UA108953C2 - OXYGEN TYPE OF WELDED CONSTRUCTION - Google Patents

Abstract

The invention relates to metallurgy. The tip of the oxygen lance of the welded structure contains upper and lower plates and tangentially arranged nozzles, each having a collar that closes the gap between the corresponding surfaces of the hole in the lower plate and the nozzle, the outer surface of which has at least three sections, namely: the main section, which is symmetric about the axis of the nozzle, the output section, which is symmetrical about the axis, which is located about the axis of the nozzle at an angle α, and the transition section, which connects the surface of the main and output sections and represents a cut surface of the body of rotation in dnosno nozzle axis with the maximum height, and the value of α ivyznachayutsya of the reported ratios. The use of the invention will allow: to improve the workability, increase the strength and reliability of the nodes connecting the nozzles with the bottom and top plates, and increase the stability of the welds between the nozzles and the bottom plate of the tip and the tip as a whole.

Description

The invention belongs to metallurgy, in particular, to multi-nozzle blowing lances of steel-smelting units (oxygen converters, electric steel-smelting, Martin and two-bath furnaces, converter-type units for liquid-phase recovery of iron, etc.).

It is known to use multi-nozzle nozzles with a tangential arrangement of nozzles relative to the longitudinal axis of the nozzle for blowing the metal melt in the converter (1). At the same time, due to the tangential component of the total momentum of the jets at the point of their meeting with the surface of the bath, the efficiency of blowing the melt in the steel melting unit is significantly increased: mixing in the "metal melt-slag-gas phase" system is improved, the degree of dispersion of the oxidizing blast in the bath is increased, and local overheating is reduced of the reaction zone, the intensity of spatter and dust formation in the blowdown zone decreases, the controllability of melting improves, the intensity of metallization decreases and the stability of the lance, the lining of the neck of the unit and other equipment increases, the processes of slag formation, dephosphorization and desulfurization of metal improve, the degree of afterburning of outgoing converter gases increases, and the thermal balance of melting improves.

However, sufficiently high stability of the tips (heads) of such lances and their reliable operation were achieved in production only when using tips of cast or solidly turned designs on converters with a capacity of up to 180 t (with a diameter of the outer tube of the lance no more than 219 mm) - for example (1 ) (Yenakievsky metallurgical plant, 160-ton converters). On the tuyere of multi-ton converters, that is, with a large diameter of the outer pipe (for example, 426 mm), such tips are practically not used due to the difficulty of organizing reliable cooling of the central part of the head of the solid-turned design, as well as the insufficient strength of the head of the cast design. For blowing multi-ton converters, nozzles with prefab tips, including welded designs, where the nozzles are made as separate parts and then connected in the assembly process with other parts of the tip (namely, with its upper and lower plates) have become the most widely distributed.

When manufacturing a nozzle tip of a prefabricated structure with a tangential arrangement of the nozzles, the main difficulty is to ensure a reliable connection of the nozzles with the specified plates.

There is a well-known tuyeres for blowing metal |(2)Ї, which has a tip of a prefabricated design, which

Zo contains a lower plate, an upper plate and nozzles, which are connected to the specified plates by spherical joints and spherical joint bushings, respectively, and the upper plate has the ability to both move along the axis of the lance and rotate relative to this axis.

The use of such a design of the tip makes it possible to change the angle of inclination of the nozzles to the axis of the lance, both in the vertical and horizontal planes, during the blowing of the metal bath with gas due to the appropriate movement of the upper plate (with the help of a special movement mechanism), i.e. theoretically ensure the possibility of blowing the steel-melting bath with gas jets oriented in the space of the unit tangentially relative to the axis of the nozzle.

However, due to the unreliable operation of hinged joints in the real conditions of steelmaking production (heating, contact with dusty gases, ingress of liquid metal and slag on the outer surface of the tip, etc.), and the rapid loss of their tightness, taking into account the high pressure of energy carriers (cooling water and oxygen), the known technical solution is not used in practice.

In production, a welded connection is usually used to ensure the tightness of the connection points of the nozzles with the plates of the tip of the prefabricated structure. However, for lance tips with a tangential arrangement of nozzles, the line of intersection of their outer surface with the curved surfaces of the plates has a complex shape. Mechanical processing along this line of nozzle ends and sides, welding chamfers in plate holes is a time-consuming and expensive operation that requires the use of special equipment. With simplified manufacturing, high-quality execution of welding seams is excluded and, as a result, there is a low stability of them and the tip as a whole.

