Injection valve components and method

Abstract

An injection valve which is positioned on the underneath portion of a teeming vessel is disclosed. It may be positioned under a ladle, or under a tundish. The valve itself includes a mounting plate, and a well block nozzle which is in open communication with the metal being teemed in the vessel. Beneath the well block nozzle is a stationary plate, therebeneath a sliding plate which may be imperforate, perforate, or have an opening containing a porous plug or ceramic sieve depending upon the type of injection. Beneath the sliding injection plate a sliding plate carrier is positioned which is engaged by spring loaded rocker arms in order to maintain a compressive relationship between the sliding plate carrier, the sliding injection plate, and the stationary plate. Centrally of the sliding plate carrier is a coupler which, in turn, is connected to a further coupler, an injection hose, and an injection supply for delivering additives to the vessel through the injection valve. Optionally the injection valve is fed by a plurality of injectants supplied which are adjusted by means of control valves. In addition, wire may also be injected simultaneously with gas, or other additives. In addition, power means are provided for replacing the sliding plate carrier, and also the sliding plate. The method of operation includes preparing the injection valve after a pour has been completed by lancing the same in a partially disassembled form, utilizing a plug, and thereafter assembling and operating the same.

Description

FIELD OF THE INVENTION

The present invention is directed to an injection valve, and more particularly an injection valve which can desirably be positioned at the lower portion of a metal teeming vessel for the injection of additives to the metal including solids and gases, the latter intended to agitate and disburse the additives.

SUMMARY OF THE PRIOR ART

The prior art is directed to the field known as "ladel metalurgy". When steel is formed in an open hearth furnace, a basic oxygen furnace, or by any other technique including the remelting and purification of scarp, it is normally tapped off of the furnace or refining vessel into a ladle. The ladle is then transported to a metalurgical platform or station. At this point additives such as nickel, molybdenum, sulfur, and even lead can be introduced to the steel. Oftentimes this is done by a lance introduced from above the vessel which is blowing argon or anothe rinert gas along with the additives. The lance itself is consumed in the process but necessarily sacrificed to deliver the additives to a position beneath whatever slag may be atop the ladle.

More recently such efforts have been disclosed in the following U.S. patents have been directed to the general subject matter: U.S. Pat. Nos. 3,395,901; 3,633,898; 3,809,146; 3,820,768; 3,931,913; 3,997,148; 3,997,334; 4,004,792; 4,268,017; 4,285,504; 4,298,192; 4,317,561; 4,355,789; 4,392,636; 4,392,637; 4,401,466; 4,413,815; 4,42`,257; 4,423,858; 4,428,546; 4,449,701; 4,494,735; 4,502,670; 4,509,977; and 4,572,482. As will be seen, the various examples position the injection of additives at various locations of the vessel.

More recently, as exemplified in PCT application No. PCT/GB83/00279 of Nov. 21, 1983, a valve known as the "Injectall" has been introduced into the market place. This valve is positioned on a side of the metal teeming vessel. As will be noted its parts are detailed, and it does suffer from the limited disadvantage of not being positioned at the bottom of the vessel where any gas injected can cause agitation throughout the entire contents of the vessel, rather than just at the level above the point of injection. All gases when introduced into a vessel generally migrate upwardly from the point of introduction.

