JP2010167145A - Method for suppressing temperature rise of coal in coal bunker - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for suppressing the temperature rise of coal in a coal bunker without taking out the coal from the coal bunker and without deteriorating the quality of the coal. <P>SOLUTION: When the temperature of the coal Cb stored in the coal bunker 12 rises caused by spontaneous heat generation, dry ice D is supplied to the coal bunker 12 thereby to form a block layer Da of CO2, which is generated by vaporization of the dry ice D, on the upper surface Cb1 of the coal Cb. Then, the temperature rise of the coal Cb caused by the spontaneous heat generation is suppressed. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a method for suppressing a temperature rise of coal stored in a coal bunker in a thermal power plant.

  In a thermal power plant using coal as fuel, coal supplied from a coal storage is temporarily stored in a coal bunker, and then coal from the coal bunker is supplied to a boiler.

  FIG. 6 shows an example of a coal supply path in a thermal power plant. As shown in FIG. 6, the coal C stored in the coal storage 1 is crushed to a predetermined size by the pulverizer 2 and then supplied to the coal bunker 10 which is a large container. The coal bunker 10 temporarily stores the coal C from the crusher 2, and the coal C supplied from the upper part gradually descends downward. And the coal C discharged | emitted from the lower end part of the coal bunker 10 is produced | generated by the pulverized coal machine 20 in a fine powder form, and is supplied to the boiler 30. FIG.

  The coal C stored in the coal storage 1 may generate heat due to contact with air and spontaneously ignite. Therefore, in the coal yard 1, when the temperature of the coal C is remarkably increased, a filling operation is performed in which the piled coal C is diffused in a flat shape, and the diffused coal C is pressed from above with a bulldozer or the like. The temperature rise of coal C is suppressed.

  Although the coal C stored in the coal bunker 10 has a smaller amount of coal storage than the coal yard 1 and the coal bunker 10 has a substantially sealed structure, the amount of air contacted is small, so the possibility of spontaneous ignition is low. Once the temperature of coal C begins to rise, the rate of temperature increase gradually increases. When the temperature of the coal C is remarkably increased in the coal bunker 10, since the diffusion and filling work in the coal bunker 10 cannot be performed, the coal C is extracted from the coal bunker 10.

  As one of techniques for preventing the temperature rise of stored coal, a method is known in which water is injected from a nozzle toward coal that spontaneously ignites (see, for example, Patent Document 1).

JP-A-11-164900

  However, the coal bunker 10 is large, and the amount of extracted coal C reaches, for example, 700 tons. It is very expensive to transfer the extracted coal C to the coal storage 1 and perform diffusion and filling operations. There is a problem of needing.

  Moreover, in order to suppress the temperature rise of the coal C stored in the coal bunker 10, when injecting water toward coal like patent document 1, the state in which the coal C in the coal bunker 10 was immersed in water Therefore, the quality problem of coal C arises, and extraction of water from coal bunker 10 also becomes a problem.

  Accordingly, an object of the present invention is to provide a method for suppressing the temperature rise of coal in the coal bunker without removing the coal from the coal bunker and without impairing the quality of the coal.

  In order to achieve the above object, according to the first aspect of the present invention, when the temperature of coal stored in the coal bunker rises due to natural heat generation, dry ice is introduced into the coal bunker, and the upper surface side of the coal A method for suppressing a rise in coal temperature in a coal bunker is characterized in that a temperature rise due to natural heat generation of the coal is suppressed by forming a barrier layer of CO2 generated by vaporization of the dry ice.

  According to the present invention, the upper surface side of the exothermic coal is covered with the CO2 barrier layer generated by the vaporization of the input dry ice. Thereby, the penetration | invasion of the air into the coal inside from the upper surface side of coal is interrupted | blocked, and the heat_generation | fever of coal is suppressed by the reduction | decrease of the air quantity which contacts coal.

  Invention of Claim 2 is the coal temperature rise suppression method in the coal bunker of Claim 1, The charging of the said dry ice is the temperature of the said coal being 50 degreeC or more, or CO density | concentration in the said coal bunker is It is characterized in that it is carried out when it becomes 5 ppm or more.

  A third aspect of the invention is characterized in that, in the coal temperature rise suppressing method in the coal bunker of the first or second aspect, the thickness of the CO2 barrier layer is 20 to 30 cm.

  According to a fourth aspect of the present invention, in the coal temperature rise suppression method in the coal bunker according to any one of the first to third aspects, the dry ice is introduced from an existing inspection port of the coal bunker. It is characterized by that.

  According to the first aspect of the present invention, it is possible to suppress an increase in the temperature of the coal in the coal bunker without removing a large amount of coal from the coal bunker. Can be reduced. Moreover, since it is not necessary to extract coal, the work days required for coal temperature control can be shortened, and the operating rate of the thermal power plant can be increased. Furthermore, since the CO2 barrier layer formed on the upper surface of the coal is a gas, it does not adversely affect the quality of the coal as in the prior art in which water is injected toward the coal.

