KR102287016B1 - Additional columns for accommodating checker bricks, metal objects for accommodating checker bricks and methods of expanding columns - Google Patents

Abstract

A checker brick accommodating metal 10 having a grid metal 20 accommodating the checker bricks of the hot stove 2 and an existing column 40 installed between the grid metal 20 and the furnace bottom 21 . and a coaxial additional column 50 installed coaxially on the outside of the existing column 40, and the coaxial additional column 50 is a column body 51 that is installed coaxially on the outside of the existing column 40 And it has the height adjustment mechanism 59 which adjusts the height of the pillar main body 51, The pillar main body 51 has the some pillar cylindrical body 52 laminated|stacked in the height direction.

Description

Additional columns for accommodating checker bricks, metal objects for accommodating checker bricks and methods of expanding columns

The present invention relates to an additional column for accommodating checker bricks supporting checker bricks in a heat storage chamber of a hot stove, a metal object for accommodating checker bricks, and a method for extending the column.

Conventionally, as a facility for supplying hot air to a blast furnace for iron making, a hot stove is used.

A plurality of hot stoves (3 to 5 units) are provided for one blast furnace, and one of these furnaces stores heat and supplies hot air from another hot stove to the blast furnace, thereby continuously supplying hot air to the blast furnace. it is made possible

A hot stove is provided with a combustion chamber and a heat storage chamber, and the checker brick for heat storage is laminated|stacked in the heat storage chamber. A checker brick accommodating metal object for supporting checker bricks is provided on the bottom surface of the hot stove, and a duct is connected to the lower side surface of the hot stove so as to communicate with the space below the checker brick accommodating metal object.

As an example of checker brick accommodating metal, it is formed by erecting a post (support stand) on the bottom of a hot stove, supporting a horizontal beam (great girder) with this post, and attaching a grid metal to the upper surface of the horizontal beam. It is known (refer patent document 1). The checker bricks are accommodated on the upper surface side of the grid metal. An open hole similar to the through hole of a checker brick is provided in a grid|lattice metal object. A ventilation space is formed between the lower surface of the grid metal and the lower surface of the hot stove. The ventilation space communicates with the above-mentioned duct. Thereby, it is comprised so that ventilation is possible in a checker brick, a grid|lattice metal object, a ventilation space, and a duct.

When accumulating heat in a hot stove, the hot air which heated the checker bricks is blown downward from the through-hole of the lowermost checker brick, collects in the ventilation space, and then is discharged from the duct to the outside.

When hot air is supplied to the blast furnace, outside air is introduced from the duct into the ventilation space, and is distributed from there to each through-hole of the checker bricks, is heated while passing through the checker bricks, and is sent to the blast furnace as hot air.

However, in a blast furnace to which hot air is supplied from a hot stove, coke is required as a reducing material for iron ore and a heat source for melting. Since it is possible to reduce the coke consumption by increasing the temperature of the hot air from the hot stove, leading to a reduction in running cost, it is preferable to increase the temperature of the hot air supplied from the hot stove to the blast furnace.

Japanese Patent Laid-Open No. 51-20004

As described above, in order to convert the hot air supplied from the hot stove to the blast furnace into high-temperature hot air having a sufficient amount of heat, the amount of heat stored in the checker bricks of the hot stove (heat storage amount) is increased to increase the temperature of the checker bricks, especially the bottom surface. It is necessary to raise the temperature.

However, when the above-mentioned checker brick accommodating metal material becomes the heat-resistant temperature or more, the checker brick accommodation metal material is damaged, and there is a fear that the checker brick collapses and the hot stove operation is stopped. For this reason, the upper limit of the hot stove exhaust gas temperature which determines the atmospheric temperature of a hot stove furnace bottom is determined by the heat resistance temperature of the checker brick accommodation metal material.

Therefore, when supplying hot air to a blast furnace, the hot air for heating at the time of heat storage is restricted below the heat resistance temperature of the metal part containing a checker brick, and the upper limit of the thermal storage energy of a checker brick is restrict|limited. As a result, the hot air supplied to the blast furnace cannot be made higher.

Here, it is conceivable to raise the upper limit of the thermal storage energy of a checker brick by replacing the checker brick accommodating metal material of an existing hot stove with the checker brick accommodating metal material with a higher heat resistance temperature.

However, in order to replace the checker brick housing metal object, it is necessary to carry out large-scale replacement/remodeling work including checker bricks. When this construction is performed, a long period of suspension of operation, such as one year or more, is required, resulting in a decrease in blast furnace production.

As another high-temperature countermeasure, it is conceivable to add more posts for supporting the lattice metal. If the post can be expanded, the intensity|strength of a checker brick accommodation metal material can be improved, and the improvement of a heat-resistant temperature will be aimed at.

However, if the spacing of the existing struts is not sufficient, it is difficult to install additional struts. That is, it is because not only the installation space of the support|pillar to add but a work space is needed between existing support|pillars. In this way, even if it is attempted to cope with the expansion of the poles, depending on the arrangement of the existing struts, the number of poles to be expanded is not sufficiently obtained, and there is a problem that it is not possible to cope with the temperature increase and the running cost reduction described above.

An object of the present invention is to increase the amount of heat stored in checker bricks to cope with high temperatures, to reduce running costs, and to shorten the air. To provide an extension method.

