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Dynamic response of highway trucks due to road surface roughness
Cornpurrs & Structures Vol. 49, No. 6. pp. 1055-1067. 1993 0 1994 Elswier Science Ltd Printed in Great Britain. 0045-7949/93 56.00 + 0.00
Pergamon
DYNAMIC RESPONSE OF HIGHWAY TRUCKS DUE TO ROAD SURFACE ROUGHNESS T. L. WANG,? M. SHAHAWY$ and D. Z. HUANGt tDepartment
of Civil and Environmental Engineering, Florida International University, Miami, FL 33199, U.S.A. $Structures Research and Testing Center, Florida Department of Transportation, Tallahassee, FL 32310, U.S.A. (Received 1 April 1992)
Alastrati-Vehicle characteristics, vehicle speed and road surface roughness are major factors influencing bridge dynamic response.. In order to improve the previous vehicle model studies, vehicle models with seven or twelve degrees of freedom were developed for H20-44 and HS20-44 trucks, respectively. Vehicle models were validated by comparisons with the real truck dynamic systems. The road surface roughness was generated from power spectral density (F’SD) functions for very good, good, average, and poor roads. The impact factors of suspension and tire forces were obtained for vehicle models running on different classes of roads at various speeds. A comparison of computed and experimental impact results was also made.
1. INTRODUCTION
Vehicle characteristics, vehicle speed and road surface roughness are some of the major factors that influence the dynamic response of a bridge due to moving
loads. In reality, a truck is a very complex mechanical system because of its suspension. Some assumptions need to be made in order to simplify the vehicle characteristics in mathematical modeling analysis. The dynamic analysis of highway vehicles has been studied since the middle of this century. Brief reviews of the literature can be found in [l-6]. Most of the previous studies have assumed that (1) the vehicle frames are rigid, (2) the interleaf friction forces are considered in a suspension system, (3) spring forces and damper forces are proportional to displacements and a single point. However, all vehicle models were limited to pitch mode vibration and road surface profiles were obtained from field measurement in most of these studies. Even though Whittemore et al. [6] used frequency domain prediction techniques to simulate pavement load, the techniques were established only for linear systems excited by stationary random inputs. In this study, the numerical road surface roughness spectrum is generated by using the random number based on the power spectrum density functions. Vehicle nonlinearity can be admitted when the generated road surface roughness is treated as an input function directly. In addition, the new vehicle models will include the roll vibration. 2.
VEHICLE MODELS
H20-44 and HS20-44 trucks are two major design vehicles in the American Association of State Highway and Transportation Oflicials (AASHTO)
Specification [7l. Two nonlinear vehicle models with seven and twelve degrees of freedom were developed according to the H20-44 and HS20-44 trucks, respectively. Figures 1 and 3 illustrate the side and front views of the H20-44 vehicle model. Three rigid masses represent the truck, front wheel/axle set, and rear wheel/axle set, respectively. In the model, the truck was assigned three degrees of freedom, corresponding to the vertical displacement (JJ), rotation about the transverse axis (pitch or O), and rotation about the longitudinal axis (roll or 4). Each wheel/axle set is provided with two degrees of freedom in the vertical and roll directions. The total degrees of freedom in the model are seven. Similarly, another vehicle model (refer to Figs 2 and 3) with twelve degrees of freedom was developed to represent an HS20-44 truck, consisting of five rigid masses as tractor, semi-trailer, steer wheel/axle set, tractor wheel/axle set, and trailer wheel/axle set. Tractor and semi-trailer were assigned three degrees of freedom (y, 0, and 4) individually. Two degrees of freedom (y and 0) were assigned for each wheel-axle set. The tractor and semi-trailer were interconnected at the pivot point (so-called fifth wheel point, see Fig. 2). Suspension force consists of the linear elastic spring force and the constant interleaf friction force [8]. The load-displacement relationships for friction force, suspension spring force, and combination of these two forces are shown in Fig. 4. The tire springs are assumed to be linear. Since the truck is a complex physical system, certain assumptions were made to simplify the model. These assumptions are as follows: 1. The vehicle runs at a constant speed.
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Fig. 1. Side view of an H20-44 vehicle model. 2. All components move with the same velocity in the longitudinal direction. 3. Provision is made in the model for wheel lift. Under this condition, the vertical tire stiffnesses are taken as zero. 4. Each tire contacts the road at a single point. 5. Force inputs are limited to the vertical direction. 6. In suspension systems, damping elements were assumed to be linear and to be of the viscous type. Damper force is proportional to the velocity. Ten per cent of the critical damping value was used for damping coefficient [6]. In the tires, the damping forces were neglected.
and relative displacements, whereas the dissipation energy, D = ZDi,of the system is obtained from the damping forces. The total kinetic energy, T = Xl;, of the system is calculated using the mass, mass moment of inertia, and translational as well as rotational velocities, of the system components. The moment of inertia of all components is assumed to be constant and the weight of each component is considered as the external force on that component. The equations of motion of the system are derived, using Lagrange’s formulation, as follows:
8%
_dT+dv+aD=o,
The total potential energy, V = Xvi, of the system is then computed from the spring stiffnesses ‘6
Ir
I
N
k
a4i
Is
4 _
‘I
I_
15 I I
‘2
*1-
\
1
I-
t-
‘4
Fig. 2. Side view of an HSZO-44vehicle model.
$3+
a4
(1)
Dynamic response of highway trucks
1057 18”
tr
-I
c
0t1
f
h
YII
Fig. 5. Side view of step bump used in vehicle validation.
3. VEHICLE MODEL VALIDATION
d.
Fig. 3. Front view of H20-44 and HS20-44 vehicle models.
where qi and di are the generalized displacements and velocities. Details of derivation are presented in 191. The equations of motion were solved by using a fourth-order Runge-Kutta scheme [lo, 111, with an integration time step of 0.005 sec. Such a small time step was necessary to avoid numerical instability. The real percentage of impact acquired from the study is defined as
sm 1
4-
Imp(%) =
[
1 x 100%
(2)
in which R, and R, are the absolute maximum responses for dynamic and static studies respectively.
(a) Friction force
In order to check that the mathematical vehicle models properly simulate a real truck dynamic system, it is necessary to validate the models. The 3/4 in-high x 18 in-long and l/2 in-high x 18 in-long step bumps were taken to generate a vertical input for H20-44 and HS20-44 vehicle models respectively, as shown in Fig. 5. The appropriate data used in dynamic simulation of the models was adopted from [8] and is given in [9]. The experimental data was available in [6]. Both damped and undamped suspensions were considered, but tire damping was neglected in this study. Typical tire force histories for H20-44 and HS20-44 vehicle models are shown in Figs 6-9. Impact factors of suspension and tire forces for wide range of vehicle speeds are given in Tables 1 and 2 for H20-44 and Tables 3 and 4 for HS20-44. It may be seen that the impact factors of suspension forces were reduced when a damped suspension system was considered in most cases. However, for tire forces, the impact factors did not change significantly between damped and undamped suspension systems. The comparisons of computed
(b) Suspension spring force 6
(c) Combination of friction and suspension spring forces Fig. 4. The relationship between the force and displacement in the suspension system.
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0’
0.3
0.6
1.2
0.9
1.5
0’ 0.3
1.6
0.6
SIMULATION TIME (SEC)
vehicle with undamped suspension system running at 3/4 inhigh step bump and 55 mph.
1.3
1.6
2.3
2.6
3.3
I 1.6
1.5
1.2
SIMULATION TIME (SEC)
Fig. 6. The tire force history of the rear axle of an H20-44
01 0.6
0.9
3.6
Fig. 7. The tire force history of the rear axle of an H20-44 vehicle with damped suspension system running at 3/4 inhigh step bump and 55 mph.
0’ 0.6
4.3
SIMULATION TIME (SEC)
I
1.3
1.6
2.3
2.6
3.3
3.6
4.3
SIMULATION TIME (SEC)
Fig. 8. The tire force history of the tractor axle of an HS20-44 vehicle with undamped suspension system running at l/2 in-high step bump and 35 mph.
Fig. 9. The tire force history of the tractor axle of an HS20-44 vehicle with damped suspension system running at l/2 in-high step bump and 35 mph.
and experimental impact results of tire forces in different axles are illustrated in Figs 10-13. The agreement between computed and experimental results was found to be very good. The computed impact factors of tire forces almost cover all experimental results.
