JP6683094B2 - Evaluation method of visible level of exhaust gas from sintering machine and selection method of carbonaceous material for sintering - Google Patents

Description

  The present invention relates to a method of evaluating a visible level of exhaust gas discharged from a stack of a sintering machine and a method of selecting a carbonaceous material used in the sintering machine in consideration of the visible level of the exhaust gas.

  This color is sometimes noticeable for the exhaust gas emitted from the stack of the sintering machine. The phenomenon in which the exhaust gas is colored white is not a phenomenon that directly affects the environment, but there is a concern that it may give a negative psychological impression to those who see the exhaust gas.

  It has been generally considered that the causative substance of coloring of the exhaust gas is an oil component (liquid volatile component) contained in the exhaust gas and generated from the volatile components of the carbonaceous material. However, it was empirically recognized that there is a difference in the coloring level of exhaust gas even when a plurality of types of carbonaceous materials having the same volatile content are used in a sintering machine. Therefore, unless the carbonaceous material is actually used in the sintering machine, the coloring level of the exhaust gas cannot be confirmed.

Japanese Patent Laid-Open No. 11-50159 JP 2001-011544 A JP, 2002-167621, A

Iron and Steel Vol.91 (2005) No.10 pp.757-762

According to the inventor of the present application, when the gas generated when the carbonaceous material was burned was analyzed, it was confirmed that a hydrocarbon component (CH ₄ ) was generated in the initial stage when the combustion of the carbonaceous material was started. A mass spectrum with a mass number of 15 was measured in order to grasp the amount of hydrocarbon components (CH ₄ ) generated. The peak area of this mass spectrum was correlated with the visible level of the exhaust gas from the sintering machine. I understood. Based on this finding, the present invention has been completed.

  The first invention of the present application is an evaluation method for evaluating the visible level of exhaust gas from a sintering machine. In this evaluation method, first, a mass spectrum having a mass number of 15 is measured for a gas generated when a carbonaceous material to be used in a sintering machine is burned in an air atmosphere. Then, the visible level is evaluated based on the measured peak area of the mass spectrum.

  As described above, the present inventor has found that there is a correlation between the peak area of the mass spectrum having a mass number of 15 and the visible level of the exhaust gas from the sintering machine. Therefore, by measuring the peak area of the mass spectrum having a mass number of 15, the visible level of the exhaust gas can be evaluated before the carbonaceous material is used in the actual sintering machine.

  When evaluating the visible level of the exhaust gas, the threshold value of the peak area can be set in advance. Then, when the measured peak area is equal to or less than the threshold value, it can be evaluated that the exhaust gas is white and cannot be visually recognized.

  The peak area can be the peak area per unit weight of the carbonaceous material. Thereby, even if the weight of the carbonaceous materials when measuring the peak area varies, the visible level of the exhaust gas can be uniformly evaluated for these carbonaceous materials.

  If the differential thermal balance-mass spectrometer is used, it is possible to achieve both combustion of the carbonaceous material in an air atmosphere and measurement of a mass spectrum having a mass number of 15.

  The second invention of the present application is a selection method for selecting a carbonaceous material used in a sintering machine. In this selection method, first, a mass spectrum having a mass number of 15 is measured for a gas produced when a carbonaceous material is burned in an air atmosphere. Then, the carbonaceous material whose measured peak area of the mass spectrum is equal to or less than a predetermined threshold value is selected as the carbonaceous material used in the sintering machine.

  As described in the first invention of the present application, the peak area of the mass spectrum having the mass number of 15 has a correlation with the visible level of the exhaust gas generated by the combustion of the carbonaceous material. Therefore, the peak area when the exhaust gas is visually recognized as white can be predetermined as a threshold value. If a carbonaceous material having a peak area equal to or less than a threshold value is selected as a carbonaceous material used in a sintering machine, even if this carbonaceous material is loaded into the sintering machine, a white color is obtained from the stack of the sintering machine. It is possible to suppress the generation of visually recognized exhaust gas.