The well-known tip of an oxygen lance of welded design IZ| - the closest analogue, containing a clip (upper plate), a spherical head (lower plate) and tangentially placed nozzles, in which the axes of the sections of the outer surface of each tangentially placed nozzle are made normal to the tangential planes of the upper and lower plates at the points of intersection of the axes of these sections with the surfaces of the plates . In addition, the outer surface of the tangentially located nozzles is equipped with edges that cover the gaps between the surfaces of the nozzles and the holes in the plates.

In a known technical solution, due to the presence on the outer surface of each tangentially placed nozzle of areas whose axes are normally tangent to the planes of the upper and lower plates at the points of intersection of the axes of these areas with the surfaces of the plates, there is a simple axisymmetric shape of the line of intersection of the outer surface of the nozzles with curvilinear plate surfaces. This significantly simplifies the mechanical processing along this line of the ends and sides of the nozzles, as well as the welding chamfers in the holes of the plates. And it also simplifies the welding of nozzles with plates, ensures an increase in the quality of welding seams and, as a result, an increase in their stability and the nozzle tip as a whole. The use of flanges that cover the gaps between the surfaces of the nozzles and the holes in the lower plate, as is known, allows to increase the strength of welds that are under high temperature and mechanical stresses.

However, in the known technical solution, the optimal shape of the outer surface of the tangentially placed nozzle is not defined, i.e., the optimal number of sections on it and the type of coupling between them are not defined. If the number of indicated sections is the minimum, equal to two (which are indicated in the formula of the closest analogue) - namely, the section connecting to the lower plate and the section connecting to the upper plate of the tip, then it is also not defined how these parts of the outer surface of the nozzle (which have axes that do not coincide with each other) are conjugated (connected) with each other. This significantly complicates the production of such nozzles in practice, and also prevents them from being produced with minimal costs. In addition, in the closest analogy, the angles between the axes of the indicated areas and the corresponding radii of the surfaces of the lower and upper plates at the points of intersection of these axes with the surfaces of the plates are strictly equal to zero, which is not always rational. So, at the same time, in the nozzle tips with a large angle increase, which ensures the tangential component of the velocity of gas (oxygen) jets (""), the section for the passage of cooling water is significantly overlapped by the nozzle bodies, which increases the loss of water pressure in the tip and can lead to a decrease in flow rate it due to the nozzle, deterioration of the cooling of the head and its rapid failure. That is, the closest analogue does not provide for the possibility of implementing admissible asymmetric recessing of the nozzle body into the body of the lower and/or upper plate, which ensures an improvement in the cooling of the tip without reducing the strength of welding seams of nozzles with plates Also, in the known technical solution, the optimal shape of the outer surface of the nozzle from the point of view of minimizing the total loss of water pressure in the tip is not defined. In addition, the optimal shape is not defined

From the shape of the inner surface of the part of the nozzle that is directly connected to the lower plate of the tip. With the usual design of blowing nozzles in the form of Laval nozzles with a conical diffuser, there is a so-called oblique section of the exit section of the nozzle (change in the shape and size of the exit section), which significantly changes the Mach number of the nozzle and can lead to the appearance of separation currents at its exit section. At the same time, the rate of erosive wear of the nozzles increases significantly with variable modes of oxygen supply through the nozzle |4| and, as a result, the stability of the tip decreases (due to the rapid failure of welding seams), the parameters of the flow of oxygen jets change significantly, the blast mode of melting is destabilized, and almost all technical and economic indicators of steel melting deteriorate.

The invention is based on the task of improving the tip of an oxygen nozzle of a welded structure, in which, due to the change in the shape of the outer and inner surfaces of the tangentially located nozzles, the manufacturability of their manufacture is improved, the pressure loss of the water flow in the nozzle head is reduced, cooling is improved and the stability of the welds between the nozzles and the lower plate of the nozzle and the nozzle as a whole, the probability of the appearance of separate gas flows at the outlet sections of the blowing nozzles decreases, their stability increases and the melting mode is stabilized, including with variable flow rates of blowing gas (oxygen) through the nozzle.

