KR100432428B1 - a method for analyzing cast iron - Google Patents

Abstract

In the pig iron analysis method according to the present invention in the pig iron analysis method by X-ray fluorescence analysis, the pig iron is pulverized into chips to make pellets (pellets) and coated with the X-ray transmissive film on the pellets at the same time pressurized coating By providing the pig iron to the X-ray fluorescence analysis device, there is an effect that can take full advantage of the XRF analysis method by overcoming the disadvantages of the general iron analysis method by XRF.

Description

Pigment analysis method {a method for analyzing cast iron}

The present invention relates to a method for analyzing pig iron, and more particularly, to a method for analyzing the pig iron by grinding the pellet into chips and then providing the same to an X-ray fluorescence spectrometer.

Iron is a metal element with the chemical symbol Fe, atomic number 26, atomic weight 55.85 and specific gravity 7.85. Pure iron is a metal that is rich in toughness and malleability. However, in general, all steel products are in fact steel or cast iron, i.e. alloys of iron and carbon, because they are generally too soft and have no strength. After all, the properties of steel depend greatly on the amount of carbon contained in the range of 0.01-0.7%. The lower the carbon content is, the easier it is to soften and increase. As the carbon content increases, the hardness and strength increase but the elastic force and elongation decrease. It shows a tendency to Commonly used steel materials have iron as their main component and include silicon, manganese, phosphorus and sulfur in addition to carbon.

Pig iron (cast iron) is the iron that melts iron ore in a blast furnace. It contains five major elements of iron (carbon, silicon, manganese, phosphorus and sulfur) and is hard but brittle. In particular, since pig iron contains a lot of carbon, it loses its inherent toughness and malleability, so it can be poured into a mold to make a casting, but it is difficult to process such as thinning or stretching under pressure. Pig iron is also used in castings because of this property, but most of it is used as raw material to make steel. Pig iron is usually produced from 3.0-4.5% carbon, 0.2-3.0% silicon, 0.5-2% manganese, 0.02-0.5% phosphorus, 0.01-0.1% sulfur.

On the other hand, it is an important subject to grasp the component of pig iron which becomes a material before manufacturing steel. Methods of analyzing the components of pig iron include wet analysis and heat treatment. The wet analysis method, which is widely used, has the disadvantage that it takes a very long time. In the heat treatment method, pig iron is cut to a certain size, and free carbon is made of Fe ₃ C in a heat treatment furnace.

Recently, the spotlight is an analysis method using an X-ray fluorescence analyzer. X-Ray Fluorescence Analysis is a technology that can analyze the element very quickly (usually 10-100 seconds) for all types of samples except liquids, solids, powders, slurries, etc. From 11Na on the phase to 92U (82 elements), several elements can be analyzed simultaneously. This high precision method is a non-destructive method that requires little pretreatment for most samples. There is no waste generated during the analysis. In addition, the simple operation at the touch of a button has the advantage of no labor or time wasted because anyone can easily operate without the expertise of analysis.

X-ray fluorescence spectrometers are widely used in steel process management, such as the analysis of the principal components of special steels, and have been widely used in the analysis of powder iron ore, sintered ores and slag (SLAG) because of the fact that there are no limitations on sample types.

In the analysis principle, when a strong X-ray generated by an X-ray generator is applied to a material, various interactions occur between materials, and one of them generates a secondary X-ray called a fluorescent X-ray. This fluorescence X-ray occurs when the inner electrons of an element exit the outer shell by primary X-rays and then transition to an orbital where electrons with higher energy remain. X-rays have unique wavelengths for each element. Fluorescence X-ray spectroscopy is a method of qualitatively and roughly dividing an element in a substance except gas by measuring the wavelength and energy intensity of this characteristic X-ray.

X-ray fluorescence analyzer consists of X-ray generator, sample chamber, detector, crest analyzer and MCA processor. Samples to be analyzed by X-ray fluorescence analysis are either solid or liquid and placed in a sample cup that is intact depending on the shape of the sample.

