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Interface Microstructure Investigation of Babbitt-
Carbon Steel Composite Using Flux with Glycerol 

and Petroleum Jelly Additives 
 

Naglaa Fathy 
Department of Physics 

College of Science  
University of Hail 
Hail, Saudi Arabia 

naglaaf2002@yahoo.com 
 

 

Abstract—The influence of adding glycerol and petroleum 
jelly during the tinning process of steel shell base of Babbitt-steel 
bimetal is studied in this paper. The morphology of interface 
layer is changed from a discontinuous layer in case of using 
flux+tin to a continuous one by adding glycerol or petroleum jelly 
to the flux+tin mixture. Also, the nterface layer thickness and the 
unbonded interface layer area increase by adding glycerol or 
petroleum jelly to flux+tin mixture due to their physical 
properties. 

Keywords-Babbitt; steel; flux; glycerol; petroleum jelly 

I. INTRODUCTION 
Depending on the specific application requirements 

(corrosion resistance, wear resistance, electrical conduction, 
etc.), the working face layer of a bimetal should be 
characterized by high performance properties [1-3]. Tin-based 
Babbitt alloys are usually used as working surface layers, 
especially in sliding bearings. Tin-based Babbitt alloys are 
mainly composed of Sn–Sb–Cu containing about 0.5–8% Cu 
and less than 8% Sb. The microstructures of tin-based Babbitt 
alloys are characterized by a solid solution matrix in which 
needles of Cu6Sn5 copper-rich constituent and fine, rounded 
particles of precipitated SbSn are distributed. The proportion of 
the copper rich constituent increases with copper content 
containing about 0.5–8% Cu and higher percentage of Sb and 
Sb which exhibit primary cuboids of SbSn, beside copper-rich 
constituent in the matrix [4-6]. Although, Babbitt-steel bimetal 
alloys are widely used materials for sliding bearings, the 
production of high performance Babbitt-steel bimetals still 
needs more effort due to the poor wettability of the steel with 
Babbitt alloy. Fluxing and tinning processes are usually used to 
improve the adhesion of the Babbitt layer on steel substrate [7, 
8]. Usually, after grinding the surface of the steel substrate 
shell, it is briefly immersed in multi-chlorides aqueous flux 
solution (24kg zinc chloride, 6 kg sodium chloride, 3kg 
ammonium chloride, 1L HCI, and enough water to make 100L) 
for 60 seconds followed by coating of the steel surface with 
either pure tin (Sn) or a Sn-lead alloy (called tinning process) 

to promote adhesion between the bearing and the Babbitt metal 
[7, 8].  

The current study is investigating the interface 
microstructure of Babbitt-steel by using a mixture of powder 
tin, flux and glycerol and a mixture of powder tin, flux and 
petroleum jelly additives. The mixing of the powder tin with 
flux as one direct tinning process is successfully used for 
fabricating Babbitt-steel bimetal composite that is promising 
for flat and horizontal bearing applications [9]. Glycerol and 
petroleum jelly are added to the tin-flux mixture to facilitate 
tin-flux application for curvature surface steel shells. 

II. EXPERIMENTAL WORK 
Carbon steel base specimens with a chemical composition 

that is shown in Table I of dimension 400x400x9mm3 are 
grinded with sand papers of 240 and 320-grit for two minutes 
each. The homemade flux is prepared using the chemicals 
listed in Table II mixed with the tin powder. The tin to flux 
ratio is 1:5 (1g of tin, and 5g of flux). The necessity of using 
flux in bimetal production is the fact that the oxides which 
always form up on all the brightened metal surfaces prevent the 
proper joining of the pieces. The flux by removing the oxides 
allows the tin to stick directly to the metal. 

TABLE I. STEEL CHEMICAL COMPOSITION (WT %) 

C Mn Cr Ni Cu Fe 
0.15 0.33 0.03 0.05 0.02 Bal. 

TABLE II. FLUX CHEMICAL COMPOSITION WT %, ML. 

ZnCl2 NaCl2 NH4Cl HCl H2O 
24g 6g 3g 1ml 1ml 

 
In the current research work, fluxing and tinning processes 

are merged in one step by mixing the flux with the tin powder. 
This research work aims to study the effect of the homemade 
tinning mixture of flux with glycerol and petroleum jelly 
additives on tinning quality and bonding characteristics of the 



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steel Babbitt bimetal. Influence of the different tinning 
mixtures on the microstructure mechanical properties and 
bonding characteristics of the carbon steel Babbitt bimetal is 
studied for three groups of samples  

 The first group of steel Babbitt bimetal was produced using 
flux+ tin(5:1 ratio). 

