HUNGARIAN JOURNAL OF 
INDUSTRY AND CHEMISTRY 

Vol. 51(1) pp. 23–27 (2023) 

hjic.mk.uni-pannon.hu 
DOI: 10.33927/hjic-2023-04 

LABORATORY MEASUREMENT OF ROLLING RESISTANCE 
COEFFICIENT UNDER DIFFERENT CONDITIONS 

SÁNDOR GUBA1*, PÉTER KOCSOR1, BÁLINT VÖRÖS1, BARNABÁS HORVÁTH1 AND ISTVÁN SZALAI1,2  

1 Mechatronics and Measurement Techniques Research Group, Research Centre for Engineering 
Sciences, University of Pannonia, Egyetem u. 10, Veszprém, 8200, Hungary 

2 Institute of Mechatronics Engineering and Research, University of Pannonia, Gasparich Márk u. 
18/A, Zalaegerszeg, 8900, Hungary 

The aim of our research was to design and construct a measuring device that can determin e the rolling resistance 
coefficient (RRC) under laboratory conditions. The measuring device  has a drum arrangement and the RRC was 
measured on two different model surfaces. The deceleration method was used to investigate t he dependence of 
the RRC on the compression force, velocity and surface temperature on steel as well as rubber surfaces. The 
measured RRC values (0.010–0.025) were similar in magnitude to those characteristic of asphalt roads. By 
increasing the model road surface temperature up to T = 60 ºC the RRC dropped by ∼13% compared to the 
equivalent values at T = 22 ºC 

Keywords: rolling resistance coefficient, deceleration measurement, temperature change, drum 
measurement, measuring device 

1. Introduction 

The motion of wheeled vehicles is hampered by the 

rolling resistance force (FRR), which occurs when an 

object rolls on another due to the interaction between a 

wheel and the track it is running on. This force is 

characterized by the rolling resistance coefficient (RRC), 

which is one of the most important factors in today’s 

automotive industry. The first study of losses as a result 

of rolling friction was carried out by Coulomb in 1785, 

while the first experimental method for determining the 

rolling resistance of vehicle wheels was drawn up by Holt 

and Wormeley [1]. 

In vehicles, one way to save energy is to reduce the 

rolling friction [2]. Manufacturers use different materials 

and pattern designs to create tires that exhibit better 

rolling friction properties, thereby further reducing the 

fuel consumption of vehicles and the greenhouse gases 

they emit. Research has shown that a 10% reduction in 

the RRC results in a 1 - 2% reduction in fuel consumption 

[2]-[3]. 

The FRR results from deformation of the rolling 

body (and surface) as shown in Figure 1. In the case of a 

body rolling at an angular velocity ω, deformation occurs 

on the contact surface between the body and surface. A 

consequence of such deformation to the body is that 

forces act on it to work against the deformation. 

Fm represents the cumulative resultant force of the system 

acting on the contact surface. The resultant force can be 

 

Received: 18 Jan 2023; Revised: 9 March 2023; 
Accepted: 10 March 2023  
*Correspondence: guba.sandor@mk.uni-pannon.hu 

split into a vertical and a perpendicular component, 

which – at a constant angular velocity – are in 

equilibrium with the other components. Fv contributes 

towards keeping the wheel in motion, which is balanced 

by the horizontal component of Fm. The vertical 

component of Fm is balanced by the force G′, which 

results from the mass of the rolling body. 

Since the rolling resistance can be interpreted as a 

force [4], the RRC is a dimensionless physical constant 

 
 

Figure 1. Motion of the wheel at a constant speed on a 

non-deformable road surface 

https://doi.org/10.33927/hjic-2023-04
mailto:guba.sandor@mk.uni-pannon.hu


  GUBA, KOCSOR, VÖRÖS, HORVÁTH AND SZALAI 

Hungarian Journal of Industry and Chemistry 

24 

derived from the quotient of the horizontal and vertical 

components of Fm: 

𝑅𝑅𝐶 =  𝐹𝑅𝑅 /𝐺′  (1) 

The magnitude of the RRC (which typically varies 

between 0.001 and 0.400) depends on the ratio and 

magnitude concerning the deformation of the road 

surface as well as tire. The degree of deformation 

depends on the material properties as well as roughness 

of the tire and the pavement, in addition to the diameter, 

pressure and rotational speed of the wheel amongst other 

factors like temperature that influence these parameters 

[5]. 

