RU81202U1 - CONVERTER STEEL EXCHANGE - Google Patents

Abstract

The utility model relates to ferrous metallurgy, namely to refractory linings of converters, and more specifically to the designs of steel-releasing units of converters.

The technical problem to which the utility model is directed is to increase the operational reliability of the steel outlet block and increase its durability, as well as the stability of the axis of the notch, with the guarantee that the neutral gas jet gets the slag cut-off mechanism into the steel outlet.

The technical problem is achieved due to the steel outlet block of the converter, made of socket blocks used to install blocks of through refractory coils, according to the utility model, the outer side of the coils is made conical with a slope angle of 5-30 ° and is directed by the narrowing part inside the converter.

Description

The utility model relates to ferrous metallurgy, namely to refractory linings of converters, and more specifically to designs of steel outlet openings of converters.

The cost of refractories is a significant item of the cost of redistribution in the converter steel production. The service life of the lining of units is largely determined by the resistance of the flight unit's refractories. Their frequent failure during the campaign forces the converter to stop for laborious repairs, often accompanied by a loss of structural strength of the upper sections of the lining.

In recent years, in world practice, the lining of converters and flight units are made of periclase-carbon refractories, which increased the lining resistance to 2-5 thousand melts and more [1, Boychenko BM, Velichko AG et al. Current trends in the development of converter steel production in the world and in Ukraine. Steel. 2002. No. 8. p.20-24].

However, with high durability of the lining of converters, the durability of the best flying units does not exceed 90-100 heats.

There are known flying units of converters made of different refractory bricks, with the near-year space lined with perelase-carbon refractory, and the flying box lined with magnesite brick, while the direction of the stream of steel is a broken profile [2, Takhautdinov RS, Nosov AD et al. Improving methods for monitoring the operation of the converter lining. Proceedings of the Seventh Steelmakers Congress. Ed. OJSC "Chermetinformation. 2003. p. 89-93.].

A lining of the converter tuyere belt is known, containing chromomagnesite backfill and masonry of tuyere refractory blocks and refractory blocks, in which the refractory blocks placed above and below the tuyere refractory blocks are displaced from the fire surface of the lining towards the reaction space with the formation of a cavity filled with refractory masses the amount of displacement of each refractory block relative to the tuyere refractory block is 15-25% of its length (3, a.s. of the USSR No. 1349422, class F27D 1/00, С22В 15/06, 1985)

A disadvantage of the known lining is that it does not exclude the penetration of the melt to the converter through the seams of the masonry of the tuyere refractory blocks, especially at the final stage of its operation in the event of the destruction of the refractory material with which cavities are filled from the side of the reaction space. In addition, in the event that the masonry leaves the refractory blocks from standing, the latter is not completely consumed in order to prevent the melt from penetrating the converter casing, since the chromomagnesite backfill does not have such a protective function.

Closest to the proposed technical solution is the construction of a notch from specially pressed periclase-carbon cubic blocks 600 × 600 × 600 mm in size with replaceable coils, the inner diameter of which was 120-140 mm and 200 mm long [4, V.I. Pishchida, B.M. . Boychenko et al. Deterioration of the steel outlet of oxygen converters. Proceedings of the Eighth Steelmakers Congress. OJSC "Chermetinformation". Moscow. 2005. S. 142-145].

Such coils withstood the effects of a stream of metal and slag for no more than 150 heats, which showed extremely low resistance. In addition, local fracture was found at the fracture site during repairs, which could lead to erosion of refractories and their burnout with liquid metal on metal the converter housing from the inside, and also the axis of the hole is shifted, which degrades the work of the gases when slag is cut off.

The broken profile of the pulmonary node contributes to the creation of a turbulent regime of steel flow with the presence of large-scale pulsations in it. The resulting vortices rotate around their center and, as it were, scoop up the environmental material, and near the walls there is a layer of refractories in contact with steel.

Thus, the wear of refractories in the flow channel increases rapidly, as follows from [1-4], with an increase in all articles of the pressure loss of the jet, which must be minimized.

In addition, during the operation of the known steel outlets, the axis of the tap hole is shifted, which leads to the churning of the gas stream of the slag cutoff device.

The technical problem to which the utility model is aimed is to increase the operational reliability of the steel outlet block and its durability, as well as the stability of the axis of the notch with a guarantee

hit of a jet of neutral gas in the steel outlet of the slag cut-off mechanism.

At the same time, it is possible to obtain such a technical result as reducing the time for repair of the steel outlet block.

The technical result is achieved due to the steel outlet of the converter, made of socket blocks and through them installed through the refractory coils, according to the utility model, the outer side of the coils is made conical with a slope of 5-30 °, and the narrowing is directed inside the converter.

A comparative analysis of the proposed technical solution with the prototype shows that the inventive device is distinguished by its structural design.

Thus, the claimed technical solution meets the criterion of "novelty."

The proposed technical solution will be clear from the following description of the application and the attached drawing.

Figure 1 - schematically shows the steel outlet of the Converter.