 The second group was produced using homemade 
flux+tin+glycerol (ratio 4:1:1) 

 The third group was produced using homemade 
flux+tin+petroleum jelly (vaseline) in a ratio of 4:1:1. 

Glycerol and petroleum jelly are used to study their effects 
on the evaporation process, the homogeneity of the tinning 
mixture, and how it holds the flux in its place. If the flux is 
easy to distribute and able to hold in its place, this will make it 
good for curved surfaces. In the tinning process 1g of the 
tinning mixture is distributed on the steel base shell. Then the 
base is placed on a preheated hot plate of 360oC for 5min. After 
heating time the steel shell is removed from the hot plate and 
the tinned surface is cleaned using towel and tap water. Then 
the samples are cooled to room temperature. Babbitt metal with 
the chemical composition shown in Figure 3 is melted in an 
electrical furnace at 4000C. After holding for about 30min the 
crucible of molten metal is removed from the furnace and is 
poured onto metallic mold containing a preheated (at 3600C for 
7min.) tinned steel shell. The volume of liquid Babbitt to solid 
steel ratio is kept to be 1:1. 

TABLE III. CHEMICAL COMPOSITION OF THE BABBIT TIN BASE ALLOY 

Element Sb Cu Sn 
Wt.% 6.5-7.5 2.5 Bal. 

 
In order to reveal the microstructure of the bimetal interface 

region between the Babbitt and the carbon steel base, 
metallographic examination is conducted by optical 
microscopy. Optical examination is conducted after grinding, 
polishing, and etching with 4% nital to define any 
discontinuities, crack, lack of bonding, voids, holes etc. The 
measurements were taken for as cast samples of the three 
groups of the carbon steel Babbitt bimetal.  

III. RESULTS AND DISCUSSION 
It is reported in [7] that the microstructure of Babbitt has a 

significant influence on the operating life of lined bearings. For 
Sn based Babbitt, the percentage of Sb and Cu alloyed with Sn 
controls the microstructure constituents. In the current study 
(see Figure 1(a)) and previous ones [4-6] it is reported that tin-
based Babbitt alloys that contain about 2.5% Cu and about 6.5-
7.5% Sb usually have a microstructure of a solid solution 
matrix, distributed needles of Cu6Sn5 copper-rich constituent 
and rounded particles SbSn precipitate. The strength and 
hardness of Babbitt with a fine-grained microstructure is 20% 
higher than that of a Babbitt with a coarser-grained 
microstructure. It is reported in [10] also that the shear stress 
and ultimate strength of the bond between the Babbitt alloy and 
the metal shell are higher for the fine-grained Babbitt compared 
with the coarse one. 

(a) Babbitt microstructure 

(b) Steel base microstructure 

Fig. 1.  Microstructures of Babbitt steel base region. 

Figure 1 shows the microstructures of the Babbitt alloy and 
the steel base regions. The microstructure of steel region shows 
mainly ferrite matrix and some pearlite due to lower carbon 
percentage. For all the conditions of bimetal casting in the 
current research, microstructures of Babbitt working surface 
and steel solid base show the same constituents. Figure 2 shows 
the interface microstructure of as-cast Babbitt-steel bimetal for 
three different groups after applying fluxing and tinning 
processing conditions. Group 1 shows the interface 
microstructure of the sample prepared using flux and tin. Group 
2 shows the interface microstructure of the sample prepared 
using flux, tin and glycerol. Group 3 shows the interface 
microstructure of the sample prepared using flux, tin and 
petroleum jelly. It is clear that addition of glycerol and 
petroleum jelly to the mixture of flux and tin has a significant 
effect on the morphology of the interface zone of Babbitt- steel 
bimetal castings. Using flux+tin produces a discontinuous 
interface layer, while by using additions of glycerol or 
petroleum jelly produces a continuous interface layer. Figure 3 
shows the effect of flux type on interface layer thickness for 
samples prepared using flux+tin, flux+tin+glycerol and 
flux+tin+petroleum jelly. It is clear that by using flux+tin 
(Group 1) a minimum interface layer thickness of 150m is 
achieved. The addition of glycerol or petroleum jelly to 
flux+tin increases the interface layer thickness that reaches 
about 240m for the glycerol addition case.  