SUMMARY OF THE INVENTION

The present invention is directed to an injection valve which is positioned on the underneath portion of a teeming vessel. It may be positioned under a ladle, or under a tundish. The valve itself includes a mounting plate, and a well block nozzle which is in open communication with the metal being teemed in the vessel. Beneath the well block nozzle is a staionary plate, therebeneath a sliding plate which may be imperforate, perforate, or have an opening containing a porous plug or ceramic sieve depending upon the type of injection. Beneath the sliding injection plate a sliding plate carrier is positioned which is engaged by spring loaded rocker arms in order to maintain a compressive relationship between the sliding plate carrier, the sliding injection plate, and the stationary plate. Centrally of the sliding plate carrier is a coupler which, in turn, is connected to a further coupler, an injection hose, and an injection supply for delivering additives to the vessel through the injection valve. Optionally the injection valve is fed by a plurality of injectants supplied which are adjusted by means of control valves. In addition, wire may also be injected simultaneously with gas, or other additives. The wire normally is advanced rapidly at speeds between 60 and 100 feet per second. This permits the wire to advance into the vessel and be melted at a point somehwat above the injection valve and thereafter disbursed by an inert gas. In addition, power means are provided for replacing the sliding plate carrier, and also the sliding plate. Alternatively means are provided for disengaging the rockers, and manually replacing the same. An alternative embodiment closely resembles the above-described construction, however the slide gate portion contains a lance guide at one position, an imperforate area adjacent the lance guide position, and a gas inlet portion which flanks the imperforate portion along with the land guide. The method of operation includes preparing the injection valve after a pour has been completed by lancing the same in a partially disassembled form, utilizing a plug, and thereafter assembling and operating the same. The method is also directed to the power change of the spent element. The method further contemplates incorporating a lance guide within the slide gate which is in flanking relationship along with the gas inlet to an imperforate portion permitting the lancing and the reactivation without removing the sliding plate.

In view of the foregoing it is a principal object of the present invention to provide a method of operating an injection valve and construction of an injection valve which permit ladle metalurgy at a lower portion of a teeming vessel, irrespective of whether it is a ladle designed for intermediate transport, or a tundish which is teeming directly into an ingot or a continuous caster.

A further object of the present invention is to provide an injection valve which can be positioned on an underneath portion of a vessel, and which has positive shut-off means which permit the same to be activated without reverse flow of the metal being teemed, and which further permits the shut-off and subsequent purging to reactivate the injection valve.

Still another object of the present invention is directed to the utilization of an alternative sliding injection plate in which the lance guide and the gas inlet are in the sliding plate, and an imperforate area separates the two. This permits the utilization of a single plate to lance, shut off flow, and reactivate by utilizing the gas injection.

Still another of many objects of the present invention look to the provision of an injection valve and a method of operating the same which is simple, safe, and economically desirable because of the limited number of parts in contact with the extremely high temperature of the teeming vessel and the molten metal contained in the vessel.

BRIEF DESCRIPTION OF THE DRAWINGS

Further objects and advantages of the present invention will become apparent as the following description of an illustrative embodiment proceeds, taken in conjunction with the illustrative drawings, in which:

FIG. 1 is a partially diagrammatic perspective view of a metal teeming vessel showing the subject injection valve, and adjacent teeming valve, and the additive system;

FIG. 2 is a longitudinal section of the subject injection valve, partially broken at the teeming vessel and well block nozzle portions;

FIG. 3 is a cross-section or transverse sectional view taken in the same scale as FIG. 2 showing the interior portion and particularly the spring loading of the rocker arm assembly to compress the refractory members;

FIG. 4 is a partially enlarged broken sectional view illustrating the means for clamping the respective stationary plate and sliding injection plate;

FIG. 5 is a plan view of the stationary plate showing how the same is clamped, and also illustrating section line 4--4 of FIG. 4 as to its location;

FIGS. 6, 7 and 8 show respectively the refractory members of the injection valve in which the slide plate of FIG. 6 has an injection orifice, the slide plate of FIG. 7 has a permeable plug for gases, and the sliding injection plate of FIG. 8 has a perforated insert for passing liquids, solids, or gases;

FIG. 8a is an enlarged view of the perforated plate insert in the slide gate shown in FIG. 8;

FIG. 9 is a view comparable to FIG. 2, but disclosing a lancing guide plate, and specific of the power change mechanism;

FIG. 10 is a transverse sectional view taken in the same scale as FIG. 9;

FIG. 11 is a partially exploded perspective view showing in spaced relationship the stationary plate, carrier plate, and portions of the drive mechanism;

FIG. 12 is a section through the multi-media injectant coupling in enlarged scale, and illustrating the introduction of wire along with gases or gas entrained solids, or liquids;

FIG. 13 is a longitudinal transverse sectional view of an alternative embodiment utilizing a three position slide gate in which the lance guide is at the left, the gas injection inlet is at the right, and as shown the imperforate portion is therebetween which is shutting off the flow from the teeming orifice; and

FIG. 14 is a transverse cross-sectional view of the three position injection valve shown in the same scale as FIG. 13 and taken along section line 14--14 of FIG. 13.

