Experimental Electric Vehicle eŠus Gen2
JOSEf BřOUšEK, MARTIN BUKVIC, PAVEL JANdURA MECCA   02 2016   PAGE 07

10.1515/mecdc-2016-0007

Experimental Electric Vehicle eŠus Gen2
JOSEf BřOUšEK, MARTIN BUKVIC, PAVEL JANdURA

1. INTRODUCTION
In 2011, the Institute of Mechatronics and Computer Engineering 
established ties with the Department for Vehicles and Engines, 
both part of Technical University of Liberec, with the aim of 
expanding the competencies of both entities in the field of 
electric mobility. In the same year, a project was drafted to 
develop a light experimental BEV category vehicle. This vehicle 
now serves as an open platform for educational purposes and 
the testing of existing and currently developed components 
designed for electric vehicles. These include, in particular, the 
design and implementation of an electric powertrain and the 
design of the traction battery and its management coupled with 
the other on-board electronics. 

2. CONCEPTION OF THE VEHICLE
Conceptually, it is a four-wheeled two-seat vehicle of the 
Roadster type chassis with a solid frame and front wheel drive 
(FWD) see Fig. 1. The frame design is mixed. It is a combination 
of a steel weldment and an assembly bolted from extruded 
aluminum profiles [1].

The wheelbase is 2462 mm. Wheel track of both axles is identical 
at 1435 mm due to the specific use of a pair of front axles from the 
Skoda Fabia with McPherson suspension. This solution opens up the 
possibility of future installation of a system for steering the rear axle. 
In the current version, the control of the rear axle is mechanically 
locked. Vehicle height is 1300 mm and its length is 3350 mm. Curb 
weight of the vehicle incl. traction battery is 850 kg. 

JOSEF BŘOUŠEK, MARTIN BUKVIC, PAVEL JANDURA
Technical University of Liberec, Studentská 2, CZ 461 17 Liberec, Czech Republic, Department of Vehicles and Engines, Mechanical 
Engineering Faculty; Institute for Nanomaterials, Advanced Technologies and Innovation
E-mail: josef.brousek@tul.cz

SHRNUTÍ
V úvodu článku je popsán vznik a koncepce experimentálního elektromobilu. Následuje popis použitých mechanických a elektrických 
komponent v kombinaci s konstrukčními řešeními dílčích celků jako je např. pohonné ústrojí vozidla nebo trakční baterie vozidla. 
Volba použitých komponent a konstrukčních řešení je zde zhodnocena vzhledem k současným trendům ve vývoji elektromobilů. 
Článek obsahuje i simulace dynamiky vozidla pro vybrané elektromotory se kterými se počítalo pro zástavbu do vozidla.
KLÍČOVÁ SLOVA: ELEKTROMOBILITA, HNACÍ ÚSTROJÍ, TRAKČNÍ ELEKTROMOTOR, PŘEVODOVKA, LITHIOVÉ AKUMULÁTORY 

ABSTRACT
In the introduction to the article, the conception and development of an experimental electric vehicle is described. It is followed by 
a description of the used mechanical and electrical components in combination with the design solutions of sub-units, such as the 
vehicle powertrain and traction battery. The choice of components and design solutions is evaluated here with regard to the current 
trends in the development of battery electric vehicles.  
KEY WORDS: ELECTRIC MOBILIT Y, POWERTRAIN, TRACTION ELECTRIC MOTOR, TRANSMISSION, LITHIUM BATTERIES 

EXPERIMENTAL ELECTRIC VEHICLE EŠUS GEN2

FIGURE 1: Experimental electric vehicle eŠus Gen2.
OBRÁZEK 1:  Experimentální elektromobil eŠus Gen2.



Experimental Electric Vehicle eŠus Gen2
JOSEf BřOUšEK, MARTIN BUKVIC, PAVEL JANdURA MECCA   02 2016   PAGE 08

In the space between the axles, the perimeter steel frame forms 
a shaft designed for installation of the battery box with traction 
battery and the BMS. This concept can dedicate most space 
for the traction battery while preserving the spatial comfort of 
the cabin and luggage compartment. Its main drawback is the 
necessity of a higher seating position for the crew due to the 
minimum design height of the battery. This ranges from about 
100 mm with Tesla Model S/X vehicles up to about 160 mm with 
the BMW i3 vehicle. For the eŠus Gen2 experimental vehicle, the 
construction height of the battery is 84 mm.

