JP3292791B2 - Sinter cake support stand and sintered pallet - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sinter cake supporting stand and a sintering pallet used in a sinter cake supporting sintering method for producing a sintered ore used in a blast furnace or the like.

[0002]

2. Description of the Related Art FIG . 5 shows a conventional sinter production process. The ore, the main raw material for sinter production, is supplied from the yard to the ore hopper 17.
The limestone as an auxiliary material is transported to a limestone hopper 16, and coke as fuel is transported to a coke hopper 15. ore,
Limestone and coke are cut out from hoppers 17, 16 and 15, and are subjected to humidity conditioning and granulation with a mixer 18 together with the ore returned from the ore return hopper 14 to become a sintering compound raw material 8. The sintering compound raw material 8 is conveyed to a surge hopper 9, stored and then cut out from a drum feeder 10.
The sintering pallet 7 is inserted through the chute 11 to form a sintering raw material layer 12. In the case of sintering using iron ore as a main raw material, the thickness of the sintering raw material layer is usually about 600 mm.
Then, the coke on the surface of the sintering raw material layer is ignited by the combustion heat of the gas in the ignition furnace 13, and the coke is burned while sucking air downward, and the raw material is sequentially sintered from the upper layer to the lower layer by the combustion heat. .

According to such a conventional method, the lower layer of the sintering raw material layer is compressed by the weight of the integrated sintered mass (hereinafter referred to as a sinter cake) of the sintered pallet after the sintering is completed, and the density is increased. I do. For this reason, ventilation becomes worse, and ventilation becomes uneven, and the burning speed of coke becomes slow,
In addition, uneven combustion occurs. As a result, there is a problem that the sintering speed is reduced, and the yield, that is, the yield of a product having a diameter of 5 mm or more is reduced, so that the productivity is reduced.

There are various methods for solving the decrease in productivity. Japanese Unexamined Patent Publication No. 2-293586 discloses a technique for improving the productivity by eliminating the load on the sinter cake and improving the ventilation of the sintered layer. A sinter cake support sintering method with the provided stand is described. JP-A-4-168234 used in this sinter cake supporting sintering method
FIG. 6 shows a sintering pallet provided with a plate-shaped support stand described in Japanese Patent Application Laid-Open Publication No. H11-209,878.

In the sinter cake supporting sintering method, when sintering proceeds and the sinter cake is formed up to the height of the support stand D, the sinter cake is transferred to the support stand D.
Is supported by the upper end, and no load is applied to the lower layer. Therefore, no load is applied to the lower sintering raw material layer, and the ventilation of the sintering layer is improved.

However, the sinter cake supporting and sintering method using the stand raises the temperature rise near the surface of the support stand D due to heat removal from the surface of the support stand D or excessive ventilation at the boundary between the support stand D and the sintering material layer. There lowered sufficiently walking without being sintered distillate in heterogeneous, there is a problem that productivity is lowered, JP-a-6-129775, as shown in FIG. 7, placed them with grid-like stand E A sintered pallet 7 is described. Since the lattice-shaped stand E is lattice-shaped, the surface area is smaller than that of the conventional plate-shaped sinter cake support stand, thereby preventing heat from the stand surface and excessive ventilation at the boundary between the stand and the packed bed. Thus, sintering can be performed in a state where the temperature in the vicinity of the stand surface can be sufficiently increased without obstructing the ventilation of the sintered layer.

[0007]

However, in the sintered pallet 7 on which the lattice-shaped stands E are installed, the surface area of each lattice-shaped stand E is smaller than the plate-like shape by about 45%, so that the internal space area is small. It becomes too wide, the sintering raw material layers are connected via the grid-shaped stand E, and the flow of the sintering gas is enhanced, sintering proceeds too much, and the sinter cake is integrated with the grid-shaped stand E, and When the sinter cake is discharged at the discharging part of the machine, the lattice stand E and the sinter cake do not separate, the sintering pallet holding the sinter cake hits the crushing guide, and the sintering machine stops overloading. However, there is a problem that the operating rate of the sintering machine decreases (hereinafter,
The ease of separation of the sinter cake from the sintering pallet including the stand of the sinter cake in the sinter mining section is referred to as the sinter cake mining properties).

