JP2018185264A - Storage material heat generation monitoring system, method for monitoring heat generation of storage material, and silo - Google Patents

Abstract

PROBLEM TO BE SOLVED: To rapidly detect heat generation of coal stored in a coal silo.SOLUTION: A coal heat generation monitoring system 10 includes: a suction hose 12 suspended from the upper part of a coal silo 100; a suction hose length adjusting device 16 for adjusting the length of the suction hose 12 on the basis of the height information of coal 120 stored in the coal silo 100 so that the suction port of the suction hose 12 is located near the surface of the stored coal 120; and a gas sensor 18 detecting the concentration of a predetermined component in the gas suctioned by the suction hose 12.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a heat generation monitoring system and a heat generation monitoring method for stored items stored in a silo.

  In a coal silo installed in a coal-fired power plant or the like, if the storage period of the coal becomes long, the coal may oxidize and generate heat in the coal silo and spontaneous ignition may occur. Therefore, the heat generation of the coal stored in the coal silo is monitored, and when the heat generation occurs, the coal is discharged or discharged to cool the heat generation portion.

  Conventionally, in order to monitor the heat generation of coal stored in a coal silo, a method for monitoring the heat generation of coal by embedding a thermocouple in the stored coal and detecting a signal from the thermocouple is known. (For example, refer to Patent Document 1).

JP 2009-68954 A

  However, in the case of the heat generation monitoring method using the thermocouple as described above, it may take a long time to detect the heat generated at a location away from the thermocouple, or the detection may not be possible.

  This invention is made | formed in view of such a condition, The objective is to provide the technique which can detect rapidly the heat_generation | fever of the stored material stored in the silo.

  In order to solve the above-described problems, a storage heat generation monitoring system according to an aspect of the present invention is based on a suction hose suspended from the top of a silo and height information of the storage stored in the silo. A suction hose length adjusting device for adjusting the length of the suction hose so that the suction port of the suction hose is positioned near the surface of the object, and a gas sensor for detecting the concentration of a predetermined component in the gas sucked by the suction hose. Prepare.

  The suction hose length adjusting device may include a winding drum for winding the suction hose and a rotation driving device for rotationally driving the winding drum.

  You may further provide the dust filter provided in the suction opening of the suction hose.

  The gas sensor may be configured to detect the concentration of carbon monoxide, carbon dioxide or odor in the gas sucked by the suction hose.

  The suction hose may be suspended near the side wall of the silo.

  Another aspect of the present invention is a silo equipped with the above-described storage heat generation monitoring system.

  Another aspect of the present invention is a method for monitoring the exotherm of stored goods. In this method, the suction hose is suspended from the top of the silo, and the suction port of the suction hose is positioned near the surface of the storage based on the height information of the storage stored in the silo. And a step of detecting the concentration of a predetermined component in the gas sucked by the suction hose.

  It should be noted that any combination of the above-described constituent elements and a conversion of the expression of the present invention between a method, an apparatus, a system, a recording medium, a computer program, etc. are also effective as an aspect of the present invention.

  ADVANTAGE OF THE INVENTION According to this invention, the heat_generation | fever of the stored matter stored in the silo can be detected rapidly.

It is a figure for demonstrating the structure of the coal silo to which the heat_generation | fever monitoring system of coal which concerns on embodiment of this invention is applied. It is a figure for demonstrating the heat_generation | fever monitoring system of coal. It is a figure which shows an example of coal temperature distribution when coal is stored in a coal silo for a long period of time.

  FIG. 1 is a diagram for explaining a configuration of a coal silo 100 to which a coal heat generation monitoring system 10 according to an embodiment of the present invention is applied.

  The coal silo 100 may be, for example, a large one having an inner diameter of 60 m, a height of 75 m, and a coal capacity of 100,000 tons.

  As shown in FIG. 1, the coal silo 100 includes a foundation 102, a side wall 104 standing on the foundation 102, and a roof 106 formed on the side wall 104. Coal 120 is stored in the coal silo 100. The side wall 104 includes a substantially cylindrical lower side wall 104a and a substantially truncated cone-shaped upper side wall 104b formed on the lower side wall 104a.

  At the upper part of the coal silo 100, a loading station stage 108 is provided. The loading station stage 108 is provided with a carry-in conveyor 110 for carrying coal. Coal carried by the carry-in conveyor 110 is dropped from the loading station stage 108 and stored in the coal silo 100.

  At the bottom of the coal silo 100, a plurality of small cones (small partition plates, small partition walls) 112 and a plurality of large cones (large partition plates, large partition walls) 114 are provided. A carry-out conveyor 116 is provided below the small cone 112. The coal 120 stored in the coal silo 100 is discharged to the carry-out conveyor 116 from the opening provided at the bottom, and is carried out of the coal silo 100 by the carry-out conveyor 116.

