JP6600171B2 - Method and apparatus for preventing spontaneous combustion of stored coal - Google Patents

Description

  The present invention relates to a method and an apparatus for preventing spontaneous combustion of stored coal.

  In general, coal used as fuel for gasifiers and boilers is stored in a coal storage tank such as a bunker or silo. Attention is required.

  Conventionally, in order to prevent spontaneous combustion of coal stored in the coal storage tank, a wire rope embedded with a temperature measuring element is suspended from the upper part of the coal storage tank, and the temperature inside the coal storage tank is measured. Things have been done.

  In addition, there exists patent document 1 as what shows the general technical level of the apparatus which measures the temperature of the coal stored in the said coal storage tank, and prevents a spontaneous combustion, for example.

JP 2011-219152 A

  However, as described above, when the wire rope embedded with the temperature measuring element is suspended from the upper part of the coal storage tank, a large pulling load acts on the wire rope when the coal is discharged from the coal storage tank. The wire rope is easily worn out, and frequent maintenance is required, and improvement has been desired.

  The present invention has been made in view of the above-described conventional problems, and is capable of detecting a temperature change of coal stored in the coal storage tank without using a wire rope, and can prevent the spontaneous ignition of coal. The present invention aims to provide a method and apparatus for preventing spontaneous combustion of coal.

The present invention is a method for preventing spontaneous combustion of stored coal in a coal storage tank provided with a dispenser at the bottom,
A burying step of burying a plurality of capsules containing a temperature sensor and a wireless module inside the coal storage tank together with coal; and
A temperature distribution creating step of determining a position inside the coal storage tank of the plurality of capsules embedded in the burying process, and creating a temperature distribution of the coal inside the coal storage tank;
Based on the temperature distribution created by the temperature distribution creating step, the temperature of the coal actuates the dispensing machine upon detecting that exceeds an allowable value out pay capsules with coal, pay the capsules from the dispensing machine A firing avoidance and payout step of stopping the dispenser at the time when it is detected that ;
The present invention relates to a method for preventing spontaneous combustion of stored coal, characterized by performing a recovery step of recovering capsules discharged together with coal in the ignition avoidance and discharge step.

  In the temperature distribution creating step, it is preferable that the positions of the plurality of capsules in the coal storage tank are determined based on the coal height level at the time of capsule introduction and the state of coal discharge / injection after the capsule introduction.

  In the temperature distribution creating step, the positions of the plurality of capsules inside the coal storage tank may be determined based on radio wave conditions of a wireless network between the capsules.

  In the method for preventing spontaneous combustion of stored coal, a plurality of dispensers are provided at the bottom of the coal storage tank, and in the ignition avoidance and discharge step, the temperature of coal is allowed based on the temperature distribution created in the temperature distribution creation step. It is preferable to operate the dispenser corresponding to the embedment location of the capsule where it has been detected that the value has been exceeded to dispense the capsule together with coal.

Moreover, the present invention is a stored coal spontaneous combustion prevention device inside a coal storage tank provided with a dispenser at the bottom,
A capsule in which a temperature sensor and a wireless module are incorporated, and a plurality of capsules are embedded in the coal storage tank together with coal;
The position of the plurality of embedded capsules inside the coal storage tank is determined, and the temperature distribution of the coal inside the coal storage tank is created, and based on the temperature distribution, it is detected that the temperature of the coal exceeds the allowable value. A data processing terminal that outputs an operation signal to the dispenser and dispenses the capsule together with the coal,
A collector for collecting capsules dispensed with the coal ;
A first radio base station that aggregates and transmits temperature data from the capsule to the data processing terminal;
A second radio base station that detects that the capsule at the burial location where the temperature of the coal has exceeded an allowable value has been paid out from the dispenser and transmits it to the data processing terminal;
The stored coal spontaneous combustion prevention, wherein the second radio base station is configured to output a stop signal from the data processing terminal to the dispenser when it is detected that the capsule is dispensed from the dispenser. It depends on the device.

In the stored coal spontaneous combustion prevention device, comprising a level meter for detecting the coal height level inside the coal storage tank,
The data processing terminal is configured to determine the position of a plurality of embedded capsules in the coal storage tank based on the coal height level at the time of capsule insertion detected by the level meter and the coal discharge / injection status after the capsule is inserted. It is preferable to do.

  The data processing terminal may be configured to determine the positions of a plurality of embedded capsules inside the coal storage tank based on the radio wave condition of the wireless network between the capsules.

