CN211595518U - Dry quenching furnace structure - Google Patents

Abstract

The utility model relates to a dry quenching furnace structure, wherein at least one partition wall is arranged at the upper part of a cone hopper and in a cooling section of the dry quenching furnace, and the partial space is divided into at least 2 cooling chambers along the circumferential direction of the dry quenching furnace; the lower part of each cooling chamber is provided with an air supply device at the position corresponding to the conical hopper; an umbrella-shaped gas collecting hood is arranged at the center of the top of the separating wall, a cooling gas outlet is arranged at the center of the separating wall below the umbrella-shaped gas collecting hood, an airflow guiding channel is arranged in the separating wall along the radial direction of the dry quenching furnace, the inner end of the airflow guiding channel is communicated with the cooling gas outlet, and the outer end of the airflow guiding channel is connected with a cooling gas circulating system of the dry quenching furnace. The utility model cancels the inclined channel area and the annular air channel of the traditional dry quenching furnace; the cooling gas after heat exchange with the red coke is led out through an airflow leading-out channel in the partition wall; the dry quenching furnace has high structural strength, long service life, capability of regulating temperature in a subarea manner and good cooling uniformity of coke.

Description

Dry quenching furnace structure

Technical Field

The utility model relates to a dry coke quenching technical field especially relates to a dry coke quenching furnace structure.

Background

In the traditional dry quenching furnace body structure, an annular air duct is arranged between the furnace bodies of the pre-storage section and the cooling section, and the annular air duct is connected with the furnace bodies through a chute area; however, in the production process, the inner ring wall forming the annular air duct is easy to damage; the reasons for this are mainly the following: 1) the bracket in the inclined flue area of the dry quenching furnace is of a layer-by-layer overhanging structure, and the stress structure is thinner and has poorer strength; 2) the inner ring wall of the annular air duct is often impacted when the materials in the furnace fall; 3) the temperature distribution of the chute area is uneven, and the bracket of the chute is easy to damage after being heated and stressed.

At present, the method for enhancing the structural strength of the annular air duct is to add a complex groove tongue structure on the wall brick of the inner annular wall to fix the brick wall at each position. The chute corbel is mainly built by refractory materials with higher compressive strength and better thermal shock stability. Under the general condition of the chute corbels, the bracket needs to be repaired every two years or so and needs to be overhauled and replaced every five years.

In addition, as the size of the coke oven increases, the size of the dry quenching furnace also gradually increases, and the problem of the distribution uniformity of the cooling gas at the lower part of the cooling section of the dry quenching furnace is difficult to solve.

Disclosure of Invention

The utility model provides a dry quenching furnace structure, which cancels a ramp area and an annular air duct of the traditional dry quenching furnace; the cooling section is divided into a plurality of cooling chambers, each cooling chamber is correspondingly provided with an air supply device, and cooling air after heat exchange with the red coke is led out through an air flow leading-out channel in the partition wall; the dry quenching furnace has high structural strength, long service life, capability of regulating temperature in a subarea manner and good cooling uniformity of coke.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a dry quenching furnace structure comprises a dry quenching furnace; the dry quenching furnace consists of a furnace top, a prestoring section, a cooling section and a conical hopper which are sequentially connected from top to bottom, wherein the prestoring section is directly connected with the inner wall of the furnace body of the cooling section; at least one partition wall is arranged in the upper part of the conical hopper and the cooling section, and the partial space is divided into at least 2 cooling chambers along the circumferential direction of the dry quenching furnace; the lower part of each cooling chamber is provided with an air supply device at the position corresponding to the conical hopper; an umbrella-shaped gas collecting hood is arranged at the center of the top of the separating wall, a cooling gas outlet is arranged at the center of the separating wall below the umbrella-shaped gas collecting hood, an airflow guiding channel is arranged in the separating wall along the radial direction of the dry quenching furnace, the inner end of the airflow guiding channel is communicated with the cooling gas outlet, and the outer end of the airflow guiding channel is connected with a cooling gas circulating system of the dry quenching furnace.

