UA28543U - Open hearth furnace crown tuyere - Google Patents

Abstract

An open hearth furnace crown tuyere contains concentrically disposed pipes forming channels for supply of oxygen, supply and takeoff of cooling water, and tip with blowing nozzles, which are directed tangentially relatively to the tuyere axis and at an acute angle to vertical, centers of original cross sections of which are disposed in one horizontal plane.

Description

Description of the invention

The useful model refers to metallurgy, mainly to the March production of steel. 2 The well-known vault tuyeres of the Martinov furnace for purging the bath with an oxidizer, for example, oxygen, from above (1, p.201-205), which contains concentrically arranged pipes that create paths for the supply of oxygen, supply and removal of cooling water, and a multi-nozzle nozzle in which the blowing nozzles are located at an acute angle to the axis of the nozzle, and the centers of the exit sections of the nozzles are located in the same horizontal plane.

However, the use of the known lance does not ensure effective mixing in the "metal melt - 70 slag - gas phase of the unit" system, a high degree of dispersion of the oxygen blast in the bath. At small angles of inclination of the nozzles to the axis of the lance (20-40 degrees, further in the text - degrees), there is, as a rule, excessively "hard" blowing of the Martin bath, poor mixing and low intensity of heat and mass transfer processes at the boundaries of "metal - slag " and "slag - gas" excessive local overheating of the reaction zone (ZZ), deterioration of the processes of slag formation, dephosphorization and desulfurization of metal, controllability of the melt, reduction of the degree of 72 afterburning CO (H") above the bath, deterioration of the heat balance of the melt, large losses of metal due to intensive splash and dust.

At large angles of inclination of the nozzles to the axis of the lance (45-75 degrees), there is, as a rule, excessively "soft" purging of the Martin bath, poor mixing of the lower layers of the metal melt, overoxidation and overheating of the upper part of the bath occurs, the melting of the solid is excessively delayed parts of the charge (scrap and its substitutes), the heat transfer from the torch to the bath and the heating capacity of the furnace deteriorate, the probability of slag-metal emulsion emissions increases, and control of the melting becomes difficult.

The well-known vault tuyer of the Martinov furnace for purging the bath with oxygen from above |21, which contains concentrically arranged pipes that create paths for the supply of oxygen, the supply and removal of cooling water, and a multi-nozzle tip in which one part of the purging nozzles is located at one acute angle to the tuyere axis, and the centers of their initial sections are located in one horizontal plane, and the other part (the seam of the blowing nozzles is located at another acute angle to the axis of the lance, and the centers of their initial sections are located in another horizontal plane.

The well-known nozzle provides simultaneous blowing of the Martin bath with hard" (from nozzles with a smaller angle of inclination to the axis of the nozzle) and "soft" (from nozzles with a greater angle of inclination to the axis of the nozzle) jets, which allows simultaneously intensifying the processes of metal refining, slag formation and afterburning of gases above the bath. "AND

However, the known tuyere is much more difficult to manufacture and operate (due to excessive sensitivity to the blow height, pressure, and oxygen consumption). So, for example, even if the tuyere height is slightly exceeded by the level of optimal values (and the exact determination of the actual height of the tuyere end above the level of the metal melt o in production conditions is a very difficult task) during the use of this tuyere, a rapid 3o reoxidation of the slag and the upper part of the bath can occur, which leads to emissions of slag-metallic emulsion. In addition, the dutt stirrups flowing from the known tuyere do not have a tangential of the velocity component (relative to the axis of the nozzle and the bath) and, as a result, do not ensure the formation of a stable vortex zone of purging, which has a high degree of oxygen distribution over the bath, lower intensity of splashing and dust formation.

The well-known vault tuyeres of the Marteniv furnace for blowing the bath with oxygen from above |Z| which contains pipes located concentrically C, which create paths for the supply of oxygen, supply and removal of cooling water, and c a nozzle with blowing nozzles directed tangentially to the axis of the lance and at an acute angle to

From" the vertical, the centers of the initial cross-sections, which are located in one horizontal plane, are taken as a prototype.

At the same time, due to the use of blowing nozzles directed tangentially to the axis of the lance, the efficiency of mixing in the system "metal melt - slag - gas phase of the unit and the degree of dispersion of the oxygen blast in the bath are increased, local overheating of the reaction zone is reduced, the processes of slag formation, dephosphorization and desulfurization of metal are improved, the intensity of spattering and dust formation in the purging zones is reduced, the controllability of the melt is improved, the stability of the lances and the efficiency of the purging of the bath of the Marteniv furnace as a whole are increased. i-y However, the specified technical solution does not define the optimal angle of twisting of the purging nozzles in the "iz" 20 depending on other design parameters of the nozzle block of the lance.

