WO1996018470A1 - Arrangement for connecting a stopper rod for a metallurgical vessel to its lifting device - Google Patents

Abstract

The invention concerns an arrangement for connecting an elongate stopper rod (2) which is made of a refractory material and is used for a metallurgical vessel to a stopper rod lifting device. For this purpose, one end of a carrier (10) made of a metal material engages in an inner longitudinal recess (8) in the stopper rod (2) from the upper end face (11) thereof and is secured against removal from the stopper rod (2) by at least one retaining element which is disposed in the carrier region projecting into the inner longitudinal recess (8) in the stopper rod (2) and engages behind an abutment surface (16) provided in the stopper rod. The region of the carrier (10) projecting into the stopper rod is delimited by a stop (70) acting against a support surface (56) of the stopper rod. The stop (70) locks the retaining element against the abutment surface. An insert, which compensates the different extensions of the stopper rod and carrier in the region between the retaining element and the stop, is provided between the support surface (56) and the stop (70) in order to prevent the connection becoming separated at higher temperatures owing to the stopper rod and carrier material having different coefficients of thermal expansion.

Description

 Arrangement for connecting a stopper rod for a metallurgical vessel to its lifting device

The invention relates to an arrangement of the type corresponding to the preamble of claim 1.

The use of refractory plug rods for regulating the flow of a molten metal from a pan or a tundish into a mold has been known for a long time. For this purpose, the stopper rod is moved in the direction of its longitudinal axis by a lifting device adjacent to the outside of the tundish, whereby a pouring opening arranged at the bottom of the tundish, into which the stopper rod engages in the lowered state and closes completely, opens more or less becomes. The flow of the molten metal can thus be regulated. Although this regulation is in principle quite simple, the extreme conditions prevailing in steel processing place special demands on the materials and the technical design of the stopper rod. So this must withstand the action of a molten metal for hours. It must also be able to withstand the strong temperature fluctuations which act on the stopper rod during a casting process and the laterally acting forces caused by the buoyancy of the metal melt and which exert a strong bending moment on the stopper rod. A breakage of the plug rod inevitably leads to the Spout can no longer be closed, which results in an uncontrolled outflow of the melt. It therefore represents a significant security risk.

To connect the stopper rod to the lifting device and to connect a gas supply line, a holding rod usually made of steel is used, which extends over a certain area into the stopper rod and is connected to it. A gas channel is incorporated into the holding rod, which communicates on the one hand with the longitudinal bore of the stopper rod and on the other hand with a connecting device for the gas supply line. It is particularly important that the connection between the holding rod and the plug rod prevents ambient air from entering the inside of the plug rod and thus the molten steel, since this would lead to increased oxidation and thus to a deterioration in the steel quality.

The technical design of the connection between the ceramic plug rod and the metal holding rod is problematic because of the high thermal and mechanical loads acting on the connection. This problem is exacerbated in particular by the fact that - in order to reduce costs - a worn plug rod should be exchangeable for a new one by the personnel on site in a few simple steps and at the same time the components required for connecting the carrier to the plug rod should require the least possible production outlay.

An arrangement that largely meets these requirements is known from DE 43 24 768 Cl.

With this arrangement, the plug rod can be mounted on the holding rod designed as a carrier tube in a simple manner by inserting the carrier tube with a preassembled stop into a longitudinal recess in the plug rod and a locking member which fits into the inner volume of the carrier tube corre¬ sponding transverse opening rests, is displaced by suitable means so that it is the upper boundary surface of an installation space provided in the stopper rod. By displacing the stop which is preassembled on the support tube and which is formed by a nut screwed onto an external thread of the support which extends upwards from the upper end face of the stopper rod and which is supported against the end face of the stopper rod by means of a thrust washer , In the direction of the locking member, the latter is braced against the upper boundary surface of the installation space provided in the stopper rod, and thus a firm, non-rotatable fit of the stopper rods on the carrier is achieved.