It is reported in [11-12] that the bonding energy of the 
bimetal interface when using Sn as an intermediate layer is 
relatively 10% larger compared to that of the bimetal interface 
without a Sn layer. So, Babbitt and steel bimetal interfacial 
bonding performances with an intermediate layer of Sn are 
better than those of an interface without Sn layer. In the current 



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research, by the addition of glycerol or petroleum jelly, a 
continuous interface Sn layer is achieved instead of the 
discontinuous Sn layer in the case of flux+tin only. This means 
that the addition of glycerol or petroleum jelly is stronger and 
more stable during pouring the molten Babbitt on the tinned 
steel base. Our current gravity casting technique is still the 
standard method of applying Babbitt to bearing steel shells. 
This process involves the use of a preheated tinned steel shell. 
Many process parameters should be considered in order to 
fabricate a high performance and long life Babbitt-steel bimetal 
bearing. One parameter of most importance is the tinning 
process. The optimization of the tinning process is essential for 
achieving a good strength bond between Babbitt and steel shell. 
Although, the addition of glycerol and petroleum jelly to the 
flux and tin mixture stabilized the Sn layer, the unbonded area 
increases (see Figure 4), although further research on the 
optimum percentage should follow.  

 

(a) Flux+tin 

(b) Flux+tin+glycerol 

(c) Flux+tin+petroleum jelly  

Fig. 2.  Interface microstructure of three samples made by using different 
combinations of flux, tin, glycerol and petroleum jelly.  

 
Fig. 3.  The effect of flux type on the tin layer thickness for samples 
prepared using flux+tin, flux+tin+glycerol and flux+tin+petroleum elly.  

 

(a) 

(b) 

Fig. 4.  Microstructure of Babbitt bimetal for samples prepared using a) 
Flux+tin+petroleum jelly b) Flux+tin+glycerol 

The typical interface microstructures of as-cast samples 
with addition of glycerol and petroleum jelly are shown in 
Figure 4. The addition of glycerol or petroleum jelly to flux+tin 
mixture increases the unbonded interface area (Figure 5). The 
largest unbonded area is observed by addition of glycerol to the 
flux+tin mixture. The interface has partial joint, which is 
characterized by the presence of the so-called “bimetallic 
connecting bridges” or unbounded areas. It is believed that the 
unbounded areas are a result of the gases produced by the 
combustion of glycerol or petroleum jelly residuals in the 
tinning layer during the preheating process and pouring of the 
Babbitt. It is well known that petroleum jelly and glycerol are 
not physically similar. Petroleum jelly is mainly a non-polar 
hydrophobic hydrocarbon and insoluble in water otherwise 
glycerol is mainly an alcohol that is strongly hydrophilic. This 
means that petroleum jelly is water-repelling material and on 
the other side glycerol is water-attracting material. The 
physical properties of glycerol explain that why large unbonded 

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Flux + Tin +
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Flux + Tin
 

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areas are observed by adding it to the flux+tin mixture. 
Petroleum jelly is flammable only when heated to liquid. Its 
product fumes are light. Generally, glycerol is considered to be 
a crucial part of the production of antifreeze and waxes. Also it 
is used to generate resins, paints and waxes, for creating 
cleaning and purifying agents for soldering. Residual glycerol 
and/or petroleum jelly in the preformed tinned surface layer 
have great influence on the morphology and the formation of 
unbonded areas in the interface between Babbitt and steel. This 
effect is significant in adding glycerol due to its attractive 
nature for water besides producing fumes after pouring molten 
Babbitt metal. 

 

 

Fig. 5.  The effect of flux type on unbonded interface area 

IV. CONCLUSIONS 
The effect of adding glycerol and petroleum jelly to 

flux+tin mixture on interface morphologies of Babbitt-steel 
bimetal composites was investigated. Based on the obtained 
results, the main conclusions can be summarized as: 

 The morphology of the interface layer is changed from 
discontinuous in case of using flux+tin to continuous by 
adding glycerol or petroleum jelly to the mixture. 

 The thickness of the interface layer increases by addition of 
glycerol or petroleum jelly to the mixture. 

 Unbonded interface layer area increases by the addition of 
glycerol or petroleum jelly to flux+tin mixture due to their 
physical properties. 

 More future investigations using a small percentage 
addition of glycerol or petroleum jelly to flux+tin mixture, 
long tinning heating time and higher Babbitt pouring 
temperature are needed to improve the quality of interface 
bond between Babbitt and steel alloys. 

ACKNOWLEDGMENT 

The author would like to thank Dr. Mohamed Ramadan of 
Casting Technology Lab., Manufacturing Technology Dept., 
CMRDI, - Egypt for the useful discussion and technical 
support. 

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