KR100503202B1 - Apparatus for controlling the hot gas in the upper portion of the quenching tower - Google Patents

Abstract

The present invention relates to a device for controlling high heat gas in the upper layer of the cooling tower for dry extinguishing the dry coke coagulated in the carbonization chamber of the coke oven, the nitrogen supply for supplying nitrogen gas to the upper layer through a plurality of injection holes Means and a collecting means for sucking high-temperature gas from the upper layer through a plurality of collecting ports, by cooling and collecting the high-temperature gas remaining in the upper portion of the chamber cooling tower of the coke dry fire extinguishing facility with nitrogen, It prevents explosion by high heat gas and prevents fire and burnout attached to the inside of the chamber cooling tower, extends the life of the cooling tower main body equipment, prevents subtraction due to frequent maintenance, and enables stable operation and reuse of the heat of high heat gas. Can contribute to increased energy production We have an effect.

Description

Apparatus for controlling the hot gas in the upper portion of the quenching tower}

The present invention relates to a device for controlling high temperature gas in the upper portion of the fire extinguishing tower of the coke dry fire extinguishing system, and more particularly to prevent the explosion phenomenon due to the congestion of the high temperature gas remaining in the upper layer of the chamber digestion tower of the coke dry fire extinguishing facility. The present invention relates to a high temperature gas control device of an upper portion of a fire extinguishing tower that recovers the heat of collection gas and can be used as a heat source for steam boiler production.

In general, the coal charged in the carbonization chamber of the coke oven is coagulated by coagulation for a certain time, such coke is extracted from the carbonization chamber and digested in the cooling tower of the dry fire extinguishing plant is used as a heat source to melt the waste water.

That is, referring to FIG. 1, the glowing coke extracted from the carbonization chamber of the coke oven into the bucket BUCKET is transferred to the dry fire extinguishing facility through the fire extinguishing truck facility 10. Then, the bucket is lifted to the crane hoisting facility 12 to discharge the red coke to the chamber cooling tower 20, and the suffocated cold coke by the circulation facility 30 is discharged through the outlet. At this time, the heat of red coke generated in the asphyxiation process is provided to the waste heat recovery facility to produce steam and power.

In general, the chamber cooling tower 20 charging the red coke is an upright cylindrical structure, the outside is surrounded by the bark, and the inside is constructed of a refractory lead, so it can withstand high heat red coke. And, the top of the cooling tower is provided with a chamber lid 40 and a charging device, the upper layer 50 constitutes a pre-chamber (PRE-CHAMBER) into which the red coke is charged, the lower layer 60 is cooling the red coke is extinguished A chamber (COOLING-CHAMBER) is formed and the lower part is provided with a discharge device through which cooling coke is discharged.

In the middle part of the prechamber, a ring duct (RING DUCT) 31, which is a circulation facility for recovering the heat generated during the asphyxiation, is connected to the outer side of the pre-chamber, and the lower side of the cooling chamber 60 collects the circulation. There is provided a circulation supply device which is recovered through the pipe 32 and then heat exchanged in the heat exchange facility 33 and then resupplied to the cooling gas.

On the other hand, when the high temperature (1250 ℃) of the red coke is charged to the prechamber 50, which is the charging level of the cooling tower, the unburnt combustible gas generated during the asphyxiation process as described above in the partial space of the upper layer 70 of the prechamber is It is not collected through the circulation collecting tube but becomes stagnant.

These combustible gases are generally composed of TAR, CO ₂ , C _m H _n , 0 ₂ , CO, H ₂ , CH ₄ , N _2, etc. Among these gases, light gases having a low molecular weight, namely C _m H _n (hydrocarbons) ) And CH ₄ (methane) will stagnate in the closed upper layer.

Since the structural problem of the prechamber, that is, the circulating gas collection is made at the center position of the prechamber, flammable gas has to be stagnant in the upper 70 space, and at the same time, a slight negative pressure (-pressure) is generated in the upper layer. It is in a condition where oxygen in the air is inhaled. As a result, the combustible gas accompanied by high temperature and high heat causes an explosion when the combustion reaction occurs upon contact with oxygen.

As such, the strong explosion sound generated by the instantaneous ignition of the flammable gas impacts the flame retardant attached to the inside of the chamber cooling tower, thereby causing fatal damage such as cracking and dropping. Due to the characteristics of the chamber that always maintains a high temperature of more than 950 ~ 1050 ℃ always almost impossible to replace, it causes a serious problem of stopping the coke production work due to the periodical repair due to the explosion. Therefore, there is a need for a method of preventing explosions due to the effect of extending the life and normal operation of the chamber cooling tower body.

