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Steering Dynamics of Tilting Narrow Track Vehicle with Passive Front Wheel Design
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2016 J. Phys.: Conf. Ser. 744 012218
(http://iopscience.iop.org/1742-6596/744/1/012218)
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Steering Dynamics of Tilting Narrow Track Vehicle with
Passive Front Wheel Design
Jeffrey Too Chuan TAN1, Hiroki ARAKAWA
1, Yoshihiro SUDA
1
1Institute of Industrial Science, The University of Tokyo, 4-6-1 Komaba, Meguro-ku,
Tokyo 153-8505, Japan
E-mail: [email protected]
Abstract. In recent years, narrow track vehicle has been emerged as a potential candidate for
the next generation of urban transportation system, which is greener and space effective.
Vehicle body tilting has been a symbolic characteristic of such vehicle, with the purpose to
maintain its stability with the narrow track body. However, the coordination between active
steering and vehicle tilting requires considerable driving skill in order to achieve effective
stability. In this work, we propose an alternative steering method with a passive front wheel
that mechanically follows the vehicle body tilting. The objective of this paper is to investigate
the steering dynamics of the vehicle under various design parameters of the passive front wheel.
Modeling of a three-wheel tilting narrow track vehicle and multibody dynamics simulations
were conducted to study the effects of two important front wheel design parameters, i.e. caster
angle and trail toward the vehicle steering dynamics in steering response time, turning radius,
steering stability and resiliency towards external disturbance. From the results of the simulation
studies, we have verified the relationships of these two front wheel design parameters toward
the vehicle steering dynamics.
1. Introduction
Narrow track vehicles [1] that are greener with a smaller footprint similar to a motorcycle are getting a
lot of attentions in recent development of new urban transportation system. In order to maintain its
rollover stability due to the tight wheel track, this type of vehicles has a symbolic characteristic of
vehicle tilting. There are many studies on such vehicle tilting [2], [3], including discussions on
optimum lean angle [4] and tiling position [5]. However, another challenge in developing such tilting
vehicles is that the coordination between active steering and vehicle tilting requires considerable
driving skill in order to achieve effective stability. To address this issue, we have proposed a passive
front wheel that mechanically follows the vehicle body tilting as an alternative way of steering for a
tilting three-wheel narrow track vehicle.
2. Passive Front Wheel Steering for Tilting Narrow Track Vehicle
2.1. Passive front wheel steering concept
In contract to conventional active front wheel steering, in this work, we propose a steering approach
with passive front wheel that mechanically follows the vehicle body tilting for a tilting three-wheel
narrow track vehicle (Fig. 1). We have developed a three-wheel narrow track vehicle with a link
structure attaching the rear wheels and it is controlled by a motor for vehicle tilting. The passive front
MOVIC2016 & RASD2016 IOP PublishingJournal of Physics: Conference Series 744 (2016) 012218 doi:10.1088/1742-6596/744/1/012218
Content from this work may be used under the terms of the Creative Commons Attribution 3.0 licence. Any further distributionof this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI.
Published under licence by IOP Publishing Ltd 1
wheel attached on the steering axle with a caster angle is free to be turned mechanically with respect
the vehicle tilting motion.
Figure 1. Steering concept of the tilting narrow track vehicle with passive front wheel design.
2.2. Passive front wheel design parameters and analyses by simulations
The objective of this work is to investigate the steering dynamics of the vehicle under various design
parameters of the passive front wheel. We have constructed the 3D model of the proposed tilting
three-wheel narrow track vehicle for multibody dynamics analysis [6], [7] using ADAMS [8] software
(Fig. 2 (left)). The vehicle model consists of four rigid bodies: body, front wheel, right rear wheel, and
left rear wheel. The system has 10 degree of freedom (DOF): 6 DOF on the body, 1 DOF on the front
wheel steering axis, and 3 DOF on the three rotating wheels.
The vehicle model is designed to have a total mass of 288 kg with a dimension of 2 m length, 0.63 m
width and 1.55 m height. The wheelbase is 1.49 m and the wheel track is 0.495 m. The front wheel
size is 100/100R12 and the rear wheels size is 90/90R12. We have determined two important front
wheel design parameters: caster angle and trail (Fig. 2 (right)) for our simulation studies. For the
practicability reason of actual vehicle construction, the comparative studies between caster angle and
trail are fixed into two set of front wheel configurations: default caster angle 0 deg versus trail 50, 100,
150 mm, and default trail 62.0 mm versus caster angle 0, 13.5, 27 deg.
Figure 2. Simulation model (left) and passive front wheel design parameters: caster angle and trail.
We have designed three simulation scenarios (Fig. 3) in order to study the vehicle steering dynamics
in steering response time (Fig. 3 (a)), turning radius (Fig. 3 (b)), steering stability and resiliency
towards external disturbance (Fig. 3 (c)).
