JPH0728948U - Water injection device in the cooling tower of the dry coke fire extinguishing system - Google Patents

Abstract

(57) [Abstract] [Purpose] Regardless of the height level of the red hot coke in the cooling tower, water is always sprayed evenly on the center of the red hot coke, and the amount of combustible components generated by the water-gas reaction can be increased. In addition, it is not necessary to consider a structure that can prevent damage to the refractory and absorb the relative displacement due to thermal expansion that occurs between the iron shell and the refractory so as not to transmit it to the water injection nozzle. It is possible to avoid complication of the structure of the water injection nozzle insertion portion. [Structure] A water injection nozzle 26 having a water cooling jacket 25 in the outer peripheral portion is arranged at the center of a lid 12 that opens and closes a charging port 8 at the top center of the cooling tower 4, and a water injection line to the water injection nozzle 26 is provided. 28, flexible pipes 29, 30, 33 capable of absorbing the displacement when the lid 12 is opened and closed in the middle of the jacket water supply line 31 to the water cooling jacket 25 and the jacket drain line 32 from the water cooling jacket 25.
34 and 35 are provided.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a water injection device in a cooling tower of a coke dry fire extinguisher.

[0002]

[Prior art]

 Generally, in the coke dry fire extinguishing equipment, as shown in FIG. 4, a pre-chamber 2 for storing high-temperature red hot coke 1 is formed and a cooling chamber 3 for cooling the red hot coke 1 is formed in the lower part. The cooling tower 4 is provided, and the bucket 5 containing the high-temperature red hot coke 1 is lifted by the hoisting machine 7 mounted on the transfer carriage 6 and then transferred to the upper part of the cooling tower 4 and then cooled. The red hot coke 1 in the bucket 5 is charged into the pre-chamber 2 in the upper part of the cooling tower 4 from the inlet 8 provided at the center of the top of the tower 4, and the red hot coke 1 is stored in the pre-chamber 2 and then cooled. In the chamber 3, the red hot coke 1 is cooled by a low temperature circulating gas 9 circulated from a heat recovery boiler (not shown) described later, and the coke 1 cooled by the circulating gas 9 and having a temperature drop. Is cut out from the cutting device 10 at the bottom of the cooling tower 4 onto the carry-out conveyor 11 and carried out to the outside by the carry-out conveyor 11, while the red hot coke 1 is cooled and the high temperature circulating gas 9 ′ is heated. It is introduced into a heat recovery boiler (not shown) to generate high temperature and high pressure steam for heat recovery.

On the upper side of the cooling tower 4, as shown in FIGS. 5 and 6, a lid truck having a lid 12 capable of opening and closing the loading port 8 suspended from a support arm 13 is mounted. 14, a hopper 15 connected to the lid carriage 14 and for guiding the red hot coke 1 from the bucket 5 to the charging port 8 of the cooling tower 4 is mounted so as to be elastically supported by a spring (not shown). The hopper cart 16 is arranged so that it can traverse through the links 18 and 19 and the drive arm 20 when the cylinder 17 expands and contracts. When the red hot coke 1 is thrown in, the cylinder 17 contracts from the state shown in FIG. After the drive arm 20 and the support arm 13 rotate counterclockwise by a required amount via the links 18 and 19, the lid 12 is lifted to a required height position, and then the lid carriage 14 is mounted. Entering By retracting from the mouth 8 to the left side in FIG. 6, as shown in FIG. 5, the loading port 8 is opened, and the hopper cart 16 is moved to a position directly above the loading port 8 in conjunction with the lid cart 14. In this state, the bucket 5 is placed on the hopper 15, and the weight of the bucket 5 causes the hopper 15 to move downward against the urging force of the spring. The lower end of the hopper 15 is connected to the loading port 8. In this state, the red hot coke 1 is charged from the bucket 5 into the cooling tower 4 via the hopper 15. On the other hand, after the red hot coke 1 is charged, when the bucket 5 is lifted from the state shown in FIG. Is raised by the urging force of the spring, and then the cylinder 17 is extended, the hopper truck 16 is retracted from the loading port 8 to the right side in FIG. 5, and the lid truck 14 moves the lid 12 away. In Fig. 5 while holding it at the required height position The lid carriage 14 stops at the position where the lid body 12 reaches right above the loading opening 8 after the lid body 12 has stopped. After the lid carriage truck 14 is stopped, the cylinder 17 is further extended and the link 18, By rotating the drive arm 20 and the support arm 13 by the required amount in the time direction via 19, the lid 12 is lowered and the charging port 8 is closed, as shown in FIG. There is.