3. PROTOTYPE OF THE DUAL MOTOR 
DRIVE SYSTEM POWERTRAIN
The main requirement of any powertrain concept is to achieve 
the maximum efficiency under all operating conditions. However, 
with the most common powertrain concept (one motor with 
SST) this requirement is hard to achieve in particular when 
there is high demand for vehicle driving dynamics or a wide 
range of driving speeds. This leads to the situation where one 
high power motor works at a fraction of its nominal power for 
the most of its operational time. This imposes high demands 
on the motor design in terms of its overall efficiency. There are 
several powertrain configurations [2][3] that due to more or less 
complicated technical solutions, offer significant improvement 
in this area of interest.
One of these is a powertrain configuration known as the Dual 
Motor Drive System (DMDS). The main idea of operation is 
based on the joint control of torque of both powertrain motors - 
primary and assistant. The DMDS control algorithm can engage 
just the primary motor, which in most cases is designed for 
maximum effectiveness at low loads when the assistant motor 
is freewheeling. The assistant motor is automatically engaged 
by the control algorithm only under specified conditions and can 
thus be optimized for heavy load operation or better efficiency at 
high driving speed. The DMDS therefore optimizes the efficiency 
of the powertrain for most operating conditions. 
One of technology advantages of DMDS as opposed to 
powertrains with multi-speed transmission (MST) [4], [5], [6], 
is the seamless torque distribution to the wheels, which is 
problematic even with dual clutch transmission. Also, the ability 
to achieve a better weight distribution of the vehicle mass and 
the cooling efficiency of individual components while preserving 
the compact design should be considered. 
Several versions of the DMDS concept can be implemented, but 
the most promising characteristics of DMDS are offered in AWD 
configuration using a combination of two sets of electric motors 
with its own singe-speed transmission (SST), installed at both 
axles. Then, the SSTs can also utilize different gear ratios. This 
particular DMDS configuration is used by Tesla powertrains [7]. 

They use two different asynchronous motors (ACIM) with the 
same gear ratio of i = 9.7 in both SSTs.  
The only fundamental requirement for an assistance motor is 
that it must generate the smallest possible losses in its magnetic 
circuit when freewheeling. From this perspective, the ACIM 
type seems to be the best suited. In this mode of operation its 
relatively narrow band of high efficiency is not a great deficiency 
when compared with PMSM. Based on the above characteristics, 
it can be said that DMDS and its latest modification with three 
motors (two motors with electronic differential for torque 
vectoring on the rear axle, one motor with SST on the front 
axle) currently ranks among the most promising concepts of 
powertrains for BEV.
We have decided to verify the real world characteristics of DMDS 
in the second generation of the experimental electric vehicle.  
Our prototype of DMDS anticipates the use of two electric 
motors mounted on both sides of a common shaft of one SST in 
FWD configuration. The main reasons for this particular design 
is to test the common behavior of two motors on the same 
shaft in the joint torque control. Another important reason was 
the significant production cost of our SST design. However, the 
principle of operation remains the same. 

3.1. REQUIREMENTS FOR DRIVING DYNAMICS
The DMDS device type provides an improvement in the overall 
efficiency in comparison with the powertrain with SST, primarily 
assuming a requirement for higher driving dynamics of the 
vehicle. For this reason, the powertrain of the Gen2 vehicle 
was designed to achieve an acceleration of 0-100 km.h-1 in 
under 10 s. This value may be still considered as a borderline 
for vehicles with better driving dynamics. The maximum speed 
of the designed powertrain is 100 km.h-1. This value has been 
chosen to enable real world testing of the vehicle acceleration 
rate. The Gen2 vehicle platform was never intended for use on 
the road, so the maximum speed and vehicle behavior at higher 
speeds was not a subject of interest. To meet this requirement, 
due to the design curb weight of 850 kg, it is necessary to have 
a peak mechanical output of the powertrain of over 70 kW.