The solution to the given problem is carried out due to the fact that the tip of the oxygen lance is a welded structure containing upper and lower plates and tangentially placed nozzles, each of which has a lip that covers the gap between the corresponding surfaces of the hole in the lower plate and the nozzle, the outer surface of which has section, the number of specified sections is not less than three, namely: the main section, which is symmetrical about the axis of the nozzle, the initial section, which is symmetrical about the axis, which is located relative to the axis of the nozzle at an angle Е, and the transition section, which conjugates the surfaces of the main and output sections and represents the cut surface of the rotation axis relative to the nozzle axis with the maximum height "P, and the values of УС and пер are determined from the ratios, respectively: , and a vertical plane passing through its axis,

groin N b, trans. .- ex(o)

Ov. where is the edge diameter.

In addition, the inner surface of each of the tangentially placed nozzles has an initial section with the shape of a truncated cylinder, the maximum height of which is determined from the ratio; pi (01704). a, where "M" is the diameter of the passage section of the nozzle on the initial part of its inner surface.

Also, each of the tangentially placed nozzles has an upper lip covering the gap between the corresponding surfaces of the hole in the upper plate and the nozzle, and the outer surface of the nozzle has five sections, including an inlet section that is symmetrical about the axis, which is located about the axis of the nozzle at an angle of О, and the upper transitional area that joins the surfaces of the main and entrance areas and the surface of the bodies cut by the rib. modern

Ov nK. 180 agosov--y8-I3- - Khy 2 - - - 2102 so5r ; where K is a coefficient equal to 0.5-1.0, A is the radius of the inner surface of the lower plate, G is the radius level of the surface of the upper plate. per, in -5-5- ex) re b. where is the diameter of the upper edge.

In addition, the length of the inlet section of the outer surface of the nozzle is determined from the relation: o -(13-25).6 where b. thickness of the upper plate.

Also, the inner surface of each of the tangentially placed nozzles has an entrance section with the shape of a truncated dicylinder, the maximum height of which is determined from the ratio: pu, - (01-04) a, a? where /h is the diameter of the passage section of the nozzle on the inlet section of its inner surface.

In addition, the outer surface of the nozzle in its main section is equidistant from its inner surface.

When creating the invention, they proceeded from the following provisions. When performing the outer surface of each of the tangentially placed nozzles, such that it has at least three sections, namely: the main section, which is symmetrical about the axis of the nozzle, the output section, which is symmetrical about the axis, which is located relative to the axis of the nozzle at an angle E , and the transition section that joins the surfaces of the main and output sections is a truncated path of the body of rotation relative to the axis of the nozzle with the maximum height "P (where the values of the connection of the outer surfaces of the nozzles with the body of the lower plate of the tip, which significantly simplifies the mechanical processing of the lower ends and edges of the nozzles, as well as welding chamfers in the holes of the lower plate, simplifies the operation of welding nozzles with the plate, ensures an increase in the quality of welding seams and, as a result, an increase stability of them and the nozzle tip as a whole; 2) high manufacturability of nozzle manufacturing (i.e. clarity in therefore: how many minimally possible sections should the outer surface of the nozzle have, how is the initial section of the outer surface of the nozzle, which is connected to the lower plate of the tip, connected to other sections of the outer surface of the nozzle, etc.); 3) simplification and reduction of nozzle manufacturing costs; all parts of their outer surface are surfaces of simple bodies of rotation, and therefore such nozzles can be manufactured without the use of special expensive equipment; 4) reduction of water pressure losses in the nozzle, improvement of cooling of the nozzles and the bottom plate and the head as a whole, and increase of their stability.

When the angle E: (between the axis of the nozzle and the axis of the output section) is equal to the angle B;, the angle between the axis of the output section of the nozzle and the radius of the inner or outer surface of the lower plate at the point of their intersection (Unl Shchi to) is equal to zero, that is, the axis of the output section perpendicular to the plane tangent to the surface (internal or external) of the lower plate at the point of its intersection with the axis of the nozzle. At small values of the angle , which provides the tingendialr component of the velocity of the oxygen jets flowing from the nozzles of the lance, (that is, at

B-1015 ), the outer diameter of the nozzle in the transition section, including . . p. its maximum value, which coincides with the edge diameter of 75, is relatively small. At

