JP2015017002A - Method and apparatus for preventing solidification of fly ash - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method and apparatus for preventing solidification of fly ash which can stably prevent solidification of fly ash.SOLUTION: A method for preventing solidification of fly ash performs: a measurement step of measuring the absolute humidity of a storage chamber storing fly ash; an introduction step of introducing fly ash into the storage chamber; and a storage step of, after the introduction step, storing the fly ash while controlling the absolute humidity of the storage chamber based on the measurement result in the measurement step so that the absolute humidity becomes equal to or smaller than a predetermined reference value not more than 15 g/m.

Description

  The present invention relates to an anti-caking method for preventing caking of fly ash and an anti-caking device for fly ash.

Fly ash used as a cement material is coal ash generated by burning coal pulverized mainly in a coal-fired power plant or the like.
Fly ash has the property of agglomerating and solidifying (hereinafter, also simply referred to as “consolidating”) when it absorbs moisture, and depending on the storage conditions, it may cause a problem in use. In addition, for example, when it is consolidated during transportation by a ship or the like, a carry-out defect (hereinafter also referred to as occupancy) occurs, and a large berthing cost and a processing cost are required.
Therefore, it is required to prevent the fly ash from consolidating.

Various methods are known as methods for preventing the consolidation of fly ash.
For example, Non-Patent Document 1 describes that fly ash is stored in an environment having an environmental humidity (critical relative humidity) of 70% or less to prevent caking.
Non-Patent Document 2 describes that caking is prevented by placing fly ash in an atmosphere having a relative humidity of 50% or less.

  The methods described in Non-Patent Documents 1 and 2 are methods that prevent the consolidation of fly ash by managing the relative humidity. There are variations in the anti-caking effect, and particularly during transportation by a ship or the like, the temperature change is large, so it is difficult to prevent caking stably.

Shunichiro Naito, Hirofumi Mori, Osamu Yamaguchi, Masahiro Kato, Hidetomo Noda, “Elucidation of the mechanism of coal ash consolidation, Part 1” The 110th Academic Lecture Meeting of the Society of Inorganic Materials, No. Unknown, June 2005 Published on February 2nd, Publisher: Inorganic Materials Society Yoshihiro Kishi, Hideki Kanda, Yuzo Shirai, Yoshimichi Okami, “Examination of solidification prevention method of coal ash by humidification and additive mixing”, Journal of Powder Engineering, 2005, 42, 160-466, 4-10

  Accordingly, in view of the above-described conventional problems, the present invention provides a fly ash consolidation prevention method and a fly ash consolidation prevention apparatus that can stably prevent the consolidation of fly ash. Is an issue.

  The present inventors have found that consolidation of fly ash occurs mainly depending on absolute humidity, not relative humidity, and have completed the present invention.

That is, the method for preventing caking of fly ash according to the present invention includes a measuring step for measuring absolute humidity in a storage chamber for storing fly ash, an introduction step for introducing fly ash into the storage chamber, and after the introduction step, And a storage step of storing fly ash while controlling the absolute humidity of the storage chamber to be not more than a predetermined reference value that is not more than 15 g / m ³ based on the result measured in the measurement step.

A measurement process for measuring the absolute humidity of the storage room for storing fly ash, an introduction process for introducing fly ash into the storage room, and an absolute humidity of the storage room based on the results measured in the measurement process after the introduction process By carrying out the storage step of storing fly ash while controlling it to be below a predetermined reference value of 15 g / m ³ or less, it is possible to stably prevent the fly ash from consolidating.

As one aspect of the present invention, the reference value may be 10 g / m ³ or more and 15 g / m ³ or less.

When the reference value is 10 g / m ³ or more and 15 g / m ³ or less, the fly ash can be efficiently consolidated without excessive dehumidification.

  As one aspect of the present invention, the relative humidity of the storage chamber may be measured in the measurement step, and the relative humidity of the storage chamber may be controlled to be 50% or less in the storage step.

