DE3526083A1 - Sheet-metal casing for a sliding plate with a nozzle, for a casting ladle or the like, and method for its manufacture - Google Patents

Abstract

Parts (2, 3) of heat-resistant non-metallic material are held in a sheet-metal casing (1). The sheet-metal casing (1) is produced by deep-drawing from a single piece of sheet steel. The one-piece design and production by deep-drawing ensure high strength and good flatness of a contact area (5) in which a sliding plate (2) rests on the sheet-metal casing (1). <IMAGE>

Description

The invention relates to a sheet metal jacket for a Sliding plate with spout, for a ladle or one other container containing liquid metal, with egg nem essentially flat support part for a plate heat-resistant material, one surrounding the support part the surrounding edge and a dome protruding from the support part for receiving an Aus containing a spout cast part made of heat-resistant material.

Liquid metal with a high melting temperature can only be used with non-metallic heat-resistant materials in contact to be brought. Such materials have little mechanical strength, which is why the heat-resistant material must be supported by a sheet metal jacket.

Known sheet metal jackets of the type mentioned are there made by that the surrounding edge, the support part and the cathedral each formed for itself and then to it be welded together. The stiffness of the known Sheet metal jackets also depend on the quality of the weld seams. When welding, the individual parts warp, causing the Support part can be uneven. This is undesirable because the Plate made of heat-resistant material because of its slide function is precisely machined and evenly from the support part  should be supported. One between the slide plate and the layer of mortar inserted should be possible have uniform thickness, which is only possible if the support part is flat. The production of the well-known sheet metal Coats are expensive because of the need for multiple items cut, shape and weld together. The appearance of well-known sheet metal jackets is due to the weld seam unsatisfactory.

The invention has for its object a sheet metal jacket of the type mentioned in such a way that the mentioned Disadvantages are avoided, especially the level unit should be good.

This object is achieved in that the Border, the support part and the cathedral from a single steel sheet formed by deep drawing.

A sheet metal jacket designed in this way can be produced more cheaply len than the well-known sheet metal shells, mainly because time-consuming welding work is not necessary. Because of the The support part can be omitted from welding work Make exactly so that the heat-resistant Ma existing plate with a layer of mortar from anywhere uniform thickness are supported on the support part can. The sheet metal jacket according to the invention also has a good one Appearance because there are no welds and on the Transitions between the border and the support part and between rule support part and dome according to claim 9, preferably from curves are present. The sheet metal jacket according to the invention is also particularly dimensionally stable.

Different shapes are possible for the cathedral, all of them in one piece with the other areas of the sheet have the jacket made. The cathedral can e.g. be cylindrical (Claim 2). In this case it is advantageous to be outdoors Provide a retracted edge at the end of the cathedral (claim 3).  

The retraction of the edge makes it form-fitting Hold of the covered parts achieved. The cathedral can also taper towards its free end (claim 4), whereby different shapes come into consideration men. The taper also creates a positive fit The sheathed material is held against falling out. The taper can be conical (claim 5). This form is particularly simple and correspondingly easy to manufacture. However, it can also be between the support part and the free end ne stage are provided (claim 6). The areas of both on the part of the step can in turn be tapered in Direction of the free end of the cathedral (claim 7). It is ever but also possible (claim 8), e.g. the top section of the cathedral, namely the section between the support part and Step conical and the dome section below it zylin to train drisch. The reverse is also possible in such a way that the lower dome section is conical and the upper dome section is cylindrical.

An advantageous method for producing the sheet metal jacket is specified in claim 10 and is characterized in that that starting from a flat sheet by deep drawing the Surrounding edge and a depression with soil is drawn, whose wall coincides with the wall of the cathedral to be manufactured true and that then the bottom of the depression and cut off a holding strip on the surrounding edge the.

With such a method it can be done proportionally strong deformation, which is necessary for the formation of the cathedral, reach without creating wrinkles in the dome wall.