In B-10, 15 and larger values of the angle (i.e., at ) the reduced outer diameter of the nozzle in the transition area and 76 - significantly increase. As a result, the cross-sectional area for the passage of water between the nozzles in the tip (especially near the lower plate) is reduced, which is the minimum cross-sectional area in the water path of the head and nozzle as a whole, and determines the throughput capacity of the nozzle for cooling water. That is, pressure losses increase significantly and water flow through the nozzle decreases, which leads to deterioration of the cooling of the nozzle and tip, including its most heat-stressed places - the lower plate, nozzle outlet sections and places of their connection (welding seams) and, as a result, reducing their stability. In addition, at large values of "59, on approximately half of the nozzle perimeter, the thermal resistance of heat transfer from the welding seam to the cooling water increases too much (the thickness and diameter of the nozzle body between the seam and water increases), which also leads to a deterioration of the strength of the seam and its stability. To exclude or to reduce the above-mentioned negative effects, it is necessary to reduce the reduced outer diameter of the nozzle in the transition section, and especially the value of 75, which is achieved by reducing the angle Э (that is, under the condition of approx. with the radius of the inner surface of the lower plate of the head. To ensure the tightness of contact (absence of gaps) between the outlet area of the nozzle and the lower plate, in it

From the seat under the nozzle, it is partially (one-sided) "recessed" with the maximum depth of immersion (into the body of the lower plate) in the place of the smallest thickness of the nozzle in its transition area. At the same time, the seat under the nozzle is made in such a way that the angle between the plane of the seat and the plane tangent to the surface of the lower plate at the point of its intersection with the axis of the nozzle is equal to the angle On, and the angle between the plane of the seat and the axis of the nozzle in the vertical plane, which passes through the visvznozzle, there is (90 Ohm,

If the value of the angle E is less than 77 V, then the maximum depth of sinking of the seat under the nozzle (into the body of the lower plate) will be too large (relative to the actual thicknesses of the lower plates of the tips of the nozzles used in practice), which will lead to a significant decrease in the strength of the unit with the connection of the nozzle with the plate and the premature destruction of the tip of the lance during blowing of the melt due to high temperature and mechanical loads on the welding seams between the malt and the lower plate of the lance.

An increase in the angle 9 greater than 7 M will lead to a sharp increase in the value of the reduced outer diameter of the nozzle in the transition area and 5, and, as a result, to the appearance and increase of all the negative effects indicated above.

Provided that the transition section of the outer surface of the nozzle is such that it joins the surfaces of the main and output sections and is a cut surface of the body of rotation with the maximum height of the declared value, the surface of the transition section is processed (performed) in the most technological and rational way. First, the surface of the transition section is made symmetrical about the axis of the nozzle in one operation together with the production of the surface of the main section, and then after the production of the surface of the initial section, the surface of the transition "automatically" receives the final asymmetric shape. With this nozzle manufacturing technology, the need to use expensive special equipment is eliminated. In addition, due to the smooth conjugation of the main and output sections of the outer surface of the nozzle, the nature of water flowing around the nozzles (flow structure) near the lower plate improves, and, as a result, the cooling of the welds and the output sections of the nozzles.

Three, the bleaching of the maximum height of the transition area of the outer surface of the nozzle is more, per H than vp). such characteristic dimensions of the transition section of the nozzle as length, wall thickness and outer diameter increase excessively. As a result, the cross-sectional area for the passage of water between the nozzles in the tip decreases (especially near the lower plate), pressure losses increase significantly and water flow through the nozzle decreases, which leads to deterioration of the cooling of the nozzle, tip and welding seams, and to a decrease in their stability.

In addition, the flow of cooling water moves away from the outlet section of the nozzle, which leads to the deterioration of the cooling of the outlet sections of the nozzles, the increase in the rate of erosive wear of the nozzles and the destabilization of the process of blowing the metal melt. And it also leads to an increase in the mass of the nozzle and the overspending of expensive and scarce high-quality copper for the manufacture of the nozzle tip.

Designing the inner surface of each tangentially located nozzle with an output section in the form of a truncated cylinder with a maximum length that is in the declared range allows for reducing the flow of purging gas (for example, oxygen) through the nozzle and, as a result, reducing the gas pressure in front of the nozzles (relatively, the so-called calculated regime for the specific parameters of the nozzle, namely its Mach number) to prevent or significantly delay the beginning of the separation of the oxygen flow in the nozzle, and thereby expand the range of effective operation of the nozzles, increase their resistance to erosive wear and ensure a more efficient and stable mode blowing of metal melt in the steel melting unit (converter).