It is a flowchart explaining the method of evaluating the visible level of exhaust gas. It is a figure which shows the weight reduction amount of a carbonaceous material, and the mass spectrum of various components (mass number is 15,18,44) contained in exhaust gas, when a predetermined carbonaceous material is burned.

  An embodiment of the present invention will be described. The present embodiment evaluates the visible level of the exhaust gas discharged into the atmosphere from the stack of the sintering machine for the carbon material used in the sintering machine (referred to as the sintering carbon material). The visible level is a level related to visual recognition of the color of exhaust gas (specifically, white). Here, the higher the visible level, the more easily the exhaust gas is visually recognized as white. In other words, the lower the visible level, the less likely the exhaust gas is visually recognized as white.

  As the carbonaceous material for sintering, powder coke, anthracite, semi-anthracite, and char can be used. When a carbonaceous material having a high volatile content is used in a sintering machine, a substance derived from the volatile content may flow into the exhaust gas and adhere to the electrostatic precipitator as an oil content. Therefore, as the carbonaceous material for sintering, carbonaceous material whose volatile content is suppressed, specifically, powdered coke, anthracite, semi-anthracite, and char can be used.

  In the present invention, the anthracite is coal having a volatile content of less than 10%, and the semi-anthracite is a coal having a volatile content of 10% or more and 15% or less. Char is a carbonaceous material whose volatile content has been reduced by heat-treating (pyrolysis, carbonization) coal having a high volatile content in an oxygen-free atmosphere. The coke volatiles are lower than those of anthracite, semi-anthracite and char.

It has been found that when the carbonaceous material is burned, a hydrocarbon component (that is, CH ₄ ) is generated in the initial stage of starting the burning. In the present embodiment, attention is paid to the fact that the amount of hydrocarbon components (CH ₄ ) generated is correlated with the visible level of exhaust gas, and the visible level of exhaust gas is determined based on the amount of hydrocarbon components (CH ₄ ) generated. I am evaluating.

There is a correlation described below between the amount of hydrocarbon components (CH ₄ ) generated and the visible level of exhaust gas. That is, the greater the amount of hydrocarbon component (CH ₄ ) generated, the higher the visible level, and the more easily the exhaust gas is recognized as white. In other words, the smaller the amount of hydrocarbon component (CH ₄ ) generated, the lower the visible level, and the more difficult it is for the exhaust gas to be recognized as white.

Based on the above-mentioned correlation, the visible level of the exhaust gas when the carbonaceous material is used in the sintering machine can be evaluated by measuring the amount of hydrocarbon component (CH ₄ ) generated in the carbonaceous material. This makes it possible to understand the visible level of exhaust gas before actually using the carbon material in a sintering machine, or to select a carbon material that can reduce the visible level of exhaust gas as the carbon material for sintering. be able to.

In the present invention, the amount of hydrocarbon component (CH ₄ ) generated is the peak area in a mass spectrum having a mass number (m (mass) / z (charge)) of 15. By using the differential thermal balance-mass spectrometer, a mass spectrum having a mass number (m / z) of 15 can be measured for the exhaust gas generated when the carbonaceous material is burned in an air atmosphere. Then, by measuring the peak area of this mass spectrum, the generation amount of the hydrocarbon component (CH ₄ ) can be specified.

The mass number of the hydrocarbon component (CH ₄ ) is 16, but the mass number of oxygen atoms used for burning the carbonaceous material is also 16. Therefore, it is difficult to identify the hydrocarbon component (CH ₄ ) contained in the exhaust gas even if the mass spectrum with the mass number of 16 is measured. On the other hand, when the mass spectrum is measured, most of the hydrocarbon component (CH ₄ ) is ionized, so that the hydrocarbon component (CH ₃ ⁺ ) is generated as a fragment. Since the mass number of the hydrocarbon component (CH ₃ ⁺ ) is 15, the hydrocarbon component (CH ₄ ) can be specified by measuring the mass spectrum with the mass number of 15.

