Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

53, 4, pp. 837-846, Warsaw 2015
DOI: 10.15632/jtam-pl.53.4.837

EXPERIMENTAL AND NUMERICAL INVESTIGATION OF FRICTION
COEFFICIENT EFFECTS ON DEFECTS IN HORIZONTAL

TUBE BENDING PROCESS

Jalal Taheri Kahnamouei
Memorial University of NewFoundland, Canada; e-mail: jtk441@mun.ca

A.M. Fattahi
Department of Mechanical Engineering, Tabriz Branch, Islamic Azad university, Tabriz, Iran

Theaimof this paper is to investigatedefects in a thin-walled tube bendingprocess (without
using mandrel and booster) and effects of friction between the dies and tube on wrinkles.
In the tube bending process, there are several effective parameters such as wall thickness,
outer diameter-to-wall thickness ratio, centerline bending radius-to-outer diameter ratio and
friction coefficient. Any mismatch in the selection of the process parameters would cause
defects inducing undesirable variations in wall thickness and cross-section distortion. In
this work, firstly, tubes with several wall thickness values are bent, and the final depths of
wrinkling and wall thickness change are reviewed. Then, to study the process numerically,
numerical simulations are carried out. Then, a series of experimental tests are carried out
to verify the simulation results. A comparison between numerical and experimental results
shows a reasonable agreement. Finally, in order to obtain a suitable friction condition, the
effects of friction coefficients on defects are studied. For this purpose, a series of simulations
has been carried out. It shows that at a certain friction coefficient, a minimum wrinkling
depth can be observed and variations in the friction coefficient between the dies and tube
has no effective influence on wall thinning and thickening.

Keywords: tube bending, wrinkle, simulation, friction, wall thickness change

1. Introduction

Recently, curved thin-walled tubular elements have been attracting more applications in au-
tomobile, aerospace, and oil industries. Tube bending is used as a hydroforming process and
application that needs high strength/weight ratio products (Manabe andAmino, 2002; Koc and
Altan, 2001). There are some parameters to be controlled in order to reduce the defect. For
example, geometry parameters and friction conditions aremodified to restrain instability of the
process. In the tube forming process, wrinkling can be avoided, but the wall thickness change is
almost inevitable. From among the considerable number of studies dealing with the wrinkling
and thinning of wall thickness in tube bending, only few studies have focused on methods to
reduce the defect. Tang (2000) employed plastic-deformation theory to investigate the plastic
deformation in pipe and tubebending and also explained the seven phenomena in tubebending,
also mentioning their practical formulas. An experimental sample was also tested to illustrate
that the results of the formulae are very similar to the experimental results. Yang et al. (2006)
investigated the effect of friction on the cross-section quality of thin-walled tube NC bending.
His results showed that the effects of frictions between all dies and tube on wall thinning are
smaller than their effects on section distortion.Therefore, in order to improve the section quality,
frictions between mandrel, wiper and tube should be decreased, but the frictions between the
pressure die, bending die and tube should increase. Gaoa and Strano (2004) made a research



838 J. Taheri Kahnamouei et al.

on the effect of friction on the quality of tube pre-bending and hydroforming. In that paper,
process variables such as the friction coefficient, tube material and pre-bent tube radius were
analyzed. It was found that a lower friction coefficient can reduce thinning in the pre-bending
process, and that a large pre-bending radius is beneficial to both pre-bending and subsequent
hydroforming.
Zeng and Li (2002) introduced a tube push-bending process combining axial forces and