DESCRIPTION OF A PREFERRED EMBODIMENT

As noted in FIG. 1, a teeming vessel 1 is shown having an outer shell. The indication valve V illustrative of the present invention is secured on the underneath side of the vessel shell. Normally and centrally located under the teeming vessel 1, is a bottom pour valve V' which actually controls the flow of molten metal from the teeming vessel shell 1 into a tundish, ingot, or other metal processing station. As shown in longitudinal section in FIG. 2, the injection valve V is secured to the teeming vessel 1 by means of a mounting plate 2. A well nozzle 3 extends inwardly and in fluid communication with the molten metal in the teeming vessel 1. At the upper portion of the valve V, there is positioned a stationary plate 4 which nestinly receives the lower portion of the well nozzle 3. The stationary plate 4 has tapered edge portions to permit its removable securement in position. In addition, a sliding injectin plate 5 is provided having an orifice which is the injection hole when in register with the injection hole of the stationary plate 4. A refractory clamp ring 8 secures the stationary plate 4 in position in a manner not unlike that disclosed in U.S. Pat. No. 4,582,232, entitled "Vale, Clamp, Refractory, and Method". A refractory clamp ring 8 also secures the sliding injection plate 5 for movement as will be defined below. A sliding plate carrier 10 is positioned beneath the sliding injection plate 5. The sliding plate carrier 10 includes a seal ring 11 intended to seal the interface between the sliding injection plate 5 and the sliding plate carrier 10 so that gases injected under pressure will not leak.

A carrier puller 12 in the form of a key shaped metal having a lug at one end portion is secured by means of a puller attachment screw 13 into position and in locking engagement with the sliding plate carrier 10. The ram 14 is secured to the sliding plate carrier 10 by the carrier puller 12 for moving the sliding injection plate 5 in and out of register with the orifice of the stationary plate 4 to permit injection, or in the alternative, to close the injection action during or after teeming a heat from the vessel 1. The ram 14 is actuated by the hydraulic cylinder 15 in a manner comparable to other sliding gate valves, and more particularly tundish valves of the character disclosed in U.S. Pat. No. 4,415,103.

The sliding plate carrier is urged into compressive relationship with the sliding injection gate 5 and the stationary injection plate 4 by means of rocker arm 16 which, includes, a spherical shoulder rocker arm pivot of the character disclosed in U.S. patent application Ser. No. 797,994 filed Nov. 14, 1985. The spherical shoulder rocker arm pivot 17 permits engagement by the spring 18 which is interior of the spring pad 19 and adjusted by means of cam follower 20. Cam follower 20 in turn is engaged by means of the spring compressor cam shaft 21 which is regulated by the cam shaft stop bar 22. Upon rotation of the spring compressor cam shaft 21 the spring pressure is released, the pressure on the rocker arm 16 is released, and the carrier assembly 10 along with the slide injection valve 5 may be removed.

In FIG. 3, it will be seen that the entire injection valve V includes the mounting plate 2, and the injection valve frame 24. The injection valve frame 24, in turn, includes a frame bottom 25 which is secured, in its assembled form to the mounting plate 2, by means of the valve mounting bolt 26 as shown in FIG. 2.

Turning now to FIG. 4 which is a section taken through FIG. 5, it will be seen that clamp ring mounting screw 27 engages the sliding plate carrier 10 and secures the sliding injection plate 5 by means of its associated refractory clamp ring 8 into position. This securement by screw 27 in essence couples the metal carrier frame 10 to the refractory injection sliding plate 5 and permits them to move in unison. Similarly, clamp block mounting bolt 28 is secured to the metal clamp block 9, and therefore retains the refractory stationary plate 4 in position.

