Rev. Téc. Ing. Univ. Zulia. Vol. 44, Nº 2, May-August, 2021, 117-126

Rev. Téc. Ing. Univ. Zulia. Vol. 44, No. 2, May-August, 2021.

Relationship between SAW Coatings Composition and The

Composition of Fluxes Obtained with Steel Slag and Rice

Husk Ashes

R. Najarro

1

, A. Cruz-Crespo

2*

,

2

Centro de Investigaciones de Soldadura, Facultad de Ingeniería Mecánica e Industrial,

Universidad Central “Marta Abreu” de Las Villas, CP 54 830, Santa Clara, Cuba.

*Corresponding author: acruz@uclv.edu.cu

the elements in the deposited metal show a quadratic dependence, the carbon content (C) is ruled by graphite

composition in the flux, while the chromium (Cr), manganese (Mn) and silicon (Si) contents are ruled by the

FeCrMn content.

Keywords: abrasive wear; hardfacing; SAW fluxes; steel slags.

y Cenizas de Cascarilla del Arroz

acero con adición de cenizas de cascarilla del arroz. Se elaboraron fundentes por peletización con base en un diseño

de tipo McLean-Anderson. Con los fundentes experimentales se obtuvieron depósitos, que fueron caracterizados

químicamente. Se obtuvieron modelos de la composición de los elementos en el metal depositado en función de la

composición del fundente y fue realizado un proceso de optimización. Se concluye, que los contenidos de los

elementos en el metal depositado muestran una dependencia cuadrática, siendo el contenido de carbono (C)

gobernado por el de grafito en el fundente, mientras los contenidos de cromo (Cr), manganeso (Mn) y silicio (Si) son

gobernados por el contenido de FeCrMn.

Palabras clave: desgaste abrasivo; escorias de acería; fundente para SAW; recargue duro.

Cruz-Crespo et al . 118

Rev. Téc. Ing. Univ. Zulia. Vol. 44, No. 2, May-August, 2021.

Almost all SAW fluxes are manufactured from natural minerals. However, the use, of steel welding slags

by SAW, as raw material, is reported (Singh and Pandey et al., 2009). In the aforementioned work, welding slags of

steels by SAW process are used to obtain a new agglomerated flux, also destined for the welding of steel structures.

In previous publications by some of the authors of this work slags of the SiO

-MnO system resulting from the SAW

welding of steel structures, and slags of the Al

O

-MgO-SiO

ferrochromomanganese, were used as matrix component of a flux for SAW surfacing (Cruz-Crespo et al., 2005;

Cruz-Crespo et al., 2017; Perdomo-González et al., 2017; Cruz-Crespo et al., 2019).

viable for the production of fluxes. However, the slags from the steel refining process are suitable as raw material for

the production of SAW fluxes, since these slags practically do not contain Fe

O

2018a).

the fact that many authors report the potential of its ashes for its use in the development of new materials, especially

due to its pusollanic properties (Jarre et al., 2021).

a restricted region.

variables, the flux matrix (X

), the graphite (X

) and the FeMnCr (X

). In flux, graphite and FeCrMn constitute the

alloying system. The experimental matrix (Table 1) was obtained as follows: From the complete design matrix (12

possible combinations of variables), and after applying the normality condition ƩXi = 100 % and eliminating the

points with variables out of range; as well as when considering the coincident experimental points, only 4 valid

and 6.57 % fluorite. The matrix components were brought to a granulometry of less than 0.25 mm; while FeCrMn

and graphite were ground and sieved in a range between 0.1 and 0.25 mm. The compositions of the raw materials

used to obtain the experimental fluxes are shown in Table 2.

technical balance. To guarantee the homogeneity of the loads they were mixed in a rotating drum for 30 min.

Agglomeration was carried out by pelletizing, using sodium silicate, as binder, in a proportion of 30 % of the dry

mass. The fluxes obtained were air-dried, then sieved to a particle’s size between 0.25 and 2.0 mm, and finally

calcined in a muffle furnace at 350

C for 120 min. The percentage composition of the flux components, considering

Relationship between SAW coatings composition and the composition of fluxes 119

Rev. Téc. Ing. Univ. Zulia. Vol. 44, No. 2, May-August, 2021.

Table 1. Experimental matrix and composition of agglomerated fluxes, % in mass.

Table 2. Chemical composition, in mass %, of flux filler components.

deposit, a sample was extracted for chemical analysis, by cross section cuts in a metallographic cutter. The

Equations 1, 2, 3 and 4 reflect the behavior of the C, Cr, Mn and Si contents in the deposited metal, depending on the

flux composition variables. In all cases, the behavior is quadratic, with a high adjustment of the models for C, Cr and

Mn: R

= 96.84 % and adjusted R

= 91.56 % (p = 0.0186) for C, R

= 97.34 % for Cr (p

= 0.0034), R

= 95.56 % (p = 0.0072) for Mn. The Si model did not show a high

of around 90 %, which makes it possible to evaluate the behavioral trend.

