction as well as for
testing of crash barriers.

In the presented work, the FEM program ANSYSr
WorkbenchTM 15.0, LS-DYNAr 15.0 and LS-Pre-
Postr 4.1 are used for the FEA simulation of the
static and the dynamic tests of barriers .

2. Steel safety barriers
The subject of the presented work is road restraint
systems, or to be more precise — steel safety barriers.
From a large number of different steel safety barriers,
two types have been used for the analysis (both made
by the same manufacturer): JSNH4/H2 and JSAM-
2/H2. The latter is a new type, which claims to have
several benefits comparing with JSNH4/H2. The goal
of the simulation was to create a model of a safety bar-

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Riassa Likhonina, Michal Micka Acta Polytechnica

rier JSAM-2/H2 in ANSYSr WorkbenchTM 15.0 and
to set parameters of both models in LS-PrePostr 4.1:
defining deformation curves and impact conditions
(velocity, vehicle density, etc.), setting the material
characteristics for separate parts of the crash barriers,
modifying contacts between the corresponding parts,
etc. This article shows the correlation of FEA results
with the literature test data results [16].

In the Czech Republic, the crash barriers can only
be used on the roads if they comply with the require-
ments specified in TP 114 [18]. Compliance with
these requirements is verified by crash tests according
to ČSN EN 1317-2 [9]. On the basis of these crash
tests, the final containment level is determined. For
a majority of the containment levels, there should be
two or more types of crash tests. This is valid for
“approved” crash barriers. For “other” crash barriers,
calculation is used. However, it is not common for
several reasons. The most important of these reasons
is the fact that calculations are not able to provide a
sufficient basis for an assessment of the complex suit-
ability of a certain crash barrier as a road restraint
system and, thus, to forecast "impact acceptability",
because "impact acceptability" is a combination of
many factors. Another reason why calculations are
not often used, is the lack of methodological guidelines,
recommendations and documents dealing with this
issue. However, for bridge crash barriers, the calcula-
tions are allowed; moreover they are, in accordance
with corresponding standards, recommended [17]. On
the other hand, the implementation and evaluation of
crash tests, although it is strictly prescribed for some
cases and situations, is expensive and demanding on
the equipment of the laboratory. Moreover, the appli-
cation of the results of the crash tests in prediction of
how the barrier will behave in practice, i.e. on roads
and during certain impacts, is contentious. Therefore,
emphasizing advantages and disadvantages of both
methods it could be shown that a FEA simulation
can be a promising method for forcasting behavior of
a crash barrier when collision happens [17]. The im-
plementation and evaluation of crash tests, although
it is strictly prescribed for some cases and situations,
is expensive and demanding on the equipment of the
laboratory. Moreover, the application of the results
of the crash tests in prediction of how the barrier will
behave in practice, i.e., on roads and during certain
impacts, is contentious [17].

The calculations could be used as “means for mak-
ing the preparation of a crash test” [17]. In comparison
with the “trial and error”, it will bring substantial
savings. For example, with the help of calculations it
is often possible to predict the influence of the change
in the construction of the crash barriers (e.g., con-
struction changes of connecting parts, changes of the
element length, etc.) on their strength and stiffness,
and then to select the appropriate parameters of crash
tests. Moreover, the calculation results can be used to
design and test new and completely innovative types of

crash barriers. And this is where FEA simulation can
play a significant role as it saves time and decreases
expenses [17].
In the presented work, there is an attempt to sim-

ulate a vehicle impact on two crash barriers and to
prove that FEA simulation , in this area, has great
prospects.

3. Finite element modelling and
simulation

This chapter describes the construction, parameters
and installation of the selected types of safety barriers,
i.e., JSNH4/H2 and JSAM-2/H2. The 3D models of
the safety barriers JSNH4/H2 and JSAM-2/H2 have
been created in the ANSYSr WorkbenchTM 15.0. The
numerical model was created for one field of the bar-
rier due to size limitations of the task. A model of
a safety barrier itself consists of a post, two parts of
a spacer, barrier strips and lower beams. All parts
of each of the geometrical models have exactly the
same sizes as specified in the technical documents by
the manufacturer. These elements are actually inter-
connected by bolts, nuts and washers specified in the
technical documents by the manufacturer. However,
in the numerical model, these connecting elements
have been replaced with bonded face contacts. For
the FEA simulation purpose, models of the ground
and a vehicle are created. They will impact the safety
barrier according to given consideration. In both cases,
the ground is represented by rectangular blocks with
cylinder concrete block as a ground of the column of
the barrier. As for the vehicle, it is represented by a
semi-cylinder [16]. It is located in such a way that its
upper edge is on the level of the upper edge of the
post and its height is sufficient enough to impact both
the barrier strip and the lower beam. In this stage,
the vehicle does not touch the crash barrier and is
app. 20 mm far from it. The problem is solved as a
symmetrical one, therefore, the symmetry is supposed
in the place of the loading of the model. This fact
explains why a semi-cylinder is used instead of a whole
cylinder for the model of a vehicle. The impact area
in case of symmetry is app. 0.25 × 0.25 m, which is in
compliance with the standards , as mentioned in previ-
ous chapters. The last thing defined in the ANSYSr
WorkbenchTM 15.0 were the boundary conditions. For
both models, the displacement of the barrier strips
and lower beams using symmetry conditions is defined.
The displacement of the vehicle was specified so that
only a movement, which has a perpendicular direction
to the barrier strip, was allowed. A movement of the
ground is not allowed in any other direction.
As it can be seen from Table 1, both types of the

