KR20180030596A - Method for producing sintered ore - Google Patents

Abstract

Provided is a method for producing sintered ores by which appropriate pseudo-particles can be assembled and productivity in a sintering machine can be improved when using fine iron ore as a blending raw material for producing sintered ores.
A method for producing sintered ores by sintering a raw material for sinter by sintering the sintered material after sintering the sintered material, the method comprising the steps of preliminarily treating the sintered material containing 10 to 50 mass% of fine iron ores with a size of 125 μm or less with a high- Assembly is done by the device.

Description

[0001] METHOD FOR PRODUCING SINTERED ORE [0002]

The present invention relates to a method for producing sintered ores as a blast furnace raw material, which is produced by using a DL sintering machine or the like after granulating the raw materials for sintering.

The sintered ores are sintered with additives such as limestone, quartz, and serpentine, and dusts, such as limestone, silica sand, and the like, to a plurality of brands of powdered iron ores (generally called sinter feeds of about 125 to 1000 mu m) Mixing and granulating a sintering blend material obtained by blending an appropriate amount of a blend of raw materials such as scales, return ore and an appropriate amount of solid fuels such as fractional cokes, charging the resulting blend into a sintering unit, and firing . The sintering compounding materials generally contain moisture, so that they aggregate to form quasi-particles when assembled. This pseudo-granular raw material for sintering helps to secure a good ventilation of the raw material loading layer when the raw material is loaded on a pallet of the sintering machine, thereby facilitating the sintering reaction smoothly.

However, iron ore for sintering has recently been made inferior due to depletion of high-quality iron ore. In other words, the lowering of the iron ore causes a tendency of an increase in slag component and a decrease in particle size, which leads to an increase in the alumina content and a deterioration in the assemblability due to the increase in the fraction of the differentiation. On the other hand, sintered ores used in blast furnaces are required to have low slag ratios, high reducibility and high strength in view of reducing the cost of producing molten iron in the blast furnace and reducing the amount of CO ₂ generated.

Among these environments surrounding the iron ores for sintering, there has recently been proposed a technique for producing high-quality sintered ores by using fine iron ore which has been used for pellets called pellet feeds . For example, there is Hybrid Pelletized Sinter method (hereinafter referred to as " HPS method ") as one of such conventional techniques. This technique is to produce a sintered ore having a low slag ratio and a high refractivity by assembling a sintering blend material containing a large amount of fine iron ore such as a pellet feed using a drum mixer and a pelletizer (Patent Document 1 Document 2, Patent Document 3, Patent Document 4, Patent Document 5).

In addition, there is a method (refer to Patent Document 6) that mixes humidity control with a high-speed rotary mixer before the sintering raw material powder assembling process, or a method of preliminarily mixing fine iron ores and iron dust with a stirring mixer (Patent Document 8), a method of preliminarily mixing a fine powder (pellet feed) with an Eirich mixer and then assembling it with a drum mixer (patent document 8), a method of mixing iron ore raw material containing not less than 60% , And then assembling with a drum mixer (Patent Document 9).

Japanese Patent Publication No. 2-4658 Japanese Patent Publication No. Hei 6-21297 Japanese Patent Publication No. Hei 6-21298 Japanese Patent Publication No. Hei 6-21299 Japanese Patent Publication No. Hei 6-60358 Japanese Patent Application Laid-Open No. 60-52534 Japanese Unexamined Patent Publication No. 1-312036 Japanese Laid-Open Patent Publication No. 7-331342 Japanese Patent Application Laid-Open No. 2001-247020

However, sintering blend materials containing a large amount of fine iron ores, particularly ultrafine iron ores, such as pellet feeds, can be obtained by assembling them using the HPS method described in the above Patent Documents 1 to 5, , There is the following problem in the method of preliminarily mixing using a high-speed stirrer or the like as described in JP-A-

That is, as shown in Fig. 1, in these methods, not only fine particles (less than 0.5 mm) but also coarse particles (more than 10 mm) are generated. The reason is that, if the wettability is the same, the fine iron ores such as the pellet feed are easy to absorb moisture because they have a large specific surface area as fine as the fine particles, and are easy to maintain a large amount of water between the powders, It is easy to absorb the above. As a result, coarse pseudo-particles in which the particle size is uneven in the form in which the fine particles are attached to the periphery of the nuclear particles are likely to be generated, but the aggregates are merely aggregated. Further, in these methods, there is also a problem that adhesion of powder, uniform distribution of fine powder and water is poor, and the operation rate of the equipment is lowered.