Carrier puller pivot pin 29 is in turn positioned and held in place by means of the retainers set screw 30. The key element secured to the carrier 10 is the female half of the quick connect coupler 31 as shown in FIGS. 2 and 3. As shown in more detail, however, the male quick connect coupler 23 is secured to a female quick connect coupler 31 and terminates in a T-fitting 32 which, in turn, has one end plugged by means of a wire guide seal 33 which leads wire 34 into the vessel 1. The injection hose 35 as shown in FIG. 12 leads to the manifold 36 of FIG. 1, controlled by control valves 37 to the injectant supply 38.

In FIGS. 9 and 10, the valve V is modified slightly to include the insertion of a lancing guide plate 39 secured in place by a lancing guide carrier 40 which is limited in its stroke by stroke limiter 41. Its usage is described below as the method of operation is set forth.

As noted particularly in FIGS. 5 and 11, the refractory plates making up the stationary plate 4 and the sliding injection plate 5 are egg-shaped in plan view. The two plates may be substantially identical or, as shown in FIG. 6, the stationary plate 4 has a recess to nestingly receive the lower indented portion of the well block nozzle 3. The four clamps shown in FIG. 5 include primarily the clamp block 9 as well as the refractory clamp ring 8. The refractory clamp rings 8 in essence act as a peripheral retainer for both the stationary plate 4 and the sliding gate 5. The sliding gate 5, and its associated ring 8, are coupled for driving engagement with the hydraulic cylinder 15 as shown primarily in FIG. 2. The stationary plate 4 may be equipped with a circular recess insert 4'. This permits a nesting fit with the well nozzle 3.

In each instance, as to the stationary plate 4 and injection slide gate 5, by providing the egg-shaped cross-section, there is refractory overlap when the slide gate 5 is in the closed position, or when the lancing guide 39 is secured in position by the lancing guide carrier 40 as shown in FIG. 9. The offset relationship between the slide plate 5 is shown in perspective in FIG. 11, and in exploded form. The stationary plate 4 is reversed from the axial location of the slide plate 5, but both are retained in a refractory clamp ring 8 to compressively engage the same and insure against expansive cracking during the thermal shock normally associated with a teeming operation. In FIG. 8a, as well as FIGS. 6 and 7, the variable types of slide plates 5 are shown. The configuration shown in FIG. 7 utilizes a permeable plug 7' for gases, and the configuration as shown in FIG. 8 utilizes a perforated plate in the central orifice as shown in both FIGS. 8 and 8a.

DESCRIPTION OF ALTERNATIVE EMBODIMENT

An alternative embodiment sliding gate valve V' is shown in FIGS. 13 and 14. For purposes of description, the same reference numerals will be used with a "prime" where they are common to the first-described embodiment. In virtually all instances all references are common, but take a different form and content based primarily on the utilization of a slide gate having a lance guide in spaced relationship to a gas inlet thereby permitting three positions, one of shut off, one in which the lance guide is in position to lance the well block orifice, and a final position for the insertion of gas, wire, or whatever additives are being injected into the ladle for purposes of ladle gate metallurgy.

Turning now to FIG. 14 it will be seen that the valve V' shows in dotted lines the well block nozzle 3'. The vessel 1', and the mounting plate 2' are as shown. A stationary plate 4' is secured in position by means of the refractory clamp ring 8'. The sliding injection plate 5' is in interfacial relationship with the stationary plate 4'. Means is provided for injection 6' through the sliding injection plate 5' and optionally a perforated portion 6' may be used with the gas injection. The sliding plate carrier 10' incorporates a seal ring 11' surrounding the sliding injection plate perforated orifice 6'. A carrier puller 12' is not shown by may be employed. The ram 14' is secured to the hydraulic cylinder 15' which actuates the sliding injection plate 5' to two of its three positions.

