RU2625509C2 - Flux-additive - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: flux additive is designed for mixing with fused fluxes and can be used for submerged arc welding of steels. The flux-additive contains components in the following ratio, wt %: strontium-barium carbonatite 1-15, sodium liquid glass 25-50, dust of electrostatic precipitators of aluminium production 35-74. The dust of electrostatic precipitators of aluminium production contains, wt %: Al₂O₃ 20-46.23; F 16-26.7; Na₂O 7.6-15; K₂O 0.4-6; CaO 0.6-2.3; SiO₂ 0.5-2.48; Fe₂O₃ 2.1-3.27; C_total 12.5-30.2; MnO 0.07-0.9; MgO 0.06-0.9; S 0.08-0.19; P 0.09-0.18.

EFFECT: improved mechanical properties of welds, in particular, impact strength at temperatures below zero due to reduction of the level of contamination with nonmetallic inclusions.

1 tbl

Description

The invention relates to welding, in particular to submerged arc welding of steels, in particular to additive fluxes intended to be mixed with welding fluxes.

Known ceramic flux additive designed for mixing with fused fluxes containing marble and ferrosilicon in the following percentage ratio, wt. %: marble 30-70, ferrosilicon - the rest [1]. An aqueous solution of sodium silicate is used as a binder.

Significant disadvantages of this ceramic flux additives are:

- reduced mechanical properties of the weld due to the high gas content in the weld due to the use of carbon dioxide released only during decomposition of marble for protection, and increased contamination by non-metallic inclusions due to reduced refining properties of the resulting slag due to the increased melting point last one.

There is also known a method of steelmaking in electric furnaces, including carrying out an oxidation period with downloading slag, conducting a recovery period and deoxidizing slag during the recovery period, characterized in that at the end of the oxidation period after loading the slag, strontium-barium carbonatite, lime and fluorspar are added to the furnace the ratio (1.0-2.0) :( 2.5-5.0) :( 0.1-1.0), respectively, while the amount of slag with a basicity of 1.5-4.0 is 1.5- 4.0% by weight of the metal [2].

This method, implemented in an arc discharge in electric arc furnaces using strontium-barium carbonatite, can significantly increase the impact strength at positive and negative temperatures.

Known selected as a prototype flux additive, designed for mixing with welding fluxes, based on liquid glass, which contains dust from aluminum electrostatic precipitators and sodium liquid glass with a ratio of components, wt. %: dust of electrostatic precipitators of aluminum production 41.67-60; sodium liquid glass 58,33-40 [3].

Significant disadvantages of this ceramic flux additives are:

- unsatisfactory in some cases, the level of contamination of the weld with non-metallic inclusions and, as a consequence, a decrease in mechanical properties and, in particular, toughness values.

The desired technical result of the invention is to increase the overall level of the mechanical properties of the weld, in particular impact strength at low temperatures, by reducing the level of contamination with non-metallic inclusions.

For this, a flux additive for welding fluxes is proposed, containing dust from electrostatic precipitators of aluminum production, containing, by weight. %: Al ₂ O ₃ 20-46.23; F 16-26.7; Na ₂ O 7.6-15; K ₂ O 0.4-6%, CaO 0.6-2.3; SiO ₂ 0.5-2.48; Fe ₂ O ₃ 2.1-3.27; C _total 12.5-30.2; MnO = 0.07-0.9; MgO = 0.06-0.9; S = 0.08-0.19; P = 0.09-0.18 and sodium liquid glass, which additionally contains strontium-barium carbonatite with a ratio of components, wt. %:

strontium barium carbonatite 1-15 sodium liquid glass 25-50 dust aluminum electrostatic precipitators 35-74