  In order to measure the mass spectrum with a mass number of 15, when burning the carbonaceous material, it is necessary to make the combustion atmosphere of the carbonaceous material equal to the combustion atmosphere of the carbonaceous material in the actual sintering machine. Therefore, in the present embodiment, the carbonaceous material is burned in the air atmosphere.

Further, when burning the carbonaceous material, it is preferable to raise the atmospheric temperature of the carbonaceous material to a temperature equal to or higher than a target temperature for completely burning the carbonaceous material. The target temperature can be determined in advance based on experiments. By raising the atmospheric temperature of the carbonaceous material to the target temperature or higher and completely burning the carbonaceous material, it becomes easy to grasp the generation amount of the hydrocarbon component (CH ₃ ⁺ ) contained in the exhaust gas. In other words, a mass spectrum having a mass number of 15 can be accurately measured.

After measuring the peak area of the mass spectrum having a mass number of 15, that is, the generation amount of the hydrocarbon component (CH ₄ ), the visible level of the exhaust gas can be evaluated based on this generation amount. When evaluating the visible level of exhaust gas, for example, the visible level of exhaust gas can be divided into a plurality of levels, and the range of the amount of hydrocarbon components (CH ₄ ) generated corresponding to each level can be determined in advance. Thereby, the visible level of the exhaust gas can be evaluated by specifying which of the plurality of levels the generated amount of the hydrocarbon component (CH ₄ ) generated belongs to.

The number of visible levels can be appropriately determined. For example, it can be divided into three levels such as a level at which white is invisible, a level at which white is slightly visible, and a level at which white is visible. By thus determining the visible level of the exhaust gas, the range of the amount of hydrocarbon component (CH ₄ ) generated corresponding to each level can be determined. Here, by determining the correlation between the visible level and the generation amount of the hydrocarbon component (CH ₄ ) based on the experiment, the range of the generation amount of the hydrocarbon component (CH ₄ ) corresponding to each level can be determined. it can. Then, the visible level can be determined by determining which level of the generated amount of the measured hydrocarbon component (CH ₄ ) is included in the range of the generated amount.

When measuring a mass spectrum having a mass number of 15 for a plurality of types of carbonaceous materials, it is necessary to make the weight of the carbonaceous materials constant when installed in a differential thermal balance-mass spectrometer. This is because if the weight of the carbonaceous material is different, the amount of gas generated by the combustion of the carbonaceous material is different, and even if the amount of hydrocarbon component (CH ₄ ) generated is measured, the visible level of the exhaust gas is uniform. It is not possible to make a comprehensive evaluation.

On the other hand, when evaluating the visible level of exhaust gas, the amount of hydrocarbon component (CH ₄ ) generated per unit weight of carbonaceous material can be calculated. Differential thermal balance-The unit weight of the carbonaceous material is measured by measuring the weight Mc of the carbonaceous material when it is installed in the mass spectrometer and dividing the generated amount of the measured hydrocarbon component (CH ₄ ) by the weight Mc. The amount of hydrocarbon component (CH ₄ ) generated per hit can be calculated. By calculating the generation amount of the hydrocarbon component (CH ₄ ) per unit weight of the carbonaceous material, the mass Mc of the carbonaceous material when different types of carbonaceous materials are installed in the differential thermal balance-mass spectrometer are different. However, it is possible to perform a uniform evaluation of the visible level of exhaust gas.

As the carbonaceous material used in the differential thermal balance-mass spectrometer, it is preferable to use dried carbonaceous material. If the amount of water contained in the carbonaceous material is different, the measurement results of the differential thermal balance-mass spectrometer may vary. In this case, it becomes difficult to uniformly evaluate the visible level based on the generation amount of the hydrocarbon component (CH ₄ ) for a plurality of types of carbon materials. Therefore, it is preferable to dry the carbonaceous material before installing the carbonaceous material in the differential thermal balance-mass spectrometer.