In order to secure the sliding and stationary plate leak-proof relationship, particularly as shown in FIG. 14, a rocker arm 16' is mounted on a spherical shoulder rocker pivot arm 17' which is actuated by spring 18' bearing upon spring pad 19' which is further actuated by the cam follower 20' and the spring cam shaft 21'. A cam shaft stop bar 22' is shown on the left-hand side of FIG. 14. The nature of the rocker arm 16' is to bear upon the sliding plate carrier 10'. A quick connect coupler 23' optionally is connected to a gas inlet and secured to the frame bottom 25'.

The principal significant difference between the second embodiment V' and the original embodiment appears apparent in FIG. 13 at the left-hand portion where it will be seen that an independent lance guide portion 50' depends from the sliding injection plate 5'. This permits shifting the slide plate 5' by means of a hydraulic cylinder or manual actuator, in order to align the lance guide 50' with the teeming orifice. Thereafter, lancing takes place as normally.

Method

When there is to be an injection valve plate change, the first step is to extend the cylinder 15 to its maximum position of extension. Then puller attachment screw 13 is backed out. Then the carrier puller 12 is disengaged from the sliding plate carrier 10. Subsequently the stroke limiter 41 is removed, and the cylinder 15 is fully retracted.

At this point the operator inserts a replacement carrier 10 with sliding injection plates 5, 6 or 7 (as shown in the FIGS. 6, 7 and 8) or lancing guide carrier 40 with lancing guide plate 39. Once these elements are preassembled with the refractory clamp rings 8 and the clamp ring mounting screws 27, the same is in the "ready position" in front of cylinder 15. At this point the operator engages the carrier puller 12 in replacement sliding plate carrier 10 or replacement lancing guide carrier 40, and the same is secured with the puller attachment screw 13.

Thereafter the cylinder 15 is actuated to its fully extended position to push out the old sliding plate carrier assembly and insert the new one. At this point the stroke limiter 41 is replaced. Upon repeats the above steps are undertaken. In most operations, the well block nozzle 3 orifice, as well as the orifice of the stationary plate 4 will be packed with an inert material, and the slide gate 5 shut off. Thus the valve is ready to inject after the vessel 1 has been charged with molten metal. When that is ready, the gas is pressurized through the quick connect coupler 23 and hose 35, and then the sliding injectin plate 5 is powered into the injection position and continually fed with gas until the teeming operation is concluded.

An alternative operating procedure which is not power driven involves similarly filling the bore of the well block nozzle 3 and the stationary plate 4 with a bore fill material and in the same manner as using the vessel when it is prepared for use with a sliding gate valve of the type shown in U.S. Pat. No. 4,063,668.

The vessel is then filled with molten metal and may be held for an indefinite period of time awaiting the initiation of injection and ladle metalurgy. The injection process is initiated by pressurizing argon gas into the injection valve V. The argon gas then displaces the bore fill material which floats to the top of the melt. Injection then continues in any manner deemed necessary to achieve the desired metalurgical results including gas bubbling, solids injection, liquids injection, and any combination of the foregoing. This occurs in various combinations and sequences, all as controlled by the control valves 37.

At the termination of injection the valve is cycled closed by moving the sliding injection plate 5 and then the gas flow is turned off. At any time when the valve is in open communication with the metal in the vessel 1, there must be gas flow to prevent the intrusion of molten metal into the valve well nozzle 3 and stationary plates 4.

When the heat or cast is finished and the station for service of the injection valve has been reached, the injection valve is serviced by replacing the injection plate 5 with a lancing guide 39. The lancing guide 39 is installed and put under spring pressure to seal the lancing guide 39 to the stationary plate 4 and damage is minimized or eliminated during the lancing operation. An oxygen lance is then inserted into the opening in the lance guide 39 and then burns out the openign plugged with metal in the stationary plate 4 in the well block nozzle 3. When the lancing is completed, spring pressure is released and the lancing guide 39 is removed from the valve V. At this time the bore of the stationary plate 4 and the well block nozzle 3 are visually inspected. If they have eroded too large a bore, the stationary plate and well nozzle 3, 4 are replaced. If the refractories are satisfactory the previous or a new injection plate 10 is loaded into the valve V, the spring pressure is reapplied by the cam 21, and the new plate and carrier are attached to the ram head. At this point the vessel is ready for pre-heat to accept another charge of meatl. In the alternative embodiment of the method, means are provided in a single sliding plate to have a lance guide and the injection in spaced relationship to each other and flanking an imperforate portion. This permits three positions in which either the lance guide is aligned with the teeming orifice and lancing can be operated, or where total shut off can be achieved, or where injection by either gases or metallic additives can be developed.