4. ROAD SURFACE ROUGHNESS
The typical road surface may be described by a periodically modulated random process. The power spectral density (PSD) is a useful tool for analyzing the periodically modulated random process. The PSD
Table 1. Maximum suspension forces and impact factors of an H20-44 vehicle running at 3/4 in-high step bump for different suspension damping conditions and vehicle soeeds Damped suspension
Undamped suspension Maximum static force &ins)
Vehicle speed (mph) 15
Front axle
Rear axle
3.704
13.440
Maximum dynamic force tkins)
Impact factor (%1
Maximum dynamic force (kit&
Impact factor f%)
20 25 30 35 40 45 SO 55
5.361 5.074 4.877 4.721 4.648 4.513 4.506 4.444 4.324
44.74 36.99 31.67 27.46 25.49 21.84 21.65 19.98 16.74
5.164 5.048 4.865 4.705 4.624 4.516 4.494 4.452 4.306
39.42 36.29 31.34 27.02 24.84 21.92 21.33 20.19 16.25
15 20 25 30 35 40 45 SO 5s
24.158 24.097 24.499 24.321 24.449 23.438 22.193 22.638 22.196
79.7s 79.29 82.28 80.96 81.91 74.39 65.13 68.42 65.15
24.163 23.990 24.051 24.129 24.489 23.405 22.093 22.622 22.189
79.78 78.50 78.95 79.53 82.21 74.14 64.38 68.32 65.10
Dynamic response of bigbway trucks
1059
Table 2. Maximum tire forces and impact factors of an H20-44 vehicle running at 3/4 in-high step bump for different suspension damping conditions and vehicle speeds Damped suspension
Undamped suspension Maximum static force
(kips)
Front axle
5.260
Rear axle
functions developed
for highway
15.040
surface roughness
by Dodds
Maximum dynamic force
Impact factor
Maximum dynamic force
Impact factor
6ph)
(kips)
(%)
Wps)
W)
15
20 25 30 35 40 45 50 55
9.313 8.926 8.946 8.888 8.950 8.942 8.892 8.964 8.952
78.19 69.70 70.08 68.97 70.15 70.00 69.05 70.42 70.19
8.882 8.882 8.940 8.878 8.918 8.940 8.893 8.965 8.961
68.86 68.86 69.96 68.78 69.54 69.96 69.07 70.44 70.36
15 20 25 30 35 40 45 50 55
29.330 29.480 28.874 29.758 29.107 28.392 29.585 29.310 29.156
95.01 96.01 91.98 97.86 93.53 88.78 96.71 94.88 93.86
29.714 29.644 28.614 29.704 29.158 28.626 29.689 29.200 28.827
97.57 97.10 90.25 97.50 93.87 90.33 97.40 94.15 91.67
Vehicle speed
have been
S(f#l)=A
and Robson [123. They are
shown as
S(r$)=A
02 --, 90
(3)
(b
2
--“2,
f#J>$
0 90
‘O’
where S(4) is the PSD (m*/cycle/m), b, is the wave number (cycle/m), A is the roughness coefficient (m3/cycle), and 4. is the discontinuity frequency = 1/(2n) (cycle/m).
Table 3. Maximum suspension forces and impact factors of an HS20-44 vehicle running at l/2 in-high step bump for different suspension damping conditions and vehicle speeds Undamped suspension Maximum static force (kips)
Steer axle
Tractor axle
Trailer axle
2.915
14.193
14.573
Vehicle speed (mph)
(4)
Maximum dynamic force (kips)
Damped suspension
Impact factor W)
Maximum dynamic force (kips)
Impact factor (%)
15 20 25 30 35 40 45
4.470 4.241 4.069 3.860 3.848 3.735 3.651
53.34 45.47 39.60 32.42 31.99 28.12 25.26
3.971 3.941 3.878 3.835 3.764 3.659 3.697
36.23 35.19 33.04 31.57 29.12 25.52 26.82
15 20 25 30 : 45
25.133 25.538 23.441 22.148 21.845 21.852 22.131
77.08 79.93 65.16 56.05 53.92 53.96 55.93
23.279 22.484 22.203 23.338 20.124 21.005 21.557
64.02 58.42 56.44 64.43 41.79 48.00 51.89
I5 20 25 30 35 40 45
23.463 22.878 22.966 22.257 21.677 21.712 22.614
61.01 56.99 57.59 52.73 48.75 48.99 55.18
23.218 23.218 22.908 22.816 22.347 33.351 23.012
59.32 59.32 57.19 56.57 53.34 53.37 57.91
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Table 4. Maximum tire forces and impact factors of an HS20-44 vehicle running at l/2 in-high step bump for different suspension damping conditions and vehicle speeds Undamped suspension Maximum static force (kips)
Steer axle
Tractor axle
Trailer axle
Maximum dynamic force (kips)
Vehicle speed (mph)
suspension Maximum dynamic force (kius)
Impact factor (%)
Impact factor (%)
3.995
15 20 25 30 35 40 45
6.891 6.524 6.482 6.458 6.501 6.405 6.426
72.49 63.13 62.25 61.65 62.72 60.32 60.84
6.518 6.488 6.499 6.470 6.455 6.358 6.476
63.15 62.40 62.69 61.96 61.57 59.16 62.09
15.994
15 20 25 30 3s 40 45
28.741 26.660 25.591 25.971 25.717 26.387 26.003
79.71 66.69 60.01 62.38 60.79 64.98 62.58
29.598 27.915 25.993 26.502 25.841 25.990 25.682
85.06 74.54 62.52 65.70 61.57 62.50 60.58
16.012
15 20 25 30 35 40 45
25.381 25.242 25.801 25.889 25.845 25.931 25.411
58.51 57.64 61.13 61.68 61.41 61.95 58.70
25.623 25.602 25.320 25.978 25.828 25.955 25.790
60.02 59.89 58.13 62.24 61.30 62.09 61.06
120 i? 0:
0
100
UNDAMPED SUSPENSION DAMPED SUSPCNSION CXPCROIENTU-:-IDATA
60 0
h-~.
0
“NDAYPCD SUSPCNSlDN DMPCD SUSPENSION CXPCRlYCNTAL DATA
d
60.
g 2
40.
z?i
20.
0
0 0 0
0
0
0
0 20
50
40
30
60
VEHICLESPEED (MPH)
100
-g
60
’ iz
60
0
t
20
30
40
50
VEHICLESPEED (MPH)
Fig. 10. The comparison of computed and experimental impact results for tire forces of the rear axle of an H20-44 vehicle running at 3/4 in-high step bump.
i?
10
Fig. 11. The comparison of computed and experimental impact results for tire forces of the steer axle of an HS20-44 vehicle running at l/2 in-high step bump.
UNDAMPED SUSPENSION DUPED SUSPENSION EXPERIMENTAL DATA
k-. -.
_----
- ---_ 8
20
30
I
40
I 50
VEHICLESPEED (MPH) Fig. 12. The comparison of computed and experimental impact results for the tire forces of the tractor axle of an HS20-44 vehicle running at l/2 in-high step bump.
20
30
40
VEHICLESPEED (MPH) Fig. 13. The comparison of computed and experimental impact results for the tire forces of the trailer axle of an HS20-44 vehicle running at l/2 in-high step bump.
Dynamic response of highway trucks
!c:,:t 0
WI
,.
.
.
64
128
192
I
256
3 2
1 -4.0 0
64
125
182
I 256
DISTANCE
DISTANCEALONGTHE ROAD(M) [ai *mt s&s
ALONGTHE ROAD(Id) (a) ni+t LLmz
E
2.0
z”
1.0
g
0.0
s
-1.0
2 -2.0 s\
gj m
256
0
D&k
DISTANCEALONGTHE ROAD(M) @a)Iam \ina Fig. f4. Vertical highway surface pro&s road.
1:::t.1 ALO: THE ROE (N) ib) Lett line
in a very good
Fig. 16, Vertical highway surface profiles in an average road.
The values of wi and w, varied from 1.36 to 2.28 [I2]. In order to simplify the description of road surface roughness, both wi and w, are assumed the value of two. Equations (3) and (4) are converted as follows:
It was found that the comparison between nume~cal and analytical PSDs agreed fairly well [9]. The random numbers which have approximate white noise properties were generated first [ 131.Then, these random numbers were passed through the first order recursive filter [14]. Finally, the output function will be the road surface roughness. The detail of the procedure has been discussed by Wang [lo]. In this study, the values of 5 x 10m6, 20 x 10m6, 80 x lo-‘* and 256 x lOA m*/cycle were used according to Intemational Organization for Standardization (ISO) specifications [15] as the roughness coefficient A for the classes of very good, good, average, and poor roads, respectively. The sample length was taken as 256m (839.9 ft) and 2048 (2”) data points were generated for this distance. The average vertical highway surface profiles of right and left lines from five simulations are shown in Figs 14-17 for very good, good, average, and poor roads respectively.
S(gl)=A
2
2.0
2 ii
1.0
s
0$ -2. 0
iz
0.0
s w
-1.0
5:
2 VI
-2.0 0
84
128
182
258
DISTANCEALONGTHE ROAD(M) ,a> Righr‘in* 5. SUMMARY
2
2
0
256
DIST:CE ALOZTHE ROE(M) (b, I&r line Fig, IS. Vertical highway surface profdes in a good road.
AND CONCLUS?ONS
According to the real H20-44 and HS20-44 trucks, two nonlinear vehicle models with seven and twelve degrees of freedom were developed and validated by the experimental data. Four different classes of road surface roughness were generated for very good, good, average, and poor roads. The maximum dynamic forces and entire force histories were recorded in 800-B simulation length when vehicle models with damped suspension system were running on the different classes of roads. Typical force histories of suspension and tire for H20-44 and HS20-44 vehicles
T. L. WANGet al.
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u
4.0
E E
2.0
6 3 0 E
-2.0
0.0
u" -4.0 iz 5 -6.0 VI 0
64
128
192
256
VI
Ol 1.2
2.2
3.2
SIMULATIONTIME (SEC)
DISTANCEALONGTHE ROAD(Id) (oi)HlqhtLine 52
5
6.0 ,
Fig. 20. The suspension force history of the tractor axle of an HS20-44 vehicle with damped suspension system running at 75 mph and average road surface condition.
-1
L
2 -6.0 3. 0 0-l
25R
DIST:CE ALOETHE (b)Left line
ROE(M)
Fig. 17. Vertical highway surface profiles in a poor road. 1.2
2.2
3.2
4.2
6.2
5.2
7.2
SIMULATIONTIME (SEC) Fig. 21. The tire force history of the tractor axle of an HS20-44 vehicle with damped suspension system running at 75 mph and average road surface condition.
O-0 VERYGOODROADSWRPACE A-.& GOODROAG SURFACE 0-o AVRRAGEROAD SURFACE o-----v
m
0.6
1.6
2.6
3.0
4.6
5.6
POOR ROM
SURFACE
6.6
SIMULATIONTIME (SEC) Fig. 18. The suspension force history of the rear axle of an H20-44 vehicle with damped suspension system running at 75 mph and average road surface condition.
0’
10
20
30
40
50
60
70
60
VEHICLESPEED (MPH) Fig. 22. Impact results of suspension forces for the front axle of an H20-44 vehicle with damped suspension system.
25,
I
140 -
z a 5 2 ?? 2cr
20 R 15 10
; E
5
2
120
O-0
d--a O--O o-----v
100. 60.
