KR101445516B1 - Hot-blast branch pipe and method for constructing hot-blast branch pipe for blast furnace hot stove - Google Patents

Abstract

The present invention provides a method of constructing a hot air tube in a furnace hot air furnace that does not require expansion shafts and can avoid various problems related to expansion joints. The height of the connecting portion of the hot air tube vertical portion 5 to the hot air furnace body 1 is set to be larger than the height of the hot air tube vertical portion 5 Is initially set higher than the height of the connecting portion of the main body 1 to the hot air tube vertical portion 5 by the thermal expansion difference absorption ratio? = 0.2? By making the lengths of the vertical portion and the horizontal portion of the hot air tube to be three times or more of the respective tube diameters, even if a thermal displacement difference or thermal displacement itself occurs, the tube can be absorbed by elastic deformation of the tube itself. So that it is possible to avoid various problems concerning the expansion joint.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for constructing a hot air tube in a furnace hot air furnace,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot air tube in a furnace hot air furnace, and particularly relates to a hot air tube connected to a hot air main tube connected to an annular tube of a hot air furnace body and a furnace It is suitable for the hot air tube part.

The hot air furnace, which is an auxiliary facility of the blast furnace, is for heating and raising the air blowing from the air blowing port, and is divided into a small internal combustion type hot air furnace and a large external type hot air furnace. In the outdoor type hot air furnace, the regenerative chamber and the combustion chamber are separated, and the upper dome is connected to each other. This connection structure is designed to absorb the thermal displacement occurring in the connection structure itself or the difference in the thermal displacement occurring in the heat storage chamber and the combustion chamber through the expansion joint made of the bellows structure called a bellows. A tension beam for obtaining a so-called reaction force is generally used for the use portion of the expansion joint. Further, in order to protect the steel sheet constituting the external angle of the hot air path from the high temperature of the hot air, it is necessary to stack the bricks inside the iron pie. This bricklaying needs to be done not only in the hot wind but also in every part where the hot wind passes.

However, in the expansion joint made of the bellows structure, it is very complicated and difficult to build bricks. In order to absorb the elongation and shrinkage, it is necessary to stack the bricks at a distance therebetween. At the stretch joint portions where elongation and contraction are repeated over a long period of time, bricks are abraded and dropped off, (Red heat) problem occurs. In addition, there is also a problem that the bellows part itself of the expansion joint is damaged by stress corrosion cracking.

Thus, the applicant of the present invention first proposed a connection structure of an external combustion type hot air furnace capable of connecting a regenerative chamber and a combustion chamber without using an expansion joint as described in Patent Document 1 below. In this connection structure, when connecting the dome of the regenerator with the dome of the combustion chamber, the ratio RD / TD of the tube diameter RD of the connecting tube to the dome diameter TD of the regenerator is 0.24 or more and 0.60 or less, By setting the ratio RD / TD of the tube diameter RD and the dome diameter ND of the combustion chamber to 0.44 or more and 0.60 or less, it is possible to prevent the drift of the gas in the furnace and to suppress the local stress in the knuckle portion near the connecting tube, Thereby connecting the chamber and the combustion chamber.

Japanese Patent Application Laid-Open No. 7-11316

However, in the hot air furnace, there are combustion chambers (including those of the heat accumulating chambers) and connecting portions of the hot air main pipes, so-called hot air pipes, and the expansion joints are used for absorbing the difference in thermal displacement, A tension beam for obtaining a so-called reaction force is used in the use portion of the expansion joint, so that there is a problem that the structure is complicated, the iron is reddish, or the expansion joint itself is damaged as in the case described above.

It is an object of the present invention to provide a method of constructing a hot air tube for a furnace hot air furnace which avoids various problems relating to expansion joints without requiring expansion joints .

In order to solve the above problems, a method for constructing a hot-air tube for a furnace hot-air furnace according to the present invention is a method for installing a hot-air tube for a furnace hot-air furnace in which a hot air main pipe (hot air main pipe), which is connected to an annular tube of a furnace, The present invention relates to a method for constructing a hot air duct for a furnace hot air furnace that constructs a hot air duct having a vertical part of a hot air tube and a horizontal part of a hot air tube, , The height of the connecting portion of the hot air tube vertical portion to the hot air furnace main body is made higher than the height of the connecting portion to the hot air tube vertical portion of the hot air furnace main body by the thermal expansion difference absorption ratio σ = 0.2δ to δ, And the initial installation is performed.

