ang_PS 10 2018


37welding technology review vol. 90  10/2018

The effect of the parameters of submerged arc surfacing  
with oscillating electrode on a padding weld forming, depth  
of fusion penetration and the content of parent metal in a weld 

prof. dr hab. inż. Igor A. Riabcew, Anatolij A. Babiniec, Iwan P. Lentjugow – E.O. Paton Electric Welding Institute of the National Academy  
of Sciences, Kiev, Ukraine; 

Corresponding author: ryabtsev39@gmail.com

Introduction

It is known that in some cases, in order to reduce the met-
al penetration of the material and to obtain wide and relative-
ly short runs, arc welding is carried out with the pendulum 
movement of the electrode wire or tape [1÷4]. In these works, 
fundamental attention was paid to studying the influence  
of the amplitude and frequency of fluctuations in the elec-
trode wire or tape on the formation of pad weld runs. How-
ever, if we take into account the fact of the direct interaction 
of the welding arc with the parent material during lateral 
fluctuations of the electrode wire, it should be expected 
that the character of metal penetration can change along 
the length of the pad weld runs. As stated earlier [5,6], une-
ven metal penetration can lead to a decrease in fatigue life  
of surfaced elements during their operation under cyclic 
loading conditions.

The analysis shows that if the electrical parameters of 
the surfacing process are not taken into account, the ampli-
tude and frequency of the electrode wire or tape fluctuations  

Igor A. Riabcew, Anatolij A. Babiniec, Iwan P. Lentjugow 

as well as the surfacing speed have a fundamental influence 
on the above characteristics of pad weld runs. Moreover, all 
these characteristics are interrelated, and when changing 
one of them, two other characteristics have to be corrected 
in order to obtain qualitative pad weld runs. 

The purpose of this work was to study the impact of the 
submerged arc surfacing speed, frequency and amplitude of 
wire fluctuations on the forming of padding welds, depth and 
character of metal penetration of the native material, and co-
efficient of the contribution of native material in the surfaced 
layer (degree of mixing γ).

In the further part of the article, the term is used: intermix-
ing of the padding weld with parent material (also referred to 
as transition zone, fused zone, mixing zone) – this is a zone 
with variable chemical composition, which arises due to a sig-
nificant difference in the chemical composition of the com-
bined materials. The chemical composition of the padding 
weld at the border with the base material changes stepwise.

Abstract

The effect of oscillating movement amplitude and frequency of elec-
trode wire swinging on forming of pad weld runs, the character of parent 
metal penetration, as well as structural and chemical inhomogeneity  
in the zone of intermixing padding weld with parent material has been 
tested while submerged arc surfacing using oscillating electrode. It has 
been stated that along with increasing frequency of electrode wire end 
oscillations and the same amplitude and surfacing speed, the weld run 
formation is improved, the width of the zone of padding weld intermix-
ture with parent material is reduced and more dispersive structure with 
lower structural and chemical inhomogeneity in a padding weld is be-
ing formed. More uniform fusion penetration into the parent material  
and alignment of fusion line can be observed. Those relations remain 
practically unchanged with increasing amplitude of oscillation. 

Keywords: 
submerged arc surfacing with oscillating electrode; 
run formation; 
inhomogeneity of padding weld metal

DOI: http://dx.doi.org/10.26628/ps.v90i10.949



38 welding technology review vol. 90  10/2018

Table I. The effect of surfacing speed, amplitude A and oscillation of electrode wire frequency N on the dimensions of surfaced runs  
and ratio of mixture γ 

Sample no
Fluctuations

Surfacing 
speed, m/h

Dimensions of the runs, mm
γ, %

А, mm N, min-1 Width Height
Amount  

of penetration

1 25 28 7 38.8 3.4 1.7 39

2* 25 45 7 36.4 2.95 1.6 37

3 40 18 7 46.8 2.05 1.8 54

4 40 32 7 47.0 1.8 1.5 50

5 25 28 10 37.5 1.9 1.8 55

6 25 45 10 35.8 2.7 1.5 52

7 40 18 10 42.6 2.1 1.5 50

8 40 32 10 44.7 1.5 1.4 49

Note: * – sample surfaced at the optimum settings of the technological parameters of the process was marked

Fig. 1. Longitudinal macroscopic microsections of samples surfaced 
with speed of 7 m/h: а) sample 1: А = 25 mm; N = 28 min-1; b) sample 2: 
А = 25 mm; N = 45 min-1; c) sample 3: А = 40 mm; N = 18 min-1; d) sam- 
ple 4: А = 40 mm; N = 32 min-1. Samples numeration – see Table I

1a)

2b)

3c)

4d)