The fly ash anti-caking device according to the present invention includes a storage chamber in which fly ash is stored, a measuring device for measuring absolute humidity in the storage chamber, and an absolute humidity in the storage chamber of 15 g / m ³ or less. And a control device that controls the reference value.

  Further, the measuring device may be arranged in the storage chamber located above the fly ash when the fly ash is stored.

  In addition, the control device includes a gas introduction unit that introduces gas into the storage chamber and a gas discharge unit that discharges gas from the storage chamber, and the gas introduction unit is based on a result measured by the measurement device. Low humidity air having an absolute humidity lower than the absolute humidity of the storage chamber may be introduced into the storage chamber from the section, and the gas in the storage chamber may be discharged from the gas discharge section.

  Further, the gas introduction part may be arranged in the storage chamber so as to be lower than the fly ash when the fly ash is stored.

  As described above, according to the present invention, consolidation of fly ash can be stably prevented.

The graph which shows the relationship between absolute humidity and the incidence rate of occupancy. The graph which shows the relationship between relative humidity, absolute humidity, and the incidence rate of occupancy.

The fly ash consolidation prevention method and fly ash consolidation prevention apparatus according to the present invention will be described below.
First, the anti-caking apparatus for fly ash according to the present invention will be described.

The fly ash anti-caking device of the present embodiment includes a storage chamber in which fly ash is stored, a measuring device that measures absolute humidity in the storage chamber, and an absolute humidity in the storage chamber of 15 g / m ³ or less. And a control device that controls the reference value.

The storage room is not particularly limited as long as it has a space where fly ash can be stored. For example, if the fly ash is to be transported by ship, store the fly ash in a warehouse. In this case, a warehouse or the like is cited as a storage room.
The storage chamber is provided with known powder introduction means such as an air slider capable of introducing fly ash into the storage chamber as necessary.

  The measuring device is not particularly limited as long as it can measure the absolute humidity in the storage room. For example, an absolute humidity measuring device that can measure absolute humidity that directly measures the absolute humidity of the storage room, a measuring device that measures relative humidity and temperature, and the like can be given. In the case of using the relative humidity measuring device, the absolute humidity can be obtained from the table representing the relationship between the temperature and the saturated water vapor amount from the measurement result of the relative humidity and the temperature.

  In addition, the caking prevention apparatus of this embodiment may be provided with the apparatus which measures relative humidity simultaneously with the apparatus which can measure absolute humidity as the said measuring apparatus. The device capable of measuring relative humidity may be provided separately from the device that measures absolute humidity, or may be a measuring device that measures relative humidity and temperature as a measuring device as described above. In this case, relative humidity and absolute humidity can be measured using the same apparatus.

The measurement device is not particularly limited as long as the measurement device is disposed at a position where the absolute humidity and relative humidity in the storage chamber can be measured. For example, when the fly ash is stored in the storage chamber, It is preferable that the storage chamber is disposed above the fly ash.
The arrangement at this position is preferable because the absolute humidity in the storage room can be measured with higher accuracy.
In addition, although the temperature of fly ash varies depending on the season and the like, for example, when storing high-temperature fly ash of about 70 ° C. transferred from a power plant or the like in the storage room, the measuring device is located above the fly ash. By being arranged, there is an advantage that the measuring device does not deteriorate or break down.
Examples of the position above the fly ash include a ceiling part of a storage room and an upper part of a side wall.

The control device is not particularly limited as long as it can be controlled so that the absolute humidity in the storage room becomes a reference value of 15 g / m ³ or less.
The control device includes, for example, a gas introduction unit that introduces gas into the storage chamber, and a gas discharge unit that discharges gas from the storage chamber, and based on the measurement result of the measurement device, the gas The introduction unit may be configured to introduce low-humidity air whose absolute humidity is lower than the absolute humidity of the storage chamber into the storage chamber and to discharge the gas in the storage chamber from the gas discharge unit.