If the value of the maximum height of the initial part of the inner surface of the nozzle h is less than ol, then with a reduced flow of oxygen through the nozzle (usually when regulated by the blowing process, the flow is reduced by 10-20 95 from its nominal value) separation of the jet flow from the walls of the nozzle diffuser will occur . At the same time, significant expenditure of energy of the oxygen flow on ejection and eddy currents, erosion of the exit section of the nozzles, violation of the nozzle blowing mode, and decrease in the stability of the nozzle block and tip take place.

If the value of h is greater than "ts, then the kinetic energy (momentum) of the gas jets flowing out of the nozzles will noticeably decrease due to noticeable braking

From the supersonic gas flow at the exit section of the nozzle, which is associated with a change in the cross-sectional area (according to the law of reversal of geometric influence) and an increase in the pressure loss of the flow due to its friction against the walls of the exit section of the nozzle. As a result, there will be a decrease in the oxygen flow rate near the metal bath, the jets will sink into the melt, and the mixing of the bath will deteriorate.

The execution on the outer surface of each of the tangentially located nozzles of the upper edge, which covers the gap between the opening of the upper plate and the surface of this nozzle, increases the strength of the welds and facilitates the operation of welding the nozzles with the upper plate.

The outer surface of a tangentially placed nozzle may have only the three areas indicated above and may not have an upper edge. If the outer surface of the nozzle has only three sections, then the upper plate is connected directly to the main section of the outer surface of the nozzle; the manufacture of nozzles is simplified and cheaper, but the manufacture of holes for nozzles and the separation of edges for welding seams in the upper plate becomes more difficult. It should also be noted that the required diameter of the upper plate is determined by the diameter of the circle on which the points of intersection of the axes of the nozzles with the surface of the upper plate are located. With large values of the angle , the required diameter of the upper plate will be larger than the permissible one, which is determined by the diameters of the pipes of the gun barrel, which is especially critical for guns with a small outer diameter of the barrel.

When designing the outer surface of tangentially placed nozzles, such that it has five sections, including: the entrance section, which is symmetrical relative to the axis, which is located relative to the nozzle axis at an angle Ов (the value of which is determined from the stated ratio), and the upper transition section , which joins the surfaces of the main and inlet sections, the required diameter of the upper plate is significantly reduced, which in this case is determined by the diameter of the circle on which the intersection points of the axes of the inlet sections of the nozzles with the surface of the upper plate are located.

However, at the same time, the reduced outer diameter of the nozzle in the upper transitional section, including its maximum value, which coincides with the diameter of the upper edge 79, increases

(especially at larger values of the angle B. As a result, the cross-sectional area for the passage of water between the nozzles in the nozzle decreases, pressure losses increase, and the flow of water through the nozzle may decrease. Moreover, with an increase in the angle Оv, the indicated negative effect intensifies, and the required diameter of the upper plate decreases. In the declared optimal range of values of the angle Оv (that is, the optimal value of the coefficient K in the stated ratio) provides a significant reduction in the diameter of the upper plate with a simultaneous relatively small degree of overlap of the nozzles of the section for the passage of water in the tip.

If the coefficient K is less than 0.5 in the ratio for determining Оv, then the size of the required diameter of the upper plate of the tip increases significantly.

If the value of the coefficient K. is greater than 1.0, then the reduced outer diameter of the nozzle in its upper transition section increases significantly.

To increase the throughput capacity of the tip for cooling water and improve the organization of its flow in the head, the upper transition section of the nozzle can be partially embedded in the body of the upper plate (analogous to the node connecting the nozzle to the lower plate). At the same time, an increase in the density of the connection of the outer surface of the nozzle with the body of the upper plate is also achieved, which additionally increases the strength and tightness of the welded joint.

When performing the upper transitional section of the tangentially located nozzle in such a way that it joins the surfaces of the main and entrance sections and is a cut-off surface of the body of rotation relative to the axis of the nozzle with a maximum height "P (which is determined from the stated ratio), high manufacturability and a reduction in nozzle manufacturing costs are ensured (simplification their mechanical processing due to the fact that all areas of the outer surface are surfaces of simple bodies of rotation), as well as reducing pressure losses and improving the structure of the flow of cooling water in the tip.

When the maximum height of the upper transition section of the outer surface of the nozzle increases (in 3. s.) that is more than v/, the characteristic dimensions of the upper transition section of the nozzle, such as length, wall thickness, and outer diameter, increase excessively, which leads to the above-mentioned negative phenomena.