The additional column for accommodating checker bricks of the present invention is an additional column for accommodating checker bricks installed between a metal grid accommodating checker bricks of a hot stove and a furnace bottom, and is installed between the grid metal object and the furnace bottom. It has a column body installed coaxially on the outside of the existing column, and a height adjustment mechanism capable of adjusting the height of the column body, wherein the column body has a plurality of columnar bodies stacked in the height direction. .

According to the present invention, by the column body installed so as to cover the outer periphery of the existing column, it is possible to form an additional column (coaxial additional column) coaxial with the existing column. Saying that the additional column is coaxial with the existing column means that the additional column and the existing column share the same installation area by installing the additional column double on the outside with respect to the existing column on the inside, and the central axis of the additional column and the central axis of the existing column are not limited to being shared at the same location. For this reason, if the interference of an additional pillar and an existing pillar does not generate|occur|produce, you may install in the state in which the additional pillar was eccentric with respect to the existing pillar, ie, each central axis shifted.

Since these coaxial additional pillars are installed in the same position as the existing pillars, there is no need for a dedicated installation space. Even if there is, it can be installed without any hindrance.

In addition, by forming the column body by lamination of a plurality of column bodies, each column body can be sufficiently shortened compared to the column body, so that loading into the hot stove and work in the furnace can be performed without any problems. .

For the connection of columnar bodies, for example, a structure in which a flange is formed at the opening end of each columnar body and fastened by a bolt passing through this flange, a socket spigot coupling structure formed by processing the flange surface, etc. can be used. there is.

Moreover, by providing a height adjustment mechanism, height adjustment can be performed between the existing pillars, and the load of the grid|lattice metal object which was a burden on the existing pillars can be replaced reliably.

For example, if a coaxial additional column is installed on the outside of an existing column in a state shorter than the existing column, and then the height of the coaxial additional column is increased with a height adjustment mechanism, in the stage where the coaxial additional column is longer than the existing column, the existing column It is possible to transfer the load of lattice metal object received by the coaxial additional column. By such a coaxial additional column, the function as an additional column can be achieved with respect to an existing column.

As a height adjustment mechanism, the structure which adjusts a height by inserting a wedge metal object from the outside, or using a jack bolt, for example can be used. The height adjustment mechanism can be provided between the column body and the grid metal, in the middle of the column body, or between the column body and the furnace bottom.

The additional pillar for checker brick accommodation metal objects of this invention WHEREIN: It is preferable that the said pillar cylinder has a some pillar member divided|segmented in the circumferential direction, respectively.

ADVANTAGE OF THE INVENTION According to this invention, from each direction of the outer periphery of an existing pillar, the pillar body which covers an existing pillar can be formed by following the divided pillar member in a circumferential direction, and connecting each in the circumferential direction.

As a pillar member divided|segmented in the circumferential direction, it can be set, for example, into two divisions at a center angle of 180 degrees (so-called centered alignment), three divisions at 120 degrees each, or four divisions at 90 degrees each. For example, you may combine the thing of 180 degree|times and the thing of 90 degree|times.

For the connection of the pillar members in the circumferential direction, for example, a structure in which a flange is formed in each pillar member and fastened with a bolt penetrating the flange, etc. can be used.

The additional pillar for checker brick accommodation metal objects of this invention WHEREIN: It is preferable that the said pillar cylinder has a cylindrical shape, and it is preferable that the said pillar member has the semi-cylindrical shape which divided the cylindrical surface into two.

ADVANTAGE OF THE INVENTION According to this invention, while being able to make a pillar main body into the structure of a general cylindrical shape, a pillar member becomes two divisions at a center angle of 180 degrees, respectively, and a pillar body can be formed with a minimum member. However, even polygonal shapes, such as a quadrangle and a hexagon, can be employ|adopted as a pillar shape.

The additional pillar for checker brick accommodation metal objects of this invention WHEREIN: It is preferable that the heat insulating material is provided between the said pillar body and the said existing pillar.

According to the present invention, since the heat insulating material is installed, when the hot stove is operated, a temperature difference is generated between the outer column body (coaxial additional column) and the inner existing column, and using the accompanying thermal expansion difference, Load transfer from an existing column to a coaxial additional column can be performed.

That is, by interposing an insulating material between the outer coaxial additional column and the inner existing column, the heat transferred from the outside during operation of the hot stove is sufficiently transferred to the outer coaxial additional column, but reaches the inner existing column. this is suppressed As a result, the outer coaxial additional column becomes high temperature and thermal expansion is relatively large, and the temperature rise of the inner existing column is suppressed and the thermal expansion becomes comparatively small, and a difference in thermal expansion occurs between them. When installing a coaxial additional column, if it is placed in a state just before bearing the load of the grid metal object, the coaxial additional column expands with the operation of the hot stove due to the difference in thermal expansion relative to the existing column, and the grid metal object is lifted. state, whereby the load transfer from the above-described existing column to the coaxial additional column can be performed.

In the additional pillar for checker brick accommodation metal objects of the present invention, it is preferable that the height adjustment mechanism has a wedge metal that is inserted from the outside of the pillar body toward the central axis of the pillar body.

ADVANTAGE OF THE INVENTION According to this invention, while sufficient load strength is acquired, a height adjustment function can be acquired with a simple structure.

As a wedge metal, it is a steel board, and it is preferable that the taper angle of front and back is larger than 0 degree and smaller than 10 degree|times. A plurality of wedge metals can be arranged at equal intervals around the coaxial additional column, for example, four wedge metals can be arranged at intervals of 90 degrees.