In addition, the hot air tube vertical portion is supported by a height adjustable bearing, and after the initial installation of the hot air tube vertical portion, the vertical portion of the hot air tube vertical portion is lowered so that the connecting portion of the hot air tube vertical portion and the hot air passage main body are at the same height And the height of the vertical portion of the hot air tube is adjusted according to the thermal expansion of the hot air furnace main body and the hot air tube vertical portion during hot air drying temperature rise after connecting the hot air tube vertical portion and the hot air furnace main body to the upper horizontal portion of the hot air tube .

After the hot air is dried, the height of the vertical portion of the hot air tube is adjusted so that the difference in thermal expansion delta-sigma between the thermal expansion difference delta and the thermal expansion difference absorption ratio is divided equally into the horizontal portion of the hot air tube and the horizontal portion of the hot air tube ) Or almost equally divided.

After the hot air duct vertical portion and the hot air duct main body are connected to the horizontal portion of the hot air duct, the bricks are piled up in the horizontal portion of the hot air duct in a state where the horizontal portion of the hot air duct is raised horizontally, And the bricks are piled up in the horizontal portion of the hot air tube in a state where the horizontal portion of the hot air tube is horizontally lowered by lowering the vertical portion of the hot air tube.

In order to solve the above problems, the hot air tube of the furnace hot air path of the present invention is a hot air tube having a hot air tube vertical portion and a hot air tube horizontal portion provided between a hot air main tube connected to an annular tube of a furnace and a hot air furnace body, And the length of the vertical portion and the horizontal portion of the hot air tube are set to three times or more of the respective tube diameters.

The lengths of the vertical portion and the horizontal portion are the lengths between the center lines of the respective pipes.

According to the method of constructing a hot air tube for a blast furnace hot air furnace of the present invention, the height of the connection portion of the hot air tube vertical portion to the hot air furnace body with respect to the thermal expansion difference? During the hot- Since the height of the connecting portion of the hot air furnace main body to the vertical portion of the hot air path furnace main body is increased by the thermal expansion difference absorption ratio σ = 0.2δ to δ, the hot air tube vertical portion is initially installed, The difference of the actual thermal expansion occurring at the connecting portion between the vertical part and the hot air furnace body becomes 隆 - σ and absorbs the difference of the thermal displacement or the thermal displacement itself, thereby eliminating the need of a stretching joint at the connecting portions of the two parts. Can be avoided.

The hot air tube vertical part is supported by a height adjustable bearing and the vertical part of the hot air tube vertical part is lowered after the initial installation of the vertical part of the hot air tube tube so that the connecting part of the hot air tube vertical part and the hot air path body are made the same height, The height of the vertical portion of the hot air tube is adjusted according to the thermal expansion of the hot air furnace body and the vertical portion of the hot air tube tube during the hot air drying temperature rise after connecting the vertical tube portion and the hot air path body to the upper horizontal portion of the hot air tube, The thermal expansion difference can be shared by, for example, the upper horizontal portion and the lower horizontal portion of the hot air tube, whereby the difference in thermal displacement or the thermal displacement itself can be absorbed.

Further, after raising the temperature by hot air, the height of the vertical part of the hot air tube is adjusted so that the difference between the thermal expansion delta and the thermal expansion difference? -Σ of the thermal expansion difference absorption ratio is divided equally or almost equally between the upper part of the hot air tube and the lower part of the hot air tube. , The difference in the thermal displacement or the thermal displacement itself can be absorbed as much as possible.

After the hot air tube vertical portion and the hot air passage main body are connected to the upper horizontal portion of the hot air tube, the vertical portion of the hot air tube is raised so that the horizontal portion of the hot air tube is horizontally placed. Then, bricks are piled up in the horizontal portion of the hot air tube, The vertical portion is lowered and the horizontal portion of the hot air duct is horizontal and the bricks are piled up in the horizontal portion of the hot air tube so that the bricks in the horizontal portion of the hot air tube and the horizontal portion of the hot air tube are easily piled, It is possible to suppress and prevent various problems such as redness and irritation.

