JP2009120945A - Structure for furnace bottom part in blast furnace - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a structure for furnace bottom part in a blast furnace with which the separation in a basic portion at the removing time, is easily performed and the restraint of heat-transfer onto the foundation, is effectively performed. <P>SOLUTION: Leg-members 113 forming a horizontally extending gap part 50 between the foundation 5 and the furnace body (furnace bottom mantel 10) structured on the foundation, are arranged, and cooling pipes 118 as means for blocking the heat-transfer from the furnace body to the foundation, are arranged. Since the gap part 50 is the air layer, the heat-transfer is restrained and then, the heat-transfer of the leg-members 113 is restrained by cooling with the cooling pipes 118. In demolition of the furnace body, the foundation 5 and the furnace body can be separated from each other by utilizing the gap part 50. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a blast furnace bottom structure and can be used for a blast furnace in which a furnace body is constructed on a foundation.

The blast furnace is formed by building a furnace body on the foundation.
When building the furnace body, it is possible to assemble the furnace body sequentially on the foundation of the installation site, but in order to shorten the construction period, recently, the furnace body ring block has been assembled in advance at another work site and installed. A block construction method is adopted in which it is transported to the site and fixed on the foundation (see Patent Document 1, etc.).

In such a block construction method, the lowermost furnace bottom mantel of the furnace body ring block is constructed on the laying beam, transported onto the foundation, placed on the foundation, and fixed.
It is also possible to assemble only the furnace bottom part on the foundation, manufacture the other part of the furnace ring block in parallel at the work site, transport it to the installation site, and connect it to the furnace bottom part. Has been made.

In installing the bottom mantel described above, it is common to place a laying beam constructed on the top of the bottom mantel on the foundation, and to fill mortar in the meantime. By solidifying the mortar, the lower foundation is integrated.
When constructing the bottom mantel on the foundation, refractory bricks are stacked on the top panel (furnace bottom plate) of the spread beam, and the bottom of the top panel is filled with mortar to transmit the load to the foundation. As a result, the foundation to the bottom of the furnace are integrated.

In the conventional furnace bottom part structure mentioned above, since the bottom part of a furnace body to a foundation is integrated, there exists a problem that the heat in a furnace is easy to be transmitted to a foundation.
On the other hand, water-cooled piping is installed in the inside of the laying beam and the surface of the foundation, or even when the laying beam is not used, the water-cooling piping is installed in the foundation (see Patent Document 2).

19 and 20 show a conventional water-cooled furnace bottom structure 90. 19 and 20 are longitudinal sectional views as seen from directions orthogonal to each other. In each figure, the furnace body 91 is constructed on a spread beam 92.
In order to support the load of the furnace body 91 on the upper surface, the laying beam 92 has a frame in which section steels 93A and 93B are assembled in the crossing direction. A cooling pipe 94A is disposed between the upper structural steel 93A, and a stamp material 96 is filled between the structural steel 93A and the cooling pipe 94A. Cooling pipes 94B are arranged below the space between the lower section steels 93B, and these section steels 93B and cooling pipes 94B are embedded in a mortar 97 filled over the entire spread beam 92.
A pipe 95 from a cooling water supply source (not shown) is connected to each of the cooling pipes 94A and 94B, and cooling water is supplied from the pipe 95 to cool the laying beam 92. , 93B and the cooling pipes 94A, 94B prevent the heat from the furnace body 91 from being transferred to the lower foundation.

  In the blast furnace as described above, the internal refractory bricks are worn with the operation, and thus periodic repairs are necessary. The block construction method described above is also employed for such dismantling. Here, in order to separate the furnace bottom portion from the foundation, a method for removing the furnace bottom mantel has been developed in which the foundation is horizontally cut with a wire saw or the like (see Patent Document 3, etc.).

JP 2006-307319 A JP-A-6-158132 JP 2006-183105 A

In the above-described method for removing the bottom mantel, it is inevitable that the work is complicated because the foundation is cut horizontally. In other words, it is necessary to divide a horizontal region to be cut into a plurality of sections, perform cutting with a wire saw in each section, and reduce the friction when pulling out horizontally and fill with spherical particles to ensure load support.
In addition, in the structure of the bottom of the blast furnace mentioned above, the heat of the furnace body is transmitted to the foundation and the deterioration of the foundation concrete is remarkable, and in order to avoid this, cooling piping is necessary over almost the entire surface of the foundation. The above complexity and the accompanying cost increase were inevitable.

  A main object of the present invention is to provide a bottom structure of a blast furnace that can be easily separated at a base portion at the time of removal and can efficiently suppress heat transfer to the base.

  The furnace bottom structure of the blast furnace of the present invention includes a foundation, a furnace body constructed on the foundation, a leg portion interposed between the foundation and the furnace body and supporting the furnace body, It comprises a horizontally extending gap formed between the foundation and the furnace body by legs, and heat transfer shielding means for shielding heat transfer from the furnace body to the foundation. To do.

In such this invention, a space | gap part is formed between a foundation and a furnace body by supporting a furnace body with a leg part. The gap can be a flat space extending in the horizontal direction, for example. This space can be used as a substitute for the horizontal cutting portion that has been constructed on the foundation in the conventional method for removing a furnace body, and the cutting work for removal can be greatly simplified or eliminated.
Moreover, the air which fills in a space | gap part becomes a heat insulation layer, and can suppress the heat transfer from a furnace body to a foundation. Furthermore, by providing the heat transfer shielding means, heat transfer via the legs can be suppressed or blocked. As a result, the basic material can be prevented from being deteriorated by the heat of the furnace body, and a conventional large-scale water-cooled pipe or the like can be omitted.

