JPH05306987A - Dust analysis method - Google Patents

Abstract

PURPOSE:To clearly and quantitatively analyze substances container in dust produced in a work section where powder material of an ironworks and the like is handled. CONSTITUTION:Heavy liquid separation is performed for sampled dust (here, a particle-like mixture of ten kinds of substances is used experimentary). Iron sand and the like of four specimen groups classified thereby is separated from soil and sand groups by means of magnetic separation. And the following operation A is performed for each specimen group, iron sand and the like separated by means of the magnetic separation respectively. In order words, light reflected from each particle existing at each place of a specimen is observed to investigate a form of each particle, color and reflection pleochroism by the use of a microscope in which polarized light is vertically made incident on the specimen. The observation result is collated with data previously obtained in similar observation on each substance and it is specified to correspond to some substance. And number of the particles every substance is shown at a rate (Wx/W and the like) of it to the other number of all the specified parsticles.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of analyzing dust generated in a coke manufacturing plant, an iron mill, a quarry, or the like, which handles powder.

[0002]

2. Description of the Related Art It is necessary to take effective dustproof measures in order to prevent dust generated in steelworks from falling to surrounding residential areas and causing pollution. To this end, it is important to identify equipment and facilities that generate a large amount of dust, and particularly equipment and facilities that cause a large amount of dust to fall in the residential area, and improve the equipment and facilities. Therefore, if the substance that constitutes the dust can be identified, it is possible to handle a large amount of the substance and to identify the equipment or facility where the substance is likely to be generated, which is useful for dust prevention measures.

Therefore, the applicant of the present invention is able to separate the sediments such as coal, coke, iron ore, and silica stone, which are expected to be the causative substances of the dusts generated in the ironworks, due to the difference in specific gravity. Attempts were made to identify the substances that make up the dust by performing heavy liquid separation. In this heavy liquid separation method, the weight of each separated substance is measured, and the content of each substance is displayed in% by weight with respect to the entire collected dust.

Further, the CEB method (chemical composition balance method), the C / H analysis method, the elemental analysis by X-ray, and the method of judging the substance from the appearance shape by the electron micrograph have been adopted.

[0005]

However, in the heavy liquid separation method, it is difficult to separate a plurality of substances having similar specific gravities. And in reality, the amount of dust, that is, the greater the number of particles, the greater the degree of pollution,
Since the results of the heavy liquid separation method are displayed in% by weight, substances with a large specific gravity occupy a large percentage even if the number of particles is small, and this result can accurately determine the degree of influence of each substance on dust pollution. Can not.

Further, each of the above-mentioned methods other than the heavy liquid separation method has advantages and disadvantages, and even a combination of several kinds of methods cannot sufficiently identify the substance constituting the dust.
The present invention is to solve such a problem, by clearly and quantitatively analyzing each substance constituting the dust, and by displaying the abundance ratio of each substance by the ratio of the number of particles. An object of the present invention is to provide a dust analysis method capable of practically determining the degree of influence of each substance on dust pollution.

[0007]

In order to achieve the above object, the method for analyzing dust according to the present invention is characterized in that the collected dust is subjected to heavy liquid separation and separation depending on the presence or absence of magnetism, and Each sample grouped by liquid separation and a sample having magnetism are placed on a microscope stage where polarized light is reflected vertically to the sample, and the reflected light from each particle present at various points in this sample is collected. Observing, the shape, color,
And to examine the reflection polychromaticity, this observation result, for each substance expected to be contained in the dust in advance, by collating the particles with each data obtained by performing the same observation as the above, Identifying which of the substances each of the predetermined number of particles in the sample corresponds to, counting the number of particles corresponding to each substance, the content of each substance in the ratio to the predetermined number of the number It is characterized by showing.

As a microscope capable of vertically irradiating polarized light onto a sample and observing the reflected light, there are a microscope having a vertical incident device attached to a polarized light microscope for transmitted light and a microscope commercially available as an ore microscope.