  The collector is preferably a screen that separates and separates capsules from the discharged coal.

  In the stored coal spontaneous combustion prevention device, a plurality of dispensers are provided at the bottom of the coal storage tank, and the data processing terminal detects that the temperature of the coal exceeds an allowable value based on the temperature distribution. It is preferable that the capsule is discharged together with the coal by outputting an operation signal to the dispenser corresponding to the embedment position of the capsule.

  According to the method and apparatus for preventing spontaneous combustion of coal stored in the present invention, it is possible to detect a temperature change of coal stored in a coal storage tank without using a wire rope, and to prevent spontaneous combustion of coal in advance. Can have an effect.

BRIEF DESCRIPTION OF THE DRAWINGS It is a whole schematic block diagram which shows the Example of the storage coal spontaneous combustion prevention method and apparatus of this invention. It is a flowchart which shows the Example of the storage coal spontaneous combustion prevention method and apparatus of this invention.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

  1 and 2 show an embodiment of a method and apparatus for preventing spontaneous combustion of stored coal according to the present invention.

  In FIG. 1, 1 is a coal storage tank such as a bunker or silo for storing coal used as fuel for a gasification furnace, a boiler, etc., and a plurality of (in the example of FIG. Four) dispensers 2 are provided.

  In the case of the present embodiment, a plurality of capsules 3 incorporating temperature sensors 3a and wireless modules 3b are introduced together with coal from the inlet 1a of the coal storage tank 1 and embedded therein. As the wireless module 3b, for example, a short-range wireless communication standard whose main purpose is a sensor network such as ZigBee (registered trademark) can be used. In addition to the charging port 1 a, a dedicated charging port (not shown) for the capsule 3 may be provided in the coal storage tank 1.

  The positions of the plurality of embedded capsules 3 in the coal storage tank 1 are determined by the data processing terminal 4, and in the data processing terminal 4, the temperature distribution of the coal in the coal storage tank 1 is created, and the temperature distribution Based on the above, the operation signal 4a is output to the dispenser 2 corresponding to the embedded portion of the capsule 3 that has detected that the temperature of the coal has exceeded the allowable value, and the capsule 3 is discharged together with the coal.

  The capsule 3 paid out together with the coal is collected by a collecting device 5. The collector 5 is a screen 5a for selecting and separating the capsule 3 from the discharged coal.

  The temperature data from the capsule 3 is collected by the first radio base station 6 and transmitted to the data processing terminal 4.

  The second radio base station 7 detects that the capsule 3 in the burial location where the temperature of the coal has exceeded an allowable value has been paid out from the dispenser 2 and transmits it to the data processing terminal 4. When the wireless base station 7 detects that the capsule 3 has been paid out from the dispenser 2, the data processing terminal 4 outputs a stop signal 4b to the dispenser 2.

  The coal height level in the coal storage tank 1 is detected by a level meter 8, and the coal height level detected when the capsule 3 is input and the coal discharge / input state after the capsule 3 is detected are detected by the level meter 8. In the data processing terminal 4, the positions of the plurality of embedded capsules 3 in the coal storage tank 1 are determined. As the level meter 8, for example, an ultrasonic wave or a microwave can be projected onto the upper surface of coal and the reflected wave is captured to obtain the coal height level. The data processing terminal 4 can also be configured to determine the positions of the plurality of embedded capsules 3 in the coal storage tank 1 based on the radio wave conditions of the wireless network between the capsules 3.

  In FIG. 1, reference numeral 9 denotes a conveyor such as a belt conveyor. The coal 9 and the capsule 3 discharged from the discharger 2 by the conveyor 9 are conveyed to the screen 5 a of the recovery unit 5. The conveyor 9 is not limited to a belt conveyor.

  Next, the operation of the above embodiment will be described.

  First, a plurality of capsules 3 in which the temperature sensor 3a and the wireless module 3b are incorporated are put in the coal storage tank 1 and embedded therein (embedding step S1 in FIG. 2). The temperature data from the capsule 3 is collected by the first radio base station 6 and transmitted to the data processing terminal 4.

