JP5811297B1 - Ore slurry manufacturing equipment and ore slurry manufacturing method - Google Patents

Abstract

An ore slurry production facility and an ore slurry production method capable of producing an ore slurry having a high solid component ratio and high specific gravity while maintaining a slurry throughput. A first thickener 1 for pre-concentrating a raw ore slurry to obtain an intermediate ore slurry, and a second thickener 2 having a thickening effect higher than that of the first thickener 1 for concentrating the intermediate ore slurry to obtain a concentrated ore slurry. Ore slurry production equipment A. Since the intermediate ore slurry pre-concentrated in the first thickener 1 is supplied to the second thickener 2, the settling speed of the ore slurry is increased in the second thickener 2 and the slurry throughput can be increased. Further, since the second stage is the second thickener 2 having a high thickening effect, a concentrated ore slurry having a high solid component ratio and high specific gravity can be produced. [Selection] Figure 1

Description

  The present invention relates to an ore slurry production facility and an ore slurry production method. More specifically, for example, an ore slurry production facility for producing a slurry of nickel oxide ore to be sent to a high temperature pressurized sulfuric acid leaching process in hydrometallurgy using a high temperature pressurized sulfuric acid leaching method for recovering nickel from nickel oxide ore And an ore slurry manufacturing method.

  High pressure acid leaching (HPAL) is a high pressure acid leaching method (HPAL) as a hydrometallurgical process for recovering valuable metals such as nickel and cobalt from low-grade nickel oxide ores such as limonite ore. A sulfuric acid leaching method is known.

  As shown in FIG. 3, in the hydrometallurgical process for obtaining a nickel / cobalt mixed sulfide from nickel oxide ore, a pretreatment step (1), a high-temperature pressurized sulfuric acid leaching step (2), and a solid-liquid separation step (3 ), Neutralization step (4), dezincification step (5), sulfurization step (6), and detoxification step (7) (for example, Patent Document 1).

  In the pretreatment step (1), the nickel oxide ore is crushed and classified to produce an ore slurry. In the high-temperature pressure sulfuric acid leaching step (2), sulfuric acid is added to the ore slurry obtained in the pretreatment step (1), and stirred at 220 to 280 ° C. to obtain a high-temperature pressure acid leaching to obtain a leaching slurry. In the solid-liquid separation step (3), the leaching slurry obtained in the high-temperature pressurized sulfuric acid leaching step (2) is subjected to solid-liquid separation, and a leachate containing nickel and cobalt (hereinafter referred to as “crude nickel sulfate aqueous solution”). A leach residue is obtained.

  In the neutralization step (4), the crude nickel sulfate aqueous solution obtained in the solid-liquid separation step (3) is neutralized. In the zinc removal step (5), hydrogen sulfide gas is added to the crude nickel sulfate aqueous solution neutralized in the neutralization step (4) to precipitate and remove zinc as zinc sulfide. In the sulfidation step (6), hydrogen sulfide gas is added to the dezincification final solution obtained in the dezincification step (5) to obtain a nickel / cobalt mixed sulfide and a nickel poor solution. In the detoxification step (7), the leaching residue generated in the solid-liquid separation step (3) and the nickel poor solution generated in the sulfidation step (6) are detoxified.

  In wet smelting using the high-temperature pressurized sulfuric acid leaching method for recovering nickel from the nickel oxide ore as described above, the nickel oxide ore is crushed and classified to a predetermined size or less using a wet sieve, Slurry and send to high temperature pressurized sulfuric acid leaching process. In addition, the ore slurry sent to the high-temperature pressurized sulfuric acid leaching process has several types of nickel oxidation so that the acid consumption in the high-temperature pressurized sulfuric acid leaching process, the nickel concentration of the resulting leachate, and other impurity concentrations are at a predetermined ratio. Made by blending ores.

  Since the solid component ratio (weight ratio of solids (ore) in the ore slurry) of the ore slurry obtained at this point is as low as 10 to 20%, if it is sent to the high-temperature pressurized sulfuric acid leaching process as it is, In this process, the nickel concentration is low, the amount of liquid for treating the same nickel amount is increased, and nickel cannot be efficiently recovered. Therefore, a thickener is used to increase the solid component ratio of the ore slurry and then send it to the high-temperature pressurized sulfuric acid leaching process. Thereby, the amount of nickel passing per unit time to the high-temperature pressurized sulfuric acid leaching process increases, and the nickel recovery efficiency is increased.

  The ore slurry sent to the high-temperature pressurized sulfuric acid leaching step can increase the amount of nickel passing through the high-temperature pressurized sulfuric acid leaching step per unit time as the solid component ratio increases. However, if the solid component ratio is too high, the viscosity of the ore slurry increases, and it becomes difficult to feed the liquid due to the pump capacity control, or the piping is blocked. Therefore, the solid component ratio of the ore slurry is adjusted to be maintained at an optimum value (40 to 45%).