In addition, as a heat transfer shielding means, a system in which a heat insulating layer is formed on the surface or inside of a leg part which becomes a heat transfer path other than the gap part, a system in which a heat insulating layer is formed in a part contacting the foundation or the leg of the furnace body Etc. can be adopted.
As a heat insulation layer, the structure which shields heat transfer using a heat insulating material is employable. As the heat insulating material, an existing material or structure may be used as appropriate.
As the heat insulating layer, a structure in which heat transfer is shielded by using a cooling device such as a method of cooling a leg portion, a method of cooling a portion contacting a foundation or a leg of a furnace body, or the like can be employed. For cooling, existing cooling means such as a water cooling pipe or an air cooling heat sink can be employed.

If the heat transfer shielding means is installed on the foundation, it may be installed at the time of foundation construction if it is a new construction of a blast furnace, and if it is a modification of an existing blast furnace, it can be embedded on the upper surface of the foundation.
When the heat transfer shielding means is installed in the furnace body, if the ring block method is used, it may be installed at the time of manufacturing the furnace bottom block, and this can be applied to any new construction or renovation of the blast furnace. When constructing a furnace body on the foundation at the installation site of the blast furnace, heat transfer shielding means may be applied to the furnace bottom during the process.
When the heat transfer shielding means is installed on the leg, if the ring block method is used, it is formed simultaneously with the manufacture of the furnace bottom block, or a leg with a separate heat transfer shielding means is manufactured, May be connected to the lower surface of the furnace bottom block. When constructing a furnace body on the foundation at the installation site of the blast furnace, a leg portion having heat transfer shielding means may be installed on the foundation during the process.

In the furnace bottom structure of the blast furnace according to the present invention, it is desirable that the leg portions are formed on the lower surface of the furnace body, and a plurality thereof are arranged at a predetermined interval.
In such this invention, a leg part can be previously installed in the lower surface of a furnace body, and work efficiency can be improved compared with the case where it installs in the foundation upper surface one by one in the installation field.
In addition, it is necessary to ensure sufficient strength for supporting the load of the furnace body as the leg portion.

In the furnace bottom structure of the blast furnace according to the present invention, it is preferable that the distance between the leg portions is an interval at which an air caster can be introduced into the gap portion between them.
In the present invention as described above, when the furnace bottom mantel is transported, for example, when it is moved from the dolly or the like used for transport onto the foundation, a smooth and efficient work is performed using the air caster introduced into the gap. be able to.

In the furnace bottom structure of the blast furnace according to the present invention, it is preferable that the heat transfer shielding means includes a cooling pipe embedded in a portion of the upper surface of the foundation where the leg portion is placed.
In the furnace bottom structure of the blast furnace according to the present invention, it is desirable to include a cooling pipe embedded in a portion to which the leg portion of the lower surface of the furnace body is connected.
In the present invention as described above, the leg portion can be cooled by the cooling pipe of the foundation or the bottom of the furnace, so that heat from the furnace body can be surely cut off. At this time, it is necessary to embed a cooling pipe on the upper surface of the foundation or the lower surface of the furnace body, but since it is not the entire surface as in the prior art, it is effective in simplifying the structure and reducing the cost.
Such a cooling pipe is not limited to either the foundation or the furnace bottom, and may be provided on both the foundation and the furnace bottom.

In the blast furnace bottom structure of the present invention, it is preferable that the heat transfer shielding means includes a cooling pipe embedded in the leg portion.
In such this invention, a leg part can be cooled with the cooling pipe installed in leg part itself, and, thereby, can interrupt | block the heat | fever from a furnace body reliably.
At this time, as a method of installing the cooling pipe on the leg, a cooling pipe can be mounted on the side of the leg, and the following structure can be used.

In the furnace bottom structure of the blast furnace according to the present invention, it is preferable that the leg portion is a steel block, and the cooling pipe is a through hole formed in the block.
In the present invention, the rigidity as the leg portion can be easily secured by using the steel block, and the cooling pipe can be easily formed by drilling a through hole in the block. The steel block has high heat conductivity, so it is unsuitable for shielding heat transfer by itself, but by forming the cooling pipe integrally, the entire block can be efficiently cooled.

In the blast furnace bottom structure of the present invention, the leg is a block formed by injecting mortar into a mold, and the cooling pipe is formed by piping previously installed in the mold before injecting the mortar. It is desirable that
In the present invention as described above, the cooling pipe can be integrally formed by molding a mortar, and manufacturing is easy. In addition, since most of the material is mortar, the material cost can be reduced.
The heat transfer shielding means by the cooling pipes of these leg portions may coexist with the heat transfer shielding means of the foundation or furnace body described above.

In the furnace bottom structure of the blast furnace according to the present invention, the furnace body has a spread beam extending in the horizontal direction at the bottom thereof, and the furnace body is constructed on the foundation by placing the spread beam on the foundation. It is desirable.
In the present invention, by using the spread beam, it is possible to manufacture the furnace bottom mantel at the work site and transport it to the foundation of the installation site.

In the blast furnace bottom structure of the present invention, the laying beam has a lattice-like frame, and an upper panel and a lower panel that are stretched on the front and back of the frame, and the legs are connected directly below the frame. It is desirable that
In the present invention as described above, since the leg portion is disposed at a portion corresponding to the frame of the laying beam, the furnace body load can be reliably supported.

  The leg portion may be manufactured separately from the laying beam and connected to the lower surface of the laying beam, but may be manufactured together with the frame when the laying beam is manufactured. Alternatively, it may be integrated with the laying beam, for example, by extending the lower edge of the laying beam frame below the bottom panel and forming a gap between the frames protruding downward, which is used as a leg. Also good.

In the bottom structure of a blast furnace according to the present invention, it is preferable that the spread beam has a mortar filled between the upper panel and the lower panel.
In the present invention, the rigidity of the frame can be increased by the mortar that fills the inner space of the spread beam.