Technological conditions of surfacing 

The tests were carried out using PP-Np-25H5FMS flux-
cored wire (ПП-Нп-25Х5ФМС) according to GOST 26101-84 
(EN 14700 T Fe8 classification) with a diameter of 2.6 mm 
and AN-26 flux (АН-26) according to GOST 9087-81. The che- 
mical composition of the weld metal corresponds to the tool 
steel 25H5MSGF. Parameters of surfacing: current intensity 
320 A, arc voltage 32 V, wire feed speed – 3.0 m/min, wire 
extension – 20 mm, surfacing speed (Vn) – 7 and 10 m/h,  
frequency of fluctuations (N) – 18; 28; 32 and 45 min-1; am-
plitude of fluctuations (A) – 25 and 40 mm. The tests were 
carried out on eight samples of S235JR steel of identical di-
mensions (Tab. I).

Process and results of the tests 

The beginning and the section with the crater were cut off 
from the pad weld runs. Next, longitudinal and transverse 
macrospecimens were made from each pad weld run to de-
termine the dimensions of runs, the degree of mixing γ and to 
study macro- and microstructure of runs. Dimensions of all 
tested runs, determined on transverse macrospecimens with 
an accuracy of 0.1 mm (average value of 5÷7 measurements) 
and degree of mixing are given in Table I.

The minimum degree of mixing at 37÷39% was found 
in samples 1 and 2, amount of penetration – 1.6÷1.7 mm. 
Smaller penetration – 1.4÷1.5 mm, found in samples 7 and 8, 
but the degree of mixing is 49÷50%.

The tests have shown that, according to the total assess-
ment of the dimensions of pad weld runs and the degree 
of mixing, samples 2 surfaced at a speed of 7 m/h, fluctu-
ation amplitude of A = 25 mm, and fluctuation frequency  
of N = 45 min-1 had the best indicators (see Tab. I). 

Figures 1 and 2 present the macrostructure of longitudi-
nal specimens of pad weld runs made at the speed of 7 and  
10 m/h, with different frequency and amplitude of fluctua-
tions. At a surfacing speed of 7 m/h, increasing the frequency 
of fluctuations in the electrode wire makes it possible to ob-
tain a more even penetration and a more fluid line of padding 
weld penetration with the parent material (Fig. 1b and 1c).  
The most even penetration line is observed in sample 2, sur-
faced at fluctuation amplitude of 25 mm and a maximum  
frequency of 45 min-1 (Fig. 1b).



39welding technology review vol. 90  10/2018

Fig. 2. Longitudinal macroscopic microsections of samples surfaced 
with speed of 10 m/h: а) sample 5: А=25 mm; N=28 min-1; b) sample 
6: А=25 mm; N=45 min-1; c) sample 7: А=40 mm; N=18 min-1; d) sam-
ple 8: А=40 mm; N=32 min-1. Samples numeration – see Table I

With an increase in the surfacing speed up to 10 m/h, an 
even penetration was not obtained at any frequency and am-
plitude of fluctuations in the electrode wire (Fig. 2a to 2d).  
At the same time, during the welding with increased speed 
(10 m/h), the increase in the frequency of electrode wire fluc-
tuations also promotes a more even penetration and greater 
„smoothness” of the fusion line (Fig. 2b and 2c), however this 
effect is lower than at the surfacing speed of 7 m/h.

Investigation of the microstructure of the padding weld of 
sample no 1 (Vn = 7 m/h, А = 25 mm, N = 28 min-1) showed that 
it has a dendritic structure (Fig. 3a). In the near-surface lay-
ers of padding weld a microstructure of cellular structure pre-
vails, with an average grain diameter of 60÷80 μm. The hard- 
ness of the matrix material, determined by the Vickers meth-
od according to GOST 9450-76, is HV1 = 5420÷6060 MPa  
(martensite + carbides). The hardness of the matrix material, 
determined by the Vickers method according to GOST 9450-
76, is HV1 = 5420÷6060 MPa (martensite + carbides).

At the crystallite boundary there is a precipitation of spher-
ical carbide chains (Fig. 3b). The structure of the surfaced 
metal of sample no 2 (Vn = 7 m/h, А = 25 mm, N = 45 min-1)  
– dendritic-cellular with a predominance of cellular (Fig. 3c), 
with a mean diameter of crystallites of 30÷40 μm. With the 
fusion line in the native material the structure becomes 
dendritic. The width of crystallites in this zone is 70÷90 μm. 
Hardness of the matrix material HV1 = 4880÷5480 MPa.  
At the crystallite boundaries, as well as in sample no 1, spher-
ical finely dispersive carbides are released (Fig. 3d). The HAZ 
has a width of 3600 μm. 

