RU2280697C1 - Blast furnace tuyere with protective coating - Google Patents

Abstract

FIELD: ferrous metallurgy, namely structures of blast tuyeres for blast furnaces.

SUBSTANCE: tuyere includes inner and outer copper sleeves mutually joined on their ends by means of flange and mouth part. Three-layer protective coating is applied onto outer working surface. Such coating is deposited by means of plasma spraying of material; it includes first and second metallic layers and also third layer containing zirconium dioxide. Protective coating is applied onto the whole outer copper surface and onto end portion of inner surface at side of its mouth part. First layer of protective coating is made of molybdenum, second layer is made of nickel base refractory alloy and third layer is made of aluminum compounds and zirconium dioxide. Each layer of protective coating has thickness 0.3 - 1.5 mm. Wire is used as material for applying each layer of coating.

EFFECT: enhanced strength, increased useful life period of tuyere.

3 cl, 1 tbl, 6 ex

Description

The invention relates to the field of ferrous metallurgy, in particular, to the design of blasting tuyeres for a blast furnace, and can be used to supply blast when smelting cast iron.

Known blast tuyere of a blast furnace with a protective coating (see p. Ukraine No. 49411 A, (s. RF No. 2002129285, decl. 03.12.2001, publ. 16.09.2002, M. Cl. ⁶ C 21 B 7 / 16), including copper inner and outer cups, connected at the ends by a flange and a snout, the coating of which is applied to the outer working surface and obtained by gas-flame spraying of the material. or mixtures thereof with an admixture of 4 ± 0.2% titanium dioxide, is 1-5 mm, and the thickness of the second layer of zirconium dioxide is 0.2 mm

However, the known blasting form does not possess the necessary resistance when working in aggressive environments due to insufficient coating density, as well as the adhesion strength of the coating to the copper base. This is due to the fact that a powder is used as a sprayed material, which contains a large amount of oxides, in addition, when a flame is sprayed on a powder consisting of a mixture of particles of different sizes, the uniformity and density of the coating is broken due to the large difference between large and small particles according to the degree of melting and the speed of their movement in the spray jet. As a result, the coating has insufficient adhesion to the base, peels off, collapses, which leads to oxidation of the copper surface of the blasting tuyere and a decrease in its service life.

The closest to the claimed blasting tuyere in terms of technical nature and the achieved result is the blasting tuyere of a blast furnace with a protective coating (see Plasma spraying of blowing tuyeres of blast furnaces, Schekhter S.Ya., Reznitsky AM et al. Automatic welding, No. 1, 1988 , pp. 54-55, Naukova Dumka, Kiev), including copper inner and outer glasses, connected at the ends by a flange and a snout, a three-layer coating of which, applied to the outer working surface and obtained by plasma spraying of the material, contains metal e the first, second and third layers of the layer comprising zirconium oxide.

The first metal layer of the nickel protective coating has a thickness of 0.2 mm, the second oxide-metal layer is 0.4 mm, the third zirconia layer is 0.8 mm.

The known blowing lance is provided with a coating that is applied only to the working surface of the lance, which does not protect its copper surface from oxidation. This is due to the fact that the oxidation of the copper surface occurs primarily in that part of the lance that is placed in the blast furnace body, since it is there that the copper surface is intensively heated during the smelting of cast iron. As a result, there is an “undermining” of the coating applied to the work surface.

In addition, the coating has a low adhesion to the base, since its first layer is made of nickel, which has insufficient adhesion to the base material and the material of the next coating layer.

The use of zirconia powder as the material for spraying the third coating layer also negatively affects the quality of the coating. This is due to the fact that during the heating of zirconium dioxide at a temperature of about 1200 ° C, an endothermic reaction occurs, accompanied by shrinkage of the coating layer due to structural transformations in it. This leads to an increase in porosity, to a decrease in the density of the coating and to a violation of its integrity. As a result, the lance is not sufficiently protected from the aggressive environment and has a limited service life.

The basis of the invention is the task to improve the blasting lance of a blast furnace with a protective coating, in which the new implementation of the lance elements and their geometric parameters, as well as new materials from which the lance elements are made, provide an increase in the density of the lance structure elements, increase the adhesion strength of the coating to the base and this ensures an increase in the resistance of the blowing lance to wear and increases its service life.

