RU2557437C1 - Cooling plate of blast furnace - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: cooling plate includes a cooled plate provided with longitudinal through channels and transverse non-through channels connected to them for circulation of cooling medium, which form cooling circuits, and holes with outlets for supply and removal of cooling medium. The cooled plate is provided with additional longitudinal non-through channels that are made on one axis and connected with transverse non-through channels to longitudinal through channels. Holes for supply and removal of cooling medium are made in end parts of additional longitudinal non-through channels with their being located in the central part of the cooled plate.

EFFECT: improving reliability, resistance, durability of operation and reducing manufacturing costs of a cooling plate of a blast furnace.

6 cl, 2 dwg

Description

The invention relates to devices for cooling blast furnaces and can be used in metallurgy in cooling systems during the construction of new, repairs and reconstructions of existing blast furnaces.

The closest in combination of features to the claimed object is a plate refrigerator selected as a prototype, containing a cooled plate with longitudinal through and connected through them transverse through channels for cooling medium circulation, which with the help of plugs form cooling circuits, and openings with conclusions for supply and removal of the cooling medium. In this case, the holes for supplying and discharging the cooling medium with leads are located in the lower and upper parts of the cooled plate (EP No. 1466989, Figs. 3, 4, 5, IPC C21B 7/10, publ. 13.10.04).

The claimed object and prototype coincide with such essential features. Both plate coolers contain a chilled plate with longitudinal through and connected through them transverse through channels for cooling medium circulation, which with the help of plugs form cooling circuits, and openings with leads for supplying and discharging the cooling medium.

Analysis of the technical properties of the prototype, due to its features, shows that the receipt of the expected technical result when using the prototype is impeded by such reasons. The location of the leads for supplying a cooling medium in the lower part of the plate, and the terminals for draining the cooling medium in the upper part of the plate does not allow reducing the thermal stresses arising in the locations of the terminals during linear expansion of the cooled plate when it is heated. Thermal stresses at the locations of the terminals are proportional to the distance between the terminals for supplying and discharging the cooling medium, in particular, when the terminals are located in its upper and lower parts, thermal stresses will lead to the formation of gaps in the body of the plate at the locations of the terminals and subsequent destruction of the plate refrigerator generally. Moreover, the use of expansion joints for linear expansion of the stove to reduce thermal stresses is characterized by an increase in the cost of the stove refrigerator, as well as the complexity of its manufacture and installation in a blast furnace. In addition, the use of the prototype requires making at least two holes in the casing of the blast furnace: one for the conclusions for supplying a cooling medium and the second for conclusions for removing the cooling medium, which, in turn, reduces the stiffness and gas tightness of the casing of the blast furnace .

The basis of the claimed object is the task of creating such a stove refrigerator of a blast furnace, in which improvements by introducing new elements and a new arrangement of elements will make it possible to use the inventive object to achieve a technical result consisting in improving the reliability, durability, durability and reducing the cost of manufacturing a stove refrigerator blast furnace.

The problem is solved due to the fact that in a plate refrigerator containing a cooled plate with longitudinal through and connected through them transverse through channels connected to them for circulation of the cooling medium, which with the help of plugs form cooling circuits, and openings with leads for supplying and discharging the cooling medium, according to the claimed technical solution, the cooled plate is equipped with additional longitudinal non-through channels, which are made on the same axis and are connected by transverse many channels with longitudinal through channels and holes for supplying and discharging the cooling medium formed in longitudinal end portions of the additional non-through channels with their location in the central part of the cooled plate.

In individual cases of execution, the claimed object may be characterized in that:

- longitudinal through, additional longitudinal non-through and transverse non-through channels for the circulation of the cooling medium in the cross section are oval;

- the working surface of the cooled plate is ribbed;

- the working surface of the chilled plate is equipped with refractory material;

- the cooled plate is made of steel;

- the cooled plate is made of copper or its alloys.

When using the inventive facility, the achievement of a technical result is achieved, which consists in increasing the reliability, durability, durability and reducing the cost of manufacturing a stove refrigerator of a blast furnace. In addition, when using the inventive object, it is possible to achieve an additional technical result, which consists in reducing the level of thermal stresses at the locations of the leads for supplying and discharging a cooling medium while reducing the number of holes in the casing of the blast furnace and in increasing its rigidity and gas density, as well as in increasing the efficiency blast furnace cooling.

