SU1765745A1 - Liquid iron sampling device - Google Patents

Abstract

The invention can be used in the chemical and metallurgical industries for sampling melts from tanks. The essence of the invention is to create conditions that reduce the amount of impurities and voids in the solidified sample of the melt, which improves the quality of the sample. For this purpose, a device containing a mold made of two halves with grooves for forming samples, a profitable extension and a metal line is provided with a U-shaped insert installed inside the mold with the formation of sample-forming chambers limited by grooves and vertical walls of U-shaped inserts. The cavity of the U-shaped insert in its upper part communicates with a profitable extension, and at the bottom - with the sample formation chambers. This solution ensures that impurities float to the profitable extension, to the mine of the sample formation chamber. The number of voids in the sample is reduced due to a quieter filling of the device. 1 hp f-ly, 3 ill. with s

Description

The invention relates to a sampling technique and may be used in metallurgy for sampling liquid iron.

A device for sampling a liquid metal containing a refractory cup with a hole in the side wall for flowing metal is known.

A disadvantage of this device is the impossibility of using it with a pneumatic probe to control a liquid metal due to the lateral supply of metal,

It is also known a device for sampling a liquid metal containing a metal pipe located on the axis of the device and a mold with a profitable cavity consisting of two halves (prototype).

A disadvantage of the known construction is that the first portion of a relatively cold and contaminated metal enters directly into the sample formation chamber. Its filling goes with great speed, which leads to the formation of shells in the sample, captivity, inclusions sang.

Pop-up contaminants first enter the sample-forming chamber, and only then into the profitable cavity. When the metal crystallizes, some of the pop-up contaminants remain in the sample.

The metal conduit outlet is located at the bottom of the sample formation chamber. As a consequence, when sampling, the device requires a long shutter speed in the submerged state until the sample is completely crystallized. With a short exposure time, the non-crystallized portion of the sample escapes.

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The poor quality of the sample due to the rapid filling, the presence of inclusions or the leakage of a part of the metal requires its remelting for x-ray or quantum-metrological analysis.

The purpose of the invention is to increase the reliability of the analysis due to the smooth filling and removal of inclusions, as well as simplifying the design and improving the usability.

These goals are achieved by the fact that in a known sampling device containing a mold made of two halves with cavities for forming samples, a profitable extension, metal lines and half the molds are cut out, and the device is equipped with a U-shaped insert installed inside of the mold in its cut-outs with the formation of sample-forming chambers limited by depressions and vertical walls of the U-shaped insert Samples, while the cavity of the U-shaped insert in its upper part communicates with the profitable extension through the hole in the horizontal wall of the insert, and in the lower part with the sample formation chambers. In addition, the bends are made in the form of grooves connecting the sample formation chambers with the cavity of the profitable extension,

Comparison of the device with other technical solutions shows that the presence of a U-shaped insert with a hole in the horizontal wall located in the cut-outs of the halves of the mold and forming the sample formation chamber makes it possible to obtain two identical samples at the same time; analysis. In addition, it reduces the amount of impurities in the sample due to their floating up into the profitable extension from the inside of the U-shaped insert, the mine of the sample formation chamber, the cutouts connecting the internal part of the U-shaped insert and the sample formation chamber that can be made in halves molds or in the insert itself, provide filling of the sample-forming chambers with iron from below, which helps to reduce the number of voids in the sample due to quieter filling. Heating the metal flowing into the mold, the vertical walls of the U-shaped insert, which are the inner edges of the sample formation chambers, causes the pores, shrinkage shell and inclusions to move to the inner edges.

samples, i.e. their removal from the analyzed surface.

This provides improved sample quality. The possibility of making the halves of the ingot mold symmetrical, and the bendings in the form of the above-mentioned grooves provide for simplifying the manufacture of the device, as well as removing the cast iron that has become stiff in the bend simplifies preparation for sampling.

FIG. Figure 1 shows a general view of a device for sampling liquid iron placed in a measuring pneumoson, longitudinal section; figure 2 - one half of the mold of the device; on fig.Z - U-obra-on insert.

The liquid iron sampling device consists of two symmetrical halves 1 of the mold, which can be made of metal, for example steel, with depressions 2 in which the U-shaped insert 3 is placed. In the horizontal wall 4 of the U-shaped insert there is an opening 5 connecting the inner part 6 of the insert with the profitable extension 7. The halves of the mold are made with recesses 9, which together with the side walls 9 of the U-shaped insert form the sample formation chambers 10. Inside the U-shaped insert is placed a metal pipe 11, which can be used as a tube made of quartz glass, the inner part 6 of the U-shaped insert 3 and the sample forming chamber 10 are connected by notches 12, which can be made as in mold halves (Fig. 2) , and in the insert itself (fig.Z). In the upper part of the sample formation chambers 10, there are discharges 13, made in the form of grooves connecting the sample formation chambers 10 with the plane of the mold and the profitable extension 7. A device for sampling liquid iron is placed inside the transport unit housing 14. Elastic cuffs 15. The metal conduit is fixed in a sleeve 16 made of cardboard with a pad 17 of soft material, for example, kaolin wool and waterglass. A cardboard sleeve with a metal pipe is fixed in the lower part of the transport unit case, for example, using a thread. A metal cap 18 with lateral holes 19, covered with paper tape 20, is fastened in the lower part of the cardboard sleeve.

