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Slide 1
C i f O d & L b t b dComparison of On-road & Laboratory-based Rolling Resistance Measurements
Dr. Jürgen Bredenbeck
Dr. Rahul Ahlawat, Dr. Michael Smith, Mr. Tatsuo Ichige Mr. Katsuhiko Furuya
Tire Meets Science 11-12 September 2013, Aachen, Germany
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Slide 2
Content
• Objective• On-Road Measurement• On-Road Results• In Door Testing• In Door Results and Comparison• Summary
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Slide 3
Objectivesj
1 C i f d lli i1. Comparison of on-road rolling resistance measurements with standardized indoor testing
2 Comparison of standardized testing on2. Comparison of standardized testing on flat-belt and drum machines
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Slide 4
Content
• Objective• On-Road Measurement• On-Road Results• In Door Testing• In Door Results and Comparison• Summary
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Slide 5
On-Road Rolling Resistance Measurements
Coast-down methode.g. VTI, Sweden [9, 12]
Instrumented trailere.g. FKFS, Germany,
Instrumented vehiclee.g. A&D, Japan
BASt, Germany,HUT, Finland [6]
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Slide 6
On-road Measurements
T t V hi lTest Vehicle: • Instrumented Mini Cooper S• Proving ground in Tochigi Japan• Proving ground in Tochigi, JapanTest Tires: • Rear left(RL) & rear right(RR)• Rear left(RL) & rear right(RR)• Bridgestone Sneaker2 (205/55 R16 91V)• 250 kPa (capped)
StartStop
250 kPa (capped)Test Procedure: • Round course 6 repeats at different speedsp p• Selection of straight, constant speed phase
for data analysis
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Slide 7
Vehicle Instrumentation I
A&D Wheel force Sensor (WFS) • Unique design• Distributed force bridges with model based• Distributed force bridges with model based
decomposition to get orthogonal force components• low cross sensitivity• low temperature sensitivity • high sampling rate
Hi h A• High Accuracy 0.1% resolution (6N or 1.8Nm)
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Slide 8
Vehicle Instrumentation II
D l V l i S• Doppler Velocity Sensor – Vehicle velocity
• GPS Sensor & In-vehicle Network– vehicle longitude, latitude, altitude, and ECU CAN communication
• A&D Wheel Position Sensor6 degrees of freedom of the tire relative to chassies– 6 degrees of freedom of the tire relative to chassies
• Inertial Sensor– vehicle roll, pitch and yaw
• Digital Signal Processing & Acquisition – 100Hz sampling of all signals
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Slide 9
Tire Rolling Resistance
R lli i i d• Rolling resistance is created in the Tire patch– Tire Patch shows an asymmetric contact y
Pressure distribution, which canbe substituted by:
• a total contact force F and• a total contact force F and • a moment MR
– MR appears as resistance force R on R ppthe wheel hub MR = R ∙ rr: dynamic rolling radiusr: dynamic rolling radius
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Slide 10
Mathematical Formulation
[ ]MR = R ∙ r [1]Torque equation: J ∙ ώ = ‐My ‐MR + FA ∙ rwith [1]: J ∙ ώ = ‐My ‐ R ∙ r + FA ∙ r [2]Force equation: m ∙ a = Fx ‐ FA
FA = Fx ‐m ∙ a [3]Kinematic condition: v = ω ∙ rKinematic condition: v = ω ∙ r
r = v / ω [4][3] in [2]: J ∙ ώ = ‐My ‐ R ∙ r + ( Fx ‐m ∙ a ) ∙ r r: Rolling radius
φ, ω, ώ: Angle, angular speed/ R = Fx ‐m ∙ a – ( 1 / r ) ∙ (J ∙ ώ + My )
with [4]: R = Fx ‐m ∙ a – ( ω / v ) ∙ (J ∙ ώ + My )
φ, ω, ώ: Angle, angular speed/ acceleration of wheel
x, v, a: Distance, speed, acceleration of wheel
J i i / fwith [4]: R Fx m a ( ω / v ) (J ώ My ) J, m: torque inertia/mass of wheel
My ,Fx: Torque/force on wheel hubD t i d b f th E i t
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FA : Adhesive forceDetermined before the Experiment
Slide 11
Parameter Determination
Ti b d t i d b• Tire mass can be determined by lifting the wheel. WFS will show the mass
• Tire rolling inertia is determined using free load rotating wheel in acceleration and deceleration condition
• Measurement items
– Tire angular speed ω [rad/s]
– Angular acceleration ώ [rad/s2]
Wh l t M [N ]– Wheel torque Myfree [Nm]
• Rolling inertia formula:My
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freeMy
Jt
Slide 12
Data selection
D i fil d 5H• Data is filtered at 5Hz • various signals are analyzed to find a
time period having constant speed, p g p ,straight line vehicle motion
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Slide 13
Content
• Objective• On-Road Measurement• On-Road Results• In Door Testing• In Door Results and Comparison• Summary
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Slide 14
On-road Rolling Resistance Force
• Three speeds • 6 tests for each speed• Calculation applied to time data of Fx and My according to introduced
form laformula
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Slide 15
Mean Rolling Resistance Forces (RRF)
• Averaging the time record data for individual speedsAveraging the time record data for individual speeds• Rolling resistance force does not vary with significantly with speed• It is possible to have good repeatability for on-road measurements
Mean RRF=85.4 N1 8 N
Mean RRF=84. 9 N Mean RRF=84.6 N1 9 NσRRF= 1.8 N
σRRC= 0.65 N/kNσRRF= 2.3 NσRRC= 0.84 N/kN
σRRF= 1.9 NσRRC= 0.70 N/kN
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Slide 16
Content
• Objective• On-Road Measurement• On-Road Results• In Door Testing• In Door Results and Comparison• Summary
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Slide 17
Indoor Testing Equipment
A&D S d d R lli i i• A&D Standard Rolling resistance test rig– 2m Drum, Steel covered
• A&D Dynamic Flat Belt Test Rig– Steel Belt
• Force Measurement utilizing A&D Hub SensorMBS S h– MBS Sensor approach
