JP6519459B2 - Ore observation sample for mineral particle analyzer and method for producing the same - Google Patents

Description

  The present invention relates to an ore observation sample used in a mineral particle analysis device, and a method for producing the same.

Knowing the types and proportions of minerals contained in naturally-derived ores and various industrial raw materials is extremely important when effectively utilizing or processing the ore and industrial raw materials to enhance their value. It is information. In recent years, analysis by automatic analysis using a mineral particle analyzer (Mineral Liberation Analyzer, sometimes referred to as “MLA” in the present invention) may be used as a means for obtaining the information.
MLA is an apparatus for analysis by mineral particle analysis based on SEM-EDS, and is used particularly in the field of mineral resources. MLA is an apparatus capable of automatically performing analysis (mineral identification, particle size measurement, position information, presence / absence of symbiotic particles, etc.) by mass analysis of mineral particles based on EDS spectrum.

When performing this automatic analysis, the ore sample is mixed with the resin and embedded and solidified. Then, as shown in Patent Documents 1 to 3, for example, the embedded solid body is rough-polished and middle-polished with a water-resistant abrasive paper, and further containing abrasive abrasives together with a lubricant on a cloth such as Rascha. Then finish polishing and mirror polishing.
Then, the ore observation sample subjected to the mirror polishing is placed in the MLA apparatus, observed by SEM, the size and number of specific minerals are automatically read, and the ore is observed by analysis by EDS. The proportion of the specified mineral in the sample is determined.

JP 2004-340851 A Unexamined-Japanese-Patent No. 2004-347330 Unexamined-Japanese-Patent No. 2009-287941

As described above, the analysis of mineral particle analysis of ore samples using MLA has greatly contributed to the improvement of the productivity of analysis work due to its automatic nature.
However, in recent years, with the diversification of ore mining sites and the refinement of process control, the number of ore samples to be subjected to mineral particle analysis has also increased.
And, by the increase in the number of samples of the ore sample to be subjected to mineral particle analysis by the MLA device, the problems concerning the MLA device have become apparent. The problem with the MLA apparatus is that it takes a long time from the installation of the ore observation sample in the MLA apparatus to the start of analysis by mineral particle analysis. Specifically, a predetermined amount of time is required for evacuating the inside of the apparatus, stabilizing the operation of the electron gun, and the like. After all, it takes about 2 to 2.5 hours in general from when ore observation sample is installed in MLA until analysis by mineral particle analysis is started.

On the other hand, as described above, since MLA is an automatic analyzer based on SEM-EDS, the cost of the apparatus is high, and it is not easy to provide a plurality of machines.
As a result, in spite of the use of the MLA apparatus, the productivity improvement of the mineral particle analysis work can not be expected because of the increase in the number of samples of the ore sample.
The present invention has been made under the circumstances, and it is an object of the present invention to provide an ore observation sample which improves the productivity of mineral particle analysis work, and a method for producing the same.

  In order to solve the above-mentioned subject, the present inventors conducted research. And even if it says an ore sample in a bite, it was thought that the content of the mineral to be measured and the abundance ratio of a plurality of mineral to be measured differ greatly depending on the elemental species of the mineral to be measured and the origin of the ore sample. However, if the origin is the same or similar ore sample and the focus is on the same elemental species, the content of the mineral to be measured in the ore sample and the abundance ratio of a plurality of mineral to be measured are close numerical values I thought about showing.

  Then, according to the content of the measurement target mineral derived from the ore sample and the abundance ratio of the plurality of measurement target minerals, the ore observation sample installed in the MLA device is pelletized, and a plurality of such pellets (for example, 2 4 to 4) are considered to be configured to be placed on the sample table of the MLA.

That is, without changing the number of ore observation samples installed in the MLA apparatus, the number of ore samples to be measured is increased to increase the number of ore samples that can be measured per MLA analysis time. It was conceived to be able to improve the productivity of
At this time, even when a plurality of pellets are placed on the MLA sample stage, the size of the pellet is secured which can secure the area to be measured which can secure the analysis accuracy. Then, the number of pellets (for example, 2 to 4) to be placed on the MLA sample table may be set according to the size of the pellets.

That is, the first invention for solving the above-mentioned problems is:
A method for producing an ore observation sample used for MLA measurement, comprising
Mixing a predetermined amount of ore powder and a predetermined amount of phenolic resin powder to obtain a mixture;
Temporary consolidation step of compression molding the above mixture into pellets;
A consolidation preparation step of placing one of the pellets in each of the compartments on the base metal partitioned by the left and right asymmetrical partition plates fixed on the base metal in a self-supporting manner ;
The base metal on which the pellets are placed is placed in a mold for producing the ore observation sample, and the inside of the mold is filled with a resin powder, and then the resin powder is solidified to form a solidified piece It is a manufacturing method of an ore observation sample characterized by having a process.
The second invention is
Ore observation sample used for MLA measurement,
Two or more pellets composed of ore powder and phenolic resin are embedded in phenolic resin ,
The resin in which the pellet is embedded is partitioned by a left-right asymmetric partition plate fixed on the base metal in a self-supporting manner, and one pellet is embedded in each partition. Ore observation sample.
The third invention is
The ore observation sample according to the second invention, wherein the number of the compartments is two .

