DE6927561U - CONTAINER WITH SLIDER CLOSURE FOR LIQUID MELT. - Google Patents

Description

Wiesbaden, July 31, 1972 £ Γ VXR / P / Su / Le. J

Pall 2378 gm

File number: G 69 275 61 .2
Interstop AG

Container with slide lock for liquid melt.

The invention relates to a container with a slide closure for liquid melt with a bottom brick with inlet and one attached to the inlet, which is arranged in the tank bottom Perforated plate and a sealing and displaceable relative to the perforated plate in a holder on Container bottom guided with a flow opening for melt connected slide plate, which with a Outlet is connected.

Such containers, in particular ladles for molten material Metal, are lined with refractory material. In the floor there is a floor stone with an outflow channel that extends downwards through a perforated plate made of refractory material attached to the floor extends, and with the flow opening one to the Underside of the fixed perforated plate slidable and tightly fitting slide plate for regulation the amount of outflow and to completely close the outflow opening is in operative connection. The slide plate is also made of refractory material.

Many occur with ladles and similar containers Difficulties arise not only on the very high level Temperature are due at which ier flow the liquid melt must be regulated, but also to the inevitable considerable temperature

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differences to which the parts of refractory material in contact with the molten metal are exposed are.

There is still no refractory material that can indefinitely combine thermal, chemical and erosive properties Withstands attack by rapidly flowing liquid metals at high temperatures. Make these attacks often the renewal of such materials is necessary at short intervals. There can also be temperature differences within the slide gate to different thermal expansion and / or deformation of the refractory materials, from which the slide lock consists, lead. As a result, it is extremely difficult the slide valve tightly at all times against the considerable static pressure level of the melt in the container keep. There is also the risk of the molten metal solidifying if it is exposed to parts of the metal that are too cold Slide plate comes into contact, which can damage the slide gate valve, e.g. by jamming ...

Another major difficulty with such liquid melt-containing containers with slide closures is the solidification of the melt upstream of the gate valve when the gate valve soot between is temporarily closed for successive casting operations.

The aim of the invention is to eliminate these difficulties largely by the refractory parts of the slide valve closure and the effluent flow, the ö ^r bottom connects the container with the slide fastener are designed in such a way that the interfaces of said portions - as far as it is closed slide valve closure are in contact with the molten metal - during the casting process a temperature of -

$ 927561-1,1172

Maintain that is equal to or slightly above the solidification temperature of the metal. As part of this task it is also desirable, that the part of the upper sliding surface the slide plate, which is in contact with the static perforated plate and pressed against it in a sealing manner is, as far as possible, a temperature which in turn is the solidification temperature of the liquid melt corresponds to or is slightly above and which essentially along said part of the upper The sliding surface of the slide plate is resistant.

For this purpose, it is proposed according to the innovation, the cross-sectional area of the outflow channel over its entire Height above the lower surface of the perforated plate or above one directly adjacent to this lower surface Make the area larger than the cross-sectional area the flow opening of the slide plate and the slide plate to be embedded in a fireproof support body made of fireproof insulating material. This has the effect that the temperature along the contact surface between the valve plate and the perforated plate is significantly increased, so that difficulties arising from undesired solidification of the liquid metal between castings result, are at least considerably reduced »The support body reduced by reducing the heat ™ losses at the slide plate is the risk that the temperature in this area drops to an extent that which solidifies the liquid metal at the bottom end of the outflow channel. This effect becomes even more special supported by the fact that the support body consists of a fireproof insulating material .. Also can slide plate and the support body can be designed together as a composite body. This results in advantages in production these parts.

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The outflow channel can in a manner known per se through the floor stone and a removable sleeve (inlet) made of refractory Be formed material to which the perforated plate connects in such a way that it together with the sleeve after Removal of the slide plate and support body can be removed from underneath the container and replaced can. This results in time savings in the assembly of the sleeve and perforated plate, which increases the economy of the casting process increased.

According to a further advantageous embodiment of the object According to the invention, the flow opening can be arranged eccentrically in the perforated plate. This is a greater overlap of the sealing surfaces between the perforated plate and the valve plate when the valve is in the closed position guaranteed, which increases the security of the process.

Finally, in a further embodiment of the invention, the slide plate and / or support body can be connected to an outlet which consists of an inner part made of refractory material and an outer part made of refractory material Composed of material with insulating properties. is. The inner part of this outlet can be in the Have cross-section diamond shape. By this special design of the outlet counteracts rapid heat dissipation to the outside, resulting in the known effect of cone formation being premature Solidification of the melt at the lower edge of the outlet is avoided and, on the other hand, a similar one Pouring stream achieved.