The steel outlet block of the converter is made of a socket block 1 and high refractory blocks inserted into it, made in the form of through conical coils 2, while the outer side of the coils is made conical with a slope angle of 5-30 °, and the narrowing is directed inside the converter. Between the socket block and the lining of the converter, refractory packing 3 is performed. The flight hole is straight-through and without kinks.

As a result of the analysis of the known designs of the converter’s openings, the authors settled on the use of steel-pouring channels without bends and with smooth inner walls.

The maximum resistance of 420-470 swimming block floats was achieved by using a design that eliminated unnecessary turbulinization of the flow due to the almost vertical outflow of steel from the converter for most of the drain time. However, with this excessively high resistance, it seemed, there were welds of coils 2 to socket blocks 1, which led to

difficulty cleaning and replacing coils. The practice of the planned replacement of 3 to 4 pieces of coils after 250 heats was mastered.

An additional advantage of this practice is that, due to unprincipled deviations in the quality of the internal surface and the dimensions of the hydraulic channel from the initial ones, this is the release of steel during the entire overhaul period of the notch with a fairly organized low-turbulent jet.

In the practical study of the proposed steel outlet block, the first batch of flying conical coils in the amount of 50 pcs. laid using synthetic adhesives to ensure smoothness and hardening of the channels. In the future, it was possible to provide the necessary requirements for the flight channel by wedging the refractories in the lining layer.

During the experimental testing of the patented steelmaking unit, conical coils with different angles of inclination of the outer side were tested. However, according to the authors, the optimal tilt angles are angles equal to 5-30 °.

The use of coils with an inclination angle of the outside of less than 5 ° did not give the desired result, because practically received the known cylindrical shape of the refractory coils, from which the authors tried to get away.

When using coils with an external angle of inclination of more than 30 °, their mechanical strength deteriorated.

An analysis of the residues of operated flight blocks of this design showed that the main factors of their wear are the gradual erosion and corrosion effects of a moving jet, especially converter slag flowing into the steel pouring ladle, and some damage to the elements of the blocks when cutting the flight hole. Measures to mitigate the influence of these factors is gas-dynamic slag cutoff during steel production, for which a special device is used.

The device is installed on the side wall of the converter housing in the immediate vicinity of the steel outlet. The gas-dynamic nozzle is mounted on a L-shaped pivot arm having an axis of rotation mounted in sliding bearings. The lever is moved using a pneumatic cylinder. The blocking gas is nitrogen with a working pressure of 1.5 MPa, the control gas is also nitrogen, the working pressure is 0.8-1.0 MPa. Remote control via pneumatic valve.

The operation of the flying device and its durability are also affected by the near-annual repair of the refractory lining.

When the lining of the metallurgical unit is worn to a depth of about 1.5 flight blocks in the area of the steel outlet, the converter is tilted to the drain side and a metal pipe with a diameter smaller than the diameter of the hole is installed and fixed on the outside of the converter. After that, a shotcrete of the damaged part of the air hole is made by applying a shotcrete mass using a shotcrete lance. For better sintering, shotcrete is applied in layers. Based on the conditions of best adhesion and strong sintering of the shotcrete coating with the lining surface, the material of the applied layer is selected in accordance with the material of the refractory lining of the converter.

An example of the implementation of a technical solution

A hot repair of the steel outlet of the 160-ton converter was carried out.

Three through conical coils were installed in series with each other in the socket block of the converter. Refractory coils had a conical design with a slope angle of 15 °, while the narrowing side was directed into the inside of the converter. Then, between the lining of the converter and the socket unit, the chromomagnesite backfill was stuffed.

Next, the gunite mass was welded in the vicinity of the air hole; for this, the MD-109 grade gunite was used, having the following chemical. composition, wt.%:

MgO≥95.0

SiO ₂ ≥1.0

The shotcrete mass was supplied to the damaged place of the converter using a shotcrete lance equipped with nozzles for supplying the shotcrete mass in a stream of compressed air at an air pressure of 6 atm. The basis of the shotcrete coating had a porous working surface, a dense texture and a fine-grained structure. After 220 heats, a planned replacement of 3 conical coils was made. Worn coils were easy to get, there were no cases of strong welding, knocking down the axis of the notch was not observed.

Thanks to the proposed solution for the use of conical coils, the conditions for their replacement have improved, and the cases of welding the coils to socket blocks have been significantly reduced, which ultimately has increased the overall resistance of the steel outlet block.

The proposed technical solution has several advantages in comparison with well-known analogues:

- the axis position of the steel outlet notch is stabilized;

- stable operation of the slag cutoff mechanism;

- reduction of time for repair of a notch and, consequently, increase in converter performance;

- no nesting of the nest block occurs.

Thus, the use of the proposed technical solution allows to increase the operational reliability of the device for slag cutoff and to ensure the accuracy of the gas stream entering the steel outlet.

Therefore, the task to which the technical solution is directed is fulfilled.

At the same time, it is possible to obtain such a technical result as reducing the cost of repairing the flight block and timely cutting off slag from liquid metal without failures and retries.

Claims (1)

The steel-releasing unit of the converter, made of composite nesting units and through them installed through the refractory coils, characterized in that the outer side of the coils is made conical with a slope angle of 5-30 ° and directed narrowing part inside the converter.