The present invention has been made to solve the conventional problems as described above, to prevent the high-temperature gas stagnation in the upper part of the chamber cooling tower of the dry fire extinguishing equipment of the coke oven to prevent the explosion phenomenon and also to recover the heat from the high heat gas The purpose is to provide a high temperature gas control device that can be.

In order to achieve the above object, according to the present invention, the apparatus for controlling the high-temperature gas in the upper layer of the cooling tower for dry extinguishing the dry coke coagulated in the carbonization chamber of the coke oven is nitrogen gas in the upper layer through a plurality of injection holes Nitrogen supply means for supplying a, and a collecting means for sucking the high-temperature gas from the upper layer through a plurality of collecting ports.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

First, according to the present invention, in order to prevent the explosion caused by the high temperature gas 70a stagnant in the upper layer 70 of the chamber cooling tower 20 of the dry fire extinguishing facility of the coke oven, circular nitrogen in the chamber upper layer 70 space The supply pipe 90 is provided, and the supply pipe 90 is equipped with a plurality of injection holes 91, 92, 93, and 94 facing the upper layer portion. Preferably, the jet is directed along the inner surface of the upper layer such that nitrogen injected through the spray port causes vortexing inside the upper layer.

The front side of the nitrogen supply pipe 90 is provided with a supply regulating electric valve 95, a nitrogen tank 96 of a predetermined size, a pressure sensor 97 for nitrogen pressure control, and a front inlet side line of the nitrogen tank 96. An electric valve 98 for shutting off the nitrogen supply is provided. The final nitrogen supply is through the main nitrogen line 99.

On the other hand, the circular collecting tube 200 is installed in a predetermined main body space on one side of the lower end of the nitrogen supply pipe 90, and the plurality of fallopian tube collecting holes 201, 202, 203, and 204 facing the inside of the upper layer are mounted. . The front end portion of the circular collecting pipe 200 is provided with a pressure control sensor 205, a collecting blower and a control motor 206, a shutoff electric valve 207, and a front end side on which the electric valve 207 is disposed. The collection line 208 is connected to the steam boiler device 33 which is a heat recovery device to recover the heat of hot gas.

At a predetermined position of the lower body of the chamber lid 40, a piston electric heat-resistant oxygen sensor 100 is provided to detect the oxygen concentration flowing into the digestion tower 20. In addition, the charging device unit 400 and the control panel 300 for controlling the nitrogen supply means and the collecting means and the sensor.

The control means is input and output to the sensor 100 with the chamber lid 40 open after the charging preparation process is completed in the charging device unit 400. That is, when oxygen is detected by the detection sensor 100, the nitrogen gas is opened by the nitrogen supply valve, and the high temperature gas stagnated in the unspecified portion of the upper layer 70 is diluted and collected by the collecting means. Then, when the chamber lid 40 is closed, the control panel 300 performs electrical control under the condition that the nitrogen supply is terminated.

By preventing the instantaneous contact between the high temperature combustible gas remaining in the chamber upper layer 70 and the oxygen in the air in advance, it is possible to prevent explosion and at the same time, use high temperature heat of the trapped gas as a recovery energy production heat source.

From the start point of charging the coke to the end of the charging, the control panel 300 according to the present invention electrically controls the dilution and removal of the hot gas component, and prevents the instantaneous contact of oxygen in the air in advance to prevent the explosion phenomenon. It is possible to recover and utilize the high heat gas depletion inside the collected chamber. That is, the high temperature gas collected through the control means is supplied to the heat exchanger 33, and after heat exchange, is recycled after the separation operation through a centrifugal dust collector 34, which is a post-process, converted into cooling gas, and a supply device of the chamber. Is reused.

When the bucket loaded with the carbonized coke of the carbonization chamber is placed on the chamber cooling tower 20 in the correct position after hoisting the crane, the preparation for charging is completed, the chamber lid 40 is opened, and the red coke loaded in the bucket is charged. If the upper cover is closed after charging, the control operation of the central cab charging unit 400 which is one cycle is completed.

When the output signal of the initial point of the control means of the control unit of the central cab charging unit 400, that is, the chamber lid 40 opening signal is input to the control panel 300 of the present invention, the control panel 300 is the oxygen sensor 100 To detect oxygen, and when oxygen is detected, a signal from the oxygen detecting sensor 100 is output to open the supply motor valve 95 of the nitrogen supply pipe 90.