In the additional column for accommodating checker bricks of the present invention, the height adjustment mechanism includes: a jack bolt that is installed upright on the furnace bottom and can abut against the column body; and a wedge metal typed between the column body and the furnace bottom. It is preferable to have water.

According to the present invention, the coaxial additional column can be set as the basic height by adjusting the height of the upper end of the jack bolt to a predetermined height from the furnace bottom in advance, and loading the column body (coaxial additional column) on this jack bolt. Thereafter, by inserting the wedge metal, the coaxial additional column can be raised from the basic height to the set height.

That is, even when the difference between the set height and the furnace bottom is large, up to the basic height can be handled with the jack bolt, and the height corresponding to the wedge metal can be as much as the difference between the basic height and the set height. For this reason, the wedge metal object can be downsized and the type operation can also be minimized. In addition, the setting of the basic height by the jack bolt can be easily operated in the no-load state before loading the coaxial additional column, and the working time can be shortened.

The checker brick accommodating metal object of the present invention is a checker brick accommodating metal object having a grid metal object for accommodating the checker bricks of a hot stove, and an existing column provided between the grid metal object and a furnace bottom, the outer side of the existing column and a coaxial additional column provided coaxially to the pole body, wherein the coaxial additional column has a column body installed coaxially on the outside of the existing column, and a height adjustment mechanism capable of adjusting the height of the column body, the column body is characterized by having a plurality of columnar bodies stacked in the height direction.

According to the present invention, it is possible to obtain the effects as described in the above-mentioned additional column for accommodating metal checker bricks of the present invention.

In the checker brick accommodating metal object of the present invention, between the coaxial additional pillars, an independent additional pillar may be provided between the grid metal object and the furnace bottom at a position spaced apart from the coaxial additional pillar.

According to the present invention, not only the reinforcement by the coaxial additional column but also the use of the independent additional column together can reduce the stress generated in the existing grid metal object, and improve the usable maximum temperature of the existing grid metal object.

The method of expanding the checker brick accommodating metal column of the present invention is a checker brick accommodating metal object having a grid metal object accommodating the checker bricks of a hot stove, and an existing column installed between the grid metal object and the furnace bottom, an additional column A method of expanding a checker brick accommodating metal column to extend the above, using a column body configured by stacking a plurality of column bodies in the height direction, and a coaxial additional column having a height adjustment mechanism capable of adjusting the height of the column body, the above A coaxial additional column, characterized in that it is installed coaxially on the outside of the existing column.

According to the present invention, it is possible to obtain the effects as described in the above-mentioned additional column for accommodating metal checker bricks of the present invention.

In the checker brick accommodating metal column expansion method of the present invention, when the hot stove is operated, the coaxial additional column is thermally expanded to be larger than the existing column, so that the load burden of the lattice metal object by the coaxial additional column is reduced to the existing It is preferable to make it larger than a pillar.

ADVANTAGE OF THE INVENTION According to this invention, in the additional column for checker brick accommodation metal objects of this invention mentioned above, the load transfer from the existing column using the difference of thermal expansion to a coaxial additional column can be performed.

According to the present invention, by using a coaxial additional column that is arranged coaxially with the existing column, it is possible to extend the additional column even when the installation space is limited. As a result, the additional column for accommodating checker bricks, the checker brick accommodating metal object, and the method for expanding the checker brick accommodating metal object, in which the heat storage amount of the checker brick can be increased to cope with the high temperature, the running cost can be reduced, and the period of construction can be shortened can provide

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram which shows the structure of the hot stove of 1st Embodiment of this invention.
It is a schematic diagram which shows the checker brick accommodation metal object of the said 1st Embodiment.
It is a schematic diagram which shows the planar arrangement|positioning of the existing pillar, a coaxial additional pillar, and an independent additional pillar of the said 1st Embodiment.
Fig. 4 is a longitudinal sectional view showing an existing column of the first embodiment.
It is a cross-sectional view which shows the existing pillar of the said 1st Embodiment.
Fig. 6 is a longitudinal sectional view showing a coaxial additional column of the first embodiment;
Fig. 7 is a cross-sectional view showing a coaxial additional column of the first embodiment.
It is an exploded perspective view which shows the column body of the coaxial additional column|pillar of the said 1st Embodiment.
It is sectional drawing which shows the lower end of the coaxial addition pillar of the said 1st Embodiment.
Fig. 10 is a longitudinal sectional view showing an independent additional column of the first embodiment;
Fig. 11 is a cross-sectional view showing an independent additional column of the first embodiment;
It is a schematic diagram which shows the checker brick accommodation metal object of 2nd Embodiment of this invention.
It is a schematic diagram which shows the planar arrangement|positioning of the existing pillar and a coaxial additional pillar of said 2nd Embodiment.

EMBODIMENT OF THE INVENTION Hereinafter, specific embodiment of this invention is described based on drawing.

[First Embodiment]

In FIG. 1, the hot stove 2 which supplies hot air is connected to the blast furnace 1 for iron manufacture. Although only one hot stove 2 is shown in FIG. 1, in general, the hot stove 2 is provided in plurality with respect to one blast furnace.

The hot stove 2 has a combustion chamber 9 and a heat storage chamber 3 . A checker brick accommodating metal object 10 is provided at the furnace bottom of the heat storage chamber 3 , and checker bricks 4 for heat storage are stacked on the checker brick accommodating metal object 10 .