  The coal silo 100 includes a heat generation monitoring system 10 for detecting the heat generation of the stored coal 120.

  FIG. 2 is a diagram for explaining the coal heat generation monitoring system 10. As shown in FIG. 2, the heat generation monitoring system 10 includes a suction hose 12, a dust filter 14, a suction hose length adjusting device 16, and a gas sensor 18.

  The suction hose 12 is suspended from the upper part of the coal silo 100. The suction hose 12 may be a rubber hose, for example. The diameter of the suction hose 12 may be about 1 cm, for example. The length of the suction hose 12 may be set according to the height of the coal silo 100.

  The dust filter 14 is provided so as to cover the suction port 12 a at the tip of the suction hose 12. The dust filter 14 prevents coal dust from entering the suction hose 12. In order to prevent the dust filter 14 from being clogged with dust, the dust filter 14 may be backwashed by periodically blowing air from the inside to the outside of the filter.

  The suction hose length adjusting device 16 is installed on the loading station stage 108. The suction hose length adjusting device 16 adjusts the suspension length H of the suction hose 12. The suction hose length adjusting device 16 includes a winding drum 20 for winding the suction hose 12 and a rotation driving device 22 for rotationally driving the winding drum 20.

  The rotary drive device 22 acquires the height information of the coal 120 stored in the coal silo 100, and the suction port 12a of the suction hose 12 near the surface of the stored coal 120 based on the height information of the coal. The suspension drum 20 is controlled to rotate so as to adjust the suspension length H of the suction hose 12. The surface of the coal 120 is the uppermost surface of the coal layer stored in the coal silo 100. The coal height information may be acquired from an existing coal height detection device in the coal silo 100 or may be acquired from a separately provided coal height detection device. Controlling the rotation of the take-up drum 20 can, for example, adjust the amount of rotation of the take-up drum 20 by rotating a motor (not shown). The adjustment of the suspension length H of the suction hose 12 is performed, for example, by previously storing the height from the bottom of the coal silo 100 to the loading station stage 108 as the maximum height, and setting the height of the acquired coal 120 to the maximum. The height obtained by subtracting a slight margin from the height obtained by subtracting from the height is calculated as the target length, and the rotation of the winding drum 20 is controlled (rotation) so that the actual suspension length H becomes the target length. The suspension length H can be adjusted by adjusting the amount).

The gas sensor 18 detects the concentration of a predetermined component in the gas sucked by the suction hose 12. Generally, water vapor is generated from coal at a coal temperature of about 30 ° C., paraffinic odor is generated at 50 to 60 ° C., and when it exceeds 60 ° C., carbon monoxide (CO) and carbon dioxide (CO ₂ ) are produced. It is known that carbon-based gas such as methane is generated when it is generated and further exceeds 100 ° C.

Accordingly, the gas sensor 18 may be configured to detect the concentration of CO, CO ₂ or odor in the gas sucked by the suction hose 12. By detecting the concentration of CO, CO ₂ , or odor in the gas sucked by the suction hose 12, it is possible to detect natural heat of coal early. The control device of the coal silo 100 connected to the gas sensor 18 determines that the coal is in an abnormal heat generation state when the concentration of the predetermined component exceeds a predetermined threshold value, and performs discharging and discharging of the coal to Cooling can be performed.

As the CO gas sensor, a constant potential electrolytic type can be suitably used. Further, as the CO ₂ gas sensor, a galvanic cell type can be suitably used.

  In the heat generation monitoring system 10 according to the present embodiment, the suspension length H of the suction hose 12 is adjusted so that the suction port 12a of the suction hose 12 is positioned near the surface of the stored coal 120 as described above. For example, when the gas sensor suction port is located near the loading station stage 108, because there is a distance from the stored coal bed surface to the gas sensor suction port, the gas generated in the coal bed diffuses, There is a possibility that gas cannot be detected by the gas sensor, or it may take time to detect. On the other hand, in the heat generation monitoring system 10 according to the present embodiment, since the suction port 12a of the suction hose 12 is located near the surface of the stored coal 120, the suction port before the gas generated in the coal layer diffuses. Suction is performed at 12a and can be detected by the gas sensor 18. Thereby, the heat_generation | fever of the coal 120 stored in the coal silo 100 can be detected rapidly.

  FIG. 3 shows an example of a coal temperature distribution when coal is stored in the coal silo 100 for a long period of time. In FIG. 3, the temperature of coal is represented by hatching.