When performing the entrance section of the outer surface of each of the tangentially placed nozzles with a length in that is in the declared range, there is a good

The organized nature of the flow of oxygen streams in the pre-nozzle volume and at the entrance to the nozzles and small pressure losses of the oxygen flow with sufficient thickness (and, accordingly, strength) of the welds connecting the upper plate and the tangentially located nozzles.

If the length of the entrance section of the outer surface of the nozzle is less than 13.5, then the height of the nozzle weld with the upper plate will be less than its thickness, which will lead to a decrease in the strength of the specified welded joints. In addition, in this case, the weld will be partially (or completely) located in the inner cavity of the nozzle baffle, which will lead to additional swirls of the gas (oxygen) flow in the nozzle and disruption of the organized flow pattern.

If the length of the inlet section of the outer surface of the nozzle is greater than u: b. then the inlet sections of the blowing nozzles will protrude too much beyond the surface of the upper plate into the cavity of the oxygen tract of the lance. This will worsen the dynamics of the oxygen flow in the pre-nozzle volume of the nozzle and in the inlet sections of the nozzles, will lead to an increase in the pressure loss of the oxygen flow and may cause the appearance of unpredicted pulsations of the oxygen flow in the nozzle and jets flowing into the cavity of the converter.

When performing the entrance section of the Inner surface of each nozzle with the shape of a truncated cylinder with a maximum height /h, which is in the declared range, the manufacture of nozzles is simplified, the flow of oxygen in the inlet parts of the nozzles is stabilized, its pressure losses and pulsations of oxygen jets are reduced. pe

If the value of the maximum length of the inlet section of the inner surface of the nozzle will be o. and oh, if it is less than 7707, then the length of the inlet section of the nozzle will not be enough to stabilize the flow at the entrance to the nozzle. Fri 04. a

If the value of h is greater than 770007h, then the loss of kinetic energy of the oxygen jet due to its friction against the walls of the inlet section of the nozzle will increase significantly.

When the main part of the outer surface of each nozzle is equidistant from its inner surface, the thickness of the nozzle wall is reduced as much as possible, which reduces the reduced outer diameter of the nozzle, increases the cross-sectional area for the passage of water in the tip of the nozzle and reduces the pressure loss of the water flow in it. At the same time, there is also the best structure of the water flow behind the nozzles (in the direction of water movement): with the minimum outer diameter of the nozzle, the minimum dimensions of the vortex zone with impaired water circulation take place, and, as a result, the cooling and stability of the peripheral areas (on the side of water removal) is improved from the tip) of welds of nozzles with the bottom plate.

The tip of the nozzle is connected (by a known method, for example, by welding) to the trunk of the nozzle, which has three channels, which are formed by three pipes: a channel for supplying gas and channels for supplying and draining cooling water. At the same time, the tip can be made according to two known options: with a central supply of cooling water or a central supply of process gas (depending on the version of the design of the barrel of the gun used). Also, the tip of the nozzle may or may not have an additional central nozzle, or additional peripheral nozzles of the second type, for example, nozzles with a smaller (compared to tangentially located blowing nozzles) cross-section diameter for additional afterburning of the converter gases leaving the bath.

The essence of the invention is explained in fig. 1-9, where in fig. 1 shows the tip of an oxygen nozzle (with a central supply of process gas) of a welded structure with five tangentially located nozzles according to item 1 of the claims (axonometry); in fig. 2 is a top view of the tip shown in fig. 1. In fig. C presents a longitudinal section of one of the tangentially placed nozzles (further on in the text - nozzles) in the tip according to clause 1 of the formula of the invention; in fig. 4 - section of the connection point of the nozzle and the lower plate of the tip of the oxygen nozzle according to item 1 of the claims. In fig. 5 presents a longitudinal section of the nozzle of the tip of the oxygen lance according to item 2 of the claims. In fig. 6 shows a part of the section of the tip along the axis of the tangentially located nozzle according to the claims of the invention (nozzle and places of its connection with the lower and upper plates), and in fig. 7 - part of the section of the tip along the axis of the tangentially located nozzle according to item 4 of the claims. In fig. 8 shows a longitudinal section of the nozzle according to item 5 of the claims. In fig. 9 shows a longitudinal section

From the nozzle according to paragraph 1-6 of the claims.