Nitrogen in the nitrogen tank 96, which is maintained at a constant pressure at the same time as the valve 95 is opened, is injected through the four injection holes 91, 92, 93, 94 provided in the chamber inner 70 through the supply pipe 90. do. Nitrogen injected through the injection port dilutes the hot gas generated after charging while generating a vortex phenomenon in the upper part of the cooling tower, and the diluted gas is lowered to the lower side as the weight is increased. At this time, the shutoff motor valve 207 of the collecting pipe 200 is opened and the blower control motor 206 is started to maintain the high temperature gas diluted with nitrogen to a predetermined 'K' target value by the collecting pressure sensor 205. The pressure is collected through the collecting ports 201, 202, 203, and 204.

After collection, the high-temperature fine gas is sent to the steam production boiler 33 to recover the heat of the high-temperature fine gas.

On the other hand, the nitrogen main motor valve 98 provided in front of the nitrogen tank 96 is kept open at all times, but when the sensor 97 of the nitrogen pressure tank is closed under a predetermined 'K' target value pressure, the main nitrogen is given. (99) Prevent backflow due to inability to supply.

In addition, the control operation means as described above allows the nitrogen supply and collection to be completed within a predetermined 'K' target time (for example, operation standard 55 seconds).

The predetermined 'K' target time of the operation control is based on the end of the charging time, and the above standard application of the conventional explosion phenomenon is that the hot gas is stagnated in the upper layer after the charging, and the lid of the chamber (40) is charged. Explosion phenomenon occurs when instantaneous contact with oxygen in the atmosphere during opening. Therefore, in the repeated operation process, the operation is performed at a predetermined 'K' target time from the opening point of the lid before charging to the closing of the lid after charging.

Therefore, according to the present invention, by cooling and collecting the high temperature gas remaining in the upper portion of the chamber cooling tower of the coke dry fire extinguishing facility with nitrogen, it prevents the explosion phenomenon by the high temperature gas to prevent fire and burns attached to the inside of the chamber cooling tower It has the effect of extending the life of the cooling tower body equipment and preventing subtraction due to frequent maintenance to ensure stable operation, and contribute to the increase of energy production effect by reusing the heat of hot gas.

The foregoing is merely illustrative of the preferred embodiments of the present invention and those skilled in the art to which the present invention pertains may make modifications and changes to the present invention without departing from the spirit and gist of the invention as set forth in the appended claims. It should be recognized.

1 is a block diagram showing a typical dry fire extinguishing equipment.

Figure 2 is a block diagram showing a state in which the high temperature gas control device according to the present invention is mounted on the upper portion of the digestion tower.

Figure 3 is a horizontal cross-sectional view showing a state in which the injection port and the collecting port of the high temperature gas control apparatus according to the present invention located inside the upper layer.

4 is a cross-sectional view of the injection hole of the high temperature gas control apparatus according to the present invention.

5 is a cross-sectional view of the collecting port of the high temperature gas control apparatus according to the present invention.

<Description of Symbols for Major Parts of Drawings>

10: fire truck

90: nitrogen supply pipe

91, 92, 93, 94: nozzle

96: nitrogen tank

100: oxygen detection sensor

200: collection tube

201, 202, 203, 204: collecting port

Claims (4)

In the apparatus for controlling the high temperature gas in the upper portion of the cooling tower for dry fired dry carbonized coke in the carbonization chamber of the coke oven, Nitrogen supply means for supplying nitrogen gas to the upper layer through a plurality of injection holes, High temperature gas control device of the upper portion of the cooling tower, characterized in that the collecting means for sucking the high temperature gas from the upper layer through a plurality of collecting ports. The method of claim 1, A chamber lid is provided at an upper end of the digestion tower, and the upper layer portion adjacent to the chamber lid is provided with an oxygen sensor. The method of claim 2, Nitrogen is supplied to the upper layer through the injection port from the opening point of the chamber lid, the high temperature gas control device of the upper portion of the cooling tower, characterized in that the nitrogen supply is stopped when the chamber lid is closed. The method of claim 1, The collecting means is in communication with the heat exchange facility, the high temperature gas suctioned through the collecting port is a high temperature gas control device of the upper portion of the cooling tower, characterized in that the heat exchange in the heat exchange facility.