Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

52, 1, pp. 227-233, Warsaw 2014

ROLE OF FILLING MATERIAL ON DEFECTS OF THIN-WALLED TUBE
BENDING PROCESS

Mohammad Sedighi

School of Mechanical Engineering, Iran University of Science and Technology, Tehran, Iran

Jalal Taheri Kahnamouei

Islamic Azad University, Bostan Abad Branch, Mechanical Engineering Department, Iran

e-mail: j.taheri@iaubos.ac.ir

This paper investigates approaches to avoid common defects such as the wrinkling, cross
section distortion and changing in wall thickness in the bending process of a thin-walled
tube. A series of experimental tests has been carried out by filling the tube with melted
lead and different types of rubbers. Firstly, tubes were filled by several kinds of rubbers
and bended, but the wrinkling was observed at the inner side of the tubes. Also the cross
section distortions happened to be above the acceptable range.Therefore, rubbers could not
be a suitable filling material for steel tubes. As the second case, lead was used as the filling
material to avoid the defects. For this purpose, the tubeswere filled by liquid lead and itwas
solidified to form a leady core to support the inner part of the tube bend. After the bending
process, lead is melted and removed. This removable leady core was called the ‘Leady Lost
Core’. To study the process numerically, a 3Dfinite elementmodel of the horizontal bending
process has been built using a commercial code. Experimental tests have been carried out
to verify the simulation results and developed to provide additional insight. To consider the
friction coefficient, in this work, “The Barrel Compression Test” method has been used.
Comparisons between the experimental and finite element results have shown remarkable
agreement. They show that wrinkle initiation and cross section distortion can be avoided
with a lost core of low temperature melting metal like lead or tin.

Key word: thin-walled tube; bending process; low temperature melting metal

1. Introduction

In recent years, curved tubular parts have appealedmore applications in automobile, aerospace,
oil industries where high strength/weight ratio elements are needed (Manabe andAmino, 2002;
Koc and Altan, 2001). The defect due to a tube bending process is a very important matter
and it should always be avoided. There are some parameters to be controlled in order to reduce
the defects. For example, geometry parameters of tubes, wall thickness, outer diameter-to-wall
thickness ratio D/t, centerline bending radius-to-outer diameter ratio R/D and friction con-
ditions are some of these parameters which are usually modified to maintain the instability. In
the tube forming process, the wrinkling and variation in the wall thickness and cross section
distortion are the commondefects. Thewrinkling often happens in the inner part of the bending
tube, while the cross section distortion happens in the outer part, which should be avoided.

Up to now, many researches have dealt with the thin-walled tube bending defects, but only
few of them included both numerical and experimental results. Tang (2000) explained seven
phenomena in tube bending and also mentioned their practical formulas. Yang et al. (2006)
investigated the effect of frictions on cross section quality of thin-walled tubeNCbending,Yang
andLin (2004) studied thewrinkling for forming the limit of tubebendingprocesses,Guarracino
(2003) analysed cylindrical tubes under flexure. Li et al. (2006) carried out a research on a new



228 M. Sedighi, J. Taheri Kahnamouei

method to accurately obtain the wrinkling limit diagram in the NC bending process of a thin-
-walled tube with large diameter under different loading paths.
There are many methods to avoid defects in the tube bending process such as using sand

filling. The rubber filling method has been reported as a numerical study by Baudin et al.
(2004). Lee et al. (2005) used an oval tube to reduce the cross section distortion. Jiang et al.
(2011) used the three-dimensional finite element method to investigate deformation behavior
of medium-strength TA18 high-pressure tubes during NC bending with different bending radii.
They showed that the cross-sectional deformation and the wall thickness variation during ben-
ding in small bending radius are clearly different from those using a normal bending. Tian et al.
(2013) mainly studied the effects of geometrical parameters on wrinkling of rectangular wave-
-guide tubes by using a 3D-FE model for rotary-draw bending processes. Zhang et al. (2011)
experimentally studied bending characteristics of a large diameter thin-walled CP-Ti tube in
rotary draw bending. Wang et al. (2012) numerically and experimentally studied the effects of
internal pressure on forming defects, corner radius and thickness distribution of 5A02 aluminum
alloy shear hydro-bending tubes.
In the present study, experimental and numerical works have been carried out to investigate

how to avoid the defects in thin wall tubes under bending by filling withmaterials such as pure
lead and rubber. As a relevant work, Ohashi et al. (2001) used a low temperature melt alloy in
the bulging process for hollow products.
In this paper, firstly a series of experimental tests was implemented by filling the tubes with

three different types of rubber and lead. Figure 1 shows a schematic presentation of the whole
experimental procedure explained in Section 2. In Section 3, a numerical investigation has been
done, and finally, in Section 4 the results are presented and discussed.

