RU2563069C1 - Blast furnace tuyere unit - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention relates to metallurgy, in particular to a blast furnace tuyere unit. The tuyere unit contains a blasting pipe attached to a blast furnace casing, a tuyere, attached to the blasting pipe end and a flexible connector connecting the blasting pipe with a tuyere sleeve. Inside the furnace casing a plate tuyere refrigerator arranged around the tuyere for the formation of the internal surface of the blast furnace is installed. Around the tuyere in the blast furnace casing a hole for the tuyere is formed which is connected along the whole periphery with a flange formed along the periphery of the blasting pipe.

EFFECT: invention prevents the leakage of the blown gas and keeping of a certain position of the tuyere in the furnace casing.

3 cl, 3 dwg

Description

Field of Invention

The invention relates to the construction of a tuyere block of a blast furnace. More specifically, the invention is applicable as a tuyere section of a blast furnace containing plate coolers located around the tuyere block.

State of the art

A plurality of blasting tuyeres are typically located in a blast furnace body at a predetermined height. These tuyeres, respectively, are connected to blasting (blowing) pipes extending from the air distribution ring passing around the furnace body. Hot blast is supplied from the blast pipes and blown through the tuyeres into the furnace (see Patent Document 1).

In a typical tuyere section of a blast furnace, as shown in FIG. 3, a lance 8 configured to supply high temperature air to the furnace is held by the lance refrigerator 9. The lance refrigerator 9, in turn, is held by the lance holder 10. The lance holder 10 is attached to the casing 11 of the furnace along the periphery of the blast furnace.

Lance bricks 5 are arranged around the lance refrigerator 9. Lance bricks 5 are formed by combining a plurality of bricks so that they surround the lance refrigerator 9. On the bottom (bottom) of the hearth of the blast furnace, bricks of bottom are laid. The hearth wall in its upper part is lined with refractory wall bricks 7. Lance bricks 5 are installed on the upper side of the wall bricks 7 of the hearth. Further, on the upper side of the 5 lance bricks, refractory bricks are installed for laying the shoulders of the blast furnace.

Between the bricks 6 of the shoulder and the casing 11 of the furnace and between the wall bricks 7 of the hearth and the casing 11 of the furnace, a plate refrigerator 1 is located. A plate refrigerator 1a for the tuyere is located between the tuyere bricks 5 and the casing 11 of the furnace.

In plate refrigerators 1 and 1a, a plurality of pipes for cooling water pass. Cooling water is supplied through conduit 15 for such cooling water. The plate coolers 1 and 1a are cooled by water flowing through the pipes for cooling water, due to which the heat coming from the inside of the furnace is captured to protect the casing 11 of the furnace.

The lance 8 and the lance refrigerator 9, surrounded by lance bricks 5, are attached to the casing 11 of the furnace by the lance holder 10. Since the casing 11 of the furnace is maintained at a low temperature by cooling with stovetop refrigerators, the thermal expansion of the casing 11 of the furnace is small, so the position of the lance 8 remains almost constant. On the other hand, bream bricks and hearth bricks 7 are heated to a high temperature to hold molten iron and slag in the furnace, which leads to their thermal expansion. Due to this thermal expansion, the tuyere bricks 5 mounted on the upper side of the hearth wall bricks 7 are squeezed up. In such a tuyere block, the tuyere 8 and the tuyere refrigerator 9 perceive an upward deforming load through the tuyere bricks 5.

Therefore, between the lower part of the lance refrigerator 9 and the lance bricks 5 there is a compressible layer 12 of masonry mortar. When the tuyere bricks 5 are compressed upward by the thermal expansion of the hearth wall bricks 7, the compressible layer 12 of the masonry mortar is compressed, preventing unnecessary load on the tuyere refrigerator 9 from the pressing tuyere bricks 5.

The blast pipe 17 is inserted into the casing 11 of the blast furnace from the outside and enters the lance holder 10, the lance refrigerator 9 and the lance 8. The blast pipe 17 is connected to the air distribution ring passing around the blast furnace casing, the lance sleeve 18. From the air distribution ring through the lance sleeve 18 and the blast tube 17 is fed hot blast for blowing through the lance into the working space of the furnace.

The blast tube 17 and the tuyere sleeve 18 are supported by a tower supporting structure (not shown) mounted around the furnace body in connection with an air distribution ring. The end of the blast tube 17 is formed as a convex spherical surface, and the inner connecting part of the lance 8 facing the blast tube is made as a concave spherical surface, thereby forming a spherical hinge. The connection between the lance 8 and the blast tube 17, having the shape of a spherical hinge, allows mutual movement of the lance 8 and the blast tube 17 while maintaining the airtightness of the joint between them.