[0009]

By performing heavy liquid separation and separation depending on the presence or absence of magnetism on the collected dust, magnetic substances can be separated from the dust and grouping can be performed according to the difference in specific gravity. And
Each of these grouped samples and magnetic substance samples are placed on the microscope stage for each sample, and the polarized light is reflected vertically onto this to observe the reflected light from each particle present in each location of each sample. To do.

In a microscope, when polarized light is vertically incident on an opaque material which is metallic or sub-metallic, the shape, color and polychromaticity of reflected light from each material can be clearly observed. As a substance that constitutes dust in an ironworks, etc., there are many opaque substances such as coal, coke, iron ore, silica, etc., which are opaque substances, so this observation method is effective, and this observation result is included in the dust in advance. For each substance that is expected to be produced, by comparing the particles with the data obtained by performing the same observations as above, it is possible to determine to some extent which of the substances each particle in the sample corresponds to. It can be clearly specified.

Here, since the observation with the microscope is performed for each grouped sample, the types of substances contained in each sample are classified to some extent, so that the substance of each particle as described above can be identified. It will be easier. Then, such a specification is performed for a predetermined number of particles in each sample, the number of particles corresponding to each substance is counted, and the content of each substance is shown as a ratio of the number to the predetermined number. The abundance ratio of each constituent substance can be displayed as a ratio of the number of particles of each substance, and the degree of influence of each substance on dust pollution can be determined practically.

[0012]

EXAMPLES Examples of the present invention will be described below. In this example, an ore microscope having an optical system for vertical incident light as shown in FIG. 1 was used as a microscope capable of vertically observing polarized light on a sample and observing the reflected light.

The vertical epi-illumination optical system of the microscope 1 includes a white light source 11, a polarizer 12 for passing only the linearly polarized light from the white light, and a reflected light from the sample 2 that reflects the polarized light onto the sample 2. A prism 13 for directing the light to the eyepiece, and an unillustrated diaphragm or condenser lens,
The reflected light passes through the prism 13 and then the analyzer 14 toward the eyepiece.

The polarizer 12 is installed on a column-shaped base 12A, and this base 12A has an upper base 1 with respect to a lower base 12a.
2b rotates about the center of the bottom circle,
The polarizer 12 is fixed to the center of the upper table 12b. Therefore, the angle of the surface of the polarizer 12 in the horizontal direction with respect to the optical axis 15 can be changed by rotating the upper table 12b with the knob 12c.

In the microscope 1, the reading angle θ is set to 0 ° when the optical axis 15 is vertically incident on the surface of the polarizer 12, and at this time, the polarizer 12 and the analyzer 14 are set. And become orthogonal Nicols. And the polarizer 1
By rotating 3 by the knob 12c and changing θ, the angle of the polarization direction of the polarizer 12 with respect to the polarization direction of the analyzer 14 can be set to an arbitrary value.

The stage 3 on which the sample 2 is placed can be moved in the vertical direction by the knob 4, and can be moved in the vertical and horizontal directions in the horizontal plane by the knob 5. And
First, of the 12 substances shown in Table 1 among the substances that are expected to be contained in dust at ironworks, etc., the particles of each substance (collection of 200 μm or less) are separately separated from each other by the microscope 1
Observed by. That is, a small amount of particles are placed on a slide glass, 1 to 2 drops of immersion liquid is added, and then a cover glass is placed on the stage 3 and the reflected light is observed to observe each particle. Were examined for shape, color, and reflection pleochroism.

The shape, color and other characteristics of each particle are θ = 0 °
With respect to the reflection polychroism, observation was performed while slowly rotating the polarizer 13 with the knob 12c, and the change in color of reflected light was examined. The results are shown in Table 1 and Table 2, respectively. Based on this result, dust mixed with various substances is analyzed.

[0018]

[Table 1]

[0019]

[Table 2]

Particles of 10 kinds of substances (having a particle size of 200 μm or less) were collected from the yard and each facility in the steel mill, and the mixture was used for analysis by the method of the present invention. The ten kinds of substances are coal, powder coke, oil coke, granulated slag, serpentine, silica stone, limestone, iron ore, iron sand, and blast furnace cast floor building dust. 0.5 for each of the above substances
Each g was mixed and stirred to obtain a mixture. Using three heavy liquids with specific gravities of 1.6, 2.2 and 3.3,
It was divided into four sample groups: iron ore group, coal group, coke group, and sediment group. Since the sediment group contains iron sand, it was separated by a magnet.