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

Fig. 1 is a bottom view according to the arrow I in Fig. 2 of a slider consisting of egg nem sheet metal casing and in this held Tei len of heat-resistant, non-metallic material, wherein the metal jacket has a koni rule Dom,

Fig. 2 is a cross section along line II-II in Fig. 1,

Fig. 3 dung a view in the direction of arrow III in Fig. 4 of a sheet metal jacket of a slider accelerator as a second embodiment of OF INVENTION, in which the dome of the metal jacket is abge ranks,

Fig. 4 is a cross section along line IV-IV in Fig. 3,

Fig. 5 is a bottom view according to the arrow V in Fig. 6 of a sheet metal jacket of a slider accelerator as a third embodiment of the invention, wherein the spine of the sheet metal jacket is formed from cylindrical,

Fig. 6 shows a cross section along line VI-VI in Fig. 5,

Fig. 7 is a view corresponding to the arrow VII in Fig. 8 of a sheet metal jacket of a slide according to a fourth embodiment of the invention, wherein the dome of the sheet metal jacket also has a cylindrical shape, but in contrast to the embodiment according to FIGS. 5 and 6 on its free margin is drawn, and

Fig. 8 is a cross section along line VIII-VIII in Fig. 7.

The slider according to FIGS. 1 and 2 consists of a steel jacket 1, a plate 2 made of heat resistant nichtmetalli's material and a spout 3 which is also made of heat-resistant, non-metallic material, before preferably made of the same material as the plate 2. The sheet metal jacket 1 serves to support the parts 2 and 3 which are embedded in the sheet metal jacket 1 with mortar 4 .

The sheet metal jacket 1 has a flat support part 5 for the plate 2 , a surrounding the support part 5 surrounding edge 6 and a dome 7th The support part 5 is flat and has an oval shape overall, as shown in FIG. 1. The peripheral edge 6 is perpendicular to the plane of the support part and the dome 7 tapers starting from its foot end on the support part 1 to its free end 7 a .

The entire sheet metal jacket is made in one piece from sheet steel by deep drawing. During deep drawing, the sheet, which is initially flat, is clamped at its edge. The clamping edge, which is no longer present on the finished sheet metal jacket, is shown in dash-dotted lines and designated 8 . When Tiefzie hen the dome 7 is initially a part that has a bottom 9 at the end of the dome, which is also shown in dash-dotted lines. For the completion of the sheet metal jacket is removed after removal of the deep-drawn part from the press of the retaining edge 8 along the free edge 6 a of the surrounding part and the bottom 9 along the free edge 7 a of the dome 7 abge.

During manufacture, a rounded transition region 10 is formed at the transition point between the peripheral edge 6 and the support part 5 . A corresponding rounded ter transition area 11 arises at the attachment point of the Do mes 7 on the support part 5th When manufacturing by deep drawing, there is an exactly flat support part 5 , which later does not warp, as is the case with the known weld constructions.

When the slide is completed, the casting part 3 is first inserted into the dome 7 , 7 mortar being entered between the outer circumference of the pouring part 3 and the inside of the dome. Then the plate 2 is inserted into the metal jacket, 2 mortar 4 being inserted between the underside of the plate 2 and the support part 5 and also between the peripheral edge 6 of the metal jacket and the outer circumference of the plate. Another layer of mortar is also inserted between the pouring part 3 and the plate 2 . The surface 2 a of the plate 2 is formed exactly flat by grinding. This surface is intended to cooperate with an also ground counter surface for sealing. For maintaining the flatness of the surface 2 a good sub-support by the support section 2 is required. For this purpose, the mortar layer between the plate 2 and the bearing part 5 should be as thick as possible everywhere. This is ensured by the good flatness of the support part 5 .

When using the slide this can optionally be brought into a position in which a pouring opening 12 is covered with an opening in a container in which there is a molten metal and in a position in which this container opening is covered, then the part of the plate 2 appearing on the right in the drawing closes the container opening.

The conical shape of the dome 7 exerts a holding effect on the pouring part 3 . This could not fall out even if it were not mortared, since its largest diameter is larger than the inside diameter of the dome 7 at its free end 7 a .