Trail [m]
Caster angle
[deg]
MOVIC2016 & RASD2016 IOP PublishingJournal of Physics: Conference Series 744 (2016) 012218 doi:10.1088/1742-6596/744/1/012218
2
(a) Steering response
time (J-Turn) (b) Turning radius
(c) Steering stability and resiliency
towards external disturbance
Figure 3. Simulation scenarios to study the vehicle steering dynamics in steering response time,
turning radius, steering stability and resiliency towards external disturbance.
3. Steering Dynamics Analyses
3.1. Steering response time towards vehicle body tilting
In the simulation study of steering response time towards vehicle body tilting (Fig. 3 (a)), the vehicle
is programmed to perform a J-Turn in a fixed travel speed 20 km/h. In the simulation, after the vehicle
achieved the fixed speed in a straight path travel, a 15 deg of vehicle body tilting is triggered (input) to
steer the vehicle. Fig. 4 shows the simulation results of the vehicle steering (angle) response in J-Turn
with a fixed wheel trail and caster angle 0, 13.5, 27 deg.
Figure 4. Steering (angle) response in J-Turn with a fixed wheel trail and caster angle 0, 13.5, 27 deg.
For the comparative studies between caster angle and trail, the simulations are run in the designated
two set of front wheel configurations. The response time for the vehicle to reach 95% of the steady
state steering angle is recorded and the plots of the response time results are shown in Fig. 5. From
both plots in caster angle (Fig. 5 (a)) and wheel trail (Fig. 5 (b)), it is observed that there are no
significant impact (maximum difference is less than 0.04 s) towards the vehicle steering response time
in both caster angle and wheel trail changes.
-1
0
1
2
3
4
5
6
0 10 20 30 40
Ste
eri
ng
an
gle
[d
eg
]
Time [s]
0[deg]
13.5[deg]
27[deg]
MOVIC2016 & RASD2016 IOP PublishingJournal of Physics: Conference Series 744 (2016) 012218 doi:10.1088/1742-6596/744/1/012218
3
(a) Impact of caster angle towards steering
response time
(b) Impact of wheel trail towards steering
response time
Figure 5. Comparison of passive front wheel designs (caster angle and trail) on steering response time
towards vehicle body tilting.
3.2. Effects on vehicle turning radius
In the simulation study to investigate the effects on vehicle turning radius by passive front wheel
steering (Fig. 3 (b)), the vehicle is programmed to perform a circular turning in a constant travel speed
of 20 km/h and 15 deg of vehicle body tilting. Fig. 6 illustrates the simulation results of the vehicle
constant circular turning path (turning radius) with a fixed wheel trail and caster angle 0, 13.5, 27 deg.
Figure 6. Vehicle constant circular turning (turning radius) with a fixed wheel trail and
caster angle 0, 13.5, 27 deg.
The simulations are repeated in the designated two set of front wheel configurations for the
comparative studies between caster angle and trail, and the plots of turning radius results are shown in
Fig. 7. From the caster angle plot in Fig. 7 (a), an increasing trend (greater than 1 m) in vehicle turning
radius is observed as the front wheel caster angle increased. However, no significant impact (less than
1 m difference) towards the vehicle steering turning radius is observed in the wheel trail changes in
Fig. 7 (b).
0
0.5
1
1.5
2
0 10 20 30
Resp
on
ce t
ime [
s]
Caster angle [deg]
0
0.5
1
1.5
2
50 100 150
Resp
on
ce t
ime [
s]
Trail [mm]
MOVIC2016 & RASD2016 IOP PublishingJournal of Physics: Conference Series 744 (2016) 012218 doi:10.1088/1742-6596/744/1/012218
4
(a) Impact of caster angle towards turning radius (b) Impact of wheel trail towards turning radius
Figure 7. Comparison of passive front wheel designs (caster angle and trail) on vehicle turning radius.
3.3. Steering stability and resiliency towards external disturbance
In the simulation study of steering stability and resiliency towards external disturbance (Fig. 3 (c)), the
vehicle is programmed to travel straight forward in a constant speed of 20 km/h, and a 10 Nm reverse
torque (impulse) (Fig. 3(c)) is applied on the front wheel as an external disturbance, with a slight lift
on the rear left wheel to induce steer. Fig. 8 shows the simulation results of the vehicle steering (angle)
response towards the external disturbance (reverse torque) with a fixed wheel trail and caster angle 0,
13.5, 27 deg.
Figure 8. Vehicle steering (angle) response towards external disturbance (reverse torque) with a fixed
wheel trail and caster angle 0, 13.5, 27 deg.
The simulations are conducted in the designated two set of front wheel configurations for the
comparative studies between caster angle and trail, and the maximum displacement of steering angle
results are plotted in Fig. 9 for the vehicle steering stability analysis. It is observed that both caster
angle plot (Fig. 9 (a)) and wheel trail plot (Fig. 9 (b)) are showing decreasing trend of maximum
displacement of steering angle (greater than 0.1 deg difference) as the parameters decreased, especially
in the wheel trail case, as large as 1 deg difference in maximum displacement of steering angle is
recorded.