According to the hot-air duct structure of the furnace hot-air furnace of the present invention, by making the lengths of the vertical portion and the horizontal portion of the hot air tube three times or more the tube diameters respectively, even if the difference in thermal displacement or the thermal displacement itself occurs, And as a result, it is not necessary to use the expansion joint, and various problems concerning the expansion joint can be avoided.

1 is a first process diagram showing an embodiment of a method for constructing a hot air tube for a furnace hot air furnace of the present invention.
2 is a second process diagram of the hot air tube building method of FIG.
3 is a third process diagram of the hot air tube construction method of FIG.
4 is a fourth process diagram of the hot air tube construction method of FIG.
5 is a fifth process diagram of the hot air tube building method of FIG.
6 is a sixth process diagram of the hot air tube construction method of FIG.
7 is a whole view showing one embodiment of the hot air tube structure of the furnace hot air path of the present invention.
8 is a general view showing various embodiments of the hot air duct structure of the furnace hot air path of the present invention.
9 is a general view showing an example of a hot air tube structure of a conventional furnace hot air furnace.

[Embodiment 1]

Next, an embodiment of a method of constructing a hot air tube for a furnace hot air furnace of the present invention will be described with reference to the drawings.

1 to 6 are all the process drawings of the hot air tube construction method of the hot air path in the present embodiment. The hot air path of the present embodiment is a full-fledged type hot air path in which a so-called combustion chamber and a regenerative chamber are integrated. Reference numeral 1 denotes a hot air furnace main body. In the drawing, reference numeral 2 denotes a hot-air main pipe connected to the annular pipe of the furnace. The hot air tube 3 refers to the structure of the connecting tube from the hot air furnace body 1 to the hot air main tube 2. In addition, although both the hot air furnace body 1, the hot air tube 3, and the hot air main tube 2 are covered with a so-called iron skin, bricks for protecting the iron fiber need to be piled up inside. Bricks need to be stacked in a special lamination method that can absorb thermal expansion and heat shrinkage. In addition, the hot air tube construction method of the present invention is also applicable to a conventional external hot air furnace. In this case, the hot air tube to be disposed between the combustion chamber of the hot air path and the hot air main tube is a target, .

1 is a first process diagram showing an initial installation state of the hot air duct lower portion 4 and the hot air duct vertical portion 5 in the hot air duct 3; The hot air tube lower horizontal part 4 is supported by the support 7 and connected to the hot air main tube 2. [ The hot air tube vertical portion 5 is supported by a jack 9 on the platform 8 and its lower end portion is connected to the horizontal portion 4 of the hot air tube bottom. The jack 9 is for adjusting the height of the hot air tube vertical portion 5. At this time, the horizontal portion 4 of the hot air tube bottom is horizontal. The height of the connecting portion of the hot air tube vertical portion 5 to the hot air passage main body 1 with respect to the height of the connecting portion of the hot air passage main body 1 to the hot air tube vertical portion 5 is set to be equal to or smaller than the height (Min). The thermal expansion difference absorption ratio? Is set to 0.2 to 1.0 times the thermal expansion difference? Between the hot air passage main body 1 and the hot air tube vertical portion 5.

The hot air furnace main body 1 and the hot air tube vertical portion 5 are also at room temperature at the time of construction as well as heated to about 100 캜 by action of the inner brick at the time of raising the drying temperature described later ). As is apparent from the figure, the length of the hot air path main body 1 in the height direction is long (high in height) with respect to the hot air tube vertical portion 5. Therefore, the amount of thermal expansion in the height direction at the time of dry heating is larger than that of the hot air tube vertical portion 5 in the hot air furnace main body 1. This difference in the amount of thermal expansion in the height direction is referred to as a thermal expansion difference?. The height of the connecting portion of the hot air tube vertical portion 5 to the hot air furnace body 1 with respect to the height of the connecting portion of the hot air furnace main body 1 to the hot air tube vertical portion 5 is set to be equal to or less than the height , And after both are connected and then dried, the thermal expansion difference? Is a real thermal expansion difference? -Σ.