In the embodiment of Fig. 3, the support member 5 and the Umfassungsrand 6 is the same as those of the off guide die of FIGS. 1 and 2. The here designated 13. Dom but has a different shape. The dome 13 has an upper section 14 , a step section 15 and a lower section 16 . The sections 14 and 16 taper a little towards the free end 13 a of the dome 13 .

Also, the sheet-metal jacket of Fig. 3 is provided by deep drawing forth. Through the stage 15 , a positive connection between a pouring part (not shown) and the sheet metal jacket can be produced.

In the embodiment according to FIGS. 5 and 6, in the te with a receiving part 5 'a cylindrical dome 17 is net angeord. The sheet metal jacket of Figs. 4 and 5 is particularly suited to designs in which the insert is non-metallic lischem heat-resistant material is made of one piece, so that a backup of the pouring part against falling out by its connection to the on the support portion 5 'lying plate is guaranteed. The actuation of a slider with a metal jacket according to FIGS. 5 and 6, optionally after one or the other direction take place, since the sealing surface of the plate opening either side of the spout is the same.

The embodiment according to FIGS. 7 and 8 differs from the embodiment according to FIGS. 5 and 6 only in that a recess 18 is provided at the free end of the dome designated 17 'here, with which the edge is achieved 17 ' a has a smaller inner diameter than the dome 17 ' in the rest. A positive hold of a pouring part can thus be achieved again.

Claims (10)

1. Sheet metal jacket for a slide plate with spout, for a ladle or other liquid metal holding container, with a substantially flat on part for a plate made of heat-resistant material, egg nem surrounding the support part and a protruding from the support part dome for Inclusion of a pouring opening containing a pouring part made of heat-resistant material, characterized in that the peripheral edge ( 6 ; 6 '), the support part ( 5 ; 5 ') and the dome ( 7 ; 13 ; 17 ; 17 ') from a single, by Thermoformed formed sheet steel. 2. Sheet metal jacket according to claim 1, characterized in that the dome ( 17 ; 17 ') is cylindrical. 3. Sheet metal jacket according to claim 2, characterized in that the dome ( 17 ') has at its free end an inwardly drawn edge ( 18 ). 4. Sheet metal jacket according to claim 1, characterized in that the dome ( 7 ; 13 ) tapers ver to its free end. 5. Sheet metal jacket according to claim 4, characterized in that the dome ( 7 ) is conical overall. 6. Sheet metal jacket according to claim 4, characterized in that the dome ( 13 ) between its attachment point on the support part ( 5 ) and its free end ( 13 a) has a step ( 15 ) over which the dome ( 13 ) tapers . 7. Sheet metal jacket according to claim 6, characterized in that the dome sections ( 14 , 16 ) on both sides of the step ( 15 ) are conical and taper towards the free end ( 13 a) of the dome ( 13 ). 8. Sheet metal jacket according to claim 6, characterized in that one of the dome sections is conical and the other cylin is drisch, the conical section tapered towards the free end of the cathedral, preferably the dome section between the support part and step conical and the cathedral section between step and free end of Thursday mes is cylindrical. 9. Sheet metal jacket according to one of the preceding claims, characterized in that the transition region ( 10 ) between the peripheral edge ( 6 ) and the support part ( 5 ; 5 ') and the transition region ( 11 ) between the support part ( 5 ; 5 ') and the cathedral ( 7 ; 13 ; 17 ; 17 ') are rounded. 10. A method for producing a sheet metal jacket according to one or more of the preceding claims, characterized in that starting from a flat sheet metal by deep-drawing the surrounding edge ( 6 ) and a depression with bottom ( 9 ) is drawn, the wall of which is connected to the wall of the to produce domes ( 7 ; 13 , 17 ; 17 ') matches and that then ran the bottom ( 9 ) of the recess and a neck test strip ( 8 ) at the surrounding edge ( 6 ) are cut off.