3.2. THE CHOICE OF ELECTRIC TRACTION MOTORS 
To optimize the DMDS concept for maximum efficiency it is 
necessary to differentiate the performance of both motors, 
usually in a ratio of 1:2 up to 1:3. The main machine should 
be able to operate continuously while driving over the entire 
range of constant speeds while exhibiting an efficiency of over 
80%. For an up-to-date BEV M1 category with a curb weight 
of 1500 kg, this corresponds to a permanent performance of 
25-30 kW. For the Gen2 vehicle, the requirement for permanent 
performance was calculated to a value of 10 kW with the ability 



Experimental Electric Vehicle eŠus Gen2
JOSEf BřOUšEK, MARTIN BUKVIC, PAVEL JANdURA MECCA   02 2016   PAGE 09

of short term overload to 20 kW. Thus, the assistance motor must 
have a peak power of min. 50 kW. As the main motor we decided 
on the ME 1302 type, liquid-cooled AF-PMSM from Motenergy, 
Inc. As an assistance motor it was originally proposed to use 
the ACIM principle, AC-34 type from HPEVS. However, during 
development we were forced to change the type of assistant 
motor. This change during development was due primarily to 
the limited budget allocated for this project. We used a custom 
modified version of an RF-PMSM motor originally developed by 
the Zero Motorcycles company, Type 75-7. An important benefit 
was the availability of configuration files for Sevcon Gen4 series 
FOC controllers which we decided to use. The main drawback of 
using this kind of “low-cost” motor is that in most cases there 
are no detailed technical data and efficiency maps available. 
However, this is not a crucial issue for verifying the fundamental 
characteristics of the DMDS concept.

3.3. SINGLE-SPEED TRANSMISSION DESIGN
From the parameters of traction motors for the DMDS device 
are derived the basic requirements for the parameters of the 
SST. Designed maximum input torque is 200 Nm and maximum 
operating speed is 8000 rpm. The overall gear ratio Ic < 9 for the 
maximum vehicle speed of 100 km.h-1. 
Due to the vehicle concept, it was decided to design the SST 
prototype in the form of a diploma thesis. For this design, 
components from the MQ 200 02T manual six-speed MST 
were taken. The input shaft was designed and manufactured 
for the aforementioned connection of both electric motors. The 
adjustment of the standard input shaft also included installation 
of the parking pawl wheel. The countershaft was also modified 
from a standard one, by shortening and adjusting the diameters.  
The differential was left as a standard one, but because of 
the shortening of the resultant depth of the SST, it is rotated 
by 180° compared to its original location in the MQ 200. The 

resulting gear is formed by tooth wheels of the second gear and 
differential constant gear with a gear number of ic = 8.9. The 
proposed SST allows service exchangeable gears in the range of 
second, third and fourth gear from the MQ 200 02T.
On both sides of the input shaft, joints are designed with tight 
springs for connecting the electric motors by means of fixed 
couplings.

FIGURE 2: from the left: Motenergy ME 1302, HPEVS AC-34, 
Zero Motorcycles ZF 75-7.
OBRÁZEK 2: zleva: Motenergy ME 1302, HPEVS AC-34, Zero 
Motorcycles ZF 75-7.

TABLE 1: Main parameters of DMDS electric traction motors.
TABULKA 1: Hlavní parametry trakčních motorů pro DMDS.

Motor Parameter Unit
Motenergy 
ME1302

HPEVS
 AC-34

Zero Motorcycles 
ZF 75-7

Motor Type [-] AF-PMSM ACIM RF-PMSM
Peak Torque [N.m] 50 144 144
Cont. Torque [N.m] 12 12 45
Peak Power [kW] 17 55 50
Cont. Power [kW] 4 4 17
Max. Speed [rpm] 8000 8000 6000*
Max. Efficiency [-] 0.92 0.88 0.92
Weight [kg] 15.9 38.5 17

* The lower max. speed of the ZF 75-7 motor means it is necessary to 
use a third gear of the MQ200 02T transmission to reach the speed of 
100 km.h-1  

FIGURE 3: Model of internal layout of the DMDS transmission.
OBRÁZEK 3: Model vnitřního uspořádání DMDS převodovky.