The microstructure of the padding weld metal of sample 
no 3 (Vn = 7 m/h, А = 40 mm, N = 18 min-1) – dendritic-cellular 
with a cellular predominance on the surface (Fig. 4b). The 
average cell diameter is 50÷60 μm. Hardness of the matrix 
material – HV1 = 6060÷6130 МPa. A martensite band was 
observed at the fusion line from the padding weld side. Mar-
tensite in this zone is formed in the form of large needles. 
The width of crystallites at the fusion line is 70÷80 μm. Width 
of HAZ – 2100 μm.

The padding weld of sample no 4 (Vn = 7 m/h, А = 40 mm, N 
= 32 min-1) also has a dendritic-cellular structure, with a cellu-
lar form predominance on the surface. Diameter of the cells 
is 40÷50 μm (Fig. 4b and 4d). At the fusion line – dendritic 
structure, the width of crystallites in this area is 60÷80 μm. 
The hardness of the crystalline matrix in a given area is low-
er than in sample No. 3 and is HV1 = 5140÷5420 MPa. Width  
of HAZ – 1800 μm.

Fig. 3. Microstructure of padding weld samples 1 (а, b) and 2 (c, d): а, c – fusion penetration zone, х20; b, d – padding weld metal, х100. Elec-
trolytic etching in chromic acid. Uхх=20 V; t=3÷5 s. Samples numeration – see Table I

5

6

7

8

a)

b)

c)

d)

a) b) c) d)



40 welding technology review vol. 90  10/2018

Fig. 4. Microstructure of padding weld samples 3 (а, b) and 4 (c, d): а, c – fusion penetration zone, х20; b, d – padding weld metal, х100. Elec-
trolytic etching in chromic acid. Uхх=20 V; t=3÷5 s. Samples numeration – see Table I

Examination of the microstructure of sample no 5 (А=25 mm, 
Vn=10 m/h, N=28 min-1) showed that it has a dendritic struc-
ture (Fig. 5b). The cellular structure prevails in the near-surface 
layers of padding weld, with an average diameter of 60÷80 μm. 
The hardness of the matrix is HV1 6860 MPa (martensite).  
Diameter of the cells in the upper part of the padding weld is 
15÷20 μm; width of crystallites h – 15÷25 μm, HAZ – 1200 μm.

The microstructure of the sample no 6 (Vn=10 m/h, А=25 mm,  
N=45 min-1) are shown in figures 5c and 5d. It also has a den- 
dritic structure with a cellular structure in the near-surface 
layers. Diameter of the cells – 25÷35 μm; width of crystallites  
h – 25÷50 μm, HAZ – 800÷900 μm. There are precipitations of 
intermetallic phases and carbides on the boundaries of crys-
tallites and cells. Microhardness HV1 6810 MPa in a bright lay-
er and HV1 6340 MPa in a dark layer.

Examination of the microstructure of sample no 7 (Vn=10 m/h,  
А=40 mm, N=18 min-1) showed that it has a dendritic struc-
ture (Fig. 6a and b). Diameter of the cells – 40÷60 μm; Crys-
tallite crystallite width – 40÷60 μm, HAZ – 1000÷1200 μm. 
Microhardness – HV1 6420 МPa. There are precipitations at 
the boundaries of crystallites and cells, but there are far few-
er of them than in the samples shown in Figure 5.

The microstructure of the padding weld metal of the sam-
ple no 8 (Vn=10 m/h, А=40 mm, N=32 min-1) is also dendrit-
ic-cellular (Fig. 6c and 6d). Diameter of the cells – 15÷30 μm;  
width of crystallites h – 30÷40 μm, HAZ – 600÷800 μm.  
The chemical and structural inhomogeneity of the 25H5FMS 
type alloy surfaced on S235JR steel was examined by mi-
crorentgenospectral analysis, X-ray diffraction analysis and 
metallographic analysis. The results of the microrentigeno-
spectral analysis of the alloying elements showed that the 
width of the fusion zone with the base material (transition 
zone) decreases with the increase of the frequency of fluctua-
tions (Tab. II). With a surfacing speed of 7 m/h, electrode wire 
fluctuation frequency N=28 min-1 and amplitude А=25 mm, the 
width of the transition zone is 35÷40 μm, and at N=45 min-1 
– 20÷25 μm (Tab. II , samples 1÷4). At А=40 mm and frequen-
cies N=18 min-1 and N=32 min-1, the width of the transition 
zone is 30÷35 μm and 15÷20 μm.