The support wall is built by masonry of refractory materials or poured by refractory materials.

The umbrella-shaped gas-collecting hood is made of refractory materials or metal materials, or is of a composite structure consisting of the refractory materials and the metal materials.

The number of the partition walls is 1-3.

The cross sections of the cooling gas outlet and the airflow guide channel are rectangular.

Compared with the prior art, the beneficial effects of the utility model are that:

1) compared with the conventional dry quenching furnace, the dry quenching furnace has the advantages that a chute area and an annular air duct are omitted, so that the structure of the dry quenching furnace is more stable, and the strength of the furnace body is higher;

2) the cooling section is divided into a plurality of cooling chambers, each cooling chamber is correspondingly provided with an air supply device, the temperature can be adjusted in a subarea manner, and the cooling uniformity of coke is good;

3) the partition wall in the dry quenching furnace consists of vertical wall bodies, and the service life of the wall bodies is long;

4) because the inclined flue area and the annular air duct are omitted, the construction difficulty is greatly reduced, the construction efficiency is improved, and the investment and maintenance cost of the dry quenching furnace are reduced.

Drawings

Fig. 1 is a front sectional view of a dry quenching furnace structure of the present invention.

Fig. 2 is a view a-a in fig. 1.

Fig. 3 is a view B-B in fig. 1.

Fig. 4 is a view C-C in fig. 1.

In the figure: 1. dry quenching furnace 2, separating wall 3, gas supply device 4, umbrella-shaped gas collecting hood 5, cooling gas discharge port 6, gas flow guiding-out channel 7, annular gas collecting pipe

Detailed Description

The following description of the embodiments of the present invention will be made with reference to the accompanying drawings:

as shown in fig. 1-4, the dry quenching furnace structure of the present invention comprises a dry quenching furnace 1; the dry quenching furnace 1 consists of a furnace top, a prestoring section, a cooling section and a cone hopper which are sequentially connected from top to bottom, wherein the prestoring section is directly connected with a furnace body of the cooling section; at least one partition wall 2 is arranged in the upper part of the conical hopper and the cooling section, and the partial space is divided into at least 2 cooling chambers along the circumferential direction of the dry quenching furnace 1; the lower part of each cooling chamber is provided with an air supply device 3 at the position corresponding to the conical hopper; an umbrella-shaped gas collecting hood 4 is arranged at the top center of the partition wall 2, a cooling gas outlet 5 is arranged at the center of the partition wall 2 below the umbrella-shaped gas collecting hood 4, an airflow guiding channel 6 is arranged in the partition wall 2 along the radial direction of the dry quenching furnace 1, the inner end of the airflow guiding channel 6 is communicated with the cooling gas outlet 5, and the outer end of the airflow guiding channel 6 is connected with a cooling gas circulating system of the dry quenching furnace.

The partition wall 2 is built by masonry of refractory materials or is formed by pouring of refractory materials.

The umbrella-shaped gas-collecting hood 4 is made of refractory materials or metal materials, or is of a composite structure consisting of the refractory materials and the metal materials.

The number of the partition walls 2 is 1-3.

The cross sections of the cooling gas outlet 5 and the gas flow guiding-out channel 6 are rectangular.