  Subsequently, the positions of the plurality of capsules 3 buried in the embedding step S1 inside the coal storage tank 1 are determined by the data processing terminal 4, and the temperature distribution of the coal inside the coal storage tank 1 is created (FIG. 2 temperature distribution creation step S2). Here, the positions of the plurality of capsules 3 embedded in the embedding step S1 in the coal storage tank 1 are the coal height level when the capsule 3 is detected and the coal discharge / It is determined in the data processing terminal 4 based on the input status. In addition, the position in the coal storage tank 1 of the plurality of capsules 3 embedded in the embedding step S1 can be determined in the data processing terminal 4 based on the radio wave condition of the wireless network between the capsules 3. .

  Based on the temperature distribution created in the temperature distribution creation step S2, if there is a capsule 3 that has detected that the coal temperature has exceeded the allowable value, the data processing terminal 4 corresponds to the embedded location of the capsule 3 The operation signal 4a is output to the dispenser 2 to be operated, the dispenser 2 is activated, and the capsule 3 is dispensed together with coal (ignition avoidance dispensing process S3 in FIG. 2).

  In the ignition avoidance and payout step S3, it is detected by the second radio base station 7 that the capsule 3 in the buried portion where the temperature of the coal exceeds an allowable value is discharged from the dispenser 2, and the data processing terminal 4 and when the second radio base station 7 detects that the capsule 3 has been paid out from the dispenser 2, a stop signal 4b is output from the data processing terminal 4 to the dispenser 2. The dispenser 2 is stopped.

  The capsule 3 discharged together with the coal in the ignition avoidance discharging step S3 is conveyed to the screen 5a of the recovery unit 5 by the conveyor 9, and the capsule 3 is selected from the discharged coal by the screen 5a of the recovery unit 5. Are separated and recovered (recovery step S4 in FIG. 2).

  The collected capsule 3 can be reused. Note that the coal delivered in the ignition avoidance and delivery step S3 is returned to the coal storage tank 1 and stored again.

  As described above, since the capsule 3 is used in the present embodiment, unlike the conventional one in which the wire rope embedded with the temperature measuring element is suspended from the upper part of the coal storage tank 1, the coal storage tank is used. When the coal is discharged from 1, a large pulling load does not act on the wire rope, and frequent maintenance is not necessary.

  Thus, the temperature change of the coal stored in the coal storage tank 1 can be detected without using a wire rope, and spontaneous ignition of the coal can be prevented beforehand.

  Since the first radio base station 6 is provided, temperature data from the capsule 3 can be aggregated and transmitted smoothly to the data processing terminal 4.

  In addition, since the second radio base station 7 is provided, the data processing terminal 4 is detected by detecting that the capsule 3 at the burial location where the temperature of the coal exceeds an allowable value has been discharged from the dispenser 2. Can be transmitted smoothly. In addition, when the second radio base station 7 detects that the capsule 3 has been paid out from the dispenser 2, the data processing terminal 4 outputs a stop signal 4b to the dispenser 2. There is no worry that the dispenser 2 is driven in vain.

  Furthermore, since the level meter 8 is provided, the coal height level in the coal storage tank 1 can be detected. In the data processing terminal 4, the inside of the coal storage tank 1 of the plurality of capsules 3 embedded in the data processing terminal 4 based on the coal height level when the capsule 3 is input detected by the level meter 8 and the coal discharge / input state after the capsule 3 is input. Therefore, the position of the capsule 3 can be accurately grasped.

  Even if the data processing terminal 4 is configured to determine the positions of the plurality of embedded capsules 3 inside the coal storage tank 1 based on the radio wave conditions of the wireless network between the capsules 3, the position of the capsules 3 can be determined. Accurately grasp.

  Since the recovery unit 5 is a screen 5a that separates and separates the capsules 3 from the discharged coal, an existing screen in a general coal storage facility can be used.

  On the other hand, in this embodiment, a plurality of dispensers 2 are provided at the bottom of the coal storage tank 1, and the data processing terminal 4 detects that the coal temperature has exceeded an allowable value based on the temperature distribution. The operation signal 4a is output to the dispenser 2 corresponding to the burying location of the capsule 3 so that the capsule 3 is dispensed together with the coal. The number of the dispensers 2 is determined according to the scale of the coal storage tank 1. Needless to say, it can be increased or decreased. For example, only one dispenser 2 is provided at the bottom of the coal storage tank 1, and when the data processing terminal 4 detects that the temperature of the coal exceeds an allowable value based on the temperature distribution, the dispenser It is also possible to output the operation signal 4a to 2 so that the capsule 3 is discharged together with coal.