In the study of steering resiliency towards external disturbance, steering angle recovery time (time
needed to return steady state) results are plotted in Figure 10 (a) (caster angle) and Figure 10 (b)
(wheel trail). It is observed that there are no significant impact (maximum difference is less than 0.3 s)
towards the vehicle steering angle recovery time in both caster angle and wheel trail changes.
0
5
10
15
20
25
0 10 20 30
Tu
rnin
g r
ad
ius [
m]
Caster angle [deg]
0
5
10
15
20
25
50 100 150
Tu
rin
g r
ad
ius [
m]
Trail [mm]
-0.5
0
0.5
1
1.5
2
2.5
3
0 5 10 15 20
Ste
eri
ng
an
gle
[d
eg
]
Time [s]
0[deg]
13.5[deg]
27[deg]
MOVIC2016 & RASD2016 IOP PublishingJournal of Physics: Conference Series 744 (2016) 012218 doi:10.1088/1742-6596/744/1/012218
5
(a) Impact of caster angle towards maximum
displacement of steering angle
(b) Impact of wheel trail towards maximum
displacement of steering angle
Figure 9. Comparison of passive front wheel designs (caster angle and trail) on steering stability
(maximum displacement of steering angle) towards external disturbance.
(a) Impact of caster angle towards steering angle
recovery time
(b) Impact of wheel trail towards steering angle
recovery time
Figure 10. Comparison of passive front wheel designs (caster angle and trail) on steering resiliency
(steering angle recovery time) towards external disturbance.
4. Conclusion
In this work, we propose an alternative steering method with a passive front wheel that mechanically
follows the vehicle body tilting. The objective of this paper is to investigate the steering dynamics of
the vehicle under two important design parameters, i.e. caster angle and trail of the passive front wheel.
From the results of the multibody dynamics analyses in three simulation scenarios, we have verified
the relationships of these two front wheel design parameters toward the vehicle steering dynamics in
steering response time, turning radius, steering stability and resiliency towards external disturbance.
The analyses results are summarized into Table 1 below. The increments of caster angle and trail are
shown to have improvement or minor impact towards the steering dynamics. However, the side effect
(on other vehicle performance) and limit of such parameters should also be studied in future work to
ensure overall improvement.
Table 1. Summary of the steering dynamics analyses with respect to the passive front wheel design
parameters (caster angle and trail).
Steering response Turning radius Steering stability Steering resiliency
Caster angle (↑) Minor impact Increased (↑) Improved* Minor impact
Trail (↑) Minor impact Minor impact Improved* Minor impact
* Maximum displacement of steering angle reduced and hence, steering stability improved.
0
0.5
1
1.5
2
2.5
3
0 10 20 30
Ste
eri
ng
an
gle
[d
eg
]
Caster angle [deg]
0
0.5
1
1.5
2
2.5
3
50 100 150
Ste
eri
ng
an
gle
[d
eg
]
Trail [mm]
0
0.5
1
1.5
2
2.5
3
0 10 20 30
Reco
very
tim
e o
f ste
eri
ng
an
gle
[s]
Caster Angle[deg]
0
0.5
1
1.5
2
2.5
3
50 100 150
Reco
very
tim
e o
f ste
eri
ng
an
gle
[s]
Trail[mm]
MOVIC2016 & RASD2016 IOP PublishingJournal of Physics: Conference Series 744 (2016) 012218 doi:10.1088/1742-6596/744/1/012218
6
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[2] So S G and Karnopp D 1997 Active dual mode tilt control for narrow ground vehicle Vehicle
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[3] Berote J, Darling J and Plummer A 2012 Development of a tilt control method for a narrow-
track three-wheeled vehicle Institution of Mechanical Engineers, Part D: Journal of automobile
engineering 226 1 48-69
[4] Karnopp D and Hibbard R 1992 Optimum roll angle behavior for tilting ground vehicles ASME
Dynamics Systems and Control Division (DSC) 44 29-37
[5] Hibbard R and Karnopp D 1993 Methods of controlling the lean angle of tilting vehicles ASME
Dynamics Systems and Control Division (DSC) 52 311-320
[6] Issa S M and Arczewski K P 1998 Kinematics and dynamics of multibody system based on
natural and joint coordinates using velocity transformations Journal of Theoretical and Applied
Mechanics 36 4 905-918
[7] Jerkovsky W 1978 The structure of multibody dynamics equations Journal of Guidance,
Control, and Dynamics 1 3 173-182
[8] Ryan R R 1990 ADAMS—Multibody system analysis software Multibody Systems Handbook
(Springer Berlin Heidelberg) 361-402
MOVIC2016 & RASD2016 IOP PublishingJournal of Physics: Conference Series 744 (2016) 012218 doi:10.1088/1742-6596/744/1/012218
7