Further, as shown in FIGS. 5 and 6, a water injection nozzle 21 is arranged in the inclined portion of the upper part of the cooling tower 4, and the water is injected from the bucket 5 in the upper part of the cooling tower 4. By blowing water 22 from the water injection nozzle 21 onto the red hot coke 1, a water gas reaction (C + H ₂ O → H ₂ + CO) is caused to generate combustible components H ₂ and CO, and the combustible components H ₂ and H ₂ , CO is burned by blowing air in a flue (not shown) that connects the cooling tower 4 and the heat recovery boiler to increase the amount of high-temperature high-pressure steam generated in the heat recovery boiler.

[0005]

[Problems to be solved by the device]

However, as described above, by arranging the water injection nozzle 21 in the inclined portion of the upper part of the cooling tower 4, when the water 22 starts to be blown from the water injection nozzle 21 or when the water is blown from the water injection nozzle 21, the water injection nozzle 21 is surrounded. Water 22 is splashed on the refractory material 23, and the refractory material 23 is rapidly cooled from a high temperature state, which may cause damage. Further, the height level of the red hot coke 1 charged into the cooling tower 4 is high. When it changes, it becomes difficult to spray the water 22 evenly on the central part of the red hot coke 1 and the combustible components H ₂ and CO due to the water gas reaction are not uniformly generated, while the red hot coke 1 When the height level of No. 1 is low, the refractory 23 on the side facing the water injection nozzle 21 may be splashed with water 22 and may be damaged in the same manner as described above. 24 and fireproof 23, a relative displacement occurs due to thermal expansion. However, because the water injection nozzle 21 is arranged so as to penetrate the iron shell 24 and the refractory material 23, the water injection nozzle 21 is inserted into the insertion portion of the water injection nozzle 21. A structure that absorbs the relative displacement generated between the iron shell 24 and the refractory 23 must be provided, which has a drawback that the structure of the insertion portion of the water injection nozzle 21 in the cooling tower 4 becomes complicated. .

In view of such a situation, the present invention can always spray water evenly on the central portion of the red hot coke regardless of the height level of the red hot coke thrown into the cooling tower. The amount of flammable components H ₂ and CO generated by the water injection nozzle can be increased, damage to the refractory can be prevented, and the relative displacement caused by thermal expansion between the iron shell and the refractory can be prevented. It is an object of the present invention to provide a water injection device in the cooling tower of the coke dry fire extinguishing equipment that can avoid the complication of the structure of the insertion part of the water injection nozzle in the cooling tower without having to consider the absorption structure so as not to transmit it to the cooling tower. is there.

[0007]

[Means for Solving the Problems]

 The present invention is to open a charging port for charging red-hot coke into the center of the top of a cooling tower of a coke dry-type fire extinguisher that cools the red-heat coke and recover the heat. , A water-blowing nozzle having a water-cooling jacket on its outer periphery is penetrated through the center of the lid to prevent displacement of the lid when the lid is opened or closed during a water-blowing line for supplying water to the water-blowing nozzle. Along with a flexible pipe that can absorb the water, a flexible pipe that can absorb the displacement when the lid is opened and closed is provided in the middle of the jacket water supply line that supplies water to the water cooling jacket and the jacket drain line that discharges water from the water cooling jacket. It is characterized in that piping is provided.

[0008]

[Operation] Therefore, when water is supplied to the water injection line and the jacket water supply line with the cover closed at the inlet, water is sprayed from the water injection nozzle to the red hot coke in the cooling tower and the water cooling jacket is also supplied. Water is supplied to the pipe to cool the water injection nozzle and then drained from the jacket drain line.

As described above, when water is sprayed from the water injection nozzle to the red hot coke thrown into the cooling tower, the water injection nozzle is the center of the lid whose opening is open at the top center of the cooling tower. Since it is penetrated through the part, the refractory around the water injection nozzle will not be splashed with water at the beginning and end of the water injection from the water injection nozzle. There is no risk of damage due to water vapor, and even if the height level of the red-hot coke thrown into the cooling tower changes, water is constantly sprayed evenly on the center of the red-hot coke, which causes a water-gas reaction. While the combustible components H ₂ and CO are effectively generated, even when the height level of the red hot coke is low, there is no fear of water splashing on the refractory material on the side facing the water blowing nozzle, and further, Phase due to thermal expansion Since the water injection nozzle is not arranged so as to penetrate through the iron shell and the refractory material where pair displacement occurs, the relative displacement generated between the iron skin and the refractory material is absorbed in the insertion part of the water injection nozzle. There is no need to provide any structure, and it is possible to avoid complicating the structure of the insertion part of the water injection nozzle in the cooling tower.

Further, when the red hot coke is charged, the water supply to the water cooling nozzle, that is, the cooling of the water injection nozzle is continued, while the water supply to the water injection nozzle is stopped and the lid is opened. The displacement due to opening and closing of the lid at this time is absorbed by the flexible piping, and the red hot coke is fed into the cooling tower through the opened charging port.

[0011]

【Example】

 An embodiment of the present invention will be described below with reference to the drawings.