In the bottom structure of a blast furnace according to the present invention, the spread beam has a hollow portion extending in a horizontal direction between the upper surface panel and the lower surface panel, and the heat transfer shielding means includes an air layer of the hollow portion. Is desirable.
In the present invention as described above, an air layer extending horizontally is secured by the hollow portion formed in the laying beam, and this air layer serves as a heat insulating layer, so that it can be used as a heat transfer shielding means.

In the furnace bottom structure of the blast furnace according to the present invention, it is preferable that the leg portion is a hollow member, and the heat transfer shielding means includes an air layer in an internal space of the leg portion.
In the present invention as described above, an air layer is secured inside the leg portion, and this air layer serves as a heat insulating layer, so that it can be used as a heat transfer shielding means.

The air layer of the spread beam or the leg air layer as the heat transfer shielding means has a lower heat transfer shielding property than the heat transfer shielding means by the positive cooling by the cooling pipe described above. Therefore, no peripheral device or power is required, and equipment costs and operation costs can be suppressed.
Therefore, such a heat transfer shielding means by the air layer is used in combination with the heat transfer shielding means by the cooling pipe described above, and a cooling pipe is installed in a portion where the heat flow through is large, and an air layer is arranged in the other portion. It is preferable to use the above.

In the blast furnace bottom structure of the present invention, it is desirable that the heat transfer shielding means includes an air layer in the gap and a blower for circulating cooling air in the gap.
In the present invention, the gap portion functions not only as a heat insulating layer but also as a refrigerant passage, so that a heat transfer shielding function can be enhanced.
The circulation of the cooling air in the gap and the cooling by the cooling pipe described above can be used in combination.

In the furnace bottom structure of the blast furnace according to the present invention, the void portion has a region ratio (void ratio) with respect to a bottom area of the bottom surface of the furnace body of a horizontal projection area at a portion where the void portion is formed within a range of 60% to 90%. It is desirable to be.
In such this invention, while being able to fully exhibit the heat insulation function of a space | gap part, the alternative function of the cutting construction at the time of the removal mentioned above can also be made sufficient.
In addition, when the porosity is less than 60%, the heat insulating function due to the voids cannot be sufficiently obtained. On the other hand, if the porosity exceeds 90%, the support strength at the bottom of the furnace may not be sufficient, which is not preferable. Therefore, it is desirable that the porosity is between 60% and 90%.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
In FIG. 1, the blast furnace 1 is dismantled and repaired by cutting the furnace body 3 built in the furnace body 2 horizontally and dividing it into a plurality of ring blocks 4 in the vertical direction. Carry out sequentially. On the other hand, the newly installed furnace body 3 is constructed by manufacturing each ring block 4 on a plurality of work sites other than the site where the blast furnace is installed, and stacking them on the foundation 5.
Of the ring block 4 described above, the furnace bottom mantel 10 is constructed by constructing a furnace bottom structure 12 serving as a furnace bottom part of the furnace body 3 on the spread beam 11.

As shown in FIG. 2, when manufacturing the furnace bottom mantel 10, the balance beam 13 is erected on the ground surface of the work site, and the laying beam 11 is placed on the upper surface of the balance beam 13. Each of the balance beam 13 and the spread beam 11 is a frame structure in which a shape steel material or the like is formed in a lattice shape.
Between the spread beam 11 and the balance beam 13, an air caster 19 (see FIG. 4) for floating the spread beam 11 and moving it horizontally can be introduced. Although FIG. 5 shows an example of the arrangement of the air casters 19 with respect to the planar shape of the spread beam 11, the arrangement method of the air casters 19 is not limited to this.

The furnace bottom structure 12 is constructed on the upper surface of the laying beam 11 configured as described above.
More specifically, an iron skin 15 that is an outer periphery is erected with respect to the furnace bottom plate 14 developed on the upper surface of the laying beam 11, a stave cooler 16 is stretched inside the iron skin 15, and A refractory material 17 such as a hearth brick or carbon brick is laminated through a joint material. In this state, the weight of the furnace bottom mantel 10 is about 1000 tons or more. In order to construct the furnace bottom mantel 10 on the balance beam 13 installed at the work site, the balance beam 13 has sufficient rigidity, The deformation of the mantel 10 is prevented.

  When the bottom mantel 10 can be manufactured at the work site, as shown in FIG. That is, the dolly 18 is connected in the transport direction (longitudinal direction) to form a plurality of dolly rows, and the plurality of dolly rows formed are drawn in parallel into the gap formed between the balance beam 13 and the ground surface, The balance beam 13 is raised by operating the hydraulic pressure of the dolly and conveyed to the side of the foundation 5.

  In transferring to the foundation 5, as shown in FIGS. 4 and 5, an air caster 19 introduced into the laying beam 11 is used. That is, after the balance beam 13 on which the furnace bottom mantel 10 is placed is laid on the foundation 5 by the dolly 18, the air caster 19 is activated to float the laying beam 11 from the balance beam 13. Transfer onto the foundation 5 by applying a horizontal force with a winch or the like.

FIG. 5 illustrates a planar shape of the spread beam 11 of the present embodiment, and FIG. 6 illustrates an enlarged lower structure of the furnace bottom mantel 10 of the present embodiment.
In FIG. 5, the spread beam 11 of the present embodiment includes a rectangular main body portion 11A and extended portions 11B projecting on both sides thereof.

  The laying beam 11 has a lattice frame as a basic structure. In this frame, a plurality of long H-shaped steel materials 111 are arranged in parallel, and the main beams 110 made of similar steel shapes are connected therebetween. Here, in the main body portion 11A, two H-shaped steel members 111 are arranged in pairs to constitute the main beam 111A, and in the expanded portion 11B (the portions on both sides in FIG. 5), the H-shaped steel member 111 is independent. The main beam 111B is configured. This is set in consideration of the fact that the load per unit area of the bottom mantel 10 constructed on the spread beam 11 is large in the main body portion 11A, but is small because it is an edge in the extended portion 11B. It is a thing.