  By using the ore observation sample according to the present invention, the number of ore samples that can be measured per MLA analysis time increases, and the productivity of mineral particle analysis work is improved.

It is a flowchart of the material for preparation of the ore observation sample which concerns on this invention, and a preparation method. They are a perspective view (a) of the ore observation sample in which two pellets were mounted, and an AA sectional view (b).

FIG. 1 is a flow diagram of materials and a method for producing an ore observation sample according to the present invention.
Hereinafter, with reference to FIG. 1, the ore observation sample according to the present invention, the material for producing the same, and the production method will be described.

(1) Ore sample The ore sample is an observation target in the ore observation sample according to the present invention. Specifically, industrial raw materials such as pulverized products of various metal ores, residues in the smelting process of various metals, and the like can be mentioned.
The particle size of the ore sample is generally 20 μm to 200 μm.

(2) Resin The resin which is mixed with the ore sample and solidifies the sample is not particularly limited, but is preferably a thermosetting resin which hardens without undergoing a liquid state. In the case of a resin having a liquid state, such as a thermoplastic resin or a two-component mixed resin, when the liquid resin is mixed with the ore sample, first, the ore particles contained in the ore sample are It is because it is thought that it may diffuse into the liquid resin and the possibility of contamination arises, and secondly, the ore particles contained in the ore sample may be separated due to the difference in specific gravity.

  From this point of view, the thermosetting resin is not liquefied even if it is heated, and therefore, it is considered that each ore particle contained in the ore sample maintains its uniform mixed state. From this point of view, the thermosetting resin is more preferably a phenolic resin.

(3) Measuring Step The measuring step is a step of measuring predetermined amounts of the ore sample and the resin described above, and weighing each of them.
In the present invention, the ratio of the ore sample to the resin is preferably 10% or more and 28.5% or less by volume ratio (ore sample / resin). When the volume ratio is 10% or more, a sufficient amount of measurement particles can be secured in mineral particle analysis. In addition, when the volume ratio is 28.5% or less, contact between mineral particles is not excessive, and identification of simple substance and bond by MLA is easy.

Although it does not specifically limit as a specific measurement operation, The specific example of the measurement operation suitable for the measurement of an ore sample is demonstrated.
First, using a measuring spoon or the like, the ore sample that has become a powder by use of a ball mill or the like is measured. Then, the weighed ore sample is placed on paper. Meanwhile, the resin powder is measured with a measuring spoon or the like. Then, the measured resin powder is placed on paper.

(4) Mixing Step The mixing step is a step of mixing the ore sample and the resin which has become a powder after use in the ball mill, which has been weighed in the above-described measurement step, to obtain a mixed sample. The method of mixing the ore sample with the resin is not particularly limited. However, it is considered preferable to avoid giving mechanical energy to the ore sample and changing its particle size and crystal structure. From this viewpoint, for example, a method of placing a predetermined amount of ore sample and resin on paper and mixing them with a spoon, spatula or the like is preferable.

(5) Temporary Consolidation Step The temporary consolidation step is a step of compressing and molding the mixture mixed in the above-described mixing step to obtain pellets.
Specifically, a forming cylinder is installed in the lower metal of the press, and a partition metal is inserted into the forming cylinder. Then, the mixed sample is poured into the molding cylinder, and further, the partition metal and the molding rod are inserted. Next, a force is applied from above the molding rod in a press vice to consolidate the mixed sample.
After the consolidation, using a scrap metal, a force is applied from the top of the forming cylinder with a vice to extract the pellets from the forming cylinder.

(6) Pellet Pellet is a compression-molded product of the mixture of ore sample and resin described above. The diameter of the said pellet is taken as the diameter which can mount a predetermined number (for example, 2-4 pieces) of pellets on the base metal fitted to the sample stand of MLA.

(7) Partition metal When placing a predetermined number of pellets on the base metal, it is preferable to install a partition metal for partitioning between the pellets. In the present invention, it is thought that contamination between pellets can be avoided by using a thermosetting resin as a resin used for embedding, but from the viewpoint of further reducing the possibility of the contamination, it is possible to use partition metal Installation is considered to be effective.