In the above block shown in FIG. 3, the lance 8 is held by the furnace body, namely, the furnace casing 11 using the lance refrigerator 9 and the lance holder 10, since for the proper operation of the blast furnace it is necessary to maintain a predetermined position of the end of the lance 8 (i.e., the position of the injection of hot blasting) inside the working space ovens.

Since the blast tube 17 and the air distribution ring are supported independently of the furnace body containing the lance 8, the blast tube 17 and the lance 8 are connected by a hinge to spherical surfaces. This is due to the fact that the blast furnace body is heated to high temperatures and subjected to thermal deformation, while the blast tube 17 is supported by the tower supporting structure through the air distribution ring and is less susceptible to thermal deformation, which leads to different behavior during thermal deformation.

Refractory bricks 5, 6 and 7 are placed on the inside of the stove refrigerators 1 and 1a to block heat shock during inflation and to prevent damage by molten blast furnace iron and slag in the furnace. Since the tuyere section extends through the thickness of the lance brick 5 and the plate cooler 1a, the distance from the casing 11 of the furnace to the lance 8 increases, and the blast tube 17 lengthens accordingly.

List of links

Patent Literature

Patent Document 1: JP-A-2002-220609

Disclosure of invention

Problems Solved by the Invention

When a hinge with spherical surfaces is used to connect between the blast tube 17 and the lance 8, as described above, the end of the blast tube 17 is inserted from the outside of the furnace casing 11 into the lance 8, resulting in joints in the form of a hinge with spherical surfaces. In the joint with spherical surfaces, mutual displacement of the blast tube 17 and lance 8 is allowed while maintaining air tightness.

However, a hinge with spherical surfaces requires very precise machining to form a spherical surface capable of being airtight, since airtightness is ensured by the contact of metal spherical surfaces passing around the air hole, which leads to an increase in production costs. In addition, even with such contacting metal surfaces, gas leaks occur when high pressure is applied.

In particular, since the distance from the casing 11 of the furnace to the lance 8 is large, and the blast tube as a result becomes longer, this blast tube 17 is maintained in a cantilever state. Accordingly, the position of the end of the blast pipe 17 can easily change, which can cause difficulties in maintaining the air tightness of the hinge with spherical surfaces on the lance 8.

Further, the lance 8 is located on the inner surface of the furnace and is supported by the lance refrigerator 9. In a typical tuyere structure 8, the tuyere cooler 9 or the tuyere holder 10 is machined to adjust so that all tuyeres located around the circumference of the furnace are equally facing the center of the furnace.

However, the lance 8 and the lance refrigerator 9, which supports the lance 8, are surrounded by bricks 5 for protection and are remote from the stove refrigerators 1 and 1a. Such a design can lead to thermal deformation of the lance refrigerator 9. Accordingly, the position of the lance 8 on the inner surface of the furnace or its orientation may change as a result of thermal deformation.

When the position of the lance 8 on the inner surface of the furnace changes, the uniformity of the circumferential direction of the circulation zone inside the furnace, which is very important for the operation of the blast furnace, is violated so that stable operation (i.e., reduction and lowering reactions of materials) cannot be achieved.

The aim of the present invention is to provide a tuyere block of a blast furnace capable of preventing gas leakage and preserving a predetermined position of the end of the tuyere in the working space of the furnace, while compensating for the difference in thermal deformation between the furnace body and the air distribution ring.

Means of solving the problem

The blast furnace tuyere block according to one aspect of the present invention comprises: a blast tube attached to the furnace shell, a tuyere attached to the end of the blast tube, and a flexible connector that connects the blast tube to the tuyere sleeve.

With this design, since the lance is attached to the end of the blast pipe, the contact metal connection between the lance and the blast pipe can be eliminated. Accordingly, it is possible to get rid of the processing of the spherical surfaces necessary for the metal connection, which reduces costs. Moreover, gas leakage arising from the metal contact joint can be prevented.

In addition, since the blast tube is attached to the furnace shell, it is possible to maintain a predetermined position of the lance attached to the end of the blast pipe relative to the furnace shell, in other words, the position of the end of the lance in the working zone of the furnace.

Additionally, since a flexible connector is installed between the blast tube and the tuyere sleeve, this flexible connector can compensate for the difference in thermal deformation between the furnace body and the air distribution ring.

