JP2017048419A - Method for producing kneaded matter made of ore and dust and method for producing briquette using the method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for producing a briquette having high strength and not easily cracked when being charged to a rotary drier or a rotary kiln.SOLUTION: Provided is a method for producing a kneaded matter produced by kneading dust included in an exhaust gas exhausted from a rotary drier 1 or a rotary kiln 3 for refining nickel oxide ore and nickel oxide ore with a grain size of 10 mm or lower by a kneading machine 9 provided with a stirring blade, in which, on the basis of the content of a specified substance obtained by analyzing the kneaded matter, a mixing ratio between the dust and the nickel oxide ore is calculated, and, when this mixing ratio is deviated from the prescribed value, the rotation number of the stirring blade of the kneading machine 9 is reduced.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a method for producing a kneaded material composed of ore and dust, and a method for producing briquettes using the method, and in particular to ore in dust generated when nickel oxide ore is dried and reduced in a rotary kiln in a ferronickel smelting process. The present invention relates to a method for producing a kneaded product obtained by kneading and a method for producing a briquette using the method.

  In a method for producing ferronickel, which is an alloy of iron and nickel, laterite ore such as saporolite ore containing nickel (a typical nickel oxide ore, hereinafter also simply referred to as ore) is used as a raw material. On the other hand, a dry smelting method in which a series of treatments including a drying step, a firing step, a melt reduction step, a purification step and the like are performed to produce ferronickel is generally employed.

  In this dry smelting method, raw ore is first charged in a rotary dryer in a drying step, and the ore (about 25 to 35% by mass) is reduced to about 15 to 25% by mass and the dried ore ( Hereinafter, this is also referred to as dry ore). Next, in the firing step, the dry ore is charged together with coal such as anthracite from the charging end of the rotary kiln. A burner is provided at the discharge end of the rotary kiln, and the combustion gas generated here is passed through the rotary kiln to heat the coal and heat the dried ore to about 800-1000 ° C. As a result, complete removal of residual adhering water, decomposition and removal of crystal moisture, and reduction treatment of a portion of the dried ore are performed, and the dried or reduced ore (hereinafter also referred to as calcined ore) obtain.

  Next, in the melt reduction process, the above-mentioned burned ore is charged into an electric furnace, and here, the burned ore is melt-reduced. Thus, ferronickel metal (hereinafter simply referred to as metal) and ferronickel slag (hereinafter simply referred to as slag) containing nickel and iron are generated. Impurities such as sulfur are removed from the obtained metal in the refining process to produce ferronickel products. On the other hand, slag is granulated with high pressure water and then used as fine aggregate for concrete, civil engineering materials, etc. Is done.

  The above-described rotary dryer or rotary kiln that performs drying or reduction has a structure that is rotatably supported by a cylindrical body, and is provided with a plurality of wing-like protrusions inside thereof. The cylindrical body has a central axis of rotation slightly inclined from the horizontal direction, and as a result, the ore charged from one end of the cylindrical body is lifted by the wing-like projections by the rotation of the cylindrical body. The operation of dropping is gradually moved toward the other end while being continuously repeated, and during that time, a process such as drying is performed by the combustion gas. During this treatment, dust derived from ore and the like is generated. This dust is discharged together with the exhaust gas discharged from the rotary dryer or rotary kiln, and is collected by an exhaust gas treatment facility attached to the rotary dryer or rotary kiln.

  Dust discharged from rotary dryers and rotary kilns is mainly composed of fine powder generated from ore and coal, but the dust recovered from exhaust gas treatment facilities contains the same amount of nickel as ore, so it can be reused as a raw material for ferronickel. Used. When reusing dust, the dust may be charged directly into a rotary kiln, etc., but generally kneaded with a kneader or the like, then granulated with a pelletizer, etc. and dried to form pellets or briquettes After that, it is done to repeat to a rotary dryer or rotary kiln.

  For example, in Patent Document 1, when a briquette is produced from pulverized coal, a nozzle that adds a binder in accordance with an increase or decrease in the supply amount of pulverized coal while keeping the rotation speed of a stirring blade constant in a kneader before forming the briquette A technique for changing the position of the is disclosed. Since the technique of Patent Document 1 is based on the premise that a binder is added, it cannot be applied to a briquette manufacturing method in which a binder is not added.

