DE9301974U1 - Cylindrical block mould with bottom protection for additives to metallic melts, preferably iron melts - Google Patents

Description

- 2 Description

"Cylindrical block mold with bottom protection for additives to metallic melts, preferably eJsoliischmelzzoii"

State of the art

The physical properties of melt additives for ladle addition determine their yield and effect and thus the application of an effective addition technique.

If, for example, such additives are lower in terms of density and melting point than the melt to be treated, or consist partly or completely of substances that already evaporate at the melting temperature, introduction methods or delivery forms for the treatment agents must be used which ensure that the reaction of the additive with the melt begins as far as possible below the bath surface. For this purpose, various process techniques and delivery forms for the treatment agents to be introduced are available for ladle addition, for example the immersion process. This is used, among other things, for introducing high-magnesium FeSiMg alloys (20-50% Mg, preferably approx. 30% Mg) into cast iron melts to produce cast iron with spheroidal graphite or vermicular graphite. Today, the FeSiMg alloy is almost exclusively immersed in the form of a cylindrical block , surrounded by a sheet metal ring or jacket 1 of approximately 1 mm thickness (Fig. 1), by means of a ceramic immersion bell into the melt in a ladle up to just above the bottom of the ladle.

The ring-shaped sheet metal casing of the cylindrical master alloy block made of FeSiMg, the surface and base of which are exposed and not covered with sheet metal (Fig.l), primarily has the task of preventing the brittle block material from cracking as a result of impact or falling stress, whereby the sheet metal casing also has a production-related form-technical task of producing a round, cylindrical block. The sheet metal casing has never been considered to have a reaction-retarding effect when the block is immersed in the melt, which is also confirmed by the fact that the current design has only been supplied with a sheet metal casing for around 30 years, and the base and surface of the cylindrical block are not covered with sheet metal and are exposed and unprotected (Fig.l).

problem

Immediately upon immersion of the block-shaped treatment agent described above into the melt, a violent reaction triggered by magnesium evaporation begins between the unprotected bottom surface of the alloy block and the melt in the ladle due to the relatively high Mg content of approx. 30%. This is partly associated with ladle ejections, which can be dangerous, especially with large melts.

Solution

This problem, or the reaction that begins immediately when the alloy block comes into contact with the melt, is prevented or largely delayed by the block's bottom protection proposed according to the invention 1 (Fig. 2).

Benefits achieved

No or only very little iron is ejected from the ladle when the treatment agent block comes into contact with the melt. Low sinking speed of the immersion bell with treatment agent to be inserted is possible. Improved yield of the additive.

W§i£§£e_Design_of_the_invention

a) An advantageous embodiment of the invention is, for example, a conical formation of the soil protection layer 1 (Fig. 3) and the block, whereby the resistance caused by buoyancy against the immersion of the block in the melt is reduced.

The angle of the truncated cone should not be greater than 130 °.

b) For the suspension of the treatment agent block in the immersion bell various solutions are used, such as casting hooks into the block surface 4 (Fig.l) or drilling holes in the protruding sheet metal casing 3 (Fig.l).

When the floor protection proposed according to the invention is made from a metal plate, this can have a cast-on hook 4 (Fig. 4) which is guided in the center of the block and protrudes from the top of the block.

c) The delay in the start of the reaction between the treatment agent block and the melt achieved by the invention can be further delayed if the bottom protection proposed according to claims 1 and 2 is additionally transferred to the surface of the block. The treatment agent block then has a closed protective layer both over the bottom, the cylindrical shell and on the surface opposite the bottom.

Drawings (explanations)

Fig.l Conventional treatment additive in cylindrical block form

1 Treatment agent

2 ring-shaped sheet metal jacket

3 holes/

4 hooks \ ^for hanging the block in the diving bell

Fig.2 Treatment agent additive proposed according to the invention in cylindrical block form with soil protection

1 Soil protection

2 Treatment agents

3 ring-shaped sheet metal jacket

Fig.3 Treatment agent additive proposed according to the invention in cylindrical block form with conical bottom and bottom protection

1 conical floor protection

2 Treatment agents

3 ring-shaped sheet metal jacket

Fig.4 Treatment agent additive proposed according to the invention in cylindrical block form with floor protection plate and welded hook

Version A with flat bottom Version B with conical bottom

1 floor protection plate

2 Treatment agents

3 ring-shaped sheet metal jacket

4 hooks welded to floor protection plate

Claims (5)

Protection claims 1. Cylindrical block mould with bottom protection for additives to metallic melts, preferably for ladle treatment characterized, that the floor protection 1 (Fig. 2) preferably consists of metallic and/or ceramic materials whose melting point or softening point is not lower than that of the melt to be treated, into which the blocks are introduced (immersed). 2. Cylindrical, block-shaped treatment agents according to claim 1 consisting of master alloys with a high magnesium content (20-50% Mg, preferably with approx. 30% Mg) characterized, - that the floor protection is at least 1 mm, preferably 3 - 10 mm thick ; - that the floor protection fits tightly to the bottom of the block and that there are no air pockets or air bubbles between the block and the floor 3. Cylindrical, block-shaped treatment agents according to the claims 1 and 2 characterized, that the floor protection and block floor 1 (Fig.3) are conical and the obtuse angle is preferably less than 130 °. 4. Cylindrical, block-shaped treatment agents according to the claims 2 and 3 characterized, that the floor protection made of sheet steel or cast iron plate for the suspension of the cylindrical block in the diving bell has a rod 4 (Fig.4) arranged vertically upwards in the middle of the plate, which protrudes from the top of the block. 5. Cylindrical, block-shaped treatment agents according to claims 1 and 2 characterized, that in addition to the base and cylindrical shell, the surface of the block also has a metallic and/or ceramic protective layer.