RU120647U1 - INSTALL DRY EXTINGUISHING OF COX - Google Patents

Abstract

1. Installation of dry coke quenching, containing at least one coke quenching chamber, a cooling agent circulation system adjacent to the above coke quenching chamber, means for removing an excess volume of cooling agent, means for batch unloading of coke from the coke quenching chamber containing at least at least three gates, which form at least two series-connected bypass chambers, characterized in that to the upper part of the bypass chamber, into which coke enters from the coke quenching chamber, there is a means for removing excess volume of the cooling agent. ! 2. Installation according to claim 1, characterized in that the means for removing the excess volume of the cooling agent is connected to the chimney. ! 3. Installation according to any one of claims 1 or 2, characterized in that the means for removing the excess volume of the cooling agent comprises an additional waste heat boiler. ! 4. The installation according to claim 3, characterized in that it further comprises a bypass circuit that connects the means for removing the excess volume of the cooling agent with the chimney. ! 5. Installation according to any one of claims 1 or 2, characterized in that the means for removing the excess volume of the cooling agent further comprises at least one filter for cleaning the cooling agent.

Description

The utility model relates to the coke industry and can be used in dry quenching systems of coke (hereinafter referred to as CCP).

State of the art

Dry coke quenching methods and their implementing devices are based on cooling coke in a coke quenching chamber with a cooling agent that circulates in the cooling agent circulation system. The coke quenching chamber is a vertically located shaft lined with refractory masonry, into which coke is supplied by means of metered loading. Coke quenching in the quenching chamber is carried out by passing through a layer of coke a cooling agent, which is inert with respect to coke. During the passage of the cooling agent through the coke layer, heat exchange occurs, as a result of which the coke gives off its heat to the cooling agent, which is then removed from the coke quenching chamber to the cooling agent circulation system. The cooling agent circulation system usually contains a coarse filter, usually made in the form of a dust collecting bin, a recovery boiler, which is a relatively tight chamber in which heat-exchanging surfaces are placed to which the cooling agent gives off heat, and means for removing excess coolant from circulation systems. After the recovery boiler, a cooling agent purification device is installed, for example, a fine filter for the cooling agent made in the form of a cyclone, followed by a blower device, for example, a smoke exhauster. During operation of the CCP, part of the cooling agent circulation system is constantly under significant vacuum, which leads to suction of air into the cooling agent circulation system. A candle is included in the circulation system of the cooling agent as a means of draining the excess volume of the cooling agent, designed to discharge into the atmosphere an excess volume of the cooling agent generated in the circulation system of the cooling agent as a result of air suction.

Adjacent to the lower part of the coke quenching chamber is a batch coke unloading device comprising at least three shutters that form at least two series-connected bypass chambers. In this case, the shutter, due to which the coke from the quenching chamber enters the bypass chamber, is called a cutter. The main purpose of this shutter is the portioned discharge of coke from the quenching chamber. The requirements for shutter shutoff tightness are not high. The task of the following valves is to seal the portioned discharge means from the emissions of the cooling agent into the environment. Therefore, the tightness conditions of these valves are very high.

As a result, the CCPF operates in a certain aerodynamic mode, namely, in the upper part of the coke quenching chamber, a pressure value is maintained close to atmospheric (the so-called aerodynamic zero), which prevents the release of the cooling agent during the supply (loading) of coke to the coke quenching chamber, and also prevents air from entering the cooling agent, the presence of which in the cooling agent leads to the burning of coke. The aerodynamic zero in the upper part of the coke quenching chamber is maintained by draining the excess volume of the cooling agent into the atmosphere through a candle (means for removing the excess volume of the cooling agent) of the cooling agent circulation system. The candle of the cooling agent circulation system is installed after the draft device. During the operation of the CCP in the lower part of the coke quenching chamber, the pressure value exceeds atmospheric by 200-300 kgf / m ² , since the shutter (cut-off) is not tight, the cooling agent freely enters the bypass chamber into which the coke enters from the coke quenching chamber. The subsequent unloading of coke from the specified bypass chamber to the next bypass chamber causes a sharp pressure drop.