The tip of the oxygen nozzle of the welded structure according to item 1 of the claims (Fig. 1-4) contains the upper 1 and lower 2 plates and tangentially placed nozzles 3, each of which has a lip 4 (Fig. 3 and 4) that covers the gap between the corresponding the surfaces of the opening in the lower plate 2 and the nozzle 3, the outer surface of which has sections, and their number is not less than three (Fig. 3 and 4): the main section 5, which is symmetrical with respect to the axis b of the nozzle C, the output section 7, which is symmetrical with respect to the axis 8, which is located relative to the axis 6 of the nozzle Z at an angle C, and the transition section 9, which joins the surfaces of the main 5 and output 7 sections and was a cut surface of the body of rotation relative to the axis b of the nozzle Z with a maximum height "P, and the values - and tach

They are determined from the ratios, respectively: t o -(08-10)-8. where V is the angle between the plane P1 passing through the axis of the tuyeres 10 (Fig. 1, 2) and the center of the exit penedris 11 of the nozzle 3, and the vertical plane P2 passing through its axis 6, not vp)

About where is the edge diameter 4.

In the tip of the oxygen nozzle according to item 2 of the claims (Fig. 5), the inner surface of each of the tangentially placed nozzles Z has an initial section 12 with the shape of a cut pilrdr and Yau, the height of which is determined from the relationship: nozzle C on the outlet section 12 of its inner surface.

In the tip of the oxygen nozzle according to the claim of the invention (Fig. 6), each of the tangentially placed nozzles Z has an upper edge 14 that covers the gap between the corresponding surfaces of the hole in the upper plate 1 and the nozzle 3, the outer surface of which has five sections, including the input section 15, which is symmetrical relative to the axis 16, which is located relative to the axis 6 of the nozzle Z at an angle Ов; and the upper transitional section 17, which joins the surfaces of the main 5 and the inlet 15 sections and represents a truncated surface of rotation relative to the axis of the nozzle З with a maximum height of Рв, and the water flow rates are determined from the ratios, respectively: ов - Кк. 180 agosov--y8-I3- 2.14 7102 sovr g, where K. is a coefficient equal to 0.9-1.0, A. the radius of the inner surface 18 of the lower plate 2, "the radius of the outer surface 19 of the upper plate 1. per,v . diameter 75 - diameter of the upper edge 14.

In the tip of the oxygen nozzle according to clause 4 of the claims of the invention (Fig. 7), the length of the entrance section 15 of the outer surface of the nozzle Z is determined from the ratio: p - (3 25)-5 where b. thickness of the upper plate 1.

In the tip of the oxygen nozzle according to item 5 of the claims (Fig. 8), the inner surface of each of the tangentially placed nozzles Z has an inlet section 20, with the shape of a truncated cylinder, the maximum height of which is determined from the ratio: poe(OM 4) a a? where 7 is the diameter of the passage section 21 of the nozzle Z on the inlet section of its inner surface.

In the tip of the oxygen nozzle according to item 6 of the claims (Fig. 9), the outer surface of the nozzle C on the main section 5 is made equidistant to its inner surface.

The device works as follows (see Fig. 1-93. Process gas (oxygen) is supplied to the tip of the welded structure through the central tract of the lance barrel, and cooling water is fed (inner annular tract) and discharged (outer annular tract) through the annular tracts of the lance barrel . The gas flow in the cavity of the upper plate 1 (in front of the nozzles 3) is divided into several flows, the number of which is equal to the number of nozzles in the nozzle head. In the tangentially located nozzles C, the gas flows are accelerated to supersonic speed and through them the process gas is blown into the cavity of the steelmaking unit in in the form of supersonic jets, which are oriented at a double angle of inclination (relative to the axis of the nozzle) to the surface of the bath. As a result, the bath receives an additional tangential component of the motion momentum, which manifests itself in an additional rotational movement of the melt (around the vertical axis, which is

With conditional lengthening of the lance axis) and improvement of technical and economic indicators of steel smelting, which were indicated above. Together with the gas, various technological powdery materials can be supplied through the tangentially located nozzles. If the tip has an additional central nozzle or other additional nozzles, gas or gas-powder jets are also fed into the cavity of the unit through them. Cooling water is fed into the nozzle between the central pipe of the nozzle barrel (which enters the cavity of the nozzle) and the upper plate 1, flows along the upper plate 1 between the nozzles З into the central part of the head, turns in it, flows along the lower plate 2 between the nozzles З into the peripheral part of the head and is diverted from the tip between the central pipe and the lower plate 2, and then into the diverting annular water channel of the gun barrel. To improve the organization of the flow of cooling water in the tip, you can additionally install directing liners (water distributors) of known designs, which are connected to the central pipe of the nozzle barrel.