The equipment of the cooled plate with additional longitudinal non-through channels so that they are made on opposite sides of the plate on the same axis, are parallel to the longitudinal through channels and placed on the inner side of them, are connected to the longitudinal through channels with transverse non-through channels near the upper lower and the lower lower side of the plate, and also that their final deaf parts are located in the central part of the cooled plate with a vertical distance between they are equipped with openings for supplying and discharging a cooling medium with leads, it is possible to concentrate the leads in the central part of the plate, to reduce the vertical distance between the leads to at least 0.15-0.3 m, which, in turn, allows to reduce thermal stresses at the locations of the terminals during expansion of the plate as a result of its heating during cooling of the blast furnace. Such equipment allows the cooled plate to expand freely in all directions, ensuring minimal stress in the terminal area, which prevents the formation of gaps in the terminal area and the destruction of the cooled plate as a whole, and also does not use linear expansion joints for the claimed object and reduce the cost of its manufacture. All this provides increased reliability, durability and durability of the stove refrigerator of the blast furnace. Also, the use of the claimed object allows to reduce to one the number of holes in the casing of the blast furnace for four conclusions for supplying and discharging the cooling medium and to increase the cooling efficiency of the blast furnace as a whole.

The implementation of longitudinal through, additional longitudinal non-through and transverse non-through channels for the circulation of the cooling medium in an oval cross-section provides increased efficiency and uniformity of cooling of the plate by increasing the ratio of the volume of the circulating cooling medium to the volume of the metal of the cooled plate, and also increases the heat transfer intensity at the surface channel - cooling medium ", which generally reduces the voltage in the area of the location of the conclusions and increase the reliability Resistance, and durability of the refrigerator of plate blast furnace as a whole.

The implementation of the working surface of the cooled plate ribbed allows you to increase the heat-absorbing area of the working surface (compared with a smooth surface, for example, one and a half times) with the simultaneous implementation of effective and uniform removal of heat by the cooling medium through the channels made in the plate. In addition, by increasing the cooling efficiency, a more reliable retention of the skull on the ribbed working surface is ensured, which reduces the destructive effect of thermal loads on the stove as a whole, helping to increase the reliability, durability and durability of the stove refrigerator of the blast furnace. The ribbed surface contributes to the reliable fixation of refractory materials on the cooled plate.

The equipment of the working surface of the cooled plate with refractory material helps prevent the damaging effect of thermal loads and the abrasive effect of the products of the technological process in the blast furnace on the working surface of the plate. Refractory material provides a reduction in thermal loads on the cooled plate. All this contributes to increasing the reliability, durability and durability of the stove refrigerator of the blast furnace, as well as improving the cooling efficiency of the blast furnace as a whole.

The manufacture of a cooled plate from steel, or copper, or from copper alloys can simplify the process of making channels in it, for example by drilling.

The use of a cooled steel plate is most appropriate for stove refrigerators, which are installed in the shoulders, steam and in the upper part of the shaft of the blast furnace, since in these zones there are variable heat loads of 10-50 kW / m, the perception of which in the stove from steel the lowest thermal stresses are observed.

The implementation of the cooled plate of copper or its alloys provides an increase in the operational characteristics of the plate, as well as effective and uniform cooling in the most difficult temperature, technological and operational zones of the blast furnace. Cooled plates made of copper or its alloys, it is most appropriate to install in the middle and lower parts of the mine blast furnace, where there are the greatest cyclic thermal loads up to 350 kW / m ² . This is due to the fact that the cooled plates made of copper or its alloys have a high thermal conductivity of 350-390 W / m · K, are able to work in cyclically varying temperature conditions and remove heat loads up to 350 kW / m ² . In addition, the implementation of the cooled plate of copper or its alloys by providing better conditions for cooling contributes to the formation of a thick layer of the skull, as well as its reliable retention on the working surface of the plate.

The essence of the claimed object is illustrated by drawings, which depict:

- figure 1 is a diagram of the inventive stove fridge blast furnace;

- figure 2 is a section along A-A in figure 1.

The following notation is affixed to the drawings:

1 - cooled plate;

2 - longitudinal through channel;

3 - longitudinal through channel;

4 - additional longitudinal non-through channel;

5 - additional longitudinal non-through channel;

6 - additional longitudinal non-through channel;

7 - additional longitudinal non-through channel;

8 - transverse non-through channel;

9 - transverse non-through channel;

10 - transverse non-through channel;

11 - transverse non-through channel;

12 - holes for supplying a cooling medium;

13 - conclusions for supplying a cooling medium;

14 - holes for the removal of the cooling medium;

15 - conclusions for the removal of the cooling medium;

16 - stubs;

17 - the working surface of the cooled plate.