  Note that the method and apparatus for preventing spontaneous combustion of stored coal according to the present invention is not limited to the above-described embodiments, and it is needless to say that various changes can be made without departing from the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Coal storage tank 2 Dispenser 3 Capsule 3a Temperature sensor 3b Wireless module 4 Data processing terminal 4a Operation signal 4b Stop signal 5 Collector 5a Screen 6 1st wireless base station 7 2nd wireless base station 8 Level meter S1 Embedding process S2 Temperature Distribution creation process S3 Ignition avoidance payout process S4 Recovery process

Claims (9)

A method for preventing spontaneous combustion of stored coal in a coal storage tank provided with a dispenser at the bottom,
A burying step of burying a plurality of capsules containing a temperature sensor and a wireless module inside the coal storage tank together with coal; and
A temperature distribution creating step of determining a position inside the coal storage tank of the plurality of capsules embedded in the burying process, and creating a temperature distribution of the coal inside the coal storage tank;
Based on the temperature distribution created by the temperature distribution creating step, the temperature of the coal actuates the dispensing machine when it is detected that exceeds the allowable value out pay capsules with coal, pay the capsules from the dispensing machine A firing avoidance and payout step of stopping the dispenser at the time when it is detected that ;
A method for preventing spontaneous combustion of stored coal, comprising: performing a recovery step of recovering capsules discharged together with coal in the ignition avoidance and discharge step. The storage according to claim 1, wherein, in the temperature distribution creating step, the positions of the plurality of capsules inside the coal storage tank are determined based on a coal height level at the time of capsule injection and a coal discharge / input state after the capsule injection. Coal spontaneous combustion prevention method. Wherein the temperature distribution creating step, the position inside the coal reservoir of said plurality of capsules, reservoir coal spontaneous combustion prevention method according to claim 1, wherein the indexed based on the radio wave state of the radio network between the capsule. A plurality of dispensers are provided at the bottom of the coal storage tank, and in the ignition avoidance dispensing process, a capsule that detects that the temperature of the coal exceeds an allowable value based on the temperature distribution created in the temperature distribution creating process The method for preventing spontaneous combustion of stored coal according to any one of claims 1 to 3 , wherein a dispenser corresponding to the buried portion is operated to discharge the capsule together with the coal. A stored coal spontaneous combustion prevention device inside a coal storage tank provided with a dispenser at the bottom,
A capsule in which a temperature sensor and a wireless module are incorporated, and a plurality of capsules are embedded in the coal storage tank together with coal;
The position of the plurality of embedded capsules inside the coal storage tank is determined, and the temperature distribution of the coal inside the coal storage tank is created, and based on the temperature distribution, it is detected that the temperature of the coal exceeds the allowable value. A data processing terminal that outputs an operation signal to the dispenser and dispenses the capsule together with the coal,
A collector for collecting capsules dispensed with the coal ;
A first radio base station that aggregates and transmits temperature data from the capsule to the data processing terminal;
A second radio base station that detects that the capsule at the burial location where the temperature of the coal has exceeded an allowable value has been paid out from the dispenser and transmits it to the data processing terminal;
The stored coal spontaneous combustion prevention, wherein the second radio base station is configured to output a stop signal from the data processing terminal to the dispenser when it is detected that the capsule is dispensed from the dispenser. apparatus. A level meter for detecting a coal height level inside the coal storage tank;
The data processing terminal is configured to determine the position of a plurality of embedded capsules in the coal storage tank based on the coal height level at the time of capsule insertion detected by the level meter and the coal discharge / injection status after the capsule is inserted. The stored coal spontaneous combustion prevention device according to any one of claims 5 to 6. The stored coal according to any one of claims 5 and 6 , wherein the data processing terminal is configured to determine the positions of a plurality of embedded capsules in the coal storage tank based on a radio wave condition of a wireless network between the capsules. Spontaneous ignition prevention device. The stored coal spontaneous combustion prevention device according to any one of claims 5 to 7 , wherein the recovery unit is a screen that separates and separates capsules from the discharged coal. A plurality of dispensers are provided at the bottom of the coal storage tank, and in the data processing terminal, based on the temperature distribution, to a dispenser corresponding to a capsule embedding location that has detected that the temperature of the coal has exceeded an allowable value The stored coal spontaneous combustion prevention apparatus according to any one of claims 5 to 8 , wherein the operation signal is output so that the capsule is discharged together with the coal.

Images