JPH07126641A - Dry type quenching device for coke - Google Patents

Abstract

PURPOSE:To provide a coke dry type quenching device for coke capable of stably increasing both circulating gas-sensible heat and recovery heat, equipped with an oxygen-contg. gas blowoff means on a chamber oven lid, suction pressure-regulating means on sloping flues, and provided with a detecting means inside the chamber oven lid and a control means therefor in the sloping flues. CONSTITUTION:This dry type quenching device for coke is equipped with an oxygen-contg. gas blowoff means 11 fitted on a chamber oven lid 10 and to blow an oxygen-contg. gas into a prechamber 3, a regulating means 14 for the blowoff of the oxygen-contg. gas, suction pressure-regulating means 17 mounted respectively on plural sloping flues 5 to regulate the gas exhaust to the sloping flues 5, a gas component detecting means 21 for detecting the gas components in the prechamber 3, a gas temperature detecting means 22, and a control means 16 to actuate the means 14 and 17 based on the results from the detecting means 21, 22, 23. Thereby, circulating gas-sensible heat and the recovery heat from coke waste heat can be increased stably.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a novel coke dry fire extinguisher.

[0002]

2. Description of the Related Art At present, a chamber-type coke dry-type fire extinguisher apparatus is widely used for the purpose of recovering coke exhaust heat as shown in FIG.

From FIG. 5, a conventional coke dry fire extinguisher 6 is shown.
1, a cooling chamber 2 for continuously cooling red hot coke produced in a coke oven is provided, and a pre-chamber 3 is provided above the cooling chamber 2. Further, a chamber furnace lid 10 is placed on the upper opening of the pre-chamber 3, and except for opening it when charging the red hot coke by kiln removal, gas leakage and dust scattering generated in the pre-chamber 3 are prevented. It is closed to prevent it.

Further, in the cooling chamber 2, a blasting head 4 which is a blowing device of a circulating gas for continuously cooling the red hot coke is provided in the lower part of the cooling chamber 2 and is supplied from the blasting head 4. The circulated gas is heat-exchanged while cooling the charging coke, and thereafter, the sloping flue 5 provided at 30 to 40 places at equal intervals is provided on the outer periphery of the upper end of the cooling chamber 2 to remove the boiler from the outside of the system. The gas that has been sent to a heat exchange device (not shown), etc., is cooled by performing heat exchange by generating high-pressure steam with such a heat exchange device, as a circulating gas with a constant air volume by a gas circulation blower, etc. It is supplied from the blasting head 4 into the cooling chamber 2. As the circulating gas, an inert gas having an N ₂ gas content of about 70% is usually used.

In the above circulating gas, in addition to being used as a coolant for red hot coke, in order to recover coke exhaust heat, high pressure steam is efficiently and stably generated in heat exchange in a boiler outside the system. There is a need. Among these, the air volume to the boiler is always controlled to be constant because of the stable cooling performance of the red hot coke, and the boiler inlet temperature is also raised to the heat resistant temperature of the normal boiler.
Since it is maintained at a constant temperature, in order to stably generate high-pressure steam, it is necessary to keep the specific heat of the circulating gas, which is the remaining fluctuation factor, constant. It was necessary to burn unburned components such as CO and H ₂ that emerged in the circulating gas into a gas having a constant specific heat and a constant inert state.

Therefore, conventionally, air is introduced into the inside of the coke dry-type fire extinguisher, and CO or H ₂ which are residual volatile components (unburned components) of coke are burned by the air to form a gas having a constant specific heat. Furthermore, powder coke and undry distillate of coke remain inside the pre-chamber of the coke dry-type fire extinguisher, but there is also an advantage that new heat can be obtained by burning these by the introduction of air. It is known that uniform introduction of air is desired in order to positively utilize these.

As the air introducing means, there is an air introducing means by a pushing fan into the pre-chamber, as shown in FIG. As the air introduction means, an air blowing nozzle is provided in a part of the outer wall of the pre-chamber 3 above the charged red hot coke surface, and the air blowing nozzle 6 and the pushing fan 7 are connected by a pipe 8 A flow rate control valve 9 is provided on the path of the pipe 8. By operating the pushing fan 7, air is forcedly fed into the pre-chamber 2 from the air blowing nozzle 6, which is required. The amount is adjusted by opening and closing the flow rate control valve 9 provided on the pipe path.