The transport unit is located at the bottom of the measuring pneumosonde, which contains a water-cooled case 21 consisting of three concentric tubes, two of which are welded to the copper head.

22. Inside the housing there is a barrel 23 comprising an outer 24 and an inner pipe 25, and a seat 26, the openings 27 connecting the inside of the transport unit with a gap between the pipes 24 and 25, which communicate with the atmosphere. Compressed air and oxygen are supplied through the gap between the housing 21 and the barrel 23.

The central channel of the pneumo-probe formed by pipe 2B is connected to the compressed air pipeline.

The device works as follows.

Before sampling, the tube 25 of the pneumatic probe is connected to an airmail system by means of a docking device. A transport unit with a device for sampling through the pneumatic post system enters the pneumatic probe and abuts against the seat 26, while the protective sleeve 16 extends beyond the head 22 of the probe. The air probe is disconnected from the airmail. Its central channel formed by pipe 25 is closed with a valve and air is squeezed into the compressed air to keep the transport unit from floating up when immersed in metal. At the same time, compressed air is blown into the gap between the housing 21m and the central barrel 23, which prevents liquid iron from flowing into the slot between the protective sleeve 16 and head 22 probe.

The probe is immersed to a depth set by a commanding device included in the probe drive control circuit. The paper tape 20 is burned and the liquid iron through the holes 19 in the cap 18 enters the metal conduit. 11 The first iron ingress entering the cold metal conduit cools down most, resulting in poor metal ; the casting properties and the most polluted spell, through the hole 5 gets into the profitable extension 7. After the first batch of cast iron passes the metal pipeline heats up, and in the result of the metal level rise in As a result of this decrease in ferrostatic pressure, the movement of the metal is stabilized and its speed decreases. As a result, the further filling of the mold occurs more smoothly. The hotter and pure metal enters the inner part of the mold. From it the metal passes through notches 12 into the sample formation chamber 10. The bottom metal supply to the sample formation chamber and smooth filling helps to improve the quality of the sample. The speed of the metal in the inner part of the U-shaped insert is directed downwards and less than in the megalopipeline due to the relatively large flow area. This helps to improve the buildup of contaminants that are removed in a profitable way to the extension, mine the volume of the sample. the metal heats up its vertical walls; therefore, during the crystallization of cast iron, gas and non-metallic inclusions,

0 trapped in the sample formation chamber, are displaced to this wall. Since the opposite surface of the sample is analyzed, it also improves its quality. The air from the sample formation chamber is displaced by the eta5 with the liquid metal through the strut 13 and, further, through the plane of contact between the profitable extension and the halves of the form in the tube between the pipes 24 and 25, which are connected to the atmosphere.

0 cuts a mold rug prevents the iron from flowing into the gap between the mold and the transport block. The exit position of the metal pipe above the shaped sample chambers allows you to extract

5 a device made of metal before it is completely crystallized without the danger of sample leakage.

In the liquid iron, required to fill the mold, the air pressure point is lifted by means of an actuator.

Pnvvmoeond dock with pneumatic post and remove the transport unit from the non-ID box from i / i well, they are disassembled. External samples are ground and subjected to

5 rschechovski or quantometric.

VeSpowef is prepared for re-Shch $ f§1 boog00. For this purpose, if SchSch1b Disconnect iron scrap, deposits 0 v & gt into tfoprtyfi of the transport block, both halves are cleaned, placed between them or used or U-shaped insert and fixed the metal sleeve of the case in the bottom part of the body

5 house On the mold set profitable extension and close the case of the sampling unit with a lid with cuffs,

Metal mold application

0 provides rapid cooling and crystallization of the sample, which makes it possible to obtain the structure of white cast iron, as well as to use the mold and the proslite extension many times. Signs that provide

5, the quiet filling of the metal-forming sample forming chamber, allows to obtain a satisfactory quality of the analyzed surface. The result is a suitable for X-ray or metric analysis that does not require

Claims (2)

remelting. Obtaining two samples at the same time increases the reliability of the analysis. Formula 1: A device for sampling liquid iron for X-ray and quantum-metrological analysis, comprising a mold made of two halves with recesses for forming samples, a profitable extension, a metal conductor, and a vent, characterized in In order to increase the reliability of the analysis, half of the mold is cut-out, and the device is equipped with a U-shaped insert installed inside the mold in its cut-outs with the formation of formation chambers Rob, 0 five limited by depressions and vertical walls of the U-shaped insert, the outlet of the metal conduit is placed in the cavity of the insert above the upper level of the sample formation chambers, while the cavity of the U-shaped insert in its upper part is connected to the profitable extension through an opening in the horizontal wall of the insert bottom - with cameras forming samples. 2. Device pop. 1, characterized in that, in order to simplify the design and increase the convenience of operation, the bumps are made in the form of grooves connecting the sample formation chambers with the cavity of the profitable extension. ri .2. FIG. 3