Fig. 1. Sketch of the tube bending process with a leady lost core

2. Experimental setup

Onexperiment has beenperformed to provide a general concept of the tubebendingprocess and
to verify FEmodeling results. A hydraulic ram bending nachine was used as shown in Fig. 2.

2.1. Using rubbers as filling materials

Three kinds of rubber were used as the filler inside the tube to support the inner side of
the tube. Firstly, a tube filled by natural rubber and was bent. After bending, severe wrinkling
was observed (Fig. 3a) at the inner side of the tub. Also, cross section distortion appeared to
be above the acceptable range. Then, as the second test, a type of red polyurethane rubberwas
used (Fig. 3b). But like in the previous test, the result was poor and the wrinkling and cross
section distortion occurred. Finally, white polyurethanewas tested as the filler and thewrinkling
defect was reduced, but the bending quality was not still acceptable, see Fig. 3c. Therefore, lead
metal was considered as the filler, which will be explained in the next Section.



Role of filling material on defects of thin-walled tube bending process 229

Fig. 2. The specimen in the ram bending machine

Fig. 3. Tube filled with (a) natural rubber, (b) red polyurethane, (c) white polyurethane

2.2. Using lead as the filling material

In this method, the tube was filled by a liquid made of a low temperature melting point
metal such as pure lead prior to bending of the tube.Then the liquidwas solidified and after the
bending, the tube was heated up to melt the core to be removed. The leady core can support
the inner part of the tube. This removable leady core is called the ‘leady lost core’. All the
experimental results of the tests will be discussed in Section 4.

3. FE Simulation

3.1. Material properties and geometry

Auniaxial tensile testwas used todeterminemechanical properties of the tubemadeof Steel-
-USt37 and a pressure test to extract lead properties. These properties are listed in Tables 1
and 2. The hardening behavior can be described by using the equation σ=K(ε)n.

TheCloumb frictionmodel is used in the simulation process. The friction coefficient between
the tube and clamp die and between the tube and rotary dies are equal to 0.15. Bulk forming
was assumed for the lead forming. “Barrel CompressionTest” (Ebrahimi andNajafizadeh, 2004)



230 M. Sedighi, J. Taheri Kahnamouei

Table 1.Mechanical properties of tube Table 2.Mechanical properties of lead

Poisson’s ratio 0.3

Maximum elongation [%] 44.2

Elasticity modulus [GPa] 210

Yield stress [MPa] 270

K 345

n 0.05

K 28.26

n 0.175

σy [N/mm
2] 25

σuts [N/mm
2] 29

E [GPa] 14

Poisson’s ratio 0.3

has been carried out to find themagnitude of the friction factor m. The corresponding friction
coefficient m has been obtained by using the equation introduced by Hwang and Tzou (1997).
Figure 4 shows the lead cylinder after deformation by ’Barrel Compression Test’ to determine
the friction factor between the lead and tube. The obtained friction coefficient between the tube
and lead is equal to 0.043.

Fig. 4. leady cylinder after deformation by “Barrel Compression Test” for measurement
of the friction coefficient

The circular tubes (made from Steel-USt37) with diameter D0 = 50mm, wall thickness
of t0 = 1.5, 1.25, 0.09mm, bending radius 150mm and bending angle 45

◦ were used in all
experiments.

3.2. FE modeling

A3Dfinite elementmodel has been built usingANSYS software. For themodel, a 4-node 3D
space shell element for the tubemodel (shell 143), a 20-node 3D space solid element for the core
model (solid 95) and three-dimensional rigid elements for the dies models have been used. All
dies and tubegeometrical parameterswere the sameas in the experimental specimen. In the tube
bending process, there are three contact surfaces between the tube/bend die, tube/rotary dies
and tube/leady core. The “Surface-to-surface contact” method has been employed to describe
the mechanical constraints for different contact pairs using CONTACT174 and TARGET169.