internal pressure.Moreover, they also made research on effects of the internal pressure, friction
condition andpushdistance on the tubedeformationpush-bendingprocess.Yang andLin (2004)
studied thewrinkling in the tubebendingprocess,where the effects of bendingangle, geometrical
dimensions, material properties and the original radius and strength coefficient of tubes on the
minimumbending radiuswere analyzed. The role of the fillingmaterial on defects in the of thin-
-walled tubebendingprocesswas reportedas anumerical and experimental studybySedighi and
Taheri Kahnamouei (2014). That paper investigated approaches to avoid common defects such
as the wrinkling, cross section distortion and wall thickness variation in the bending process
of a thin-walled tube. So, a series of experimental tests was carried out by filling the tube
with melted lead and different types of rubbers. They showed that wrinkle initiation and cross
section distortion can be avoided with a lost core made of low temperature melting metal like
lead or tin. Jiang et al. (2011) used a three-dimensional finite element method to investigate
deformation behavior of medium-strength TA18 high-pressure tubes during NC bending with
differentbendingradii.Thearticle showed that if amandrel is used, the thickening ratio increases
from the initial bending section to the bending section.
In the present study, firstly, the wrinkle phenomenon and the wall thickness change in a

thin-walled tube are studied using theoretical, experimental and FEmethods. In order to verify
the finite element analysis results, some experiments have been done and comparisons drawn
between the experimental and numerical results in Section 2. In Section 3, FEM analysis of
effects of friction between the dies and tube on these defects is studied. Finally, in Section 4
the results are presented and discussed. The results show that at a certain friction coefficient a
minimumwrinkling depth can be observed and variations in the friction coefficient between the
dies and tube have no effective influence on the wall thinning and thickening.

2. Methodology

2.1. Analytical approach

Changes inwall thickness is related tomany factors, suchasmaterial, size and shape,bending
and wall factors, bending method, tooling and bending operation. When a tube is bent, then
tensile or compressive stresses cause wall thinning or thickening. Thewrinkling in the inner wall
of the bending radius is one of the common defects in the tube bending process. It has a direct
relation with the outer diameter-to-wall thickness ratio and the centerline bending radius-to-
outer diameter ratio (Fig. 1).

Fig. 1. Example of a wrinkled bending section of a tube and its parameters (Yang and Lin, 2004)



Experimental and numerical investigation of friction coefficient effects... 839

Based on the known energy principle, the critical moment of wrinkling onset is when the
internal energy of thewrinkled shell (U) is equal to thework doneby the external forces (T), and
the wrinkling happens if the external forces are larger than the internal energy of the wrinkled
shell (Yang and Lin, 2004). According to the wrinkling wave function proposed by Wang and
Cao (2001) and Yang and Lin (2004), the depth of wrinkling in the normal direction w can be
characterized with the following function

w = w0

√
Rcosθ
R0

(
1−cos 2πmϕ

φ1−φ0
)

w0 =
√
r0R0(φ1−φ0)

πm
(2.1)

where r0 is the tube diameter, R0 is the bending radius, m is the wave number along the
circumferential direction of the tube, ϕ is the curve coordinate in the tube bending direction
which changes from φ1 to φ2.
When a tube is bent, two typical stress zones can be defined. One is the tension zone at the

extrados of the bend; the other is the compressive zone at the intrados of the bend. These cause
tube thickening at the intrados and thinning at the extrados, respectively, as shown in Fig. 2.

Fig. 2. Cross section of tube after bending

Based on plastic deformation theory, equations (2.2) give the rate of wall thinning and wall
thickening for the extrados and intrados of the bend which has been proposed by Tang (2000)

t0 max =
(
1−

r0
4R0

)
t ti max =

(
1+
2R0r0+3r20
8R20

)
t (2.2)

where t is tube wall thickness.

2.2. Material properties and geometry

Auniaxial tension test is used to obtainmechanical properties of steel (USt37) and is listed
in Table 1. The hardening behavior can be described by equation σ = K(ε)n. The Coulomb
friction model is used in the simulation process.

Table 1.Mechanical properties of the tube

Poisson’s ratio 0.3
Maximum elongation [%] 44.2
Elasticity modulus [GPa] 210
Yield stress [MPa] 270
K 345
n 0.05

The tooling parameters are shown in Table 2. Circular tubes of diameter r0 = 50mm, wall
thickness of t0 =1.5, 1.25, 0.9mm, bending radius 150mm and bending angle 45◦ were used in
the experiments.