In the case when the angle of rotation of the nozzle relative to the center of its output cross-section (the angle between the axis of any c" of the blowing nozzles and the straight line passing through the center of the output cross-section of this nozzle and the point of intersection of the axis of the lance with the plane passing through the center of the output cross-section nozzle at an acute angle y to the axis of the nozzle, where y is the angle of inclination of the axis of the blowing nozzle to the axis of the nozzle on the condition that the axis of the nozzle crosses the axis of the nozzle, i.e. 59 in the absence of its twist) is less than optimal, the tangential component of speed c (impulse) is significantly reduced oxygen jets flowing out and the effect of tangential blowing supply, the strength of horizontal mixing of the bath is sharply reduced.

In the case when the angle of rotation of the nozzle relative to the center of its initial cross-section is greater than optimal, the depth of penetration of the jets into the melt is significantly reduced, which leads to overoxidation of the slag, deterioration of mixing and slowing down of heat and mass transfer processes in the depth of the metal bath. In addition, this significantly complicates the production of the nozzle block, especially when using the main method of their production - drilling.

The basis of a useful model is the task of improving the vault nozzle of the Marteniv furnace, in which, due to the use of blowing nozzles with an optimal twist angle depending on other structural parameters of the nozzle block of the nozzle, optimal parameters of the interaction of the jet jets with the bath are provided, which will increase the efficiency of blowing the Marteniv furnace furnaces with such tuyeres, improve the processes of slag formation, dephosphorization and desulfurization of metal, the process of mixing the bath and controllability of the melt, reduce soot and metal oxidation, increase the degree of absorption of oxygen in blowing and afterburning of CO

ЧН2) above the bath, improve the thermal balance of melting, shorten the duration of the dotting period and melting in general, increase the stability of the lances, and, as a result, reduce the cost of steel (by reducing the specific costs of the metal charge, fuel, oxygen, ferroalloys and copper for its smelting) and increase the productivity of units (Marten furnaces).

The solution to the task is achieved due to the fact that in the vault tuyere of the Marteniv furnace, 7/o, which contains concentrically located pipes that create paths for the supply of oxygen, the supply and removal of cooling water, and a tip with blowing nozzles directed tangentially relative to the tuyere axis and under at an acute angle to the vertical, the centers of the exit sections of which are located in the same horizontal plane, according to a useful model, the angle between the axis of any of the blowing nozzles and the line passing through the center of the exit section of this nozzle and the point of intersection of the axis of the lance with the plane that passes through the center of 7/5 of the nozzle outlet section at an acute angle to the nozzle axis, determined from the ratio: (0.3.y) « o, x (0.7.y), deg., where y is the angle of inclination of the axis of the blowing nozzle to axes of the lance, provided that the axis of the nozzle crosses the axis of the lance, grad.; with. - the angle between the axis of the blowing nozzle and the straight line that passes through the center of the outlet section of this nozzle and the point of intersection of the axis of the nozzle with the plane that passes through the center of the outlet section of the nozzle at an angle y to the axis of the nozzle, degrees.

The use of vault lances of Martinov furnaces with blowing nozzles with an optimal twist angle depending on other design parameters of the nozzle block of the lance, which is determined from the given ratio, allows you to organize highly effective blowing of the bath of the Martinov furnace due to: - more intense mixing of the bath in the horizontal direction due to the tangential component the momentum of the escaping oxygen jets and an increase in the total energy of mixing in the "metal 7 melt - slag - gas phase of the unit" system; as a result - intensification of all heat and mass exchange processes in the system, improvement of thermal operation of furnaces, homogenization of melt, process of metal desulfurization, etc.; - reduction of the intensity of pulsations and stabilization of the purging zone; as a result - reduction of splashing and sweeping of equipment, increase of usable output and stability of blowing devices; (ze) - intensification of heat transfer from the high-temperature reaction zone due to an increase in its surface and increased mixing; as a result - a decrease in the temperature of the reaction zone, the amount of iron that evaporates, an improvement in the service conditions of refractories, the furnace vault and the nozzle tips. IF)

If the value o is greater than the value determined from the given ratio, then in this case, the depth of penetration of the jets into the melt is significantly reduced, which leads to overoxidation of the slag, deterioration of mixing and slowing down of heat and mass transfer processes in the depth of the metal bath. In addition, this significantly complicates the production of the nozzle block, especially when using the main method of their production - drilling.

If the value is less than the value determined from the given ratio, then in this case, the tangential component of the speed (impulse) of the flowing oxygen jets and the effect of the tangential supply of the blowing are significantly reduced, the strength of the horizontal mixing of the bath is sharply reduced. o) c The essence of a useful model is explained by a drawing. The vault tuyere of the Marteniv furnace contains concentrically located pipes 1 that create paths for the supply of oxygen 2, the supply of cooling water and the outlet 4 of cooling water, and a tip 5 with blowing nozzles b, which are directed tangentially to the axis 7 of the tuyere and at an acute angle to the vertical. the centers of 8 initial cross-sections which are located in one horizontal plane.