The checker brick 4 has a substantially hexagonal shape in plan view, and a plurality of through-holes penetrating vertically are formed. A plurality of checker bricks 4 are arranged in a lattice shape in the horizontal direction, and are piled up from the checker brick accommodating metal 10 to the furnace top vicinity of the hot stove 2 .

In the checker bricks 4, respective through-holes communicate with each other, and air can flow between the furnace top and the furnace bottom of the heat storage chamber 3 through the respective through-holes.

A duct 5 is connected to the lower side surface of the hot stove 2 , and a ventilation space 6 is formed in the gap between the checker brick accommodating metal objects 10 . Via the ventilation space 6 , the duct 5 communicates with the through hole of the checker brick 4 .

[Checker Brick Accommodating Metal (10)]

As shown in Fig. 2, the checker brick accommodating metal 10 includes a grid metal 20 for supporting the checker brick 4 from the upper surface, and a girder for supporting the grid metal 20 from the lower surface side ( 30) has. In addition, the checker brick accommodating metal object 10 is a plurality of existing pillars 40 and a plurality of coaxial additional pillars 50 supporting the girder 30 , and a plurality of independent additions supporting the lattice metal material 20 . A pillar 60 is provided. These lattice metal objects 20 , girders 30 , existing columns 40 , coaxial additional columns 50 and independent additional columns 60 are each made of cast iron. However, other materials such as refractory materials, steel plates, and cast steel may be employed as long as there is no problem in terms of heat resistance and temperature.

The grid metal material 20 has a flat plate shape, and is horizontally extended and provided at the bottom of the furnace 2 inside the hot stove 2 . A plurality of ventilation holes are formed vertically through the grid metal material 20 , and are respectively communicated with the through holes of the checker brick 4 .

The girder 30 is a horizontally supported beam material, is arranged in plurality along the lower surface of the grid metal material 20 , and supports the grid metal object 20 from the lower surface side.

The existing pillars 40 are arranged at predetermined intervals along the longitudinal direction of the girder 30 , and support the girder 30 at the upper end. The lower end of the existing column 40 is fixed to the furnace bottom of the hot stove 2 and is embedded in the heat-resistant concrete 22 . On the heat-resistant concrete 22, a foundation brick 23 is further laid.

The coaxial additional column 50 is disposed on the outside of the existing column 40 coaxially with the existing column 40 , and supports the girder 30 at the upper end. The lower end of the coaxial additional column 50 is fixed to the heat-resistant concrete 22 and is embedded in the foundation brick 23 .

The independent additional pillar 60 is disposed in the space between the existing pillar 40 and the coaxial additional pillar 50 at a predetermined distance from the periphery, and supports the grid metal 20 at the upper end. The lower end of the independent additional pillar 60 is fixed to the heat-resistant concrete 22 and is embedded in the foundation brick 23 .

As shown in FIG. 3 , in the furnace bottom of the hot stove 2 , the existing pillars 40 are arranged along the girder 30 , so they are each linearly arranged. The coaxial additional pillars 50 are arranged coaxially with each of the existing pillars 40 , ie, at the same position, and the arrangement in the furnace bottom is linear according to the existing pillars 40 .

On the other hand, the independent additional column (60) is arranged irrespective of the girder (30). In the arrangement of the independent additional pillars 60 , the intermediate position of the existing pillars 40 or the like is used to secure a gap with the surroundings. For this reason, most of the independent additional pillars 60 are also arranged linearly. However, in the vicinity of the outer periphery of the hot stove 2, it does not necessarily become linear arrangement|sequence.

Hereinafter, details of the existing pillar 40 , the coaxial additional pillar 50 and the independent additional pillar 60 will be described.

[Existing column (40)]

The existing pillar 40 is installed at the time of the shaft path of the hot stove 2, and as shown in FIGS. 4 and 5, it is formed of the cylindrical steel material continuous over the whole length.

In FIG. 4 , the lower end of the existing column 40 is embedded in the heat-resistant concrete 22 of the furnace bottom of the hot stove 2 . Before the lower end is embedded in the heat-resistant concrete 22, the existing column 40 is adjusted to its fixed height.

At the lower end of the existing pillar 40, the lower plate 41 is fixed. A hot stove furnace bottom shell 221 is provided at the furnace bottom of the hot stove 2 . Between the lower plate 41 and the hot stove furnace bottom shell 221, a wedge metal 42 is provided. According to the type position of the wedge metal 42 , the height of the existing pillar 40 can be adjusted. After performing such height adjustment, by pouring concrete, the existing pillar 40 is installed at a predetermined height, and the lower end is embedded in the heat-resistant concrete 22 .

The installation procedure of the existing pillar 40 becomes as follows.

First, the wedge metal 42 is installed on the furnace bottom shell 221, the lower plate 41 is mounted thereon, and the existing column 40 is vertically held.

Next, the wedge metal 42 is typed from the outer periphery of the existing pillar 40 , and the height of the upper end of the existing pillar 40 is adjusted to a predetermined height.

When the height of the existing pillar 40 reaches a predetermined height, concrete is poured to surround the lower plate 41 and the wedge metal 42 , thereby forming the heat-resistant concrete 22 . Thereby, the lower end of the existing pillar 40 is fixed to the furnace bottom.

When the existing pillar 40 is fixed to the furnace bottom, the foundation brick 23 is laid on the surface of the heat-resistant concrete 22 around the existing pillar 40 . In addition, the upper end of the existing column 40, the girder 30 and the metal grid 20 is supported.