VERY GOOD ROAD SURFACE GOOD ROAD SURFACE AVERAGE ROAD SVRFACE POOR ROAD SURFACE ~c.p_.._---
v... -.._,v
60.
0 0.6
1.6
2.6
3.6
4.6
5.6
6.6
SIMULATIONTIME (SEC) Fig. 19. The tire force history of the rear axle of an H20-44 vehicle with damped suspension system running at 75 mph and average road surface condition.
t;
40.
d 2
20.
x--._s
.o/-,...
..‘.
o----o F:
.v...
p ,./’
,-I+-o-_-O
o/ e__-4-__‘L-----9----e---~---r~
0 10
20
30
40
50
80
70
60
VEHICLESPEED (MPH) Fig. 23. Impact results of suspension forces for the rear axle of an H20-44 vehicle with damped suspension system.
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Dynamic response of highway trucks
Table 5. Maximum suspension forces and impact factors of front axle of an H20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Road surface conditions Good Average
very good Maximum static force (kips)
3.704
VehiCle speed (mph) 15 25 35 45 55 65 75
Orips)
Impact factor (“/I
Maximum dynamic force (kips)
Impact factor (“/I
Maximum dynamic force (kipsl
4.008 3.996 4.947 4.064 4.054 4.102 4.084
8.20 7.87 9.26 9.71 9.43 10.73 10.24
4.146 4.166 4.183 4.199 4.296 4.370 4.368
11.92 12.46 12.93 13.36 15.99 17.98 17.91
4.444 4.421 4.847 4.950 4.954 5.170 5.660
Maximum dynamic fOW2
Poor
Impact
Maximum dynamic
Wl
(kips)
rmpact factor Wl
19.97 19.34 30.84 33.63 33.74 39.57 52.79
5.050 5.188 6.l65 6.244 6.182 5.739 5.995
36.32 40.06 66.44 68.57 66.89 54.94 61.85
factor
force
Table 6. Maximum suspension forces and impact factors of rear axle of an H20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Road curface conditions
very good
Maximum static
Vehicle
force fkiP@
speed (mph)
IJ.440
15 25 35 45 :: 75
Average
Good
Poor
&bsl
factor <“/of
Maximum dynamic force fkips)
Impact factor @f
Maximum dynamic force &ips)
Impact factor W-t
Maximum dynamic force Rips>
Impact factor (%I
17.274 17.275 17.561 17.518 17.435 17.463 17.570
28.53 28.53 30.67 30.34 29.72 29.93 30.73
17.804 17.840 17.976 18.003 18.057 18.290 18.859
32.47 32.74 33.75 33.95 34.36 36.08 40.32
18.679 20.203 20.241 21.442 21.336 21.161 21.264
38.98 50.32 50.60 59.54 58.75 57.45 58.21
22.553 21.271 23.304 24.976 25.586 27.657 25.771
67.81 58.26 73.39 85.83 90.37 105.78 91.75
Maximum dynamic force
Impact
Table 7, Maximum tire forces and impact factors of front axie of an H20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good Maximum static force (kipsl
5.260
Road surface conditions Good Average
Poor
Vehicle speed (mph)
Maximum dynamic force tkipsl
Impact factor WI
Maximum dynamic force
Impact factor (“Al
Maximum dynamic force Ikipsf
Impact factor (%f
Maximum dynamic force (kipsl
Impact factor WI
:: 35 45 55 65 75
5.462 5.516 5.525 5.588 5.627 3.636 5.643
4.87 3.83 5.04 6.23 6.98 7.15 7.29
5.660 5.823 5.940 5.978 6,199 6.183 6.261
10.70 7.69 12.92 13.64 17-67 17.54 19.03
6.230 6.442 7.183 7.480 7.729 9.046 9.384
22.47 18.43 36.55 42.20 46.94 71.97 78.40
7.544 8.412 9.863 9.960 9.71 I 9.6i8 10.265
43.42 59.92 87.51 89.36 84.61 82.85 95.16
YeBY GO00 RDAD SURFACE *--a GDOB ROAD SURFACE 4---o AYERAGS RDAD SURFACE (I -... P POOR ROAO SURFACE l . FXPERMXTAL DATA
O--O
.=--~..,_~_..~-~-
_,d..V
,’
Fig. 24. Impact results of tire forces for the front axle of an H20-44 vehicle with damped suspension system.
Fig. 25. The comparison of computed and experimental impact results of tire forces for the rear axle of an H20-44 vehicle with damped suspension system.
T. L.
1064 140
.
o-
et ai.
160
0 VERY DOOD RQAD SUfWACL
O--P
10
WANG
G ;
POOR ROAD SURFACE
20
30
50
40
60
70
o-0 A-.4 O---o v----v
140 120
50
10
WRY GOOD ROAD SURFACE Gooll ROAD SumwE AW$RAGE ROAD SURFACE POOR ROAD SURFACE
20
V~HIC~SP~~D(MPH)
30
40
50
80
70
80
VEHIC~SP~ED(MPH)
Fig. 26. Impact results of suspension forces for the steer axle of an HS20-44 vehicle with damped suspension system.
Fig. 27. Impact results of suspension forces for the tractor axle of an HS20-44 vehicle with damped suspension system.
Table 8. Maximum tire forces and impact factors of rear axle of an H20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good
static force (hips)
IS.040
Vehicle speed (mph) 1.5 25 35 45 55 65 75
Maximum dynamic force &ipsl
Impact factor (%I
15.799 15.967 16.018 16.066 16.138 16.306 16.227
6.50 6.82 7.30 8.42 7.89
Road surface conditions Good Average ~Maximum Maximum dynamic Impact dynamic Impact force force factor factor WI Chips) @ripsI (%I 16.407 16.783 17.083 17.306 17.592 17.681 18.543
9.09 11.59 13.58 15.07 16.97 17.56 23.29
17.673 19.408 19.906 21.421 20.759 21.596 22443
17.51 29.04 32.35 42.42 38.02 43.59 49.22
Poor Maximum dynamic
Impact
force
factor
(k&N
(“,I
22.165 20.809 23.165 26.091 25.358 25.894 26.853
47.37 38.36 54.02 73.47 68.60 72.17 78.55
Table 9. Maximum suspension forces and impact factors of steer axle of an HS20-44 vehicle with damned _ suspension _ for different
road surface
conditions
Road surface conditions Average Good
Very good Maximum static force
Vehicle speed
Maximum dynamic force
Impact factor
&ins)
(mph)
&ins)
2.915
15 25 35 45 55 65 75
3.350 3.373 3.360 3.433 3.379 3.385 3.411
Poor
Maximum dynamic
Impact
Maximum dynamic
Impact
Maximum dynamic
Impact
WI
force &ins)
factor (%)
force @ins)
factor W)
force (kins)
factor WJ)
14.93 15.72 15.28 17.78 15.92 16.12 17.03
3.479 3.551 3.677 3.683 3.510 3.576 3.593
19.35 21.81 26.15 26.33 20.41 22.67 23.24
3.680 3.881 4.045 4.063 4.875 4.504 4.365
26.25 33.15 38.76 39.37 67.24 54.52 49.76
4.625 4.505 5.028 5.318 6.069 5.508 N/A
58.67 54.53 72.50 82.42 108.20 88.95 WA
Table 10. Maximum suspension forces and impact factors of tractor axle of an HS20-44 vehicle with damned system for different
Very good Maximum static force (hips)
14.193
Vehicle tsm% 15 25 35 45 55 65 75
system
and vehicle speeds
road surface
conditions
suspension
and vehicle speeds
Road surface conditions Good Average
Poor
Maximum dynamic force (hips)
Impact factor Wl
Maximum dynamic force (hips)
Impact factor W)
Maximum dynamic force (hips)
Impact factor W)
19.083 19.142 19.499 19.252 19.221 19.024 19.033
34.45 34.87 37.38 35.65 35.42 34.04 34.11
19.763 19.353 20.000 20.222 20.311 20.773 20.087
39.25 36.36 40.91 42.48 43.11 46.36 41.53
20.798 20.719 20.63 I 22.300 23.371 22.340 22.211
46.54 45.98 45.36 57.12 64.67 57.40 56.50
Maximum dynamic
Impact
force @ins)
factor W)
22.856 23.435 25.662 28.500 28.324 26.323 WA
61.04 65.12 80.81 100.80 99.56 85.47 N/A
Dynamic response of highway trucks
01 10
1065
1
’
20
30
40
60
60
70
80
VEHICLESPEED (YPH)
VEHICLESPEED (MPH) Fig. 28. Impact results of suspension forces for the trailer axle of an HS20-44 vehicle with damped suspension system.
Fig. 29. Impact results of tire forces for the steer axle of an HS20-44 vehicle with damped suspension system.
