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Stress Analysis of Stiffener Plate at the Base of the
Overhanging Traffic Sign Post under
Effect of Vehicle-Induced Gusts
Luangsod Somchai1, Tempiam Anan1, Fongsamootr Thongchai2 and
Chartpuk Prakorb1 1Department of Mechanical Engineering,
Rajamangala University of Technology Phra Nakhon, Thailand
2Department of Mechanical Engineering, Chiang Mai University,
Thailand [email protected]
Abstract This research is an analysis of stiffener plate
dimensions at the column base of the overhanging traffic sign post
under effect on vehicle-induced gusts. The finite element analysis
(FEA) result is compared with the result form computation using
mathematical equation and an experimental result which cited from
Fongsamootr T. and Chartpuk P. [2006]. It is found that the FEA
result has deviation about 1% and 8% respectively. Traffic sign
post structure is exerted by three forces in the same time; body
force, Vehicle-Induced Gusts and wind load. The higher stiffener
plate leads to decrease of maximum stress at the column base.
Height extension of stiffener plate from 250 to 350 mm with fixed
thickness and base width leads to increase in the safety factor of
column and stiffener plate. Rectangular stiffener plate with cut
off a corner (type C) is the best type for supporting the base of
traffic sign post column. Cutting of a corner of rectangular
stiffener plate results increase of stress in itself but less than
maximum stress in traffic sign post column.
Keywords-overhanging traffic sign post; stiffener plate;
vehicle-induced gusts
I. INTRODUCTION Traffic sign is a component for traffic symbol.
Traffic sign
is installed on highway area or roadside [1]. It controls and
introduces for the traffic route. Fig. 1 shows the overhanging
traffic sign, stiffener plate and steel column. The structure of
overhanging traffic sign is complex structure particular stiffener
plate which cannot be analyzed by using mathematics equation.
Finite element method is suitable ways to solve this problem.
According to Fongsamootr T. and Chartpuk P. [2, 3] analyzed the
strength of traffic sign post under wind effect but theirs in
formations still lack of analyzing of strength at stiffener plate.
A.Sanz Andres, J. Santiago Prowald, C. Baker and A. Quinn [4]
presented a mathematical model for the vehicle-induced load on a
flat sign panel, simple enough to give analytical results, but able
to explain the main characteristics of the phenomenon. Phillip M.
Cali and Eugene E. Covert [5] investigated the induced horizontal
loads by vehicle-induced gusts on an overhead highway sign
structure. The experiment was designed to measure unsteady loads on
a
model highway sign (1:30 scale) produced by a model vehicle
passing underneath. Osman Hag Elsafi, Sreenivas Alampalli and Frank
Owens [6] described a computer-aided, spreadsheet implementation of
a new procedure for design of end-plates and base-plates of sign,
signal, and light cantilevered traffic support-structures and also
for base-plates of span-wire-mounted traffic-signal structures.
However, in previous study have no researcher analysis stiffener
plate stress at the base of the overhanging traffic sign post for
large structure. Thus, the aim of this study is analysis of
stiffener plate stress at the base of the overhanging traffic sign
post under effect on vehicle-induced gusts, equivalent static wind
load and its body force.
(a) Overhanging traffic sign (b) Stiffener plate and steel
column
Figure 1. Overhanging traffic sign post
II. STRESS AND STRAIN ANALYSIS OF TRAFFIC SIGN COLUMN ON A MODEL
1:6
In this study there are three methods for analyzing of stress
and strain of traffic sign column; a) Experiment b) Finite element
method c) Mathematical equation.
A. Experimental Setup Experimental model was fabricated column
from stainless
steel 304 (scale factor 1:6). The length of column traffic sign
is 123.33 mm with diameter 44.56 mm and thickness 4.7 mm and size
of base steel plate is: width 96.7 mm, length 96.7 mm and thickness
4.7 mm. There are eight triangular stiffness plates. Size of
stiffness plate size is: width 25 mm, height 43.4 mm and thickness
2 mm.
