JP7002005B2 - How to evaluate copper slag - Google Patents

Description

The present invention relates to a method for evaluating copper slag. More specifically, the present invention relates to a method for evaluating copper slag for evaluating the elution characteristics of arsenic and lead from copper slag with high accuracy.

Copper is generally produced from mined ore (sulfide ore) containing copper by the following method.

First, after crushing and crushing the sulfide ore, the valuable component and the gangue component are separated by a method such as flotation to obtain a copper concentrate. This copper concentrate is put into a high-temperature furnace such as a self-melting furnace, melted, and then charged into a converter to separate the remaining gangue components and some impurities as converter slag, resulting in a copper grade of about 99%. Obtain blister copper. Then, the obtained blister copper is electrolytically refined to obtain electrolytic copper having a purity of about 99.99%. In addition to copper, sulfide ore contains valuable components such as gold and silver, and these components are also recovered in the process of producing copper.

On the other hand, when copper is produced by the process as described above, self-melting furnace slag and converter slag containing impurities (hereinafter collectively referred to as copper slag) are generated from the self-melting furnace and the converter. For example, in addition to the above-mentioned valuable components, the sulfide ore contains components constituting the ore such as sulfur and gangue components such as silicon, iron and calcium, and a trace amount of impurity components such as lead, antimony and arsenic. However, it is contained in sulfide ore. Some of these components will be contained in the copper slag.

Copper slag has a glassy structure in which silicon, iron, and calcium are stable, and impurity components are stably incorporated into the glassy structure. For this reason, copper slag hardly shows a chemical change even in an acidic atmosphere, and has a feature that elution of impurity components is unlikely to occur and there are few environmental problems. In addition, since copper slag has a characteristic that its specific gravity is larger than that of sand, attention is being paid to copper slag as a substitute for sea sand, and effective reuse as an aggregate is progressing.

As described above, copper slag has a stable structure, but when it is used as a substitute for sea sand, elution of impurity components is evaluated in consideration of the influence on the environment.

For example, when copper slag is used as an aggregate, its quality is specified by JIS A5013-3, a JIS standard for copper slag aggregate, and its particle size and alkali-silica reactivity must be satisfied.

In addition, among the environmental safety qualities of copper slag, the grades of lead and arsenic are industrially important. The evaluation of the content of lead and arsenic in copper slag is evaluated in accordance with the method specified in JIS K0058-2 as Part 2: Content test method in JIS regarding chemical substance test methods for slags. Is common.

In order to use copper slag as an aggregate, etc., it is necessary to maintain the quality that meets the above-mentioned standards. In order to maintain the quality, it is important to accurately evaluate the elution characteristics of lead and arsenic from copper slag.

As a method for evaluating the elution characteristics of components (target components) such as lead and arsenic from copper slag, there are the following methods.

First, copper slag powder that passes through the entire amount of the 2 mm sieve is prepared by crushing the copper slag. Then, a hydrochloric acid solution having a concentration of 1 mol / L as a solvent and copper slag powder are mixed so as to have a mass-volume ratio of 3% to form a copper slag slurry, and the copper slag slurry is added to a shaking container.

Then, set the shaking container containing the copper slag slurry in the shaking machine, and shake about 200 times per minute for 2 hours with a shaking width of 4 to 5 cm.

After the shaking is completed, if necessary, centrifuge at 3000 rpm for 20 minutes, and the obtained supernatant is filtered through a filter. Then, the concentration of the target component contained in the filtered filtrate is measured by a method such as JIS K0102 or ICP emission spectrometry which is a publicly established method, the content concentration of the target component is calculated, and the elution of the target component is performed. It is the evaluation value of the characteristic.

The obtained evaluation values of the elution characteristics of the target component are used for examining a method for improving the content and elution property of the target component in the copper slag.

JIS K0058-2

However, when the evaluation values of the elution characteristics of the target component obtained by the above method are obtained, the evaluation values obtained from the samples of the same lot vary widely, and it is difficult to stably evaluate the elution characteristics. When examining the method for improving the content and elution of the target component in copper slag, the evaluation value of the elution characteristics of the target component is used to evaluate the improvement method, but the evaluation values vary even in the same lot. If there is, it is difficult to properly evaluate the method for improving the elution characteristics.

In view of the above circumstances, it is an object of the present invention to provide a method for evaluating copper slag that can appropriately evaluate the elution of arsenic and lead from copper slag.