1 to 3 show an embodiment of the present invention. In the drawings, the parts designated by the same reference numerals as those in FIGS. 4 to 6 represent the same parts, and are located at the center of the top of the cooling tower 4. A water-blowing nozzle 26 having a water-cooling jacket 25 on the outer peripheral portion is arranged through the guide pipe 27 at the center of the lid 12 which can open and close the opening 8 for opening the water, and the water-blowing nozzle 26 is supplied with water. In the middle of the water injection line 28 for supplying 22, flexible pipes 29, 30 capable of absorbing the displacement when the lid 12 is opened and closed are provided, and a jacket water supply line 31 for supplying water 22 ′ to the water cooling jacket 25 and a water cooling system. Flexible pipes 33, 34 and 35 capable of absorbing the displacement when the lid 12 is opened and closed are provided in the middle of the jacket drain line 32 for discharging the water 22 ′ from the jacket 25.

As shown in FIG. 3, the water injection line 28 is connected to an industrial water line 36 and has a fixed pipe 38 extending from a valve unit 37 in which various kinds of valves (not shown) are incorporated, and a lid body. A fixed pipe 39 attached to the carriage 14 and a fixed pipe 40 connected to the water injection nozzle 26 are provided, and the transverse movement of the lid carriage 14 when the lid 12 is opened and closed is performed between the fixed pipes 38 and 39. A flexible pipe 29 for absorbing is provided, and a flexible pipe 30 is provided between the fixed pipes 39 and 40 for absorbing the lifting operation of the lid 12 when the lid 12 is opened and closed.

As shown in FIG. 3, the jacket water supply line 31 includes a fixed pipe 41 extending from the valve unit 37, a fixed pipe 42 attached to the lid carriage 14, and a fixed pipe connected to the water cooling jacket 25. A pipe 43 is provided, and a flexible pipe 33 for absorbing the traverse movement of the lid carriage 14 when the lid 12 is opened and closed is provided between the fixed pipes 41 and 42, and between the fixed pipes 42 and 43. A flexible pipe 34 is provided to absorb the lifting and lowering operation of the lid 12 when the lid 12 is opened and closed.

Further, as shown in FIG. 3, the jacket drainage line 32 includes a fixed pipe 44 connected to the water cooling jacket 25 and a fixed pipe 45 attached to the hopper truck 16, and the fixed pipe 44 , 45 is provided with a flexible pipe 35 for absorbing the vertical movement of the lid 12 when the lid 12 is opened and closed, and the end of the fixed pipe 45 is provided at the tip of the lid carriage 14 and the hopper carriage 16. It is designed to be opened on a coke powder recovery trough 46 extending in a gutter shape in the transverse direction.

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

When the lid 12 closes the charging port 8, water is supplied from the industrial water line 36 to the water injection line 28 and the jacket water supply line 31 by operating the valve unit 37, the water injection nozzle 26 The water 22 is sprayed onto the red hot coke 1 in the cooling tower 4, and the water 22 ′ is supplied to the water cooling jacket 25 to cool the water injection nozzle 26, and the water 22 ′ which has cooled the water injection nozzle 26. Is drained from the jacket drain line 32 to the coke powder recovery trough 46.

In this way, when the water 22 is sprayed from the water injection nozzle 26 to the red hot coke 1 charged in the cooling tower 4, the water injection nozzle 26 opens and closes the inlet 8 opening at the center of the top of the cooling tower 4. Since it is penetrated in the center of the flexible lid 12, the water 22 is splashed on the refractory material 23 around the water blowing nozzle 26 at the beginning and end of the blowing of the water 22 from the water blowing nozzle 26. There is no risk that the refractory 23 will be rapidly cooled from a high temperature and damaged, and even if the height level of the red hot coke 1 charged into the cooling tower 4 changes. The water 22 is constantly sprayed evenly on the center of the water to effectively generate combustible components H ₂ and CO by the water-gas reaction, while the water injection nozzle 26 is used even when the height level of the red hot coke 1 is low. When There is no concern that the water 22 will be splashed on the refractory 23 on the opposite side, and furthermore, the water injection nozzle 26 is not arranged so as to penetrate the iron shell 24 and the refractory 23 in which relative displacement due to thermal expansion occurs. It is not necessary to provide a structure for absorbing the relative displacement generated between the iron shell 24 and the refractory 23 in the insertion portion of the water injection nozzle 26, and the structure of the insertion portion of the water injection nozzle 26 in the cooling tower 4 is It also avoids complications.