The problem is solved in that in the known blasting lance of a blast furnace with a protective coating containing copper inner and outer glasses, connected at the ends by a flange and a snout, the protective coating of which is made of three layers, applied to the outer working surface, obtained by plasma spraying of the material and contains metal the first and second layers, as well as the third layer containing zirconium dioxide, according to the invention new is that the protective coating is applied to the entire outer copper surface and windows the inner part of the inner surface from the side of the snout, the first layer of the protective coating is made of molybdenum, the second is made of heat-resistant nickel-based alloy, the third layer is made of aluminum and zirconia compounds, each layer having a thickness of 0.3-1.5 mm and as a material for obtaining each coating layer used wire.

Also new is the fact that flux-cored wire is used as a wire to obtain a third layer of protective coating.

Also new is the fact that a wire containing compounds of aluminum, zirconium dioxide and silicon dioxide was used to obtain the third layer of protective coating.

A causal relationship between the set of essential features of the device and the achieved technical result is that the claimed constructive implementation of the blasting tuyere of a blast furnace with a protective coating, namely:

- supply of the blowing lance with a protective coating applied to the entire outer copper surface and the terminal part of the inner surface from the side of the snout;

- the implementation of the first coating layer of molybdenum;

- the implementation of the second coating layer of a heat-resistant alloy based on nickel;

- the implementation of the third coating layer of compounds of aluminum and zirconium dioxide;

- optimization of coating thickness;

- the use of wire to obtain each coating layer, in combination with well-known features, provides increased adhesion of the coating to the base and due to this, an increase in the durability of the blowing tuyere is achieved, and its service life is also increased.

The achievement of the specified technical result also contributes to the fact that to obtain the third layer of the protective coating as a wire used flux-cored wire.

The achievement of the specified technical result also contributes to the fact that to obtain the third layer of the protective coating used wire containing compounds of aluminum, zirconium dioxide and silicon dioxide.

Simultaneously supplying the blowing lance with a protective coating applied to the entire outer copper surface and the end part of the inner surface from the side of the snout, performing a three-layer protective coating of molybdenum, a heat-resistant alloy based on nickel and aluminum and zirconia compounds with a thickness of 0.3-1 , 5 mm, as well as obtaining a coating by plasma spraying of a wire, allows one to obtain a high-quality protective coating, to ensure the resistance of the blowing lance from wear and increase its service life.

Obtaining the first layer of a protective coating by plasma spraying a molybdenum wire provides the connection of the sprayed coating with the base, primarily due to the mechanical adhesion of the sprayed particles to the protrusions and depressions on the surface of the base formed by pre-treatment.

In addition, during the deposition of molten molybdenum particles at the moment of collision with the surface of the base, the molybdenum particles fuse with the base metal to form metal bonds. Molybdenum particles in a collision cause the base metal to melt and penetrate deeply into it with the formation of intermetallic compounds. The molybdenum layer increases the heat resistance of the coating, and is also a sublayer for applying the next coating layer, since molybdenum has increased adhesion both to the base metal and to the material of the next layer of the protective coating - a heat-resistant nickel-based alloy, which is applied to the first layer by plasma spraying the wire . Heat-resistant steels related to austenitic steels, capable of maintaining high mechanical properties when heated to significant temperatures, have high chemical and thermal stability, and have high corrosion resistance. The quality of the protective coating is also improved due to the implementation of the third layer by plasma spraying of a flux-cored wire, all components of which have a melting point in excess of 2000 ° C, and also receive a coating that is not wettable or partially wettable by liquid iron and liquid blast furnace slag, which does not enter into chemical interaction with gas phase.

The protective coating, the third layer of which is obtained by plasma spraying of a flux-cored wire, has great resistance to thermal shock, density and adhesion. This is due to the fact that at high temperatures, the calcium and aluminum oxides that make up the flux-cored wire inhibit the structural transformations occurring as a result of the endothermic reactions accompanying the heating of zirconia. Thus, shrinkage of the coating is eliminated.

The presence of silicon dioxide in the composition of the wire used to apply the third coating layer provides silicon carbide under the action of plasma and operating temperatures during operation of the blowing lance, which gives the protective coating a high density and heat resistance.