In the fused zone there is a smooth change in concentra-
tion, the chemical heterogeneity of the weld metal is insignif-
icant and amounts to Crmax/Crmin=1.23÷1.47 for chromium, 
and Momax/Momin=1.21÷1.31 for molybdenum. Increasing the 
frequency of fluctuations in the electrode wire favors obtaining 

a) b)

c) d)



41welding technology review vol. 90  10/2018

Fig. 5. Microstructure of padding 
weld samples 5 (а, b) and 6 (c, d):  
а, c – fusion penetration zone, 
х20; b, d – padding weld metal, 
х100. Electrolytic etching in chro-
mic acid. Uхх=20 V; t=3÷5 s. Sam-
ples numeration – see Table I

a) b)

c) d)

Table II. Effect of oscillation electrode surfacing parameters on the microstructure and chemical inhomogeneity of samples 1÷8

Sample 
no 

Surfacing conditions Microstructural state parameters
Indicators of chemical heterogeneity 

according to Cr and Mo

Vn, 
m/h

А, 
mm

N, 
min-1

dkomórki, 
μm

Width of the 
transition zone, μm

Microhardness 
HV1, МPа

Crmax/Crmin Mоmax/Momin

1 7 25 28 60÷80 35÷40 5420÷6060 4.5/3.4=1.32 0.32/0.25=1.28

2* 7 25 45 30÷40 20÷25 5420÷5480 4.8/3.9=1.23 0.40/0.33=1.21

3 7 40 18 50÷60 30÷35 6060÷6130 3.4/2.3=1.47 0.42/0.32=1.31

4 7 40 32 40÷50 15÷20 5140÷5400 3.1/2.2=1.41 0.35/0.28=1.25

5 10 25 28 25÷35 35÷40 6800 4.2/3.1=1.35 0.41/0.30=1.36

6 10 25 45 15÷20 20÷25 6700÷6800 4.6/3.2=1.44 0.38/0.30=1.26

7 10 40 18 40÷60 30÷35 6400÷6300 3.8/2.9=1.31 0.42/0.34=1.23

8 10 40 32 15÷30 15÷20 6340÷6810 3.5/2.4=1.46 0.34/0.28=1.21

Note: * – sample surfaced at the optimum settings of the technological parameters of the process was marked



42 welding technology review vol. 90  10/2018

Fig. 6. Microstructure of padding weld samples 7 (а, b) and 8 (c, d): а, с – fusion penetration zone, х20; b, d – padding weld metal, х100. Elec-
trolytic etching in chromic acid. Uхх=20 V; t=3÷5 s. Samples numeration – see Table I

a dispersive structure, a more even distribution of alloying 
elements, a more „smoothed” fusion line, as well as increas-
ing the homogeneity of the chemical composition of the sur-
faced metal. The hardness of the matrix is 5140÷6060 MPa.  
In the surfaced samples, Сr7С3 and Fe3C carbides, as well 
as intermetallic phases of the Mo5Cr6Fe18 type were found.

With the increase of the surfacing speed to 10 m/h a simi-
lar relationship is observed (Tab. II, samples 5÷8). Increasing 

the frequency of fluctuations reduces the width of the tran-
sition zone, the chemical heterogeneity of the weld metal is  
Crmax/Crmin=1.31÷1.46 for chromium, and Momax/Momin=1.21÷1.36 
for molybdenum. The matrix hardness in this case is slightly 
higher and amounts to 6340÷6810 MPa.

a) b)

c) d)



43welding technology review vol. 90  10/2018

Literatura
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Conclusions

The tests carried out on the influence of the submerged arc surfacing with oscillating  electrode on the padding weld prop-
erties have shown that as the frequency of fluctuations in the electrode wire increases, at the same amplitude of the oscillating 
movements and the surfacing speed:
– surfacing formation is improved;
– the homogeneity of the chemical composition of the surfaced metal increases, and the more dispersive structures are 

obtained;
– the width of the fusion zone with the parent material is reduced;
– a more even distribution of alloying components occurs;
– there is a more even penetration and „alignment” of the fusion zone of padding weld with the parent material.

It should be noted that these relationships practically do not change as the amplitude of fluctuations increases. Optimal 
parameters of padding weld forming, penetration depth and degree of mixing as well as structural and chemical homogeneity 
are ensured in test conditions at the frequency of electrode wire fluctuations of N=45 min-1, amplitude А=25 mm and welding 
speed of Vn=7 m/h.

[4] Goloborodko Zh.G., Dragan S.V., Simutenkov I.V.: Automatic submerged 
arc surfacing of structural steels with transverse high-frequency move-
ments of electrode, The Paton Welding Journal, N 6, pp. 34-37, 2013. 

[5] Рябцев И.А., Бабинец А.А.: Усталостная долговечность многослойных 
наплавленных образцов, Сварочное производство, № 4, c. 15-19, 
2015.

[6] Babinets A.A., Ryabtsev I.A., Kondratiev I.A., Ryabtsev I.I., Gordan G.N.: 
Investigation of thermal resistance of deposited metal designed for resto-
ration of mill roll, The Paton Welding Journal, N 5, pp. 16-20, 2014.