JP 2011-136256 A

  The dust generated by the above ferronickel smelting is generally low in wettability because it is derived from fine coal powder or calcined ore charged in the rotary kiln, and the kneading state is not affected even when water is added during kneading. It tends to be uniform. For this reason, when the obtained kneaded product is granulated with a pelletizer or the like, it has been a problem that a granulated product with low strength is produced. Specifically, a granulated product produced using a kneaded product having a non-homogeneous kneaded state may have a crushing strength of less than 10 kgf / p as measured according to JIS Z 8841.

  As described above, when the granulated product having a strength of less than 10 kgf / p is charged into a rotary dryer or rotary kiln, the strength is low while it is being lifted or dropped together with the ore by the wing-like projections described above. As a result, it was quickly crushed, re-scattered as dust, and discharged again with exhaust gas. Therefore, there has been a demand for a method for producing a granulated product having a uniform kneaded state and having a strength of, for example, 10 kgf / p or more which is not easily crushed when charged in a rotary dryer or rotary kiln.

  The present invention has been made in view of the above-described conventional problems, and was charged into the rotary dryer or rotary kiln using dust generated in the rotary dryer or rotary kiln used in the drying step and firing step of nickel oxide ore. The aim is to produce briquettes with high strength that sometimes do not break easily.

  In order to achieve the above object, a method for producing a kneaded product according to the present invention includes a stirring blade for dust contained in exhaust gas discharged from a nickel oxide ore smelting step and nickel oxide ore having a particle size of 10 mm or less. A method for producing a kneaded material prepared by kneading with a kneader, wherein the mixing ratio of the dust and the nickel oxide ore is calculated based on the content of a specific substance obtained by analyzing the kneaded material Then, when the mixing ratio deviates from a predetermined value, the rotation speed of the stirring blade is lowered.

  According to the present invention, it is possible to produce a kneaded material that is homogeneously kneaded from dust collected in a treatment facility for exhaust gas discharged from a rotary dryer or rotary kiln that performs drying or firing of nickel oxide ore. By forming the briquette, it is possible to obtain a briquette having a high strength that is not easily broken when inserted into a rotary dryer or rotary kiln.

It is a flowchart which shows one specific example of the ferronickel smelting plant to which the manufacturing method of the kneaded material which concerns on this invention is applied suitably. It is process drawing which shows one specific example of the manufacturing method of the kneaded material which concerns on this invention. It is the graph which plotted the crushing intensity | strength of the briquette sample produced in the Example, taking the electric current value of a kneader on a horizontal axis. It is the graph which plotted the current value of the kneading machine on the horizontal axis for the +10 mm yield of the briquette sample produced in the example.

  Hereinafter, a specific example of the briquette manufacturing method according to the present invention will be described with reference to FIG. 1 taking as an example the case of using dust and nickel oxide ore as raw materials for briquette manufacturing. In the smelting of ferronickel, a nickel oxide ore prepared by blending a plurality of laterite ores so as to have a predetermined composition is generally used as a raw material. The prepared nickel oxide ore is first charged into the rotary dryer 1, where the adhering moisture is reduced until the water content becomes about 15 to 25% by mass, and becomes a dry ore.

  The obtained dry ore is discharged from the discharge end of the rotary dryer 1 and then put into the sieving means 2 having an opening of about 10 to 50 mm. Here, after the large-sized ore on the sieve is removed, the rotary kiln 3 is charged together with, for example, a powdery nickel compound and coal such as anthracite as a reducing agent. The dried ore is further dried in the rotary kiln 3 and then partially reduced to a calcined ore. The obtained sinter is discharged from the discharge end of the rotary kiln 3 and then sent to the electric furnace 4 where it is melted and reduced to produce metal and slag containing nickel and iron.

  The rotary dryer 1 and the rotary kiln 3 are provided with the exhaust gas treatment facilities 5 and 6, respectively. The dust generated in the rotary dryer 1 and the rotary kiln 3 is discharged together with the exhaust gas and is discharged by the exhaust gas treatment facilities 5 and 6. Each is collected. The collected dust is sent to the dust tank 7 and temporarily stored, then cut out by the quantitative feeder 7a provided at the lower part thereof, and charged into a subsequent mixer 8 such as a pug mill type.