It is preferable that the shape of the partition metal which concerns on this invention can be self-supporting on a base metal from a viewpoint of workability. For example, if two pellets are placed on a base metal, it is conceivable to divide into two sections by a partition metal having a U-shaped, N-shaped, etc. shape, and three pellets If it mounts, dividing into 3 divisions by the partition metal which has shapes, such as a Y-shape, is considered.
Here, adjustment is performed so that the partition metal does not extend beyond the pedestal. And it is preferable from a viewpoint of workability to fix the said partition metal on a base metal using a carbon paste etc.
In addition, it is preferable that the partition be made to have a left-right asymmetry such as a U-shape to visually differentiate each section. According to the configuration, it is possible to easily distinguish the predetermined number of pellets placed on both sides of the cutting metal, which is preferable. On the other hand, when the partition metal is N-shaped, Y-shaped, etc., the same effect can be obtained by slightly distorting this to make it asymmetrical.

(8) Consolidation Preparation Process In the consolidation preparation process, a partition metal is placed on a base metal, and the partition metal is fixed using carbon paste. Then, it is a step of placing one pellet obtained in the temporary consolidation step in each of the sections sandwiching the partition metal.

(9) Resin A predetermined number of pellets placed one by one in each section, sandwiching a partition metal on the above-mentioned base metal, are integrated by embedding on the base metal, and ore observation described later It is a resin for producing a sample.
As described in "(2) Resin", the resin is thermally cured from the viewpoint of avoiding the possibility that the ore particles contained in the ore sample diffuse into the liquid resin and the possibility of contamination occurs. Resin is preferable, and the same curing can be realized by using the same resin as the resin of “(2) resin”, which is preferable. And, the resin is more preferably a phenol resin

(10) Consolidation Step In the above-mentioned hot consolidation step, resin powder (multifast) is filled on a base metal on which the pellet produced in the above-mentioned consolidation preparation step is placed, and the pellet is embedded and heated , Curing and cooling.

The base metal on which the pellets prepared in the above-described consolidation preparation step are placed is placed on the ram of the hot consolidation machine and the cylinder of the hot consolidation machine is lowered.
After the resin powder (multifast) is added into the cylinder, the resin is heated for a fixed time to cure the above-described pellet and multifast resin. After the heating, the base metal and the resin are cooled to obtain a consolidated piece in which two or more pellets (formed bodies) composed of the ore powder and the resin are embedded with the resin.

(11) Ore observation sample The consolidated pieces obtained in the consolidation step are rough-polished and intermediate-polished with a water-resistant abrasive paper, and abrasive abrasive grains are included with a lubricant on a cloth like rasher to finish polish Mirror finish. In this manner, two or more of the predetermined number of pellets described above were embedded with the resin (multifast) and fixed on the base metal, and an ore observation sample in which the pellet surface was mirror-polished was obtained.

The said ore observation sample is demonstrated using FIG.
In FIG. 2, (a) is a perspective view of the ore observation sample in which two pellets were mounted, (b) is AA sectional drawing of the said perspective view.
In FIGS. 2 (a) and 2 (b), the ore observation sample 1 has two pellets 2 and a U-shaped partition plate 3, which are fixed on a base metal 5 by a resin 4. And as shown in FIG.2 (b), the pellet 2 and the partition plate 3 are being fixed on the base metal 5 with resin 4. As shown in FIG. Then, the two pellets 2 are placed one by one on the base metal separated into two sections divided by the partition plate 3 and embedded in the resin 4, so contamination due to the components of each other is caused. The possibility of being avoided. The partition plate 3 is preferably fixed on the base metal 5 with the carbon paste 6 before being embedded and fixed in the resin 4 in terms of operation.
However, as shown in FIG. 2A, the partition plate 3 does not have to completely separate the resin 4 as long as the possibility of the above-mentioned contamination can be avoided. Specifically, it is considered that the resin 4 should be partitioned at about 70%, preferably at least 80%, of the diameter of the ore observation sample 1.

  From this point onward, the ore observation sample 1 according to the present invention can be installed in the MLA and the analysis operation can be performed with high productivity, like the ore observation sample according to the prior art.

(Summary)
By carrying out the flow of the ore observation sample according to the present invention and the materials and production method for producing the same as described above, the number of ore samples that can be measured per MLA analysis time increases. As a result, the productivity of the mineral particle analysis work has been improved.

Claims (3)

A method for producing an ore observation sample used for MLA measurement, comprising
Mixing a predetermined amount of ore powder and a predetermined amount of phenolic resin powder to obtain a mixture;
Temporary consolidation step of compression molding the above mixture into pellets;
A consolidation preparation step of placing one of the pellets in each of the compartments on the base metal partitioned by the left and right asymmetrical partition plates fixed on the base metal in a self-supporting manner ;
The base metal on which the pellets are placed is placed in a mold for producing the ore observation sample, and the inside of the mold is filled with a resin powder, and then the resin powder is solidified to form a solidified piece And a process for producing an ore observation sample. Ore observation sample used for MLA measurement,
Two or more pellets composed of ore powder and phenolic resin are embedded in phenolic resin ,
The resin in which the pellet is embedded is partitioned by a left-right asymmetric partition plate fixed on the base metal in a self-supporting manner, and one pellet is embedded in each partition. Ore observation sample. The ore observation sample according to claim 2, wherein the number of the compartments is two .

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