A disadvantage of this arrangement, however, is that due to the greater coefficient of thermal expansion of the metallic carrier material compared to the ceramic plug rod material, an increase in temperature, as occurs to a considerable extent when filling the liquid metal into the tundish, releases the tension between the stop and the locking members, so that the security against rotation of the plug rod to the carrier is no longer guaranteed at high temperatures.

The invention has for its object to develop a generic arrangement so that an increase in temperature does not lead to loosening the connection between the stopper rod and the carrier.

This object is achieved by the invention reproduced in claim 1.

In the arrangement according to the invention, an insert is provided between a support surface provided on the stopper rod and a stop acting against it, which causes a holding element provided on the carrier to bear against a contact surface provided in the inner longitudinal recess of the stopper rod, which provides the various thermal Changes in length of the stopper rod and of the carrier in the area between the holding element and the stop are compensated. The holding element therefore remains braced against the contact surface even at higher temperatures of the arrangement. The unwanted This reliably prevents the plug rod from rotating on the carrier at higher temperatures.

In this context, holding elements are to be understood as all possible devices provided in the area of the support projecting into the stopper rod, which are suitable for at least counteracting the support in the stopper rod by means of a positive interaction with a contact surface provided in the stopper rod or an insert fastened therein To lock tensile loads between them. This also means, for example, connections through interlocking threads.

In a preferred embodiment, the stop consists of a nut which is screwed onto an external thread of the support which extends upward from the end face of the stopper rod and which is supported via a thrust washer on the insert compensating for the different changes in length and is thus designed as a counter device . With this configuration, on the one hand, the position of the stop on manufacturing tolerances can be individually adapted, on the other hand, firm locking of the plug rod mounted on the carrier is possible in a simple manner.

In order to distribute the holding forces over as large an area as possible of the plug rod material and thus to be able to lower the material load without requiring considerable manufacturing effort, it is advantageous, according to claim 3, to extend at least a part of the end of the plug rod in the region of the support which projects into the stopper rod and provide the annular space, the base of which forms the support surface.

A thermal expansion coefficient which is suitable for use in the annular space and which projects slightly beyond the end face of the stopper rod and on which the counter device is supported is then particularly suitable as an insert.

This can according to claim 5 in the longitudinal direction in several rere segments can be divided, whereby also a different temperature distribution over the cross section of the arrangement is compensated for, without this leading to considerable stresses within the support tube.

For better distribution of the holding forces exerted by the locking member on the stopper rod, it is advantageous if, according to claim 6, the upper contact surface, against which the retaining element acts, is provided in the inner volume of a press-in sleeve which is pressed into the stopper rod during isostatic pressing becomes.

In order to avoid that the holding forces exerted on the support surface via the insert are transferred directly to the relatively brittle, ceramic plug rod material, it is advantageous according to claim 7 to expand the annular space up to the upper end face of the press-in sleeve, so that the Support surface is formed by the upper end face of the press-in sleeve and the insert is supported on this.

The arrangement can be produced particularly inexpensively if it has the features of claims 8 and 9. In this case, both the press-in sleeve and the support tube forming the insert are made of the same metallic material as the carrier. The area of the stopper rod surrounding the carrier along its length between the counter device and the holding element, which compensates for the clamping forces exerted on the holding element by tightening the counter device, thereby experiences a change in length corresponding to the carrier when the temperature changes, so that the holding elements always rest on the upper contact surface. Should a higher contact pressure of the holding elements against the upper contact surface be necessary at higher temperatures, it is also possible to manufacture the insert from a material which has a higher coefficient of thermal expansion than the carrier and thus overcompensates its change in length.

In a further embodiment of the According to the arrangement, at least one blind bore extending approximately parallel to the central longitudinal recess is provided from the end face of the stopper rod, the bottom of which forms the support surface (claim 10).

In this embodiment, the insert advantageously consists of a rod-shaped component which has an absolute thermal coefficient of longitudinal change which is at least the sum of the absolute longitudinal coefficient of the carrier in the area between the counter device and the holding element and that Plug material in the same area.

An arrangement according to claim 12 is particularly preferred, in which the length of the blind bore corresponds approximately to twice the distance between the contact surface and the end face of the stopper rod.