With this design, it is possible to prevent gas leakage and maintain a predetermined position of the tuyere in the working zone of the furnace, while the difference in thermal deformation between the furnace body and the air distribution ring is compensated.

According to the above-described aspect of the present invention, it is preferable that the plate refrigerator is installed inside the furnace casing around the lance and forms the inner surface of the blast furnace.

When the distance between the tuyere and the furnace casing to which the blast tube is attached is large, the blast tube can be cantilevered and change the position of the end of the tuyere. Conversely, according to the above-described aspect of the invention, since conventional tuyere lance bricks are excluded and the stove refrigerator directly acts as the inside surface of the furnace, the length of the blast tube can be minimized and thereby prevent the lance from shifting.

According to the above-described aspect of the present invention, preferably a lance hole is formed on the furnace casing around the lance and connected to the entire periphery of the flange formed on the periphery of the blast pipe.

When this flange is attached to the lance hole, it is advisable to use bolts located on the flange at a predetermined interval for ease of attachment and detachment for repair.

Brief Description of the Drawings

FIG. 1 is a sectional view of an illustrative embodiment of the invention.

FIG. 2 is a sectional view of another illustrative embodiment of the invention.

FIG. 3 is a section of a known example.

Description of options

The following is a description of an illustrative embodiment of the invention with reference to the attached drawings.

As shown in FIG. 1, the tuyere block 20 (The design of the tuyere section) in an illustrative embodiment comprises: a blow pipe 31 attached to the casing 21 of the furnace; a lance 32 attached to the end of the blast tube 31, and a flexible connector 34 that connects the blast tube 31 to the tuyere sleeve 33.

Since the hot high-pressure blast supplied to the blast furnace passes through the interior of the flexible connector 34, a metal bellows is used as the flexible connector 34.

The flange to which the lance is attached is formed at the end of the blow pipe 31. The lance 32 is attached to the flange with bolts or the like.

The blast tube 31 has a flange at the opposite end with respect to the lance 32. A flexible connector 34 is connected to this flange. The flexible connector 34 has a flange at the opposite end with respect to the blast pipe. A tuyere sleeve 33 is connected to this flange. The opposite end of the tuyere sleeve relative to the flexible connector 34 is connected to an air distribution ring (not shown).

The blast tube 31 and lance 32 are supported by a furnace casing 21. The tuyere sleeve 33 and flexible connector 34 are supported by an air distribution ring (not shown). When supplying hot blast from the air distribution ring, this hot blast can be fed through the tuyere sleeve 33, the flexible connector 34 and the blast tube 31 into the tuyere 32 and blown through the tuyere 32.

It should be noted that the direction and position of the lance 32 relative to the blast tube 31 is adjusted so that the direction and position of the lance 32 are already set appropriately when the lance 32 is installed in the furnace.

A lance hole 211 is formed in the casing 21 of the blast furnace. A flange 311 is formed at the periphery of the blow pipe 31.

The end (located near the tuyere 32) of the blow pipe 31 is inserted from the tuyere hole 211 inside the furnace (left in the drawing) so that the flange 311 covers the tuyere hole 211.

The flange 311 is attached to the periphery of the hole 211 under the lance with bolts at predetermined intervals, which allows an airtight connection.

Due to the connection between the flange 311 and the periphery of the lance hole 211, the blow pipe 31 is attached to the furnace casing 21.

Inside the casing 21 of the furnace are a stovetop refrigerator 22 horns, a stovetop refrigerator 23 lances and a stovetop refrigerator 24 shoulders.

The lamella fridge 23 has a cutout 231 through which a lance is inserted. The blast tube 31 and the tuyere 32 are inserted into the furnace casing 21 through the tuyere hole 211 and pass through the cutout 231 so that they are surrounded by a tuyere refrigerator 23.

Inside the hearth, a stovetop refrigerator 22 is lined with refractory wall bricks 25.

Refractory blocks (for example, lance bricks 5 in Fig. 3) are not used on the inner surface of the plate cooler 23 of the lance and the plate refrigerator 24 of the shoulders. Instead, refractory bricks 232 and 242, respectively, are installed on the surface of the interior of the furnace (on the internal surfaces of the furnace) on the stove refrigerator 23 lances and on the stove refrigerator 24 shoulders.

Due to the use of the lance fridge-freezer 23 in this illustrative embodiment, the thickness T1 from the furnace casing 21 to the inner surface of the furnace is smaller than the thickness T2 (shown by the dotted line in the drawing) from the furnace casing 11 to the inner surface of the furnace in known blast furnaces.