However, with the push-in fan only,
It was difficult to obtain uniform air introduction in the circumferential direction of the prechamber. That is, since the air blowing direction into the pre-chamber 3 is biased due to the air blowing from only a specific direction, the amount of air that passes through the gap of the charging coke in the pre-chamber 3 and is brought to each sloping flue 5 is made uniform. Was hard to get.

As another means for introducing air, FIG.
As shown in, there is an air introduction means by negative pressure from the sloping fluff. As the air introducing means, a negative pressure is applied to the inside of the chamber including the sloping fluff 5, an air blowing nozzle 6 is provided in a part of each sloping flue 5, and a pipe 8 is connected to the air blowing nozzle 6. A flow rate control valve 9 is provided on the path of the pipe 8, and the other end of the pipe 8 is open to the atmosphere. That is,
Since the air can be introduced without using the pushing fan 7 etc. by setting the internal pressure to a negative pressure, it is possible to adjust the introduction of the required amount of air by opening / closing the flow rate control valve 9 provided on the pipe path. It was something to do. According to this, in the periphery of the upper end of the cooling chamber 2, 30 to 40 are evenly spaced.
Since the air blowing nozzles 6 are provided in all of the sloping flumes 5 provided at some places, there is no occurrence of non-uniformity of the blowing air unlike the air introducing means by the pushing fan 7 into the pre-chamber 3. Therefore, uniform combustion can be performed.

However, when the introduction of air is provided in each sloping flue 5, there is an action of burning coke residual volatile matter and powder coke which are discharged into the circulating gas at the downstream portion of the sloping flue 5. , Pre-chamber 3
There is no combustion effect inside, and the powder coke and the non-dry fraction of coke inside the pre-chamber 3 are not used at all, so it cannot be said to be a very efficient air introduction means. .

On the other hand, as a coke reforming technology by introducing air into a prechamber of a coke dry digestion facility for low temperature kiln discharged coke from a room type coke oven, Japanese Patent Application Laid-Open No. 2-19 is known.
There are disclosed technologies such as 487 and JP-A-2-199191.

In such a coke manufacturing method, carbonization is carried out in a coke oven at a low temperature for a short time, and the obtained coke is burned by introducing air in a prechamber of a coke dry-type fire extinguisher to reform undried coke. After completely dry-distilling it, it tries to cool it in the cooling chamber. In this case, as the thermal energy necessary for reforming the non-dry-distilled coke, the powder coke or the non-dry-distilled volatile matter in the prechamber is used by burning.
Therefore, it is important to introduce air evenly in the sense that the dry distillation is promoted for the coke component produced by the low temperature dry distillation.

Further, in the above-mentioned method for producing coke by low temperature carbonization, there is a case where the thermal energy necessary for reforming the non-carbonized coke is insufficient only by burning the powder coke in the prechamber or the non-carbonized volatile matter. Therefore, even in a new energy source to make up for the shortage in such a case, uniform introduction is indispensable from the viewpoint of preventing heating due to local abnormal combustion, just like the introduction of air. The current situation is that there is a strong demand for the development of a uniform means of introducing sources.

[0014]

Accordingly, it is an object of the present invention to provide a novel coke dry fire extinguisher.

Another object of the present invention is to uniformly introduce the oxygen-containing gas into the pre-chamber while adjusting the amount of the oxygen-containing gas to a predetermined amount in order to positively and efficiently perform heat exchange in the chamber. However, the present invention provides a coke dry-type fire extinguisher capable of producing a gas having a constant specific heat by uniformly burning this with unburned components, coke powder, and the like.

Further, an object of the present invention is to adjust the oxygen-containing gas and the new energy source in the prechamber to a predetermined amount when the thermal energy required for reforming the non-dry-distilled coke is insufficient. It is introduced uniformly, and the introduced oxygen-containing gas and the unburned components and powder coke remaining in the chamber are uniformly burned to reform the undistilled coke and produce a gas with a constant specific heat. The present invention provides a coke dry fire extinguisher that can be used.