In the sintering operation, a sintering combustion zone having a maximum temperature of 1350 to 1400 ° C. descends from the upper part to the lower part at a speed of 15 to 30 mm / min in the vicinity of the sinter cake supporting stand. The stand itself is the heat transfer by the contact of the sinter cake on its upper surface,
The side receives heat transfer by convection and radiation, and the sinter cake support stand itself is exposed to a maximum of 1000 ° C. or higher from near normal temperature, and the temperature difference in the height direction of the stand is also 500-7.
00 ° C. On the other hand, even when the stand is cooled, a temperature difference occurs between the upper part and the lower part of the stand. Moreover, it is repeated in a period of 50 to 70 minutes. Due to the severe thermal shock of the low cycle, thermal strain is accumulated, and cracks due to the thermal strain are generated in the sinter cake support stand. Further, as the crack progresses, the sinter cake support stand is partially broken, the life becomes extremely short, the frequency of replacement increases, and there is a problem that the operating rate of the sintering machine decreases and the equipment cost becomes extremely expensive.

On the other hand, with regard to the arrangement of stands per sintered pallet, the stand arrangement as shown in FIG. 7 has a problem in the support balance of the sinter cake and the sinter cake discharging property. Also, the arrangement of the stands of each pallet in the endless pallet row has a problem of an increase in equipment costs due to an increase in the support balance of the sinter cake and the number of stands.

Further, the existing great bar is divided into two or three rows with a length of 1/2 to 1/3 with respect to the length of the pallet in the advancing direction of the pallet. There is a problem of restrictions on the structure of the stand attached to the pallet frame at the part.

In view of the above, the present invention provides a sinter cake support stand which can secure the air permeability of the side of the support stand on the pallet and enhance the mining efficiency, and a low cycle severe sinter cake support sintering method. Provided are a sinter cake support stand and a sintered pallet having a shape capable of mitigating thermal shock as much as possible.

[0012]

The present invention SUMMARY OF THE INVENTION are as - follows.

On a sintering pallet of a downward suction type sintering machine
In the sinter cake support stand disposed via the mounting portion , the height is 30 to 70% of the thickness of the sintering material layer, and the length of the upper side with respect to the lower side of the cross section in the pallet traveling direction is 30 to 7%.
0% Ri Do a plate of positive trapezoid, and the width of the mounting portion
Sinter cake support stand which is characterized 1/3 der Rukoto from 1/2 of the stand height.

[0014]  On the side of the sinter cake support stand
Vertical slit with open upper end at least at one location
Characterized in that an aperture is provided. Sinter case
Ki support stand.

[0015]  On the side of the sinter cake support stand
Cross-section by staggering vertical grooves on both sides
Characterized by having a wavy shape Sinter case
Ki support stand.

The sinter cake support stand of any one of the above-mentioned (1) to (5) is provided in the rear row of the plurality of great bars on the sintering pallet in the sintering pallet advancing direction parallel to the advancing direction of the sintering pallet and perpendicular to the sintering pallet surface. Through the mounting part
A sintered pallet, wherein 1 to 5 sheets are installed.

[0017]

The function of the existing sinter cake support stand of the present invention
The height from the rate bar is 70% of the thickness of the sintered layer.
Can be selected variously up to a minimum of 30% depending on sintering conditions,
The higher the stand height, the greater the support effect of the sinter cake
No. The stand length is about 495mm and the existing great bar
The same as the length.

