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Acta Polytechnica Vol. 52 No. 3/2012

Explosion Cladding of Lead on Steel

Milan Turňa1, Jozef Ondruška1, Zuzana Turňová1

1
Slovak University of Technology, Faculty of Materials Science and Technology, J. Bottu 25, 917 24 Trnava, Slovakia

Correspondence to: milan.turna@stuba.sk

Abstract

This work deals with explosion cladding of lead on steel. The welded materials and the Semtex S type explosive are

characterised. The preparation of the welded materials and the proposed welding assembly are described. The welding

parameters, the welding conditions and the fabrication of the weld overlays are discussed. The quality of the fabricated

bimetals was studied by optical and electron microscopy and by mechanical tests.

Keywords: lead, structural carbon steel, explosion cladding.

1 Introduction

As it is well known, fusion welding, soldering and
thermal cutting of lead, including metals combined
with lead, is at present prohibited in technical prac-
tice. In some cases, however, the use of lead is pos-
sible and/or unavoidable. Obvious examples are in
the military and chemical industries. Bimetals of
lead and other structural materials are interesting
for the chemical industry. Bimetals such as Pb —
structural carbon steel are attractive mainly owing
to the high corrosion resistance of lead and the suf-
ficient strength of steel. These bimetalsare used for
fabricating vessels for storing dangerous materials,
e.g. H2SO4 90 %, H2SO4 60 %, PSCl3 95 %, PCl3,
NaNO3. For storing aggressive media a lead layer on
steel 3–5 mm in thickness is used depending on the
corrosive medium. Until recently the interior of the
chemical vessels was first tinned, and then a Pb layer
was deposited on it. This procedure posed a great
health risk for the persons performing the operations

even resulting in occupational diseases. To avoid this
kind of risk solid state surfacing, namely by explosion
cladding, has been selected as a more suitable tech-
nology.

2 Experimental

The materials selected for our experiments were as
follows: 99.95% lead by STN 42 3701, and the steel
type 11 373 by STN 42 5340, S235JRG1 by EN
10025A1. Owing to its low melting point, lead is used
with working temperatures only from 150 to 170 ◦C.
Only technically pure lead is used in the chemical in-
dustry as pure lead has the highest resistance against
corrosion. The chemical resistance of lead in some
environments may be increased by the addition of a
small amount of H2SO4 to provide a protective layer
on the material surface. So-called “hard lead” is not
suitable for welding, since it causes embrittlement
of welded joints. The chemical composition of the
welded materials is shown in Tables 1 and 2.

Table 1: Chemical composition of Pb 99.95

Pb 99.95 by STN 42 3701 [wt.%]

Pb Ag Bi Cu Sb As Fe Zn Sn

min. max. max. max. max. max. max. max. max.

99.95 0.001 5 0.030 0.001 5 0.005 0.002 0.002 0.002 0.002

Table 2: Chemical composition of steel type 11 373

Steel type 11 373 by STN 42 5340 [wt.%]

C N P S –

max. 0.170 max. 0.007 max. 0.045 max. 0.045 –

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Table 3: Physical properties of lead

Physical properties of Pb 99.95

Density ρ [kg · m−3] 11 341
Elasticity modulus in tension E [MPa] (14.71 to 17.65)·10−3
Elasticity modulus in shear G [MPa] 6.865 · 10−3
Sound propagation velocity v [m · s−1] 1 200

Table 4: Mechanical properties of steel type 11 373

Selected mechanical properties of steel type 11 373

Yield point Rp0.2 [MPa] 225

Ultimate tensile strength Rm [MPa] 363 to 441

Minimum ductility A5 [%] 25

Table 5: Cladding parameters (charge thickness H, explosive density ρ, detonation velocity vd, distance spac-
ing h, setting angle of accelerated metal [◦], deviation angle of accelerated metal [◦], collision velocity vk, final
velocity v0)

No. H P vd h α ϑd vk V0 Expl.

[mm] [g · cm−3] [m · s−1] [mm] [◦] [◦] [m · s−1] [m · s−1] type
1 31.6 0.980 1 336 5.1–9.8 2.23 8.6–8.9 1 060–1070 207 SP-14

2 31.5 0.984 1 340 7.5 0 8.8 1 340 208 SP-14

3 50.8 1.090 1 454 7.2 0 12.6 1 454 343 SP-14

4 50.7 1.110 1 474 7.0–13.1 2.80 12.7–13.5 1 210–1230 351 SP-14

5 51.7 1.030 1 390 8.0–17.5 4.35 12.5–13.1 1 040–1050 320 SP-14

6 51.5 1.260 1 250 8.0–17.5 4.35 – – – SN-12

7 51.8 1.250 1 250 8.8–18.0 4.26 – – – SN-12

8 21.6 1.156 1 990 4.9–22.7 8.10 9.1–9.6 1 070–1080 332 S-25

Figure 1: Parts of the Fe–Pb binary diagram

The physical and mechanical properties of Pb
and steel needed for the welding process are presented
in Tables 3 and 4.

The parameters of the cladding process are given
in Table 5.

Prior to welding, it was necessary to make a de-
tailed study of the Pb — steel binary diagram, and to

ascertain the possibility that undesired phases might
be formed (Figure 1).