By the above, the existing column 40 supporting the lattice metal material 20 through the girder 30 is formed.

The hot stove 2 is movable in a state in which the girder 30 and the lattice metal material 20 are supported only by these existing pillars 40 . However, additional columns are provided for the purpose of increasing the heat storage amount of the checker brick 4 to increase the temperature.

In this embodiment, the coaxial additional pillar 50 and the independent additional pillar 60 are provided as an additional pillar.

[Coaxial additional column (50)]

The coaxial additional column 50 is to be additionally installed in the hot stove 2, and, as shown in FIG. 6, a steel column body 51 installed coaxially on the outside of the existing column 40, The height adjustment mechanism 59 which can adjust the height of the pillar main body 51 is provided. And the pillar main body 51 has the some pillar cylindrical body 52 laminated|stacked in the height direction.

7 and 8 , the columnar body 52 is constituted by a pair of semi-cylindrical columnar members 53 having a central angle of 180 degrees. In order to couple the pillar members 53 to each other, flanges 531 are formed on the pillar members 53 , and the flanges 531 are fastened to each other with bolts 532 .

When assembling the pair of pillar members 53 , by sandwiching the existing pillars 40 therebetween, the pillar cylindrical body 52 is provided coaxially on the outside of the existing pillars 40 .

Between the pillar member 53 and the existing pillar 40, a heat insulating material 54 is provided.

The heat insulating material 54 may be pasted on the inner surface of the pillar member 53 beforehand, and may be wound around the outer surface of the existing pillar 40 . Moreover, you may fill in the space|interval with the existing pillar 40 which arises after installation of the pillar member 53. The heat insulating material 54 may be formed by blowing out other than a sheet-like or mat-like thing.

If a sufficient temperature difference occurs between the coaxial additional column 50 and the existing column 40 to generate a difference in expansion, the thickness of the coaxial additional column 50 is increased, or the coaxial additional column is not used, without using the insulating material 54 . You may use another method, such as increasing the clearance gap between (50) and the existing pillar (40).

The columnar body 52 is connected to each other by fastening the arc-shaped flanges 521 comrades along the respective upper and lower end edges with bolts 522 and fixed, thereby forming the column body 51 .

An upper end member 58 is connected to the column body 52 at the uppermost stage of the column body 51 . Through this upper end member 58 , the column body 51 is connected to the girder 30 .

In FIG. 6, when installing the coaxial additional pillar 50, the foundation brick 23 around the existing pillar 40 is partially removed, and the heat-resistant concrete 22 is exposed. And the height adjustment mechanism 59 is formed between the column body 52 of the lowest stage of the column body 51 and the heat-resistant concrete 22. As shown in FIG.

As shown in FIG. 9 , a base plate 222 is laid on the surface of the heat-resistant concrete 22 . The base plate 222 is provided with a metal wedge 591 , a jack bolt 592 , and a fixing bolt 593 .

The wedge metal material 591 is a steel piece having a taper angle greater than 0 degrees and smaller than 10 degrees, the height can be adjusted by the type from the outside, and can bear a large load.

The jack bolt 592 is screwed to a nut fixed to the base plate 222, and the height of the head can be adjusted by rotating it. By this height adjustment, the height position of the columnar body 52 of the lowest stage can be adjusted, and thereby, the height position of the coaxial additional column|pillar 50 can be determined.

The fixing bolt 593 has a lower part buried and fixed in the heat-resistant concrete 22, and penetrates the bolt hole of the base plate 222 and the bolt hole of the flange 521 of the lowermost columnar body 52, By screwing and fastening a nut, the columnar body 52 can be fixed to the heat-resistant concrete 22 .

The installation procedure of the coaxial additional pillar 50 is as follows.

First, around the existing pillars 40 to install the coaxial additional pillars 50, some of the foundation bricks 23 are removed to expose the heat-resistant concrete 22 (see FIG. 6).

Then, the base plate 222 is laid on the surface of the exposed heat-resistant concrete 22 (see FIG. 9), and the wedge metal 591, the jack bolt 592, and the fixing bolt 593 are installed on the base plate 222. put

Next, the pillar body 51 is assembled on the jack bolt 592 .

First, the upper end member 58 (refer FIG. 6) which will be the uppermost stage of the column body 51 is carried in on the jack bolt 592, it is suspended by a crane, and the column body 52 is below the upper end member 58. secure space for one step of

Then, a pair of pillar members 53 (refer to FIG. 8 ) are combined below the upper end member 58 with the existing pillar 40 sandwiched therebetween to form the second stage columnar body 52 . At this time, a heat insulating material 54 (see FIG. 7 ) is sandwiched between the existing pillar 40 and each pillar member 53 . When the columnar body 52 is completed, the crane is raised again and the space of the new columnar body 52 is ensured.

The pillar body 51 is formed by connecting a predetermined number of pillar cylinders 52 by repetition of the assembly and hanging up of such pillar body 52. As shown in FIG.

When the column main body 51 is formed, after adjusting the jack bolt 592 to a predetermined height, the crane which hung the column main body 51 is lowered, and the column body 52 of the lowest stage is supported by the jack bolt 592. and fixed with a fixing bolt (593). At this time, the wedge metal material 591 is set so as to contact the flange 521 of the columnar body 52 .