Regarding the stand width, the upper part is thinner and the lower part is thicker, that is, the trapezoidal cross-sectional shape is preferable from the viewpoint of the sinter cake mining properties. Further, also in the longitudinal direction of the stand, the forward direction can be thinned from the surface of the sinter cake in terms of the mining properties .

The length of the upper side is 30 to 70% of the length of the lower side.
If a plate of positive trapezoidal shape and the sinter cake supporting stand,
It absorbs the difference in thermal expansion due to the temperature difference in the upper part of the sinter cake support stand, reduces the accumulated thermal strain, and reduces or delays the occurrence of cracks due to thermal fatigue. Top side length 3
If it is less than 0%, the supporting area of the sinter cake is too small,
If it exceeds 70%, the absorption of the difference in thermal expansion becomes insufficient. 30-7
Although 0% can be taken only in the rear part of the pallet in the longitudinal direction of the stand, the effect of absorbing the difference in thermal expansion is small.
If the upper end of the sinter cake support stand is divided by providing a vertical slit-shaped opening from the upper side to the lower side of the sinter cake support stand, the effect of absorbing the difference in thermal expansion is large. However, sinter cake support stand height 1
If the height is less than 0%, the height is too small in view of the height at which the thermal shock is applied. If the height is more than 40%, cracks tend to be generated from the bottom of the opening, which may limit the service life, which is not preferable. The larger the number of divisions, the better, but the cracks tend to occur from the bottom of the hole, which may limit the life.

As another structure for improving the heat absorbing function of the upper part of the sinter cake support stand, vertical grooves are provided on the side surface of the sinter cake support stand in a staggered manner with respect to both side surfaces, so that the cross section becomes wavy. There is a structure. At the time of heating and cooling, the restrained part receives stress due to the temperature difference between the upper and lower parts of the stand, and the upper end becomes the maximum stress,
Because it becomes smaller in the lower direction, it is easy to expand and contract as it goes up, and it has a wavy shape that gives flexibility toward the bottom, that is, bellows shape, for example, it is easy to expand and contract like a fan, improving the thermal stress relaxation function Let it. The cross-sectional shape of the vertical groove may be semicircular, angular, or V-shaped. The length of the flute is within 5/6 of the height of the stand from the top, and no further effect is obtained. The width of the vertical groove is within 1/3 of the thickness of the upper portion, and there is no stretching effect beyond that. The depth of the vertical groove is a depth along the outer shape, and is within 1/6 of the thickness of the upper portion.

With respect to the shape of the mounting portion for inserting the stand into the pallet frame, a shape similar to the existing great bar in the longitudinal direction and the height direction is adopted. The difference between the thermal expansion due to the material of the stand and the thermal expansion of the pallet frame is corrected by the length in the longitudinal direction. The width of the mounting part is an important factor due to the problem of the vertical stability of the stand, and is determined in relation to the stand height so that the stand does not contact when passing through the interference part of the sintering machine. If it exceeds 2, it is not economical, and if it is less than 1/3, the vertical stability of the stand is lacking. Therefore, a width of 1/2 to 1/3 of the stand height is appropriate. The width of the lower part of the mounting part of the stand is also an important factor, and this is the width that allows the sintering pallet to advance to the mining part, turn downward, and stably hold the stand vertically when turning to the return side, The width of the lower part of the mounting part can be made smaller than the width of the mounting part by the width of the existing great bar, and the weight of the stand can be reduced.

There is no opening in the horizontal plane at the same level as the existing great bar surface of the stand mounting portion for sucking down the sintering gas between the existing great bars. Therefore, if a stand is arranged on the sintering pallet, the porosity of the existing great bar for sucking down the sintering gas is reduced, and the sintering function tends to be negative. Therefore, an improvement has been made by providing a slit having a width of 5 mm on the existing great bar surface of the mounting portion of the stand described in JP-A-5-43950. The number of slits, that is, the slit area, is preferably as large as possible in view of the structure of the stand mounting portion.