Table 11. Maximum suspension forces and impact factors of trailer axle of an HS20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good Maximum static force otips)
14.573
Vehicle ?ms 15 25 35 45 55 65 75
Maximum dynamic force otips) 18.862 19.059 19.178 19.152 18.972 19.433 19.273
Impact factor (%) 29.43 30.79 31.60 31.42 30.18 33.35 32.25
Road surface conditions Average Good Maximum dynamic force (kips) 19.342 19.849 20.476 19.988 19.711 20.176 20.832
Impact factor (%) 32.73 36.20 40.51 37.16 35.26 38.45 42.95
Poor
Maximum dynamic force (kips)
Impact factor (%)
Maximum dynamic force (kips)
Impact factor
21.560 20.991 22.221 23.344 22.818 22.301 22.87 1
47.95 44.04 52.48 60.19 56.58 53.03 56.94
26.376 24.079 31.295 26.473 28.589 29.283 N/A
80.99 65.23 114.74 81.66 %.I7 100.94 N/A
W)
Table 12. Maximum tire forces and impact factors of steer axle of an HSZO-44 vehicle with damped suspension system for different road surface conditions and vehicle sneeds Very good Maximum static force (kips)
3.995
Road surface conditions Good Average
Vehicle speed (mph)
Maximum dynamic force (kips)
Impact factor (%)
Maximum dynamic force otips)
Impact factor (%)
Maximum dynamic force (kips)
15 25 35 45 55 65 75
4.294 4.365 4.348 4.422 4.475 4.521 4.562
7.49 9.25 8.84 10.68 12.00 13.17 14.18
4.474 4.612 4.912 4.845 4.960 5.035 5.033
11.99 15.43 22.96 21.28 24.15 26.02 25.99
4.893 5.314 5.443 6.074 6.703 6.023 6.822
Poor
factor (%)
Maximum dynamic force Orips)
Impact factor (%)
22.48 33.01 36.25 52.03 67.79 50.76 70.76
6.461 6.821. 7.040 8.774 8.455 8.572 N/A
61.73 70.74 76.22 119.62 111.64 114.56 N/A
Table 13. Maximum tire forces and impact factors of tractor axle of an HS20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good Maximum static force (kivs)
15.994
Vehicle
15 25 35 45 55 65 75
Road surface conditions Good Average
Poor
Maximum dynamic force (kius)
Impact factor (%)
Maximum dynamic force (kips)
Impact factor (%)
Maximum dynamic force (kips)
Impact factor (%)
Maximum dynamic force fkins)
17.804 17.874 18.377 18.613 18.892 18.402 18.441
11.32 11.76 14.90 16.38 18.12 15.06 15.30
19.507 19.524 20.991 21.919 21.552 21.730 20.608
21.97 22.08 31.25 37.05 34.76 35.87 28.85
21.910 21.549 22.724 25.667 26.469 25.530 25.746
36.99 34.74 42.08 60.48 65.50 59.63 60.98
24.960 29.212 28.563 39.058 33.769 29.674 N/A
Impact factor I%) 56.06 82.65 78.59 144.21 111.14 85.54
VA
o----o VRRY woo ROAO SuRFACL F
A-
100
-d
O----o v-.-.0
GOOD ROM SURFACE AVERAGE ROAD SURFACE POOR ROAU SURFACE
_-0-_---a--
___o----_&-
10
20
30
40
50
60
70
0
80
10
20
VEHICLE SPEED (MPH)
70 o---o
i? w
50
80
70
Fig. 31. Impact results of tire forces for the trailer axle of an HS20-44 vehicle with damped suspension system.
70 0-o A---A
40
VEHICLE SPEED (MPH)
Fig. 30, The comparison of computed and experimental impact results of tire forces for the tractor axle of an HS20-44 vehicle with damped suspension system.
60
30
SIBElI AXLE TRACTORAXLE TRAILER AXLE
G
0-o .%---A O--o
SD
SCEER AXLE TRACTOR AXLE TRAILER AXLE
507
01
12
14
18
,
18
20
22
24
’
28
28
’
12
30
14
16
18
20
22
24
26
28
30
L2 W')
Lz @T)
Fig. 32. Impact results of suspension forces in an HS20-44 vehicle with damped suspension system running at 55 mph and good road surface condition for different L, values.
Fig. 33. Impact results of tire forces in an HS20-44 vehicle with damped suspension system running at 55 mph and good road surface condition for different L, values.
running at 75 mph and average road surface condition are shown in Figs 18-21. A summary of the impact factors of suspension and tire forces for different road surface conditions and vehicle speeds is given in Tables 5-14 and ill~trat~ in Figs 22-31. The different distances between the tractor and trailer axles (L,) of an HS20-44 vehicle have also been studied. The results are shown in Table 15, Figs 32 and 33. The conclusions of this study are summarized as follows:
suspension and tire forces. However, the vehicle speeds influence the impact factors significantly in average and poor roads. 3. The impact factors of both suspension and tire forces obtained from the poor road are the highest among these four different road surface conditions for speed varied from 15 to 75 mph. The lowest impact factors are always found in the very good road. 4. In Tables 13 and 14, it may be seen that the impact factors of tire forces of tractor axle are much higher than those of trailer axle in HS20-44 vehicle. 5. When values of L, changed, the impact factors of all three axles of HS20-44 vehicle varied slightly. However, Figs 32 and 33 show that the highest
1. The impact factors of both suspension and tire forces increased with vehicle speed in most cases. 2. The impact factors were affected slightly by the vehicle speeds in very good and good roads for both Table 14. Maxims
tire forces and impact factors of traiier axle of an HS20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good
Maximum static force (kipsl
16.012
Vehicle speed (mph) 15 25 35 4.5 55 65 75
Maximum dynamic force (hips) 17.059 17.470 17.401 17.450 17.588 17.823 17.801
Impact factor (%l 6.54 9.10 8.67 8.98 9.84 11.31 11.17
Road surface conditions Good Average Maximum dynamic force Chips) 17.743 17.952 18.673 18.482 19.164 18.970 19.863
Impact factor (%l 10.81 12.11 16.61 15.42 19.68 18.47 24.05
Maximum dynamic force @ipsl 19.007 19.959 20.308 22.922 21.423 21.476 21.720
Impact factor W) 18.70 24.65 26.83 43.15 33.79 34.12 35.64
Poor Maximum dynamic force Wpsl 25.085 22.258 28.01 I 25.813 27.585 28.116 N/A
Impact factor Wl 56.66 39.00 74.93 61.21 72.27 . 75.59 N/A
Dynamic response of highway trucks
1067
Table 15. Maximum suspension forces, tire forces, and impact factors of an HS20-44 vehicle with damped suspension system running at 55 mph and good road surface condition for different L, values Tire
Suspension
JG* (ft)
Steer axle
14 16 18 20 22 24 26 28
Tractor axle
14 16 18 20 22 24 26 28
Trailer axle
14 16 18 20 22 24 26 28
Maximum static force (kips)
2.915
14.193
14.573
Maximum dynamic force (kips)
Impact factor (%)
3.510 3.510 3.548 3.574 3.501 3.506 3.541 3.539
20.41 20.40 21.72 22.61 20.11 20.29 21.48 21.40
20.311 20.648 20.639 19.531 20.120 20.578 20.070 19.904
43.11 45.48 45.42 37.61 41.76 44.99 41.41 40.24
19.711 19.768 19.754 19.613 19.746 19.788 19.770 19.786
35.26 35.65 35.56 34.58 35.50 35.79 35.66 35.77
Maximum static force (kips)
3.995
15.994
16.012
Maximum dynamic force (kips)
Impact factor (%)
4.960 4.960 4.861 4.870 4.821 4.867 5.007 5.026
24.15 24.15 21.68 21.90 20.67 21.84 25.33 25.80
21.552 21.744 21.323 20.332 20.957 21.181 21.955 21.093
34.76 35.96 33.32 27.13 31.03 32.44 37.28 31.89
19.164 19.019 18.929 19.097 18.924 18.869 19.105 19.014
19.68 18.78 18.21 19.26 18.18 17.84 19.32 18.74
*L2 is the distance between the tractor and trailer axles. impact factors were obtained when L, = 14-16 ft and 26-28 ft for both suspension and tire forces. 6. Some experimental data obtained by Whittemore et al. [6] were used to compare with computed data. A comparison of computed and experimental impact results for tire forces is presented in Figs 25 and 30. It can be seen that the computed impact values agree very well with the experimental data. REFERENCES
1. S. J. Fenves, A. S. Veletsos and C. P. Siess, Dynamic studies of bridge on the AASHO road test. Highway Research Board, Report 71, National Academy of Scienses, Washington, DC (1962). 2. S. J. Fenves, A. S. Veletsos and C. P. Siess, Dynamic studies of the AASHO road test bridge. Hiahwav Research Board, Report 73, National Academy of Sciences, Washington, DC (1962). 3. S. Levy and J. P. D. Wilkinson, The Component Element Merhod in Dynamic. McGraw-Hill, New York (1976). 4. G. R. Potts and H. S. Walker, Nonlinear truck ride analysis. J. Engng for Industry, Trans. ASME, May, 597-602 (1974). 5. A. S. Veletsos and T. Huang, Analysis of dynamic response of highway bridges. J. Engng Mech. Div., AXE %, 593620 (1970). 6. A. P. Whittemom, J. R. Wiley, P. C. Schultz and D. E. Pollock, Dynamic pavement loads of heavy highway
10. 11.
12. 13.
14. 15.
vehicles. National Cooperative Highway Research Program Report, Washington, DC (1970). Standard Specifications for Highway Bridges, 14th Edn. American Association of State Highway and Transportation Officials, Washington, DC (1989). T. Huang, Dynamic response of three-span continuous highway bridges. Ph.D. dissertation, University of Illinois, Urbana, IL (1960). T. L. Wang and D. Z. Huang, Computer modeling analysis in bridge evaluation. Final research report prepared for Florida Department of Transportation under Contract No. C-3394 (WPI-0510542), Tallahassee, FL (1991). T. L. Wang, Ramp/bridge interface in railway prestressed concrete bridges. J. Struct. Engng, AXE 116, 1618-1659 (1990). T. L. Wang, V. K. Garg and K. H. Chu, Railway bridge/vehicle interaction studies with a new vehicle model. J. Struct. Engng, AXE 117, 2099-2116 (1991). C. J. Dodds and J. D. Robson, The description of road surface roughness. J. Sound Vibr. 31, 175-183 (1973). J. Moshman, Random number generation. In Mathematical Methods for Digital Computers (Edited by A. Ralston and H. S. Wilf), Vol. II, Chap. 12, pp. 249-263. John Wiley, New York (1967). R. K. Otnes and L. Enochson, Digital Time Series Analysis. John Wiley, New York (1972). C. J. Dodds, BSI proposals for generalized terrain dynamic inputs to vehicles. ISO/TC/l08/WG9, Document No. 5, International Organization for Standardization (1972).