As shown in FIG. 6, in the main body portion 11A, a leg member 113 is installed on the lower surface of the main beam 111A, and a bottom plate 112 is stretched between the main beams 111A. In the extended portion 11B, a leg member 113 is installed on the lower surface of the main beam 111B, and a bottom plate 112 is stretched between the main beam 111B and the adjacent main beam 111A. The entire lower surface of the spread beam 11 is covered with the leg members 113 and the bottom plate 112.
Mortar 114 is filled between main beams 111A and 111B. The mortar 114 is filled to a level below a predetermined height from the upper flanges of the main beams 111A and 111B. A cooling pipe 116 and an auxiliary beam 115 are arranged on the upper surface of the mortar 114.

The auxiliary beam 115 has the same top surface height as the main beams 111A and 111B. A space between the auxiliary beams 115 is filled with a stamp material 117, and the cooling pipe 116 is embedded with the stamp material 117. The upper surface of the stamp material 117 is also at the same level as the main beams 111A and 111B.
The upper surface of the spread beam 11 is formed horizontally by the upper surfaces of the main beams 111A and 111B, the auxiliary beam 115, and the stamp material 117.
The above-described furnace bottom structure 12 is constructed by placing a furnace bottom plate 14 on the upper surface of the spread beam 11 and sequentially connecting an iron skin 15.

In the spread beam 11 described above, the entire load including the furnace bottom structure 12 is supported by the leg member 113. The leg member 113 is supported by the balance beam 13 placed at the work site in the manufacturing stage, and is supported by the foundation 5 after being transported to the installation site.
For this reason, the leg member 113 is made of a material having a sufficiently large load resistance. Specifically, a steel plate or block is used.

  In the foundation 5, a receiving member 51 is installed at a site where the leg member 113 is installed. That is, the foundation 5 is, for example, a reinforced concrete structure, but the receiving member 51 is embedded and installed when the foundation 5 is formed. However, it may be buried after concrete curing of the foundation 5. With this receiving member 51, even if the load of the furnace bottom mantel 10 is concentrated on the leg member 113 portion, the load can be dispersed by the receiving member 51, so that the concrete 5 of the foundation 5 is not cracked. Furthermore, it is desirable that a portion of the concrete of the foundation 5 adjacent to the receiving member 51, particularly a portion directly below, is added with a reinforcing bar so as not to crack.

In this embodiment, the leg member 113 is a leg portion of the present invention, and a gap portion 50 having a thickness corresponding to the height of the leg member 113 is provided between the upper surface of the foundation 5 and the bottom plate 112 of the spread beam 11. It is formed.
In the present embodiment, the void ratio (region ratio of the area of the void portion in the total bottom area) of the void portion 50 in the bottom surface shape of the spread beam 11 is between 60% and 90%.

An air caster 19 is introduced into the gap 50 when the furnace bottom mantel 10 is transferred to the foundation 5, and the upper surface of the air caster 19 is raised to raise the furnace bottom mantel 10.
For this reason, the height of the leg member 113 is set according to the thickness of the air caster 19 described above. That is, the thickness of the gap 50, that is, the height of the leg member 113 is set to be larger than the height of the air caster 19 at the time of introduction and smaller than the height of the air caster 19 in the operating state.
Further, the interval between the leg members 113, that is, the width of the gap 50 is made larger than the width of the air caster 19 to be introduced. Assuming a normal air caster 19, the distance between the leg members 113 is preferably 1600 to 3000 mm. If this is smaller than 1600 mm, it becomes difficult to put in and out the air caster 19 due to interference. On the other hand, if it is larger than 3000 mm, the bending stress applied to the laying beam 11 between the leg members 113 becomes large, and the refractory material may be adversely affected by the bending.

An air caster rail 52 having a smooth surface is stretched between the receiving members 51 on the upper surface of the foundation 5 so that the air caster 19 during operation can smoothly slide.
After being transferred to the foundation 5, the air caster 19 is taken out from the gap 50. In this state, the gap 50 is maintained as a space. Here, the gap 50 is a series of spaces formed between the leg members 113 and penetrates in the vertical direction of FIG. For this reason, ventilation is appropriately obtained in the gap 50, and the cooling effect of the lower surface of the spread beam 11 and the upper surface of the foundation 5 can be obtained by this ventilation.
In order to enhance this cooling effect, a fan 50 </ b> A that blows air to the gap 50 is installed along the periphery of the foundation 5. The fan 50 </ b> A may exhaust air from the gap 50. A fan that blows air may be installed at one end of the gap 50 and a fan that exhausts may be installed at the other end.
It is preferable that the flow rate of ventilation formed in the gap 50 by the fan 50A is 10 to 30 m / sec. If the flow rate is less than 10 m / sec, the surrounding refractory material, mortar and the like are not sufficiently cooled, and the life may be shortened. When the flow velocity is higher than 30 m / sec, the operating cost of the fan 50A increases, and the heat absorption due to ventilation becomes insufficient, resulting in a decrease in cooling efficiency.

In the present embodiment, the laying beam 11 is provided with a cooling pipe 118 as heat transfer shielding means.
The cooling pipe 118 receives the circulation of the cooling water from the same cooling water supply source (not shown) as the cooling pipe 116 described above and cools the surroundings. Here, the cooling pipe 116 is embedded in the upper part of the spread beam 11 and cools the entire upper surface of the spread beam 11. On the other hand, the cooling pipe 118 is embedded in the lower part of the spread beam 11 so as to surround the installation site of the leg member 113, and by cooling the leg member 113, heat transfer from the leg member 113 to the foundation 5 is blocked. It is supposed to be.
As the cooling pipes 118 and 116, piping materials having a nominal diameter of 25A to 50A can be used.
The flow rate of the cooling water passed through the cooling pipes 118 and 116 is preferably 1 to 5 m / sec. If the flow rate is less than 1 m / sec, the surrounding refractory material, mortar and the like are not sufficiently cooled, and the life may be shortened. When the flow rate is higher than 5 m / sec, the operation cost for circulating the cooling water becomes high, and the heat absorption by the cooling water becomes insufficient and the cooling efficiency is lowered.

