JPH1180740A - Removal of attached carbon of coke oven and apparatus therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To readily remove carbon attached to the wall of carbonizing chamber of a coke oven in a short time. SOLUTION: In a method for removing an attached carbon 10 on the ceiling part of a carbonizing chamber by installing a compressed air piping 15 along the rack beam of the pushing machine of a coke oven and spraying compressed air to the ceiling part from a compressed air jetting nozzle 14 of an ejector 11 laid on the top of a beam head 4, hot air Q in the oven is sucked and sprayed upward by the ejector effects of compressed air from the compressed air jetting nozzle 14 of the elector 11 laid on the top of the beam head so that the release amount drawn by the hot air Q in the oven is doubled and the carbon 10 attached to the ceiling part of the carbonizing chamber 8 can be thrown away and removed in a short time.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for removing carbon adhering to a ceiling portion of a coking chamber of a coke oven.

[0002]

2. Description of the Related Art Hydrocarbons (CmH) in coke oven gas generated during dry distillation are placed on the furnace walls of the coke oven carbonization chamber.
n) or carbon generated by thermal decomposition of coal tar adheres. The adhesion of the carbon becomes more remarkable as the operation rate of the coke oven is higher and the volatile matter of the charged coal is higher.

[0003] The carbon adhered to the furnace wall closes the joints of the furnace wall bricks densely and has a function of preventing gas leakage from the carbonization chamber to the combustion chamber, and although it is necessary to some extent, it grows when left as it is. As a result, the thermal conductivity of the furnace wall is reduced, and the effective volume of the carbonization chamber is reduced, thereby reducing the productivity of the furnace. Further, the carbon adhering to the furnace wall causes extrusion troubles such as coke blocking and clogging, and also causes damage to the furnace body. Therefore, it is necessary to periodically remove the carbon.

As a method and an apparatus for removing carbon adhering to a furnace wall, an oxygen-containing gas is supplied through a hollow portion of a rack beam of a coke oven extruder, and the oxygen-containing gas is supplied to the furnace when a coke is extruded from a nozzle provided in the rack beam. Method and apparatus for injecting air into the inside (Japanese Patent Laid-Open No. 3-195797),
A method of spraying coke oven waste gas onto carbon adhering to the upper part of the coking chamber of a coke oven to decompose and remove the adhering carbon (Japanese Patent Laid-Open No. 5-156261), a rotatable U provided on the upper front surface of the extruder The upright nozzle is raised during the coke extrusion work by the extrusion ram, and while moving up and down in that state, the adhering carbon supporting agent such as water mist mixed oxygen-enriched air is injected to remove the adhering carbon near the riser tube base. Combustion removal method (Japanese Patent Laid-Open No. Hei 5-271662),
An air ejection duct whose tip is locked along the rack beam of the extruder is provided, and the air ejection duct is provided with air ejection openings on the left and right over the entire length, and after the rack beam retreats, it is left in the coke oven, A method and apparatus for injecting air in both sides of the furnace in the longitudinal direction to burn carbon in the furnace wall of the coke oven carbonization chamber (Japanese Patent Laid-Open No. 6-166874). A coal port automatic cleaning apparatus (JP-A-6-322374) in which a compressed air supply pipe is arranged with its tip nozzle portion facing upward has been proposed.

[0005]

SUMMARY OF THE INVENTION The above-mentioned JP-A-3-195
The method and apparatus disclosed in Japanese Patent Publication No. 797 are mainly intended to remove carbon adhering to the lower part of the coking chamber, and do not combust and remove the carbon adhering to the ceiling part of the coking chamber.

In the method disclosed in Japanese Patent Application Laid-Open No. 5-156261, a coke oven combustion waste gas is introduced into a carbonization chamber.
It is intended to remove adhering carbon. However, since the amount of oxygen in the combustion waste gas is small, not only the decomposition efficiency of carbon is poor and the carbon removing effect cannot be expected, but also there is a drawback that a large amount of equipment cost is required. .

Furthermore, the method disclosed in Japanese Patent Application Laid-Open No. 5-271662 is intended to mainly remove carbon adhering to the lower part of the riser pipe, and does not combust and remove carbon adhering to the ceiling of the carbonization chamber. .

Further, the method and apparatus disclosed in Japanese Patent Application Laid-Open No. Hei 6-166874 are mainly intended to remove carbon adhering to the side wall of the coking chamber, and combust and remove the carbon adhering to the ceiling of the coking chamber. Not something.