In the state in which the column body 51 is assembled, a slight gap is formed between the upper surface of the upper end member 58 and the lower surface of the girder 30 . And the load of the grid|lattice metal material 20 and the girder 30 is borne only on the existing pillar 40, and the coaxial additional pillar 50 is not burdened.

The gap between the upper surface of the upper member 58 and the lower surface of the girder 30 is smaller than the adjustment allowance of the height adjustment mechanism 59, that is, the adjustable range by the wedge metal 591 at the design stage. is set to be

And by height adjustment of the column body 51 by the height adjustment mechanism 59, the load of the grid|lattice metal material 20 and the girder 30 shifts to the state which is also borne by the coaxial additional column 50.

That is, by inserting the wedge metal 591 from the outside of the coaxial additional column 50 , the column body 51 is lifted upward, and the gap between the upper surface of the upper end member 58 and the lower surface of the girder 30 . This decreases, the gap disappears before long, and the upper surface of the upper end member 58 and the lower surface of the girder 30 come into contact with each other, and the girder 30 is in a state supported by the column body 51 by further forming.

In this state, the load burden of the girder 30 by the existing column 40 may still remain. The load burden of the existing column 40 is further reduced or canceled by the difference in thermal expansion with the coaxial additional column 50 by heating by the resumption of operation of the hot stove 2 .

[Independent Additional Pillars (60)]

The independent additional pillar 60 is additionally installed in a site where there is no girder 30 between the existing pillars 40 of the hot stove 2, and as shown in FIG. 10, the steel pillar body ( 61) and the height adjustment mechanism 69 which can adjust the height of the pillar main body 61 is provided. And the pillar body 61 has the some pillar cylinder 62 laminated|stacked in the height direction.

As shown in FIG.10 and FIG.11, the columnar body 62 is a cylindrical member, and has the flange 621 in the upper and lower opening periphery.

The column body 62 is mutually connected by fastening each flange 621 comrades with the bolt 622 and fixed, and becomes the column body 61. As shown in FIG.

An upper end member 68 is connected to the column body 62 of the uppermost stage of the column body 61 . Through this top member 68 , the column body 61 is directly connected to the grid metal body 20 .

In FIG. 10, when installing the independent additional pillar 60, the foundation brick 23 of an installation position is partially removed, and the heat-resistant concrete 22 is exposed. And the height adjustment mechanism 69 using the wedge metal 691 is formed between the column body 62 of the lowest stage of the column body 61 and the heat-resistant concrete 22. As shown in FIG.

The height adjustment mechanism 69 arrange|positions the upper end member 68 and the some pillar cylinder 62 one step at a time, similarly to the height adjustment mechanism 59 (refer FIG. 9) of the coaxial addition pillar 50 mentioned above, and a crane It is assembled as a series of pillar main body 61 by repeating the operation of lifting with , and the overlapping description is abbreviate|omitted here.

By the above operation|work, it will be in the state in which the pillar main body 61 was assembled with the pillar body 62 and the upper end member 68. As shown in FIG. In the state in which the column body 61 is assembled, a slight gap is formed between the upper surface of the upper end member 58 and the lower surface of the lattice metal material 20 . This gap is set so that it may become a dimension smaller than the adjustment allowance of the height adjustment mechanism 69, ie, the adjustable range by the wedge metal 691 at a design stage.

Therefore, by inserting the wedge metal 691 from the outside of the independent additional pillar 60 , the pillar body 61 is lifted upward, and between the upper surface of the upper end member 68 and the lower surface of the grid metal material 20 . decreases, and eventually the gap disappears, so that the upper surface of the upper member 68 and the lower surface of the lattice metal material 20 come into contact, and the state in which the lattice metal material 20 is supported by the column body 61 by further pressing do.

[The order of expansion of additional pillars]

In this embodiment, the installation procedure of the existing pillar 40 at the time of the axial path of the hot stove 2, and the installation procedure of the coaxial additional pillar 50 and the independent additional pillar 60 at the time of the additional pillar expansion have already been described, respectively. like a bar

Here, the overall operation sequence at the time of the additional pillar extension will be described.

The additional pillar extension to the hot stove 2 is performed during a blast furnace idle period, etc., and when extension is performed, first, the operation of the hot stove 2 is stopped, and the furnace temperature is cooled until it becomes a workable temperature.

Next, a worker enters the furnace from the manhole 8 (refer to FIGS. 2 and 3 ), and at the installation site of the coaxial additional column 50 and the independent additional column 60, the foundation brick from the furnace bottom surface 21 (23) is excavated to expose the heat-resistant concrete (22). The waste material of the foundation brick 23 is carried out from the manhole 8. As shown in FIG.

Then, the material of the coaxial additional pillar 50 and the independent additional pillar 60, ie, the pillar member 53, the pillar cylinder 62, and the structural members of the height adjustment mechanisms 59 and 69 are carried in from the manhole 8. So, assemble

In each part, when the column bodies 51 and 61 of the coaxial additional column 50 and the independent additional column 60 are assembled, the height adjustment mechanism 59, 69 is operated to the girder 30 and the lattice metal object ( 20) to start the load bearing.

Here, the operation of the hot stove 2 is restarted after the in-furnace work is finished and the worker leaves. The existing column 40, the coaxial additional column 50, and the independent additional column 60 are thermally expanded by the heat in the furnace accompanying the operation. However, since the existing column 40 is surrounded by the heat insulating material 54 and the temperature rise is relatively small, the amount of thermal expansion is small. In contrast, the coaxial additional column 50 and the independent additional column 60 have a large amount of thermal expansion, so that the load burden of the girder 30 and the lattice metal material 20 is further increased. As a result, the load burden by the existing pillar 40 is reduced or released. This situation can be selected by adjusting the gap during design or construction.