The shape of the stand in the advancing direction of the sintering pallet is divided into a plurality of parts in the pallet advancing direction in the same manner as the existing great bar, and it is easy to incorporate the same into the pallet frame as in the existing great bar. . However, since the mounting width of each stand to the pallet frame is much larger than the width of the existing great bar for the vertical stability of the stand, that is, to prevent the stand from falling down, the conventional method of assembling the great bar cannot be used. Since the existing great bar has a narrow width of about 30 mm, if the great bar is slightly inclined between the pallet frames, the lower jaw of the great bar also comes off and can be easily removed and attached. However, in the case of the sinter cake support stand, since the width of the mounting portion is much wider than the existing great bar, even if the mounting portion is inclined and inserted between the pallet frames, the mounting portion competes with the pallet frame in the inserted state, and the stand is palletized. Cannot rotate in the direction perpendicular to the frame. Therefore, the existing notch at one end of the pallet frame is extended, and the mounting portion of the stand is inserted at a right angle to the pallet frame from there, and in that state, the stand is moved in parallel to a predetermined position, that is, sideways. Just attach it. The removal is reversed. In addition, about the part which expanded the notch part on one side end of the pallet frame, an end great bar similar to the wide existing great bar was prepared instead of the existing great bar, and the notch was filled in. The end great bar may be held with the existing great bar holding pin.

The concept of the arrangement and arrangement of the sinter cake support stands in the longitudinal direction of the endless sintered pallet rows and the individual pallets is uniform in order to minimize disturbance in the sintering speed due to uneven sinter cake support. Based on the idea that a balance of support must be maintained. The sinter cake support stand may be placed on all individual pallets of the endless sintered pallet row, or placed on the first pallet and not on the second pallet for the purpose of reducing equipment costs. As in the case of the third pallet, the pallet row may be arranged one by one, or the first pallet may have a larger number of pallets and the second pallet may have a larger number of pallets. Alternatively, the third pallet may be staggered with respect to the pallet row so as to increase the number of arranged pallets.

The number of sinter cake supporting stands arranged in the width direction of each sintered pallet varies depending on the arrangement method of the stands in the pallet row. A five-sheet arrangement may be used. In short, any arrangement and arrangement that can support the sinter cake in a balanced manner with respect to the pallet arrangement, that is, an arrangement and arrangement that can support the sinter cake with substantially the same area may be used. If the number of stands for the pallet width is increased, the stand 1
Although the sinter cake supporting load per sheet is small, it is not preferable because of the unique use stability of the stand, the shape control in manufacturing, and the increase in interference with the related parts of the sintering machine. Use about one sheet as a guide.

The existing great bars are arranged in two or three rows with respect to each pallet, and are located in the front row as compared with the conventional sinter cake support stand which is arranged in the entire length in the sintering pallet traveling direction. That is, since the stand on the front side in the strand traveling direction has been removed, the sinter cake mining properties are extremely improved. In addition, since the layout of the sinter cake support stand follows the layout of the existing great bar, the size of the existing great bar is smaller when the stand is assembled than when it is integrated over the entire length of the conventional pallet in the pallet travel direction. And the effects of dimensional errors due to aging are eliminated.

[0027]

EXAMPLES Hereinafter, detailed explanation of the embodiments with reference to FIGS. The sintering step was the same as the conventional method shown in FIG. 5 , and the layer thickness was 600 mm.

[0028]

Embodiment 1 As an embodiment, a sinter cake support stand F made of a trapezoidal plate is shown in FIG . The stand height 1 from the existing great bar is 200 mm for the purpose of improving the ventilation of the lower sintering material layer of 1/3 of the thickness of the sintering material layer. The stand length is about 495 mm, which is similar to the length of existing great bars. Stand length 2 is about 345mm
The upper end of the stand is cut into a trapezoidal shape by cutting both ends in the length direction about 75 mm each, absorbing the difference in thermal expansion due to the temperature difference in the upper part of the stand, reducing the accumulated thermal strain, and reducing the occurrence of cracks due to thermal fatigue. Reduce and delay.