  Since the thickening behavior varies depending on the ore species, the solid component ratio of the ore slurry obtained from the thickener depends on the blended ore species, the blend ratio, the type of flocculant used for thickening, the amount added, and the like. Therefore, conventionally, depending on the type of blended ore and blend ratio, the type and amount of flocculant are adjusted with reference to past data and the rules of worker's experience to obtain an ore slurry with the desired solid component ratio. It was.

  However, when the ore type is changed, it is difficult to adjust the flocculant, and the solid component ratio and specific gravity of the ore slurry may decrease. In addition, even if the same ore type is used, the silicon quality that affects the thickening behavior may fluctuate greatly, which may also reduce the solid component ratio and specific gravity of the ore slurry.

  As shown in FIG. 4, the conventional ore slurry manufacturing equipment B connects a plurality of thickeners 101 and 102 in parallel according to the required amount of slurry processing, and the ore slurry obtained from each thickener 101 and 102 is oreed. The slurry is temporarily stored in the slurry storage tank 103 and supplied to the high-temperature pressurized sulfuric acid leaching process.

  In this way, the slurry throughput can be increased by connecting a plurality of thickeners 101 and 102 in parallel. However, there is a problem that the solid component ratio and the specific gravity of the ore slurry vary more greatly than in the case of using a single thickener, making adjustment more difficult.

JP-A-2005-350766

  In view of the above circumstances, an object of the present invention is to provide an ore slurry production facility and an ore slurry production method capable of producing an ore slurry having a high solid component ratio and high specific gravity while maintaining a slurry throughput.

The ore slurry production facility of the first invention comprises a first thickener for pre-concentrating an ore slurry having a solid content ratio of 10 to 20% to obtain an intermediate ore slurry, and concentrating the intermediate ore slurry to obtain a concentrated ore slurry. And a second thickener having a thickening effect higher than that of the first thickener.
The ore slurry production facility of the second invention is characterized in that, in the first invention, a flocculant is added to the first thickener so that the solid component ratio of the intermediate ore slurry is 35 to 40%. .
The ore slurry production facility of the third invention is characterized in that, in the first or second invention, an ore slurry storage tank for temporarily storing the concentrated ore slurry is provided.
In the ore slurry manufacturing method of the fourth invention, an ore slurry having a solid component ratio of 10 to 20% is pre-concentrated by the first thickener to obtain an intermediate ore slurry, and the second thickener having a thickening effect higher than that of the first thickener. The intermediate ore slurry is concentrated to obtain a concentrated ore slurry.
The ore slurry production method of the fifth invention is characterized in that, in the fourth invention, the flocculant added to the first thickener is adjusted so that the solid component ratio of the intermediate ore slurry is 35 to 40%.
The ore slurry manufacturing method of the sixth invention is characterized in that, in the fourth or fifth invention, the concentrated ore slurry is temporarily stored in an ore slurry storage tank and then sent to a high-temperature pressurized sulfuric acid leaching step.

According to the first invention, since the intermediate ore slurry pre-concentrated in the first thickener is supplied to the second thickener, the ore slurry sedimentation speed is increased in the second thickener, which is required for the second thickener particle sedimentation. The water area to be reduced can be reduced, and the slurry throughput can be increased. Moreover, since the latter stage is a second thickener having a high thickening effect, a concentrated ore slurry having a high solid component ratio and high specific gravity can be produced.
According to the second invention, since the solid component ratio of the intermediate ore slurry is 35 to 40%, the sedimentation rate of the ore slurry is increased in the second thickener, and the slurry throughput can be increased.
According to the fourth invention, since the intermediate ore slurry pre-concentrated in the first thickener is supplied to the second thickener, the ore slurry sedimentation speed is increased in the second thickener, which is required for the second thickener particle sedimentation. The water area to be reduced can be reduced, and the slurry throughput can be increased. Moreover, since the latter stage is a second thickener having a high thickening effect, a concentrated ore slurry having a high solid component ratio and high specific gravity can be produced.
According to the fifth invention, since the solid component ratio of the intermediate ore slurry is 35 to 40%, the sedimentation rate of the ore slurry is increased in the second thickener, and the slurry throughput can be increased.

It is explanatory drawing of the ore slurry manufacturing equipment which concerns on one Embodiment of this invention. It is a graph which shows the solid component ratio with respect to (A) silicon quality of the ore slurry obtained by the Example and the comparative example, and (B) is a graph which shows specific gravity with respect to silicon quality. It is the whole process figure of the hydrometallurgy using the high temperature pressurization sulfuric acid leaching method. It is explanatory drawing of the conventional ore slurry manufacturing equipment.

