Simulation of an Emergency Collision of an Electric Locomotive with
a Truck
Mikhail Vladimirovich Zhuykov
1,2
, Alexander Eduardovich Pavlyukov
1
,
Konstantin Mikhailovich Kolyasov
1
and Daniil Vadimovich Duvanov
1,2
1
Ural State University of Railway Transport, Yekaterinburg, Russia
2
LLC Ural Locomotives, Verkhnyaya Pyshma, Russia
Keywords: Emergency collision, electric freight locomotive, passive restraint system, finite element method, discrete
element method, bulk cargo, kinetic energy absorption, deformation, acceleration.
Abstract. The article presents a real case of a collision of an electric locomotive with a truck that was transporting
crushed stone, as a result of which it led to tragic consequences. Numerical modeling combined on the basis
of the finite element method and the discrete element method made it possible to evaluate the effect of bulk
cargo located at the time of collision in the back of a truck on irreversible deformations of the driver's cab,
destruction of glazing, absorption of impact energy, as well as accelerations at the driver's seat installation
places. The numerical modeling technique takes into account the geometric and physical nonlinearity of the
object of study. Particles of bulk cargo are considered as solid bodies with unchangeable geometry. The
deformation of the system occurs due to deformations at the points of contact between the particles. The
results of the study can be used to make changes to the power frame of the driver's cab of operated electric
locomotives in order to avoid tragic consequences and preserve the life and health of the locomotive crew.
1 INTRODUCTION
In the work (Krasyukov, 2020) and article
(Krasyukov, 2014), the number of emergency
collisions of railway rolling stock on public tracks for
2001 to 2008 inclusive is given, where it is indicated
that more than 72% of all collisions occur at
unguarded railway crossings, 10% at guarded railway
crossings, 17% with wagons during shunting work,
1% – with other obstacles.
Collisions of railway transport with trucks happen
very often. Trucks often transport crushed stone, sand
or other bulk cargo, therefore, when an electric
locomotive collides with trucks, not only material
damage to the rolling stock can be caused, but also
damage to the health of the locomotive crew, and
sometimes injuries incompatible with life in the
electric locomotive directly at the time of the
collision.
A striking example of the above is the case of a
collision that occurred on October 23, 2021 with a
freight electric locomotive 3ES5K "Ermak"
(Zapovednaya highway, https://zen.yandex.ru), as a
result of which the driver's assistant died from his
injuries, the consequences of the collision are shown
in Fig. 1.
The above case shows that it is necessary to
minimize the injury of the locomotive crew, as well
as to exclude the death of the locomotive crew in case
of emergency collisions of electric freight
locomotives. Reducing injuries and eliminating the
death of the locomotive crew is possible due to a
workable passive restraint system used on newly
produced freight electric locomotives, as well as in
the modernization of driver's cabs on operated freight
electric locomotives manufactured in the Russian
Federation (RF).
The object of the study is the driver's cabin of an
electric freight locomotive with glazing.
In this article, the authors conduct a study of the
collision of an electric locomotive with a truck, in the
body of which there is a bulk cargo, and evaluate
deformations, energy intensity and longitudinal
accelerations (in places where the driver's seats are
installed) for the driver's cab of an electric locomotive
based on numerical modeling in order to assess the
performance of the passive restraint system.
In numerical modeling, the authors combine two
methods: the finite element method and the discrete
Zhuykov, M., Pavlyukov, A., Kolyasov, K. and Duvanov, D.
Simulation of an Emergency Collision of an Electric Locomotive with a Truck.
DOI: 10.5220/0011582500003527
In Proceedings of the 1st International Scientific and Practical Conference on Transport: Logistics, Construction, Maintenance, Management (TLC2M 2022), pages 253-259
ISBN: 978-989-758-606-4
Copyright
c
2023 by SCITEPRESS – Science and Technology Publications, Lda. Under CC license (CC BY-NC-ND 4.0)
253
element method. The combination of these methods
makes it possible to assess the impact of bulk cargo
located at the time of collision in the truck body on
irreversible deformations of the driver's cab,
destruction of glazing, absorption of impact energy,
as well as accelerations at the driver's seat installation
places.