When particles adhere to each other inside the coating, the same mechanisms act as when the coating interacts with the surface of the base metal. In particular, the interaction of particles with each other is achieved through their mechanical adhesion, as well as through diffusion, epitaxy, and physical bonding under the influence of van der Waals forces. When particles adhere to each other, all these mechanisms act, which ensures an increase in the density of the coating and its adhesion to the base.

The supply of the blowing lance with a protective coating applied to the entire outer copper surface and the end part of the inner surface from the side of the snout part also provides an increase in the adhesion strength of the coating to the base. This is due to the fact that the coating protects not only the working part of the tuyere from oxidation, but also that part that is placed in the blast furnace body, since this part of the tuyere is oxidized and “undermining” of the protective coating begins if it is not protected.

It was experimentally established that the optimal thickness of each layer of protective coating is 0.3-1.5 mm. Blast furnaces of blast furnaces with a protective coating, the thickness of each layer of which is less than 0.3 mm, are destroyed during operation due to oxidation of the copper surface. In the coating, the thickness of each layer of which exceeds 1.5 mm, the adhesion strength is significantly reduced, which adversely affects the quality of the coating and reduces the operational properties of the blowing lance.

Blast furnace tuyeres, the protective coating of which is obtained by plasma spraying the wire, have an increased density, as well as the adhesion of the coating to the base, since plasma spraying of the wire allows you to continuously feed and evenly distribute the coating material along the torch of the plasma jet. As a result, the wire is evenly heated in the plasma stream, melted, and the material of each coating layer is evenly distributed over the surface. Thanks to this, a dense coating with increased adhesion is obtained. In addition, the use of wire simplifies the introduction of the sprayed material into the plasma jet, increases the utilization of the material.

Thus, a lance equipped with a coating that has a high density and adhesion to the base is protected from oxidation of the copper surface, from the action of an aggressive environment (gas, splashes of metal and slag), as well as from the mechanical effect of the charge components of blast furnace smelting.

The inventive blasting tuyere of a blast furnace with a protective coating is made as follows.

A three-layer protective coating is applied to the blowing lance, including copper inner and outer glasses, connected at the ends by a flange and a snout, made by known technology. The coating is applied to the entire outer copper surface and the terminal part of the inner surface from the side of the snout portion by plasma spraying of the wire. The first coating layer is obtained by spraying a molybdenum wire, the second layer by spraying a wire of heat-resistant nickel-based alloy, the third layer by spraying a flux-cored wire containing aluminum and zirconia compounds, or a wire containing silicon oxide. Each layer of protective coating has a thickness of 0.3-1.5 mm. The wire used to obtain the coating is a purchased product obtained in accordance with the regulatory and technical documentation (molybdenum wire - TU-48-19-203-85, wire made of KhN78T alloy, GOST 2246-70) and has a diameter of 1.6-1 , 8 mm.

Industrial tests of blowing tuyeres with a three-layer protective coating were carried out at blast furnace No. 9 of Krivorozhstal OJSC. The protective coating was obtained by plasma spraying the wire using a direct-acting plasma torch with a power of 25 kW (operating current 160 A, voltage 70 V) on the pre-treated copper surface of the tuyere, on the entire outer surface and the terminal part of the inner surface from the side of the snout.

To obtain the first layer of the protective coating, molybdenum wire was used, for the second layer, a wire made of ХН78Т alloy, for the third layer, a flux-cored wire containing Al ₂ О ₃ - 60%, AlN - 20%, ZrO ₂ - 15%, CaO (MgO ) - 5% in an aluminum alloy sheath, or a wire containing aluminum, Al ₂ O ₃ (50%), SiO ₂ , ZrO ₂ .

Blast furnace tuyeres were made with a thickness of each layer of protective coating from 0.1 to 2.0 mm.

A study was made of the effect of coating thickness on the quality of blasting tuyeres with a protective coating, namely, the adhesion strength of coatings to the substrate was determined. The results of the study are shown in the table.

In the object of the prototype (example No. 1), a protective coating is applied to the working surface of the blowing lance by plasma spraying of the powder; the first coating layer is made of nickel 0.2 mm thick, the second layer, oxide-metal - 0.4 mm thick, the third layer of zirconia 0.8 mm thick. A lance with such a coating has insufficient adhesion of the coating to the base, as a result, the coating is rapidly destroyed and does not protect the copper surface of the lance from oxidation.