[0017]

In order to achieve the above object, the inventor of the present invention has conducted extensive research on a new coke dry fire extinguisher system, and as a result, first of all, a uniform oxygen-containing gas in the prechamber has been obtained. The furnace lid provided on the upper part of the chamber, which has been used only as a gas seal of a coke dry fire extinguisher as an introduction means, is a brick structure, but the pressure to the furnace lid is such that the internal pressure of the chamber is about 0 to 10 mm. When only a large number of oxygen-containing gas injection nozzles are provided in the furnace lid, it is sufficient that the negative pressure is only applied, and it is extremely small and the furnace lid has the strength to support its own weight. However, paying attention to the fact that the brick structure can be stably maintained, oxygen-containing gas blowing means is formed in the chamber furnace lid, and oxygen for adjusting the amount of oxygen-containing gas blown from the oxygen-containing gas blowing means is adjusted. By installing a perforated gas injection amount adjusting means in which we have found that it is possible to achieve the introduction means. Further, when the red hot coke is charged, it is necessary to move the furnace lid in the horizontal direction, which hinders the installation of the oxygen-containing gas blowing amount adjusting means connected to the oxygen-containing gas blowing nozzle to the furnace lid. With regard to the above, by using a flexible tube or the like for a part of a member (for example, a pipe) connected to the oxygen-containing gas blowing nozzle, the oxygen-containing gas blowing amount adjusting means can be sufficiently dealt with.

Next, as a means for uniformly burning the introduced oxygen-containing gas in the chamber and the unburned components of CO and H ₂ , and the residual components of the powder coke and the non-distilled fraction of coke, the charging in the prechamber is performed. Since the bulk density and properties of coke are not uniform, oxygen-containing gas is introduced uniformly,
Even if the amount of oxygen-containing gas introduced into each sloping flue through the gap of the charging coke in the prechamber is made uniform, abnormal combustion may occur locally. Noting that variations can be indirectly captured as differences in temperature and gas constituents within the prechamber and each sloping flue, a detector for detecting such indirect data is installed in the prechamber and each sloping flap. Provided in the ryu, the data value detected by this is arithmetically processed by the control means connected to the detection means to detect an abnormal combustion portion, and to control the total amount of the oxygen-containing gas introduced,
By knowing that it is possible to indirectly control the oxygen-containing gas supply amount by reducing the suction amount to the sloping fluff portion corresponding to the abnormal combustion portion, based on the calculation result of the control means, The combustion means can be achieved by providing the gas blowing means with an oxygen-containing gas blowing quantity capable of adjusting the oxygen-containing gas introduction quantity and by providing a suction pressure adjusting means capable of adjusting the gas drawing quantity into the sloping flue. It is the one that was found.

Further, in the novel method for producing coke by low temperature carbonization, if the powdered coke in the pre-chamber or the non-carbonized volatile matter is simply burned, the thermal energy required for reforming the non-carbonized coke is insufficient. As a uniform introduction means of a new energy source for supplementing the above, similarly to the uniform introduction means of the oxygen-containing gas into the pre-chamber, a blowing means of a new energy source is formed on the chamber furnace lid, The introduction means can be achieved by installing a blowing amount adjusting means for adjusting the blowing amount of the energy source from the blowing means, and the blowing amount can be achieved by a detecting means and a controlling means similar to the burning means. It has been found that a uniform combustion means can be obtained by controlling, and in such a case, as shown in FIG. 6, by introducing an oxygen-containing gas. Regarding the burning rate of coke, focusing on the fact that powder coke has an excellent burning rate due to an extremely small amount of oxygen-containing gas, it has been used in the conventional coke production as a function to heat undry carbonized coke and accelerate dry distillation. It was found that the coke powder generated in the process but with low utility can be achieved extremely effectively and economically by preferentially using the coke powder that has been recovered and treated as a new energy source. It is a thing.

That is, the present invention has been completed by organically combining these based on the findings obtained above.

Therefore, an object of the present invention is to form a cooling chamber, a plurality of sloping flues for drawing in and discharging the gas in the chamber are provided in an outer peripheral portion of the cooling chamber, and a cooling chamber is provided above the cooling chamber. A coke dry fire extinguisher in which a chamber is provided and an openable chamber furnace lid is attached to the red hot coke inlet of the upper opening of the prechamber, wherein the oxygen-containing gas provided in the chamber furnace lid is used as a prechamber. Oxygen-containing gas blowing means for blowing into the inside, oxygen-containing gas blowing amount adjusting means for adjusting the oxygen-containing gas blowing amount from the oxygen-containing gas blowing means, and to the sloping flue provided in each of the sloping flue Of the gas pressure in the pre-chamber and the suction pressure adjusting means for adjusting the exhaust amount of the gas Gas component detecting means, gas temperature detecting means for detecting the gas temperature in the pre-chamber, drawn gas temperature detecting means for detecting the temperature of the gas drawn into each sloping flue, and gas detected by the gas component detecting means The oxygen-containing gas blowing amount adjusting means is operated based on the component and the gas temperature detected by the gas temperature detecting means, and the individual pulling adjusting means is operated based on the drawn gas temperature detected by the drawn gas temperature detecting means. It is achieved by a coke dry-type fire extinguisher.