Cruz-Crespo et al . 120

Rev. Téc. Ing. Univ. Zulia. Vol. 44, No. 2, May-August, 2021.

Relationship between SAW coatings composition and the composition of fluxes 121

Rev. Téc. Ing. Univ. Zulia. Vol. 44, No. 2, May-August, 2021.

Cruz-Crespo et al . 122

Rev. Téc. Ing. Univ. Zulia. Vol. 44, No. 2, May-August, 2021.

Cr and Mn, which are carbide formers, shift the isothermal transformation curves of austenite to the right, while

lowering the starting point of the martensitic transformation, which cause the appearance of residual austenite. Given

The contribution was determined based on the chemical composition of the alloy load components (Table 2) and

their proportions in the conformation of the experimental fluxes, considering the contribution of sodium silicate, used

as a binder (Table 1). In determining the contribution of elements to the deposit by the flux-wire system, it was

deposited metal (Table 3 and Figure 5), it is observed that there is relative correspondence for Cr, Mn and C. The

contribution of the wire-flux system differs of the composition of deposits, since oxidation-reduction processes take

place during deposition. The tendency to a certain linearity in the behavior between the contribution of the flux-wire

system and the experimental composition obtained in the deposits (Figure 5), shows that the concentration conditions

contained in the pool, according to the reactions of Equations 6 and 7, releasing iron and favoring the reduction of

provided by the flux matrix (SiO

is provided by the steel slag, by the ash and by the sodium silicate), and the

presence of Mn and C that act as deoxidizers (Equations 6 and 7), favor the reaction of Equation 5, which leads to

the increase of this element in the metal. Namely:

obtained experimentally, the transfer coefficients of the elements were determined (K

coefficient of the element to the deposited metal, E

element in the deposited metal) (Table 3). The transfer coefficient reflects the effective use of the alloying element,

provided by the consumables to obtain the deposited metal. In the case of C, Mn and Cr, since the values are lower

than one, it is confirmed that there are losses related to the oxidation of these elements. The C and Mn transfer

coefficient values, in a general exceed those frequently reported in the literature; while Cr transfer coefficient is in

In the case of Si, in correspondence with what has already been discussed about the reduction of SiO

, the transfer

Relationship between SAW coatings composition and the composition of fluxes 123

Rev. Téc. Ing. Univ. Zulia. Vol. 44, No. 2, May-August, 2021.

plan, Table 1), shows that the deposit alloying is governed by the concentration conditions.

arc, its oxidation occurs predominantly with the oxides in the liquid metal (Quintana et al., 2003).

Flux composition optimization

wire (Table 3), could satisfy the requirements for abrasive wear. However, from the point of view of the deposited

metal composition, the C and Cr contents should be the highest possible, since this favors the formation of hard

structures that limit the penetration of the abrasive material on the coating surface. The independent optimization of

of composition of the flux, so it is necessary to find a compromise condition, which can be achieved by obtaining the

function of desirability (Becerra et al., 2014).

of the “desired” function has been obtained (Figure 6). It is observed that the best results tend towards an increase in

graphite and a decrease in the matrix with high FeCrMn values, the optimum of the “desired” function being equal to

0.82, which corresponds to the following: C

= 2.45 and Cr

= 15.88 %).

the requirements for abrasive wear, corresponding to the AWS EFe5 classification, according to what was reported

Cruz-Crespo et al . 124

Rev. Téc. Ing. Univ. Zulia. Vol. 44, No. 2, May-August, 2021.

Figure 7, with the presence of needle-shaped martensite and residual austenite, indicate that the flux selected as

optimal, could be suitable for abrasive wear. Several authors, among which are Gulenc and Kahraman (2003), and

Coronado et al. (2009), carried out studies that validate the performance on abrasive wear of steels coatings, with a

similar composition and microstructure of the deposits in the present work.

austenite-light area).

Relationship between SAW coatings composition and the composition of fluxes 125

Rev. Téc. Ing. Univ. Zulia. Vol. 44, No. 2, May-August, 2021.

contents in the fluxes, show a quadratic dependence. The graphite content in the flux governs the C content in the

deposits, while the Cr, Mn and Si content are governed by the FeCrMn content in the flux. The transfer of C, Cr and

Mn to the deposit, from the flux-wire system, is manifested with losses due to the oxidation processes of these

elements, while the Si content in the deposited metal is higher than that provided, due to the reduction of SiO

present in the slag.

and the presence of residual austenite. From the optimization process to maximize C and Cr, the flux with the best

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