This point is also evident from the following experiments conducted by the inventors. First, in this experiment, granulation is carried out by using a blending raw material containing an irregularly granulated iron ore (vanadium content: 40 mass%) such as pellet feed. At this time, the particle size distribution of the produced granulated particles And the particle size distribution was measured. The results are shown in Fig. First, as shown in Fig. 2 (a), a large proportion of the pellet feed in the sintering and blending raw material has a higher ratio of coarse particles (more than 8 mm) compared to the case of not including the pellet feed. The weight ratio reached about 75% by mass. In addition, the particle size distribution of the pellet feed (FIG. 2 (b)) in the granulated pseudo-particles showed the same tendency as the particle size distribution of the granulated particles (FIG. 2 (a)). That is, it was found that the pellet feed in the coarse particle was as high as about 80 mass%, and most of the pellet feed was localized during the assembly. From this, it can be seen that coarse pseudo-particles are formed by the pellet feeds coalescing with each other. It was also found that the pseudoparticle belonging to the assembly region also had a high water content (Fig. 2 (b)). From this, water is preferentially absorbed by the pellet feed, which causes the pellet feeds to cohere with each other to form coarse pseudo-particles. As a result, much moisture is absorbed in the coarse pseudo-particles.

As described above, when the compounding raw material containing a large amount of fine iron ore such as a pellet feed and the like is assembled, the particle diameters become uneven in any case, and the fine particles are merely agglomerated to each other to produce coarse pseudo-particles with weak bonding strength It becomes easier to do. Therefore, when such similar particles are deposited on the pallet of the sintering machine and deposited, as shown in Fig. 3 (a), the sintering raw material loading layer becomes a dense deposited structure and the bulk density becomes large. Further, when such coarse pseudo-particles are deposited on the pallet of the sintering machine at a constant layer thickness, they become fragile when load (compressive force) is applied to the pseudo-particles, Which causes deterioration of the air permeability, which is an obstacle to the operation of the sintering machine. As a result, the sintering time is prolonged, and the yield of the sintered ores is lowered, thereby lowering the productivity. Further, it is necessary to increase the amount of the quicklime used as the binder used in the assembly, which leads to an increase in the cost of producing the sintered ores. In the case where the solid fuel such as the partial coke is coated in the subsequent step, And the like. As a result, burning or heat generation is caused and the burning speed is lowered.

It is an object of the present invention to propose a method for producing an sintered ore which can improve the productivity in a sintering machine by assembling the appropriate pseudo-particles when the fine iron ore is used as a blending raw material for producing sintered ores.

As a result of intensive studies on the problems of the prior art described above, the inventors have found that by pre-treating a raw material for sinter having a predetermined amount of fine particles having a predetermined particle size with a high-speed agitating device, It is possible to prevent coarse granulated particles (pseudo-particles) which are uneven and weak in bonding strength from being generated and to assemble appropriate pseudo-particles to improve the productivity in the sintering machine.

That is, the present invention relates to a method for producing sintered ores by sintering a raw material for sinter after sintering the sintered material by sintering to obtain a sintered ores having a sintering temperature of not more than 125 탆, And assembling is carried out by an assembling apparatus.

Further, in the method of manufacturing the sintered ores according to the present invention constituted as described above,

(1) When the stirring time t (sec) by the high-speed stirring device is compared with the circumferential velocity U (㎧) of the blades of the high-speed stirring device, the condition of 300 <U × t <2000 is satisfied To perform pre-processing such that,

(2) When the peripheral speed U (占) of the blades of the high-speed agitating device is set to the agitation time t (sec) by the high-speed agitator, pre-processing is performed so as to satisfy the condition of 400 <U × t <1200 ,

(3) The assembling apparatus may be a drum mixer and / or a disk pelletizer,

(4) In assembling the above-described assembling apparatus, it is preferable to coat the treated raw material with limestone and coat the surface of the assembled particle with a high-

(5) The raw material for sinter includes at least one kind of crystal water ore, and the content of crystal water is 4 mass% or more,

(6) The iron ore fine of 125 占 퐉 or less contains limestone in an amount of 5% by mass or more,

(7) The sintering raw material to be treated with the high-speed stirrer may contain not more than 3 mass% of slaked lime or quick lime in addition to the lime content to be coated,

(8) In the sintering raw material used for the high-speed agitator, when the proportion of the fine iron ore is 30 mass% or more, the raw material is subjected to a drying treatment

Is considered to be a more preferable solution.