Next, an embodiment of the present invention will be described with reference to the drawings.
The ore slurry manufacturing facility according to one embodiment of the present invention is a hydrometallurgical process using a high-temperature pressure sulfuric acid leaching method for recovering nickel from nickel oxide ore. Used for manufacturing. That is, the ore slurry production facility uses nickel oxide ore as a raw material ore slurry obtained by pulverizing and classifying nickel oxide ore, and concentrating the raw ore slurry so as to have a target solid component ratio and specific gravity to obtain a concentrated ore slurry. To manufacture.

  As shown in FIG. 1, the ore slurry production facility A of the present embodiment includes a first thickener 1, a second thickener 2, and an ore slurry storage tank 3.

  Each thickener 1, 2 includes a thickener body having a cylindrical outer frame and a conical bottom portion having a deep central portion, and a rake that rotates inside the thickener body. The ore slurry supplied to the thickener body settles and agglomerates to form an upper supernatant liquid part and a lower sedimentation concentration part, and ore concentrated from the slurry recovery port provided at the bottom of the thickener body. The slurry is collected. In order to improve the sedimentation property of the ore slurry, a floc is formed by adding a flocculant to the thickener body. In addition, by slowly rotating the rake, the sediment concentration of the ore slurry is advanced in the sedimentation concentration section to ensure a uniform deposition state.

  The first thickener 1 and the second thickener 2 are connected in series. The raw ore slurry is supplied to the first thickener 1 at the front stage, and the intermediate ore slurry obtained from the first thickener 1 is supplied to the second thickener 2 at the rear stage. The concentrated ore slurry obtained from the second thickener 2 is supplied to the ore slurry storage tank 3 and temporarily stored, and then sent to the high-temperature pressurized sulfuric acid leaching step.

  In this specification, the ore slurry supplied to the first thickener 1 is “raw ore slurry”, the ore slurry obtained from the first thickener 1 is “intermediate ore slurry”, and the ore slurry obtained from the second thickener. Is called “concentrated ore slurry”.

  As the second thickener 2, a thickener having a thickening effect higher than that of the first thickener 1 is used. Here, the thickening effect means the solid component ratio and the specific gravity of the resulting ore slurry, and the high thickening effect means that an ore slurry having a high solid component ratio and specific gravity can be obtained. The thickening effect depends on the shape and size of the thickener.

  The raw ore slurry supplied to the first thickener 1 is crushed nickel oxide ore, classified to a predetermined size or less using a wet sieve, and further blended with a plurality of types of nickel oxide ore to form a slurry. Is. The solid component ratio of the raw ore slurry is 10-20%.

  The raw ore slurry is pre-concentrated by the first thickener 1 to obtain an intermediate ore slurry. Here, it is preferable to adjust the kind and amount of the flocculant added to the first thickener so that the solid component ratio of the intermediate ore slurry is 35 to 40%.

  The obtained intermediate ore slurry is supplied to the second thickener 2 having a high thickening effect, and the intermediate ore slurry is concentrated to obtain a concentrated ore slurry. The solid component ratio of the concentrated ore slurry is 40-45%. The concentrated ore slurry is temporarily stored in the ore slurry storage tank 3 and then sent to the high-temperature pressurized sulfuric acid leaching process.

  As described above, since the intermediate ore slurry pre-concentrated in the first thickener 1 is supplied to the second thickener 2, the sedimentation speed of the ore slurry is increased in the second thickener 2, and the particles of the second thickener 2 are settled. The required water area can be reduced, and the slurry throughput of the second thickener 2 can be increased. As a result, the amount of slurry processing in the entire ore slurry production facility A can be increased. Moreover, if the solid component ratio of the intermediate ore slurry is 35 to 40%, the sedimentation rate of the ore slurry is increased in the second thickener 2, and this can increase the slurry throughput. Therefore, a high slurry throughput can be maintained as in the conventional ore slurry manufacturing facility in which a plurality of thickeners are connected in parallel.

  Further, since the second stage is the second thickener 2 having a high thickening effect, a concentrated ore slurry having a high solid component ratio and high specific gravity can be produced.

  Furthermore, since the first thickener 1 and the second thickener 2 are connected in series, fluctuations in the solid component ratio and specific gravity of the ore slurry are reduced compared to a configuration in which a plurality of thickeners are connected in parallel, Adjustment is easy.

(Solid component ratio, specific gravity)
An ore slurry was produced using an ore slurry production facility (Example) configured to connect the first thickener 1 and the second thickener 2 in series and an ore slurry production facility (Comparative Example) configured in parallel. . That is, the ore slurry manufacturing facility of the example is the ore slurry manufacturing facility A according to the above-described embodiment shown in FIG. 1, and the ore slurry manufacturing facility of the comparative example is the ore slurry manufacturing facility B having the conventional configuration shown in FIG. The first thickener 1 in the embodiment and the first thickener 101 in the comparative example are the same thickener and have the same thickening effect. Further, the second thickener 2 in the embodiment and the second thickener 102 in the comparative example are the same thickener and have the same thickening effect.

