EP0076564A1

EP0076564A1 - Hot tops

Info

Publication number: EP0076564A1
Application number: EP82304235A
Authority: EP
Inventors: Heinrich Comes; Klaus Friede
Original assignee: Foseco Trading AG
Current assignee: Foseco Trading AG
Priority date: 1981-09-23
Filing date: 1982-08-11
Publication date: 1983-04-13
Also published as: EP0076564B1; AU546187B2; ATE13264T1; ZA825958B; BR8205540A; IN157313B; ES267396Y; AU8754182A; ES267396U; KR880001957B1; KR840001451A; MX162784A; DE3263540D1

Abstract

A hot top lining slab (2) for an ingot mould (1) used in the casting of e.g. steel ingots has a plurality of ribs (4, 5, 6, 7, 8) on its back face and is thick and of low density matter. The ribs (4, 5, 6, 7, 8) define a plurality of enclosed recesses (9) spaced inwardly from the periphery of the slab. The slabs (2) enable the amount of head metal to be reduced but sound ingots still obtained.

Description

The invention concerns hot tops for metallurgical moulds, in particular for ingot moulds, especially for casting steel.
In casting steel ingots it is desirable to keep the metal in the head of the mould molten whilst the metal in the body of the mould is cocling and solidifying, because the metal in the body of the mould shrinks as it cools and solidifies and, if the head metal is kept molten, the head metal feeds down into the ingot body and achieves the desirable effect of inhibiting the formation of shrinkage cavities in the body of the ingot. The head metal may be kept molten by use of a hot top and this may comprise a number of refractory, heat-insulating articles e.g. slabs positioned as a lining in the head of the mould or in a separate head box at the top of the mould, in the latter case the head metal being within the head box.
Originally hot top linings were commonly of firebrick, usually with a density of about 2 to 3g./cm.³. Firebrick is not a good heat-insulator and for this reason the firebrick linings were thick e.g. 75 mm. However, the thick firebrick linings were of high thermal capacity and therefore exerted a marked and undesirable initial chilling effect on the head metal.
The chilling effect mentioned above and other disadvantages of firebrick hot top linings were greatly reduced or eliminated by the subsequent development of slurry-formed, expendable hot top lining articles having good heat-insulating properties and low densities,. typically about 1.1 g./cm.³. The good heat-insulating properties of such articles mean that adequate heat-insulation is provided by a much thinner lining, typically 3D mm., compared with firebrick linings.
Partly because the known slurry-formed, expendable lining articles are thin and partly because of the thermal properties of the materials of the articles, such linings are of low thermal capacity and therefore exert only a small initial chilling effect on the head metal. The chilling effect of such linings is minimised by making the linings as thin as is compatible with providing the required heat-insulation and mechanical strength. In any event the dewatering and drying steps necessary in making the slurry-formed articles become considerably more difficult if the thickness of the article is significantly greater than 30 mm. Moreover, if th_E articles are made thicker, they become heavier and less Easily handled.
According to the invention a hot top lining .slab is of slurry-formed refractory, heat-insulating material, has a density in the range of 0.3 to 0.85 g./ cm.³, has a plurality of ribs at one face of the slab defining a plurality of enclosed recesses spaced inwardly from the periphery of the slab and has an average overall thickness of at least 40 mm. In use the slabs are positioned with the recessed face outwards i.e. away from the molten metal.
It has been found in accordance with the invention that the particular combination of features specified enables a very desirable combination of advantages to be obtained.
The fact that the slabs are slurry-formed is a manufacturing convenience and, as part of the thickness of the slabs is accounted for by the ribs, the slabs do not present the dewatering and drying difficulties that would arise if the slabs were of the same overall thickness but die not have the recesses.
The great thickness of the slabs enables an excellent heel-insulating effect to be achieved, an effect enhanced by the air in the recesses. Furthermore, good heat-insulating properties are associated with the low density of the slabs. Despite the thickness of the slabs, a very small initial chilling effect is suffered as the material of the slabs is itself of low thermal capacity, a factor associated with the low density of the slabs.
The fact that the slabs are of low density material coupled with the presence of the recesses means that, despite their thickness, the slabs are not heavy and they can easily be handled. Also, the presence of the ribs serves to increase the mechanical strength of the slabs whilst not greatly increasing their thermal capacity. This combination of properties is especially valuable as the strength of slurry-formed refractory, heat-insulating slabs tends to decrease with a decrease in density.
In casting steel ingots it was widely accepted for many years that all the head metal should be discarded and therefore an important objective was to minimise the ratio of metal in the head of the ingot to metal in the body of the ingot (subject to the requirement that the body of the ingot should be sound) in order that the proportion of cast metal discarded should be as low as possible. More recently this objective has been somewhat modified and hot top linings have been designed so that some of the head metal should be usable. However, hot top linings commonly result in the formation of ingots with a shoulder where the head metal adjoins the body of the ingot and, if the head metal is not entirely discarded, the shoulder can result in defects in the steel after the ingot has been rolled. Such defects are minimised if the shoulder is slight and this factor has favoured the use of thin hot top linings. The present invention contrasts with this approach: the thick slabs enable the proportion of head metal to be decreased. Preferably the average overall thickness of the slabs is at least 5D mm.
In the slabs of the invention the ribs preferably account for at least 30%, e.g. about 50%, of the overall thickness of the slab. The ribs preferably define at least three recesses and the total area of the recesses at the outer face of the slab is preferably at least 30% of the total area of the outer surface of the slab. Some or all of the ribs, especially those separating adjacent recesses, preferably taper outwardly. The tapered ribs are preferably at least twice as wide at the base as at the tip. The preferred features just described characterise slabs of the invention with especially valuable thermal and mechanical properties and which are easy to make and handle.
The recesses may be of various shapes preferably generally rectangular.
The slabs may be slurry-formed in known manner using known materials and using a former shaped to form the slabs with the ribs and recesses. The ingredients of the slab comprise particulate refractory filler, some at least of which is lightweight e.g. has a bulk density not greater than 0.35 g./cm.³, a binder and, optionally, organic and/or inorganic fibres. Preferably the lightweight filler is one or more of calcined rice husks and expanded minerals, e.g. expanded perlite. The density of the slab is most preferably 0.4 to 0.7 g./cm..
An edge of the slab (the lowermost edge in use) is preferably bevelled so that the molten metal contacting face of the slab does not extend downwards as far as the opposite face of the slab. Preferably the bevelled edge is generally concave and the concavity is preferably provided by means of a multiple, e.g. oouble, re-entrant bevel . In this way the abruptness of the resultant shoulder is diminished and the height in the hot top where'residual mould flux remains after casting is increased. As already mentioned, the thickness of the slab enables the proportion of head metal to be decreased and the features just described help to maximise the proportion of the head metal that is usable.
An ingot mould having a hot top lining comprising slabs of the invention forms a part of the invention as does a head box having such a lining. Preferably the lining is in the head of an ingot mould having straight internal walls.
The invention is further described with reference to the accompanying diagrammatic drawings in which:

Figure 1 is a vertical section through the upper part of an ingot mould having a hot top lining comprising slabs of the invention,
Figure 2 is a cross-section through the hot top lining at line 1-1 in Figure 1 and,
Figure 3 in a view of the recessed face of one of the slabs.

Referring to the drawings, the ingot mould has wells 1 tapering together upwardly to give an ingot narrower at the top than the bottom, and in the head of the mould is a hot top lining comprising four slurry-formed refractory, heat-insulating slabs 2 having a density of 0.5 g./cm.³. The slabs 2 are suspended from the top of the mould by conventional means (not shown) and are held firmly in position by four wedges 3 of refractory, heat-insulating material.
Each of the slabs 2 has peripheral ribs 4, 5, 6, 7 at its outer face and these ribs together with two outwardly tapering inner ribs 6 define three recesses 9 in the outer face of the slab.
Whilst the invention has been described above with specific reference to the drawings, it is to be understood that the recesses 9 may be vertically disposed in the outer face of slab 2. If desired, the eight-piece assembly illustrated in Figure 2 may be substituted by four, interengaging slabs cr a six-piece assembly consisting of four slabs and two wedges.

Claims

1. A hot top lining slab (2) of slurry-formed refractory heat-insulating material, characterised in that the slab has a density in the range of 0.3 to 0.85 g/cm , and has a plurality of ribs (4, 5, 6, 7, 8) at one face of the slab (2) defining a plurality of enclosed recesses (9) spaced inwardly from the periphery of the slab (2) and has an average overall thickness of at least 40 mm.

2. A hot top lining slab (2) according to claim 1 characterised in that the average overall thickness of the slab is at least 50 mm.

3. A hot top lining slab (2) according to claim 1 or 2 characterised in that the ribs (4, 5, 6, 7, 8) provide at least 30% of the overall thickness of the slab (2).

4. A hot top lining slab (2) according to any preceding claim characterised in that the ribs (4, 5, 6, 7, 8) define at least three recesses (9).

5. A hot top lining slab (2) according to any preceding claim characterised in that the total area of the recesses (9) at the outer face of the slab (2) is at least 30% of the total area of the outer surface of the slab (2).

6. A hot top lining slab (2) according to any preceding claim characterised in that at least one of the ribs (8) taper outwardly.

7. A hot top lining slab (2) according to any preceding claim characterised in that the at least one tapered rib (8) is at least twice as wide at the base as at the tip.

8. A hot top lining slab (2) according to any preceding claim characterised in that the face opposite to the face having the recesses (9) is bevelled at the edge which is to be lowermost in use.

9. A hot top lining slab (2) according to claim 8 characterised in that the bevel is a multiple, re-entrant bevel.

10. An ingot mould or ingot mould head box (1) having a hot top lining provided by a plurality of slabs (2) according to any preceding claim characterised in that each slab has its recessed surface facing outwardly.