Further, according to the present invention, the powder coke blowing means for blowing the powder coke provided in the chamber furnace lid into the prechamber, and the powder coke blowing amount for adjusting the powder coke blowing amount from the powder coke blowing means. Adjusting means, and operates the oxygen-containing gas blowing amount adjusting means and the powder coke blowing amount adjusting means based on the gas component detected by the gas component detecting means and the gas temperature detected by the gas temperature detecting means. In addition, the above coke dry fire extinguisher is characterized in that the coke dry fire extinguisher has control means for activating each of the pull-in adjusting means based on the pull-in gas temperature detected by the pull-in gas temperature detecting means.

Further, in the present invention, an oxygen-containing gas blowing nozzle is provided on a chamber furnace lid as the oxygen-containing gas blowing means, and the oxygen-containing gas blowing nozzle and the oxygen-containing gas storage are provided as the oxygen-containing gas blowing amount adjusting means. And an oxygen-containing gas supply pipe connecting the section and a flow rate adjusting valve on the path of the oxygen-containing gas supply pipe, the flow rate adjusting valve is provided with a drive means, the control means connected to the drive means, and The present invention can also be achieved by the coke dry fire extinguisher described above, which has means for operating the drive means by the control means to adjust the opening degree of the flow rate adjusting valve.

Further, in the present invention, as the suction pressure adjusting means, a heat resistant butterfly valve is installed at a gas inlet to each sloping flue, and the heat resistant butterfly valve is provided with a driving means and is connected to the driving means. The present invention is also achieved by any one of the above-described coke dry fire extinguisher, which has the control means and means for operating the drive means by the control means to adjust the opening degree of the heat-resistant butterfly valve.

Furthermore, in the present invention, as the gas component detecting means, a gas sampling hole is formed in each part of the pre-chamber, and a gas component analyzer for analyzing the gas sampled from the gas sampling hole is installed to set the gas temperature. As a detecting means, a thermocouple is provided in each part of the prechamber,
Further, the above-mentioned or any one of the coke dry fire extinguishing apparatuses characterized in that each of the sloping fluff is provided with a thermocouple as the inlet gas temperature detecting means.

In the present invention, a powder coke blowing nozzle is provided on the chamber furnace lid as the powder coke blowing means, and a powder coke blowing nozzle and a powder coke storage unit are connected as the powder coke blowing amount adjusting means. A coke supply pipe, a transfer amount adjusting valve provided on the path of the powder coke supply pipe, a drive unit provided on the transfer amount adjusting valve, the control unit connected to the drive unit, and the drive unit by the control unit. It is also achieved by the coke dry fire extinguisher device described above or any one of the above items, characterized in that the coke dry fire extinguishing device is provided with a means for operating the.

[0027]

In the coke dry fire extinguisher of the present invention, the individual suction pressure adjusting means are operated so that the temperature distribution of the drawn-in gas in each sloping flue becomes uniform, so that the chamber-furnace lid is provided on the upper part of the chamber. The oxygen-containing gas blown into the pre-chamber from the oxygen-containing gas blowing means is normally introduced into the pre-chamber uniformly (especially uniformly in the circumferential direction of the chamber), and then directly in the red hot coke in the pre-chamber. It is detected through the exhaust from each sloping flue through, and when partial variation occurs due to local abnormal combustion of the introduced oxygen-containing gas with the unburned components and powder coke in the pre-chamber. By calculating the temperature and gas component values, the abnormal combustion portion is detected, the total amount of the oxygen-containing gas introduced is limited, and By reducing the suction amount of the sloping off Liu portion corresponding to the combustion section, in which uniform and complete combustion of the introduced oxygen-containing gas and unburned components or coke inside the pre-chamber can be achieved.