The present invention relates to a method for producing an assembling raw material for sinter which is composed of pseudo-iron ores and coarsely agglomerated fine grains or pseudo-particles having a relatively small particle size and a small particle size distribution, It suggests. When the raw material for sintering obtained by this method is loaded on the pallet of the sintering machine, it is possible to reduce the density of the sintering raw material loading layer formed on the pallet and to shorten the sintering time accompanied by improvement in air permeability And is further effective in improving the productivity of high-quality sintered ores.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a comparative graph of the particle size distribution of pseudo-particles in the presence or absence of a fine iron ore blend. Fig.
Fig. 2 is a graph showing the distribution of pellet feed and the distribution of moisture per pore size of pseudo (assembled) particles.
3 is a comparative diagram of a conventional granulated particle deposition layer (a) and an assembled particle deposition layer (b) of the present invention.
4 is a view for explaining an example of a facility line for carrying out the method of manufacturing the sintered ores according to the present invention.
Fig. 5 is a diagram for explaining a facility line used for examining the effect of pretreatment before assembly. Fig.
6 is a graph showing the relationship between the harmonic mean diameter and the additional mixing time.
7 is a graph showing the relationship between the particle size distribution function and the additional mixing time.
8 is a graph showing the relationship between the relative passing air amount and the additional mixing time.
9 is a graph showing the relationship between the production rate and (U x t) when the peripheral speed U is fixed under the condition of U = 9 kPa and the stirring time t is changed in the range of t = 0 to 240 seconds.
10 is a graph showing the relationship between the production rate and (U x t) when the stirring time t is fixed under the condition of t = 120 seconds and the peripheral speed U is changed to a range of U = 0 to 18 kPa.
11 is a graph showing the relationship between the production rate and (U x t) when the peripheral speed U is fixed under the condition of U = 9 kPa and the stirring time t is changed in the range of t = 0 to 240 seconds.
Fig. 12 is a graph showing the scattering state represented by the relationship between (U x t) and the production rate in the case of U &lt; 8 mu and U &amp;ge; 8 mu.

(Mode for carrying out the invention)

&Lt; Pre-processing before assembly, which is a feature of the present invention >

Fig. 4 is a view for explaining an example of a facility line for carrying out the method for producing the sintered ores according to the present invention. Fig. A method for producing the sintered ores according to the present invention will be described with reference to Fig. 4. First, a raw material for sinter 11 containing 10 to 50 mass% of fine iron ores of 125 占 퐉 or less is prepared. The sintering raw material 11 is a mixture of the above-mentioned fine iron ores of 10 to 50 mass% of pellet feed or tailing ore of 125 탆 or less and the remaining iron ores of sintered iron, It is preferable that it is made of other raw materials. In the present invention, the reasons for limiting the content of fine iron ores of 125 占 퐉 or less to 10 to 50 mass% as the sintering raw material (11) are as follows.

That is, the inventive range of the above-mentioned fine iron ore is set because the coarse particles having uneven grain size and weak bonding strength are formed, and when less than 10%, pseudo-particles having weak bonding strength are not generated. There is a problem that coarse particles with weak strength are generated. However, the amount of the fine iron ores of 125 占 퐉 or less is not more than 50% by mass and the upper limit is set to 50%. The reason for setting the particle diameter to 125 탆 or less is that since the adhesion force showing the adhesiveness between the particle layers in the powdery filler layer to which water is added increases at a particle diameter of 125 탆 or less, 125 [micro] m was set as a section of particle size.

Next, pre-treatment of the prepared raw material for sinter 11 is carried out in the high-speed stirrer 12. The purpose of the high-speed agitator 12 is to crush aggregates of fine particles which cause coarse granulated particles before assembling, to crush the coarse granulated particles in order to suppress generation of coarse granulated particles. In order to break down the aggregates of the fine particles efficiently, it is effective to apply the shear force to the aggregate itself and remove the fine particles directly. As an example of the high-speed stirrer 12, there may be used, for example, an Irihi mixer (manufactured by Nippon Airi KK), a Pellegaia mixer (manufactured by Kitagawa Tecco), a Proshear mixer . Among them, the IRISH mixer is known as a &quot; high-speed stirring assembly &quot;, and is a facility that has an assembling function accompanied by agglomeration and growth of particles by liquid cross-linking.

Next, the sintering raw material 11, which has been preliminarily processed by the high-speed mixer 12, is agitated and mixed by the drum mixer 13 under water addition. The sintered raw material 11 after the assembly is supplied to the sintering machine 14 and becomes sintered body in the sintering machine 14. Then, the sintered ores are supplied to the blast furnace 15 as blast furnace raw materials together with coke, limestone and the like to produce pig iron.