978-1-4673-1773-3/12/$31.00 2013 IEEE
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Strain gauges KYOWA type KFG-5-120-C1-11L3M2R with resistance
120.0120.8 at ambient temperature 24 C and 50 %RH was used. Six
strain gauges were installed on the surface of traffic sign column
which installed in pair opposite at 3 points along the length of
column. First point of strain gauge is higher from column base 75
mm, second point is 370 mm and third point is 815 mm. Strain gauge
indicator model SM-60D and switching balance box SS 24 were used.
Stiffener plate and location of strain gauge are shown in the Fig.
2.
Figure 2. Experimental setup
B. Finite Element Method Analyses. SolidWorks program is
implement which have been
designed finite element model (scale 1:6) and CosmosWorks
program is used for analysis stress and strain in the column.
Pre-Processing, material properties of stainless steel 304 are
followed; Youngs modulus 193 GPa, Poissons ratio 0.3, tensile
stress 520 MPa, compressive stress 210 MPa, density 8,000 kg/m3 and
body force is taken into account. In this study, ten nodes
tetrahedral element type is used all parts of structures and six
nodes tetrahedral element type is used for traffic sign plate.
Solve-Processing, computer-aid engineering analyzes stress and
strain.
Post-Processing, the results are displayed in form of numerical
value of stress and strain in spreadsheet.
C. Mathematical Equations Stress and strain in the column of
traffic sign is calculated
based on beam equations with respected body force as load.
Parameters of traffic sign column are defined and shown in Fig. 3
body force as load which exerts on each cross section of column is
determined by SolidWorks. Given density of column material is 8,000
kg/m3.
Figure 3. Parameters of traffic sign post
Where x is x-axis coordinate z is z-axis coordinate xi is center
of mass of structure traffic sign zi is center of mass of structure
traffic sign ri is displacement of center of mass
i is angle of center of mass respect x-axis D is outside
diameter of traffic column d is inside diameter of traffic sign
column ai is position of strain gauge (Outer side) bi is position
of strain gauge (Inner side)
Data reduction: Compressive stresses occur in column at focused
point (ai) can be calculated by (1) as follows.
,ii
pi
PA
= (1)
Bending moment can be calculated by (2)
i
im
M CI
= (2)
Combine stress is calculated by (3)
i
i i
i
P M CA I
= (3)
Where 4 4( ) / 64I D d= and 2 2 ( ) / 4A D d = Strain is
calculated by (4)
i
iE
= (4)
Where E is Youngs Modulus
D. Comparision of the Results Obtained stress occurs in column
of traffic sign was shown
in Fig. 4-5. This figure shows the results which obtain from
three methods; experiment, finite element method and mathematical
equation. It can be seen that the stress occurs in column of
traffic sign on range of 75815 mm agree with each other. When
compared to the result from finite element method, the obtained
result from mathematical equation and the result from experimental
have deviation about 1% and 8% respectively. However, when
considered result as shown in Fig. 4-5, it can be seen that to
solve the problem like this by experiment and mathematical equation
has a limit because they cannot analysis stress occur throughout
the length of column but finite element method can analyze. The
result from finite element method shows highest stress
concentration at 890 mm from base of column.
Figure 4. Stress distribution along the length of column at
outer side
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Figure 5. Stress distribution along the length of column at
inner side
III. MODELING AND SIMULATION OF REAL SIZE TRAFFIC SIGN POST
Finite element model scale 1:1 is developed and analyzed stress
concentration in by using SolidWorks program combine with
CosmosWorks program.
A. Model of Overhanging Traffic Sign Post Size of traffic sign
post refer to standard size which
defined by office of transport and traffic policy and planning,
ministry of transport Thailand [1]. The length of traffic sign
column is 8,750 mm with diameter 318.5 mm and thickness 6 mm, size
of base steel plate is: width 620 mm length 620 mm thickness 28 mm
and size of traffic sign plate is: width 3,500 mm height 2,400 mm
thickness 2 mm.
B. Material Properties The traffic sign post is made from steel
JIS G3444 grade
STK41 and traffic sign plate ASTM A36. The boundary condition is
assumed to be isotropic and linear elastic material. An element
type of tetrahedral 10 nodes has been adopted for the analysis. The
properties of traffic sign post material including elasticity
modulus E, Poisons ratio , and density are given in Table I.