Even if the hot air path tube main body 1 and the hot air tube vertical portion 5 are connected by the horizontal portion 6 of the hot air tube in the state of FIG. 1, the hot air tube vertical portion 5 and the hot air path main body 1, Is the actual thermal expansion difference? -?. In this case, however, at the time of construction, the horizontal portion 6 of the hot air tube top is connected in a state in which the hot air path main body 1 side is lowered, and then the hot air path main body 1 side rises at the time of raising the drying temperature (See FIG. 6), and the internal stress of the horizontal portion 6 on the hot air duct tube becomes large. 2, the hot air tube vertical portion 5 is lowered by the thermal expansion difference absorption ratio? By the jack 9, and the hot air tube vertical portion 5 and the hot air furnace main body 1 are separated from each other by the jack 9, Are connected to each other at the same height, and then both are horizontally connected by the upper horizontal portion 6 of the hot air duct tube. For example, in this state, even if the hot air path furnace main body 1 side of the hot air duct upper horizontal portion 6 rises up to the state of Fig. 6, for example, the internal stress does not become so large.

The state of Fig. 2 is incomplete as a hot air furnace. This is because, for example, bricks are not piled in the horizontal portion 4 of the hot air tube branch and the horizontal portion 6 of the hot air tube. Generally, bricks are first piled up in the horizontal part 4 of the hot air tube branch from the strength plane and workability, and later bricks are piled up in the horizontal part 5 of the hot air tube top. Therefore, in the present embodiment, as shown in Fig. 3, the hot air tube vertical portion 5 is again raised by the thermal expansion difference absorption ratio? By means of the jack 9, and the horizontal portion 4 of the hot air tube tube lower portion is leveled , And in this state, bricks are piled up in the horizontal portion 4 below the hot air tube branch. 4, the jack 9 is used to lower the hot air tube vertical portion 5 again by the thermal expansion difference absorption ratio?, And the hot air tube tube upper portion 5 The horizontal portion 6 is in a horizontal state, and bricks are piled up in the horizontal portion 6 of the hot air duct tube in this state.

In this state, the construction of the hot wind path itself is completed. At this time, the horizontal portion 6 of the hot air duct tube is in a horizontal state as in the state of FIG. 2, and the internal stress is zero or almost zero. From this state, therefore, the temperature is increased to the drying temperature of the hot air furnace. As described above, both the hot air furnace main body 1 and the hot air tube vertical portion 5 are also elongated in the height direction by thermal expansion. At this time, as shown in Fig. 5, since the hot air path main body 1 is grounded at the lower end only, the hot air tube vertical portion 5 is extended not only at the upper side but also at the support portion of the jack 9 It also extends downward. The height of the hot air tube vertical portion 5 is adjusted by the jack 9 in accordance with the thermal expansion or the thermal deformation state so that the internal stresses of the hot air duct bottom horizontal portion 4 and the hot air duct upper horizontal portion 6 Do not get too big.

After the drying, the height of the hot air tube vertical portion 5 is adjusted by the jack 9 to adjust the height of the hot air main tube 2 side of the hot air duct lower portion 4 and the hot air tube vertical And the height difference between the side of the hot air path main body 1 and the side of the hot air tube vertical part 5 in the horizontal part 6 of the hot air path tube (? -?) / 2 of the actual thermal expansion difference, that is, by making the real thermal expansion difference? -? Equally or almost equally distributed to the hot air duct upper horizontal portion 6 and the hot air duct lower horizontal portion 4 , The difference in thermal displacement or the thermal displacement itself can be absorbed as much as possible and the internal stress of the hot air tube top horizontal portion 6 and the internal stress of the hot air tube bottom horizontal portion 4 can be minimized at the same time.