As a method of processing a sample by X-ray fluorescence analysis, there are a cutting method, a chip method, and a melting method. In pig iron analysis, the cutting method should cut pig iron to 4 x 4 cm, but at present there is no suitable cutting machine. In the case of a band saw, there is a disadvantage in that a lot of carbon is hardened by quenching and thus cutting is not possible. As a melting method, a method of pulverizing pig iron into chips to melt and melt it to make pellets, but there is no furnace that can be melted yet, even if there is a small amount of sample when making pellets by melting the melt and pig iron powder (about) 0.5kg), the trace of phosphorus in the iron, etc., the intensity of the analysis results (intensity) is small, making it difficult to detect. Therefore, it is most preferable to directly analyze pig iron itself.

The chip method is a method in which pig iron is crushed into powder by pressing chips, pressurized into pellets, and then placed in a sample cup for analysis. However, in the case of analyzing pig iron by such a method, when the X-rays are applied to the pellets, the pellets are broken and the powder is scattered to the surroundings, which causes a significant obstacle to the analysis results and causes errors in the results. There were a lot.

Accordingly, the present inventors have led to the present invention as a result of studying to provide a means for more effectively utilizing the chip method in the method of analyzing the components of pig iron by X-ray fluorescence analysis.

1 is an X-ray fluorescence peak of phosphorus, silicon and manganese obtained by the pig iron analysis result by the method according to the present invention

The present invention has been made to achieve the above object, in the pig iron analysis method by X-ray fluorescence analysis, the first step of making pellets by grinding pig iron into chips, and coating the X-ray transmissive film on the pellet and It provides a pig iron analysis method comprising a second step of simultaneously pressing and the third step of providing the pressure-coated pig iron to the X-ray fluorescence analysis device.

The present invention also provides a pig iron analysis method according to the pig iron analysis method, wherein the X-ray transmissive film is a polyethylene film.

The present invention comprises the first step is a step of filling the pellet cup with a certain amount of pig iron chips and putting the film adhesive ring on the pellet cup first press with a pellet press, the second step is the first press Pigment analysis consisting of coating the film on the film bonding ring by pressing X-ray-transmissive film on the pellet and only pressing the inner portion of the pellet cup, and removing the film portion that is out of the outer surface of the film bonding ring. Provide a method.

The present invention also provides a pig iron analysis method characterized in that in the above method, the film adhesive ring is made of PVC.

Hereinafter, the present invention will be described in detail.

As a device for producing pellets according to the present invention, a general compression molding apparatus may be used. In the field of powder metallurgy, the powder material is compacted into pellets having the desired shape before being sintered. Compression molding is a method of separating the irregularities of a two-part mold and processing by filling a cavity in a preheated mold with a molding powder having a weight or volume. When the mold is closed, the uneven parts are engaged with each other, and pressure is applied thereto. Usually, the hydraulic pressure is transmitted through an accumulator in the center of the press which can be hydraulically controlled or by means of a separately attached pump.

In the first step, pig iron is first ground into chips to be powdered. Thereafter, a predetermined amount of pig iron powder is filled into the lower mold of the pellet, that is, the pellet cup. The general pellet forming process is completed by pressing the upper mold in this state. However, in the present invention, the film adhesive ring is placed on the upper edge of the pellet cup filled with pig iron, and then pressed.

The film adhesive ring is not particularly limited in material, but for example, a PVC film may be used.

After this primary press process, the PVC ring is attached to the top of the pig iron pellets. In this way, the X-ray-transmissive plastic film is covered on the pellet-shaped pig iron first press, and then second press is performed again. At this time, the secondary press is performed such that pressure is applied only to the inside of the lower mold among the pellet molds. Since the secondary press process is a process for attaching the X-ray transmissive film to the upper portion of pig iron already having a pellet shape, the pressure is applied to the punch instead of the upper mold. At this time, the punch may be designed to be similar to the size of the inner circle of the pellet cup. The X-ray transmissive film may be a plastic film having X-ray transmissive properties, for example, a commercially available X-ray polyethylene film can be used.

When the process is completed, the film is attached to the adhesive ring by pressure, and as the punch presses only the pig iron pellet portion and not the outside of the pellet cup, the edge portion of the adhesive ring edge of the film is Will fall off.

As a result, the analytical pig iron pellets are attached to the X-ray transmissive film on the top, and in this state is provided to the X-ray fluorescence spectrometer. The coated iron pellets as described above do not have a pellet rupture phenomenon during X-ray fluorescence analysis, so that repeated analysis can be performed several times.

Example

1. XRF analysis possibility investigation test according to the present invention

The pig iron pellets coated with polyethylene film according to the present invention were applied to an X-ray fluorescence spectrometer, and the bursting of the samples and the intensity of peaks for each component were investigated.