  When the carbonaceous material is dried, it is preferable to heat the carbonaceous material at a temperature lower than the temperature at which the combustion of the carbonaceous material is started and at a temperature higher than or equal to the temperature required to evaporate the water contained in the carbonaceous material. .

  Further, when drying the carbonaceous material, it is preferable to heat the carbonaceous material under an atmosphere of an inert gas. Even when the carbonaceous material is heated at a temperature lower than the temperature at which the combustion of the carbonaceous material starts, the carbonaceous material reacts with oxygen in the oxygen atmosphere. Therefore, in order to prevent the carbonaceous material from reacting with oxygen, it is preferable to heat the carbonaceous material in an atmosphere of an inert gas. As the inert gas, for example, argon gas can be used.

  In the above-described embodiment, a procedure (one example) for evaluating the visible level of exhaust gas will be described with reference to the flowchart shown in FIG.

  In step S101, the carbonaceous material to be evaluated is installed in a differential thermal balance-mass spectrometer, and the carbonaceous material is burned in an air atmosphere. Here, the atmospheric temperature of the carbonaceous material is raised to the above-mentioned target temperature or higher. A mass spectrum having a mass number (m / z) of 15 is measured for the gas generated by the carbonaceous fuel.

In step S102, the peak area of the mass spectrum, that is, the generation amount of the hydrocarbon component (CH ₄ ) is calculated based on the mass spectrum measured in the process of step S101. In step S103, the visible level of the exhaust gas is evaluated based on the generation amount of the hydrocarbon component (CH ₄ ) calculated in the process of step S102. The evaluation method is as described above.

The generation amount of the hydrocarbon component (CH ₄ ) can be calculated once or plural times for one kind of carbonaceous material. When the generation amount of the hydrocarbon component (CH ₄ ) is calculated a plurality of times, the average value of the generation amount can be calculated.

According to this embodiment, focusing on the fact that there is a correlation between the generation amount of the hydrocarbon component (CH ₄ ) and the visible level of the exhaust gas, based on the generation amount of the hydrocarbon component (CH ₄ ), The visible level of exhaust gas can be evaluated. When evaluating the visible level, it suffices to burn the carbonaceous material using a differential thermal balance-mass spectrometer, so the visible level of the exhaust gas should be evaluated even if the carbonaceous material is not used in an actual sintering machine. You can

  If the visible level of the exhaust gas is evaluated as in the present embodiment, the carbonaceous material used in the actual sintering machine can be selected based on this evaluation result. That is, it is possible to select a carbonaceous material in which the exhaust gas is unlikely to be white, from a plurality of types of carbonaceous materials. Then, by using the selected carbonaceous material in an actual sintering machine, exhaust gas visually recognized as white can be suppressed from being discharged into the atmosphere.

  In the above embodiments, the case where the carbonaceous material is one brand alone has been described. Here, in the sintering operation, a mixed carbonaceous material (a mixture of carbonaceous materials having different volatile components) in which a plurality of types of carbonaceous materials are mixed may be charged into a sintering machine. Even when the mixed carbonaceous material is used, by treating it as one brand, the visible level of the exhaust gas can be evaluated as in the present embodiment.

When the mixed carbonaceous material is used, the amount of hydrocarbon component (CH ₄ ) generated in the mixed carbonaceous material is measured in advance, and the mixed carbonaceous material whose generated amount is equal to or less than a threshold value can be used. This threshold is an amount of hydrocarbon component (CH ₄ ) generated corresponding to a visible level that is difficult to visually recognize when the exhaust gas is white, and can be set in advance. On the other hand, the amount of hydrocarbon component (CH ₄ ) generated can be measured for each type of carbonaceous material forming the mixed carbonaceous material, and it can be confirmed whether or not the generated amount is less than or equal to a threshold value. Then, a mixture of carbonaceous materials when the generation amount is equal to or less than the threshold value can be used as the carbonaceous material for sintering.