In a specific embodiment, the inventive stovetop refrigerator of the blast furnace contains a cooled plate 1, in which, for example, by drilling, longitudinal through channels 2 and 3, additional longitudinal through channels 4, 5, 6 and 7, transverse through channels 8, 9, 10 and 11, openings 12 with outlets 13 equipped therein for supplying a cooling medium and openings 14 with outlets 15 equipped therein for discharging a cooling medium. In addition, the plate 1 is equipped with plugs 16 for channels. All channels 2-11 are made in one plane in the body of the plate 1, while channel 2, channels 4 and 5, channels 6 and 7 and channel 3 are made parallel and are located at a given distance between each other.

The longitudinal through channels 2 and 3 are made near the opposite large sides of the plate 1. The additional longitudinal non-through channels 4 and 5 are made on the opposite smaller sides of the plate 1 on the same axis and are located on the inner side of the channel 2. The additional longitudinal non-through channels 6 and 7 are made from the opposite the smaller sides of the plate 1 on the same axis and are located on the inner side of the channel 3. In this case, the final blind parts of the channels 4 and 5, as well as channels 6 and 7 are located in the central part of the plate 1 with a given vertical distance Ali among themselves. In addition, in the plate 1 there are two holes 12 for supplying a cooling medium, which are connected to the end blind parts of the channels 5 and 7 and each of which is equipped with a terminal 13 for supplying a cooling medium, and two holes 14 for withdrawing a cooling medium, which are connected to the final deaf parts of channels 4 and 6 and each of which is equipped with a terminal 15 for the removal of the cooling medium.

Transverse non-through channels 8 and 9 are made from opposite large sides of the plate 1 on one axis and are located near one smaller (upper) side of the plate 1. Transverse non-through channels 10 and 11 are made from opposite large sides of the plate 1 on one axis and are located near the other smaller ( bottom) of the plate 1. In this case, channel 8 connects channels 2 and 4, channel 9 - channels 3 and 6, channel 10 - channels 2 and 5, and channel 11 - channels 3 and 7.

The plugs 16 are installed so that the through 2, additional longitudinal through-through 4 and 5 and transverse through-through 8 and 10 channels form one cooling circuit, and through 3, the additional longitudinal through-through 6 and 7 and transverse non-through 9 and 11 channels form a different cooling circuit. The working surface 17 of the stove 1 is directed into the interior of the blast furnace (not shown in the drawings).

In a specific embodiment, the stove refrigerator of the blast furnace operates as follows.

The cooling medium enters through two central terminals 13 for supplying the cooling medium through two openings 12 to the cooling plate 1. Industrial or chemically purified water can be used as the cooling medium for the stove cooler of the blast furnace. Moving along two cooling circuits, one of which is formed by channels for circulation 5, 10, 2, 8, and 4, and the other by channels 7, 11, 3, 9, and 6, the cooling medium removes heat from the body of the plate 1, heats up and is removed through two central leads 15. The central location of the holes 12 and 14 with leads 13 and 15, respectively, ensures that the plate 1 expands freely when it is heated, reducing the level of thermal stresses at the locations of leads 13 and 15, which, in turn, improves reliability, durability and longevity of work pl tovogo refrigerator blast furnace. This makes it possible to use a plate refrigerator for a blast furnace without the use of linear expansion joints, and the cost of a plate refrigerator is also reduced. In addition, the grouping of two pairs of terminals 13 and 15 in one central part of the stove refrigerator allows one to reduce the number of holes in the casing of the blast furnace, providing an increase in its rigidity and gas density.

Claims (6)

1. Plate refrigerator of a blast furnace containing a cooled plate with longitudinal through and connected through them transverse through channels connected to them for circulating the cooling medium, which with the help of plugs form cooling circuits, and openings with leads for supplying and discharging the cooling medium, characterized in that the cooled plate is equipped with additional longitudinal non-through channels, which are made on the same axis and are connected by transverse non-through channels with longitudinal through channels, and The inlet and outlet of the cooling medium are made in the end parts of additional longitudinal non-through channels and are located in the central part of the cooled plate. 2. Plate refrigerator according to claim 1, characterized in that the channels for the circulation of the cooling medium in the cross section are oval in shape. 3. Plate refrigerator according to claim 1, characterized in that the working surface of the cooled plate is ribbed. 4. Plate refrigerator according to one of claims 1 to 3, characterized in that the working surface of the cooled plate is equipped with refractory material. 5. Plate refrigerator according to one of claims 1 to 3, characterized in that the cooled plate is made of steel. 6. Plate refrigerator according to one of claims 1 to 3, characterized in that the cooled plate is made of copper or its alloys.

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