The invention is illustrated in FIGS Drawings shown and then explained in more detail. Show it

Fig. 1 is a partial representation of the lower part of a pouring ladle with slide gate in longitudinal section and

FIG. 2 shows a cross section along line A-A in FIG. 1.

The ladle 10 has a metal jacket 11 which encloses a refractory lining 12. At the bottom of the pan is surrounded by the refractory lining outside a rectangular Bodenstein .3 of refractory material with a round hole, which also carries out fire ^e esters material in the lower part serving as inlet sleeve fourteenth The sleeve 14 is un its lower surface with a perforated plate 1 5 fixedly connected from refractory material. A flow opening 16 leads through the bottom block 13, the sleeve 14 and the perforated plate 15, and the lower end of the flow opening 16 can be opened and closed with the aid of a slide valve generally designated 17. The movable part of the slide gate valve can be moved optionally in both directions of an axis with the aid of a drive that exerts pressure or tension, such as, for example, with the aid of a hydraulic drive device, partially shown at 1 8.

The slide lock also consists of a slidable slide plate 19 embedded in a support body 23 made of refractory material. Refractory material with a circular cross-sectional flow opening of the same diameter as the lower lying in the perforated plate 15 of the flow passage 16 valve plate and supporting bodies rest in a linearly displaceable by the drive 18 cast-iron housing 24 _t which also includes a Sammelausguß generally designated 21, of the is firmly connected in the interior of the housing with the support body and the slide plate and its central flow opening 22, which is diamond-shaped in cross section, is axially aligned with the flow opening 20 of the slide plate.

The collecting spout 21 consists of an inner part 21 a made of refractory material and an outer part 21b made of refractory material surrounding this part with heat-insulating Properties. The support body 23 also consists of fire

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Plague material with good heat insulating properties as well as sufficient mechanical strength. Its thermal conductivity is lower than that of the refractory material the slide plate 19. The housing 24 is slidably mounted on corresponding sliding guides, which are provided in a slide housing 26 below the ladle. The slide housing 26 is with the help pressed up against the bottom of the pan by bolts to provide the required lock and the ent- I Speaking necessary tight contact between the perforated plate 15 and the slide plate 19 to ensure. The surface of the slide plate 19 is a sliding surface formed and is here in linear sliding motion with the lower surface of the perforated plate 15 · In the event of a sliding movement of the slide lock initiated by the drive 1 8 17, the slide plate 19 can be moved between a position in which its opening 20 with the opening 16 located in the perforated plate completely coincides and a position in which the two openings are radially offset from one another laterally, so that the opening in the perforated plate 1 5 is closed by the slide plate 19.

The cross-section of the throughflow opening 16 widens gradually above the section _t, denoted by 16 ', which lies directly above the interface between the perforated plate and the slide plate. As a result, the cross section of the throughflow opening 16 is significantly larger than that of the throughflow opening 20 in the slide plate. The latter forms the cross-section which determines the maximum outflow which leaves the ladle at a given static pressure head. It is furthermore desirable that the height of the throughflow opening _f ie. the distance between said interface between perforated plate and slide plate and the upper end face of the bottom block 13, which lies in the same plane as the pan bottom, in relation to the cross section of the flow

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Opening is as small as possible. As an example, consider a ladle with a capacity of 100 tons of steel listed, at which the diameter of the flow opening 20 in the slide plate and that close to said Diameter of the flow opening 1 6 at the interface below the section 16 'about 50 mm to 70 mm, while the diameter of the flow opening 1 6 within the sleeve 14 in its narrowest cross section at least is about 130 mm; the distance between the mentioned The interface between the slide plate and the perforated plate and the bottom of the ladle should be around 300 mm be.

Such an arrangement ensures that the temperature differences between the contents of the molten metal in the ladle and the metal column resting on the sealing surface (Boundary surface) of the slide plate 19 is in the closed slide position, reduced to a minimum are. The flow openings 1 6 and 20 do not have to have circular cross-sections, but a number of such openings can also be provided.

The perforated plate 1 5 and the slide plate 1 9 must be made of highly refractory material and at least on their surfaces have a low porosity and a fine grain structure, so that a good seal is ensured. It is therefore important that there are no gaps between the lower surface of the perforated plate 15 "and the surface of the slide plate 19 (sliding surfaces) into which liquid metal melt can penetrate. This would undoubtedly harden in any gaps and ensure reliable movement of the slide gate valve Therefore, the contact surfaces of perforated plate 1 5 and slide plate 1 9 must be ground to a surface evenness of less than 0.05 mm. A highly refractory material used for perforated plate 1 5 and slide plate Ί 9 contains over 88 to 90% Al ₂ O- and

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has a rustiness of about 19 % and a hot flexural strength at 1400 degrees Celsius of 180 to 220 kg / cm. The thermal conductivity of this material is 3.8 to 4.1 kcal / m. / H. / ⁰ C at 1000 ° to 1200 ° C.