  Examples of the present invention will be described below.

Powder coke, eight types of carbonaceous materials, and mixed carbonaceous materials were prepared, and the amount of hydrocarbon component (CH ₄ ) generated was calculated for each of the powdered coke and each carbonaceous material.

(Type of carbon material)
The analysis values (industrial analysis values and elemental analysis values) of the powder coke, the eight kinds of carbon materials A to H, and the mixed carbon materials I and J are as shown in Table 1 below. The eight types of carbon materials A to H include char, anthracite and semi-anthracite. The mixed carbonaceous material I is a carbonized product (char) produced by carbonizing carbon using a vertical shaft furnace (moving bed). Since this char causes uneven burning due to the structure of the shaft furnace, a char having a high volatile content (volatile content of 20 to 30%) and a char having a low volatile content (volatile content of 5% or less) are mixed at a mass ratio of 2: 8. It is in the state of doing. Here, such char is taken up as a mixed carbonaceous material. The mixed carbonaceous material J is assumed to be so-called miscellaneous coal, which is recovered in a state in which coal with a low volatile content or coal with a low volatile content is mixed with coal with a high volatile content used in an iron mill. This time, this miscellaneous coal was reproduced by mixing coal (bituminous coal) having a volatile content of 20 to 40% and coke having a volatile content of 1% or less at a mass ratio of 4: 6.

(Measurement of hydrocarbon component (CH ₄ ) generation amount)
Coke powder and carbonaceous materials A to J were dried, and 15 mg of each sample prepared to have a particle size of 150 to 250 μm was prepared. When measuring a mass spectrum having a mass number (m / z) of 15 using a differential thermal balance-mass spectrometer, in order to ensure measurement accuracy, powder coke or carbonaceous material having a particle size of 150 to 250 μm It is preferable to use A to J.

  As a differential thermal balance-mass spectrometer, Bruker AXS / TG-DTA2000SA + MS-9610 was used. The powder cokes and the carbon materials A to J were installed in a differential thermal balance-mass spectrometer, and the powder cokes and the carbon materials A to J were burned in an air atmosphere. Here, as the air atmosphere, air was supplied at a flow rate of 50 ml / min. At a temperature rising rate of 50 ° C./min, the ambient temperature was raised from room temperature to 1450 ° C. (temperature above the target temperature). When raising the atmospheric temperature, it is preferable to keep the temperature rising rate constant in order to suppress uneven distribution of combustion in the powder coke and the carbonaceous materials A to J.

A mass spectrum having a mass number (m / z) of 15 was measured for the gas generated by the combustion of the powder coke and the carbon materials A to J by a differential thermal balance-mass spectrometer. Here, as the measurement conditions of the differential thermal balance-mass spectrometer, the emission voltage was 100 [μA], the SEM voltage was 950 [V], and the degree of vacuum was 1.9E-3 [Pa] (filter split mode). . When measuring the mass spectrum of the powder coke and the carbon materials A to J, it is necessary to fix the measurement conditions. If the measurement conditions are different, the peak area of the mass spectrum changes, and it becomes difficult to perform a uniform visual level evaluation based on the amount of hydrocarbon component (CH ₄ ) generated. Therefore, it is necessary to fix the measurement conditions and measure the mass spectrum having a mass number (m / z) of 15.

  FIG. 2 shows the measurement results for the carbon material F shown in Table 1. In FIG. 2, the horizontal axis represents the ambient temperature. In addition, the vertical axis on the left side represents the amount of reduction [mg] in weight of the carbonaceous material, and the vertical axis on the right side represents the intensity [A] of the mass spectrum.

In addition to the mass spectrum having a mass number (m / z) of 15, FIG. 2 shows mass spectra having a mass number (m / z) of 18,44. The mass spectrum with a mass number (m / z) of 18 is derived from the water component (H ₂ O), and the mass spectrum with a mass number (m / z) of 44 is a carbon dioxide component (CO ₂ ) Is derived from.