According to this embodiment, the following effects can be obtained.
That is, the beam 11 is supported only by the leg member 113 with respect to the foundation 5 and the air gap 50 is left as an air layer, so that the air gap 50 also serves as a heat transfer shielding means. Heat becomes difficult to transfer through the gap 50. On the other hand, the cooling of the leg member 113 by the cooling pipe 118 prevents the heat of the furnace body from being transmitted to the foundation 5 through the leg member 113. As a result, the heat transfer to the foundation 5 is shielded, the concrete of the foundation 5 can be prevented from being deteriorated, and the conventionally required cooling structure and the like can be simplified.

  Further, the bottom mantel 10 is placed on the foundation 5 by the leg members 113, and the blast furnace in a state where the bottom mantel 10 and the foundation 5 are partitioned in advance by the gap 50 in other regions occupying most of the bottom surface. Operation as is done. Therefore, when the bottom mantel 10 is removed in dismantling the blast furnace, the bottom mantel 10 can be separated from the foundation 5 by using the gap 50, and the conventional horizontal cutting operation of the foundation 5 can be performed. Can be omitted.

In addition, this invention is not limited to the said embodiment, Other embodiment or a deformation | transformation etc. which are described below are also included in this invention.
In the first embodiment, the cooling pipe 118 is installed along the leg member 113 at the bottom of the spread beam 11 as the heat transfer shielding means, but a cooling pipe may be installed on the foundation 5.
[Second Embodiment]
In FIG. 7, the present embodiment basically has the same configuration as the first embodiment. However, in the present embodiment, the cooling beam 118 is not installed in the laying beam 11, and instead, a cooling tube 53 as a heat transfer shielding means is embedded along the receiving member 51 of the foundation 5.
In such an embodiment, the receiving member 51 is cooled by the cooling pipe 53, and the leg member 113 is also cooled via the receiving member 51. Therefore, the heat transfer from the leg member 113 is shielded by the cooling pipe 53 as the heat transfer shielding means.
Both the cooling pipe 53 on the foundation 5 side and the cooling pipe 118 on the laying beam 11 side described above may be used together as heat transfer shielding means.

[Third Embodiment]
Furthermore, it is good also as a structure which embeds a cooling pipe in leg member 113 itself and cools itself.
In FIG. 8, this embodiment basically has the same configuration as the first embodiment. However, in the present embodiment, the cooling beam 118 is not installed in the laying beam 11, and instead, a cooling tube 119 as a heat transfer shielding unit is embedded in the leg member 113 itself.
In such an embodiment, the leg member 113 is cooled from the inside by the cooling pipe 119. Therefore, the heat transfer from the leg member 113 is shielded by the cooling pipe 119 as the heat transfer shielding means.
Such a cooling pipe 119 of the leg member 113 may be used as a heat transfer shielding means in combination with one or both of the cooling pipe 53 on the foundation 5 side and the cooling pipe 118 on the laying beam 11 side. .

The leg member 113 incorporating the cooling pipe 119 can be manufactured as follows.
In FIG. 9, a flat and long block steel material is used as the base material of the leg member 113, and a through hole extending in the longitudinal direction is formed in the steel material, so that the through hole is used as the cooling pipe 119. be able to.
As a base material of the leg member 113, a concrete molded product in a flat and long block shape can be used. Specifically, a mold having a desired block-like inner shape is prepared, and concrete is poured into the mold to be solidified. When the cooling pipe 119 is formed on such a leg member 113, a pipe material may be installed in advance in a mold before molding, and concrete may be filled around the pipe.

The leg member 113 is fixed to the lower surface of the spread beam 11.
As shown in FIG. 10, the leg members 113 are continuously connected in the longitudinal direction. At this time, as described in the first embodiment, the gap portion 50 into which the air caster 19 can enter is formed between the leg members 113.
When the leg members 113 are connected to each other, a series of cooling pipes traversing the laying beam 11 can be formed by sequentially connecting the cooling pipes 119 incorporated therein.

In each of the embodiments described above, in the air gap, the air layer also serves as a heat transfer shielding means, and as a heat transfer shielding means for shielding heat transfer through the legs, the foundation, legs, furnace body The leg portion or its vicinity was cooled by using a cooling pipe provided on any of the spread beams or a combination of these cooling pipes.
In the present invention, the heat transfer shielding means for shielding the heat transfer through the legs is not limited to the one that performs active cooling as in each of the above-described embodiments, and heat insulation such as an air layer having high heat insulation properties. Heat transfer may be shielded by forming a layer.
[Fourth Embodiment]
In FIG. 11, this embodiment basically has the same configuration as that of the first embodiment. However, in the present embodiment, the above-described cooling pipe 118 (see FIG. 6) is not installed below the laying beam 11. Further, the filling of the mortar 114 is also omitted, and the area from the middle to the lower surface of the spread beam 11 is a hollow portion 114A.
In such an embodiment, after the heat from the furnace bottom structure 12 is partially cooled by the cooling pipe 116, it passes through the layers of the auxiliary beam 115 and the stamp material 117 and tries to transfer heat downward. Here, part of the heat transfer reaches the leg 113 through the main beams 111A and 111B, but the heat transfer through the hollow part 114A is shielded because the hollow part 114A is an air layer.