  According to the invention described in claim 2, since the dry ice is charged when the temperature of the coal is 50 ° C. or higher or the CO concentration in the coal bunker is 5 ppm or higher, it is necessary to prevent the coal from burning. Can be prevented.

  According to the invention described in claim 3, since the thickness of the CO2 barrier layer is 20 to 30 cm, the barrier effect between coal and air is enhanced, and the effect of suppressing the temperature rise of coal can be enhanced.

  According to the fourth aspect of the present invention, since the dry ice is introduced from the existing inspection port of the coal bunker, it is not necessary to newly install a dry ice introduction place.

It is sectional drawing which shows the implementation condition of the coal temperature rise suppression method in the coal bunker concerning embodiment of this invention. It is sectional drawing of the coal bunker of FIG. It is the top view which looked at the coal bunker of FIG. 2 from the BB direction. It is a top view of the coal bunker of FIG. It is a front view of the coal bunker of FIG. It is a schematic diagram which shows an example of the supply path | route of coal in a thermal power plant.

  Next, embodiments of the present invention will be described in detail with reference to the drawings.

1 to 5 show an embodiment of the present invention. As shown in FIG. 1, the coal bunker 10 is disposed in the middle of the coal supply path of the thermal power plant, and has an upper bunker 11 and a lower bunker 12. The upper bunker 11 and the lower bunker 12 are arranged in series in the vertical direction. The upper bunker 11 is a container for storing the coal C supplied from the previous process. The lower bunker 12 is a container that stores the coal C from the upper bunker 11 and supplies the coal C to the next process. In the coal bunker 10, the coal C supplied to the upper bunker 11 gradually descends downward and flows into the lower bunker 12. The coal bunker 10 has a capacity of storing about 500 m ³ of coal C.

  As shown in FIGS. 4 and 5, the upper bunker 11 is formed in a cylindrical shape extending in the vertical direction, and has a substantially square cross-sectional shape. The upper bunker 11 is formed so that the diameter gradually decreases from the top to the bottom. The upper bunker 11 has an upper opening 11 a for supplying coal C at the upper part, and a lower opening 11 b for supplying coal C to the lower bunker 12 at the lower part.

  The lower bunker 12 is formed in a cylindrical shape having a circular cross section, and the outer shape is a truncated cone shape. The lower bunker 12 is formed so that the diameter gradually decreases from the top to the bottom. In the lower bunker 12, an upper opening 12a for receiving the coal C supplied from the upper bunker 11 is formed in the upper part, and a lower opening 12b for supplying the coal C to the next process is formed in the lower part. Yes. The lower end of the upper bunker 11 enters the upper opening 12 a of the lower bunker 12, and the lower end of the upper bunker 11 opens into the upper opening 12 a of the lower bunker 12.

  2 and 3 show the support structure of the coal bunker 10. As shown in FIG. 2, the lower outer peripheral portion of the upper bunker 11 is supported by a steel beam 16 of a building of a thermal power plant via a support member 16a. The upper outer peripheral portion of the lower bunker 12 is supported by another steel beam 17 of the building of the thermal power plant via a support member 18. The upper end portion of the lower bunker 12 is covered with the upper wall 12c, and the lower end portion of the upper bunker 11 enters the central portion of the upper wall 12c in the radial direction. That is, the lower end portion of the upper bunker 11 extends through the upper wall 12 c and into the upper opening 12 a of the lower bunker 12. A plurality of inspection ports 13 are provided in the upper wall 12c. Each inspection port 13 can be opened and closed, and is closed except during inspection.

  As shown in FIG. 1, a gate valve 14 is provided below the lower bunker 12. The gate valve 14 adjusts the supply amount of the coal C to the next process by controlling the opening degree. When the coal C is not supplied, the gate valve 14 is closed. The sliding portion of the gate valve 14 is sealed with a packing 15. A belt conveyor 19 is disposed immediately below the lower bunker 12. The belt conveyor 19 has a function of transporting the coal C discharged from the lower bunker 12 to the next process.

  Below, the coal temperature rise suppression method in the coal bunker 10 is demonstrated.

  Coal C supplied to the coal bunker 10 is temporarily stored in the coal bunker 10, discharged from the lower end of the lower bunker 12, and conveyed to the next process by the belt conveyor 19. Here, since the coal Ca supplied into the upper bunker 11 gradually descends toward the lower bunker 12 over time, the coal Cb in the lower bunker 12 is converted into the coal Ca in the upper bunker 11. Compared with the coal bunker 10, the period stored in the coal bunker 10 is long, and it is in a state where natural heat is easily generated. That is, the coal C in the coal bunker 10 is stored in a dense state, and it is difficult to release the heat generated by the spontaneous heat generation to the outside, so the coal in the lower bunker 12 that has a long storage period. Cb is more likely to accumulate heat due to spontaneous heating than coal Ca in the upper bunker 11.

