RU1782191C - Method of manufacturing fashion casts and mold therefor - Google Patents

Abstract

SUMMARY OF THE INVENTION: a method for producing shaped castings involves the accumulation of metal and slag in smelting tanks and pouring them into casting molds, in which each casting mold, consisting of two containers communicating with one another, has finished and completely filled the first tank with superheated slag. then the metal is poured into it until the second mold tank is completely filled with slag. The mold consists of two containers communicating with each other, and the second container is located in the upper part of the first container, and the volume is W The capacity is equal to the volume of the forming part of the first capacity. A technological insert with a working surface with a desired desired end surface of the casting is fitted with gaps on the cylindrical outer surface of the thread in the upper part to provide slag exit. The rod for producing a cylindrical cavity in the casting is made in the form of an axially split sleeve with a cylindrical outer surface and a conical inner one, into which a conical axis is placed. In this case, the cutting surfaces of the sleeve, forming one of its parts, are made parallel to each other and parallel to the axial plane of the sleeve, and all other cutting planes are made separate. 2 sec item, 2 s. P. f-ly, 1 tab., 2 ill. sl c

Description

The invention relates to foundry and special electrometallurgy and can be used to produce high-quality shaped castings from metals of various smelting methods, including electroslag metal.

A known method according to which the metal is accumulated in the melting tank by the electroslag method and is poured into casting molds or pouring metal into casting molds is carried out together with slag,

used to produce electroslag metal.

This method makes it possible to obtain castings of a relatively complex configuration and high quality using precise metal molds - reusable chill molds without the use of any burn prevention measures.

The casting metal obtained in this way is not inferior and even superior in quality to the deformed metal of open smelting. However, the performance of such a method is extremely low, since it is limited in that the method requires the simultaneous pouring of metal and slag into the mold, which means that the volume of metal and slag accumulated in one melting tank should correspond to the filling volume of only one form. In order to fill out another form, it is necessary to repeat the process of accumulation of metal and slag, etc., i.e., in the known method, it is not possible to dose in certain proportions of metal and slag into several forms.

Existing double and multi-strand casting schemes, when a melt is poured into two or more molds from one tank, are not widely used due to a relatively small increase in productivity, while the casting process is significantly complicated. In addition, the disadvantage of this method using casting molds known for its implementation is that the upper part of the casting directly above which the slag bath is located is flat, which limits the scope of the method and increases the mass ratio of the workpiece and the finished part. The resulting holes have a conical shape due to the need to use conical metal rods, which increases the machining allowances. In addition, the removal of the rods from the mold is associated with certain difficulties associated with the need to relatively accurately determine the knockout time depending on the mold filling mode, the temperature regime of melt crystallization, etc. The use of rods from non-metallic materials is not justified due to a one-time ™ their use.

At the same time, this method is quite energy intensive. The specific energy consumption for various sources is approximately 750-820 kW. h / t In practice, power consumption is most often in the range of 1000-1200 kW. h / t

The aim of the invention is to increase productivity while maintaining high quality castings

This is achieved by the fact that before draining the metal accumulated in a melting tank, for example, an induction furnace, in each ligue form, which consists of two tanks communicating with each other, first the first tank is completely filled with superheated slag and then the metal is poured into it until it is completely filling the second tank with slag It is possible to pour metal accumulated in the melting tank by the electroslag method. In this case, before casting the metal into molds, it is first drained from the melting tank

slag used to produce electroslag metal into a separate tank where the same overheated slag is accumulated in parallel.

Foundry mold for carrying out

0 of the method includes a first vessel for receiving the melt and forming the casting, and a second vessel for draining the excess slag and communicating with the first at a level that ensures that the first vessel is completely filled before the slag enters the second. The volume of the second tank is equal to the volume of the forming part of the first tank or the volume of the casting. The first tank is placed with gaps to provide output

0 slag technological insert with a working surface corresponding to the desired end surface of the casting. The rod for producing a cylindrical cavity in the casting is made in the form of a sleeve split in the axial direction 5 with a cylindrical outer surface and a conical inner one, inside of which a conical axis is placed.