The width of the stand F is thinner at the upper part of 200 mm and thicker at the lower part, because of the sinter cake's mining properties, the upper part is 33 mm and the lower part is 40 mm. The longitudinal direction and the height direction of the mounting portion 4 for inserting the stand F into the pallet frame adopt a shape similar to the existing great bar. The width of the mounting part 4 is ｍ of the stand height 1 and 100 m
m, the width of the lower part 5 of the mounting part is 70 mm.

The productivity of the present sinter cake support stand has been improved to 31 to 42 t / d / m ^2, and the decrease in the operating rate of the sintering machine has been reduced to about 0.3% compared to about 3.5% of the conventional support stand. 5
As a result, the production volume increased by 3% compared to the conventional case.

[0031]

Embodiment 2 As an embodiment, FIG. 2 shows a sinter cake support stand G having a vertical slit-shaped opening from the upper side to the lower side. Number of apertures is 2 and height is 50m
m. The width is the smallest possible width of the machine finish, eg 1
0 mm is preferred. The provision of the slit-shaped opening portion absorbs the difference in thermal expansion due to the temperature difference in the upper part of the stand, reduces the accumulated thermal strain, and reduces and delays the occurrence of cracks due to thermal fatigue.

Since the decrease in the operation rate of the sintering machine could be reduced to about 0.5%, the production amount of the sinter increased by about 3%.

[0033]

Embodiment 3 As an embodiment, a sintered pallet 7 having a trapezoidal sinter cake support stand F ₁ , F ₂ , F ₃ is installed.
As shown in FIG . With respect to the pallet width of 3 m, the sinter cake support stands F ₁ and F ₃ are respectively arranged at positions of about 500 mm from the respective side walls 19, and the sinter cake support stand F ₂ is arranged substantially at the center of the pallet width, In the direction, it was installed only in the back row of the existing array of great bars. The area that supports the sinter cake per stand is exactly 1/3 of the area of the sintered pallet,
The support balance of the sinter cake is made uniform, and the sintering function can be stabilized. The sinter cake support stands F ₁ , F ₂ and F ₃ were set on all pallets.

The trapezoidal shape of the sinter cake support stands F _{1 to} F ₃ can absorb the difference in thermal expansion due to the temperature difference in the upper part of the stand, reduce the occurrence of thermal strain, reduce the occurrence of cracks due to thermal fatigue, and delay it. Therefore, the stand life was improved to 6 months or more compared to 0.5 months of the conventional sinter cake support stand. As a result, the amount of sinter production was improved by about 3%.

[0035]

Fourth Embodiment FIG. 4 shows a sinter cake support stand H having a trapezoidal shape and a vertical groove formed on the side surface of the stand in a zigzag manner with respect to both side surfaces, and having a corrugated cross section. The overall shape and dimensions of the sinter cake support stand H
It is similar to those of the sinter cake supporting stand F in FIG. This flute shape is semicircular, and the width of the flute is about 10 m
m, the depth of the flute is about 5 mm, and the length of the flute is about 160 mm from the top of the stand.

The corrugated sinter cake support stand H freely absorbs the difference in thermal expansion and contraction due to the temperature difference between the upper and lower portions of the stand, reduces the accumulated thermal distortion, reduces the generation of cracks, and delays.

With the sinter cake support stand H, the decrease in the operation rate of the sintering machine could be reduced by about 0.5%, so that the production amount of the sinter increased by about 3%.

[0038]

According to the present invention, by sintering the cake support stand positive trapezoidal plate, improves aeration and yield of the underlying sintered material layer, not only the productivity is improved, The service life of the stand can be extended as compared with the conventional case, the equipment cost can be reduced, and the stand replacement of the sintering machine can be reduced, so that the operation rate can be improved.