As described above, in the present embodiment, although the active cooling is not performed, the heat transfer from the leg member 113 can be shielded by the hollow portion 114A as the heat transfer shielding means.
In such this embodiment, since the active cooling by the refrigerant | coolant which passes along a cooling pipe is not performed, an apparatus structure can be simplified and an installation cost and an operating cost can be reduced.
The heat transfer shielding means by the hollow portion 114A may be used in combination with the other heat transfer shielding means described above. For example, in FIG. 11, the leg member 113 may be provided with the above-described cooling pipe 119 (see FIG. 8) to cool the legs. In such a case, a refrigerant circulation device is required. However, the presence of the hollow portion 114A as the heat transfer shield means that the cooling performance of the refrigerant circulation device can be reduced. Can be reduced.

[Fifth Embodiment]
In FIG. 12, this embodiment basically has the same configuration as that of the first embodiment. However, in the present embodiment, the above-described cooling pipe 118 (see FIG. 6) is not installed below the laying beam 11. The filling of the mortar 114 is also up to the upper half, and the lower half of the spread beam 11 is a hollow portion 114A.
Specifically, the web portion of the main beams 111A and 111B is stretched with an intermediate plate 112A at an intermediate height position, filled with mortar 114 thereon, and below that is a hollow portion 114A. .
Furthermore, in this embodiment, the hollow part 113A is also formed in the leg part.
Specifically, the lower ends of the main beams 111 </ b> A and 111 </ b> B of the spread beam 11 are extended and are in direct contact with the receiving member 51. A bottom plate 112 is stretched at a predetermined height from the lower ends of the main beams 111A and 111B on the web portions of the main beams 111A and 111B. For this reason, the lower ends of the main beams 111A and 111B protrude downward from the bottom plate 112, and a leg portion is formed by the protruding portion, and a gap portion 50 is formed around the leg portion.

  In such an embodiment, the heat from the furnace bottom structure 12 is partially cooled by the cooling pipe 116, passes through the auxiliary beam 115 and the stamp material 117 layer, and further passes through the mortar 114 layer downward. Try to heat up. However, since the hollow portion 114A is an air layer, heat transfer through the hollow portion 114A is shielded. A part of the heat transfer reaches the leg part through the main beams 111A and 111B, but since the hollow part 113A is also formed in the leg part, the heat transfer through the leg part is also suppressed.

In this embodiment as well, although positive cooling is not performed, heat transfer through the legs can be shielded by the hollow portions 114A and 113A as heat transfer shielding means. And since the active cooling by the refrigerant | coolant which passes along a cooling pipe is not performed, an apparatus structure can be simplified and an installation cost and an operating cost can be reduced.
It should be noted that the heat transfer shielding means by the hollow portions 114A and 113A may be used in combination with the other heat transfer shielding means described above. For example, in FIG. 6 or FIG. 7, the main beam 111A, 111B may be extended in place of the leg member 113 to form a leg portion having a hollow portion 113A. In such a case, a refrigerant circulation device for the cooling pipes 118 and 53 is required. However, the presence of the hollow portion 113A as the heat transfer shielding means in the legs can reduce the cooling performance in the refrigerant circulation device. Therefore, the equipment cost and the operation cost can be reduced accordingly.

In each of the first to fifth embodiments described above, the furnace bottom mantel 10 is assembled in advance outside the installation site of the blast furnace 1, and this is transferred to the foundation 5 and installed. It was. For this purpose, the bottom beam mantel 10 is assembled on the laying beam 11 for securing the bottom strength required for transfer.
On the other hand, a method of assembling the bottom mantel 10 on the foundation 5 that is the installation site of the blast furnace 1 may be employed. In such a system, the spread beam 11 is not used, but even in such a system, the leg portion, the gap portion, and the heat transfer shielding means based on the present invention can be configured to implement the present invention.

[Sixth Embodiment]
In FIG. 13, the foundation 5 is constructed of concrete or the like at the installation site of the blast furnace 1. Leg members 113 are intermittently disposed on the foundation 5, and a steel mold material 111 is assembled thereon. A furnace bottom plate 14 is stretched on the upper surface of the mold steel material 111, and a layer of mortar 114 </ b> B is formed on the lower surface side of the gap portion of the mold steel material 111. A cooling pipe 116 is disposed on the upper surface of the mortar 114B, and the mortar 114 is filled between the upper surface of the mortar 114B and the furnace bottom plate 14 so as to embed the cooling pipe 116.
A furnace bottom structure is formed by the mold steel material 111, the mortar 114B, the mortar 114, and the furnace bottom plate. This furnace bottom structure is surrounded by a furnace bottom mantel 10. The bottom mantel 10 is fixed to the foundation 5.
In addition, as a layer of the mortar 114B, a mortar previously formed in a slab shape at another place may be supported on the lower end of the mold steel material 111, or the mold frame is temporarily fixed to the lower surface of the mold steel material 111, and the mortar is fixed. It may be filled.

In the present embodiment, a gap 50 is formed between the leg members 113 to separate the upper surface of the foundation 5 from the lower surface of the furnace bottom structure (the lower surface of the mortar 114B) at a predetermined interval. The gap 50 functions as a heat transfer shielding means for shielding heat from the furnace with an air layer. Further, the cooling pipe 116 embedded in the furnace bottom structure functions as a heat transfer shielding means for shielding the heat transmitted from the inside of the furnace to the foundation 5 by cooling the surrounding mortars 114 and 114B. In the present embodiment, the cooling pipe 116 is installed at a lower position than in the first to fifth embodiments described above, and is effective for cooling the leg member 113.
Also in this embodiment, heat transfer shielding is performed on the space other than the legs by the gap 50 that also serves as the heat transfer shielding means, and heat transfer via the legs is performed by the cooling pipe 116 that is the heat transfer shielding means. Shielding is performed.
Thus, even in a structure that does not use the spread beam 11, the function and effect can be obtained by the configuration based on the present invention.