crash barriers have the same containment level, that
is in terms with the crash test types performed for
their validation and certification [1]. However, they
differ in used materials as JSAM-2/H2 is made of
the new micro-alloyed steel, which, according to the
manufacturer, allows a reduction of the overall weight,

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vol. 56 no. 6/2016 Finite Element Modelling and Simulation of Vehicle Impact

JSNH4/H2 JSAM-2/H2
Manufacturer ArcelorMittal Distribution Solutions

Czech Republic, s.r.o.
ArcelorMittal Distribution Solutions

Czech Republic, s.r.o.
Type Single-sided safety barrier Single-sided safety barrier
Containment level H2 H2
Dynamic deflection 1.75 m 1.5 m
Working width 1.85 m 1.6 m
Acceleration severity index 1.186 1.1
Material S235JR, S355MC S235JR, S355MC, S420MC
Type of a barrier strip NH4: thickness 4 mm, length

4250 mm
AM: thickness 2.8 mm, length

4250 mm
Lower beam SP3: thickness 3 mm, height

214 mm, width 28 mm, length
4250 mm

AM: thickness 2.8 mm, height
214 mm, width 28 mm, length

4250 mm
Post V140: thickness of a wall 5 mm,

width 140 mm, length 2170 mm
C 150 × 75 × 25: thickness of a wall

3.5 mm, width 150 mm, length
1755 mm

Weight 42.67 kg/m 29 kg/m

Table 1. Comparison of JSNH4/H2 and JSAM-2/H2 [16].

while preserving the same or even better functional-
ity. As Table 1 shows, the application of the new
steel type enables production of these parts of the
safety barrier JSAM-2/H2 with a smaller thickness.
Besides, the post has been changed both in terms of
cross section and its dimensions. All of this affects
important parameters like the dynamic deflection, the
working width and the acceleration severity index.
This fundamentally improves the characteristics of
the safety barrier. But the main achievement is the
weight reduction that is approximately 32 % — from
42.67 kg/m to 29 kg/m.

This fact is not only beneficial in terms of costs, but
also in terms of influence on the environment. Also,
the maintenance and installation is much easier. In
simulation, the following materials were used: S235JR
for JSNH4/H2 and S355J0 for JSAM-2/H2. Their
load curves used in the ANSYSr 15.0 are shown in Fig-
ure 1. The vehicle is modeled by a cylinder, whose ma-
terial is isotropic elastic (see Table 2). For the ground,
the material of the type GEOLOGIC_CAP_MODEL
was used. The parameters listed in Table 3 were spec-
ified for this material. For concrete, the standard
model CSCM_CONCRETE with default parameters
was used.

Notice that the value of the mass density of the
“vehicle” differs according to what type of a crash test
has to be simulated. The mass density is calculated
from the weight of the car and the dimensions of the
car model according to the following formula:

% =
m

V
and V =

πr2h

2
,

Figure 1. Comparison of the working curve of S235JR
and S355J0 steel used in simulation [16].

Mass density [kg/m3]
— passenger car 2.621 · 104
— lorry 2.912 · 105
— bus 3.785 · 105

Young’s Modulus [Pa] 2.000 · 1011

Poisson’s ratio [–] 0.3

Table 2. Parameters for specification of vehicle ma-
terial type [16].

where % is a mass density [kg/m3], m is a car mass
[kg], V is a volume [m3], r = 0.150 m is a radius of a
cylinder and h = 0.7 m is a height of a cylinder. The
same meshing properties are specified for both models.
The element size is 0.20 m, the minimum edge length
is 3 · 10−3 m; the smoothing, the relevance center and
the span angle center are set to be medium.