The large cross section of the flow opening 16 causes an unhindered downward flow of heat from the main contents of the liquid melt inside the ladle. On the other hand, the support body 23 provided below the slide plate 19 provides good thermal insulation for the slide plate. Although in Figure 1 the support body 23, as shown at 23 ', essentially the entire slide plate 19 includes, it would also suffice if the area of the slide plate that is in the closed slide position adjacent to the lower end of the flow opening 16, sufficient is isolated. The thickness of the support body 23 in the mentioned area should be about 50 mm to 7.5 mm, according to the heat-insulating properties of the material used.

In order to achieve the best results, the sleeve 14 as well as the sleeve 21a of the outlet 21 should be made of highly refractory Consist of material with a lower thermal conductivity, in contrast to the perforated plate 15, which avis highly refractory Material with the highest possible thermal conductivity - as stated above - is to be produced.

High alumina; Refractory material for the sleeves 14 and 21a contains over 78% Al ₃ O ₃ with a porosity of about 19%, while the hot bending strength at 1400 degrees Celsius is about 150-170 kg / cm * The thermal conductivity for this material is 2.0 to 2 , 1 kcal / m. / H./°C at ICOO ⁰ to 1200 ° C.

The refractory material with insulating properties for the support body 23 and the outer shell 21b is either a high-alumina material with over 70% Al ₂ O ₃

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a porosity of 50 to 60% and a volume weight from 1.3 to 1.4, with a thermal conductivity of 0.38 kcal at 600 ° C and 0.52 kcal at 1200 ° C or a material with more than 65% Α1 ~ 0 with a porosity from 50 to 60% and a density over 1, 0 and one Thermal conductivity of 0.41 kcal at 600 ° and 0.43 kcal at 1200 ° C.

All joints that come into contact with the molten metal and are marked with an R are marked with highly refractory mortar, e.g. magnesite mortar, (with not too low iron oxide content) with an addition of a few percent magnesium sulfate. All the joints that are not in contact with the molten metal and therefore have a lower average temperature, are marked with a T and should be coated with a fine, porous chamotte mortar with good thermal insulation properties be filled out. The narrow joint between the slide plate 19 and the support body 23 is made with a suitable adhesive mortar to fill.

Schj & erplatte 19 and support body 23 can from below the ladle removed. After removing these parts the sleeve 14 and the perforated plate 15 (both above the slide plate 19 attached) can be removed from below the ladle and replaced. The outside dimension the sleeve 1 λ runs upwards to conical and the Flow opening 1 6 within this sleeve as well as in Bodenstein 1 3 run inversely conically downwards.

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6927581-111.72

Claims (6)

Protection claims: 1. Container with slide lock for liquid melt, with a floor stone arranged in the container bottom with an inlet and a perforated plate attached to the inlet, as well as a sealing and displaceable relative to the perforated plate guided in a holder on the container bottom, with a Flow opening for the melt connected slide plate, which is connected to an outlet, through it characterized in that the cross-sectional area of the outflow channel (16) over its entire height above the lower surface the perforated plate (15) or above one directly this lower surface adjacent area is larger than the cross-sectional area of the flow opening of the Slide plate (19) and that the slide plate in a refractory support body (23) made of refractory insulating material is embedded. 2. Container with slide closure according to claim 1, characterized characterized in that the slide plate (19) and support body (23) are designed together as a composite body. 3. Container with slide closure according to claim 1 and 2, characterized in that the outflow channel (16) in on known way through the floor stone (13) and a removable sleeve (14) (inlet) made of refractory material is formed, to which the perforated plate (15) so that it connects together with the sleeve of is removable and replaceable underneath the container « 4 «container with slide closure according to claims 1 and 3f characterized by an eccentric arrangement of the Flow opening in the perforated plate (15) * - τι - 5- container with slide closure according to claims 1 up to 4, characterized in that the slide plate and / or support body are connected to an outlet (22), which consists of an inner part (21a) made of refractory material and an outer part (21b) made of refractory insulating material is composed. 6. Container with slide closure according to claim 5 characterized in that the inner part (21a) of the outlet ^ - has a diamond shape in cross section.