In review it will be seen that an injection valve V has been described both as to structure and operation. The injection valve can have alternative types of sliding injection plates 5 as shown in FIGS. 6, 7 and 8, where the slide injection plate of FIG. 6 is perforate, the sliding injectin plate of FIG. 7 (7) has a porous permeable plug for gases, and the sliding injection plate 6 as shown in FIG. 8 has a perforated plate for liquids or gases.

Although particular embodiments of the invention have been shown and described in full here, there is no intention to thereby limit the invention to the details of such embodiments. On the contrary, the intention is to cover all modifications, alternatives, embodiments, usages and equivalents as fall within the spirit and scope of the present invention, specification and appended claims.

Claims

1. A method of servicing an injection valve which includes a stationary plate having an orifice therein, a sliding injection plate having an orifice therein, and a carrier plate to which an injection valve is secured, all of which are serviced and actuated by means of a power means engaging the sliding injection plate which moves in combination with the carrier plate comprising the steps of,

at the termination of injection, converting the valve condition to shut-off and permitting the stationary plate orifice to form a sealed orifice,

thereafter removing the carrier plate and its associated sliding plate refractory, and replacing the same with a lance guide plate having a tapered opening therebeneath,

moving the lance guide plate into coaxial relationship with the sealed orifice portion of the stationary plate and the well block nozzle,

utilizing an oxygen lance to open the orifice in the stationary refractory plate and the well block nozzle,

replacing the lancing guide plate with a sliding injection plate and carrier assembly,

thereafter moving the sliding injection plate and carrier into the shut-off position,

and thereafter inserting a bore fill into a orifice in the stationary plate and well block nozzle prior to charging the vessel with a molten metal.

2. In the method of claim 1 above,

engaging means provided within the valve to cause a power transport of the carrier and sliding gate to the off position.

3. In the method of claim 1,

providing a spring loading of the respective plates by means of a cam engaging springs which spring load the plates,

disengaging said cam to in turn disengage the pressure on the springs which are forcing the refractories into compressive relationship,

thereafter removing the carrier plates for manual replacement,

and thereafter re-engaging and cam activating the springs to secure all members in place.

4. In the method of claim 1 above,

providing a manifold permitting multiple media injection into the injection valve.

5. In the method of claim 1 above,

providing means for rapidly inserting a wire for alloying through the carrier and sliding injection plate.

6. A method of servicing an injection valve mounted beneath a teeming opening which includes a stationary plate, a sliding injection plate having a gas insert orifice therein, an imperforate portion adjacent said gas insert orifice, and a lance guide in flanking relationship with the imperforate portion combining the steps of

at the termination of the injection, converting the valve condition to shut off,

upon reactivating, positioning the lance guide beneath the teeming opening,

lancing any plugged metal in the teeming opening through the lande guide in place,

and thereafter optionally shifting the sliding gate portion to the shut off position or to the gas injection and ladle metallurgy position.

7. In the injection valve of claim 6 above,

cam means for removably securing a compressive relationship on the rocker arm springs.

8. In the injection valve of claim 6 above,

means for removably securing the power means to the combination of sliding gate and carrier,

thereby permitting the manual removal of the carrier and slide gate upon deactivation of the springs loading the rocker arms.