In order to investigate the influence of pretreatment before the assembly, which is a feature of the present invention, the same sintered raw material containing 30 mass% of fine iron ores of 125 占 퐉 was mixed with a high-speed stirring mixer (Irihi mixer) Pre-processing before assembly was carried out by a drum mixer. The mixing time by each mixer was varied from 0 to 160 seconds, and the grain size distribution was obtained for the sintered raw material after the preliminary treatment and the assembly was carried out for 160 seconds by the drum mixer. Based on this, Is and Ip 6, 7 and 8 show the coarsening average diameter Dp (mm), the particle size distribution function (Isp), and the relative passing air volume of the packed bed before sintering. Also, in any of the examples, the prior art example in which the drum mixer preprocesses is 0 seconds is a conventional example. By using the high-speed stirring mixer, the harmonic mean diameter increased, and the effect that the particle size distribution due to the particle size distribution function Isp was sharpened was obtained. An increase effect was also obtained for the relative passing air amount. Here, the larger the relative passing air flow rate, the larger the gas amount in the sintering machine operating at a constant negative pressure, and the productivity is improved.

Dp = 1 /? (Wi / di)

Isp = 100 (Is Ip)

Is = Dp ^2? Wi (1 / di-1 / Dp) ²

Ip = (1 / Dp) ^2? Wi (di-Dp) ²

From here,

Dp: Harmonic mean diameter (mm)

wi: Weight presence rate in the interval (-)

di: Representative average diameter of section (mm)

Isp: Particle size distribution function

Is: Particle size distribution function in fine grains (-)

Ip: Particle size distribution function in assembly (-)

6, 7, and 8 show that the pre-processing before the assembly was carried out with a high-speed mixer, compared with the conventional example in which the pre-processing was not performed and the comparative example in which the pre- (Fig. 6), a lower particle size distribution function (Fig. 7), and a higher relative passing air volume (Fig. 8) of the pre-sintered packed bed can be obtained and a sintered material of good quality can be obtained .

<Regarding suitable operating conditions of the high-speed stirrer>

In order to investigate suitable operating conditions of the high-speed stirrer in the method of producing the sintered ores according to the present invention, the same sintering raw material containing 30 mass% of fine iron ores of 125 탆 in diameter was subjected to a high- ) And stirring time t (seconds). An example of fixing the circumferential speed U under the condition of U = 9 占 and changing the stirring time t in the range of t = 0 to 240 seconds and the example of fixing the stirring time t under the condition of t = 120 seconds and setting the circumferential speed U to U = For example of changing to the range of ㎧ and fixing the circumferential speed U under the condition of U = 6 하고 and changing the agitation time in the range of 0 to 240 seconds, the production rate of the sintered ores obtained by sintering after sintering is obtained U × t).

Here, it is possible to prevent coarse granulated particles (pseudo particles) having uneven particle diameters and weak bonding strength from being generated, and as a condition capable of assembling the proper pseudo-particles, U x t obtained by multiplying the peripheral velocity U by the stirring time t . As a dimension of U x t, a physical quantity having a dimension of length "m" has a physical quantity. Since it is considered to be a moving distance given by a blade rotating at high speed, it is thought that it can be sorted by different peripheral speed and stirring time. In the high-speed agitator, since the raw material injected from the upper portion flows downward, the stirring time changes when the occupancy rate of the raw material in the apparatus is constant and when the feeding rate is changed. At this time, it can be seen that a stable quality sintered body can be manufactured by defining an appropriate range U x t.

The relation between the production rate (t / hr / m 2) and (U x t) when the peripheral speed U is fixed under the condition of U = 9 하고 and the stirring time t is changed in the range of t = 0 to 240 sec is shown in Fig. 1, the relation between the production rate (t / hr / m 2) and (U x t) when the stirring time t is fixed under the condition of t = 120 seconds and the peripheral speed U is changed to the range of U = (T / hr / m 2) and (U x t) when the peripheral speed U was fixed under the condition of U = 6 psi and the stirring time t was changed in the range of t = 0 to 240 seconds The relationship is shown in Fig. 11 and Table 3 below.

From the results of Figs. 9 to 11 (based on the data of Tables 1 to 3), the relationship between (U x t) and the production rate is obtained for two conditions of U &lt; 8 psi and U 8 psi, As a scatter plot. From the results shown in Fig. 12, it is preferable to perform pretreatment with a high-speed stirrer so as to satisfy the condition of U x t satisfying the condition of 300 &lt; U x t &lt; 2000, It is more preferable to perform pretreatment with a high-speed stirrer so as to satisfy the condition of 1200. In any of the examples, it can be seen that the range of U x t can be generalized as a suitable example for various examples of the peripheral speed and stirring time of the high-speed stirrer, in that the range of the U x t is almost the same.