In addition to the above-described hot air tube construction method, the inventors of the present invention have found that the lengths of the vertical portion and the horizontal portion constituting the hot air tube are three times or more of their tube diameters, and the difference between the thermal displacements Is absorbed by the elastic deformation of the pipe, thereby developing a hot air duct structure that does not use the expansion joint. It is preferable that the length of the hot air tube vertical portion 5 is three times or more and six times or less the tube diameter of the hot air tube vertical portion 5. More preferably 5 times or more and 5.5 times or less. The length of the hot air tube horizontal parts (4, 6) may be at least three times the tube diameter of the hot air tube horizontal parts (4, 6) and may be made longer depending on the position of the hot air furnace main body and hot air furnace main tube . In the analysis results obtained by the finite element method when the internal pressure and the thermal expansion are applied to the blast furnace hot air furnace of 5000 m 3 when the lengths of the vertical portion and the horizontal portion constituting the hot air tube are three times or more of their tube diameters, It is possible to suppress the maximum stress occurring at the connection portion between the branch pipe upper horizontal portion 6 and the hot air pipe vertical portion 5 to 210 N / mm 2 within the tolerance of fatigue endurance. However, when the hot air tube construction method according to the present embodiment is used in combination, it is possible to reduce the stress generated at the connection portion between the horizontal portion 6 of the hot air tube top and the vertical portion 5 of the hot air tube tube to 140 N / The internal stress generated in the hot air tube 3 can be significantly reduced.

As described above, in the method of constructing a hot-air tube for a furnace hot-air furnace according to the present embodiment, the hot-air tube vertical part 5 and the hot air tube vertical part 5 Of the connecting portion to the hot air furnace main body 1 is set to be higher than the height of the connecting portion of the hot air furnace main body 1 to the hot air tube vertical portion 5 by the thermal expansion difference absorption ratio? = 0.2? The difference of the actual thermal expansion occurring at the connecting portion between the vertical portion 5 of the hot air tube vertical portion 5 and the hot air passage main body 1 becomes δ-σ after the hot air tube vertical portion 5 is initially installed, By absorbing the difference in displacement or the thermal displacement itself, it is not necessary to provide a telescopic joint at the joint of the two, thereby avoiding various problems with the telescopic joint.

The hot air tube vertical portion 5 is supported by the jack 9 and the vertical airflow tube vertical portion 5 is lowered after the initial installation of the hot air tube vertical portion 5, The connecting portion of the main body 1 is made to have the same height so that the hot air tube vertical portion 5 and the hot air path main body 1 are connected to the upper horizontal portion 6 of the hot air tube, The height of the hot air tube vertical portion 5 is adjusted in accordance with the thermal expansion of the hot air tube vertical portion 5 and the hot air tube vertical portion 5 so that the thermal expansion difference, So that the difference in thermal displacement or the thermal displacement itself can be absorbed.

After the hot air is dried and heated, the height of the hot air tube vertical portion 5 is adjusted to adjust the actual thermal expansion difference? -Σ of the thermal expansion difference? And the thermal expansion difference absorption ratio? To the horizontal portion 6 of the hot air tube tube, The difference in the thermal displacement or the thermal displacement itself can be absorbed as much as possible.

After the hot air tube vertical portion 5 and the hot air path main body 1 are connected by the horizontal portion 6 of the hot air duct tube and the horizontal portion 4 of the hot air duct tube 4 rises up the hot air tube vertical portion 5, The bricks are stacked in the horizontal part 4 of the hot air tube branch and then the vertical part 5 of the hot air tube is lowered so that the horizontal part 6 of the hot air tube is horizontal, 6, it is possible to easily build bricks in the horizontal part 6 and the horizontal part 4 of the hot air tube top, and to suppress and prevent various problems such as brick wear and tear, .

[Description of Symbols]

1 hot air furnace main body 2 hot air main pipe

3 Hot air tube 4 Lower part of horizontal tube

5 Hot air tube vertical part 6 Hot air tube upper part Horizontal part

7 Support 8 Stands

9 jacks

[Embodiment 2]

Next, an embodiment of the hot air tube structure of the furnace hot air path of the present invention will be described with reference to the drawings.

Fig. 7 is an overall view of the hot air duct structure of the hot air path of the present embodiment. Reference numeral 11 denotes a heat storage chamber and reference numeral 12 denotes a combustion chamber. Reference numeral 18 in the drawing denotes a hot air main pipe connected to an annular pipe of a furnace. The hot air tube 14 refers to a structure of a connection tube from the combustion chamber 12 to the hot air main pipe 18. Further, in the hot air passage of the present embodiment, the expansion joint is not used at the connection portion between the heat storage chamber 11 and the combustion chamber 12. In the regenerator 11, the combustion chamber 12, the hot air tube 14, and the hot air main tube 18, bricks are piled in the inside to protect the outer surface, while the outer shell is covered with so-called iron. Bricks are made up of special lamination methods that can absorb thermal expansion and heat shrinkage.