9. An injection valve for use at a lower portion of a teeming vessel comprising, in combination,

a mounting plate securing the valve to the vessel at a lower portion thereof and at an orifice thereof,

a well block nozzle positioned in the orifice for the injection valve haivng a central injection orifice,

a stationary plate at the upper portion of the injection valve positioned for injecting communication through the stationary plate orifice in alignment with the well block orifice,

a sliding injection plate and sliding plate carrier each secured to the other, and positioned beneath the stationary plate and having a central orifice proportioned for communication with the orifices of the stationary plate and the well block nozzle,

spring loaded rocker arm means secured to the valve and in compressive relationship with the sliding plate and carrier,

and gas injection means secured to the lower portion of the carrier in open communication with the slide plate orifice for the injection of additives gases, fluids, and solids to the metal in the vessel.

10. A lancing guide assembly for use with the valve of claim 9,

said lancing guide including a lancing guide carrier proportioned to be engaged by the rocker arms which are spring loaded,

said lancing guide having a tapered central opening for guidingly receiving an oxygen lance in communication with the stationary plate and well block nozzle.

11. An injection valve for use at a lower portion of a teeming vessel comprising, in combination,

a mounting plate securing the valve to the vessel at a lower portion thereof and at an orifice thereof,

a well block nozzle positioned in the orifice for the injection valve having a central injection orifice,

a stationary plate at the upper portion of the injection valve positioned for injecting communication through the stationary plate orifice in alignment with the well block orifice,

a sliding injection plate and sliding plate carrier each secured to the other, and positioned beneath the stationary plate, and having a lance guide at one portion, a gas injection orifice remotely spaced from said lance guide, and an imperforate portion between the lance guide and the injection portion,

yieldable means secured to the valve and in compressive relationship with the slide plate and carrier and stationary plate,

and injection means secured to the lower portion of the carrier in open communication with the slide plate orifice injection inlet for the injection of gases, fluids, or solids to the metal in the vessel.

12. In the stationary plate of claim 11 above,

a recess central and concentric with the orifice for receiving an extension on a well block injection nozzle portion.

13. A stationary plate for use in an injection valve comprising a flat refractory plate having two opposed faces,

said flat refractory having an enlarged section and tapered sidewall extending upwardly from one face,

said one face being proportioned for relative sliding relationship with a slide gate,

the planar configuration of said stationary plate being essentially egg shaped with the pouring orifice at the major intersection of the major and minor diameters of the egg-shaped cross-section.

14. A slide injection plate for use in an injection valve for face to face relationship with a stationary plate and having a lower face and an upper face comprising, in combination,

a refractory plate,

said refractory plate having an egg-shaped planar upper and lower face,

said refractory plate having an orifice at the intersection of the major and minor axis of said egg-shaped faces,

said slide plate having tapered walls, said walls tapering outwardly in a direction away from the face of the slide plate intended for face-to-face sliding relationship with the stationary plate.

15. A lance guide for use in an injection valve comprising,

a plate portion having tapered sidewalls,

said sidewalls tapering downwardly and outwardly from one face to said plate intended for sliding relationship with a stationary plate,

a depending injection guide portion depending from the plate portion,

said plate portion having an egg-shaped planar section,

an orifice at essentially the intersection of the major and minor axes of said plate of the lance guide,

and a tapered opening extending downwardly and outwardly interiorly of the depending guide portion for receiving a lance in open communication with the stationary plate and well block nozzle of a teeming vessel.

16. In the lance guide of claim 15 above,

said tapered inner section having two frustoconical portions, the frustoconical portion with the extreme taper being immediately in communication with the orifice of the lance guide.

17. A sliding injection plate for use in an injection valve comprising, in combination,

a refractory plate,

said refractory plate having a lance guide at one portion thereof,

said refractory plate having an orifice at another location for the injection of materials into a ladle,

and an imperforate portion on said sliding injection plate intermediate the lance guide and the injection orifice, whereby said sliding injection plate can be put into three positions which accomplish either lancing, total shut off, or ladle injection.

18. In the sliding injection plate of cliam 17 above,

said side plate having tapered walls, said walls taping outwardly in a direction away from the face of the slide plate and intended for face-to-face sliding relationship with a stationary plate.