The apparatus disclosed in Japanese Patent Laid-Open Publication No. Hei 6-322374 removes carbon by blowing compressed air from a nozzle of a rack beam toward a coal hole.
The carbon removal effect cannot be expected. That is, in the case of the present apparatus, the carbon removal is a physical action by the blowing force of the compressed air, but the discharged air amount is 5 m ³ / min or less, and the blowing speed to the carbon part 1 m away from the nozzle is reduced. Is 1 m / sec or less (test result), which is not satisfactory as a carbon removing effect.

It is an object of the present invention to provide a method and an apparatus for removing carbon adhering to a coke oven, which can solve the above-mentioned drawbacks of the prior art and can easily remove carbon adhering to the ceiling of the coking chamber in a short time.

[0011]

According to a first aspect of the present invention, there is provided a method of removing carbon adhering to a coke oven, wherein a compressed air pipe is provided along a rack beam of the coke oven extruder, and a nozzle installed above the beam head. In the method of spraying more compressed air and removing the carbon adhering to the ceiling of the carbonization chamber, the hot air in the furnace is sucked upward by the ejector effect of the compressed air from the compressed air ejection nozzle of the ejector installed above the beam head. It is squirted to remove carbon adhering to the ceiling of the carbonization room.

As described above, the hot air in the furnace is sucked and ejected upward by the ejector effect of the compressed air from the compressed air ejection nozzle of the ejector installed on the upper portion of the beam head. The internal hot air can be spouted at a high speed, and the carbon adhering to the ceiling of the carbonization chamber can be blown away and removed in a short time.

According to a second aspect of the present invention, there is provided an apparatus for removing carbon adhering to a coke oven, wherein a compressed air pipe communicating with a compressed air supply device is provided on a rack beam of the coke oven extruder, and a tip nozzle portion thereof is provided. The ejector is arranged upward at the center of the trumpet-shaped diffuser arranged above the beam head.

As described above, a compressed air pipe communicating with the compressed air supply device is provided on the rack beam of the coke oven extruder, and the compressed air nozzle at the tip thereof is provided at the center of the trumpet-shaped diffuser arranged above the beam head. By configuring the ejector upward, the ejector effect of the compressed air ejected from the compressed air nozzle arranged upward causes the lower part of the diffuser to be in a vacuum state and a large amount of hot air in the furnace is sucked and carbonized at high speed. The carbon spouted on the ceiling of the room and attached to the ceiling of the carbonization room can be blown away and removed in a short time.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION In the present invention, the shape of the diffuser for obtaining the blowing air amount and the blowing speed for removing the adhering carbon is 3 to 6 degrees in the trumpet angle, and the bell mouth is in the throat. The throat diameter is determined according to the amount of intake air, and may be about 50 to 150 mm. However, the compressed air ejected from the compressed air nozzle needs to have a sound velocity or higher.

Under the above conditions, the compressed air pressure is 4 kg / cm
² · G, when the compressed air ejection amount is 2 m ³ / min, the suction amount of the hot air in the furnace sucked by the ejector effect is 20 m ³ / min, the blowing air amount is 22 m ³ / min, and 1 m from the tip of the ejector. The blowing speed to the distant carbon adhesion portion is 20 m / sec or more, which is enough to blow off soft carbon generated on the ceiling portion of the carbonization chamber.

The compressed air supply device in the present invention includes a compressor for compressing air, a tank for storing compressed air, a supply drum for supplying compressed air to a compressed air pipe of a rack beam, and a supply hose having a cable reel. Known equipment can be used.

The time when the compressed air is ejected from the compressed air nozzle of the ejector can be performed when the rack beam advances or retreats, or when the rack beam retreats. Normally, compressed air is ejected from the compressed air nozzle when the rack beam retreats, a large amount of hot air in the furnace is sucked by the ejector effect of the compressed air, and high-speed blast air is ejected to the carbon deposition part on the ceiling of the carbonization chamber. Then, carbon attached to the ceiling of the carbonization chamber is blown away and removed in a short time.

Most of the blowing air in this case is hot air in the furnace sucked by the ejector effect.
The spraying part is not locally cooled, and damage such as spalling of the carbonized room brick caused by the conventional cold air blowing does not occur. Further, since a large amount of coke dust is present in the hot air in the furnace, the carbon can be effectively blown off by the coke dust in the blowing air.

The distance between the tip of the ejector of the present invention and the ceiling of the carbonization chamber is preferably in the range of 300 to 1000 mm. For removing carbon from the ceiling of the carbonization chamber, the ceiling is installed at the center in the furnace width direction. Further, the material of the ejector portion is required to be heat-resistant steel because it is exposed to the high heat of the coke oven carbonization chamber.