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Riassa Likhonina, Michal Micka Acta Polytechnica

Name Description Value
RO [kg/m3] Mass density 2100
BULK [Pa] Initial bulk modulus 4.102 · 107
G [Pa] Initial shear modulus 3.076 · 107

ALPHA Failure envelope parameter 2
THETA Failure envelope linear coefficient 0.292
GAMMA Failure envelope exponential coefficient 0
BETA Failure envelope exponent 0
R Cap, surface axis ratio 3
D [Pa] Hardening law exponent 7.524 · 107
W [Pa] Hardening law coefficient 0.031394
X0 [Pa] Hardening law exponent 0
C Kinematic hardening coefficient 1
N Kinematic hardening parameter 1
FTYPE Formulation flag 1 — default — means soil
VEC Vectorization flag 0 — default — means vectorized

Table 3. Parameters for ground specification [16].

4. Results and discussion
The numerical model was transformed from the
ANSYSr WorkbenchTM 15.0 to the ANSYS LS-
DYNAr 15.0 and solved. The results were evaluated
in the program LS-PrePostr 4.1.
The next figures show the most important results

from the FEA simulation of the crash test TB11 per-
formed for the JSAM-2/H2. From a graph of the
vehicle kinetic energy (see Figure 2), it can be seen
that its value is gradually decreasing within the impact
and in the end it reaches 1.7735 kNm. Its maximum
value, at the beginning of the impact, is 18.288 kNm,
which means 36.576 kNm for a symmetrical task.

The vehicle velocity decreases as well and reaches al-
most zero (see Figure 3). Its initial value of 9.5006 m/s
is set before simulation and corresponds to the crash
speed value specified in standards [9].

The following figures illustrate safety barrier defor-
mation at a time step of 0.125 s (see Figure 4).
The most interesting and informative is the graph

showing the internal energy of the construction (see
Figure 5).
It can be seen that the maximum value is

57.611 kNm, i.e., 115.222 kNm for a symmetrical task.
When we look at the internal energy at a time step of
0.125 s, as we did for the JSNH4/H2, its value is equal
to 44 kNm, i.e., 88 kNm for a symmetrical task. These
values more than fully comply with the value speci-
fied in the TP 114 (40.600 kNm) and with the value
of the kinetic energy obtained during the simulation
(36.576 kNm). Therefore, it can be stated that the
FEA simulation of the crash test TB11 for the JSAM-
2/H2 was successfully performed according to both
the criteria of consumed energy and the maximum
displacement value at a certain time step.
The next graph of interest is the one that illus-

Crash test Impact force [kN]
JSNH4/H2 JSAM-2/H2

TB11 74.250–105.183 38.250–82.840
TB42 130–183.440 45–157.560
TB51 104–218.978 78–211.380

Table 4. Comparison of JSNH4/H2 and JSAM-2/H2
— impact forces [16].

trates the acceleration of the vehicle (see Figure 6).
It can be seen that the maximum value of the acceler-
ation reaches 92.044 m/s2. At a time step of 0.125 s,
it is equal to 42.500 m/s2. Therefore, the impact
forces corresponding to these values of acceleration
are 82.8396 kN and 38.250 kN, respectively. Mind the
fact that the TP 101 specifies the following alternative
load forces corresponding to the crash test TB11: 15–
35 kN for a crash barrier with a dynamic deflection of
1.500–2.500 m and 35–80 kN for a crash barrier with
a dynamic deflection of 0.100–0.500 m [17]. It can
be seen that the impact forces obtained during the
FEA simulation are sufficient, or even higher, than the
alternative load forces described in the TP 101 [17].

4.1. Comparision of FEA results for
JSNH4/H2 and JSAM-2/H2

Comparing the two types of the crash barriers it can
be noticed that the impact forces, which the safety
barrier can resist, are higher for JSNH4/H2 for all of
the crash tests (see Table 4).
It is explained by the fact that JSNH4/H2 has a

higher stiffness due to the construction dimensions.
There is also a difference in the values of the internal
energy of the two types, which is presented in the

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Figure 2. Kinetic energy of a vehicle — JSAM-2/H2, TB11 [16].

Figure 3. Vehicle velocity — JSAM-2/H2, TB11 [16].

Figure 4. Safety barrier deformation at time step 0.125 s — JSAM-2/H2, TB11 [16].

Figure 5. Internal energy — JSAM-2/H2, TB11 [16].

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Riassa Likhonina, Michal Micka Acta Polytechnica

Figure 6. Vehicle acceleration — JSAM-2/H2, TB11 [16].