  The graph which shows the solid component ratio with respect to the silicon quality of the ore slurry obtained in the Example and the comparative example is shown in FIG. Moreover, the graph which shows the specific gravity with respect to silicon quality is shown in FIG.2 (B).

  As can be seen from FIGS. 2A and 2B, in both the examples and the comparative examples, the higher the silicon quality, the lower the solid component ratio and the specific gravity. However, when the silicon quality is the same, it can be seen that the example has a higher solid component ratio and specific gravity than the comparative example. From this, according to the ore slurry production facility A of the above embodiment, it was confirmed that an ore slurry having a high solid component ratio and high specific gravity can be produced.

(Slurry processing amount)
In the said Example, the addition amount of the flocculant added to the 1st thickener 1 was adjusted, and the solid component rate of the intermediate ore slurry was 35 to 40%. In Examples and Comparative Examples, the operation was performed so that the amount of slurry supplied to the high-temperature pressurized sulfuric acid leaching process was 250 m ³ / h. Table 1 shows the specific gravity and flow rate of the supply slurry, discharge slurry, and ore slurry in the ore slurry storage tank in each thickener in Examples and Comparative Examples. The specific gravity of the raw ore slurry is 1.20 t / m ³ .

In the embodiment, to obtain an intermediate ore slurry density 1.38t / m ³ Concentration of the ore slurry specific gravity 1.20 T / m ³ by the first thickener 1. Further, to obtain concentrated ore slurry density 1.51t / m ³ Concentration of the intermediate ore slurry density 1.38t / m ³ by the second thickener 2. By setting the supply amount of the intermediate ore slurry to the second thickener 2 to 618 m ³ / h, a target slurry supply amount of 250 m ³ / h was obtained.

In the comparative example, was obtained ore slurry density 1.38t / m ³ Concentration of the ore slurry specific gravity 1.20 T / m ³ by the first thickener 101. The second thickener 102 and concentration of the ore slurry specific gravity 1.20 T / m ³ specific gravity 1.51t / m ^3, to obtain a solid component 44% of the ore slurry. The raw ore slurry was supplied to the second thickener 102 at 656 m ³ / h to obtain an ore slurry having a flow rate of 179 m ³ / h. The shortage with respect to the target slurry supply rate of 250 m ³ / h was compensated from the first thickener 101. That is, ore slurry having a flow rate of 71 m ³ / h was obtained from the first thickener 101. In the ore slurry storage tank 103, the ore slurry obtained from the first thickener 101 and the second thickener 102 was mixed to obtain an ore slurry having a specific gravity of 1.42 t / m ³ and a solid component ratio of 42%.

  From the above, it can be seen that in the example, even if the supply amount to the second thickener 2 is less than that in the comparative example, the discharge amount increases and the target slurry supply amount can be obtained. This is because the pre-concentrated intermediate ore slurry is supplied to the second thickener 2, so that the sedimentation speed of the ore slurry is increased in the second thickener, and the water area required for particle sedimentation of the second thickener 2 is reduced. This is thought to be because the slurry throughput can be increased.

  From this, according to the ore slurry production facility A of the above embodiment, it was confirmed that the slurry throughput could be increased and that a high slurry throughput could be maintained as in the conventional ore slurry production facility.

A ore slurry manufacturing equipment 1 1st thickener 2 2nd thickener 3 Ore slurry storage tank

Claims (6)

A first thickener for pre-concentrating an ore slurry having a solid content ratio of 10 to 20% to obtain an intermediate ore slurry;
An ore slurry production facility comprising: a second thickener having a thickening effect higher than that of the first thickener, wherein the intermediate ore slurry is concentrated to obtain a concentrated ore slurry. The ore slurry manufacturing equipment according to claim 1, wherein a flocculant is added to the first thickener so that a solid component ratio of the intermediate ore slurry is 35 to 40%. The ore slurry production facility according to claim 1, further comprising an ore slurry storage tank that temporarily stores the concentrated ore slurry. The first ore thickener pre-concentrates the ore slurry with a solid content rate of 10-20% to obtain an intermediate ore slurry,
A method for producing an ore slurry, wherein the intermediate ore slurry is concentrated by a second thickener having a thickening effect higher than that of the first thickener to obtain a concentrated ore slurry. The ore slurry manufacturing method according to claim 4, wherein the flocculant added to the first thickener is adjusted so that the solid component ratio of the intermediate ore slurry is 35 to 40%. 6. The ore slurry manufacturing method according to claim 4, wherein the concentrated ore slurry is temporarily stored in an ore slurry storage tank, and then sent to a high-temperature pressurized sulfuric acid leaching step.