Pergamon
DYNAMIC RESPONSE OF HIGHWAY TRUCKS DUE TO ROAD SURFACE ROUGHNESS T. L. WANG,? M. SHAHAWY$ and D. Z. HUANGt tDepartment
of Civil and Environmental Engineering, Florida International University, Miami, FL 33199, U.S.A. $Structures Research and Testing Center, Florida Department of Transportation, Tallahassee, FL 32310, U.S.A. (Received 1 April 1992)
Alastrati-Vehicle characteristics, vehicle speed and road surface roughness are major factors influencing bridge dynamic response.. In order to improve the previous vehicle model studies, vehicle models with seven or twelve degrees of freedom were developed for H20-44 and HS20-44 trucks, respectively. Vehicle models were validated by comparisons with the real truck dynamic systems. The road surface roughness was generated from power spectral density (F’SD) functions for very good, good, average, and poor roads. The impact factors of suspension and tire forces were obtained for vehicle models running on different classes of roads at various speeds. A comparison of computed and experimental impact results was also made.
1. INTRODUCTION
Vehicle characteristics, vehicle speed and road surface roughness are some of the major factors that influence the dynamic response of a bridge due to moving
loads. In reality, a truck is a very complex mechanical system because of its suspension. Some assumptions need to be made in order to simplify the vehicle characteristics in mathematical modeling analysis. The dynamic analysis of highway vehicles has been studied since the middle of this century. Brief reviews of the literature can be found in [l-6]. Most of the previous studies have assumed that (1) the vehicle frames are rigid, (2) the interleaf friction forces are considered in a suspension system, (3) spring forces and damper forces are proportional to displacements and a single point. However, all vehicle models were limited to pitch mode vibration and road surface profiles were obtained from field measurement in most of these studies. Even though Whittemore et al. [6] used frequency domain prediction techniques to simulate pavement load, the techniques were established only for linear systems excited by stationary random inputs. In this study, the numerical road surface roughness spectrum is generated by using the random number based on the power spectrum density functions. Vehicle nonlinearity can be admitted when the generated road surface roughness is treated as an input function directly. In addition, the new vehicle models will include the roll vibration. 2.
VEHICLE MODELS
H20-44 and HS20-44 trucks are two major design vehicles in the American Association of State Highway and Transportation Oflicials (AASHTO)
Specification [7l. Two nonlinear vehicle models with seven and twelve degrees of freedom were developed according to the H20-44 and HS20-44 trucks, respectively. Figures 1 and 3 illustrate the side and front views of the H20-44 vehicle model. Three rigid masses represent the truck, front wheel/axle set, and rear wheel/axle set, respectively. In the model, the truck was assigned three degrees of freedom, corresponding to the vertical displacement (JJ), rotation about the transverse axis (pitch or O), and rotation about the longitudinal axis (roll or 4). Each wheel/axle set is provided with two degrees of freedom in the vertical and roll directions. The total degrees of freedom in the model are seven. Similarly, another vehicle model (refer to Figs 2 and 3) with twelve degrees of freedom was developed to represent an HS20-44 truck, consisting of five rigid masses as tractor, semi-trailer, steer wheel/axle set, tractor wheel/axle set, and trailer wheel/axle set. Tractor and semi-trailer were assigned three degrees of freedom (y, 0, and 4) individually. Two degrees of freedom (y and 0) were assigned for each wheel-axle set. The tractor and semi-trailer were interconnected at the pivot point (so-called fifth wheel point, see Fig. 2). Suspension force consists of the linear elastic spring force and the constant interleaf friction force [8]. The load-displacement relationships for friction force, suspension spring force, and combination of these two forces are shown in Fig. 4. The tire springs are assumed to be linear. Since the truck is a complex physical system, certain assumptions were made to simplify the model. These assumptions are as follows: 1. The vehicle runs at a constant speed.
1055
1056
T. L.
WANG et al.
I-
-1
Fig. 1. Side view of an H20-44 vehicle model. 2. All components move with the same velocity in the longitudinal direction. 3. Provision is made in the model for wheel lift. Under this condition, the vertical tire stiffnesses are taken as zero. 4. Each tire contacts the road at a single point. 5. Force inputs are limited to the vertical direction. 6. In suspension systems, damping elements were assumed to be linear and to be of the viscous type. Damper force is proportional to the velocity. Ten per cent of the critical damping value was used for damping coefficient [6]. In the tires, the damping forces were neglected.
and relative displacements, whereas the dissipation energy, D = ZDi,of the system is obtained from the damping forces. The total kinetic energy, T = Xl;, of the system is calculated using the mass, mass moment of inertia, and translational as well as rotational velocities, of the system components. The moment of inertia of all components is assumed to be constant and the weight of each component is considered as the external force on that component. The equations of motion of the system are derived, using Lagrange’s formulation, as follows:
8%
_dT+dv+aD=o,
The total potential energy, V = Xvi, of the system is then computed from the spring stiffnesses ‘6
Ir
I
N
k
a4i
Is
4 _
‘I
I_
15 I I
‘2
*1-
\
1
I-
t-
‘4
Fig. 2. Side view of an HSZO-44vehicle model.
$3+
a4
(1)
Dynamic response of highway trucks
1057 18”
tr
-I
c
0t1
f
h
YII
Fig. 5. Side view of step bump used in vehicle validation.
3. VEHICLE MODEL VALIDATION
d.
Fig. 3. Front view of H20-44 and HS20-44 vehicle models.
where qi and di are the generalized displacements and velocities. Details of derivation are presented in 191. The equations of motion were solved by using a fourth-order Runge-Kutta scheme [lo, 111, with an integration time step of 0.005 sec. Such a small time step was necessary to avoid numerical instability. The real percentage of impact acquired from the study is defined as
sm 1
4-
Imp(%) =
[
1 x 100%
(2)
in which R, and R, are the absolute maximum responses for dynamic and static studies respectively.
(a) Friction force
In order to check that the mathematical vehicle models properly simulate a real truck dynamic system, it is necessary to validate the models. The 3/4 in-high x 18 in-long and l/2 in-high x 18 in-long step bumps were taken to generate a vertical input for H20-44 and HS20-44 vehicle models respectively, as shown in Fig. 5. The appropriate data used in dynamic simulation of the models was adopted from [8] and is given in [9]. The experimental data was available in [6]. Both damped and undamped suspensions were considered, but tire damping was neglected in this study. Typical tire force histories for H20-44 and HS20-44 vehicle models are shown in Figs 6-9. Impact factors of suspension and tire forces for wide range of vehicle speeds are given in Tables 1 and 2 for H20-44 and Tables 3 and 4 for HS20-44. It may be seen that the impact factors of suspension forces were reduced when a damped suspension system was considered in most cases. However, for tire forces, the impact factors did not change significantly between damped and undamped suspension systems. The comparisons of computed
(b) Suspension spring force 6
(c) Combination of friction and suspension spring forces Fig. 4. The relationship between the force and displacement in the suspension system.
1058
T. L.
WANG et al.
I
0’
0.3
0.6
1.2
0.9
1.5
0’ 0.3
1.6
0.6
SIMULATION TIME (SEC)
vehicle with undamped suspension system running at 3/4 inhigh step bump and 55 mph.
1.3
1.6
2.3
2.6
3.3
I 1.6
1.5
1.2
SIMULATION TIME (SEC)
Fig. 6. The tire force history of the rear axle of an H20-44
01 0.6
0.9
3.6
Fig. 7. The tire force history of the rear axle of an H20-44 vehicle with damped suspension system running at 3/4 inhigh step bump and 55 mph.
0’ 0.6
4.3
SIMULATION TIME (SEC)
I
1.3
1.6
2.3
2.6
3.3
3.6
4.3
SIMULATION TIME (SEC)
Fig. 8. The tire force history of the tractor axle of an HS20-44 vehicle with undamped suspension system running at l/2 in-high step bump and 35 mph.
Fig. 9. The tire force history of the tractor axle of an HS20-44 vehicle with damped suspension system running at l/2 in-high step bump and 35 mph.
and experimental impact results of tire forces in different axles are illustrated in Figs 10-13. The agreement between computed and experimental results was found to be very good. The computed impact factors of tire forces almost cover all experimental results.
4. ROAD SURFACE ROUGHNESS
The typical road surface may be described by a periodically modulated random process. The power spectral density (PSD) is a useful tool for analyzing the periodically modulated random process. The PSD
Table 1. Maximum suspension forces and impact factors of an H20-44 vehicle running at 3/4 in-high step bump for different suspension damping conditions and vehicle soeeds Damped suspension
Undamped suspension Maximum static force &ins)
Vehicle speed (mph) 15
Front axle
Rear axle
3.704
13.440
Maximum dynamic force tkins)
Impact factor (%1
Maximum dynamic force (kit&
Impact factor f%)
20 25 30 35 40 45 SO 55
5.361 5.074 4.877 4.721 4.648 4.513 4.506 4.444 4.324
44.74 36.99 31.67 27.46 25.49 21.84 21.65 19.98 16.74
5.164 5.048 4.865 4.705 4.624 4.516 4.494 4.452 4.306
39.42 36.29 31.34 27.02 24.84 21.92 21.33 20.19 16.25
15 20 25 30 35 40 45 SO 5s
24.158 24.097 24.499 24.321 24.449 23.438 22.193 22.638 22.196
79.7s 79.29 82.28 80.96 81.91 74.39 65.13 68.42 65.15
24.163 23.990 24.051 24.129 24.489 23.405 22.093 22.622 22.189
79.78 78.50 78.95 79.53 82.21 74.14 64.38 68.32 65.10
Dynamic response of bigbway trucks
1059
Table 2. Maximum tire forces and impact factors of an H20-44 vehicle running at 3/4 in-high step bump for different suspension damping conditions and vehicle speeds Damped suspension
Undamped suspension Maximum static force
(kips)
Front axle
5.260
Rear axle
functions developed
for highway
15.040
surface roughness
by Dodds
Maximum dynamic force
Impact factor
Maximum dynamic force
Impact factor
6ph)
(kips)
(%)
Wps)
W)
15
20 25 30 35 40 45 50 55
9.313 8.926 8.946 8.888 8.950 8.942 8.892 8.964 8.952
78.19 69.70 70.08 68.97 70.15 70.00 69.05 70.42 70.19
8.882 8.882 8.940 8.878 8.918 8.940 8.893 8.965 8.961
68.86 68.86 69.96 68.78 69.54 69.96 69.07 70.44 70.36
15 20 25 30 35 40 45 50 55
29.330 29.480 28.874 29.758 29.107 28.392 29.585 29.310 29.156
95.01 96.01 91.98 97.86 93.53 88.78 96.71 94.88 93.86
29.714 29.644 28.614 29.704 29.158 28.626 29.689 29.200 28.827
97.57 97.10 90.25 97.50 93.87 90.33 97.40 94.15 91.67
Vehicle speed
have been
S(f#l)=A
and Robson [123. They are
shown as
S(r$)=A
02 --, 90
(3)
(b
2
--“2,
f#J>$
0 90
‘O’
where S(4) is the PSD (m*/cycle/m), b, is the wave number (cycle/m), A is the roughness coefficient (m3/cycle), and 4. is the discontinuity frequency = 1/(2n) (cycle/m).