[Effect of the first embodiment]

According to this embodiment, by the column body 51 installed so as to cover the outer periphery of the existing column 40, it is possible to form the coaxial additional column 50 coaxial with the existing column 40.

Since the coaxial additional pole 50 is installed at the same position as the existing pole 40, a dedicated installation space is not required, and a separate additional pole (independent additional pole 60) is installed between the existing poles 40. Even if it is not possible or if there is a limit to the number even if it is possible, it can be installed without any hindrance.

Moreover, by forming the column body 51 by lamination|stacking of the several column body 52, each column body 52 can be made short enough compared with the column body 51, and carrying in into the hot stove 2 is carried out. However, the work in the furnace can be performed without any hindrance.

Moreover, by providing the height adjustment mechanism 59, height adjustment can be performed between the existing pillars 40, and the load of the grid|lattice metal object 20 and the girder 30 which were borne on the existing pillar 40. can definitely be replaced.

For example, after installing the coaxial additional pole 50 in a state shorter than the existing pole 40 (relatively small in height) on the outside of the existing pole 40, the coaxial addition with the height adjustment mechanism 59 When the height of the column 50 is increased, the load of the lattice metal material 20 received from the existing column 40 at a stage where the coaxial additional column 50 is longer than the existing column 40 is reduced by the coaxial additional column 50 ) can be moved to By this coaxial additional pillar 50, with respect to the existing pillar 40, the function as an additional pillar can be achieved.

In this embodiment, the columnar body 52 was comprised by the some column member 53 divided|segmented in the circumferential direction, respectively. For this reason, from each direction of the outer periphery of the existing pillar 40, the pillar member 53 divided in the circumferential direction is made to follow, and by connecting each in the circumferential direction, the pillar body 52 - which covers the existing pillar 40 - A pillar body 51 may be formed.

In particular, in the present embodiment, the columnar body 52 has a cylindrical shape, and the columnar member 53 has a semi-cylindrical shape obtained by dividing the cylindrical surface into two. For this reason, while the column body 51 can be made into the structure of a general cylindrical shape, the column members 53 are each divided into two parts with a center angle of 180 degrees, and the column body 51 can be formed with a minimum number of members. there is.

In this embodiment, the heat insulating material 54 was provided between the existing pillar 40 and the coaxial additional pillar 50. For this reason, when the hot stove 2 is operated, a temperature difference is generated between the outer coaxial additional column 50 and the inner existing column 40, and using the thermal expansion difference accompanying this, the existing column 40 ) to the coaxial additional column 50 can be performed.

In the present embodiment, the height adjustment mechanism 59 has a wedge metal 591 that is inserted from the outside of the column body 51 toward the central axis of the column body 51 . By using such a wedge metal material 591, while sufficient load strength is obtained in the coaxial additional pillar 50, a height adjustment function can be acquired with a simple structure.

In the present embodiment, the height adjustment mechanism 59, together with the above-described wedge metal 591, is provided upright on the base plate 222 of the furnace bottom, and is a jack bolt 592 capable of abutting against the column body 51. ) was used. For this reason, by adjusting the height of the upper end of the jack bolt 592 to a predetermined height from the furnace bottom surface 21 in advance, and loading the column body 51 on this jack bolt 592, the coaxial additional column 50 is basic. height can be set. Thereafter, the coaxial additional post 50 can be raised from the basic height to the set height by typing the wedge metal 591 .

That is, even when the difference between the set height and the furnace bottom is large, the jack bolt 592 can respond up to the basic height, and the height corresponding to the wedge metal 591 is only as much as the difference between the basic height and the set height. For this reason, the wedge metal 591 can be downsized and the type operation can also be minimized. In addition, the setting of the basic height by the jack bolt 592 can be easily operated in the no-load state before the coaxial additional pillar 50 is loaded, and the working time can be shortened.

[Second Embodiment]

In 1st Embodiment mentioned above, the coaxial additional pillar 50 and the independent additional pillar 60 were used together as an additional pillar. On the other hand, in this embodiment, only the coaxial additional pillar 50 is provided as an additional pillar, and the independent additional pillar 60 is not provided.

12 and 13 , a checker brick accommodating metal object 10A is provided at the furnace bottom of the hot stove 2 .

The checker brick accommodating metallic object 10A is similar to the checker brick accommodating metallic object 10 of the first embodiment described above, in the case of the axial path of the hot stove 2, only the existing pillar 40 is used for the girder 30 and the lattice metal. Water 20 was supported.

In the extension of the additional pillar, in the checker brick accommodating metal 10A, the coaxial additional pillar 50 is provided outside the existing pillar 40 . However, between the existing pillars 40, the additional pillar (independent additional pillar 60 of 1st Embodiment) is not provided.

In addition, in this embodiment, the individual structure of the coaxial additional column|pillar 50, the existing column|pillar 40, the girder 30, and the grid|lattice metal material 20 is the same as that of 1st Embodiment mentioned above. For this reason, the overlapping description about each is abbreviate|omitted.

Also according to this embodiment, the effect of the coaxial additional column 50 can be obtained. And although reinforcement by the independent additional pillar 60 as in the first embodiment is not obtained, for the performance required as the additional pillar of the checker brick accommodating metal 10A, if only the coaxial additional pillar 50 is sufficient, the structure can be simplified and the time period can be shortened.