The use of the invention will allow: to improve manufacturability, to simplify and reduce the cost of manufacturing tangentially placed nozzles and the tip as a whole, to increase the strength and reliability of the joints (welds) of the nozzles with the lower and upper plates, to reduce the pressure loss of the water flow in the nozzle head, to improve cooling and increases the stability of the welding seams between the nozzles and the lower plate of the tip and the tip as a whole, reduce the probability of the appearance of separate gas flows at the outlet sections of the blowing nozzles, increase their resistance against erosive wear, stabilize the pulsation mode of melting, including with variable flows of purging gas (oxygen ) through the lance.

Sources of information: 1. Kazakov A.A. Effectiveness of the use of converter nozzles with a double angle of inclination of nozzles / A.A. Kazakov, A.S. Peregudov, L.F. Litvinov et al. // Metallurgical and mining industry. - 1986. - Mo. 1. - P. 17-18. 2. Furma for blowing metal. A. p. Mo 430161. USSR, according to Mo 1736861/22-2 dated 07.01.1972, MKV S21S 5/48. Published on May 30, 1974. Bull. Mo 20. 3. Tip of an oxygen lance. Patent for a utility model Mo 66827 of Ukraine, according to the Mo y201105574 application dated 05/04/2011, MKV С21С 5/48. Published on January 25, 2012. Bull. Mo 2. 4. Nozzles of oxygen-converter nozzles with increased resistance against edge wear / A.V. Sushchenko, F.Yi. Lukhtura, A.B. Kovura et al. // Stal. - 2005. - Mo 9. - b. 20-25.

Claims (6)

FORMULA OF THE INVENTION 1. An oxygen lance tip of welded construction comprising upper and lower plates and tangentially placed nozzles, each of which has a lip covering the gap between the corresponding surfaces of the hole in the lower plate and the nozzle, the outer surface of which has sections, which differs in that the number sections is at least three, namely: the main section, which is symmetrical with respect to the axis of the nozzle, the output section, which is symmetrical with respect to the axis, which is located relative to the axis of the nozzle at an angle a, and the transition section, which joins the surfaces of the main and output sections and is a truncated surface K'vah of rotation relative to the axis of the nozzle with the maximum height "P, and the values of sa and "UR are determined from the ratios, respectively: a - (0.8-1.0)-8, where B is the angle between the plane that passes through the axis of the nozzle and the center of the outlet section of the nozzle, and the vertical plane passing through its axis is vipo) where Ob is the diameter of the edge. Zo 2. The tip of the oxygen nozzle according to claim 1, which differs in that the inner surface of each of the tangentially placed nozzles has an initial section with the shape of a truncated cylinder, the maximum height of which is determined from the ratio: Пи - (0.1 - 0.4).ау, where du is the diameter of the passage section of the nozzle on the initial part of its inner surface. 3. The tip of an oxygen lance according to claims 1 or 2, characterized in that each of the tangentially placed nozzles has an upper lip covering the gap between the corresponding surfaces of the hole in the upper plate and the nozzle, and the outer surface of the nozzle has five sections, including including the inlet section, which is symmetrical with respect to the axis, which is located relative to the axis of the nozzle at an angle Ов, and the upper transition section, which joins the surfaces of the main and inlet sections. axes of the somla with the maximum height "Pv, and tahri - Khyri Srerv 8 and 102 V. the values of av and Pv determine | ratios, respectively: ov - K. 180 agosovb----y8------ - 2. --102 со5р where K is a coefficient equal to 0.5-1.0, A is the radius of the inner surface of the lower plate, r is the radius of the outer surface of the upper plate; the first vipios); re de 75 - the diameter of the upper edge. 4. The tip of the oxygen nozzle according to claim 3, which differs in that the length of the entrance section of the outer surface of the nozzle is determined from the ratio: and. -(53-25).6. where b is the thickness of the upper plate. 5. The tip of the oxygen lance according to paragraph With or 4, which differs in that the inner surface of each of the tangentially placed nozzles has an inlet section with the shape of a truncated cylinder, the linearity of which is determined from the ratio: ц ! ! ts, where a is the diameter of the passage section of the nozzle on the inlet section of its inner surface. 6. The tip of an oxygen nozzle according to any of claims 1-5, which is characterized by the fact that the outer surface of the nozzle in its main section is equidistant from the inner surface of the nozzle. Fig.