FIGURE 4: The final model of the DMDS powertrain.
OBRÁZEK 4: Výsledný model hnacího ústrojí DMDS.



Experimental Electric Vehicle eŠus Gen2
JOSEf BřOUšEK, MARTIN BUKVIC, PAVEL JANdURA MECCA   02 2016   PAGE 10

The SST housing is made from aluminum alloy. Since it is 
a prototype, manufacturing using chip machining on a CNC 
milling machine was chosen. The shapes of the SST housing were 
then subjected to this technology. The housing was designed with 
regard to low weight and sufficient stiffness of the construction. 
Given the requirement for mutual alignment, the lid (cover) 
and the housing are secured with respect to one another with 
precise pins. Material for manufacture of the prototype housing 
is EN AW 7021 [AlZn5.5Mg1.5]. This material exhibits low 
internal stress, excellent dimensional stability, strength and also 
very good machinability. For oil filling and draining, there are 
formed two holes with plugs with threads on the SST. The weight 
of the housing including flanges for connecting electric motors is 
8 kg. The complete SST including fillings weighs 22 kg.
The parking pawl system prevents starting (drive away) of the 
vehicle, even when handbrake is unloaded. The base plate of the 
pawl (latch) is designed for manufacture by milling on a CNC 
machine from the same material as the SST housing.
The pawl is mechanically operated by a Bowden cable in the 
Gen2 vehicle, which is based on the original VW Group DSG 
transmission selector lever.
The parking pawl is produced from 11 523 non-alloyed steel. 
Other parts are taken from the VW Group DQ series transmission.

3.4. CONNECTING THE ELECTRIC MOTORS TO THE 
TRANSMISSION AND FITTING THE POWERTRAIN TO THE 
VEHICLE
Both types of electric motor have a standard NEMA C-face 
flange and a grooved output shaft. To connect them to the SST 
housing, flanges from the same material as the housing were 
designed. Steel couplings are used for connection to the SST 
driving shaft. The DMDS is positioned in the vehicle in front of 
the front axle. Here it is hung behind the SST housing, both on 
an extruded profile, which is resiliently mounted in silent blocks, 
and furthermore it is flexibly clamped in the axle housing of the 
front axle. 

4. DESCRIPTION OF THE TRACTION 
BATTERY BOX DESIGN AND THE BMS 
The battery box was designed as an aluminum welding with 
two reinforcing bars. The box is inserted into a shaft formed by 
a peripheral steel frame which is bolted to the lower rim of the 
box. This solution could be further developed in the form of an 
automatic exchange system for the battery box.
Requirements for traction batteries on current M1 category BEVs 
are mostly met using Li-Ion cell technologies with NCA-C(Si) 
and NMC -C(Si) chemical structures. In addition to the chemical 
structure, the format of the cell and its size also significantly affects 
its specific energy density. The small cylindrical format 18650 cells 
exhibit the highest specific energy density in the last decade. Cells in 
other formats, whether prismatic, cylindrical or pouch embodiment, 
exhibit significantly worse specific energy density.  
Modules of the Gen2 traction battery are designed for Saft 
VL 41 M cylindrical cells of the NCA-C type. These large format 
(144 Wh) cells were preferred to the small ones (~12 Wh) of 

FIGURE 5: Parking pawl mechanism.
OBRÁZEK 5: Mechanismus parkovací západky.

FIGURE 6: Detail of the DMDS installation in the vehicle.
OBRÁZEK 6: Detail instalace DMDS ve voze.



Experimental Electric Vehicle eŠus Gen2
JOSEf BřOUšEK, MARTIN BUKVIC, PAVEL JANdURA MECCA   02 2016   PAGE 11

the 18650 format, mainly due to easier installation. For the next 
generation of traction battery, we already take into account 
a transition to the 18650 format or the newly introduced 20700 
and 21700 formats. 
The designed battery box enables the setting up of modules with 
cells in two basic versions. 
The first one enables installation of 11 battery modules with an 
energy of 18.8 kWh, but without active thermal management. 
The second one uses thermal management for peak load of the 
6C / 960A battery. Then the box is set up with 10 modules with 
an energy of only 17.2 kWh.  
Each module consists of 12 cells in the 3s4p wiring, see Fig. 8. 
Cells are positioned between two faces from flame retardant 
plastic. Cell terminals are interconnected flat Cu busbars with 
a cross-section of 70 mm2 and then covered with a plastic 
lid. One 10 k thermistor is attached to each four cells. Their 
outlets together with the wires for sensing the cell voltage are 
connected to a common connector for connecting the module 
with the BMS.