Crash test Internal energy [kNm]
JSNH4/H2 JSAM-2/H2

TB11 43 88
TB42 135 120
TB51 max. 233.760 max. 245.050

Table 5. Comparison of JSNH4/H2 and JSAM-2/H2
— internal energy [16].

following table (see Table 5).
The value of the internal energy in TB11 for JSAM-

2/H2 is approximately twice higher than that for the
JSNH4/H2. From this, it can be concluded that the
JSAM-2/H2 better absorbs kinetic energy of a vehicle
during an impact, and therefore it is safer for passen-
gers. This fact is also proved by the ASI index speci-
fied in the technical documentation, which is lower for
the JSAM-2/H2: 1.1 as compared with 1.186 [2, 3].
Similarly, the value of the internal energy obtained
during the TB51 is higher for the JSAM-2/H2 in com-
parison with the JSNH4/H2. However, it is a little
bit lower during the TB42.

4.2. Correlation of results
Table 6 represents the values of the kinetic energy ob-
tained during real crash tests and an alternative load
force used during the calculations for crash test types
TB11, TB42 and TB51. These values are specified in
the technical standards [9, 17].

According to the results, which were obtained dur-
ing the FEA simulation and discussed in previous
section, it can be concluded that both safety barriers
passed the crash tests TB11 and TB42 according to
the criteria of the consumed energy, and therefore
the models correspond to the containment level H1.
According to the impact forces the barriers are able
to withstand, both types passed all three crash tests —
TB11, TB42, TB51 – and, thus, correspond to the con-
tainment level H2 specified in the technical documents
by the manufacturer [2, 3].
Taking into consideration the mentioned facts, it

can clearly be seen that by the performance of the
same functions, the crash barrier JSAM-2/H2 proved
to have several advantages against the crash barrier
JSNH4/H2. Among them is a better energy absorp-
tion, and therefore higher safety for the vehicle occu-
pants. Another advantage is its weight, which is lower
by 32 % than the weight of the 2JSNH4/H2 (29 kg
against 42.670 kg) [2, 3].

5. Conclusions
Resuming all the facts, it can be concluded that the
ANSYSr WorkbenchTM 15.0 and the ANSYS LS-
DYNAr 15.0 proved to be very good tools for a stress
assessment of different constructions — resistance
against plastic deformation. Though it is indicated
in standards that the safety barriers should be tested
in real crash tests, preparation and financing of such
tests is, however, a challenging task. The ANSYSr
has excellent tools for simulating similar tests and
it can be used for preliminary calculations, which
would help to avoid possible mistakes and wasting
time. Besides, it would reduce costs, and what is most
important — increase the efficiency of the preparation
of experimental tests and improve the final results.

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vol. 56 no. 6/2016 Finite Element Modelling and Simulation of Vehicle Impact

Test Alternative load
force barriers
specified in [17]

Impact force obtained
in simulation:

JSNH4 (top value),
JSAM-2 (bottom value)

Kinetic energy
specified in [9]

Internal energy obtained
in simulation:

JSNH4 (top value),
JSAM–2 (bottom value)

TB11 15–35 kN 74.3–105.2 kN
38.3–82.8 kN

40.6 kNm 43 kNm
88 kNm

TB42 45–80 kN 130–183.4 kN
45–157.6 kN

126.6 kNm 135 kNm
120 kNm

TB51 90–140 kN 104–219 kN
78–211.4 kN

287.5 kNm 233.8 kNm
245.1 kNm

Table 6. Correlation of FEA results.

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461

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http://www.ocel-drevo.fsv.cvut.cz/NFF/docs/sborniky/NFF-sbornik14.pdf
http://www.cesti.cz/technicke_listy/tl2014/2014_WP3_TL3_8b.pdf
http://www.cesti.cz/technicke_listy/tl2014/2014_WP3_TL3_8b.pdf
http://das.tuwien.ac.at/fileadmin/mediapool-das/Diverse/Publications/BoA_Siofok/files/p047.pdf
http://das.tuwien.ac.at/fileadmin/mediapool-das/Diverse/Publications/BoA_Siofok/files/p047.pdf
http://das.tuwien.ac.at/fileadmin/mediapool-das/Diverse/Publications/BoA_Siofok/files/p047.pdf
http://papers.sae.org/910323/
http://www.cmms.agh.edu.pl/abstract.php?p_id=317
http://www.cmms.agh.edu.pl/abstract.php?p_id=317

	Acta Polytechnica 56(6):455–461, 2016
	1 Introduction
	2 Steel safety barriers
	3 Finite element modelling and simulation
	4 Results and discussion
	4.1 Comparision of FEA results for JSNH4/H2 and JSAM-2/H2
	4.2 Correlation of results

	5 Conclusions
	References