  From FIG. 3, it can be seen that the coal located near the side wall 104 (lower side wall 104 a) of the coal silo 100 is likely to generate heat. In the coal silo 100, air flows upward from an opening provided at the bottom for discharging the coal to the carry-out conveyor 116, and this air oxidizes the coal to generate heat (in FIG. 3, arrows indicate the flow of air). Represent). When coal is dropped from above and stored in the coal silo 100, a large coal lump is likely to be biased near the side wall 104, so that there are many gaps in the vicinity of the side wall 104 and the air flow is faster. As a result, the coal located in the vicinity of the side wall 104 is likely to promote the oxidation reaction and easily generate heat. This means that gas is likely to be generated from coal located in the vicinity of the side wall 104.

  Therefore, as shown in FIG. 3, the suction hose 12 may be suspended near the side wall 104 (lower side wall 104 a) of the coal silo 100. The suction hose 12 extends obliquely downward along the upper side wall 104b from the suction hose length adjusting device 16 installed on the loading place stage 108, and is a pulley 30 provided near the boundary between the upper side wall 104b and the lower side wall 104a. Is suspended in the vicinity of the lower side wall 104a. Also in this case, the length of the suction hose 12 is adjusted so that the suction port of the suction hose 12 is positioned near the surface of the stored coal 120. In this manner, by suspending the suction hose 12 near the side wall 104 of the coal silo 100, it is possible to more quickly detect the heat generation of the coal 120 stored in the coal silo 100.

  In the above, this invention was demonstrated based on the Example. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to the combination of each component and each processing process, and such modifications are also within the scope of the present invention. .

  In the heat generation monitoring system 10 of the above-described embodiment, the coal height information may be acquired from an existing coal height detection device in the coal silo 100 or may be acquired from a separately provided coal height detection device. Explained as good. In this case, for example, the height information of the coal is obtained by using contact sensors suspended from the loading stage 108 (for example, a plurality of sensors attached to a plurality of locations of one cable or wire, that is, level meters). It is possible to acquire or to obtain information on the height of coal calculated from the amount of coal carried in and out.

  In the above-described embodiment, the coal silo 100 includes the lower side wall 104a having the substantially cylindrical shape and the upper side wall 104b having the substantially truncated cone shape, but the coal silo may have any shape. For example, it may be a substantially cuboidal coal silo whose longitudinal direction is the coal loading / unloading direction by the carry-in conveyor or the carry-out conveyor. Further, four carry-out conveyors 116 are provided in parallel, but one or two carry-out conveyors 116 may be provided.

  In the embodiment described above, one heat generation monitoring system 10 is described as being fixed to the coal silo 100. However, a plurality of heat generation monitoring systems may be provided for the coal silo 100, or a heat generation monitoring system may be provided. May be movably installed at a desired position (such as an upper position of a place where monitoring is to be focused on or a horizontal position where gas is easily detected). Also, the suction hose may be suspended from a desired position by making it possible to select the suspension position of the suction hose.

  In the above-described embodiment, the present invention has been described by taking the heat generation monitoring system for coal stored in the coal silo as an example. However, the present invention is not limited to a coal heat generation monitoring system, and can be applied to other silo storage heat generation monitoring systems such as grains, biomass, and recycled solid fuel.

  DESCRIPTION OF SYMBOLS 10 Heat generation monitoring system, 12 Suction hose, 14 Dust filter, 16 Suction hose length adjustment device, 18 Gas sensor, 20 Winding drum, 22 Rotation drive device, 30 Pulley, 100 Coal silo, 102 Base, 104 Side wall, 106 Roof, 108 Loading stage, 110 carry-in conveyor, 112 small cone, 114 large cone, 116 carry-out conveyor, 120 coal.

Claims (7)

A suction hose hanging from the top of the silo;
A suction hose length adjusting device that adjusts the length of the suction hose so that the suction port of the suction hose is positioned near the surface of the stored product based on the height information of the stored product stored in the silo;
A gas sensor for detecting a concentration of a predetermined component in the gas sucked by the suction hose;
A heat generation monitoring system for stored items, comprising: The suction hose length adjusting device is:
A winding drum for winding the suction hose;
A rotational drive device for rotationally driving the winding drum;
The heat generation monitoring system for stored items according to claim 1, comprising:   3. The stored product heat generation monitoring system according to claim 1, further comprising a dust filter provided at a suction port of the suction hose.   The said gas sensor is comprised so that the density | concentration of carbon monoxide, a carbon dioxide, or an odor in the gas suck | inhaled with the said suction hose may be detected, The stored goods of any one of Claim 1 to 3 characterized by the above-mentioned. Fever monitoring system.   The storage heat generation monitoring system according to any one of claims 1 to 4, wherein the suction hose is suspended near a side wall of the silo.   A silo comprising the storage heat generation monitoring system according to any one of claims 1 to 5. Dropping a suction hose from the top of the silo;
Adjusting the length of the suction hose so that the suction port of the suction hose is located near the surface of the storage based on the height information of the storage stored in the silo;
Detecting a concentration of a predetermined component in the gas sucked by the suction hose;
A method for monitoring heat generation of stored items, comprising:

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