Further, in the coke dry-type fire extinguisher of the present invention, by operating the individual suction pressure adjusting means so that the distribution of the drawn-in gas temperature in each sloping flue becomes uniform, the chamber furnace lid on the upper part of the chamber is operated. The oxygen-containing gas and powder coke blown into the pre-chamber from the provided oxygen-containing gas blowing means and powder coke blowing means are usually uniformly introduced into the pre-chamber,
The oxygen-containing gas passes through the red hot coke in the prechamber as it is and is exhausted from each sloping flue. In the case of the manufacturing method of the prechamber, if the thermal energy necessary for reforming the non-dry distillation coke is insufficient just by burning the powder coke derived from the red hot coke or the non-dry distillation volatile matter remaining in the prechamber, or due to an excessive supply, etc. Even if variations occur due to local abnormal combustion of the introduced oxygen-containing gas and powder coke inside the furnace, the detected temperature and gas component values are calculated to calculate the abnormal combustion portion or undistilled coke Insufficient amount of heat energy required for quality and the insufficient portion are detected, and the total amount of oxygen-containing gas introduced and the powder coke The amount of oxygen introduced into the pre-chamber and unburned components and coke powder are adjusted by adjusting the amount of gas introduced and by reducing or increasing the amount of suction to the sloping flue part corresponding to insufficient thermal energy or abnormal combustion. A uniform and complete combustion with
The thermal energy required for reforming the non-dry-distilled coke is obtained.

[0029]

EXAMPLES Examples of the present invention will now be described in more detail based on the embodiments.

FIG. 1 is a sectional view showing a part of a coke dry fire extinguisher according to an embodiment of the present invention.

As shown in FIG. 1, the coke dry fire extinguisher 1 according to the present invention is provided with a cooling chamber 2 for continuously cooling the red hot coke produced in the coke oven, and the upper outer periphery of the cooling chamber 2. In the department,
The sloping fluff 5 is provided at about 30 to 40 places at equal intervals.

A pre-chamber 3 for a buffer is provided above the cooling chamber 2. A chamber furnace lid 10 is attached to the red hot coke charging port at the upper opening of the pre-chamber 3 so as to move horizontally when the red hot coke is charged. Further, the furnace lid 10 is provided with, as an oxygen-containing gas blowing means, one or more oxygen-containing gas blowing nozzles 11 at equal intervals on the circumference at a certain distance from the center of the furnace lid 10. Each oxygen-containing gas blowing nozzle 11 and the oxygen-containing gas storage unit 12 are connected by an oxygen-containing gas supply pipe 13 as a contained gas blowing amount adjusting means. A flow rate adjusting valve 14 is provided on the path of the oxygen-containing gas supply pipe 13, and a drive unit 15 is attached to the flow rate adjusting valve 14, and the drive unit 15 is connected to a control unit 16. ing. Here, a part of the oxygen-containing gas supply pipe 13 is formed by using a flexible member such as a flexible tube so as to follow this movement when the furnace lid 10 moves in the horizontal direction. Has been done.

Heat-resistant butterfly valves 17 are installed in the gas inlets of all of the sloping flukes 5 as the suction pressure adjusting means in each part of the sloping flukes 5, and the heat-resistant butterfly valves 17 are provided with a drive unit 18. Is provided, and the drive device 18 is connected to the control device 16.

Further, in each part of the pre-chamber 3 and the sloping flue 5, a gas sampling hole 19 is first formed in the brick wall above the pre-chamber 3 as a gas component detecting means. 20 is attached, and the other end of the pipe 20 is connected to a gas component analyzer 21. Further, as a gas temperature detecting means, in the vicinity of the inlet of the gas sampling hole 19,
Thermocouples 22 are attached respectively. A thermocouple 22 is attached near the upper end of each sloping fluff 5. Further, the gas component analyzer 21 and the thermocouples 22 and 23 are connected to the controller 16. It is desirable to provide a plurality of gas sampling holes on the circumference at equal intervals, but even one gas sampling hole has a sampling function.

The coke dry fire extinguisher 1 of the present invention having the above-mentioned structure operates as follows based on the flow chart shown in FIG.