Examples of the gas introduction unit and the gas discharge unit include a conduit to which an opening / closing device such as a valve is attached, and a pump for introducing or discharging a gas such as air is attached to the conduit. May be.
Further, the opening / closing device or pump of the gas introduction unit and the gas discharging unit may be configured to be opened / closed or movable automatically or manually based on the measurement result of the measurement device.

It is preferable that the gas introduction part of the present embodiment is arranged in the storage chamber so as to be lower than the fly ash when the fly ash is stored.
Examples of the position where the gas introduction part is below the fly ash include the bottom part of the storage chamber and the lower part of the side wall. In order to arrange the gas introduction part at such a position, for example, one end of the conduit of the gas introduction part is attached so as to open near the bottom part of the storage chamber or the bottom part of the side wall.

  As the gas introduction part, for example, an air slider for introducing fly ash into a storage room is used, and a blower is connected to the air slider so that low-humidity air can be introduced into the storage room. Part.

  When the gas introduction unit is disposed in the storage chamber so that the fly ash is located below the fly ash when the fly ash is stored, the gas introduction unit is configured to use the gas based on the result measured by the measurement device. When introducing low-humidity air whose absolute humidity is lower than the absolute humidity of the storage room from the introduction part into the storage room, the low-humidity air will pass through the inside of the fly ash, and while drying the inside of the fly ash, the storage room Therefore, the fly ash can be prevented from being consolidated more accurately.

  The control device of the present embodiment may be a device that can control the relative humidity simultaneously with the control of the absolute humidity in the storage room. In this case, a device similar to the control device that controls the absolute humidity may be used as the control device.

Next, a method for preventing caking of fly ash according to the present embodiment will be described.
The method for preventing caking of fly ash according to the present embodiment includes a measurement step for measuring the absolute humidity of a storage chamber for storing fly ash, an introduction step for introducing fly ash into the storage chamber, and the measurement after the introduction step. A storage step of storing fly ash while controlling the absolute humidity of the storage chamber to be not more than a predetermined reference value that is not more than 15 g / m ³ based on the results measured in the step.
In the present embodiment, for example, a method for preventing fly ash consolidation using the fly ash consolidation prevention device will be described.

Fly ash is coal ash produced as a by-product when pulverized coal is burned in a thermal power plant or the like, and is usually a nearly spherical particle having a diameter of about 5 to 250 μm.
The main component of the fly ash is SiO ₂ , but slight calcium and sulfate ions are also present on the fly ash surface.
When calcium and sulfate ions react with each other on the fly ash surface, half water or anhydrous gypsum is produced, and further, when two water gypsum is produced from the half water or anhydrous gypsum by moisture absorption, the fly ash particles are interlinked. It is said that the phenomenon of consolidation occurs. That is, caking is caused by the presence of moisture in the environment where fly ash is stored. Therefore, caking can be prevented by controlling the humidity of the fly ash storage chamber.

(Measurement process)
In the fly ash caking prevention method of the present embodiment, a measurement step of measuring the absolute humidity of the storage room is performed.
As described above, since fly ash is consolidated by moisture, the humidity of the storage chamber becomes a problem when stored.
In the measurement process of this embodiment, the absolute humidity of a storage room for storing fly ash is measured.
In this embodiment, the absolute humidity is measured using the measuring device.

In addition, the measurement step may be performed before the introduction step or after the introduction step.
When the measurement step is performed after the introduction step, the absolute humidity of the storage chamber is measured within 0 to 30 minutes, preferably within 0 to 10 minutes after the fly ash is introduced into the storage chamber. This is preferable because it can prevent the fly ash from solidifying more stably.

In the measurement process of the present embodiment, relative humidity may be measured in addition to absolute humidity.
In such a case, by controlling the relative humidity of the storage chamber in the storage step to be described later, consolidation of fly ash can be prevented more accurately.

(Introduction process)
In the method for preventing fly ash consolidation according to this embodiment, an introduction step of introducing the fly ash into the storage chamber is performed.
Fly ash is introduced into the storage chamber using the powder introduction means such as an air slider.