In the method for evaluating copper slag of the first invention, copper slag powder obtained by crushing copper slag is mixed with an acidic solution to form a slurry, and the elution property of the copper slag is evaluated based on the concentration of arsenic eluted in the slurry. The method is characterized in that the particle size of the copper slag powder is smaller than 0.15 mm.
The method for evaluating copper slag of the second invention is characterized in that, in the first invention, the copper slag powder is a powder that has passed through a sieve having an opening of 0.15 mm.
In the method for evaluating copper slag of the third invention, copper slag powder obtained by crushing copper slag is mixed with an acidic solution to form a slurry, and the elution property of the copper slag is evaluated based on the concentration of lead eluted in the slurry. The method is characterized in that the particle size of the copper slag powder is smaller than 0.105 mm.
The method for evaluating copper slag according to the fourth invention is characterized in that, in the third invention, the copper slag powder is a powder that has passed through a sieve having an opening of 0.105 mm.
The method for evaluating copper slag according to the fifth aspect of the present invention is characterized in that, in the first, second, third or fourth invention, the acidic solution is hydrochloric acid.

According to the first or second invention, the variation in the concentration of arsenic eluted from the copper slag powder can be reduced, so that the elution of arsenic from the copper slag powder can be appropriately evaluated.
According to the third or fourth invention, the variation in the concentration of lead eluted from the copper slag powder can be reduced, so that the elution of lead from the copper slag powder can be appropriately evaluated.
According to the fifth invention, the elution of arsenic and lead from the copper slag powder can be appropriately evaluated.

(A) shows the concentration of arsenic and lead contained in the filtrate when the opening for sieving the copper slag powder is 2 mm or less, and the arsenic and arsenic contained in the filtrate at each opening when the opening is changed. It is a graph which showed the ratio of the concentration of lead, and (B) is the graph which showed the relationship between the particle size of copper slag powder and the concentration of arsenic and lead contained in a filtrate.

The method for evaluating copper slag according to the present embodiment is a method for evaluating the elution of impurities from copper slag, and is characterized in that variation in evaluation values can be suppressed.

The evaluation values obtained by the evaluation method of the copper slag of the present embodiment are obtained from the evaluation of the quality of the copper slag when the copper slag is used as the aggregate, the evaluation of the content of lead and arsenic in the copper slag, and the copper slag. It can be used to evaluate the elution of lead and arsenic.

<Evaluation method of copper slag of this embodiment>
The evaluation method of the copper slag of this embodiment will be described.
First, the outline of the evaluation method of the copper slag of the present embodiment will be described.

First, the copper slag to be evaluated is crushed using a ball mill, a vibration disc mill, or the like to prepare copper slag powder. At this time, the copper slag powder is prepared so that the entire amount of the copper slag powder passes through the sieve having a predetermined opening.

Then, the copper slag powder is mixed with a solvent to form a copper slag slurry, and the copper slag slurry is added to the shaking container. For example, a hydrochloric acid solution having a concentration of 0.5 to 2.0 mol / L, preferably 1 mol / L and copper slag powder as a solvent, and the mass-volume ratio of the copper slag powder to be 1 to 5%, preferably 3%. Prepare a copper slag slurry so as to be, and add this copper slag slurry to a shaking container.

Then, the shaking container containing the copper slag slurry is set in the shaker, and the shaking container is shaken. For example, the shaking container is shaken over 2 hours at a cycle of about 200 times per minute so that the shaking width is 4 to 5 cm. Then, the components contained in the copper slag slurry are eluted in the solvent.

After the shaking is completed, the copper slag slurry is separated into a supernatant liquid and a solid content. For example, the copper slag slurry is centrifuged for 20 minutes in a centrifuge at 3000 rpm, if necessary, to separate the supernatant liquid and the solid content.

If the obtained supernatant is filtered with a filter, an analytical solution can be obtained, and the concentration of the target component contained in this analytical solution is measured. For example, the concentration of the target component contained in the analytical solution is measured by a method such as JIS K0102 or a publicly established method such as ICP emission spectrometry. Then, by calculating the content concentration of the target component contained in the analytical solution, the amount eluted in the solvent from the copper slag slurry (hereinafter, may be referred to as the elution amount) can be grasped, so that the evaluation value of the elution characteristic of the target component can be grasped. Can be used as.

<Analysis of arsenic>
Here, when the mesh size of the sieve used when preparing the copper slag powder is large, the powder having a large particle size is included. Then, when the copper slag slurry is shaken, the contact between the copper slag powder and the solvent becomes insufficient, and the amount of the eluted components is not stable. That is, even if the copper slag slurry is prepared at the same time, the amount of elution from the copper slag slurry into the solvent becomes large.

Therefore, when the target component is arsenic, the copper slag powder is prepared so that the entire amount of the copper slag powder passes through the sieve having a mesh size of 0.15 mm. Then, if the copper slag slurry is prepared at the same time, it is possible to eliminate (or make it very small) the variation in the amount of arsenic eluted from the copper slag slurry into the solvent. Then, since the elution amount of arsenic in the analytical solution obtained by the above method is stable, the obtained elution amount of arsenic can be used as an evaluation value of the elution characteristics of arsenic in copper slag.