Examples 2-6 show the research data of blowing tuyeres, the coatings of which are made by plasma spraying of the wire and applied to the entire outer copper surface and the terminal part of the inner surface from the side of the tuyere part of the tuyere. The thickness of each coating layer was: 0.1 mm; 0.3 mm; 1.0 mm; 1.5 mm; 2.0 mm (examples 2, 3, 4, 5, 6, respectively). The first coating layer was made of molybdenum, the second was made of heat-resistant nickel-based alloys, for example, ХН78Т, 06Х15Н60М15, Х20Н80 (for all types of wire from nickel-based alloys, similar results were obtained when studying the quality of the coating), the third layer was made of aluminum compounds and zirconium dioxide, or a layer of compounds of aluminum, silicon oxides and zirconium.

The best indicators characterizing the blowing lance and the quality of the coating were obtained by performing each coating layer with a thickness of 0.3 mm, 1.0 mm, 1.5 mm (examples 3, 4, 5, respectively). With a thickness of each coating layer of 0.1 mm, the adhesion strength of the coating to the base is insufficient, which leads to the destruction of the coating and

Table No. p / p Coating composition Thickness mm The adhesion strength of the coating to the base, MPa I layer II layer III layer I layer II layer III layer I option II option one 2 3 four 5 6 7 8 9 one. nickel oxide metal zirconium dioxide - 0.2 0.4 0.8 25 2. molybdenum XH78T Al ₂ O ₃ , AlN, Al, Al ₂ O ₃ , 0.1 0.1 0.1 18-20 ZrO ₂ , CaO SiO ₂ , ZrO ₂ 3. molybdenum XH78T Al ₂ O ₃ , AlN, Al, Al ₂ O ₃ , 0.3 0.3 0.3 40-42 ZrO ₂ , CaO SiO ₂ , ZrO ₂ four. molybdenum XH78T Al ₂ O ₃ , AlN, Al, Al ₂ O ₃ , 1,0 1,0 1,0 43-45 ZrO ₂ , CaO SiO ₂ , ZrO ₂ 5. molybdenum XH78T Al ₂ O ₃ , AlN, Al, Al ₂ O ₃ , 1,5 1,5 1,5 40-41 ZrO ₂ , CaO SiO ₂ , ZrO ₂ 6. molybdenum XH78T Al ₂ O ₃ , AlN, Al, Al ₂ O ₃ , 2.0 2.0 2.0 29-31 ZrO ₂ , CaO SiO ₂ , ZrO ₂

blowing lance, reducing the service life of the lance (example 2). Increasing the thickness of the coating reduces the quality of the coating, leading to unreasonable consumption of coating materials (example 6). Studies have shown that the optimal thickness of each coating layer is 0.3-1.5 mm, since tuyeres with such a coating have the best quality indicators.

The blasting tuyere of a blast furnace with a protective coating can be manufactured on existing equipment using known materials and means, which confirms the industrial applicability of the claimed device.

Thus, the inventive blasting tuyere of a blast furnace with a protective coating is characterized by high quality, which is achieved by increasing the density of the coating and the adhesion of the coating to the base, which ultimately allows you to protect the surface of the tuyere from aggressive media and increase its service life.

Claims (3)

1. The blasting tuyere of a blast furnace with a protective coating, containing copper inner and outer cups, connected at the ends by a flange and a snout, the protective coating of which is made of three layers, is applied to the outer working surface, obtained by plasma spraying of the material and contains metal first and second layers, and also a third layer containing zirconia, characterized in that the protective coating is applied to the entire outer copper surface and the terminal part of the inner surface from the side of the snout, the first coat the second protective coating is made of molybdenum, the second is made of heat-resistant nickel-based alloy, the third layer is made of aluminum and zirconia compounds, each layer having a thickness of 0.3-1.5 mm, and as a material for each coating layer used wire. 2. The blowing lance according to claim 1, characterized in that cored wire is used as a wire to obtain a third layer of protective coating. 3. The blowing tuyere according to claim 1, characterized in that to obtain the third layer of the protective coating, a wire containing compounds of aluminum, zirconia and silicon dioxide is used.