From the results shown in Fig. 9, it can be understood that when the peripheral speed U of the rotating blades of the high-speed agitating device is 9 (㎧) in the pretreatment of the sintering raw material performed in the high- Sec or more is preferable. It is also understood from the results of Fig. 10 that it is preferable to set the peripheral velocity U (占 6) of the rotating blades of the high-speed agitator to 6? U? 12 when the agitation time of the high-speed agitator is 120 seconds. Furthermore, from the results shown in Fig. 11, it can be seen from the results of Fig. 11 that when the peripheral speed U of the blade rotating at high speed in the high-speed agitating device is 6 (㎧) in the pretreatment of the raw material for sintering performed by the high- 60 seconds or more is preferable.

<Other suitable operating conditions>

In the method of manufacturing the sintered ores according to the present invention, a disk pelletizer alone or in combination with a drum mixer may be used in addition to the drum mixer as the assembling device in the above-described embodiments.

Further, in assembling the assembling apparatus, it is preferable that the treated raw material is coated with limestone, and the outer surface of the assembled particles is covered with a high-system fuel. It is preferable that the casing is made of an outer casing. The outer casing is made of an outer casing made of calcium ferrite having a high strength on the surface thereof. The casing is adhered to the surface of the casing because of hydrophobicity, To increase productivity.

As the raw material for the sintering, it is preferable to use at least one kind of material containing crystal water ore and having a crystal water content of 4 mass% or more. The reason why the content of the crystal water is preferably 4 mass% or more is because the ore having a high crystal number has a high specific surface area and can improve the granularity of the ore. Furthermore, it is preferable that the fine iron ores of 125 占 퐉 or less contain limestone in an amount of 5% by mass or more. It is preferable that the limestone is contained in an amount of 5 mass% or more. By including the fine limestone, the mixing property of the fine ore and the limestone can be improved and the sintering reaction can be promoted.

In addition to the limestone content to be coated, it is preferable to add 3 mass% or less of slaked lime or quicklime to the sintering raw material to be treated with the high-speed stirrer. The reason why it is preferable to add calcium hydroxide or calcium oxide by 3 mass% or less is that the addition of calcium hydroxide or calcium oxide can improve the crushing strength of the granulated particles and improve the air permeability in the sintered raw material filled layer. In the sintering raw material used for the high-speed agitator, when the proportion of the fine iron ore is 30 mass% or more, it is preferable to dry-treat the raw material for sinter. The reason why it is preferable to perform the drying treatment at 30 mass% or more is that the latent heat for evaporating moisture in the sintering process is required, and it is possible to reduce the carbonaceous materials such as minute coke required by drying in advance.

(Industrial availability)

According to the method of producing the sintered ores of the present invention, it is possible to produce high-quality sintered ores with high productivity using various sintering machines, and it is possible to perform high-productivity blast furnace operation by using the sintered ores obtained in the present invention as the blast furnace raw material It becomes.

Claims (9)

A method for producing sintered ores by sintering a raw material for sinter by sintering with a sintering machine, comprising the steps of pre-treating the sintered material containing 10 to 50 mass% of fine iron ores having a size of 125 μm or less with a high- Wherein the sintered ores are formed by sintering. The method according to claim 1,
Wherein when the stirring time t (sec) by the high-speed stirring device is set to the circumferential velocity U (㎧) of the wing of the high-speed stirring device, Wherein the sintering treatment is carried out at a temperature higher than the melting point. 3. The method of claim 2,
The pretreatment is carried out so as to satisfy the condition of 400 &lt; U x t &lt; 1200 when the peripheral speed U (의) of the blades of the high-speed agitator is set to the agitation time t Wherein the method comprises the steps of: 4. The method according to any one of claims 1 to 3,
Wherein the assembling device is a drum mixer and / or a disk pelletizer. 5. The method according to any one of claims 1 to 4,
Wherein the granulated material is coated with limestone and the surface of the granulated particles is coated with a high-system fuel in the assembly of the granulating device. 6. The method according to any one of claims 1 to 5,
Wherein at least one kind of the raw material for sinter contains crystal ore and the content of crystal water is 4 mass% or more. 7. The method according to any one of claims 1 to 6,
And the limestone is contained in an amount of not less than 5 mass% in the fine iron ores of not more than 125 占 퐉. 8. The method according to any one of claims 1 to 7,
Wherein the sintering raw material to be treated with the high-speed stirrer is added with not more than 3 mass% of slaked lime or burnt lime in addition to the lime content to be coated. 9. The method according to any one of claims 1 to 8,
Wherein the raw material is subjected to a drying treatment when the proportion of the fine iron ore in the raw material for sinter used in the high-speed stirrer is 30 mass% or more.

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