– Fx: 300N ±0.3N– Fz: 15kN ±20NFz: 15kN ±20N– Machines Meet Reference Lab repeatability
criteria
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Slide 18
Test Procedure for Indoor Testing
Follow ISO28580 Test Procedure3h h l di i i• 3h thermal conditioning
• 30 min warm up• Test conditions: Speed 80 km/h, 210kPa (capped), 80% max Load• Skim Test at 150NMeasurements:• Spindel Force• Loaded Tire radiusCalculation of:• Surface Force• Parasitic Force• Rolling resistance Force• Temperature correction• Rolling resistance Coefficient • Curvature correction [3], [5]
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Slide 19
Content
• Objective• On-Road Measurement• On-Road Results• In Door Testing• In Door Results and Comparison• Summary
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Slide 20
Comparison of Results
On‐Road (Fz=2.73kN)
Indoor (Fz=4.82kN)
Drum Machine
Clark’s Curvature Correction
Flat‐belt Machine
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Slide 21
Potential Reasons for Differences
Ti li ( b ) h d [4]• Tire alignment (camber, toe) on the road [4]• Roughness of road surface (unevenness, macrotexture) [7, 10-12]
• Energy dissipation in the suspensionEnergy dissipation in the suspension• Dynamic vertical deflection of the tire leading to additional
hysteresis • Additional friction losses due to microslip
• Uncontrolled environmental factors such as temperature and inflation pressureinflation pressure
• Measurement errors such as loaded tire radius
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Slide 22
Indoor Testing Results
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Slide 23
Repeatability Results
E ll bili i hi d f b h d & fl b l hi• Excellent repeatability is achieved for both drum & flat-belt machines• Tire ranking is preserved during iterative testing
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Slide 24
Rank Preservation
• Drum and Flat-Belt machines rank tires differentlyy• Flat-Belt results are lower than drum and curvature corrected [3, 5]
drum machine results
[5]
[3]
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Slide 25
Temperature Differences
Drum acts as a heat sink whereas belt gets heated up
Flat belt machineFlat-belt machine
Drum machineDrum machine
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Slide 26
RRF vs RRC
R l i ki i d f• Relative ranking is not preserved for both RRF and RRC
• Ranking based on RRC and RRF gwill be different as they represent different things
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Slide 27
Summaryy
• Repeatable on-road measurements are possibleRepeatable on road measurements are possible
• Indoor measurements offer superior control of test parameters and very high repeatability
• Measured losses are significantly less than what we see on the real road
• In door testing should include more test variables (such as camber, toe, slip, etc.) to get a closer approximation of in-vehicle & on-road tireapproximation of in vehicle & on road tire performance
• Relative tire rankings from drum and flat-belt gmeasurements are not necessarily equivalent
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Slide 28
Acknowledgementsg
O d d t i iti• On-road data acquisition: – Takayasu Sasaki – Yuuki Sakurai– Masaaki Banno– Hiroki Yamaguchi
• Indoor data acquisition:• Indoor data acquisition: – Atsuo Murakami– Tomikazu Oyama– Masaki Takahashi
• Kenji Sato, A&D Company, Japan• Dr. Rahul AhlawatDr. Rahul Ahlawat
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Slide 29
References1. “Passenger car, truck and bus tyres – Methods of measuring rolling resistance – Single point tests and correlation of
measurement results”, ISO/FDIS 28580, 20092 Hall & Moreland “Fundamentals of rolling resistance” Rubber Chemistry and Technology July/Aug 20012. Hall & Moreland, Fundamentals of rolling resistance , Rubber Chemistry and Technology, July/Aug 20013. Freudenmann, Unrau & El‐Haji, “Experimental determination of the effect of the surface curvature on rolling
resistance measurements”, Tire Science & Technology, Vol. 37, No. 4, 20094. “The pneumatic tire”, Chapter 12: Rolling Resistance, NHTSA, 20065. S.K. Clark, “A handbook for the rolling resistance of pneumatic tires”, 19796. Leinonen & Juhala, “Development of measurement equipment for measuring tire rolling resistance on road”, 8th
biennial ASME conference on engineering systems design & analysis, July 4‐7, 2006, Torino, Italy7 Popov Cole Winkler & Cebon “Laboratory measurement of rolling resistance in truck tyres under dynamic vertical7. Popov, Cole, Winkler & Cebon, Laboratory measurement of rolling resistance in truck tyres under dynamic vertical
load”, Proceedings of the Institute of Mechanical Engineers, Vol. 217, Part D: Journal of Automobile Engineering, 2003
8. Petrushov, “Coast down method in time and distance variables for tire rolling resistance determination”, SAE 2009‐01 007201‐0072
9. Sandburg & Ejsmont, “Noise emission, friction and rolling resistance of car tires – Summary of an experimental study”, National conference on noise control engineering, Dec 3‐5, 2000, Newport beach, California
10. Gillespie, “Measuring road roughness and its effects on user cost and comfort: A symposium”, Issue 884, 198511. Meyer, “Surface characteristics of roadways: International research and technologies”, Issue 1031, ASME, 199012. Karlsson, Hammarström, Sörensen & Eriksson, “Road surface influence on rolling resistance ‐ Coastdown
measurements for a car and an HGV”, VTI, 201113 Salaani et al “NHTSA tire rolling resistance test development project Phase I” Paper Number 09 0300
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13. Salaani et al., NHTSA tire rolling resistance test development project – Phase I , Paper Number 09‐0300