The blowing of the blowing air from the ejector is performed by confirming the position of the carbonization chamber of the ejector installed above the beam head and opening and closing the supply switching valve for the compressed air. In order to more effectively remove carbon, it is also possible to confirm the position where carbon is attached by an image sensor or the like, adjust the ejector to that position, and blow out blowing air to effectively remove carbon.

In the present invention, the position of the ejector installed above the beam head can be detected directly by a laser distance meter or by measuring the moving distance of a rack beam. Alternatively, a method of indirectly calculating such as calculating the moving distance of the ejector by measuring the rotation speed of the motor shaft is also possible. Further, the approximate position of the ejector in the carbonization chamber can be determined based on the time, that is, the elapsed time from the start of extrusion by the rack beam. The elapsed time from the start of extrusion can be detected by a method of directly measuring the time, but can also be read from a chart such as an electric current recorder or a rotary recorder.

In the above description, the removal of carbon adhering to the ceiling of the coking chamber has been described. However, the present invention is not limited to the ceiling of the coking chamber, and the carbon adhering to the brick of the side wall of the coking chamber is not limited thereto. It is also effective for removal. However, in the case of the brick part in the side wall of the carbonization chamber, it is necessary to install at least two or more ejectors.

[0024]

【Example】

Embodiment 1 Hereinafter, details of the present invention will be described with reference to FIGS. FIG. 1 is an overall explanatory view of a coke oven, FIG.
Is a side view showing an example of a method of installing the ejector, and FIG. 3 is a cross-sectional view showing an example of the structure of the ejector.

1 to 3, reference numeral 1 denotes a coke oven, 2
Is an extruder, 3 is a rack beam provided in the extruder 2, 4
Is a beam head at the tip of the rack beam 3, 5 is a coke guide wheel, and 6 is a bucket wheel. Reference numeral 7 denotes an ascending pipe for guiding the coke oven gas generated in the coking chamber 8 of the coke oven 1 to the air collecting main pipe 9, and reference numeral 10 denotes carbon adhered to the ceiling of the coking chamber 8.

Numeral 11 denotes an ejector fixed to a support 12 installed above the beam head 4 at the tip of the rack beam 3. The diffuser 13 has a trumpet shape with a trumpet angle of 3 to 6 °, and a bellmouth-shaped throat. And a compressed air ejection nozzle 14 disposed at the center. Reference numeral 15 denotes a pipe for supplying compressed air to a compressed air jet nozzle 14 of the ejector 11 disposed along the rack beam 3, and a compressed air tank 16 and a pressure reducing valve 17 installed on the extruder 2, a supply stop switching valve 18, It is connected via a hose winding drum 19. Reference numeral 20 denotes a compressor that supplies compressed air to the compressed air tank 16.

Compressor 20 is started to store compressed air pressurized to 7 to 9 kg / cm ² · G in compressed air tank 16 in advance.
Ejector 1 fixed to support 12 installed on top of
When 1 is located at the carbon 10 position, the supply stop switching valve 1
8, compressed air reduced to 4 kg / cm ² · G by the pressure reducing valve 17 is supplied at 2 m ³ / min to the pipe 15 via the hose winding drum 19, and the compressed air is ejected from the compressed air jet nozzle 14 of the ejector 11. If the compressed air is ejected at a speed higher than the speed of sound, the in-furnace hot air Q containing coke dust i is sucked from the lower part at 20 m ³ / min by the ejector effect, and the compressed air and the in-furnace hot air Q are discharged from the outlet of the ejector 11. Is sprayed onto the carbon 10 at a spray speed of 20 m / sec or more.

When the carbon 10 adhered to the ceiling of the carbonization chamber 8 is removed by the above-described configuration, when the ejector 11 fixed on the upper part of the beam head 4 is located at the position of the carbon 10 at the time of coke extrusion, The supply stop switching valve 18 is operated, and the pressure
2 m ³ / min compressed air decompressed to kg / cm ² · G
To supply to the pipe 15 via the hose winding drum 19,
If the compressed air is ejected from the compressed air ejection nozzle 14 of the ejector 11 at a speed higher than the speed of sound, the hot air Q containing the coke dust i from the lower part becomes 20 by the ejector effect.
m ³ / min in the sucked in of compressed air furnace hot air Q from the outlet of the ejector 11 blowing air 20 m / s
The carbon 10 adhering to the ceiling of the carbonization chamber 8 is sprayed at a spray speed of ec or more, and the carbon 10 is blown off and removed in a short time.

In this case, most of the blowing air from the outlet of the ejector 11 is hot air Q in the furnace containing coke dust i, so that the ceiling of the carbonization chamber 8 is locally cooled by the blowing air. Therefore, damage such as spalling of the ceiling brick can be prevented. Further, since the in-furnace hot air Q contains a large amount of coke dust i, the carbon 10 can be efficiently removed by spraying the coke dust i.