Tests have shown that the insert then preferably consists of the carrier material (claim 13). This measure makes it particularly cost-effective to use.

Exemplary embodiments of the invention are illustrated schematically in the drawing. Show it:

1 shows a longitudinal section through a first embodiment of the device according to the invention; Fig. 2 an auxiliary assembly rod and

3 shows a longitudinal section through a second embodiment of the device according to the invention.

If in the following "above" or "below" is mentioned, the information refers to the hanging operating position of the arrangement shown in FIGS. 1 and 3.

The arrangement designated 100 in the drawing as a whole consists of an elongated, metallic carrier 10, which projects with its lower region 1 into a longitudinal recess 8 of a refractory ceramic stopper rod 2. The carrier 10 has a central longitudinal bore 3 that extends over its entire length on, whose diameter is about 30% of the outer diameter of the carrier 10. On its outer circumference 5, the carrier 10 carries an external thread 6 which extends from its upper end 4 to its lower region 1 and which serves on the one hand to receive a nut 7 and on the other hand to fasten the carrier 10 to a lifting device (not shown in the drawing). The nut 7 forming a stop 70 delimits the lower region 1 of the carrier 10 which can be inserted into the longitudinal recess 8 of the stopper rod 2 and is supported by means of a thrust washer in the arrangement shown in FIG. 1 on the upper, front ends 52 of two diametrically opposite one another , rod-shaped inserts 54 inserted into blind bores 53 machined into the stopper rod. The lengths of the rod-shaped inserts 54 are dimensioned such that they protrude slightly above the upper end face 11 of the stopper rod 2 when fully inserted into the blind bores 53. The lower ends 55 on the end face up on the bottoms of the blind bores 53, which form support surfaces 56, via which holding forces exerted by the stop 70 are transmitted into the plug rod material. In the direction of the longitudinal axis L of the arrangement between the support surfaces 56 and the upper end face 11 of the stopper rod 2 is approximately twice the distance between the end face and holding elements provided on the carrier, the function of which will be described below.

Locking elements 60 which can be displaced perpendicularly to the longitudinal axis L and which rest in two bores machined into the carrier 10 radially perpendicular to the longitudinal axis L of the arrangement serve as holding elements.

The locking members 60 consist of a cylindrical bolt 14 which rests in the bore 12 and forms a sliding fit with this. The end of the bolt 14, which faces the longitudinal bore 3 and has a length of approximately half the outer diameter of the carrier 10, is designed as a steep, tapering cone 15. In the In the "unlocked" position, the bolt 14 remains entirely in the cross section of the carrier 10 and extends approximately from the outer mouth of the bore 12 to the longitudinal axis L of the arrangement, so that the lower region 1 of the carrier 10 can be inserted into the longitudinal recess 8 of the stopper rod . In the "locked" position, the bolt 14 protrudes from the cross section by about half the diameter of the longitudinal bore 3 and engages behind an upper boundary surface 16, which is oriented perpendicular to the longitudinal axis L of the arrangement, of an installation space 17 which widens the longitudinal recess 8 and which is inside the plug rod 2 is provided. As a result, in this position of the bolt 14, the carrier cannot be pulled upward out of the plug stem 2.

In order to prevent the radially inward force components acting on the bolt 14 from being supported by the upper boundary surface 16 and which would shift the bolt 14 from the "locked" position to the "unlocked" position, the upper boundary surface is 16 provided with an undercut 18. A further securing of the bolt 14 in its "locked" position is provided by a securing sleeve 19 inserted into the longitudinal bore 3, which is supported on a cross-sectional constriction 51 provided at the lower end 20 of the carrier 10. The cross-sectional constriction 51 is brought about by means of a perforated disk attached to the lower end 20 of the carrier 1, the hole diameter 22 of which corresponds approximately to the inner diameter 23 of the securing sleeve. The perforated disk 21 shown is secured to the carrier 10 by a spot weld 35, which can optionally be released by an external force, for example by a hammer blow. The securing sleeve 19 extends from the perforated disk 21 upwards so far in the longitudinal bore 3 that it covers the bore 12 with its outer circumference, so that the bolt 14 cannot "shift" from its position.