TABLE I. STYLES MATERIAL PROPERTY FOR COLUMN TRAFFIC SIGN
Material Type
Tensile Strength
Poissons Ratio
Yield Strength
Mass Density
Elastic Modulus
(MPa) (MPa) (kg/m3) (GPa) JIS G3444
Grade STK41
402 0.3 235.4 7850 200
ASTM A 36 Steel 400 0.26 250.0 7850 200
C. Apply Forces There are three forces exert on the traffic sign
post; body
force, equivalent static wind load and force due to
vehicle-induced gusts. Equivalent static wind load [7] can be
calculated by (5,6) and force due to vehicle-induced gusts is
calculated by (7) which proposed by A.Sanz Andres, J. Santiago
Prowald, C. Baker and A. Quinn in 2003 [4].
1) Body Force Body force is a weight of traffic sign post
structure which
calculate by using SolidWorks program. Volume and density are
properties of material that use for this calculation process, also
gravity force.
2) Equivalent Static Wind Load Equivalent static wind load
equation [7] is
212
q V= (5)
A w e g pF I qC C C= (6) Where Ce is exposure factor, (1) Iw is
significant factor of the wind force, (1) CP is external pressure
coefficient, (1.52) Cg is gust effect factor, (2.35) is air
density, (1.2 kg/m3) V is reference wind speed, (15 m/s) A is area
of traffic sign plate, (3.52.4 m2) q is reference velocity
pressure, (135 N/m2) FA is equivalent static wind pressure, (482
N/m2)
3) Vehicle-Induced Gusts Force due to vehicle-induced gusts can
be calculated by, (7)
2 2 2 2 2
2 2 5/ 22
4 [( ) ]b
Ch B U A U t dF
U t d
=
+ (7)
Where is air density, (1.2 kg/m3) h is traffic sign plate
height, (2.4 m) B is half of width of traffic sign, (3.5 m) U is
highest velocity of truck, (90 km/hr) d is distance between center
of truck projection area to center of traffic sign plate in
vertical direction, (4.5 m) Ab is twofold of projection area of
truck, (18.75 m2) t is time (start -1 to 1 second) FC is
vehicle-induced gusts, (N)
Fig. 6 shows magnitude of force due to vehicle-induced gusts
which exert on traffic sign post by (6)
Figure 6. Relation between vehicle-induced gusts and time from
(7)
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IV. ANALYTICAL RESULTS OF REAL SIZE TRAFFIC SIGN POST
Three types, i.e. type (A) rectangle, type (B) triangle and type
(C) rectangle with cut off a corner have been considered for
stiffener plate. The type of stiffener can be found in Table II.
The height of stiffener plate are vary about 250, 300 and 350 mm
with fixed thickness and base width, maximum stress in stiffener
plate and maximum stress in traffic sign post column have been
determined. Safety factor of structure has been determined. Results
have been shown in the Table II.
Since, it has biggest volume of material, stiffener plate type A
is the most strength when it compared with stiffener plate type B
and C.
Fig. 711 show distribution of stress which occurs in stiffener
plate. Extension in height of stiffener plate with fixed thickness
and base width results decreasing of maximum stress in column for
all type stiffener plates. Considering Fig. 8, in area A has lowest
stress about 2.3 MPa, thus this area is redundant part thus it can
be cut off and it becomes C type like shown in Fig. 9 and 10.
For these reasons, stiffener plate C type is the most suitable
for supporting of overhanging traffic sign post. However, the
maximum stress in stiffener plat is less than maximum stress in
column.