  The dust charged in the mixer 8 is mixed while water is added so that the water content is about 15 to 30% by mass. The dust whose moisture content has been adjusted by the mixer 8 (hereinafter referred to as humidity control dust) is further kneaded using a kneader 9 such as a Dow mixer to be formed into a kneaded product, and then the briquette machine 10 Supplied. Thereby, the briquette which has a predetermined shape is produced. This briquette is supplied to the rotary kiln 3 as a raw material for ferronickel.

  By the way, since the above-mentioned dust is mainly generated in the rotary kiln 3, this dust includes fine powder of dry ore from which the adhering water has been removed from the nickel oxide ore as a raw material, fine powder of burned ore from which crystal water has been partially removed. , And fine powder of coal as a reducing agent. In this way, the dust tends to have low wettability because it contains coal and sinter, and briquettes obtained by compression molding only dust with adjusted moisture content as described above have poor granulation strength. In some cases it was enough.

  Therefore, in one specific example of the method for producing briquettes according to the present invention, nickel oxide ore having a particle size of 10 mm or less obtained by sieving with a sieving means having an opening of 10 mm is supplied to a kneader and kneaded with the humidity control dust described above. Thus, a viscous and homogeneous kneaded material suitable for forming a briquette having a high strength is produced. Hereinafter, a method for producing such a kneaded product will be specifically described with reference to FIG.

  As described above, the dust generated in the rotary dryer 1 and the rotary kiln 3 is collected in the exhaust gas treatment facilities 5 and 6 and then temporarily stored in the dust tank 7 (S1). The dust in the dust tank 7 is cut out at a substantially constant flow rate by a rotary valve 7a provided at the lower part of the dust tank 7 (S2). The dust cut out from the rotary valve 7a is put into a screw conveyor (not shown) and conveyed in a substantially horizontal direction (S3), and then supplied to the pug mill type mixer 8. The pug mill mixer 8 is supplied with water from a pipe having a valve whose flow rate can be adjusted, and is adjusted to a moisture content of 15 to 30% by mass while mixing with a stirring blade. (S4).

  The conditioned dust is discharged from the pug mill type mixer 8, then put on a dust belt conveyor (not shown) and conveyed substantially horizontally (S 5), and then supplied to the kneader 9. On the other hand, a portion of the dry ore obtained by the rotary dryer 1 is extracted and sieved by a sieving means having a mesh opening size of 10 mm (not shown), and a dry ore having a particle size of 10 mm or less (hereinafter also referred to as powdered ore) Is obtained (S6). The fine ore is conveyed to a kneading machine 9 after being conveyed by a fine ore belt conveyor (not shown) (S7). As a result, the conditioned dust and powder ore are kneaded (S8).

  Since the fine ore contains a large amount of silicate mineral having very high wettability, it is hardened even if no solvent is added as a binder when compression molding is performed by a briquette molding machine described later by mixing with dust in the kneader 9. Tighten up. As a result, the briquette produced by the briquette molding machine has extremely high strength without being forced to dry.

  The amount of the fine ore supplied to the kneader 9 is preferably adjusted so that the fine ore is contained in an amount exceeding 0 parts by weight and not more than 40 parts by weight with respect to 100 parts by weight of the kneaded material after being kneaded on a dry basis. It is more preferable to adjust the supply amount so that it is contained in the range of from mass parts to 38 mass parts. Even if a minute amount of fine ore is added, the effect appears, but naturally the effect of increasing the strength of the briquette cannot be obtained at 0 parts by mass. On the other hand, if adding more than 40 parts by mass, the amount of powdered ore added to the amount of dust recovered will be too large, so the amount of briquette produced will be too large, This leads to an increase in capital investment.

  The dust and powder ore conditioned as described above are repeatedly bonded to each other and broken into coarse lumps by the action of shearing, rolling, and compaction caused by the rotation of the stirring blade in the kneader 9. The production of a sticky kneaded product is promoted. The obtained kneaded material is discharged from the discharge section of the kneader 9 and then conveyed by a kneaded material belt conveyor (not shown) (S9) and temporarily stored in a kneaded material hopper (not shown) (S10). Then, it is extracted from the bottom of the kneaded product hopper, and is supplied to the briquette machine 10 by a kneaded product belt feeder (not shown) (S11), and is molded into a predetermined shape by the briquette machine 10 (S12). The kneading machine 9 is preferably kneaded with at least biaxial stirring blades, and more preferably a horizontal biaxial kneading machine capable of kneading relatively uniformly.