(Storage process)
In the method for preventing caking of fly ash according to the present embodiment, after the introduction step, the absolute humidity of the storage chamber is less than a predetermined reference value of 15 g / m ³ or less based on the result measured in the measurement step. A storage process for storing fly ash while controlling is performed.

In the fly ash caking prevention method of the present embodiment, a predetermined reference value having an absolute humidity of 15 g / m ³ or less may be determined in advance.
The reference value is 15 g / m ³ or less, preferably 10 g / m ³ or more and 15 g / m ³ or less.
When the reference value is 15 g / m ³ or less, by controlling the absolute humidity of the storage room in which the fly ash is stored in the storage process to a reference value or less, consolidation can be prevented stably.
When the reference value is 10 g / m ³ or more, it is possible to stably prevent caking of fly ash without excessive dehumidification of the storage room even in a hot and humid environment such as summer. it can.

The determination of the reference value may be performed after the measurement process or may be performed before the measurement process.
When the reference value is determined after the measurement step, the reference value can be determined based on the measurement result obtained by measuring the absolute humidity of the storage room in the measurement step.
For example, when the absolute humidity of the storage room measured in the measurement step is relatively high, the reference value is determined to be higher within the range, and within the range when the humidity is relatively low. Thus, it is possible to determine an appropriate reference value corresponding to a change in the environment, for example, by determining a lower reference value. Therefore, the solidification of fly ash can be stably prevented without excessively dehumidifying the storage chamber.

  Furthermore, the determination of the reference value may be performed before the introduction step or after the introduction step.

In the storage step, the fly ash is stored while controlling the absolute humidity of the storage chamber to be equal to or lower than the reference value.
As a method for controlling the absolute humidity of the storage room, it is preferable to use the control device as follows.

When the absolute humidity in the storage room measured by the measuring device exceeds the reference value, the opening and closing means of the gas introduction unit is opened, and low humidity air is introduced into the storage room. The humidity is controlled to be equal to or lower than the reference value. At the same time, the gas discharge unit is also opened, and the gas in the storage chamber is discharged from the gas discharge unit, so that the gas in the storage chamber can be efficiently replaced and the absolute humidity in the storage chamber can be controlled below the reference value. it can. At this time, a means for sucking gas such as a pump may be moved.
Note that it is preferable that the gas discharged from the gas discharge unit is discharged in the same amount (same volume) as the low-humidity air introduced into the storage chamber because the gas in the storage chamber can be replaced more efficiently.
Further, by discharging a gas having the same volume as the low-humidity air introduced into the storage chamber from the gas discharge section, the pressure in the storage chamber rises, and fly ash is introduced from the storage chamber into the introduction port, the discharge port, etc. There is also an advantage that it can be surely prevented from blowing out.
As the low-humidity air, a gas having an absolute humidity lower than that of a gas such as air in the storage room and having a reference value or less is used. Preferably, a gas having an absolute humidity of about 10 g / m ³ or less is used as the low humidity air. Examples of the low humidity air include air and nitrogen gas.

  On the other hand, when the absolute humidity of the storage room measured in the measurement step is equal to or lower than the reference value, it is not necessary to lower the humidity, so the gas introduction part and the gas discharge part are closed and the storage room is sealed. And store the fly ash.

In the storage process, as another example of the method for controlling the absolute humidity of the storage room when the absolute humidity of the storage room measured in the measurement process is higher than the reference value, for example, A known dehumidifier may be used.
In this case, the control device includes a dehumidifier, and controls the absolute humidity of the storage room by moving the dehumidifier based on the result measured by the measurement device.
Alternatively, after dehumidifying the storage room so that the absolute humidity is less than or equal to the reference value, the storage room is sealed and kept in a state where moisture does not enter the storage room, thereby reducing the absolute humidity of the storage room. The fly ash may be stored while being controlled below the reference value.