When the combustion of the carbonaceous material F is started, the weight of the carbonaceous material F measured by the differential thermal balance-mass spectrometer decreases. In FIG. 2, when the atmospheric temperature exceeds 400 [° C.], the weight of the carbonaceous material F begins to decrease. Further, when the atmospheric temperature exceeds 400 [° C.], the intensity of the mass spectrum having a mass number (m / z) of 15 starts to increase. In FIG. 2, a mass spectrum having a mass number (m / z) of 15 is generated in the atmosphere temperature range of 400 to 700 [° C.], and a peak of this mass spectrum exists. The area of the region R shown in FIG. 2 is the peak area in the mass spectrum having a mass number (m / z) of 15, that is, the amount of hydrocarbon component (CH ₄ ) generated.

  In the coke dust and the carbonaceous material A, a mass spectrum having a mass number (m / z) of 15 was not generated. In the carbonaceous materials B to E and G to J, the mass spectra having a mass number (m / z) of 15 showed peaks as in the carbonaceous material F. However, carbon materials B to J had different mass spectrum intensities with a mass number (m / z) of 15.

Table 2 below shows the measurement results of the amounts of hydrocarbon components (CH ₄ ) generated for the powder coke and the carbon materials A to J. Here, the generation amount of the hydrocarbon component (CH _4), calculates the amount of generated hydrocarbon components in per unit weight of the carbonaceous material (CH _4).

(Sintering test)
The visible level of the exhaust gas discharged from the chimney was confirmed by performing the firing process using the experimental equipment (known as a pan) in which the actual sintering machine was downsized. Here, only a cyclone for removing dust contained in the exhaust gas and a suction blower are arranged in the exhaust gas moving passage between the pot and the chimney. Moreover, in order to confirm the visible level of exhaust gas, no exhaust gas treatment equipment is installed in the exhaust gas passage between the pan and the chimney. The diameter of the pot is 300 [mm], and the thickness of the pot is 600 [mm]. The suction pressure of the suction blower is 1530 [kPa].

  The raw materials used in the sintering test are shown in Table 3 below.

  Brands A to E were prepared as iron ores, and these iron ores were mixed at the mass% shown in Table 3 above. Further, limestone, quicklime, and serpentine, which are auxiliary materials, were mixed with the iron ore. The mixing amount (mass%) of limestone, quick lime and serpentine is as shown in Table 3 above. On the other hand, the return ore and powder coke were blended with the mixture of the iron ore and the auxiliary raw material, and the return ore and each of the carbonaceous materials A to J (see Table 1 above) were blended.

  The content of the return ore was set to 15% by mass with respect to the total mass of the iron ore and the auxiliary raw materials. Further, the amount of the powder coke mixed with the return ore was set to 4.5% by weight based on the total mass of the iron ore and the auxiliary raw material. On the other hand, regarding each of the carbonaceous materials A to J mixed with the return ore, each carbonaceous material is contained so that the amount of fixed carbon contained in each carbonaceous material A to J becomes equal to the amount of fixed carbon contained in the powder coke. The compounding amounts of A to J were adjusted.

  The coke powder and the carbonaceous materials A to J were prepared so that the particle size distributions would be the same. Table 4 below shows the particle size distribution of the powder coke and the carbonaceous materials A to J.

Table 5 below shows the results of confirming the visible level of exhaust gas in the above-mentioned sintering test. Here, the visible level of the exhaust gas was confirmed by visually observing the exhaust gas discharged from the chimney. When the white color of the exhaust gas could not be confirmed at all, it was marked with “◯”, when the white color of the exhaust gas could be confirmed slightly, it was marked with “Δ”, and when the white color of the exhaust gas could be confirmed, it was marked with “x”. On the other hand, in Table 5 below, the generation amount of the hydrocarbon component (CH ₄ ), the amount of volatile components, and the sulfur content (Total-S) are shown for the powder coke and the carbon materials A to J.