Table 3. Maximum suspension forces and impact factors of an HS20-44 vehicle running at l/2 in-high step bump for different suspension damping conditions and vehicle speeds Undamped suspension Maximum static force (kips)
Steer axle
Tractor axle
Trailer axle
2.915
14.193
14.573
Vehicle speed (mph)
(4)
Maximum dynamic force (kips)
Damped suspension
Impact factor W)
Maximum dynamic force (kips)
Impact factor (%)
15 20 25 30 35 40 45
4.470 4.241 4.069 3.860 3.848 3.735 3.651
53.34 45.47 39.60 32.42 31.99 28.12 25.26
3.971 3.941 3.878 3.835 3.764 3.659 3.697
36.23 35.19 33.04 31.57 29.12 25.52 26.82
15 20 25 30 : 45
25.133 25.538 23.441 22.148 21.845 21.852 22.131
77.08 79.93 65.16 56.05 53.92 53.96 55.93
23.279 22.484 22.203 23.338 20.124 21.005 21.557
64.02 58.42 56.44 64.43 41.79 48.00 51.89
I5 20 25 30 35 40 45
23.463 22.878 22.966 22.257 21.677 21.712 22.614
61.01 56.99 57.59 52.73 48.75 48.99 55.18
23.218 23.218 22.908 22.816 22.347 33.351 23.012
59.32 59.32 57.19 56.57 53.34 53.37 57.91
T. L. WANG et al.
1060
Table 4. Maximum tire forces and impact factors of an HS20-44 vehicle running at l/2 in-high step bump for different suspension damping conditions and vehicle speeds Undamped suspension Maximum static force (kips)
Steer axle
Tractor axle
Trailer axle
Maximum dynamic force (kips)
Vehicle speed (mph)
suspension Maximum dynamic force (kius)
Impact factor (%)
Impact factor (%)
3.995
15 20 25 30 35 40 45
6.891 6.524 6.482 6.458 6.501 6.405 6.426
72.49 63.13 62.25 61.65 62.72 60.32 60.84
6.518 6.488 6.499 6.470 6.455 6.358 6.476
63.15 62.40 62.69 61.96 61.57 59.16 62.09
15.994
15 20 25 30 3s 40 45
28.741 26.660 25.591 25.971 25.717 26.387 26.003
79.71 66.69 60.01 62.38 60.79 64.98 62.58
29.598 27.915 25.993 26.502 25.841 25.990 25.682
85.06 74.54 62.52 65.70 61.57 62.50 60.58
16.012
15 20 25 30 35 40 45
25.381 25.242 25.801 25.889 25.845 25.931 25.411
58.51 57.64 61.13 61.68 61.41 61.95 58.70
25.623 25.602 25.320 25.978 25.828 25.955 25.790
60.02 59.89 58.13 62.24 61.30 62.09 61.06
120 i? 0:
0
100
UNDAMPED SUSPENSION DAMPED SUSPCNSION CXPCROIENTU-:-IDATA
60 0
h-~.
0
“NDAYPCD SUSPCNSlDN DMPCD SUSPENSION CXPCRlYCNTAL DATA
d
60.
g 2
40.
z?i
20.
0
0 0 0
0
0
0
0 20
50
40
30
60
VEHICLESPEED (MPH)
100
-g
60
’ iz
60
0
t
20
30
40
50
VEHICLESPEED (MPH)
Fig. 10. The comparison of computed and experimental impact results for tire forces of the rear axle of an H20-44 vehicle running at 3/4 in-high step bump.
i?
10
Fig. 11. The comparison of computed and experimental impact results for tire forces of the steer axle of an HS20-44 vehicle running at l/2 in-high step bump.
UNDAMPED SUSPENSION DUPED SUSPENSION EXPERIMENTAL DATA
k-. -.
_----
- ---_ 8
20
30
I
40
I 50
VEHICLESPEED (MPH) Fig. 12. The comparison of computed and experimental impact results for the tire forces of the tractor axle of an HS20-44 vehicle running at l/2 in-high step bump.
20
30
40
VEHICLESPEED (MPH) Fig. 13. The comparison of computed and experimental impact results for the tire forces of the trailer axle of an HS20-44 vehicle running at l/2 in-high step bump.
Dynamic response of highway trucks
!c:,:t 0
WI
,.
.
.
64
128
192
I
256
3 2
1 -4.0 0
64
125
182
I 256
DISTANCE
DISTANCEALONGTHE ROAD(M) [ai *mt s&s
ALONGTHE ROAD(Id) (a) ni+t LLmz
E
2.0
z”
1.0
g
0.0
s
-1.0
2 -2.0 s\
gj m
256
0
D&k
DISTANCEALONGTHE ROAD(M) @a)Iam \ina Fig. f4. Vertical highway surface pro&s road.
1:::t.1 ALO: THE ROE (N) ib) Lett line
in a very good
Fig. 16, Vertical highway surface profiles in an average road.
The values of wi and w, varied from 1.36 to 2.28 [I2]. In order to simplify the description of road surface roughness, both wi and w, are assumed the value of two. Equations (3) and (4) are converted as follows:
It was found that the comparison between nume~cal and analytical PSDs agreed fairly well [9]. The random numbers which have approximate white noise properties were generated first [ 131.Then, these random numbers were passed through the first order recursive filter [14]. Finally, the output function will be the road surface roughness. The detail of the procedure has been discussed by Wang [lo]. In this study, the values of 5 x 10m6, 20 x 10m6, 80 x lo-‘* and 256 x lOA m*/cycle were used according to Intemational Organization for Standardization (ISO) specifications [15] as the roughness coefficient A for the classes of very good, good, average, and poor roads, respectively. The sample length was taken as 256m (839.9 ft) and 2048 (2”) data points were generated for this distance. The average vertical highway surface profiles of right and left lines from five simulations are shown in Figs 14-17 for very good, good, average, and poor roads respectively.
S(gl)=A
2
2.0
2 ii
1.0
s
0$ -2. 0
iz
0.0
s w
-1.0
5:
2 VI
-2.0 0
84
128
182
258
DISTANCEALONGTHE ROAD(M) ,a> Righr‘in* 5. SUMMARY
2
2
0
256
DIST:CE ALOZTHE ROE(M) (b, I&r line Fig, IS. Vertical highway surface profdes in a good road.
AND CONCLUS?ONS
According to the real H20-44 and HS20-44 trucks, two nonlinear vehicle models with seven and twelve degrees of freedom were developed and validated by the experimental data. Four different classes of road surface roughness were generated for very good, good, average, and poor roads. The maximum dynamic forces and entire force histories were recorded in 800-B simulation length when vehicle models with damped suspension system were running on the different classes of roads. Typical force histories of suspension and tire for H20-44 and HS20-44 vehicles
T. L. WANGet al.
1062
u
4.0
E E
2.0
6 3 0 E
-2.0
0.0
u" -4.0 iz 5 -6.0 VI 0
64
128
192
256
VI
Ol 1.2
2.2
3.2
SIMULATIONTIME (SEC)
DISTANCEALONGTHE ROAD(Id) (oi)HlqhtLine 52
5
6.0 ,
Fig. 20. The suspension force history of the tractor axle of an HS20-44 vehicle with damped suspension system running at 75 mph and average road surface condition.
-1
L
2 -6.0 3. 0 0-l
25R
DIST:CE ALOETHE (b)Left line
ROE(M)
Fig. 17. Vertical highway surface profiles in a poor road. 1.2
2.2
3.2
4.2
6.2
5.2
7.2
SIMULATIONTIME (SEC) Fig. 21. The tire force history of the tractor axle of an HS20-44 vehicle with damped suspension system running at 75 mph and average road surface condition.
O-0 VERYGOODROADSWRPACE A-.& GOODROAG SURFACE 0-o AVRRAGEROAD SURFACE o-----v
m
0.6
1.6
2.6
3.0
4.6
5.6
POOR ROM
SURFACE
6.6
SIMULATIONTIME (SEC) Fig. 18. The suspension force history of the rear axle of an H20-44 vehicle with damped suspension system running at 75 mph and average road surface condition.
0’
10
20
30
40
50
60
70
60
VEHICLESPEED (MPH) Fig. 22. Impact results of suspension forces for the front axle of an H20-44 vehicle with damped suspension system.
25,
I
140 -
z a 5 2 ?? 2cr
20 R 15 10
; E
5
2
120
O-0
d--a O--O o-----v
100. 60.