The shift 14.24 from the "unlocked" position In the "locked" position after insertion of the lower part 1 of the carrier 10, an assembly aid rod 36 can be inserted from above into the longitudinal bore 3 of the carrier 10 and is shown in FIG. 2. The assembly aid tab 36 consists of an elongated round rod 37, which comprises a handle 38 at its upper end. Its lower end forms a tapered cone 39 which, when inserted, interacts with the cones 15, 26 of the bolts 14, 24 located in the cross section of the carrier 10 and displaces them outwards. In this "locked" position, the bolts 14, 24 engage behind the upper boundary surface 16, so that the carrier 10 can no longer be pulled out of the plug rod 2.

By subsequently tightening the nut 7 against the thrust washer 9, which is supported on the front ends 52 of the rod-shaped inserts 54, the carrier 10 can be countered, as a result of which a firm, rotatable fit of the stopper rod 2 on the carrier 10 is ensured is. As the temperature of the arrangement increases, the rod-shaped inserts 54 expand to an extent that corresponds to the sum of the thermal linear expansion of the carrier between the counter device and the holding element and the thermal linear expansion of the plug rod material than in the area between the support surface 56 and the upper contact surface 16 , The thrust washer 9 is "tracked" by the thermal expansion of the rod-shaped inserts 54 of the displacement of the nut 7 caused by the thermal expansion of the carrier relative to the bolts 14, so that the thrust washer 9 is always under tension on the upper ends 52 the rod-shaped inserts 54 rests and thus the bolts 14, 24 are pulled against the upper contact surface 16. A firm, non-rotatable seating of the stopper rod 2 on the carrier 10 is therefore ensured even at high temperatures.

In the embodiment according to FIG. 1, the rotationally symmetrical installation space 17 is machined into a press-in sleeve 29 which is made of a metal workpiece. fabricated turned part. The installation space 17 has a cylindrical region 30, which extends downward from the upper contact surface 16 and to which a flat-tapering region 31 adjoins, which merges into the longitudinal recess 8. Through this configuration of the installation space 17, the bolts 14, 24 — possibly after removing the securing sleeve 19 — after the nut 7 has been removed or moved upward from its position “locked” into the “unlocked” position in that the Carrier is pushed further into the longitudinal recess 8 of the plug rod 2 and the bolts 14, 24 are displaced back into the cross section of the carrier 10 through the side walls of the flat conical region 31 of the installation space 17. After this process, the carrier 2 can be pulled up out of the stopper rod.

In its area 32 above the upper boundary surface of the installation space 17, the press-in sleeve forms part of the longitudinal recess 8. In this area 32, an inner all-round groove 33 is machined into the press-in sleeve 29, which serves to receive a heat-resistant sealing ring 34. The high sealing action between the press-in sleeve 29 and the carrier 10, which is required in special applications, can be achieved by the sealing ring 34.

In the embodiment of the arrangement 100 shown in FIG. 1, the press-in sleeve 29 has a cylindrical outer shape. Their security against rotation in the stopper rod 2 is served by a flat key surface 40 milled into its outer periphery. Since the press-in sleeve 29 is pressed together with the stopper rod 2, its outer periphery is completely surrounded by the ceramic stopper rod material.

In the exemplary embodiment according to FIG. 3, an annular space 58 which enlarges the central longitudinal recess 8 of the plug rod 2 is machined between the upper end face 11 of the plug rod and the upper end face 57 of the press-in sleeve 29 '. The bottom of the ring The space-forming region of the end face 57 of the press-in sleeve 29 'represents the support face 56' in this exemplary embodiment.

An insert designed as a support tube 59 is inserted into the annular space 58 from above and extends from the support surface 56 to slightly above the upper end surface 11 of the plug rod 2.

In this embodiment of the arrangement 100 according to the invention, the nut 7 is countered via the pressure disc 9 against the upper end 62 of the support tube 59, as a result of which the plug rod 2 is firmly seated on the carrier 10 in the manner described.