TABLE II. TYPE OF STIFFENER PLATE AND RESULTS
Type of stiffener
plate
Dimensions
(mm)
Max. Stress at stiffener
plate
(MPa)
Max. Stress at column
(MPa)
Safety factor
stiffener
plate at
column
(A) rectangle
w =140 h =250 t =12
81
94
2.90 2.50
w =140 h =300 t =12
80 92 2.94 2.55
w =140 h =350 t =12
78
90 3.01 2.61
(B) triangle
w =140 h =250 t =12
91
92 2.58 2.55
w =140 h =300 t =12
90
92 2.61 2.55
w =140 h =350 t =12
84
88 2.80 2.67
(C) rectangle with cut off a corner
w =140 h =250 t =12 b= 10 c= 10
86
90
2.73 2.61
w =140 h =300 t =12 b= 10 c= 10
84 90 2.80 2.61
w =140 h =350 t =12 b= 10 c= 10
80 87 2.94 2.70
Figure 7. Maximum stress in the column of traffic sign post for
type A rectangle with w =140 mm, h =250 mm and t =12 mm
Figure 8. Stress distribution in stiffener plate of type A
rectangle with w =140 mm, h =250 mm and t =12 mm
Figure 9. Stress distribution in stiffener plate of type B
triangle with w =140 mm, h =250 mm and t =12 mm
Figure 10. Stress distribution in stiffener plate of type C
rectangle with cut off a corner with w =140 mm, h =250 mm, t =12 mm
b =10 mm and c =10 mm
t
w
h
w
h
w
h
b
c
Deformed shape
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Figure 11. Stress distribution in stiffener plate of type 3
rectangle with cut off a corner with w =140 mm, h =350 mm, t =12 mm
b =10 mm and c =10 mm
V. CONCLUSIONS The aim of this study is investigation the
aspect
(configuration) of stiffener plate which suitable for traffic
sign post structure is exerted by three forces in the same time:
body force, Vehicle-Induced Gusts and wind load. The shape and size
of stiffener plate are designed using SolidWorks program. Finite
element method (CosmosWorks program) has been used to analyze the
stress. The height of stiffener plate has an effect on stress
concentration at the base of column, the higher stiffener plate
results decrease of stress concentration in column. Rectangular
stiffener plate with cut off a corner (Type C) is the best type for
supporting the base of traffic sign post column. Cutting of a
corner of rectangular stiffener plate results increase of stress in
its self but less than maximum stress in traffic sign post
column.
ACKNOWLEDGMENT The authors would like to thank the University of
Chiang
Mai and Rajamangala University of Technology Phra Nakhon
Thailand, Mechanical engineering department for facility and
financial support.
REFERENCES [1] Manual of the support structures for traffic
control devices. Office of
transport and traffic policy and planning, Ministry of
Transport. Thailand. 2004.
[2] Fongsamootr T. and Chartpuk P. Analyses of Stress
Distribution in Overhanging Traffic Sign Pole Using Finite Element
Method, KKU Engineering Journal. ISSN 0125-8273. Published on
behalf of Faculty of Engineering, KHON KAEN University, Thailand.
Volume33, Number6, NovemberDecember, 2006.
[3] Fongsamootr T. and Chartpuk P. Analysis of VehicleInduced
Gusts Effect on Stress Distribution and Natural Frequency of
Traffic Sign Post Using Finite Element Method, Conference of
Mechanical Engineering Network of Thailand. 20th 1820 October 2006
at Mandarin Golden Valley Resort Khao Yai Hotel. Organize by
Suranaree University of Technology, Thailand.
[4] A.Sanz Andres, J. Santiago Prowald, C. Baker and A Quinn.
2003. Vehicle induced loads on traffic sign panels. Journal of Wind
Engineering and Industrial Aerodynamics. Volume 91, Issue 7 (June
2003): pp 925942.
[5] Philip M. Cali and Eugene E. Covert. 2000. Experimental
measurements of the loads induced on an overhead highway sign
structure by vehicle-induced gusts. Journal of Wind Engineering and
Industrial Aerodynamics. Volume84, Issue1 (January 2000): pp
87100.
[6] Osman Hag Elsafi, Sreenivas Alampalli and Frank Owens. 2001.
Computer-aided implementation of a new procedure for design of
end-plates and base-plates for traffic support structures. Journal
of Engineering Structures. Volume23, Issue11 (November 2001): pp
15031511.
[7] The calculation standard of wind load and response of the
building. Department of Public Works and Town & Country
Planning. Ministry of Interior. 2007.
[8] A.D.Quinn, C.J.Baker, N.G.Wright. 2001. Wind and Vehicle
induced Forces on Flat Plates-Part 2: Vehicle Induced Force.
Journal of Wind Engineering and Industrial Aerodynamics. Volume 89,
Issue 9 (July 2001): pp 831847.
[9] Robert D.Cook, David S. Malkus and Michael E. Plesha.
Concept and applications of Finite Element Analysis. 3 rd Edition.
New York: John Wiley & Son. 1989.
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