VERY GOOD ROAD SURFACE GOOD ROAD SURFACE AVERAGE ROAD SVRFACE POOR ROAD SURFACE ~c.p_.._---
v... -.._,v
60.
0 0.6
1.6
2.6
3.6
4.6
5.6
6.6
SIMULATIONTIME (SEC) Fig. 19. The tire force history of the rear axle of an H20-44 vehicle with damped suspension system running at 75 mph and average road surface condition.
t;
40.
d 2
20.
x--._s
.o/-,...
..‘.
o----o F:
.v...
p ,./’
,-I+-o-_-O
o/ e__-4-__‘L-----9----e---~---r~
0 10
20
30
40
50
80
70
60
VEHICLESPEED (MPH) Fig. 23. Impact results of suspension forces for the rear axle of an H20-44 vehicle with damped suspension system.
1063
Dynamic response of highway trucks
Table 5. Maximum suspension forces and impact factors of front axle of an H20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Road surface conditions Good Average
very good Maximum static force (kips)
3.704
VehiCle speed (mph) 15 25 35 45 55 65 75
Orips)
Impact factor (“/I
Maximum dynamic force (kips)
Impact factor (“/I
Maximum dynamic force (kipsl
4.008 3.996 4.947 4.064 4.054 4.102 4.084
8.20 7.87 9.26 9.71 9.43 10.73 10.24
4.146 4.166 4.183 4.199 4.296 4.370 4.368
11.92 12.46 12.93 13.36 15.99 17.98 17.91
4.444 4.421 4.847 4.950 4.954 5.170 5.660
Maximum dynamic fOW2
Poor
Impact
Maximum dynamic
Wl
(kips)
rmpact factor Wl
19.97 19.34 30.84 33.63 33.74 39.57 52.79
5.050 5.188 6.l65 6.244 6.182 5.739 5.995
36.32 40.06 66.44 68.57 66.89 54.94 61.85
factor
force
Table 6. Maximum suspension forces and impact factors of rear axle of an H20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Road curface conditions
very good
Maximum static
Vehicle
force fkiP@
speed (mph)
IJ.440
15 25 35 45 :: 75
Average
Good
Poor
&bsl
factor <“/of
Maximum dynamic force fkips)
Impact factor @f
Maximum dynamic force &ips)
Impact factor W-t
Maximum dynamic force Rips>
Impact factor (%I
17.274 17.275 17.561 17.518 17.435 17.463 17.570
28.53 28.53 30.67 30.34 29.72 29.93 30.73
17.804 17.840 17.976 18.003 18.057 18.290 18.859
32.47 32.74 33.75 33.95 34.36 36.08 40.32
18.679 20.203 20.241 21.442 21.336 21.161 21.264
38.98 50.32 50.60 59.54 58.75 57.45 58.21
22.553 21.271 23.304 24.976 25.586 27.657 25.771
67.81 58.26 73.39 85.83 90.37 105.78 91.75
Maximum dynamic force
Impact
Table 7, Maximum tire forces and impact factors of front axie of an H20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good Maximum static force (kipsl
5.260
Road surface conditions Good Average
Poor
Vehicle speed (mph)
Maximum dynamic force tkipsl
Impact factor WI
Maximum dynamic force
Impact factor (“Al
Maximum dynamic force Ikipsf
Impact factor (%f
Maximum dynamic force (kipsl
Impact factor WI
:: 35 45 55 65 75
5.462 5.516 5.525 5.588 5.627 3.636 5.643
4.87 3.83 5.04 6.23 6.98 7.15 7.29
5.660 5.823 5.940 5.978 6,199 6.183 6.261
10.70 7.69 12.92 13.64 17-67 17.54 19.03
6.230 6.442 7.183 7.480 7.729 9.046 9.384
22.47 18.43 36.55 42.20 46.94 71.97 78.40
7.544 8.412 9.863 9.960 9.71 I 9.6i8 10.265
43.42 59.92 87.51 89.36 84.61 82.85 95.16
YeBY GO00 RDAD SURFACE *--a GDOB ROAD SURFACE 4---o AYERAGS RDAD SURFACE (I -... P POOR ROAO SURFACE l . FXPERMXTAL DATA
O--O
.=--~..,_~_..~-~-
_,d..V
,’
Fig. 24. Impact results of tire forces for the front axle of an H20-44 vehicle with damped suspension system.
Fig. 25. The comparison of computed and experimental impact results of tire forces for the rear axle of an H20-44 vehicle with damped suspension system.
T. L.
1064 140
.
o-
et ai.
160
0 VERY DOOD RQAD SUfWACL
O--P
10
WANG
G ;
POOR ROAD SURFACE
20
30
50
40
60
70
o-0 A-.4 O---o v----v
140 120
50
10
WRY GOOD ROAD SURFACE Gooll ROAD SumwE AW$RAGE ROAD SURFACE POOR ROAD SURFACE
20
V~HIC~SP~~D(MPH)
30
40
50
80
70
80
VEHIC~SP~ED(MPH)
Fig. 26. Impact results of suspension forces for the steer axle of an HS20-44 vehicle with damped suspension system.
Fig. 27. Impact results of suspension forces for the tractor axle of an HS20-44 vehicle with damped suspension system.
Table 8. Maximum tire forces and impact factors of rear axle of an H20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good
static force (hips)
IS.040
Vehicle speed (mph) 1.5 25 35 45 55 65 75
Maximum dynamic force &ipsl
Impact factor (%I
15.799 15.967 16.018 16.066 16.138 16.306 16.227
6.50 6.82 7.30 8.42 7.89
Road surface conditions Good Average ~Maximum Maximum dynamic Impact dynamic Impact force force factor factor WI Chips) @ripsI (%I 16.407 16.783 17.083 17.306 17.592 17.681 18.543
9.09 11.59 13.58 15.07 16.97 17.56 23.29
17.673 19.408 19.906 21.421 20.759 21.596 22443
17.51 29.04 32.35 42.42 38.02 43.59 49.22
Poor Maximum dynamic
Impact
force
factor
(k&N
(“,I
22.165 20.809 23.165 26.091 25.358 25.894 26.853
47.37 38.36 54.02 73.47 68.60 72.17 78.55
Table 9. Maximum suspension forces and impact factors of steer axle of an HS20-44 vehicle with damned _ suspension _ for different
road surface
conditions
Road surface conditions Average Good
Very good Maximum static force
Vehicle speed
Maximum dynamic force
Impact factor
&ins)
(mph)
&ins)
2.915
15 25 35 45 55 65 75
3.350 3.373 3.360 3.433 3.379 3.385 3.411
Poor
Maximum dynamic
Impact
Maximum dynamic
Impact
Maximum dynamic
Impact
WI
force &ins)
factor (%)
force @ins)
factor W)
force (kins)
factor WJ)
14.93 15.72 15.28 17.78 15.92 16.12 17.03
3.479 3.551 3.677 3.683 3.510 3.576 3.593
19.35 21.81 26.15 26.33 20.41 22.67 23.24
3.680 3.881 4.045 4.063 4.875 4.504 4.365
26.25 33.15 38.76 39.37 67.24 54.52 49.76
4.625 4.505 5.028 5.318 6.069 5.508 N/A
58.67 54.53 72.50 82.42 108.20 88.95 WA
Table 10. Maximum suspension forces and impact factors of tractor axle of an HS20-44 vehicle with damned system for different
Very good Maximum static force (hips)
14.193
Vehicle tsm% 15 25 35 45 55 65 75
system
and vehicle speeds
road surface
conditions
suspension
and vehicle speeds
Road surface conditions Good Average
Poor
Maximum dynamic force (hips)
Impact factor Wl
Maximum dynamic force (hips)
Impact factor W)
Maximum dynamic force (hips)
Impact factor W)
19.083 19.142 19.499 19.252 19.221 19.024 19.033
34.45 34.87 37.38 35.65 35.42 34.04 34.11
19.763 19.353 20.000 20.222 20.311 20.773 20.087
39.25 36.36 40.91 42.48 43.11 46.36 41.53
20.798 20.719 20.63 I 22.300 23.371 22.340 22.211
46.54 45.98 45.36 57.12 64.67 57.40 56.50
Maximum dynamic
Impact
force @ins)
factor W)
22.856 23.435 25.662 28.500 28.324 26.323 WA
61.04 65.12 80.81 100.80 99.56 85.47 N/A
Dynamic response of highway trucks
01 10
1065
1
’
20
30
40
60
60
70
80
VEHICLESPEED (YPH)
VEHICLESPEED (MPH) Fig. 28. Impact results of suspension forces for the trailer axle of an HS20-44 vehicle with damped suspension system.
Fig. 29. Impact results of tire forces for the steer axle of an HS20-44 vehicle with damped suspension system.