  The coal bunker 10 has a structure almost close to a sealed state, but as shown in FIG. 1, air A has entered through the sliding portion of the inspection port 13 and the gate valve 14 (in the vicinity of the packing 15), This air A comes into contact with the coal Cb in the lower bunker 12. Thereby, heat_generation | fever of coal Cb is accelerated | stimulated by reaction with coal Cb and the air A, and the temperature of coal Cb rises. Thus, in the lower bunker 12, once the temperature of the coal Cb starts to rise, the rate of temperature increase of the coal Cb gradually increases.

  The temperature of the coal Cb and the CO concentration in the lower bunker 12 are constantly monitored. When the temperature of the coal Cb is 50 ° C. or higher or the CO concentration in the lower bunker 12 is 5 ppm or higher, dry coal into the lower bunker 12 is dried. Ice D is charged by the operator. The dry ice D is introduced by opening an existing inspection port 13 provided on the upper wall 12c of the lower bunker 12 and moving from the opening of the inspection port 13 toward the upper surface Cb1 side of the coal Cb stored in the lower bunker 12. Is called. In this embodiment, the input amount of dry ice D is set to 10 kg so that the thickness T of the blocking layer Da described later is 20 to 30 cm.

  Since the dry ice D is obtained by solidifying carbon dioxide and has a property of being vaporized without becoming liquid, the dry ice D introduced from the inspection port 13 is vaporized as shown in FIG. A CO2 barrier layer Da is formed on the upper surface Cb1 side of the coal Cb. Thereby, the upper surface Cb1 side of coal Cb will be in the state covered with the shielding layer Da of CO2 produced by vaporization of the supplied dry ice D. Here, since the thickness T of the CO2 blocking layer Da is set to 20 to 30 cm, the blocking effect between the coal Cb and the air A is increased, and the suppressing effect on the temperature rise of the coal can be increased. Moreover, since the temperature of dry ice D is lower than that of ice, the low-temperature CO2 falls below the heat-generating coal Cb, so that the coal Cb is cooled by the low-temperature CO2 and further increases the temperature suppression effect of the coal Cb. It becomes possible.

  Thus, by forming the CO2 barrier layer Da on the upper surface Cb1 side of the coal Cb by introducing the dry ice D, the temperature rise of the coal Cb in the coal bunker 10 can be suppressed. Need not be extracted from the coal bunker 10, and the work cost for suppressing the temperature rise can be greatly reduced. Further, since the CO2 barrier layer Da is a gas, it does not adversely affect the quality of the coal C as in the prior art in which water is injected toward the coal.

  Since the dry ice D is introduced when the temperature of the coal Cb is 50 ° C. or higher or the CO concentration in the coal bunker 10 is 5 ppm or higher, the coal Cb can be prevented from burning. . In addition, since the dry ice D is introduced from the existing inspection port 13, there is no need to newly install a dry ice D introduction place.

  The embodiment of the present invention has been described in detail above, but the specific configuration is not limited to the above-described embodiment, and even if there is a design change or the like without departing from the gist of the present invention, It is included in this invention. For example, in this embodiment, the dry ice D is charged by an operator. However, the dry ice D may be automatically charged in conjunction with a device that monitors the heat generation of the coal Cb. . Moreover, although the dry ice D is input only with respect to the coal Cb stored in the lower bunker 12, the upper surface of the coal Ca is also increased when the temperature of the coal Ca stored in the upper bunker 11 rises. By introducing the dry ice D to the Ca1 side, it is possible to suppress the temperature rise of the coal Ca.

10 Coal bunker 11 Upper bunker (Coal bunker)
12 Lower bunker (coal bunker)
13 Inspection Port 14 Gate Valve 19 Belt Conveyor A Air C Coal Ca Coal in Upper Bunker Cb Coal in Lower Bunker D Dry Ice Da CO2 Barrier Layer

Claims (4)

  When the temperature of coal stored in the coal bunker rises due to natural heat generation, dry ice is introduced into the coal bunker, and a barrier layer for CO2 generated by vaporization of the dry ice is formed on the upper surface of the coal. The coal temperature rise suppression method in a coal bunker characterized by suppressing the temperature rise by the natural heat_generation | fever of the said coal.   2. The coal temperature increase suppression in the coal bunker according to claim 1, wherein the dry ice is charged when the temperature of the coal is 50 ° C. or more or the CO concentration in the coal bunker becomes 5 ppm or more. Method.   The method for suppressing a rise in coal temperature in a coal bunker according to claim 1 or 2, wherein the CO2 barrier layer has a thickness of 20 to 30 cm.   The method for suppressing a rise in coal temperature in the coal bunker according to any one of claims 1 to 3, wherein the dry ice is introduced from an existing inspection port of the coal bunker.

Images