[Other embodiment]

The present invention is not limited to the above-described embodiment, and modifications and the like within the scope capable of achieving the object of the present invention are included in the present invention.

For example, in the height adjustment mechanism 59, the jack bolt 592 is omissible. Instead of the jack bolt 592, the column body 52 may be supported by using a steel piece or the like as a spacer, and then the wedge metal 591 may be inserted to adjust the height.

The height adjustment mechanism 59 is not limited to a structure using the wedge metal 591 . However, as a structure in which the height can be adjusted while bearing a large load, it is preferable that it is a wedge member by the wedge metal 591 or another heat-resistant material.

The column member 53 assembled as the columnar body 52 is not limited to the semi-cylindrical shape obtained by dividing the cylinder into two, and may be divided into three or more. However, since the number of parts increases, it is preferable that it is about two divisions.

The column main body 51 is not limited to a circular cross section, A rectangular cross section etc. may be sufficient. However, considering the uniformity of the direction, it is preferable that the cross section is circular.

The hot stove 2 to which the present invention is applied may be an internal combustion type, an external combustion type, or a furnace top combustion type, and the present invention can be applied to any of them as long as a checker brick housing metal supporting checker bricks is used. there is.

The material used for the coaxial additional column 50 and the independent additional column 60 is not limited to cast iron, and other materials such as refractory materials, steel plates, and cast steel may be employed as long as the material can withstand the temperature of high temperature.

INDUSTRIAL APPLICATION This invention can be utilized for the additional pillar for checker brick accommodation metal objects which support checker bricks in the heat storage chamber of a hot stove, the checker brick accommodation metal object, and the pillar extension method.

1: blast furnace
2: hot stove
3: heat storage room
4: Checker Bricks
5: Duct
6: ventilation space
8 : Manhole
9: combustion chamber
10, 10A: Checker brick acceptance metal
20: lattice metal
21: the bottom of the furnace
22: heat-resistant concrete
221: hot stove furnace bottom shell
222: base plate
23 : foundation brick
30 : girder
40: Existing column
41: bottom plate
42: wedge metal
50: coaxial additional column
51: pillar body
52: column body
521, 531: flange
522, 532: volts
53: column member
54: insulation
58: upper member
59: height adjustment mechanism
591: wedge metal
592 : Jack Bolt
593: fixing bolt
60: independent additional pillars
61: pillar body
62: column body
621: flange
622: bolt
68: upper member
69: height adjustment mechanism
691: wedge metal

Claims (10)

It is an additional column for accommodating checker bricks that bear the load of the grid metal installed between the grid metal object accommodating the checker bricks of the hot stove and the bottom of the furnace,
a column body installed coaxially on the outside of the existing column installed between the grid metal object and the furnace bottom;
and a height adjustment mechanism capable of adjusting the height of the column body;
The column body has a plurality of columnar bodies stacked in the height direction, A checker brick accommodating metal additional column, characterized in that. According to claim 1,
The column body has a plurality of column members each divided in the circumferential direction, The additional column for accommodating checker bricks is characterized in that. 3. The method of claim 2,
The columnar body has a cylindrical shape, and the column member has a semi-cylindrical shape obtained by dividing a cylindrical surface into two, an additional column for accommodating checker bricks. According to claim 1,
Between the column body and the existing column, characterized in that the insulating material is installed, checker brick additional column for accommodating metal. 5. The method according to any one of claims 1 to 4,
The said height adjustment mechanism has a wedge metal thing type|mold toward the center axis line of the said pillar body from the outer side of the said pillar body, The additional pillar for checker brick accommodation metal objects characterized by the above-mentioned. 6. The method of claim 5,
The height adjustment mechanism is characterized in that it has a jack bolt which is installed upright on the bottom of the furnace and can abut against the pillar body, and a wedge metal that is inserted between the pillar body and the bottom of the furnace. additional pillars. A lattice metal accommodating checker bricks of a hot stove, and a checker brick accommodating metal having an existing column installed between the lattice metal and the furnace bottom,
It is installed coaxially on the outside of the existing column, and has a coaxial additional column that bears the load of the grid metal,
The coaxial additional column is
and a column body installed coaxially on the outside of the existing column;
and a height adjustment mechanism capable of adjusting the height of the column body;
The said column body has a several columnar body laminated|stacked in the height direction, The checker brick accommodation metal object characterized by the above-mentioned. 8. The method of claim 7,
Between the coaxial additional columns, an independent additional column is provided between the grid metal object and the furnace bottom at a position spaced apart from the coaxial additional column, Checker brick accommodation metal article. A checker brick for adding additional columns bearing the load of the grid metal object to the grid metal object accommodating the checker bricks of the hot stove, and the checker brick accommodation metal object having the existing column installed between the grid metal object and the furnace bottom It is a method of extending the column of receiving metal,
Using a coaxial additional column having a column body configured by laminating a plurality of columnar bodies in the height direction, and a height adjustment mechanism capable of adjusting the height of the column body,
The coaxial additional column, characterized in that installed coaxially on the outside of the existing column, checker brick accommodating metal column expansion method. 10. The method of claim 9,
When the hot stove is operated, the coaxial additional column is thermally expanded to be greater than the existing column, so that the load burden of the lattice metal by the coaxial additional column is greater than that of the existing column, checker brick accommodating metal How to extend the column.

Images