Table 11. Maximum suspension forces and impact factors of trailer axle of an HS20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good Maximum static force otips)
14.573
Vehicle ?ms 15 25 35 45 55 65 75
Maximum dynamic force otips) 18.862 19.059 19.178 19.152 18.972 19.433 19.273
Impact factor (%) 29.43 30.79 31.60 31.42 30.18 33.35 32.25
Road surface conditions Average Good Maximum dynamic force (kips) 19.342 19.849 20.476 19.988 19.711 20.176 20.832
Impact factor (%) 32.73 36.20 40.51 37.16 35.26 38.45 42.95
Poor
Maximum dynamic force (kips)
Impact factor (%)
Maximum dynamic force (kips)
Impact factor
21.560 20.991 22.221 23.344 22.818 22.301 22.87 1
47.95 44.04 52.48 60.19 56.58 53.03 56.94
26.376 24.079 31.295 26.473 28.589 29.283 N/A
80.99 65.23 114.74 81.66 %.I7 100.94 N/A
W)
Table 12. Maximum tire forces and impact factors of steer axle of an HSZO-44 vehicle with damped suspension system for different road surface conditions and vehicle sneeds Very good Maximum static force (kips)
3.995
Road surface conditions Good Average
Vehicle speed (mph)
Maximum dynamic force (kips)
Impact factor (%)
Maximum dynamic force otips)
Impact factor (%)
Maximum dynamic force (kips)
15 25 35 45 55 65 75
4.294 4.365 4.348 4.422 4.475 4.521 4.562
7.49 9.25 8.84 10.68 12.00 13.17 14.18
4.474 4.612 4.912 4.845 4.960 5.035 5.033
11.99 15.43 22.96 21.28 24.15 26.02 25.99
4.893 5.314 5.443 6.074 6.703 6.023 6.822
Poor
factor (%)
Maximum dynamic force Orips)
Impact factor (%)
22.48 33.01 36.25 52.03 67.79 50.76 70.76
6.461 6.821. 7.040 8.774 8.455 8.572 N/A
61.73 70.74 76.22 119.62 111.64 114.56 N/A
Table 13. Maximum tire forces and impact factors of tractor axle of an HS20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good Maximum static force (kivs)
15.994
Vehicle
15 25 35 45 55 65 75
Road surface conditions Good Average
Poor
Maximum dynamic force (kius)
Impact factor (%)
Maximum dynamic force (kips)
Impact factor (%)
Maximum dynamic force (kips)
Impact factor (%)
Maximum dynamic force fkins)
17.804 17.874 18.377 18.613 18.892 18.402 18.441
11.32 11.76 14.90 16.38 18.12 15.06 15.30
19.507 19.524 20.991 21.919 21.552 21.730 20.608
21.97 22.08 31.25 37.05 34.76 35.87 28.85
21.910 21.549 22.724 25.667 26.469 25.530 25.746
36.99 34.74 42.08 60.48 65.50 59.63 60.98
24.960 29.212 28.563 39.058 33.769 29.674 N/A
Impact factor I%) 56.06 82.65 78.59 144.21 111.14 85.54
VA
o----o VRRY woo ROAO SuRFACL F
A-
100
-d
O----o v-.-.0
GOOD ROM SURFACE AVERAGE ROAD SURFACE POOR ROAU SURFACE
_-0-_---a--
___o----_&-
10
20
30
40
50
60
70
0
80
10
20
VEHICLE SPEED (MPH)
70 o---o
i? w
50
80
70
Fig. 31. Impact results of tire forces for the trailer axle of an HS20-44 vehicle with damped suspension system.
70 0-o A---A
40
VEHICLE SPEED (MPH)
Fig. 30, The comparison of computed and experimental impact results of tire forces for the tractor axle of an HS20-44 vehicle with damped suspension system.
60
30
SIBElI AXLE TRACTORAXLE TRAILER AXLE
G
0-o .%---A O--o
SD
SCEER AXLE TRACTOR AXLE TRAILER AXLE
507
01
12
14
18
,
18
20
22
24
’
28
28
’
12
30
14
16
18
20
22
24
26
28
30
L2 W')
Lz @T)
Fig. 32. Impact results of suspension forces in an HS20-44 vehicle with damped suspension system running at 55 mph and good road surface condition for different L, values.
Fig. 33. Impact results of tire forces in an HS20-44 vehicle with damped suspension system running at 55 mph and good road surface condition for different L, values.
running at 75 mph and average road surface condition are shown in Figs 18-21. A summary of the impact factors of suspension and tire forces for different road surface conditions and vehicle speeds is given in Tables 5-14 and ill~trat~ in Figs 22-31. The different distances between the tractor and trailer axles (L,) of an HS20-44 vehicle have also been studied. The results are shown in Table 15, Figs 32 and 33. The conclusions of this study are summarized as follows:
suspension and tire forces. However, the vehicle speeds influence the impact factors significantly in average and poor roads. 3. The impact factors of both suspension and tire forces obtained from the poor road are the highest among these four different road surface conditions for speed varied from 15 to 75 mph. The lowest impact factors are always found in the very good road. 4. In Tables 13 and 14, it may be seen that the impact factors of tire forces of tractor axle are much higher than those of trailer axle in HS20-44 vehicle. 5. When values of L, changed, the impact factors of all three axles of HS20-44 vehicle varied slightly. However, Figs 32 and 33 show that the highest
1. The impact factors of both suspension and tire forces increased with vehicle speed in most cases. 2. The impact factors were affected slightly by the vehicle speeds in very good and good roads for both Table 14. Maxims
tire forces and impact factors of traiier axle of an HS20-44 vehicle with damped suspension system for different road surface conditions and vehicle speeds Very good
Maximum static force (kipsl
16.012
Vehicle speed (mph) 15 25 35 4.5 55 65 75
Maximum dynamic force (hips) 17.059 17.470 17.401 17.450 17.588 17.823 17.801
Impact factor (%l 6.54 9.10 8.67 8.98 9.84 11.31 11.17
Road surface conditions Good Average Maximum dynamic force Chips) 17.743 17.952 18.673 18.482 19.164 18.970 19.863
Impact factor (%l 10.81 12.11 16.61 15.42 19.68 18.47 24.05
Maximum dynamic force @ipsl 19.007 19.959 20.308 22.922 21.423 21.476 21.720
Impact factor W) 18.70 24.65 26.83 43.15 33.79 34.12 35.64
Poor Maximum dynamic force Wpsl 25.085 22.258 28.01 I 25.813 27.585 28.116 N/A
Impact factor Wl 56.66 39.00 74.93 61.21 72.27 . 75.59 N/A
Dynamic response of highway trucks
1067
Table 15. Maximum suspension forces, tire forces, and impact factors of an HS20-44 vehicle with damped suspension system running at 55 mph and good road surface condition for different L, values Tire
Suspension
JG* (ft)
Steer axle
14 16 18 20 22 24 26 28
Tractor axle
14 16 18 20 22 24 26 28
Trailer axle
14 16 18 20 22 24 26 28
Maximum static force (kips)
2.915
14.193
14.573
Maximum dynamic force (kips)
Impact factor (%)
3.510 3.510 3.548 3.574 3.501 3.506 3.541 3.539
20.41 20.40 21.72 22.61 20.11 20.29 21.48 21.40
20.311 20.648 20.639 19.531 20.120 20.578 20.070 19.904
43.11 45.48 45.42 37.61 41.76 44.99 41.41 40.24
19.711 19.768 19.754 19.613 19.746 19.788 19.770 19.786
35.26 35.65 35.56 34.58 35.50 35.79 35.66 35.77
Maximum static force (kips)
3.995
15.994
16.012
Maximum dynamic force (kips)
Impact factor (%)
4.960 4.960 4.861 4.870 4.821 4.867 5.007 5.026
24.15 24.15 21.68 21.90 20.67 21.84 25.33 25.80
21.552 21.744 21.323 20.332 20.957 21.181 21.955 21.093
34.76 35.96 33.32 27.13 31.03 32.44 37.28 31.89
19.164 19.019 18.929 19.097 18.924 18.869 19.105 19.014
19.68 18.78 18.21 19.26 18.18 17.84 19.32 18.74
*L2 is the distance between the tractor and trailer axles. impact factors were obtained when L, = 14-16 ft and 26-28 ft for both suspension and tire forces. 6. Some experimental data obtained by Whittemore et al. [6] were used to compare with computed data. A comparison of computed and experimental impact results for tire forces is presented in Figs 25 and 30. It can be seen that the computed impact values agree very well with the experimental data. REFERENCES
1. S. J. Fenves, A. S. Veletsos and C. P. Siess, Dynamic studies of bridge on the AASHO road test. Highway Research Board, Report 71, National Academy of Scienses, Washington, DC (1962). 2. S. J. Fenves, A. S. Veletsos and C. P. Siess, Dynamic studies of the AASHO road test bridge. Hiahwav Research Board, Report 73, National Academy of Sciences, Washington, DC (1962). 3. S. Levy and J. P. D. Wilkinson, The Component Element Merhod in Dynamic. McGraw-Hill, New York (1976). 4. G. R. Potts and H. S. Walker, Nonlinear truck ride analysis. J. Engng for Industry, Trans. ASME, May, 597-602 (1974). 5. A. S. Veletsos and T. Huang, Analysis of dynamic response of highway bridges. J. Engng Mech. Div., AXE %, 593620 (1970). 6. A. P. Whittemom, J. R. Wiley, P. C. Schultz and D. E. Pollock, Dynamic pavement loads of heavy highway
10. 11.
12. 13.
14. 15.
vehicles. National Cooperative Highway Research Program Report, Washington, DC (1970). Standard Specifications for Highway Bridges, 14th Edn. American Association of State Highway and Transportation Officials, Washington, DC (1989). T. Huang, Dynamic response of three-span continuous highway bridges. Ph.D. dissertation, University of Illinois, Urbana, IL (1960). T. L. Wang and D. Z. Huang, Computer modeling analysis in bridge evaluation. Final research report prepared for Florida Department of Transportation under Contract No. C-3394 (WPI-0510542), Tallahassee, FL (1991). T. L. Wang, Ramp/bridge interface in railway prestressed concrete bridges. J. Struct. Engng, AXE 116, 1618-1659 (1990). T. L. Wang, V. K. Garg and K. H. Chu, Railway bridge/vehicle interaction studies with a new vehicle model. J. Struct. Engng, AXE 117, 2099-2116 (1991). C. J. Dodds and J. D. Robson, The description of road surface roughness. J. Sound Vibr. 31, 175-183 (1973). J. Moshman, Random number generation. In Mathematical Methods for Digital Computers (Edited by A. Ralston and H. S. Wilf), Vol. II, Chap. 12, pp. 249-263. John Wiley, New York (1967). R. K. Otnes and L. Enochson, Digital Time Series Analysis. John Wiley, New York (1972). C. J. Dodds, BSI proposals for generalized terrain dynamic inputs to vehicles. ISO/TC/l08/WG9, Document No. 5, International Organization for Standardization (1972).