When the red hot coke 1 is charged, the supply of the water 22 ′ to the water cooling jacket 25, that is, the cooling of the water injection nozzle 26 is continued while the supply of the water 22 to the water injection nozzle 26 is stopped. From the state shown in FIG. 1, the cylinder 17 contracts, and the drive arm 20 and the support arm 13 rotate counterclockwise through the links 18 and 19 by a required amount, so that the lid body 12 reaches a required height. The displacement due to the upward movement of the lid 12 at this time is absorbed by the flexible pipes 30, 34, 35, and then the lid carriage 14 is retracted from the loading port 8 to the left side in FIG. Then, the loading port 8 is opened, and the displacement caused by the traverse movement of the lid carriage 14 at this time is absorbed by the flexible pipes 29 and 33, and the hopper truck 16 is loaded in a manner interlocking with the lid carriage 14. mouth 8, the hopper 15 descends by a required amount, and the red hot coke 1 is fed into the cooling tower 4 via the hopper 15 in a state where the lower end of the hopper 15 is connected to the charging port 8. Although the tip of the fixed pipe 45 of the jacket drainage line 32 moves along with the traverse movement of the hopper truck 16, the tip of the fixed pipe 45 is guttered in the traverse direction of the lid truck 14 and the hopper truck 16. The water 22 'after being supplied from the jacket water supply line 31 to the water cooling jacket 25 to cool the water injection nozzle 26 is constantly released onto the coke powder recovery trough 46 extending to the coke powder from the jacket drain line 32. It is drained to the powder recovery trough 46.

In this way, regardless of the height level of the red hot coke 1 charged into the cooling tower 4, the water 22 can always be sprayed evenly on the central portion of the red hot coke 1 and the combustible component H due to the aqueous gas reaction can be obtained. ₂ , the amount of CO generated can be increased, damage to the refractory 23 can be prevented, and the relative displacement due to the thermal expansion generated between the iron shell 24 and the refractory 23 can be prevented from occurring. It is not necessary to consider the structure that absorbs so as not to transmit it to the blowing nozzle 26, and it is possible to avoid complication of the structure of the insertion portion of the water blowing nozzle 26 in the cooling tower 4.

The apparatus for injecting water into the cooling tower of the coke dry fire extinguishing equipment of the present invention is not limited to the above-mentioned embodiment, and various modifications may be made without departing from the gist of the present invention. Of course.

[0022]

[Effect of device]

As described above, according to the water injection device in the cooling tower of the coke dry fire extinguishing equipment of the present invention, water is always supplied to the center of the red heat coke regardless of the height level of the red heat coke injected into the cooling tower. Can be sprayed evenly, the amount of flammable components H ₂ and CO generated by the water-gas reaction can be increased, damage to the refractory can be prevented, and moreover, between the steel skin and the refractory. It is not necessary to consider the structure that absorbs the relative displacement due to the generated thermal expansion so as not to be transmitted to the water injection nozzle, and it is possible to achieve the excellent effect that it is possible to avoid complication of the structure of the insertion part of the water injection nozzle in the cooling tower. .

[Brief description of drawings]

FIG. 1 is a side sectional view of an embodiment of the present invention.

FIG. 2 is a plan view showing a water piping system according to an embodiment of the present invention.

FIG. 3 is a schematic diagram showing a water piping system in an embodiment of the present invention.

FIG. 4 is a schematic diagram showing a general coke dry fire extinguishing facility.

FIG. 5 is a side cross-sectional view showing a state in which red hot coke is introduced in a water injection device in a cooling tower of a conventional coke dry fire extinguishing facility.

FIG. 6 is a side sectional view showing a non-charging state of red hot coke in a water injection device in a cooling tower of a conventional coke dry fire extinguisher facility.

[Explanation of symbols]

 1 red-hot coke 4 cooling tower 8 inlet 12 lid 22 water 22 'water 25 water-cooling jacket 26 water-blowing nozzle 28 water-blowing line 29 flexible piping 30 flexible piping 31 jacket water supply line 32 jacket drainage line 33 flexible piping 34 flexible piping 35 flexible Piping

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shuji Saeki 4-53-3 Kitahama, Chuo-ku, Osaka City, Osaka Prefecture Sumitomo Metal Industries, Ltd. (72) Inventor Isamu Minamizawa 1850 Minato, Wakayama, Wakayama Sumitomo Metal Wakayama Steel Works Co., Ltd.

Claims (1)

[Scope of utility model registration request] 1. A charging port for charging red-hot coke is opened at the center of the top of a cooling tower of a coke dry-type fire extinguisher for cooling red-heat coke to recover heat, and a lid can be opened and closed at the charging port. Installed, a water injection nozzle having a water cooling jacket on the outer peripheral portion is arranged to penetrate through the center of the lid, and absorbs displacement when the lid is opened and closed in the middle of a water injection line that supplies water to the water injection nozzle. A flexible pipe that can absorb the displacement when the lid is opened and closed is provided in the middle of the jacket water supply line that supplies water to the water cooling jacket and the jacket drain line that discharges water from the water cooling jacket. The water injection device in the cooling tower of the coke dry fire extinguishing facility.