The angle between the axis 9 of any of the blowing nozzles 6 and the line 10 passing through the center 8 of the outlet section of this nozzle 6 and the point 11 of the intersection of the axis 7 of the lance with the plane that passes through the center 8 of the outlet section of the nozzle 6 at an acute angle to axis 7 of the lance, determined from the ratio: (0.3.y) « oh (0.7.y), deg., where y is the angle of inclination of the axis 9 of the blowing nozzle 6 to the axis 7 of the lance, provided that the axis 9 of the nozzle b intersects the axis of 7 lancets, deg. o (see drawing); о, - the angle between the axis 9 of the blowing nozzle 6 and the straight line 10 passing through the center 8 of the outlet section 20 of this nozzle b and the point 11 of the intersection of the axis 7 of the nozzle with the plane that passes through the center 8 of the outlet section of the nozzle 6 at an angle u to the axis of 7 lances, degree. (see drawing). c" The device works as follows.

In the process of Martinov smelting, oxygen is supplied through the oxygen supply path 2 of the vault lance to the blowing nozzles b of the tip 5, which, passing through the blowing nozzles 6 with design parameters determined from the given ratio, flows into the working space of the Martinov furnace in the form of blowing jets, which are used to blow the bath from above with optimal parameters of their interaction with the bath.

To cool the nozzle 5 and the design of the tuyeres as a whole, which are exposed to high temperatures in the working space of the Martinov furnace, cooling water is supplied through the tract C, and cooling water is discharged through the tract 4. 60 An example of specific use of the vault lance of the proposed design for blowing the bath of the Martinov furnace from above.

Bath purging in 650-t and 900-tit Marteniv furnaces of OJSC, MMK named after Ilyich" with the help of 2-4 vaulted oxygen lances of the proposed design. For these conditions, the value of the angle y is 45 degrees. At the same time, close to the maximum yield of suitable metal and degrees of desulfurization are ensured. In this case, the range of optimal values of the angle о is: the lower limit - (0.3.y) "x oh (0.7-y), deg.; upper limit - (0.7.y) - 0.7.

45 - 31.5 degrees. The actual value of the angle o for these conditions is 20.0 degrees, that is, it corresponds to the range of optimal values.

The use of a vault nozzle of the proposed design for blowing the bath of a Martinov furnace from above, due to the use of blowing nozzles with an optimal twist angle depending on other structural parameters of the nozzle block of the nozzle, allows you to ensure optimal parameters of the interaction of jet jets with the bath, to increase the efficiency of blowing the bath of a Martinov furnace with such nozzles, to improve the processes of slag formation, dephosphorization and desulfurization of metal, the process of mixing the bath and controllability of the melting, to reduce soot and oxidation of the metal, to increase the degree of assimilation of oxygen by blowing and 7/0 afterburning of CO (H") above the bath, to improve the thermal balance of melting, to reduce the duration of the dotting period and smelting as a whole, to increase the stability of lances, and, as a result, to reduce the cost of steel (by reducing the specific consumption of metal charge, fuel, oxygen, ferroalloys and copper for its smelting) and to increase the productivity of units (Martenov furnaces).

Sources of information 1. Markov B.L. The method of purging Marchen baths. - M.: Metallurgy, 1975. - 280 p. 2. Effectiveness of nozzles of various designs when blowing the Martenov bath with oxygen / Ya.A.

Shneerov, N.M. Vinogradov, N.M. Blaschuk et al. // Byul. NTI Ferrous metallurgy. - 1970. - Language - P. 27-29. 3. Application of oxygen nozzles with tangential arrangement of nozzles on Martenov furnaces / A.A.

Kirsanov, B.L. Markov, A.A. Dobrokhotov et al. // Byul. NTI Ferrous metallurgy. - 1974. - Mo15. - p. 30.

Claims (1)

The formula of the invention is the vault tuyer of the Martinov furnace, which contains concentrically located pipes that create paths for the supply of oxygen, the supply and removal of cooling water, and a nozzle with blowing nozzles directed tangentially to the axis of the tuyer and at an acute angle to the vertical, the centers of the output sections of which are located in one horizontal plane, which differs in that the angle between the axis of any of the blowing nozzles and the straight line passing through the center of the exit section of this nozzle and the point of intersection of the axis of the nozzle with the plane that passes through the center of the exit section of the nozzle at an acute angle to the axis lance, soz are determined from the relationship: (0) Ba (0, y), erad,, t where y is the angle of inclination of the axis of the blowing nozzle to the axis of the lance, provided that the axis of the nozzle intersects the axis of the lance, deg.; yuyu "- the angle between the axis of the blowing nozzle and the straight line that passes through the center of the outlet section of this nozzle and (oz) the point of intersection of the axis of the nozzle with the plane that passes through the center of the outlet section of the nozzle at an angle y to the axis of the nozzle, deg. - . and? ime) (ee) 1 sh» syu» 60 b5