Thermal management was designed using the properties of the 
PCM material [8] to instantly transform heat from the cells to 
a change of its phase. This principle is extended to a system of 
distribution plates (sheets) that facilitate the rapid transfer of 
heat from the PCM to the exchanger in the battery box base. 
Thus, it is hybrid management. In the traction battery prototype, 
this system has not been set up yet.
The electronic BMS system of the vehicle comes from Ewert 
Energy Systems, Inc. It is a centralized system with a main unit. 
Balancing cell current is 100 mA.

5. CHARGING SYSTEM OF THE VEHICLE
The charging system of the Gen2 vehicle is implemented using 
three one phase on-board chargers, each with an output (power) 
of 2.3 kW. If there is a three-phase socket, it can be charged 
with a power up to 7 kW and the vehicle can thus be fully 
recharged in 3 hours. The vehicle is equipped with the European 
standardized charging plug according to IEC 62196, also known 
as “Mennekes”. The BMS allows charging of the traction battery 
by recuperative braking.

6. CONCLUSION
At the beginning, given the considerable complexity of the 
issues as a whole, we have chosen a DMDS with the same type 
of electric motors, namely with the ME 1302 type. Currently, 
there is an ongoing optimization of the setting of the inverters 
for master-slave operation of both motors on a common shaft 
to achieve the maximum possible parameters declared by the 
manufacturers. This optimization is evaluated by means of 
measurements on a chassis dynamometer at this time, see Fig. 9. 
After the successful optimization of the master-slave operation 
we are planning to implement the fundamental parts of the 
DMDS control algorithm, still with the ME 1302 motors. In the 
future after evaluating the real-world characteristic we would 
like to implement an advanced DMDS control algorithm with 
two different motors. 

FIGURE 7: Functional sample of the Gen2 vehicle traction battery.
OBRÁZEK 7: Funkční vzorek trakční baterie vozu Gen2.

FIGURE 8: Model of disassembled module of Gen2 traction battery.
OBRÁZEK 8: Model rozloženého modulu trakční baterie Gen2.



Experimental Electric Vehicle eŠus Gen2
JOSEf BřOUšEK, MARTIN BUKVIC, PAVEL JANdURA MECCA   02 2016   PAGE 12

ACKNOWLEDGEMENTS
This publication was written at the Technical University of 
Liberec as part of the project 21127 with the support of the 
Specific University Research Grant, as provided by the Ministry 
of Education, Youth and Sports of the Czech Republic in the year 
2016. 
The results of this project LO1201 were obtained through the 
financial support of the Ministry of Education, Youth and Sports 
in the framework of the targeted support of the “National 
Programme for Sustainability I” and the OPR&DI project Centre 
for Nanomaterials, Advanced Technologies and Innovation 
CZ.1.05/2.1.00/01.0005.

LIST OF ABBREVIATIONS
ACIM Alternating Current Induction Motor
AF-  Axial Flux Electric Machine
BEV Battery Electric Vehicle
BMS Battery Management System
DCT Dual Clutch Transmission
DMDS Dual Motor Drive System
Li–Ion Lithium – Ion technology
MST  Multi – Speed Transmission
NCA  Nickel Cobalt Aluminum
NEDC  New European Driving Cycle
NMC  Nickel Manganese Cobalt
PCM  Phase Change Material
PMSM  Permanent Magnet Synchronous Machine
RF-  Radial Flux Electric Machine
SST  Single – Speed Transmission
AWD  All Wheel Drive

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FIGURE 9: Experimental vehicle eŠus Gen2 on a chassis dynamometer.
OBRÁZEK 9: Experimentální elektromobil eŠus Gen2 na válcové brzdě.