As a result, the coated pellets did not burst during X-ray fluorescence, and several repeated analyzes were possible.

In addition, it can be seen that the intensity of the peak of each component is large enough to be sufficiently detected to enable analysis. (See Figure 1)

2. Numerical Comparison with Wet Analysis Results

The following table shows the results of wet analysis and pig iron analysis (mean value after five measurements) of 22 predetermined pig iron samples, respectively. As shown in the table, the results of the analytical method according to the present invention were almost the same as the results of the conventional wet method. In other words, the pig iron analysis method according to the present invention, compared with the conventional wet method that takes a long time, while the analysis time is much shorter, the accuracy of the result is the same level, a satisfactory alternative means for the wet analysis method I could see that.

no. Silicon (Si) A B Manganese (Mn) A B Phosphorus (A) B 1 2 3 4 5 0.650.920.630.691.09 0.620.890.650.681.10 0.170.220.210.190.20 0.170.210.210.200.20 0.1260.1130.1030.1090.093 0.1250.1100.1040.1100.095 678910 0.521.060.900.931.18 0.521.020.920.941.18 0.180.240.240.200.22 0.180.250.240.210.23 0.1050.1110.0950.0940.122 0.1090.1150.0970.0920.124 1112131415 0.230.841.120.880.87 0.250.821.100.890.86 0.300.220.150.360.24 0.290.220.140.350.24 0.0440.0370.0250.0410.045 0.0460.0360.0250.0410.044 16171819202122 0.730.910.561.320.370.780.38 0.710.940.571.330.380.780.37 0.340.330.170.430.410.590.38 0.340.330.180.430.420.600.38 0.0460.0490.0280.1350.1340.1330.151 0.0430.0480.0270.1360.1340.1320.152

In the above table, A is the result by the wet analysis method, B is the result obtained by the analysis method according to the present invention.

3. Comparison of analysis time with wet analysis

The following is a comparison of the analysis time by the general wet analysis and the X-ray fluorescence analysis according to the present invention. (When analyzing 10 samples)

1) Wet analysis

Sampling-30 minutes

Beaker, Weight Basis-30 minutes

Carbon, silicon, manganese, phosphorus, sulfur analysis-7 hours

Total-8 hours

2) X-ray fluorescence analysis according to the present invention

Sampling-50 minutes

Pellet Press and Film Coating-40 minutes

Carbon, sulfur analysis (C / S analyzer)-60 minutes

Manganese, Phosphorus, Sulfur (XRF)-30 minutes

Total-3 hours

As such, a difference of about 5 hours occurred when analyzing pig iron 10, and the analysis time according to the present invention was found to be significantly reduced.

In addition, there was no significant difference in the consumption of chemicals, vitreous instruments, etc., and the consumption of cups, films, PVC rings, etc. for XRF analysis.

As described above, in the pig iron analysis method according to the present invention in the pig iron analysis method by X-ray fluorescence analysis, the pig iron is pulverized into chips to make pellets and at the same time coated with the X-ray transmissive film on the pellets By providing the pressure-coated pig iron to the X-ray fluorescence spectrometer, it is possible to overcome the shortcomings of the general XRF method and the conventional wet analysis method, and make the most of the advantages of the XRF analysis method such as short analysis time. It can be effective.

Claims (4)

In the pig iron analysis method by X-ray fluorescence analysis, the first step of making the pellets by grinding the pig iron into chips, the second step of coating and pressing the X-ray transmissive film on the pellets and pressurized coated pig iron Pig iron analysis method comprising the step of providing a X-ray fluorescence analysis device. The pig iron analysis method of claim 1, wherein the X-ray transmissive film is a polyethylene film. The method of claim 1, wherein the first step comprises a step of filling a pellet cup with a predetermined amount of pig iron chips and placing a film adhesive ring on the pellet cup, followed by a primary press with a pellet press, In the second step, the X-ray-transmissive film is put on the first pressed pellet, and the second press is applied to only the inner portion of the pellet cup to coat the film on the film bonding ring, and at the same time, the film is released from the outer ring of the film bonding ring. Pig iron analysis method comprising a step of removing the film portion. The pig iron analysis method according to claim 3, wherein the film adhesive ring is made of PVC.