[Seventh Embodiment]
In contrast to the configuration of the sixth embodiment, a cooling pipe 53 may be embedded in the foundation 5 to cool the leg member 113.
In FIG. 14, the present embodiment basically has the same configuration as the sixth embodiment. However, in the present embodiment, a cooling pipe 53 is embedded in the vicinity of the upper surface of the foundation 5, and the leg member 113 is cooled. As the cooling pipe 53 embedded in the foundation 5, the structure described in the second embodiment can be used.
In such an embodiment, the leg member 113 is cooled by the cooling pipe 53. Therefore, the heat transfer from the leg member 113 is more effectively shielded by the cooling pipe 53 as the heat transfer shielding means.

[Eighth Embodiment]
It is good also as a structure which embeds the cooling pipe 119 in leg member 113 itself with respect to the structure of the said 6th Embodiment, and cools itself.
In FIG. 15, this embodiment basically has the same configuration as that of the sixth embodiment. However, in this embodiment, a cooling pipe 119 as a heat transfer shielding means is embedded in the leg member 113 itself. As the leg member 113 having the cooling pipe 119, those described in the third embodiment can be used.
In such an embodiment, the leg member 113 is cooled from the inside by the cooling pipe 119. Therefore, the heat transfer from the leg member 113 is more effectively shielded by the cooling pipe 119 as the heat transfer shielding means.

[Ninth Embodiment]
In contrast to the configuration of the sixth embodiment, a furnace bottom plate 14 similar to the upper surface may be stretched on the lower surface of the mold steel material 111 to hold the layer of the mortar 114B.
In FIG. 16, this embodiment basically has the same configuration as that of the sixth embodiment. However, in the present embodiment, a furnace bottom plate 14 similar to the furnace bottom plate 14 stretched on the upper surface of the mold steel material 111 is also stretched on the lower surface of the mold steel material 111. The mortar 114B is filled on the lower furnace bottom plate 14, and the cooling pipe 116 is disposed thereafter as in the sixth embodiment, and the mortar 114 is filled thereon.
In such an embodiment, it is possible to hold the mortar 114B by the lower furnace bottom plate 14, whereby the layer of the mortar 114B can be filled in-situ, and the gap portion of the mold steel material 111 can be reliably filled. it can.

[Tenth embodiment]
In contrast to the configuration of the ninth embodiment, a cooling pipe 53 may be embedded in the foundation 5 to cool the leg member 113.
In FIG. 17, this embodiment basically has the same configuration as that of the ninth embodiment. However, in the present embodiment, a cooling pipe 53 is embedded in the vicinity of the upper surface of the foundation 5, and the leg member 113 is cooled. As the cooling pipe 53 embedded in the foundation 5, the structure described in the second embodiment can be used.
In such an embodiment, the leg member 113 is cooled by the cooling pipe 53. Therefore, the heat transfer from the leg member 113 is more effectively shielded by the cooling pipe 53 as the heat transfer shielding means.

[Eleventh embodiment]
It is good also as a structure which embeds the cooling pipe 119 in leg member 113 itself with respect to the structure of the said 9th Embodiment, and cools itself.
In FIG. 18, this embodiment basically has the same configuration as that of the ninth embodiment. However, in this embodiment, a cooling pipe 119 as a heat transfer shielding means is embedded in the leg member 113 itself. As the leg member 113 having the cooling pipe 119, those described in the third embodiment can be used.
In such an embodiment, the leg member 113 is cooled from the inside by the cooling pipe 119. Therefore, the heat transfer from the leg member 113 is more effectively shielded by the cooling pipe 119 as the heat transfer shielding means.

[Other Embodiments]
In each of the embodiments, the cooling pipe 118, the cooling pipe 119, or the cooling pipe 53 that cools the leg member 113 is used as the heat transfer shielding means, but other cooling means may be used.
For example, in addition to cooling by a cooling pipe through which cooling water flows, a so-called heat sink having a large number of fins molded from a material having high heat conductivity may be attached to the surface of the leg member 113. With such a heat sink, the leg member 113 can be cooled by the cooling air passing through the gap 50, and the heat transfer from the leg member 113 can be shielded.
Or you may employ | adopt the other structure which can shield the heat transfer via the leg member 113, and let the leg member 113 be a block shape | molded with the material with high heat insulation, and heat-conducting shielding effect on itself. You may give it. However, as described above, since a high load resistance is required for the leg member 113, it is desirable to adopt the configuration as in each of the embodiments described above.

In the above embodiment, the blast furnace 1 is provided with the furnace body 3 and the furnace body rod 2, but it is desirable that the furnace body 3 and the furnace body rod 2 are not joined during operation. By not joining the furnace body 3 and the furnace body 2 during operation, it is possible to avoid the influence of unnecessary relative displacement between the furnace body 3 and the furnace body 2 due to the thermal behavior during operation of the blast furnace.
In addition, when an earthquake occurs between the furnace body and the foundation, relative displacement due to mutual slip may occur. However, according to the detailed examination by the present inventors, in the blast furnace body targeted by the present invention, even during an earthquake, the sliding force between the foundation and the leg is “static coefficient of friction> shearing during an earthquake. Because of the relationship of “force factor”, the problem of slipping is avoided by allowing the blast furnace body to stand by itself stably. According to the experiment results of the present inventors, the static friction coefficient = 0.64 to 0.73, the shearing force coefficient at the time of the earthquake = 0.2 (in the case of Kanto), there is a sufficient difference between the two companies, There is no slippage between the two.

  INDUSTRIAL APPLICABILITY The present invention can be used as a blast furnace bottom structure, and can be used in a blast furnace that constructs a furnace body on a foundation.