In the present embodiment, when the relative humidity of the storage chamber is measured in the measurement step, the relative humidity of the storage chamber is 50% or less, preferably 30% or less in the storage step. You may control.
Controlling the humidity of the storage room with two types of humidity indicators, absolute humidity and relative humidity, has the following advantages.
By controlling the absolute humidity to be below the reference value as described above, it is possible to prevent fly ash consolidation, but if the reference value is set higher, the type of fly ash, etc. Depending on the situation, it may be difficult to prevent consolidation completely. In such a case, by controlling the absolute humidity of the storage room to be equal to or lower than the reference value and simultaneously controlling the relative humidity to be 50% or lower, it is possible to reliably prevent the fly ash from consolidating.
In this case, by controlling the storage chamber to have an absolute humidity of 13 g / m ³ or more and 15 g / m ³ or less and a relative humidity of 50% or less, an anti-caking effect can be reliably obtained.

The said storage process is implemented over the time to store according to the use of fly ash.
For example, even when it is necessary to store fly ash for a long time such as 12 hours or more and 3 days or less, such as ship transportation as described above, the absolute humidity of the storage room is controlled to be equal to or less than the reference value. Thus, consolidation of fly ash can be stably prevented during transportation.

The fly ash consolidation prevention method of the present embodiment is, for example, that the storage step is carried out while the fly ash is being transported on the water by a ship, so that the fly ash is consolidated at the time of unloading, resulting in a settling. Can be prevented.
When the fly ash anti-caking device according to the present embodiment is used during the transportation, it is preferable that the fly ash anti-caking device is configured as an anti-caking device that uses a ship's hold for transportation as the storage room.

In addition, by focusing on the absolute humidity of the storage room and controlling it to be equal to or less than the reference value, consolidation can be prevented stably even in an environment with a large temperature change.
In particular, even when it is necessary to store fly ash for a long time in an environment where the temperature and humidity are high, such as during ship transport in the summer, consolidation is controlled by controlling the absolute humidity of the storage room below the reference value. It can be stably prevented.

  The fly ash anti-caking method and the fly ash anti-caking device according to this embodiment are as described above. However, the embodiment disclosed herein is illustrative and restrictive in all respects. It should be considered not. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  Examples of the present invention will be described below, but the present invention is not limited thereto.

  As fly ash, the fly ash shown in Table 1 was prepared.

36 samples of fly ash shown in Table 1 were prepared for each 4000 t, and one sample was introduced into the hold for each voyage.
Immediately after introducing fly ash into the hold (within 10 minutes), the absolute humidity, relative humidity, and temperature in the hold were measured.
Relative humidity and temperature in the hold are measured using temperature and humidity automatic recording (device name: Ondotori TR77-Ui, manufactured by T & D), and absolute humidity is calculated from the measured relative humidity and temperature using the following formula. Calculated.

<Measurement of absolute humidity>
Absolute humidity (g / m3) =
217 × {6.11 × 10 ^[7.5 × ^{t / (t + 237.3)]} } / (t + 273.15) × RH / 100

here,
RH: relative humidity,
t: Temperature and pressure are 1 atm (assumed to be 101.25 (hPa))
217: Constants calculated from the equation of state of gas 6.11, 7.5, 237.3: Coefficient of the equation of the saturated water vapor pressure at the temperature t ° C. The equation of Tetens (1930) The above equation of state of gas And the following equation.
(Mass of water in unit volume) = (molecular weight of water) / [(gas constant) × (water vapor pressure) / (temperature)] = [(molecular weight of water) / (gas constant)] × [(water vapor pressure) / (Temperature)] = 217 × [(water vapor pressure) / (temperature)]
Here, the molecular weight of water: 18.01, gas constant: 8.314 (JK ⁻¹ mol ⁻¹ )