840 J. Taheri Kahnamouei et al.

Table 2. Tooling geometry dimensions

Tooling parameter Length [mm] Dimension [mm]

Bend die 300(D) 52

Rotary die 150 52

2.3. Experimental setup

The experiment is performed to provide a general concept of the tubebendingprocess and to
verify the FEmodeling. For this purpose, a hydraulic horizontal tube bendingmachine has been
used. The horizontal bending is widely used for bending tubes, particularly for tight bending
radii and thin wall tubes. The dies setup on the horizontal bendingmachine is shown in Fig. 3.
Thework piece is held between the bend die and rotary dies. The bend die strokes linearly and,
synchronically, rotary dies are actuated to rotate on the tube, and the work piece bends to any
requested angle.

Fig. 3. Sketch of the tube horizontal bending

2.4. The FE model

A 3D finite element model is built using ANSYS software. The tube is modeled by shell
143 which is well suited to model nonlinear, flat or wrapped, thin to moderately thick shell
structures. Three dimensional rigid elements for the dies models have been used. Shell 143 is
4-node 3D space shell element and has six degrees of freedom at each node: translations in the
nodal x, y, and z-directions and rotations about the nodal x, y, and z-axis. The geometry, node
locations, and the coordinate system for this element are shown in Fig. 4 (ANSYSHelp, 2007).

The Coulomb friction coefficient between the tube and dies are assumed to be equal to 0.15
(Trana, 2002) andall dies and tube geometric parameters are the sameas used in the experimen-
tal setup. In the tube bending process, there are three contact surfaces between the tube/bend
die, tube/rotary dies. The “surface-to-surface contact” method has been employed to describe
the mechanical constraints for different contact pairs using CONTACT174 and TARGET169.
Figure 5 shows a representative finite element model with the initial tube blank and the tool
set.



Experimental and numerical investigation of friction coefficient effects... 841

Fig. 4. Shell (143) geometry (ANSYS Help, 2007)

Fig. 5. FEmodel for the horizontal bending process

3. Experimental verification of the numerical model

In order to verify the finite element analysis results, some experiments have been done. InFig. 6,
a comparison between the experimental and numerical results are presented. No wrinkling can
be seen in the tube with 1.5mm thickness but in the tube with 1.25mm and 0.9mm thickness
wrinkling is observed.

Also thewrinkling depth in the experimental andFEmodeling results is compared inFig. 7.
It can be seen that the amount of wrinkling in the tube is in direct correlation with the tube
wall thickness. An increasing in the wall thickness decreases the possibility of wrinkling. From
Fig. 6 and Fig. 7 it can be concluded that the FE results are reasonable and can be used for
further investigation of the friction coefficients effect on wrinkling.

FEM simulations and experimental results for the extrados wall thickness at the bend zone
have been compared and they are shown in Fig. 8. It can be seen that the wall thickness at
the outside of the bend is always decreased. Also by an increase in d/t ratio, the thinning value
decreases. Themaximum thinning reduction in 1.5mm tube is equal to 6.5% and theminimum
thinning reduction in 0.9mm tube is equal to 3%. It can also be observed from Fig. 8 that the
wall thickness has a great influence on the thinningwhen the bending radius and tube diameters
are fixed.

Also experimental and FEM results for the intrados wall thickness at the bend zone have
been compared and shown in Fig. 9. It can be seen that the thickness at the inside of the bend
is increased, and the maximum thickness thickening reduction is equal to 10%.



842 J. Taheri Kahnamouei et al.

Fig. 6. Verification of the FE results by experiments.Wall thickness: (a) 1.5mm, (b) 1.25mm,
(c) 0.9mm

Fig. 7. Comparison of FE and experimental results

Fig. 8. Comparison of the thickness distribution in FE and experimental results at the extrados radius
(without considering hardening and friction parameters)



Experimental and numerical investigation of friction coefficient effects... 843

Fig. 9. Comparison of the thickness distributions in FE and experimental results at the intrados radius
(without considering hardening and friction parameters)

4. Results and discussion

The friction conditions between the bend die, rotary die and tube have a large effect on the
wrinkling in thin-walled tube horizontal bending, especially for small R/D and large D/t. In
order to study the effects of friction on defects after verification of the FE model, a set of
runs have been implemented. There are two different cases of friction in the horizontal bending
process. One refers to friction between the bend die and tube; another refers to friction between
the tube and rotary dies. For this purpose, two series of friction conditions are employed. These
runs include values of the friction coefficient between the benddie and tube as 0.05, 0.1, 0.2, 0.3,
0.4, 0.5 and friction between the rotary dies and tube as 0.05, 0.1, 0.2, and 0.3. In the following,
the obtained results will be discussed for four different subsections separately.