When the thickness T1 from the casing 21 of the furnace to the inner surface of the furnace is reduced, the length of the arm (i.e., the length of the blast tube 31 and the lance 32 extending through the thickness T1 and supported cantilever) can be reduced. Accordingly, the position shift of the lance 32 on the inner surface of the furnace can be reduced, which is important for stable operation.

Moreover, by replacing the refractory blocks installed inside the furnace (i.e., lance bricks 5 in FIG. 3) with a lance refrigerator 23, it is possible to prevent the lance from being pushed up due to thermal deformation of the refractory bricks.

In this illustrative embodiment, the surface of the lance fridge-freezer 23 forms the inside surface of the furnace, which is defined according to a profile suitable for the blast furnace. Accordingly, the surface of the plate refrigerator 23 (i.e., the inner surface of the furnace) remains at the same level as the surface of the tuyere bricks 5, as shown in FIG. 3. In this illustrative embodiment, the thickness of the tuyere section is reduced due to the location of the furnace casing 21 near with the inner surface of the furnace compared to the casing 11 of the known furnace (i.e., reducing the diameter of the tuyere section of the blast furnace body).

Between the casing 21 of the furnace and stationary refrigerators (i.e., a stove horn refrigerator 22, a lance stove refrigerator 23 and a shoulder refrigerator 24), a refractory filler 29 (for example, a refractory mortar) is laid.

A seal plate 291 is installed inside the cutout 231 through which the lance 21 is inserted, and a hole 291 is installed in the holes 211 under the lance. The seal plate 291 blocks the refractory filler 29 embedded inside the furnace casing 21 so that the space defined by the cutout 231, the lance hole 211 and the blast pipe 31 was not filled with filler and remained hollow.

On the other hand, between the cutout 231 and the tuyere 32, an elastic refractory material, such as mineral wool, is laid.

The assembly process of an illustrative embodiment is performed in the following order.

First, a furnace casing 21 is constructed to determine the external shape of the blast furnace body. Then, a stove horn refrigerator 22 and hearth wall bricks 25 are installed inside the furnace casing 21. After that, on the upper side of the stove refrigerator of the hearth 22 and the wall brick 25 of the hearth, a stove refrigerator 23 lances and a stove refrigerator 24 shoulders are installed.

Now, refractory material 292 is laid inside the cutout 231 of the plate refrigerator 23, and a sealing plate 291 is installed inside the cutout 231 and the holes 211 under the lance.

Further, outside the furnace, a tuyere sleeve 33, a flexible connector 34, a blow pipe 31 and a tuyere 32 are assembled together. The assembled tuyere sleeve 33 and a tuyere 32 are placed in front of the tuyere hole 211, the tuyere 32 and the blow tube 31 are inserted into the furnace.

After that, a refractory material 292 is placed between the cutout 231 and the tuyere 32. The tuyere 32 and the blow pipe 31 are placed in the cutout 231 through which the tuyere was inserted into the tuyere refrigerator 23. At this time, the lance 32 protrudes from the plate cooler 23 of the lance into the interior of the furnace.

In this state, the flange 311 of the blast tube 21 is attached to the periphery of the lance hole 211.

Upon completion of the above process, a refractory filler 29 is placed inside the furnace casing 21.

The installation of the tuyere block at this end.

Since the refractory filler 29, embedded inside the furnace casing 21, is blocked by the sealing plate 291 from getting into the notch 231 and the hole 211 under the lance, the space surrounding the blast tube 31 remains unfilled with the refractory filler 29.

Leaving this space free, if the lance is damaged during operation, it becomes possible to easily replace the lance 32 by disconnecting the flexible connector 34 after stopping the supply of hot air, and pulling out the blow pipe 31 and lance 32 from the casing 21 of the furnace.

As the sealing plate 291, a metal plate and an elastomer (e.g., refractory rubber) can be used.

In this illustrative embodiment, the following advantages are achieved.

Since the lance 32 is fixed to the end of the blast tube 31, the commonly used contact metal connection between the lance 32 and the blast tube 31 can be eliminated. Accordingly, it is possible to dispense with the treatment of spherical surfaces for a contact metal joint in order to reduce production costs. Moreover, gas leakage occurring in the contact metal joint can be prevented.