In FIG. Figures 1 and 2 show a mold, section.

The first tank is formed by the bottom T and the ring shell 2. The second tank is formed by the ring shell 2 and the part 3. In the opening of the bottom 1 there is a cut 5 in the axial direction of the sleeve with a cylindrical outer surface and conical in the lower part, consisting of parts 4, 5, 6 , 7 with gaps between them. Moreover, the cutting surfaces of the sleeve, dividing parts 4, 5 and 7 are made parallel to each other and parallel to the axial plane of the sleeve, and the cutting planes, dividing parts 5, 6, 7 are made radial.

5 In the upper part of the split sleeve is made conical on the inner surface at a small length and cylindrical on the outside. A sleeve 8, is mounted on the conical inner surface. limiting radial movement of parts

bushings inward. A technological insert is planted on a cylindrical outer surface in the upper part of the split sleeve, consisting of two parts 9, 10, which are fixed by the ring 11. Inside the split

0 of the sleeve, an axis 12 is placed with a conical surface in the lower part, which serves to expand the components of the sleeve in the radial direction

The axis 12 in the upper part has a rectangular cut with a slope on one side into which the wedge 13 is inserted. Details, 10 technological inserts are made in the lower parts with 4 cutouts 14, which serve to facilitate the flow of the melt, and in the upper parts have 4 equally spaced windows 15 for air to escape from the inner cavity of the insert when the level of slag in it rises due to the displacement of the latter by incoming metal.

The volume of the second cavity V2 is equal to the volume of the filled metal VL

The method and casting form work as follows.

The superheated slag accumulated in the melting tank is poured into the first container of the mold until it is completely filled. Then metal is discharged from the other melting tank, which passes through the slag, is further refined, enters the lower part of the first tank and displaces the slag with a volume equal to the volume of the metal being poured. into the second tank, where it overflows over the edges of the first tank, Metal is poured until the second tank is completely filled with slag. In this way, the volume of metal to be poured is visually limited. After completely filling the second tank with slag, the metal pouring is stopped and the cycle is repeated with a different shape, etc., which can be mounted on the conveyor. On the walls of the first container and the rod, as a result of the quick pouring of first slag and then metal, a thin slag skull is formed, as in the known method of electroslag chill casting, which eliminates the interaction of the cast metal with the mold and the possibility of burning. The slag bath displaced into the upper part of the casting mold forms a kind of thermal extension that contributes to the directional solidification of the casting, eliminating the formation of shrinkage friability in the casting, i.e., the crystallization process is similar to the known electroslag chill casting method.

In contrast to this method, the core for producing a cavity in the casting is not knocked out immediately after pouring the melt. After the metal and slag have solidified, the wedge 13 supporting the conical axis 12 is removed and pushed out of the split sleeve. The ring 11 is removed, fixing the parts 9, 10 of the technological insert and the sleeve 8. Then the mold is turned over and the crystallized workpiece is removed together with the slag bath, the split sleeve and

details 9, 10 of the technological insert. In this position, the parts 4, 5, 6, 7 of the split sleeve are easily removed from the hole in the casting and slag overstack after the 5 is shifted to the inside of the split sleeve. Then, parts 9.10 of the process insert are disconnected through the connector, and solidified slag is removed from them. When the mold is overturned, slag is removed from the second tank.

0 Experimental swimming trunks were carried out at the Belarusian Automobile Plant.

When conducting experimental melts, a metal of chemical composition corresponding to the grade of steel 18Kh2N4VA was obtained in

5 induction furnace followed by treatment with synthetic slag. To prepare the slag used in the electroslag process, an ANF-29 grade flux was used, which was obtained in

0 a separate unit with a ceramic crucible and a graphite non-consumable electrode. In order to decarburize the slag during its melting in the crucible, nickel oxide was introduced in the form of agglomerate in an amount of 0.7%

5 by weight of slag. The slag at the end of melting was superheated to a temperature of 100-200 ° C higher than the melting temperature of the metal. The metal mold was mounted horizontally. On one side, a vessel with superheated slag was supplied to it, and on the other, a vessel with liquid metal. First, slag portions were poured into the mold. Immediately upon filling with slag the entire first container of the mold