Our aim was to study the dependence of the RRC on 

various measurement conditions such as velocity, 

compression force and surface temperature on different 

surfaces. For this purpose, a laboratory-scale device was 

designed and constructed by us which can measure the 

RRC of a model tire on two different model surfaces in 

the event of various conditions. 

2. Experimental 

2.1. Measurement system 

In industry, the methods and conditions for measuring the 

RRC are specified in the standards ISO 18164:2005 and 

ISO 28580:2018. In practice, the most common currently 

used measurement setups are trailer measurements, the 

coast-down method, measurements based on fuel 

consumption and drum measurements [6]. However, 

these all measure the value of the FRR indirectly and infer 

the value of the coefficient. Each measurement method 

has different advantages and disadvantages, moreover, 

none of them can be used to carry out a complete study. 

The appropriate measurement method must be chosen 

according to the situation and opportunities presented by 

it. The drum measurement method is the most widely 

used technique for determining the FRR and RRC under 

laboratory conditions [6]. The measuring device 

designed by us is based on this principle. 

Our apparatus consists of a drum with a large 

diameter on which the model road surfaces are mounted, 

a drive chain, a test wheel, a mechanism that presses the 

wheel and drum together as well as sensors needed to 

make the measurements (Figure 2). 

From the values of the FRR and compression force 

measured, the RRC can be obtained using the parameters 

of the drum and wheel. In the drum measurement 

method, the curvature of the model road surface causes 

an error, but this can be corrected according to the 

following equation: 

𝐹𝑅𝑅 =  𝐹𝑅𝑅,𝑚𝑒𝑎𝑠𝑢𝑟𝑒𝑑 √
𝑟𝑑𝑟𝑢𝑚

𝑟𝑑𝑟𝑢𝑚 + 𝑟𝑤ℎ𝑒𝑒𝑙
 (2) 

where rdrum and rwheel are the radii of the drum and wheel, 

respectively. 

Using this arrangement, the rolling friction force 

can be determined by direct force measurements. In this 

case, the force acting on the axis of the wheel (or drum) 

is measured by applying a given compression force. 

Furthermore, the FRR can be determined indirectly by 

measuring the torque, power or angular deceleration. 

When measuring the power, the rolling friction 

force and its coefficient are determined from the 

difference between the amount of power required to drive 

the freely rotating drum and the power that is needed 

when the wheel is pressed against it (∆P). Due to the 

differential measurement, the bearing and aerodynamic 

losses do not affect the result. One disadvantage is that 

the power consumption changes as the driving motor 

heats up and could lead to an error. 

The deceleration method is similar to the one based 

on power measurements, however, instead of ∆P, the 

difference in the deceleration of the drum is measured. 

Since this is also a differential method, the 

aforementioned sources of errors are not present. An 

additional advantage of measuring the deceleration rather 

than the power is that heating of the driving motor is also 

cancelled out. 

Our equipment can determine the RRC on two 

different model surfaces, namely rubber and steel, by 

measuring the force, power and deceleration. The 

temperature of the surfaces can be controlled by heating 

blankets mounted on the inner surface of the drum. The 

blankets consist of a resistance heating wire embedded in 

silicone rubber and are powered by a high-performance 

HP 6030A power supply. Using the blankets, the surface 

temperature was set between room temperature and 

60 ± 2 ºC. Figure 3 shows that the heat distribution on 

the surfaces of the drum was uniform, a small difference 

 
 

Figure 2. Schematic diagram of the measurement 

system 

 

 
 

Figure 3. Heat map of the drum at 10 km/h 



MEASUREMENT OF ROLLING RESISTANCE COEFFICIENT 

51(1) pp. 23–27 (2023) 

25 

of ∼2 ºC between the temperature of the rubber and 
model steel surfaces was observed. 