Table 2 shows the hold where the absolute humidity in the hold immediately after the introduction of fly ash exceeded 15 g / m ³ , and the hold where the absolute humidity immediately after introduction was 15 g / m ³ or less and the relative humidity exceeded 50%. Dehumidification was performed so that the indicated absolute humidity and relative humidity were obtained.
The dehumidifying method was performed by blowing the air dehumidified by the dehumidifier into the fly ash from the air slider at the bottom of the hold with a blower, and simultaneously sucking it out of the hold with another blower from the top of the hold. The inside of each hold was adjusted to the absolute humidity, temperature, and relative humidity shown in Table 2, and then sealed to prevent moisture from entering the hold.
On the other hand, for the hold where the absolute humidity in the hold after introduction of fly ash was 15 g / m ³ or less, or the relative humidity was 50% or less, dehumidification was not performed, and the hold was sealed as it was.

Then, after each sample was transported for 36 hours by a bulk carrier, it was confirmed by visual observation whether or not the settling occurred in the hold and no settling occurred.
In addition, for samples where there is occupancy, the number of columns where occupancy occurred is counted, and the number of occurrences of such occupancy is divided into three to three columns, four to seven columns, and eight or more columns. The relationship between the absolute humidity and the storage humidity is shown in FIG.
In addition, the occurrence occurrence row described here is a state where fly ash remains on the entire surface of the canvas between two corrugated sheets existing at the bottom of the hold or a part of it, and more than a few tens of centimeters. This means the total number of rows counted for the corrugated sheet in the entire hold.
The results are shown in Table 2 and FIGS.

As shown in Table 2, in the fly ash stored at an absolute humidity of 15 g / m ³ or less, 17 out of 20 samples were not settled.
On the other hand, in the fly ash in which the absolute humidity during storage exceeded 15 g / m ³ , settling occurred in 16 out of 18 samples.
Moreover, in the sample in which occupancy occurred, in the sample having a high absolute humidity immediately after dehumidification, there were many samples that were occupying two or more rows. This is clear from the graph shown in FIG. FIG. 1 shows that there is a correlation between absolute humidity and the number of occupancy occurrence columns when the occupancy is more than one column.

  Furthermore, as shown in Table 2 and FIG. 2, when attention is paid to the relative humidity of each sample, it can be seen that all the samples were stored under conditions where the relative humidity was less than 70%. Moreover, even if the sample was less than 30% relative humidity, a lot of occupancy occurred. That is, it is clear that it is not possible to prevent staying by simply controlling the relative humidity.

Claims (7)

A measurement process for measuring the absolute humidity of the storage room for storing fly ash;
An introduction step of introducing fly ash into the storage room;
After the introduction step, a storage step of storing fly ash while controlling the absolute humidity of the storage chamber to be equal to or lower than a predetermined reference value of 15 g / m ³ or lower based on the result measured in the measuring step How to prevent caking of fly ash. The method for preventing caking of fly ash according to claim 1, wherein the reference value is 10 g / m ³ or more and 15 g / m ³ or less. In the measurement step, measure the relative humidity of the storage room,
The fly ash consolidation prevention method according to claim 1 or 2, wherein in the storage step, the relative humidity of the storage chamber is controlled to be 50% or less. A storage room where fly ash is stored;
A measuring device for measuring absolute humidity in the storage room;
A fly ash anti-caking device comprising: a control device that controls the absolute humidity in the storage chamber to a reference value of 15 g / m ³ or less.   5. The fly ash anti-caking device according to claim 4, wherein the measuring device is disposed in the storage chamber above the fly ash when the fly ash is stored. The control device includes a gas introduction unit that introduces gas into the storage chamber, and a gas discharge unit that discharges gas from the storage chamber,
Based on the result measured by the measuring device, low-humidity air whose absolute humidity is lower than the absolute humidity of the storage room is introduced from the gas introduction part into the storage room, and the gas in the storage room is discharged from the gas discharge part. The fly ash anti-caking device according to claim 4 or 5, wherein the fly ash is prevented from being consolidated.   7. The fly ash anti-caking device according to claim 6, wherein the gas introduction unit is disposed in the storage chamber so as to be lower than the fly ash when the fly ash is stored.

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