The schematic diagram which shows the blast furnace of 1st Embodiment of this invention. The schematic diagram which shows manufacture of the furnace bottom mantel of the said 1st Embodiment. The schematic diagram which shows conveyance of the furnace bottom mantel of the said 1st Embodiment. The schematic diagram which shows transfer of the furnace bottom mantel of the said 1st Embodiment. The partially broken top view which shows the spread beam of the said 1st Embodiment. Sectional drawing which shows the principal part of the said 1st Embodiment. Sectional drawing which shows the principal part of 2nd Embodiment of this invention. Sectional drawing which shows the principal part of 3rd Embodiment of this invention. Sectional drawing which shows the leg member of the said 3rd Embodiment. The perspective view which shows arrangement | positioning of the leg member of the said 3rd Embodiment. Sectional drawing which shows the principal part of 4th Embodiment of this invention. Sectional drawing which shows the principal part of 5th Embodiment of this invention. Sectional drawing which shows the principal part of 6th Embodiment of this invention. Sectional drawing which shows the principal part of 7th Embodiment of this invention. Sectional drawing which shows the principal part of 8th Embodiment of this invention. Sectional drawing which shows the principal part of 9th Embodiment of this invention. Sectional drawing which shows the principal part of 10th Embodiment of this invention. Sectional drawing which shows the principal part of 11th Embodiment of this invention. Sectional drawing which shows the conventional furnace bottom part structure. Sectional drawing which shows the conventional furnace bottom part structure.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Blast furnace 2 ... Furnace body 3 ... Furnace body 4 ... Ring block 5 ... Base 10 ... Furnace bottom mantel 11 ... Laying beam 11B ... Expansion part 11A ... Main part 12 ... Furnace bottom structure 13 ... Balance beam 14 ... Furnace bottom plate 15 ... Steel cooler 17 ... Stave cooler 17 ... Refractory material 18 ... Dolly 19 ... Air caster 50A ... Fan 50 ... Cavity 51 ... Receiving member 52 ... Air caster rail 53 ... Cooling pipe (heat transfer shielding means)
110 ... main beam 111 ... shaped steel materials 111A, 111B ... main beam 112 ... bottom plate 113 ... leg member (leg part)
113A ... Hollow part (heat transfer shielding means)
114, 114B ... Mortar 114A ... Hollow part (heat transfer shielding means)
115 ... Auxiliary beam 116 ... Cooling pipe 117 ... Stamp material 118, 119 ... Cooling pipe (heat transfer shielding means)

Claims (15)

  A foundation, a furnace body constructed on the foundation, a leg part interposed between the foundation and the furnace body to support the furnace body, and the foundation and the furnace body by the leg part A furnace bottom structure of a blast furnace, comprising a horizontally extending gap formed between and a heat transfer shielding means for shielding heat transfer from the furnace body to the foundation. In the bottom structure of the blast furnace according to claim 1,
A furnace bottom structure of a blast furnace, wherein the leg portions are formed on a lower surface of the furnace body, and a plurality of the leg portions are arranged at a predetermined interval. In the blast furnace bottom structure according to claim 2,
The bottom structure of a blast furnace, wherein the space between the legs is a space at which an air caster can be introduced into the space between the legs. In the bottom structure of the blast furnace according to any one of claims 1 to 3,
The furnace bottom structure of a blast furnace, wherein the heat transfer shielding means includes a cooling pipe embedded in a portion on which the leg portion of the upper surface of the foundation is placed. In the bottom structure of the blast furnace according to any one of claims 1 to 4,
The furnace bottom structure of a blast furnace, wherein the heat transfer shielding means includes a cooling pipe embedded in a portion supported by the legs on the lower surface of the furnace body. In the bottom structure of the blast furnace according to any one of claims 1 to 5,
The bottom structure of a blast furnace, wherein the heat transfer shielding means includes a cooling pipe embedded in the leg portion. In the bottom structure of the blast furnace according to claim 6,
The bottom structure of a blast furnace, wherein the leg portion is a steel block and the cooling pipe is a through hole formed in the block. In the bottom structure of the blast furnace according to claim 6,
Blast furnace furnace characterized in that the leg is a block formed by injecting mortar into a mold and the cooling pipe is formed by piping previously installed in the mold before injecting the mortar. Bottom structure. In the bottom structure of the blast furnace according to any one of claims 1 to 8,
A furnace bottom of a blast furnace, wherein the furnace body has a spread beam extending in a horizontal direction at a bottom portion thereof, and the furnace body is constructed on the foundation by placing the spread beam on the foundation. Construction. In the bottom structure of the blast furnace according to claim 9,
The laying furnace has a lattice-shaped frame, an upper panel and a lower panel that are stretched on the front and back of the frame, and the legs are connected directly below the frame. Bottom structure. In the bottom structure of the blast furnace according to claim 10,
The bottom structure of a blast furnace, wherein the spread beam has a mortar filled between the upper panel and the lower panel. In the bottom structure of a blast furnace according to claim 10 or claim 11,
The bottom structure of a blast furnace, wherein the spread beam has a hollow portion extending in a horizontal direction between the upper surface panel and the lower surface panel, and the heat transfer shielding means includes an air layer of the hollow portion. In the bottom structure of a blast furnace according to any one of claims 1 to 12,
The bottom structure of a blast furnace, wherein the leg portion is a hollow member, and the heat transfer shielding means includes an air layer in an internal space of the leg portion. In the bottom structure of the blast furnace according to any one of claims 1 to 13,
The furnace bottom structure of a blast furnace, wherein the heat transfer shielding means includes an air layer in the gap and a blower for circulating cooling air in the gap. In the bottom structure of a blast furnace according to any one of claims 1 to 14,
The furnace bottom of a blast furnace, wherein the void portion has an area ratio (void ratio) of a horizontal projection area at a portion where the void portion is formed to a bottom area of the bottom surface of the furnace body in a range of 60% to 90%. Construction.

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