The drum is driven by a 0.28 kW Robax 

asynchronous motor controlled by a Siemens 

SINAMICS CU240E-2 PN-F control unit connected to a 

SINAMICS PM340 power module. The rotational speed 

and, therefore, the deceleration of the drum are measured 

by a custom-made inductive rotary encoder based on a 

BALLUFF BES 516-360-S4-C inductive sensor. The 

wheel is positioned by two linear units, which are 

perpendicular to each other. 

Control functions and data acquisition are provided 

by a Python program running on a Raspberry Pi single-

board computer described in [7]. 

2.2. Measurement method 

Taking into account the advantages and disadvantages of 

the applicable methods concerning the drum setup, the 

measurements were made using the deceleration method. 

Firstly, the drum was accelerated to a constant angular 

velocity before the driving motor was disengaged, 

causing the drum to decelerate. The rate of deceleration 

was measured in the form of angular deceleration (β) and 

this measurement repeated by pressing the measuring 

drum and wheel together by applying a given force. 

Together, the rate of deceleration of the drum and wheel 

was greater due to losses resulting from their interaction 

caused by the FRR, which can be calculated by the 

moments of inertia of the drum (Idrum) and wheel (Iwheel) 

according to the following equation: 

𝐹𝑅𝑅 =  𝛽𝑑𝑟𝑢𝑚
𝐼𝑑𝑟𝑢𝑚

𝑟𝑑𝑟𝑢𝑚
+  𝛽𝑑𝑟𝑢𝑚

𝐼𝑤ℎ𝑒𝑒𝑙𝑟𝑑𝑟𝑢𝑚

𝑟𝑤ℎ𝑒𝑒𝑙
2   

− 𝛽𝑙.𝑤ℎ𝑒𝑒𝑙
𝐼𝑤ℎ𝑒𝑒𝑙

𝑟𝑤ℎ𝑒𝑒𝑙
 − 𝛽𝑙.𝑑𝑟𝑢𝑚 

𝐼𝑑𝑟𝑢𝑚

𝑟𝑑𝑟𝑢𝑚
  (3) 

where βl.drum and βl.wheel denote the angular deceleration 

of the compressed drum and wheel, respectively, and 

βdrum stands for the angular deceleration of the freely 

decelerating drum. 

3. Results and discussion 

The measurements were carried out at an initial tire 

pressure of ∼2 bars. The compression force was changed 
between 30 N and 60 N, moreover, the circumferential 

speed was varied between 5 km/h and 20 km/h. The 

surface temperature of the drum was adjusted by 

changing the feeding current of the heating blankets. A 

minimum of three data points were measured under each 

set of conditions before their averages and standard 

deviations were calculated. The standard deviations of 

the compression force and surface temperature were also 

calculated. Error bars X and Y were generated using 

these standard deviations. The value of the RRC on the 

rubber surface was higher than on the steel one in most 

cases. 

3.1. Measurements when different 
compression forces were applied 

According to the literature, the RRC does not depend on 

the magnitude of the compression force. Our 

measurement data, which is presented in Figure 4, show 

that the RRC increases as the compression force rises. 

The reason for this disagreement may have occurred as 

the tire pressure of the model wheel, which depends on 

the compression force applied, was set in the unloaded 

state. Increasing the tire pressure can either increase or 

decrease the RRC depending on the surface it is in contact 

with [5]. With the current measuring device, the tire 

pressure cannot be changed during the measurement. 

This could be an option for future development. It is 

worth mentioning that the standard deviation of the data 

in the case of the rubber surface is higher than in that of 

the steel surface. 

3.2. Measurements at different velocities  

The dependence of the RRC on the circumferential 

velocity of the drum was measured between 5 km/h and 

20 km/h at an initial tire pressure of ∼2 bars while 
subjected to a compression force of 40 N. The measured 

values (Figure 5) show an increasing trend, which is 

consistent with data in the literature [5], [8] from which 

large changes in the RRC are only expected above 

50 km/h. 