  The kneaded material discharged from the kneading machine 9 was sampled at least when the addition ratio of the humidity-controlling dust and the nickel oxide ore was changed, and this was analyzed to obtain the content of a specific substance. The mixing ratio of dust and nickel oxide ore is calculated based on the content of a specific substance. When the calculated mixing ratio deviates from the predetermined ratio, the rotational speed of the stirring blade is decreased. Thereby, since the residence time in the kneader 9 can be lengthened, a kneaded material kneaded more uniformly can be obtained. As a result, briquettes having a crushing strength of 10 kgf / p or more and a briquette size + 10 mm yield of 80% or more can be stably produced. In addition, as for the sampling position, one point may be collected from the discharge part of the kneader 9, or two or more points may be collected.

  Generally, when the mixing is insufficient, the rotation speed of the stirring blade is increased. However, in the above-described method for producing a kneaded material, a silicate mineral that is a kind of clay mineral contained in fine ore Is used in place of the binder, and when the number of revolutions of the stirring blade is increased, the kneaded product is simply broken into pieces. Therefore, the rotational speed of the stirring blade is lowered, and the dust and the powdered ore are gradually mixed so that the viscosity of the kneaded material increases under the influence of the clay mineral. That is, it is possible to mix dust while increasing the viscosity of the clay mineral by lowering the rotation speed of the stirring blade and mixing it slowly, so that a kneaded material in which the powder mineral and dust are sufficiently mixed can be obtained. it can.

  The specific substance that is the basis for calculating the mixing ratio of the dust and the nickel oxide ore is preferably the carbon content contained in the kneaded product. The reason why the carbon content is preferable is that the nickel oxide ore used as a raw material in ferronickel smelting contains only about 1% by mass of carbon, whereas the dust discharged along with the exhaust gas includes a rotary dryer and This is because pulverized coal and fine coal powder added as a reducing agent in the rotary kiln contain about 3 to 8% by mass.

That is, when the dust containing 3 to 8% by mass of carbon and the nickel oxide ore containing about 1% by mass of carbon are supplied to the kneader 9, the kneading state in the kneader 9 is This is because if it is non-uniform, significant variation will occur in the carbon content contained in the kneaded product obtained in the discharge section. The carbon content of the dust supplied to the kneader 9 is preferably sampled and measured periodically, so that the mixing ratio can be accurately calculated. Depending on the composition of the ore, Ni, MgO, SiO ₂ or the like can be a specific substance.

  In the above-described method for producing a kneaded product, as one index for grasping the kneading state of the kneader 9, the current value of an electric motor that drives the agitating blade to rotate according to the fluctuation of the raw material (hereinafter also referred to as kneader current value). You may manage fluctuations. Specifically, the current value is managed to increase as the proportion of fine ore increases. The kneader current value at that time is preferably maintained within a predetermined range.

Example 1
At the ferronickel smelting plant, dust is collected with a rotary dryer for drying nickel oxide ore as a raw material and an exhaust gas treatment facility attached to a rotary kiln for firing, and water and fine ore are collected into this dust. The kneaded material was prepared by adding. Specifically, first, industrial water was added to the dust using a pug mill type mixer to generate humidity-controlling dust, and the obtained humidity-controlling dust was supplied to a kneader together with powdered ore and kneaded. A dow mixer (registered trademark) having an effective volume of about 3.60 m ³ was used as the kneader.

  Dust and fine ore were supplied to the kneader so as to have a mixing ratio of 65:35 in terms of mass ratio on a wet basis. This mixing ratio is 63:37 in terms of dry-based mass ratio. The stirring blade of the kneader was operated at a rotation speed at which the frequency of the electric motor was 45 Hz, and the kneaded material of Sample 1 was sampled from the discharge part of the kneader in this state. The operation was continued without changing the conditions, and after a while, the kneaded material of Sample 2 was sampled from the same position. Next, the rotational speed of the stirring blade was increased so that the frequency of the motor was 50 Hz, and after a while, the kneaded material of Sample 3 was sampled from the same position. Further, the rotational speed of the stirring blade was lowered so that the frequency of the electric motor was 45 Hz, and after a while, the kneaded material of Sample 4 was sampled from the same position.