In the exemplary embodiment according to FIG. 3, two circumferential grooves 41, 42 which are at a vertical distance from one another are additionally worked into the outer circumference of the press-in sleeve 29 '. This configuration of the press-in sleeve 29 'creates additional connecting surfaces between the press-in sleeve 29' and the plug rod 2, so that overall the surface load acting on the plug rod material is reduced compared to the exemplary embodiment according to claim 1.

To improve the sealing effect, in this embodiment, for example, a heat-resistant sealing ring 43, as shown in FIG. 3, can also be inserted into the upper circular groove 41.

Claims

Patent claims 1. Arrangement for connecting an elongated stopper rod (2) made of a refractory material for a metallurgical vessel with the lifting device for the stopper rod with a carrier (10), at one end of which the lifting device acts and which engages with the other end engages in an inner longitudinal recess (8) of the stopper rod (2) from its upper end face (11), with at least one area of the carrier (10) protruding into the inner longitudinal recess (8) of the stopper rod (2) The holding element provided, which engages behind at least one contact surface (16) running in the stopper rod and which runs transversely to the longitudinal axis (L) of the arrangement, and locks the stopper rod against being pulled off the carrier and is provided on the carrier (10) with one above the retaining element , against a support surface (56) of the stopper rod stop (70) which limits the area of the support (10) projecting into the stopper rod (2) and the holding element counters against the contact surface (16), characterized in that at least one insert is provided between the support surface (56) and the stop (70), which is used in the event of temperature fluctuations due to the different thermal expansion coefficients of the stopper rod and of the carrier material in between the holding element and the stop (70) effective length range caused different changes in length compensated so that the holding element bears against the contact surface (16) even at higher temperatures of the stopper rod (2) and the support (10). 2. Arrangement according to claim 1, characterized in that the stop (70) of a nut (7) which is screwed onto an outer thread (6) of the carrier (10) extending from the end face of the stopper rod upwards supported against the application by means of a thrust washer (9). 3. Arrangement according to claim 1 or 2, characterized in that an annular space extending from the upper end face (11) of the stopper rod (2) at least around part of the region of the carrier (10) projecting into the stopper rod (58) is provided, the base of which forms the support surface (56). 4. Arrangement according to claim 3, characterized in that the insert is a suitable in the annular space (58) Stütz¬ tube (59) suitable thermal expansion coefficient, via which the stop (70) is supported on the support surface (56). 5. Arrangement according to claim 4, characterized in that the support tube (59) is divided into several longitudinal segments. 6. Arrangement according to one of claims 1 to 5, characterized in that the stopper rod (2) has a press-fit sleeve (29) firmly connected to it, the internal volume of which is an installation space (17) into which the contact surface (16) is incorporated, comprises _/ which forms a part of the longitudinal recess (8) above the installation space (17). 7. Arrangement according to claim 6, characterized in that the annular space (58) extends to the upper end face (57) of the press-in sleeve (29). 8. Arrangement according to claim 6 or 7, characterized gekenn¬ characterized in that the press-in sleeve (29) is made of the same metallic material as the carrier (10). 9. Arrangement according to claim 8, characterized in that the support tube (59) is made of the same metallic material as the carrier (10). 10. Arrangement according to claim 1 or 2, characterized gekenn¬ characterized in that from the upper end face (11) of the stopper rod (2) at least one approximately parallel to the central longitudinal recess (8) extending blind bore (53) is provided, the bottom of which Forms support surface (56). 11. The arrangement according to claim 10, characterized in that the support on the support surface (56) and the upper end face (11) of the plug rod (2) slightly superior insert (54) is rod-shaped and has an absolute thermal expansion coefficient, which is about the Sum of the absolute thermal expansion coefficient of the carrier (10) in the area between the stop (70) and the holding element and that of the plug rod material in the area between the support surface (56) and the upper contact surface (16). 12. The arrangement according to claim 10, characterized in that the length of the blind bore (53) corresponds approximately to twice the distance between the contact surface (16) and the end face (11) of the plug rod (2). 13. Arrangement according to claim 11 or 12, characterized gekenn¬ characterized in that the insert (54) is a made of the carrier material metal rod.