2 MATERIALS AND METHODS
The main approaches and provisions to the concepts
of passive restraint systems (PRS) for passenger
trains of locomotive traction are considered in
(Sobolevskaya, 2015; Tyrell, 2005). The main design
solution of PRS for modern freight electric
locomotives manufactured in the territory of the
Russian Federation is presented in (Zhuykov, 2022).
The main design solution of PRS for modern
freight electric locomotives manufactured in the
territory of the Russian Federation is shown in Fig. 2.
The weakest point in the existing PRS is the
driver's cab due to the fact that at the moment the
current domestic standards do not take into account
the variety of scenarios in emergency collisions, in
contrast to European and American standards for
crash tests, and, therefore, need to be improved.
The authors of this article for the study of an
emergency collision took an obstacle in the form of a
truck with the following dimensions: length 6600 mm
(6.600 m), width 2500 mm (2.500 m), height 2975
mm (2.975 m). The weight of the truck is 24558 kg
(24.558 tons), the weight of the bulk cargo is 22388
kg (22.388 tons), the weight of the electric
locomotive is 200,000 kg (200 tons). The initial speed
of the collision is 72 km/h (20 m/s).
The structure of the model of a two-section
electric locomotive, shown in Fig. 3, for collision
research based on numerical modeling consists of the
following components: two bodies, four trolleys, two
modular cabins, body-to-trolley connections,
intersectional coupling, railway track, obstacle.
When setting the problem, initial conditions are
set, it is assumed that the material of the electric
locomotive is not deformed at the initial moment, all
the components of the electric locomotive move at the
same speed in the same direction. While all the rail
nodes and obstacles are at rest. In addition, the
Figure 1: Consequences of the collision between 3ES5K (Ermak) electric locomotive and truck on October 23, 2021:
(
a
)
g
eneral view after the collision,
(
b
)
view of the cab of the electric locomotive after the collision.
Fi
g
ure 2: The main desi
g
n solution of the PRS of modern domestic frei
g
ht electric locomotives.
TLC2M 2022 - INTERNATIONAL SCIENTIFIC AND PRACTICAL CONFERENCE TLC2M TRANSPORT: LOGISTICS,
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volumetric forces due to the acceleration of gravity
are set.
To model the bulk cargo, the discrete element
method was used, which was developed by Kandall
in 1971 to analyze problems related to the rock
mechanics.
Assumptions were used in the calculation
(Larsson, 2014):
1. Particles are treated as solids with
unchangeable geometry. The deformation of
the system occurs due to deformations at the
points of contact between the particles.
2. Particle-particle contact occurs at the points of
contact.
3. A contact is used that allows a slight overlap at
the contact points. The overlap is small
compared to the particle size, movement and
rotation of the particles.
4. Only at the points of contact is there any
interaction between the particles. The time step
is small enough, allowing only the force from
the particle to its contact particles.
5. Newton's second law of motion is used to
determine the motion of solid particles,
acceleration and velocity are constant at each
time step.
6. The time step allows the disturbance to
propagate only to the nearest neighboring
particle, the forces acting on the particle are
determined only by the interaction with the
contacting particles.
To study an emergency collision based on
numerical simulation, the ANSYS 2022R1
calculation complex with the LS-DYNA R12.0 solver
was used (Livermore Software Technology
Corporation (LSTC), 2018; Livermore Software
Technology Corporation (LSTC), 2018), the finite
element method and the discrete element method with
an explicit integration scheme were chosen, the
geometric and physical nonlinearity of the object of
study was taken into account. Shell finite elements
were used for the body of the electric locomotive,
modular cab, trolley frames, obstacles and rails; for
wheelset axles - three-dimensional hexahedral finite
elements; for the suspension of the chassis, one-
dimensional finite elements were used, which allow
simulating a linear elastic-dissipative connection
between two nodes; and distributed mass elements for
equipment, locomotive crew. The number of one-
dimensional elements used was: beam – 72, spring
and damper – 134; elements of distributed mass – 2;
three-dimensional hexahedral finite elements - 2600;
shell finite elements -289115; discrete elements - 227.
3 RESULTS AND DISCUSSION
In case of an emergency collision of an electric
locomotive with a truck, in the body of which there is
a bulk cargo, irreversible deformations of the driver's
cab and the body of the electric locomotive occur.