Moreover, since the blast tube 31 is attached to the casing 21 of the furnace, it is possible to maintain a predetermined position of the lance 32 attached to the end of the blast pipe 31 relative to the casing of the furnace 21, in other words, the position of the end of the lance 32 in the working area of the furnace.

Additionally, since the flexible connector 34 is located between the blast tube 31 and the tuyere sleeve 33, this flexible connector can compensate for the difference in thermal deformation between the furnace body and the air distribution ring.

With this design, it is possible to prevent gas leakage and to maintain a predetermined position of the end of the lance 32 and at the same time compensate for the difference in thermal deformation between the furnace body and the air distribution ring.

Since a lance refrigerator 23 is installed around the tuyere 32 inside the furnace casing 21, which defines the internal surface of the furnace, the necessary lance bricks can usually be eliminated, which reduces the thickness of the furnace body by the thickness of the tuyere bricks, therefore, the distance between the furnace casing 21 to which the blast tube is attached 31, and lance 32 can be reduced.

When the distance between the tuyere 32 and the casing 21 of the furnace to which the blast tube 31 is attached is large, the blast tube 31 mounted cantilever can lead to a displacement of the position of the tuyere 32. On the contrary, in the present illustrative embodiment, since lance bricks are usually necessary (see FIG. 3) are excluded, and the lance cooler 23 serves directly as the inside surface of the furnace, the length of the blast tube 31 can be minimized and the position of the lance 32 can be prevented from shifting.

Since the lance hole 211 is formed in the casing 21 around the lance 32 and the entire periphery of the flange 311 formed on the periphery of the blow pipe 31 is connected to the lance hole 211, the blow pipe 31 can be fixed to the furnace cover 21 in a predetermined orientation and to prevent gas leakage from holes 211 under the lance.

The connection between the flange 311 and the lance hole 211 makes it easy to connect and disconnect for repair, since the bolts located on the flange 311 at a predetermined interval are used.

The present invention is not limited to the above option, but includes other variations and modifications and the like, without departing from the scope of the invention.

For example, although the blast tube 31 and lance 32 are located substantially orthogonal to the casing 21 of the furnace, in practice, the lance 32 is often tilted down to the furnace. Accordingly, the lance 32 can be attached to the blow pipe 31 at an angle, or the blow pipe 31 can be attached to the casing 21 at an angle.

For example, in another illustrative embodiment shown in FIG. 2, the end of the blow pipe 31 is bent towards the hearth, and the lance 32 connected to this end is inclined towards the hearth. To install an inclined lance 32, a cutout 231 made in the lamella refrigerator 23 is also formed inclined. It should be noted that the remaining structural elements in the illustrative embodiment shown in FIG. 2 remain the same as in the embodiment of FIG. one.

To use the surfaces of the plate cooler 23 of the tuyeres and the plate cooler 24 of the shoulders as the internal surfaces of the furnace, refractory bricks 232 and 242, respectively, are installed on the stove cooler 23 of the tuyere and the stove cooler 24 of the shoulder, respectively, to protect their surfaces. However, the location of the refractory bricks 232 and 242 is not limited to such an alternating structure, but they can be arranged continuously relative to each other. Alternatively, refractory bricks 232 and 242 may not be used when the surfaces of the stove refrigerators 23 and 24 can be adequately protected by a protective layer formed by a coating of refractory material and the like applied to the surfaces of the stove refrigerators 23 and 24.

It should be understood that the specific shape, material, dimensions, etc. in illustrative embodiments, when implementing the invention, can be changed as necessary.

The list of items in the drawings

20 - tuyere block

21 - furnace cover

211 - hole for the lance

22 - stove horn refrigerator

23 - lance plate refrigerator

231 - cutout

232 - refractory brick

24 - plate refrigerator shoulders

25 - wall horn brick

29 - refractory filler

291 - sealing plate

292 - refractory material

31 - blow pipe

311 - flange

32 - lance

33 - lance sleeve

34 - flexible connector

Claims (3)

1. The tuyere block of a blast furnace containing a blast tube attached to the casing of the blast furnace, a lance attached to the end of the blast tube, and a flexible connector connecting the blast tube to the tuyere sleeve. 2. The tuyere block of a blast furnace according to claim 1, characterized in that it comprises a plate refrigerator installed inside the casing of the blast furnace around the tuyere, the surface of which forms the inner surface of the blast furnace. 3. The tuyere block of a blast furnace according to claim 1 or 2, characterized in that a hole for a tuyere is made around the tuyere in the casing of the blast furnace, connected along the entire periphery with a flange made around the periphery of the blast pipe.

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