As shown in Table 5 above, the visible level of exhaust gas correlates with the amount of hydrocarbon component (CH ₄ ) generated. Specifically, regarding the powder coke and the carbonaceous materials A to C, the generation amount of the hydrocarbon component (CH ₄ ) is 3.00E-7 [A · sec / g-sample (dry)] or less, and the visible level. Was "○". Regarding carbon materials D to F and I, the amount of hydrocarbon component (CH ₄ ) generated was more than 3.00E-7 [A · sec / g-sample (dry)] and not more than 1.00E-6. And the visible level was “Δ”. Regarding the carbon materials G to J, the generation amount of the hydrocarbon component (CH ₄ ) was larger than 1.00E-6, and the visible level was “x”.

  On the other hand, according to Table 5 above, it can be seen that the visible level of the exhaust gas has no correlation with the volatile content of the carbonaceous material. For example, when focusing on the carbonaceous materials B, C, and E to G as anthracite coal, a correlation cannot be found between the visible level of the exhaust gas and the volatile content of the carbonaceous material. Further, according to Table 5 above, it can be seen that the visible level of the exhaust gas has no correlation with the sulfur content (Total-S) of the carbonaceous material. For example, focusing on the carbonaceous materials B, C, and E to G as anthracite coal, it is not possible to find a correlation between the visible level of the exhaust gas and the sulfur content (Total-S) of the carbonaceous material.

According to the test results shown in Table 5, the carbonaceous material in which the amount of hydrocarbon component (CH ₄ ) generated is 3.00E-7 [A · sec / g-sample (dry)] or less is actually sintered. It is possible to suppress the generation of white exhaust gas.

  When the exhaust gas treatment equipment (dust collector, denitration equipment, desulfurization equipment, etc.) is provided, the components derived from the white exhaust gas may be removed in the exhaust gas treatment equipment. In that case, it cannot be denied that the components derived from the white exhaust gas adversely affect the exhaust gas treatment equipment (such as shortening the life of the adsorbent).

Here, when selecting the carbonaceous material used in the actual sintering machine, the threshold value of the generation amount of the hydrocarbon component (CH ₄ ) may be determined in advance. Then, a carbonaceous material whose measured hydrocarbon component (CH ₄ ) generation amount is equal to or less than a threshold value can be selected as the sintering carbonaceous material. In the example described above, the threshold value can be 3.00E-7 [Asec / g-sample (dry)]. Since the amount of hydrocarbon component (CH ₄ ) generated changes according to the measurement conditions when measuring the mass spectrum, the threshold value under the predetermined measurement conditions may be determined in advance.

Claims (5)

An evaluation method for evaluating the visible level of exhaust gas produced by a sintering machine,
A mass spectrum having a mass number of 15 is measured for a gas generated when the carbonaceous material to be used in the sintering machine is burned in an air atmosphere,
Based on the measured peak area of the mass spectrum, evaluate the visible level,
An evaluation method characterized by the above.   The evaluation method according to claim 1, wherein when the peak area is equal to or less than a predetermined threshold value, the exhaust gas is evaluated as a level at which the exhaust gas cannot be visually recognized as white in the evaluation of the visible level.   The said peak area is a peak area per unit weight of the said carbonaceous material, The evaluation method of Claim 1 or 2 characterized by the above-mentioned.   4. The evaluation method according to claim 1, wherein the carbonaceous material is burned in an air atmosphere and the mass spectrum is measured using a differential thermal balance-mass spectrometer. A selection method for selecting the carbonaceous material used in the sintering machine,
A mass spectrum having a mass number of 15 is measured for a gas produced when the carbonaceous material is burned in an air atmosphere,
The carbonaceous material whose peak area of the measured mass spectrum is less than or equal to a predetermined threshold value is selected as the carbonaceous material used in the sintering machine.
A method of selecting a carbonaceous material for sintering, which is characterized in that

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