Irreversible deformations of the driver's cab and the
electric locomotive body are shown in Fig. 4 (a), 4
(b), 4 (c), 4 (d) for four values of the physical collision
time: 0.05 sec., 0.10 sec., 0.15 sec., 0.20 sec.,
respectively. The movement of bulk cargo when an
electric locomotive collides with a truck is shown in
Fig. 5 (a), 5(b), 5(c), 5 (d) for four values of the
physical collision time: 0.05 sec., 0.10 sec., 0.15 sec.,
0.20 sec., respectively.
As a result of the collision of an electric
locomotive with a truck, in the body of which there
was a bulk cargo, the glazing of the driver's cabin was
Figure 3: Structure of an electric locomotive model for collision study based on numerical simulation.
Simulation of an Emergency Collision of an Electric Locomotive with a Truck
255
Figure 4: Study results: (a) irreversible deformations at a time of 0.05 seconds, (b) irreversible deformations at a time of 0.10
seconds, (c) irreversible deformations at a time of 0.15 seconds, (d) irreversible deformations at a time of 0.20 seconds.
Figure 5: Study results: (a) movement of bulk cargo at a collision time of 0.05 seconds, (b) movement of bulk cargo at a
collision time of 0.10 seconds, (c) movement of bulk cargo at a collision time of 0.15 seconds, (d) movement of bulk cargo
at a collision time of 0.20 seconds.
TLC2M 2022 - INTERNATIONAL SCIENTIFIC AND PRACTICAL CONFERENCE TLC2M TRANSPORT: LOGISTICS,
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Figure 6: Destruction of the glazing of the driver's cab according to the simulation results at a collision time of 0.2 seconds.
destroyed from the side of the driver's assistant,
visually shown in Fig. 6 at the time of the physical
collision time of 0.20 seconds.
According to the results of numerical simulation
of an emergency collision of an electric locomotive
with a truck, in the body of which there is a bulk
cargo, the dependences of kinetic energy absorption
and accelerations in the places of installation of the
driver's seats on time are obtained. The absorption of
kinetic energy in an emergency when an electric
locomotive collides with a truck without bulk cargo
was 0.064 MJ, and with bulk cargo – 0.324 MJ.
The results of numerical simulation of an
emergency collision showed that the power frame of
the driver's cab meets the safety requirements, the vital
space for the locomotive crew is preserved, the
acceleration in the driver's seats did not exceed
75 m/s
2
.
Graphs of absorbed kinetic energy are shown in
Fig. 7 (a), accelerations at the driver's seat installation
places in Fig. 7 (b) and in Table 1.
4 CONCLUSIONS
The authors of the article present a real case of a
collision of an electric locomotive with a truck that
was transporting crushed stone, as a result of which it
led to tragic consequences.
The article presents a methodology for
investigating an emergency collision of an electric
freight locomotive based on numerical modeling,
taking into account the geometric and physical
nonlinearity of the object of study using the finite
element method and the discrete element method.
The values of irreversible deformations, absorbed
energy, accelerations in the places where the driver's
seats are installed in an emergency collision are
determined.
The application of the finite element method
together with the discrete element method makes it
possible to assess the destruction of the glazing of the
driver's cab of an electric freight locomotive.
Table 1: Results of an emergency collision study based on numerical simulation of an emergency collision of an electric
locomotive with a truck.
Type of collision Without bulk cargo With bulk cargo
Cabin deformation, mm 23.4 10,6
Absorption of kinetic energy, MJ 0.64 0.324
Acceleration at the
p
laces where the driver's seats are installed, m/s
2
59.42 73.95
Obstacle mass, tons 24.558 46.946
Initial collision s
p
eed, km/h 72
The height of the upper
p
oint of the obstacle from the LRH, mm 3.370 2.900
Simulation of an Emergency Collision of an Electric Locomotive with a Truck
257
(a)
(b)
Figure 7: Study results: (a) absorbed kinetic energy, (b) accelerations in the places where the driver's seats are installed.
The results of the study can be used to improve
drivers' cabins when modeling emergency collisions
for electric locomotives of other series in operation,
which require a reduction in irreversible deformations
to preserve vital space for the survival of the
locomotive crew and not exceed accelerations in the
places where the driver's seats are installed 75 m/s
2
.
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