All materials to be explosion welded must be free
from impurities and organic deposits, irrespective of
the cleaning effect of cleaning agents. The weld sur-
faces on steel were machined by grinding to rough-
ness Ra = 3.2 μm, and shortly before welding they

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Figure 2: Scheme of the peel test

Figure 3: Shear test of the bimetal

were degreased with acetone. The lead was straight-
enedprior to welding, cleaned with a steel brush and
degreased with acetone.

The welding parameters are given in Table 5. The
explosives for explosion welding do not form a unified
group. They need to have specific properties for each
technological process. To achieve good process repro-
ducibility, the explosive that is used needs to have
a stable detonation regime in non-sealed charges.
Loose Semtex S type explosives were used for fab-
ricating Pb — steel bimetals. These explosives were
manufactured at RIICH Synthesia, Pardubice. After
welding, the bimetals were cleaned from detonation
products with a brush under running water and were
then prepared for further study.

The following assessment methods were applied
for our study of the quality of the fabricated bimetal
joints: ultrasonic defectoscopy, mechanical tests, cor-
rosion resistance tests and metallographic investiga-
tion.

2.1 Ultrasonic defectoscopy

The inspection was performed from the lead side.
Probe coupling was ensured by the use of oil. The
tests were performed usingthe USIP 11equipment
with a MSEB 6H probe with 6 MHz frequency. No
defects were found in the joint boundary zone. The
initial 3.2 mm thickness of the lead plate was reduced
to 2.8 to 3.0 mm owing to the high detonation veloc-
ity and compression.

2.2 Mechanical tests

The quality of the fabricated joints was assessed by
the following mechanical tests: a peel test, a shear
strength test, and a bend test.

Peel test: an ordinary shop hydraulic press was
used for this test. It must be stated that this test

is not standardised and therefore it serves only to
provide information on the boundary quality. The
scheme of the test specimens is shown in Figure 2.
The test showed that the boundary remained undam-
aged and the punch penetrated through the lead.

Shear strength test: three specimens with dimen-
sions as shown in Figure 3 were cut from the bimetals
in the direction of detonation wave propagation. Fail-
ure of the specimens occurred on the lead side. This
suggests that the lead — steel boundary is of higher
strength than the pure lead, thus proving sufficient
joint strength. The tensile strength of the initial lead
used for cladding was determined to be 12.8 MPa.

The bend test is presented in Figure 4. Similar
specimens to those used for the tensile test were ma-
chined from the fabricated bimetal. The specimen
was firmly clamped in a vice and its free end was
bent by 180◦ around a mandrel of �14 mm in diame-
ter. The specimen was placed in such a manner that
the notch face included a 30◦ angle with the normal
plane. The boundary was so strong that no dam-
age occurred even when the mandrel diameter was
reduced to �8 mm.

Figure 4: Scheme of the bend test of the bimetal

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2.3 Metallographic assessment of the
welded joints

Observation by optical microscopy showed that the
basic structure of the steel was polyhedral, locally
deformed on the boundary. The thickness of the de-
formed layer was around 0.5 mm. The measured wave
amplitude was 0.08 to 0.1 mm, and the waving period
was 0.48 to 0.53 mm. The weld boundary is shown
in Figures 5 to 8.

Figure 5: Weld boundary of the lead — steel bimetal
110×

Figure 6: Weld boundary of the lead — steel bimetal
600×

A more detailed assessment of the character of the
fractured surfaces of a Pb — steel welded joint was
performed by scanning electron microscope (SEM).
The specimens from which the lead was torn off in
the peel test were observed. It was observed that fail-
ure occurred after preliminary plastic strain, mostly
by ductile fracture. Figures 7 and 8 show the ductile

fractures in the lead which progressed to the darker
zones where insufficient bonding of materials was ob-
served. The bonding of Pb to the parent steel mate-
rial was around 55 %.

Figures 7 and 8 show the fractures after fusing
down of Pb from the steel surface in a vacuum.

Figure 7: Ductile fracture in the lead (REM) 500×

Figure 8: The lead fused from the steel surface 500×

3 Conclusions

The aim of our study was to develop and test a special
technology for lead cladding on a steel plate made of
structural carbon steel. A total of 8 bimetallic welded
joint swith dimensions of 120×120×14 mm were fab-
ricated. On the basis of our results it can be stated:

Sound welded joints were fabricated by explosion
cladding with optimum parameters. A new explo-
sive was tested and it was found to be suitable for
cladding the lead. Mechanical testing (a peel test, a
shear test, and a bend test) of the bimetals proved
their high quality. The failure of the specimens oc-
curred on the lead side during the shear test. The
boundary was so strong that no damage occurred

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even when the mandrel diameter was reduced to
�8 mm in the bend test. The peel test showed that
the boundary remained undamaged and the punch
penetrated through the lead.

On the basis of our experience and results it may
be stated that this technology is promising one for
fabricating bimetals. It is important to emphasize
that the technology we have developed posseses no
health hazards unlike the risky process of lead sur-
facing by flame.

Acknowledgement

This work was realised with support from
GA VEGA MŠ VVŠ SR and SAV. Projects No.
1/2594/12.

References

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