<Analysis of lead>
On the other hand, when the target component is lead, the copper slag powder is prepared so that the entire amount of the copper slag powder passes through the sieve having a mesh size of 0.105 mm. Then, if the copper slag slurry is prepared at the same time, it is possible to eliminate (or make it very small) the variation in the amount of lead eluted from the copper slag slurry into the solvent. Then, since the elution amount of lead in the analytical solution obtained by the above method is stable, the obtained elution amount of lead can be used as an evaluation value of the elution characteristics of lead in copper slag.

<Solvent>
The concentration of the hydrochloric acid solution forming the copper slag slurry and the mass-volume ratio of the copper slag powder and the hydrochloric acid solution in the copper slag slurry are not particularly limited. However, the above-mentioned concentration and mass-volume ratio can stabilize the elution amount of arsenic and lead from the copper slag slurry.

Further, the solvent for forming the copper slag slurry is not limited to the hydrochloric acid solution, and other acids can also be used. For example, a nitric acid solution or the like can also be used.

<About shaking>
When shaking the shaking container containing the copper slag slurry, the shaking width, the shaking cycle, and the shaking time are not limited to the above description and may be appropriately set.

The effectiveness of the copper slag evaluation method of this embodiment was confirmed by experiments.

<Example>
In the example, copper slag produced in the converter step of copper smelting was collected and crushed so as to pass through a sieve having a mesh size of 0.15 mm to prepare copper slag powder. For this copper slag powder, the elution amounts of lead and arsenic were measured for each particle size from 46 μm to 2 mm.

The elution amounts of lead and arsenic were measured as follows.

First, 4.8 g of the prepared copper slag powder was taken and placed in a beaker having a volume of 250 ml, and 160 ml of a 1 mol / L concentration hydrochloric acid solution was added into the beaker to prepare a copper slag slurry.

The beaker containing the copper slag slurry was shaken using a TS-12H type shaker manufactured by Thomas Scientific Instruments Co., Ltd. The condition for shaking the beaker was that the shaking width was 4.5 cm, and the beaker was shaken at a speed of about 200 times per minute for 2 hours.

After the shaking was completed, the shaken copper slag slurry was placed in a centrifuge (KUBOTA-5200 type) and centrifuged at a speed of 3000 rpm for 20 minutes.

The copper slag slurry after centrifugation is filtered using a filter having a pore size of 0.45 μm for solid-liquid separation, and the obtained filtrate is obtained by measuring the components by the ICP emission spectrometry method specified in JIS K0102. The arsenic and lead content concentrations were calculated from the measured values.

<Comparison example>
As a comparative example, the arsenic and lead content concentrations were the same as in the examples except that the copper slag powder prepared by pulverizing the sieve so as to pass the entire amount of the sieve having a mesh size of 2 mm, which was conventionally adopted, was used. Was calculated.

The results are shown in FIG.
As shown in FIG. 1, in the examples, the smaller the particle size, the larger the elution amount as compared with the comparative example. Moreover, when the amount of arsenic was smaller than 0.150 mm, the elution amount was constant regardless of the particle size, and when the amount of lead was smaller than 0.105 mm, the amount of elution was constant regardless of the particle size.
The variation (coefficient of variation) of the evaluation values in the same sample is 11% by weight of lead and 7.3% by weight of arsenic in the comparative example, but 3.3% by weight of lead and 3.7% by weight of arsenic in the example. %, And the variation is small.

From the above results, it was confirmed that if the copper slag evaluation method of the present embodiment is used, the variation in the amount of arsenic and lead elution from the copper slag can be reduced, and the elution characteristics from the copper slag can be evaluated accurately.

The method for evaluating copper slag of the present invention is suitable as a method for evaluating elution of lead or arsenic from copper slag when it comes into contact with an acid.

Claims (5)

It is a method of mixing copper slag powder obtained by crushing copper slag with an acidic solution to form a slurry, and evaluating the elution property of copper slag based on the concentration of arsenic eluted in the slurry.
A method for evaluating copper slag, wherein the particle size of the copper slag powder is smaller than 0.15 mm. Copper slag powder,
The method for evaluating copper slag according to claim 1, wherein the powder has an opening of 0.15 mm and has passed through a sieve. It is a method of mixing copper slag powder obtained by crushing copper slag with an acidic solution to form a slurry, and evaluating the elution property of copper slag based on the concentration of lead eluted in the slurry.
A method for evaluating copper slag, wherein the particle size of the copper slag powder is smaller than 0.105 mm. The particle size of copper slag powder is
The method for evaluating copper slag according to claim 3, wherein the powder has a mesh size of 0.105 mm and has passed through a sieve. The method for evaluating copper slag according to claim 1, 2, 3 or 4, wherein the acidic solution is hydrochloric acid.

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