The hot air duct 14 of the present embodiment is provided with a hot air duct first horizontal portion 15 connected to the combustion chamber 12, a hot air duct vertical portion 16 connected to the hot air duct first horizontal portion 15, And a hot air tube second horizontal part 17 connecting the hot air main pipe 18 and the hot air main pipe 18. The bricks piled up in the interior of the hot air tube 14 raise the temperature from the initial temperature of the construction to about 100 ° C at the time of operation. However, the difference in thermal displacement due to thermal deformation, (Mutation) itself occurs. Therefore, conventionally, as shown in Fig. 9, the hot air duct first horizontal portion 15 and the hot air duct second horizontal portion 17 are made to absorb the elastic joints A by using the expansion joints A as shown in Fig. In addition, a tension beam 13 for obtaining the reaction force is also juxtaposed at a portion where the expansion joint A is used.

As described above, the expansion joint (A) has various problems in using it. Therefore, in the present embodiment, as shown in Fig. 7, the length of the hot air duct first horizontal portion 15 is set to be three times or more the tube diameter of the hot air duct first horizontal portion 15, The length of the hot air tube second horizontal part 17 is set to be not less than three times the tube diameter of the hot air tube vertical part 16, By making the diameter of the pipe more than three times the diameter of the pipe, it is possible to use a structure in which the expansion joint is not used. Each tube diameter represents the outer diameter of the tube section. Each of the lengths represents the distance between the intersections of the center lines at the connection portion with the connecting tube portion.

It is preferable that the length of the hot air tube vertical portion 16 is three times or more and six times or less the tube diameter of the hot air tube vertical portion 16. More preferably 5 times or more and 5.5 times or less. The length of the first horizontal part 15 of the hot air tube may be three or more times the tube diameter of the first horizontal part 15 of the hot air tube and may be made longer depending on the position of the hot air furnace main body and the hot air furnace main pipe. Likewise, the length of the hot air tube second horizontal part 17 may be three or more times the tube diameter of the hot air tube second horizontal part 17, and may be made longer depending on the positions of the hot air furnace main body and the hot air furnace main pipe.

For example, the difference between the thermal displacement of the hot air tube first horizontal portion 15 and the thermal displacement of the hot air tube second horizontal portion 17 or the difference between the thermal displacement of the hot air tube vertical portion 16, The thermal deformation itself can be absorbed by the elastic deformation of the hot air tube vertical portion 16, and as a result, the expansion joint is not necessary. For example, in the result of the analysis by the finite element method when the internal pressure and the thermal expansion are applied to the blast furnace hot air furnace of 5000 m 3, for example, in the connection between the first horizontal portion 15 of the hot air tube and the vertical portion 16 of the hot air tube, Although it was found that a large stress was generated, its size was within the allowable fatigue endurance stress of 210 N / mm 2.

7 is a so-called best mode in which the expansion joint is not used at the connection portion between the heat storage chamber 11 and the combustion chamber 12 by using the technique described in the above Patent Document 1. However, In the branch pipe structure, it is not necessarily assumed that the expansion joint is not used. 8A, the expansion joint A and the tension beam 13 are used for the second horizontal portion 17 of the hot air duct tube. 8 (b), the expansion joint A and the tension beam 13 are used for the hot air duct first horizontal portion 15. [ 8 (c), the expansion joint A and the tension beam 13 are used at the connection portion between the heat storage chamber 11 and the combustion chamber 12. [ 8D uses the expansion joint A and the tension beam 13 in the connecting portion between the heat storage chamber 11 and the combustion chamber 12 and the first horizontal portion 15 of the hot air duct tube. 8E uses the expansion joint A and the tension beam 13 in the connecting portion of the heat storage chamber 11 and the combustion chamber 12 and the second horizontal portion 17 of the hot air duct tube.