First, the gas temperature of each part of the prechamber 3 is detected by the thermocouple 22 provided in the prechamber 3 (S
1), the gas components in each part of the prechamber 3 are added to the prechamber 3
It is detected by the gas component analyzer 21 through the pipe 20 from the gas sampling hole 19 provided in (S2), and then the temperature of the drawn gas of each sloping flue is detected by the thermocouple 23 provided in the sloping flue (S3).

This gas component analyzer 21 and both thermocouples 2
The detected values of 2, 23 are input to the control device 16, but the control device 16 is based on the signals from the gas component analyzer 21 and the thermocouples 22 and 23 of both types, and the control device 16 in the pre-chamber 3 receives the signals. How the gas components and the gas temperature are distributed inside the chamber 3 (particularly in the circumferential direction), and how the drawn-in gas temperature for each sloping flue 5 is distributed in each sloping flue 5. Is calculated. Since the gas sampling hole 19 and the thermocouples 22 and 23 of both kinds are provided in large numbers in the circumferential direction of the prechamber 3 and for each sloping flume 5 as described above, the gas sampling holes 19 and The distribution of the gas component and the gas temperature in the pre-chamber 3 and the distribution of the drawn gas temperature in the sloping flue 5 are calculated by referring to the analysis values of the detected gas components and the detected temperatures of all the thermocouples 22 and 23. There is. Then, based on this calculation result, the total amount of oxygen-containing gas to be supplied into the pre-chamber 3 is calculated, and the distribution of the amount of blown oxygen-containing gas in the circumferential direction (or the suction amount of each sloping flue 5) is distributed. Calculation is performed (S4).

The control unit 5 supplies the oxygen-containing gas supplied from the oxygen-containing gas storage unit 12 through the oxygen-containing gas supply pipe 13 so that the oxygen-containing gas supply amount according to the calculation result is supplied into the pre-chamber 3. The drive unit 15 attached to the flow rate adjusting valve 14 for adjusting the gas flow rate is operated to adjust the opening degree of the flow rate adjusting valve 14. In addition, the same amount of exhaust gas as this oxygen-containing gas is exhausted from the pre-chamber 3 through the gas inlet of each sloping flu 5 (in this case, the intake and exhaust of the circulating gas in the cooling chamber is included. And the distribution of the amount of oxygen-containing gas passing through the charging coke in the prechamber 3 is
Normally, the pre-chambers 3 are provided so as to be uniform irrespective of the location and to reduce the amount of oxygen-containing gas at the abnormal combustion location when abnormal combustion occurs. The driving device 18 attached to the heat-resistant butterfly valve 17 of the sloping fluff 5 is individually operated to adjust the opening thereof (S5).

Next, FIG. 3 is a sectional view showing a part of a coke dry fire extinguisher 31 according to another embodiment of the present invention.

As shown in FIG. 3, in the coke dry-type fire extinguisher 31 of the present embodiment, a powder coke blowing nozzle 24 is formed in the center of the chamber furnace lid 10 as a powder coke blowing means on the chamber furnace lid 10 to blow the powder coke. As a quantity adjusting means, the powder coke blowing nozzle 24 and the powder coke storage unit 25 are connected by a powder coke supply pipe 26, and a transport flow rate adjusting valve 27 is provided on the path of the powder coke supply pipe 26. Further, the carrier flow rate adjusting valve 27 is provided with a drive device 28, which drives the control device 1
It is connected with 6. Other than these, the coke dry fire extinguisher 1 has the same configuration as that of FIG.

Next, the flowchart shown in FIG. 4 is provided with a process of supplying coke powder in addition to the above process.

Also in this process, similarly to the flow chart shown in FIG. 3, first, the gas temperature of each part of the prechamber 3 is detected by the thermocouple 22 provided in the prechamber 3 (S1), and the gas of each part of the prechamber 3 is detected. The components are detected by the gas component analyzer 21 through the pipe 20 through the gas sampling hole 19 provided in the pre-chamber 3 (S2), and then the drawn gas temperature of each sloping flue is detected by the thermocouple 23 provided in the sloping flue ( S
3). Then, similar to the above, the control device 16 controls the gas component and the gas temperature inside the pre-chamber 3 (particularly in the circumferential direction) based on the signals from the gas component analyzer 21 and the thermocouples 22 and 23 of both types. Is calculated and how the drawn-in gas temperature for each sloping fluff 5 is distributed in each sloping fluff 5, and based on this calculation result The total amount of oxygen-containing gas to be supplied is calculated, and the distribution of the amount of oxygen-containing gas blown out in the circumferential direction (or the suction amount for each sloping flue 5) is calculated (S4).