4. Results and discussion

In order to investigate the effects of the filling material on defects, a set of experimental and
numerical FE runs have been implemented and compared. In one of them, a hollow tube was
bent and another one was a filled tube. The difference between the experiment and simulation
shows an error equal to 10%.

4.1. Effect of the leady lost core on wrinkling

FE simulation and experimental results are shown in Fig. 5. It presents two tubes which
have been bent with the filler (leady lost core) and without filler. The tube with the core is



Role of filling material on defects of thin-walled tube bending process 231

Fig. 5. Comparison of finite element analysis and experimental results; (a) experimental test for the
tube filled with lead, (b) experimental test for the tube without filling material, (c) FE simulation
result for the tube filled with lead, (d) FE simulation result for the tube without filling material

perfectwithout anywrinkling but in the tubewithout the core severe wrinkling occurred.Based
on the explanation presented by Li et al. (2006), regarding the stain energy principle, it can be
emphasized that the critical moment of the wrinkling onset happened when the internal energy
of the wrinkled shell U is equal to the work done by the external forces T . It can be concluded
from Fig. 5 that the filler causes the internal energy of the wrinkled shell to be increased and
the wrinkling phenomenon not to occur.

4.2. Effect of the leady lost core on cross section distortion

Figure 6 shows the cross section distortion in tubes under bending with and without the
leady lost core. It shows that the cross section distortion occurs in the tube bent without the

Fig. 6. Comparison of the tube cross section with and without the lost leady core; (a) experimental test
for the tube without filling material, (b) experimental test for the tube filled with lead,
(c) FE simulation result for the tube without filling material, (d) FE simulation result for

the tube filled with lead



232 M. Sedighi, J. Taheri Kahnamouei

filler. The tube with the core has a quite prefect circular cross section without any distortion
after the bending process. Also it shows that the FE and experimental results are the in a good
agreement.

4.3. Effect of the leady lost core on changing the wall thickness

InTable 3 FE simulations and experimental results for the extrados and intrados wall thick-
nesses at the bending zone are compared. It can be seen that the wall thickness outside the
bending is always decreased, but when the tube is filled by the leady lost core, the thinning
value of the extrados wall thickness is increased. It can be found that the thinning in the filled
tube is more than 5% higher in comparison with the non-filled tube. Also, Table 3 shows that
thewall thickening of the filled tube is about 2% less than for the non-filled tube. Figure 6 shows
that the filling material decreases the movement of neutral axis, so it increases tension in the
outer side of the tube and decreases the compression in the inner side of the tube. Consequently,
the outer wall thickness increases, while the inner wall thickness decreases.

Table 3.Comparison of wall thickness variations

Extrados Intrados
wall thickness wall thickness

Filled
Experimental 1.2 0.915
Numerical 1.059 0.905

Non-
filled

Experimental 1.14 0.9
Numerical 1.04 0.91

5. Conclusion

This studydealswith themakinguseof a low temperaturemetal as thefiller inside a tubeduring
the thin-walled tube bending process. A 3DFEmodel and experiments have been conducted to
study the effect of the filler on wrinkling, cross section distortion, wall thinning and thickening.
The results of nonlinear FE analysis have been verified by experimental results. According to
the results of this research, it can be concluded that:

• If the rubber core is used inside the tube, the wrinkling phenomenon and cross section
distortion could be reduced, but they could not be completely avoided in the steel tube.

• If a low temperature metal filling material is used inside the tube, the defects such as
wrinkling and cross section distortion can be completely avoided.

• Using a filling material increases the inner-tube energy and, consequently in accordance
with the low energy, it can prevent the wrinkling phenomena.

• The filling material decreases the movement of neutral axis toward the inner part of the
bending and, therefore, it increases tension in the outer side and decreases compression in
the inner side of the tube. As a result, the outer wall thickness undergoes reduction, while
the inner wall thickness decreases.

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Manuscript received March 13, 2013; accepted for print September 6, 2013