However, in any embodiment, the length of the hot air duct first horizontal portion 15 is set to be three times or more the tube diameter of the hot air duct first horizontal portion 15, and the length of the hot air duct vertical portion 16 The length of the hot air duct second horizontal portion 17 is set to be three times or more the tube diameter of the hot air duct second vertical portion 16, . Therefore, since the difference in thermal displacement and the thermal displacement itself can be absorbed by the elastic deformation of each tube portion constituting the hot air tube 14, even if the expansion joint is used, the load of the expansion joint is small, , And the deformation (displacement) is also small.

As described above, in the hot-air duct structure of the blast furnace hot-air furnace of the present embodiment, by making the lengths of the vertical portion 16 and the horizontal portions 15, 17 of the hot air tube 14 three times or more as large as the respective tube diameters, Even if a difference in thermal displacement or a thermal displacement itself occurs, it can be absorbed by the elastic deformation of the pipe itself. As a result, it becomes unnecessary to use the expansion joint, and various problems concerning the expansion joint can be avoided.

[Description of Symbols]

11 Regeneration chamber 12 Combustion chamber

13 Tension beam 14 Hot air tube

15 Hot air tube 1 Horizontal part 16 Hot air tube vertical part

17 hot air tube second horizontal part 18 hot air main pipe

A stretch joint

Claims (8)

A hot air tube having a vertical portion of a hot air tube and a hot air tube horizontal portion provided between a hot air main tube and a hot air furnace main body connected to a ring tube of a furnace A method for constructing a hot air tube for a blast furnace hot air furnace,
The height of the connecting portion of the hot air tube vertical portion to the hot air furnace body is set to be larger than the height of the connecting portion to the hot air tube vertical portion of the hot air furnace main body with respect to the thermal expansion difference delta at the time of dry heating by hot air between the hot air furnace main body and the hot air tube vertical portion Height of the hot air tube vertical portion is set higher than the height of the hot air tube vertical portion by the thermal expansion difference absorption ratio? = 0.2? To?. The method according to claim 1,
The hot air tube vertical portion is supported by a height-adjustable bearing, the hot air tube vertical portion is initially installed,
After the installation, the vertical portion of the hot air tube is lowered so that the vertical portion of the hot air tube and the connecting portion of the hot air path body are the same height, and the vertical portion of the hot air tube and the hot air path body are connected to the upper portion of the hot air tube,
After the connection, the height of the hot air tube vertical portion is adjusted in accordance with the thermal expansion of the hot air furnace main body and the hot air tube vertical portion during the drying elevating operation by the hot air.
Wherein the hot wind tube is installed in a furnace. 3. The method of claim 2,
After the hot air is dried, the height of the vertical portion of the hot air tube is adjusted so that the difference in thermal expansion delta-sigma between the thermal expansion difference [delta] and the thermal expansion difference absorption ratio [sigma] is divided equally or almost equally between the upper portion of the hot air tube and the lower portion of the hot air tube. Wherein the hot wind tube is installed in a furnace. 3. The method of claim 2,
After the hot air tube vertical portion and the hot air path main body are connected to the upper portion of the hot air tube, the bristles are piled up in the horizontal portion of the bottom of the hot air tube with the horizontal portion of the hot air tube lowered horizontally, And the brick is piled up in the upper horizontal portion of the hot air tube in a state where the vertical portion of the branch pipe is lowered and the horizontal portion of the upper portion of the hot air tube is horizontal. The method according to claim 1,
Wherein the length of the vertical and horizontal portions of the hot air tube is set to three times or more of the diameter of each of the hot air tube vertical portion and the horizontal portion. 6. The method of claim 5,
Wherein the vertical length of the hot air tube vertical portion is three times or more and six times or less the tube diameter of the vertical airflow tube vertical portion. A hot air duct having a hot air duct vertical portion and a hot air duct horizontal portion provided between a hot air main pipe connected to an annular pipe of a furnace and a hot air furnace body,
Wherein a length of the vertical portion of the hot air tube and a length of the horizontal portion are three times or more of the respective diameters. 8. The method of claim 7,
Characterized in that the length of the hot air tube vertical portion is three times or more and six times or less the tube diameter of the vertical airflow tube vertical portion.

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