Further, based on the calculation result of the step S4, the control device 16 confirms that the thermal energy required for reforming the non-dry distillation coke is not sufficient just by burning the remaining powder coke and the non-dry distillation volatile matter. When it is detected or when it is detected that there is a variation due to local abnormal combustion of the introduced oxygen-containing gas and the powder coke in the pre-chamber 3 due to excessive supply, etc., the optimum supply amount of the powder coke is calculated, An appropriate amount of powder coke is supplied from the powder coke supply device 25 through the powder coke supply pipe 26, and a drive device 28 attached to a transfer flow rate adjusting valve 27 for adjusting the amount of powder coke is operated to open the transfer flow rate adjusting valve 27. Is adjusted and supplied into the pre-chamber 3. The coke powder is positively blown while being stirred by the oxygen-containing gas supplied from the ceiling surface of the prechamber 3 while being stirred by the charging coke surface. Therefore, the powder coke is efficiently burned, so that the sensible heat of the circulating gas can be increased and the thermal energy required for reforming the non-distilled coke can be supplied (S5, 6).

Next, the control device 16 causes the oxygen-containing gas supply device 12 to supply an oxygen-containing gas supply pipe so that the oxygen-containing gas supply amount according to the calculation result in the step S4 is supplied into the pre-chamber 3. A drive device 15 attached to a flow rate adjusting valve 14 that adjusts the flow rate of the oxygen-containing gas supplied through 13 is operated to adjust the opening degree of the flow rate adjusting valve 15. In addition, the same amount of exhaust gas as the oxygen-containing gas is exhausted from the pre-chamber 3 through the gas inlet of the sloping flu 5 (in this case, intake and exhaust of the circulating gas in the cooling chamber are not included. ), And the distribution of the amount of oxygen-containing gas passing through the charging coke in the pre-chamber 5 is usually uniform regardless of the location, and when abnormal combustion occurs or in the non-dry-distilled coke. When a shortage of heat energy required for reforming occurs, the oxygen-containing gas amount at the location of such abnormal combustion or shortage of heat energy is reduced or increased so that each of the prechambers 3 is provided. The drive devices 18 attached to the heat-resistant butterfly valve 17 of the sloping fluff 5 are individually operated to adjust the opening thereof (S7).

[0045]

According to the present invention, by introducing the oxygen-containing gas into the pre-chamber uniformly, it is possible to produce a gas having a constant specific heat, whereby the sensible heat of the circulating gas can be stably increased, and the coke exhaust heat can be removed. The amount of heat recovered can be increased efficiently and stably.

It is possible to prevent heating and melting of bricks on the outer wall of the chamber due to localized abnormal combustion accompanying non-uniform introduction of the oxygen-containing gas into the chamber.

Furthermore, in the novel method for producing coke by low temperature carbonization previously proposed by the applicant, the coke powder and the oxygen-containing gas are uniformly introduced into the pre-chamber so that the powder coke can be efficiently burned and the non-carbonization is performed. The heat energy required for reforming the coke can be supplemented, the sensible heat of the circulating gas can be greatly increased, and the recovered heat can be increased.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing a part of a coke dry fire extinguisher according to an embodiment of the present invention.

FIG. 2 is a flowchart showing the operation of the coke dry fire extinguisher system of the present invention configured as shown in FIG.

FIG. 3 is a cross-sectional view showing a part of a coke dry fire extinguisher according to another embodiment of the present invention.

FIG. 4 is a flowchart showing the operation of the coke dry fire extinguisher system of the present invention configured as shown in FIG.

FIG. 5 is a cross-sectional view showing one embodiment of a conventional coke dry fire extinguisher.

[Explanation of symbols]

1, 31, 61 ... Coke dry fire extinguisher, 2 ... Cooling chamber, 3 ... Prechamber, 4 ... Circulating gas blasting head, 5 ... Sloping flu,
6 ... Oxygen-containing gas blowing nozzle, 7 ... Pushing fan, 8 ... Piping, 9 ... Flow control valve, 10 ... Chamber furnace lid, 11
... Oxygen-containing gas blowing nozzle, 12 ... Oxygen-containing gas storage section, 13 ... Oxygen-containing gas supply pipe,
14 ... Flow rate adjusting valve, 15, 18, 28 ... Driving device,
16 ... Control device, 17 ... Heat resistant butterfly valve,
19 ... Gas sampling hole, 20 ... Piping, 21 ... Gas component analyzer, 22, 23 ... Thermocouple, 24 ...
Powder coke blowing nozzle, 25 ... powder coke storage unit,
26 ... Powder coke supply pipe, 27 ... Transport flow rate adjusting valve.