The claimed limits are selected empirically based on the possibility of manufacturing a flux additive, the quality of the welds obtained during welding, the stability of the welding process and the required mechanical properties. For the manufacture of flux additives used the following materials. Dust of aluminum electrostatic precipitators with the following chemical composition, wt. %: Al ₂ O ₃ = 20-46.23; F = 16-26.7; Na ₂ O = 7.6-15; K ₂ O = 0.4-6; CaO = 0.6-2.3; SiO ₂ = 0.5-2.48; Fe ₂ O ₃ = 2.1-3.27; With _total = 12.5-30.2; MnO = 0.07-0.9; MgO = 0.06-0.9; S = 0.08-0.19; P = 0.09-0.18. BSK grade strontium-barium carbonatite manufactured by NPK Metalltekhprom LLC according to TU 1717-001-75073896-2005, while the chemical composition changed, wt. %: SrO = 1.41-6.25; BaO = 6.29-16.86; TiO ₂ = 0.02-0.05; Cr ₂ O ₃ = 0.05-0.20; Al ₂ O ₃ = 1.6-3.05; Na ₂ O = 0.37-3.02; K ₂ O = 0.85-2.69; CaO = 13.6-18.9; SiO ₂ = 12.82-41.22; Fe _total = 4.18-14.85; With _total = 1.32-8.45; MnO = 0.06-0.33; MgO = 0.48-6.24; S = 0.20-0.22; P = 0.02-0.04.

Sodium water glass had a silicate modulus value of 2.0-3.5 at a solution density of 1.30-1.60 g / cm ³ .

The manufacture of the inventive flux additives was carried out by grinding strontium-barium carbonatite to a fraction of less than 1 mm, followed by mixing with dust from aluminum electrostatic precipitators and sodium liquid glass. The resulting mixture was stirred until a homogeneous mass was obtained in the mixer, then drying was carried out at room temperature for 24 hours, after which grinding was performed. The separation of the 0.45-3.0 mm fraction was carried out. Then the granules were calcined at a temperature of 150-300 ° C. The inventive flux additive was mixed with welding fluxes AN-348A, AN-67, after which the samples were welded using an ASAW-1250 welding tractor. Technological tests were carried out when welding a weld on specimens of steel grade 09G2S with a length of at least 500 mm. For comparison, welding was performed under fluxes AN-348A, AN-60 using ceramic flux additives according to the prototype. The influence of changes in the chemical composition of components with boundary, foreign and claimed limits, as well as with the additive of ceramic flux additives according to the prototype (column 9) on the mechanical properties of the weld (temporary resistance - σ _B , N / mm ² , yield strength - σ _T , N / mm ² , elongation δ,%, impact strength at a temperature of minus 40 ° С KCU ^-40C , J / cm ² , as well as the line length of oxide non-metallic inclusions are given in the table.

Using the inventive mixture in comparison with the prototype allows to increase the overall level of mechanical properties of the weld, yield strength σ and tensile strength σ _B by 1-3 N / mm, elongation by 3%, impact strength at negative temperatures by 2-6 J / cm ² , by reducing the string length of oxide non-metallic inclusions.

List of sources of information:

1. A.S. USSR 173588 B23K.

2. Patent of the Russian Federation 2197539 C21C 5/52.

3. Pat. 2564801 RF, IPC ⁸ B23K 35/362.

Claims (2)

A flux additive for welding fluxes containing sodium liquid glass and dust of electrostatic precipitators of aluminum production, including, by weight. %: Al ₂ O ₃ 20-46.23; F 16-26.7; Na ₂ O 7.6-15; K ₂ O 0.4-6; CaO 0.6-2.3; SiO ₂ 0.5-2.48; Fe ₂ O ₃ 2.1-3.27; C _total 12.5-30.2; MnO 0.07-0.9; MgO 0.06-0.9; S 0.08-0.19; P 0.09-0.18, characterized in that it additionally contains strontium-barium carbonatite with a ratio of components, wt. %: strontium barium carbonatite 1-15 sodium liquid glass 25-50 dust aluminum electrostatic precipitators 35-74