If the number of sinter cake supporting stands arranged in the width direction of the sintering pallet is larger than one or two conventional sinter cake supporting stands, unevenness of the sinter cake support balance can be eliminated, and ventilation of the lower sintering material layer can be achieved. And the yield is improved, which contributes to the improvement of productivity.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an embodiment of a sinter cake support stand of the present invention.

FIG. 2 is a perspective view showing an embodiment of the sinter cake support stand of the present invention.

FIG. 3 is a perspective view showing an embodiment of the sintered pallet of the present invention provided with a sinter cake support stand.

FIG. 4 is an embodiment of a sinter cake support stand according to the present invention .
FIG.

FIG. 5 is a view showing a conventional sinter production process.

FIG. 6 is a perspective view of a sintered pallet provided with a conventional support stand.

FIG. 7 is a perspective view of a sintered pallet provided with a conventional lattice stand.

[Explanation of symbols]

D support stand E grid-like stand F sinter cake supporting stand G sinter cake supporting stand H sinter cake supporting stand F _1, F _2, F ₃ sinter cake supporting stand 1 stand height 2 stand length 3 opening 4 mounting unit 5 Lower part of mounting part 7 Sintering pallet 8 Sintering compound raw material 9 Surge hopper 10 Drum feeder 11 Chute 12 Sintering raw material layer 13 Ignition furnace 14 Returning hopper 15 Coke hopper 16 Limestone hopper 17 Ore hopper 18 Mixer 19 Side wall

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Kunihiro Imada 20-1 Shintomi, Futtsu-shi, Chiba Nippon Steel Corporation Technology Development Division (72) Inventor Tadahiro Inazumi 20-1 Shintomi, Futtsu-shi, Chiba New Nippon Steel Corporation Technology Development Division (72) Inventor Masami Fujimoto 20-1 Shintomi, Futtsu City, Chiba Prefecture Nippon Steel Corporation Technology Development Division (72) Inventor Kazuyuki Kawano 20 Futtsu City, Futtsu City, Chiba Prefecture -1 Nippon Steel Corporation Technology Development Division (72) Inventor Toshiro Aso 20-1 Shintomi, Futtsu-shi, Chiba Prefecture Nippon Steel Corporation Technology Development Division (72) Inventor Shoichi Kusada Kita, Nishi-ku, Osaka-shi 1-12-19 Horie, Kurimoto Ironworks Co., Ltd. (72) Inventor Susumu Matsuno 1-12-19, Kitahorie, Nishi-ku, Osaka City, Kurimoto Ironworks Co., Ltd. (56) References JP-A-4-168234 (JP, A ) JP-A-6-147765 (JP, A) JP-A-6-129775 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) F27B 21/08

Claims (4)

(57) [Claims] Preparative to 1. A lower suction type sintering machine sintering pallets
In the sinter cake support stand arranged via the attachment portion , the height is 30 to 70% of the thickness of the sintering material layer, and the upper side length to the lower side of the pallet traveling direction cross section is 30 to 70%.
Ri a is Do a plate of positive trapezoidal%, and the width of the mounting portion scan
Stand sinter cake supporting stand to be from 1/2 and feature 1/3 der Rukoto of height. 2. The sinter cake support stand according to claim 1, wherein a vertical slit opening having an open upper end is provided at at least one side of the sinter cake support stand. 3. The sinter cake support stand according to claim 1, wherein the sinter cake support stand has vertical grooves formed on the side surface thereof in a zigzag manner with respect to both side surfaces so as to have a wavy cross section. 4. The sintering pallet according to claim 1, wherein a plurality of great bars on the sintering pallet are arranged at the rear of the sintering pallet in the direction of travel of the sintering pallet and perpendicular to the direction of travel of the sintering pallet. a mounting portion of the sinter cake supporting stand
A sintering pallet, wherein 1 to 5 sheets are installed through the pallet.