And the composition of Ni, MgO, SiO ₂ and C contained in each of the dust and nickel oxide ore charged in the kneader, and Ni and MgO contained in each of the kneaded materials of the above samples 1 to 4 , SiO ₂ , and C were analyzed using a combustion infrared absorption method and an ICP emission spectroscopic analysis method. The analysis results are shown in Table 1 below. Table 2 below shows the mixing ratio of dust and nickel oxide ore in the kneaded material calculated from these analysis results.

From the results of Tables 1 and 2, it was found that the state of dust and fine ore in the kneader can be managed by calculating the mixing ratio of dust and fine ore from the carbon content of the kneaded product. Moreover, it turned out that a homogeneous kneaded material is obtained by lowering | hanging the rotation speed of a kneading machine from the carbon analysis value of the sample obtained by the samples 1-4. Further, it was found that it is possible to calculate the mixing ratio of the fine ore based on the content of MgO and SiO ₂ of the kneaded material in place of carbon.

(Example 2)
Example except that the frequency of the electric motor for rotationally driving the stirring blades of the kneader is changed in the order of 50 Hz, 60 Hz, and 45 Hz, and a plurality of kneaded materials are sampled from the discharge portion of the kneader during the operation of each frequency. A kneaded material was prepared in the same manner as in Example 1. And 44 mm square briquette was produced from the obtained kneaded material, and the crushing strength and +10 mm yield were measured. The crushing strength and the +10 mm yield of the briquettes prepared from each sampled kneaded product are plotted in FIG. 3 and FIG. 4 for each motor frequency, with the horizontal axis as the current value of the kneader. In addition, the crushing strength of the briquette was the strength per briquette measured according to JIS Z 8841.

  From these results of FIG. 3 and FIG. 4, the crushing strength is 10 kgf / p or more by lowering the frequency of the electric motor that rotationally drives the stirring blades of the kneader, specifically by reducing the frequency of the electric motor from 50 Hz or 60 Hz to 45 Hz. +10 mm yield, and briquettes with 80% or more could be obtained. This is because the residence time of the kneaded material in the kneader can be secured for a long time by lowering the rotational speed of the stirring blade of the kneader, and thus a more homogeneous and highly viscous kneaded material can be obtained. This is probably because

DESCRIPTION OF SYMBOLS 1 Rotary dryer 2 Sieving means 3 Rotary kiln 4 Electric furnace 5, 6 Exhaust gas treatment equipment 7 Dust tank 7a Metering feeder 8 Mixer 9 Kneading machine 10 Briquette machine S1 Storage process in dust tank S2 Cutting process by rotary valve S3 Transport by screw conveyor Process S4 Humidity adjustment process by pug mill type mixer S5 Transport process by dust belt conveyor S6 Sieving process by sieving means S7 Transport process by fine ore belt conveyor S8 Kneading process by kneading machine S9 Transport process by kneaded material belt conveyor S10 Kneaded material hopper Storage step in S11 Fixed quantity supply step with kneaded material belt feeder S12 Molding step with briquette machine

Claims (6)

A method for producing a kneaded material prepared by kneading dust contained in exhaust gas discharged from a smelting step of nickel oxide ore and nickel oxide ore having a particle size of 10 mm or less with a kneader equipped with a stirring blade,
The mixing ratio of the dust and the nickel oxide ore is calculated based on the content of the specific substance obtained by analyzing the kneaded product, and when the mixing ratio deviates from a predetermined value, A method for producing a kneaded product, wherein the rotational speed is lowered.   The method for producing a kneaded product according to claim 1, wherein the specific substance is carbon.   The method for producing a kneaded product according to claim 1 or 2, wherein the stirring blade is composed of at least two shafts.   The nickel oxide ore is mixed at a ratio of more than 0 parts by weight and 40 parts by weight or less on a dry basis with respect to 100 parts by weight of the kneaded product. The manufacturing method of the kneaded material as described in any one of.   The dust is added and mixed with water so as to have a moisture content of 15 to 30% by mass in a pug mill mixer before kneading with the kneader. 2. A method for producing a kneaded product according to item 1. A briquette production method, comprising feeding a kneaded product obtained by the kneaded product production method according to any one of claims 1 to 5 to a molding machine to form a briquette.

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