Claims (6)

[Claims] 1. A cooling chamber is formed, a plurality of sloping flues for sucking and discharging gas in the chamber are provided at an outer peripheral portion of the cooling chamber, and a pre-chamber for a buffer is provided at an upper portion of the cooling chamber. In the coke dry-type fire extinguisher in which a chamber furnace lid that can be opened and closed is attached to the red hot coke inlet of the upper opening of the prechamber, the oxygen-containing gas provided in the chamber furnace lid is blown into the prechamber. Oxygen-containing gas blowing means to insert, oxygen-containing gas blowing amount adjusting means for adjusting the oxygen-containing gas blowing amount from the oxygen-containing gas blowing means, and the gas to the sloping flue provided in each of the sloping flue A suction pressure adjusting means for adjusting the exhaust amount and a gas component detecting hand for detecting the gas component in the pre-chamber Stage, a gas temperature detecting means for detecting the gas temperature in the pre-chamber, a drawn gas temperature detecting means for detecting the temperature of the gas sucked into each sloping flue, and a gas component and a gas detected by the gas component detecting means. While operating the oxygen-containing gas blowing amount adjusting means based on the gas temperature detected by the temperature detecting means,
A coke dry fire extinguisher comprising control means for activating each of the pull-in adjusting means based on the pull-in gas temperature detected by the pull-in gas temperature detecting means. 2. A powder coke blowing means for blowing the powder coke provided in the chamber furnace lid into a pre-chamber, and a powder coke blowing amount adjusting means for adjusting the powder coke blowing amount from the powder coke blowing means. Having the gas component detected by the gas component detection means and the gas temperature detected by the gas temperature detection means, actuating the oxygen-containing gas blowing amount adjusting means and the powder coke blowing amount adjusting means, and withdrawing the gas. The coke dry fire extinguisher according to claim 1, further comprising control means for activating each of the pull-in adjusting means based on the pull-in gas temperature detected by the gas temperature detecting means. 3. An oxygen-containing gas blowing nozzle is provided on a chamber furnace lid as the oxygen-containing gas blowing means, and the oxygen-containing gas blowing nozzle and the oxygen-containing gas storage section are connected as the oxygen-containing gas blowing amount adjusting means. And an oxygen-containing gas supply pipe, a flow rate adjusting valve is provided on the path of the oxygen-containing gas supply pipe, the flow rate adjusting valve is provided with drive means, the control means connected to the drive means, and the control means The coke dry fire extinguisher according to claim 1 or 2, further comprising means for operating a driving means to adjust an opening degree of the flow rate adjusting valve. 4. As a suction pressure adjusting means, a heat resistant butterfly valve is installed at a gas inlet to each sloping flue, the heat resistant butterfly valve is provided with a driving means, and the control means connected to the driving means, The coke dry fire extinguisher according to any one of claims 1 to 3, further comprising a means for operating the driving means by a control means to adjust the opening degree of the heat-resistant butterfly valve. 5. As the gas component detecting means, a gas sampling hole is formed in each part of the pre-chamber, and a gas component analyzer for analyzing the gas sampled from the gas sampling hole is installed. 5. A coke dry fire extinguisher according to claim 1, wherein a thermocouple is provided in each part of the chamber, and a thermocouple is provided in each sloping flue as the intake gas temperature detecting means. apparatus. 6. A powder coke blowing nozzle is provided on a chamber furnace lid as the powder coke blowing means, and a powder coke supply pipe connecting the powder coke blowing nozzle and the powder coke storage unit is provided as the powder coke blowing amount adjusting means. A transfer amount adjustment valve is provided on the path of the powder coke supply pipe, a drive unit is provided in the transfer amount adjustment valve, the control unit connected to the drive unit, and the drive unit is operated by the control unit. The coke dry fire extinguisher according to any one of claims 2 to 5, further comprising means for adjusting an opening degree of the transfer amount adjusting valve.