  

 

Figure 4. Measurements when different compression 

forces were applied with an initial tire pressure of 

∼2 bars and a velocity of 10 km/h in the case of the 
steel (A) and rubber (B) surfaces 



  GUBA, KOCSOR, VÖRÖS, HORVÁTH AND SZALAI 

Hungarian Journal of Industry and Chemistry 

26 

3.3.  Measurements at different model road-
surface temperatures 

The effect of the road-surface temperature on the RRC 

was investigated by adjusting the temperature of the 

drum, thereby modelling driving on a hot road surface. 

The surface temperature was set at constant values 

between 20 °C and 60 ºC. In all cases, the drop in 

temperature due to rotation of the wheel was below 2 ºC. 

It should be noted that the temperature of the model 

wheel was below the surface temperature throughout the 

experiment. The RRC decreased linearly between 0.024 

and 0.021 as the temperature increased (Figure 6), 

therefore the following equation was fitted to the 

measurement points to determine the temperature (T) 

dependence of the RRC: 

𝑅𝑅𝐶 =  𝑅𝐶𝐶0 − 𝑎𝑇  (4) 

where RRC0 denotes the extrapolated value of RRC when 

T = 0 ºC and a stands for the slope of the regression line. 

The parameters of the linear regression are shown in 

Table 1. 

In our experimental setup, the small change of the 

RRC with the temperature shows that the temperature of 

our model wheel remained less than that of the surface. 

Based on the literature [9], it is expected that the decrease 

in the RRC would be greater if the temperature of the 

surface and wheel were identical. An additional possible 

research direction could be the use of a closed system in 

which the temperature of the drum and wheel can be 

adjusted simultaneously by means of the built-in heating 

blankets. 

4. Conclusions 

In our work, a laboratory device to measure the RRC 

based on the drum measurement method was designed 

and constructed, which is able to determine the RRC on 

two different model surfaces at various temperatures. 

The dependence of the RRC on the compression force, 

velocity as well as the temperatures of the two surfaces, 

namely steel and rubber was determined based on the 

deceleration method. The measured RRC values (0.010–

0.025) were similar in magnitude to those characteristic 

of asphalt roads. 

 

Figure 6. Measurements at different surface 

temperatures with an initial tire pressure of ∼2 bars by 
applying a compression force of 40 N and at a velocity 

of 10 km/h in the case of steel (A) and rubber (B) 

surfaces (The red line denotes the linear regression.) 

 

Figure 5. Measurements at different circumferential 

velocities with an initial tire pressure of ∼2 bars and 
by applying a compression force of 40 N in the case of 

the steel (A) and rubber (B) surfaces 

Table 1. The parameters of the fitted curve 

 RRC0 a (ºC
-1) 

Steel 0.024 -4.15·10-5 

Rubber 0.027 -7.28·10-5 

 



MEASUREMENT OF ROLLING RESISTANCE COEFFICIENT 

51(1) pp. 23–27 (2023) 

27 

• The RRC increased as the compression force rose. 
Since the RRC is independent of the compression 

force, this discrepancy may have resulted from 

changes to the tire pressure that affected the 

measurements. A possible solution to this 

problem is to continuously adjust the tire pressure 

as the compression force changes. 

• The dependence of the RRC on the velocity was 
investigated at three different speeds, that is, 

5 km/h, 10 km/h and 20 km/h. The data shows an 

increasing trend, which is consistent with the 

literature. 

• The dependence of the RRC on temperature was 
also tested. By increasing the temperature of the 

model road surface up to T = 60 ºC, only a slight 

decrease (∼13%) in the measured RRC was 
observed. 

Acknowledgement 

This work was supported by the TKP2020-NKA-10 

project financed under the 2020-4.1.1-TKP2020 

Thematic Excellence Programme by the National 

Research, Development and Innovation Fund of 

Hungary. 

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