Then, each sample group and magnetically selected iron sand were treated in the same manner as described above, each cover glass was fixed on the stage 3 of the microscope 1, and the particles in the cover glass were divided into 10 parts vertically and horizontally. For each particle existing at 100 locations, the same observation as above is performed at 512 times while moving the knob 5. At that time, the observation result of each particle is collated with the observation data of each substance shown in Table 1 and Table 2 to identify which substance each particle corresponds to. If there is something that cannot be specified, skip this and observe the next particle, and with respect to the total number C of particles that can be specified, the number of particles of each substance C ₁ , C ₂ , C ₃ ,
The ratio (Cx / C) was calculated.

A series of flow is shown in the flow chart of FIG. Here, the operation A indicates the observation and identification by the microscope 1. Wx / W to Bx / B correspond to Cx / C calculated in each sample group. Therefore, the content rate in the mixture of each substance is the ratio of the number of particles Wx to Bx of each substance in each sample group to the total number of particles that can be specified in the entire mixture T = W + X + Y + Z + B (Cx / T).
Indicated by. The result is shown by Δ in the graph of FIG. Since it was difficult to identify silica stone, serpentine, and limestone,
I counted them all together.

On the other hand, without performing the above-mentioned heavy liquid separation and magnetic separation,
Using the mixture as a sample as it is, the same observation with the microscope 1,
The identification was carried out to calculate Cx / C. In this case, T =
Since it is C, Cx / C directly corresponds to Cx / T. The result is shown by a circle in the graph of FIG. Here, since the first mixture was prepared by mixing 0.5 g of each substance, each substance occupies 10% by weight, but the specific gravity of each substance is about 4.5 for iron-based substances and silica stones. Considering that sediments such as etc. are around 2.7 and coal and coke are different from 1.4 to 1.8, the ratio of the number of particles of each substance to the total particles of the mixture is calculated and the theoretical value is calculated. And the result is shown in Figure 3.
In the graph, is shown by x.

As can be seen from FIG. 3, the granulated slag is considered to be easy to identify because of its characteristic shape and color.
Fewer particles were identified and the Cx / T values were significantly lower than calculated. This is because the granulated slag is fragile, so it was crushed during mixing etc. and became too fine and difficult to see,
It is considered that this is because the iron content contained in the granulated slag was determined to be iron ore.

Considering these facts, the results of the method of the present invention in which each sample group subjected to heavy liquid separation and magnetic separation were observed and specified by a microscope are very close to theoretical values. It can be said that there is.

[0026]

As described above, according to the method of the present invention, each substance constituting dust can be clearly and quantitatively analyzed, and the abundance ratio of each substance is displayed by the ratio of the number of particles. Therefore, there is an effect that the degree of influence of each substance on dust pollution can be practically determined.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a microscope used in Examples.

FIG. 2 is a flowchart showing a flow of a series of operations performed in an example.

FIG. 3 Content rate (Cx /
It is a graph which shows the analysis result of T), and a theoretical value.

[Explanation of symbols]

 1 Microscope 12 Polarizer 3 Stage

Claims (1)

[Claims] 1. The collected dust is subjected to heavy liquid separation and separation depending on the presence or absence of magnetism, and then each sample grouped by the heavy liquid separation and a magnetic sample are separated from the sample. The polarized light is placed on the stage of a microscope that is vertically reflected, and the reflected light from each particle present at various places in this sample is observed to examine the shape, color, and reflection polychromaticity of each particle. The observation results, for each substance that is expected to be contained in the dust in advance, by collating the particles with each data obtained by performing the same observation as described above, a predetermined number of each particle in the sample Is identified as which of the above substances, the number of particles corresponding to each substance is counted, and the content of each substance is shown as a ratio of the number to the predetermined number. Analysis method.