The coke cooling method in the dry quenching furnace structure comprises the following steps:

in the process of dry quenching, red coke is loaded from the top of a dry quenching furnace 1, and low-temperature inert gas is respectively blown into the dry quenching furnace 1 through each gas supply device 3 under the action of a circulating fan; the low-temperature inert gas blown from each gas supply device 3 respectively enters the corresponding cooling chambers above to contact with the red coke, and the sensible heat of the red coke is absorbed; uniformly discharging the cooled coke through a coke discharging device at the bottom of the cone hopper; the high-temperature inert gas absorbing the sensible heat of the red coke rises to the top of each cooling chamber and is uniformly collected by the umbrella-shaped gas collecting hood 4, and then turns back downwards to enter a cooling gas outlet 5; the inert gas is discharged from the dry quenching furnace 1 through an air flow guide channel 6 in the partition wall 2, enters a dry quenching boiler for heat exchange after primary dust removal, and is blown into the dry quenching furnace 1 again for recycling through a circulating fan after secondary dust removal;

the accurate adjustment of the cooling temperature of the coke at each part of the dry quenching furnace 1 can be realized by adjusting the feeding amount of the low-temperature inert gas of each gas supply device 3, and finally the coke in the dry quenching furnace 1 is uniformly cooled.

A novel dry quenching furnace structure cancels a chute area and an annular air duct in the conventional dry quenching furnace structure. And a gas exhaust device is additionally arranged in the dry quenching furnace. The gas discharge device comprises a partition wall 2 and an umbrella-shaped gas collecting hood 4; a cooling gas outlet 5 is arranged at the center of the partition wall 2 below the umbrella-shaped gas-collecting hood 4, and the cooling gas outlet 5 is positioned in a space formed by natural accumulation below the umbrella-shaped gas-collecting hood 4 in the downward cooling process of coke.

In order to realize the temperature-regulating cooling in a subarea manner, and in order to fix the umbrella-shaped gas collecting hood 4 and arrange the airflow guiding-out channel 6, a partition wall 2 is arranged below the umbrella-shaped gas collecting hood 4. The outer end of the partition wall 2 is fixedly connected with the inner wall of the furnace body of the cooling section of the dry quenching furnace 1, and the bottom of the partition wall is supported on the furnace body at the conical hopper part of the dry quenching furnace 1. The number of the division walls 2 is at least one, the cooling section is divided into at least 2 cooling chambers, an air supply device 3 is arranged below each cooling chamber at the position corresponding to the cone hopper, and each air supply device 3 can be independently adjusted, so that the flowability of cooling gas and the cooling uniformity of coke can be better improved.

The cooling gas (high-temperature inert gas) discharged from each gas flow guide channel 6 can be respectively connected with a cooling gas circulating pipeline through a pipeline, and can also be collected by an annular gas collecting pipe 7 and then sent into the cooling gas circulating pipeline.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (5)

1. A dry quenching furnace structure comprises a dry quenching furnace; the dry quenching furnace is characterized by comprising a furnace top, a prestoring section, a cooling section and a cone hopper which are sequentially connected from top to bottom, wherein the prestoring section is directly connected with the inner wall of a furnace body of the cooling section; at least one partition wall is arranged in the upper part of the conical hopper and the cooling section, and the partial space is divided into at least 2 cooling chambers along the circumferential direction of the dry quenching furnace; the lower part of each cooling chamber is provided with an air supply device at the position corresponding to the conical hopper; an umbrella-shaped gas collecting hood is arranged at the center of the top of the separating wall, a cooling gas outlet is arranged at the center of the separating wall below the umbrella-shaped gas collecting hood, an airflow guiding channel is arranged in the separating wall along the radial direction of the dry quenching furnace, the inner end of the airflow guiding channel is communicated with the cooling gas outlet, and the outer end of the airflow guiding channel is connected with a cooling gas circulating system of the dry quenching furnace.

2. A dry quenching furnace structure as claimed in claim 1, wherein said dividing wall is built from masonry of refractory material or is cast from refractory material.

3. The dry quenching furnace structure as claimed in claim 1, wherein the umbrella-shaped gas-collecting hood is made of refractory material or metal material, or is a composite structure composed of refractory material and metal material.

4. The dry quenching furnace structure as claimed in claim 1, wherein the dividing wall is 1-3.

5. The dry quenching furnace structure as claimed in claim 1, wherein the cross section of the cooling gas discharge port and the gas flow guiding channel is polygonal or circular.

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