4.1. The effect of friction between rotary dies and tube on wrinkling

TheFEmodeling of the bending process for different amounts of friction between the rotary
dies and tube have been carried out. Variations in the friction coefficient and wrinkling depths
are shown in Fig. 10. It shows that the depth of wrinkling for all three thicknesses are decreased
when the friction coefficient is decreased from 0.3 to 0.2 and the depth of the wrinkling is
increased when the friction coefficient is reduced from 0.2 to 0.05. This shows that the least
wrinkling depth will happen at a certain friction coefficient.

Fig. 10. Variations in wrinkling depth vs. friction coefficient between the tube and rotary dies

4.2. The effect of friction between rotary dies and tube on the wall thickness change

The effects of the friction coefficient between the rotary die and tube on the wall thickness
are shown in Figs. 11 and 12. It can be found that it has no influence on the thinning and
thickening of the tube wall.



844 J. Taheri Kahnamouei et al.

Fig. 11. Variations in wall thinning vs. friction coefficient between the tube and rotary dies (without
considering hardening and friction parameters)

Fig. 12. Variations in wall thickening vs. friction coefficient between the tube and rotary dies (without
considering hardening and friction parameters)

4.3. The effect of friction between bend die and tube on the wrinkling

Variations in the friction coefficient andwrinkling depths for different thicknesses (1.5, 1.25,
0.9mm) are presented in Fig. 13. It shows that for all three thicknesses, the depth of wrinkling
is decreased when the friction coefficient is reduced from 0.5 to 0.2. But when the friction
coefficient is reduced from 0.2 to 0.05, the depth of wrinkling increases. It is found that the
minimumwrinkling depth takes place at friction coefficient of 0.2.

Fig. 13. Variations in wrinkling depth vs. friction coefficient between the tube and bend die

4.4. The effect of friction between bend die and tube on the wall thickness change

The effects of the friction between the bend die and tube on the wall thickness are shown in
Figs. 14 and 15. Same as in the previous Subsection, it can be found that friction between the
bend die and tube has no influence on the thinning and thickening of the tube wall.



Experimental and numerical investigation of friction coefficient effects... 845

Fig. 14. Variations in wall thinning vs. friction coefficient between the tube and bend die (without
considering hardening and friction parameters)

Fig. 15. Variations in wall thickening vs. friction coefficient between the tube and bend die (without
considering hardening and friction parameters)

According to the results given in these figures, it can be concluded that friction between the
tube, bend die and rotary dies have a significant and important effect on the wrinkling, and
have no influence on the thinning and thickening of tube wall thickness in the tube horizontal
bending process.

5. Conclusion

A 3D FE model has been created to study the effect of friction on defects in the bending
process.TheFE results have beenverifiedby experimental tests and they are in good agreement.
According to the results of the analysis, it can be concluded that:

• Theminimumwrinkling depth occurs at a certain value of the friction coefficient.
• Friction conditions may affect the balance of internal energy between the wrinkled shell
and the work done by the external forces. So, there should be a certain friction coefficient
value for which a stable state exists between the two mentioned energies.

• Extremely low or high friction conditions are detrimental for the tube bending process. A
perfect tubular part can be obtained at a suitable friction condition.

• Variations in the friction coefficient between the dies and tube have no influence on the
thinning and thickening of the tube wall.

Finally, it should be noticed that there are other effective parameters in the tube bending
such as bending speed, bending radius. Future works should address these factors in detail.



846 J. Taheri Kahnamouei et al.

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Manuscript received December 2, 2013; accepted for print April 17, 2015