5 forms, metal portions were poured into the same container until the second tank was completely filled with slag, where it was poured over the edges of the first container, displaced by mztall. The metal is drained through a funnel at the drain hole of the metal container into which argon was supplied under pressure. After pouring the metal of the foundry, the mold was removed from the pouring place, another form was applied, and the process was repeated 5 rs. The whole process of filling slag and metal in the mold, calculated to produce castings of gear wheels weighing 4.6 kg, took 17-25 seconds, with a tank with a metal of 50 kg and a tank with

0 kg of slag 70 kg and conveyor feed of casting molds, obtaining 10 castings takes about 5 minutes When using the proposed method, productivity is no longer limited by the dosage problem

5 melt, as in electroslag chill casting, and in the process of extraction of castings and cleaning of casting molds, which in time (takes up to 1 min, to the mold used in this case, which ensures its design, therefore, with the appropriate organization of production, which consists in the use of several containers with metal and slag of a large volume, conveyor feeding of casting molds in the amount of 30-50 pcs, the productivity can be 450-500 high-quality billets per shift with an 8-hour working day (casting weight 4.6 kg), whichit fully satisfies the conditions of not only mass production, but also mass production and is unattainable with electroslag chill casting.

The mechanical properties of the metal castings obtained by the proposed method were determined on radial samples and are shown in the table in comparison with metal from billets of other production methods, including electroslag chill casting, open casting and TU requirements for forged metal. The samples were made from blanks with a square cross section with a side of a square of 15 mm. The billets were subjected to heat treatment according to the regime: 1 - quenching from 950 ° С, air 2 - quenching from 860 ° С, air, tempering at 200 ° С, air.

The above results indicate that the metal of castings obtained by the proposed method is not inferior in terms of mechanical properties to the deformed open-smelting metal, metal obtained by electroslag chill casting, and significantly exceeds in terms of such indicators as elongation, narrowing and impact strength, metal of open smelting, obtained by conventional casting without slag and with slag in a chill mold.

The use of the proposed method for the production of shaped castings and molds for the production of shaped castings has significant advantages compared with the known:

-allows to carry out conveyor casting, which greatly increases productivity, while maintaining high quality castings;

-allows the use of metal prepared in induction furnaces, which reduces the consumption of electrical energy;

- slag composition is greatly simplified;

-allows you to get the cavity in the castings of a cylindrical section, which reduces the allowance for machining;

-allows to obtain shaped end surfaces of the upper part of the casting;

- significantly simplifies the extraction of metal rods to form

internal cavities;

- provides a sufficiently accurate dosage of the amount of slag and metal to obtain castings of a given size, which also reduces machining allowances and increases the yield of casting.

At the same time, the method and the mold are quite simple, which allows it to be successfully implemented in any modern engineering, repair and foundry industries.

Claims (4)

1. A method of manufacturing shaped castings, including the accumulation of metal and slag in melting tanks and pouring them into molds, characterized in that in each mold consisting of two tanks communicating with each other, first the first tank is completely filled with superheated slag, then the metal is poured into it until the slag is completely filled second capacity. 2. A mold for the production of shaped castings, consisting of a container for metal and slag and a process rod, characterized in that the tank for metal and slag is made of two tanks communicating with each other, and the second tank is placed in the upper part of the first tank, and its volume is equal to the volume of the forming part of the first tank. 3. The mold according to claim 2, with the fact that the core is made in the form split in the axial direction of the sleeve with a cylindrical outer surface and a conical inner one in which the conical axis is mounted, while the cut surface of the sleeve forming one of its parts is made parallel to each other and the axial plane of the sleeve, and all other cut planes are made radial. 4. Foundry form according to paragraphs. 2 and 3, with the fact that the cylindrical the outer surface of the sleeve in the upper part is fitted with a gap with a technological insert, the working surface of which corresponds to the end surface of the casting. The average values of the mechanical properties of 18Kh2N4VA steel obtained by various methods Aa V / J FIG. 1 7 / FIG. 2