Example 2 Furnace height 7125 mm, furnace width 460 mm, furnace length 16500 m
m, a compressed air jet nozzle was installed above the beam head of the extruder, and compressed air of 4 kg / cm ² · G was supplied at a rate of 2 m ³ / min to the ceiling of the carbonization chamber by 500 m.
m, and the wrapper angle of Example 1 was set at 3 to 3 mm above the beam head of the extruder.
An ejector 1 having a 6 ° trumpet-shaped throat bell mouth-shaped diffuser 13 and a compressed air jet nozzle 14
1 is installed at a distance of 500 mm from the ceiling, and 4 kg / cm
² · G compressed air is supplied to the compressed air jet nozzle 14 at 2 m ³ / min, and hot air Q in the furnace including coke dust i is sucked from the lower part at 20 m ³ / min by the ejector effect and ejected from the outlet of the ejector 11. Compressed air and furnace hot air Q
For each of the methods of the present invention in which blowing air consisting of was sprayed onto the carbon 10 adhered at a blowing speed of 20 m / sec or more, the removal efficiency of carbon adhered to the ceiling was investigated. Table 1 shows the results. In this case, the carbon adhesion amount on the ceiling was 7.2 kg / kiln.

[0031]

[Table 1]

As shown in Table 1, an ejector 11 is installed above a beam head of an extruder, and compressed air is supplied to a compressed air jet nozzle 14 to generate hot air Q containing coke dust i from a lower portion by an ejector effect. To 20m ³ / m
In the case of the method of the present invention, in which the carbon was adhered to the ceiling and sucked in and sprayed, the carbon removal amount was 6.7 kg / time, and the carbon removal rate was 93%. On the other hand, in the case of the conventional method in which a compressed air ejection nozzle is installed above the beam head of the extruder and compressed air is directly blown on the carbon adhered to the ceiling, the carbon removal amount is 4.6 kg / time,
The carbon removal rate was 64%.

[0033]

According to the first aspect of the present invention, there is provided a method for removing carbon adhering to a coke oven, wherein the hot air in the oven is sucked upward by the ejector effect of the compressed air from the compressed air jet nozzle of the ejector installed above the beam head. Thus, a large amount of hot air in the furnace can be ejected at a high speed with a small amount of compressed air, and carbon attached to the ceiling of the carbonization chamber can be blown away and removed in a short time.

According to a second aspect of the present invention, there is provided an apparatus for removing adhering carbon in a coke oven, wherein a compressed air pipe communicating with a compressed air supply device is provided on a rack beam of the coke oven extruder, and compressed air at the tip thereof is provided. The lower part of the diffuser is evacuated due to the ejector effect of the compressed air ejected from the compressed air nozzle that is arranged upward, by arranging the nozzle upward at the center of the flared diffuser arranged above the beam head and configuring the ejector. Thus, a large amount of hot air in the furnace is sucked and spouted at high speed to the ceiling of the coking chamber, and the carbon adhering to the ceiling of the coking chamber can be blown away and removed in a short time.

[Brief description of the drawings]

FIG. 1 is an overall explanatory view of a coke oven in which the apparatus of the present invention is installed.

FIG. 2 is a side view showing an example of a method of installing an ejector.

FIG. 3 is a sectional view showing an example of the structure of an ejector.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 coke oven 2 extruder 3 rack beam 4 beam head 5 coke guide car 6 bucket car 7 riser pipe 8 carbonization chamber 9 air collecting main pipe 10 carbon 11 ejector 12 support 13 diffuser 14 compressed air jet nozzle 15 pipe 16 compressed air tank 17 Pressure reducing valve 18 Supply stop switching valve 19 Hose winding drum 20 Compressor

Claims (2)

[Claims] 1. A method for removing compressed carbon adhering to a ceiling portion of a carbonization chamber by arranging a compressed air pipe along a rack beam of a coke oven extruder and blowing compressed air from a nozzle installed above a beam head. The hot air in the furnace is sucked and ejected by the ejector effect of the compressed air ejecting nozzle of the ejector installed in the upper part of the beam head, and the carbon adhering to the ceiling of the carbonization chamber is blown off and removed. A method for removing carbon adhering to a coke oven. 2. A compressed air pipe communicating with a compressed air supply device is arranged along a rack beam of a coke oven extruder, and a tip end of the compressed air pipe is directed upward to a center of a trumpet-shaped diffuser arranged above a beam head. An apparatus for removing carbon adhering to a coke oven, wherein the apparatus is arranged to constitute an ejector.