A known installation of dry quenching of coke (international application No. PCT / UA2008 / 000072), including:

- at least one coke quenching chamber,

a cooling agent circulation system adjacent to the aforementioned coke quenching chamber,

- means for removing the excess volume of the cooling agent,

- means for portioned discharge of coke from the coke quenching chamber, comprising at least three shutters, which form at least two series-connected bypass chambers.

A disadvantage of the known CCCP and the method implemented therein is that when the coke is unloaded from the dry coke quenching chamber in the coke batch unloading unit, significant pressure drops are formed, which in turn leads to: inefficient operation of the batch coke unloading facility, to increase the requirements for shutter tightness means of portioned discharge of coke, and also leads to emissions of the cooling agent in the vehicle operating area.

Also a disadvantage of the known CCP is the inefficient cooling and dedusting of coke.

The essence of the utility model

The main objective of the utility model is the development of a dry coke quenching unit, which will reduce the amount of coolant emissions during coke unloading from the portioned coke unloading facility into the vehicle operating area.

Another objective of the utility model is to reduce the pressure drops of the cooling agent in the batch coke unloading device when coke is unloaded to the vehicle.

Another objective of the utility model is to expand the arsenal of technical equipment for dry quenching of coke.

Other objectives and advantages of the claimed utility model will be disclosed below as the presentation of the present description and drawings.

The task is achieved by removing the excess volume of the cooling agent from the upper part of the bypass chamber, into which the coke enters from the coke quenching chamber, while the upper part of the bypass chamber into which the coke enters from the quenching quenching chamber is adjacent to the means for removing the excess volume of the cooling agent.

When implementing the installation of dry quenching of coke, the tasks are solved in that in the known installation of dry quenching of coke, including:

- at least one coke quenching chamber,

- a circulation system of a cooling agent adjacent to the above coke quenching chamber,

- means for removing the excess volume of the cooling agent,

- means for portioned discharge of coke from the coke quenching chamber, containing at least three shutters, forming at least two series-connected bypass chambers,

according to the claimed utility model

- to the upper part of the bypass chamber, into which the coke enters from the coke quenching chamber, there is adjacent a means for removing the excess volume of the cooling agent.

In a particular embodiment of a dry quenching extinguishing installation, a means for removing an excess volume of a cooling agent is connected to a chimney.

In a particular embodiment of the dry coke quenching apparatus, the means for removing the excess volume of the cooling agent comprises an additional recovery boiler.

In a particular embodiment, the dry coke quenching unit further comprises a bypass circuit that connects the means for removing the excess volume of the cooling agent with the chimney.

In a particular embodiment of the dry coke quenching apparatus, the means for removing the excess volume of the cooling agent further comprises at least one filter for cleaning the cooling agent.

The adjacency to the upper part of the bypass chamber, into which the coke enters from the coke quenching chamber, of the means for removing the excess volume of the cooling agent, reduces the pressure fluctuations in the bypass chamber into which the coke enters from the quench quench chamber, which leads to an increase in the tightness of the shutters of the batch unloading means coke. The removal of the excess volume of the cooling agent through the bypass chamber, into which the coke enters from the coke quenching chamber, leads to an increase in the dedusting of coke and a decrease in its temperature during unloading onto the vehicle.

The use of an additional recovery boiler connected to means for removing the excess volume of the cooling agent leads to an increase in the efficiency of heat recovery of the cooling agent and to a reduction in environmental pollution.

The use of a bypass circuit leads to an increase in the reliability of the USTC during an emergency or planned shutdown of an additional waste heat boiler.

Blueprints

When considering options for implementing this utility model, narrow terminology is used. However, the present utility model is not limited to accepted terms and it should be borne in mind that each such term covers all equivalent elements that work in a similar way and are used to solve the same problems.

Figure 1 shows the installation of dry quenching of coke, claimed as a utility model.

Figure 2 shows an embodiment of a dry coke quenching installation, claimed as a utility model, in which the means for removing the excess volume of the cooling agent contains an additional waste heat boiler.

Utility Model Implementation

The dry coke quenching installation (Fig. 1) includes a coke quenching chamber 1, a cooling agent circulation system 2, which includes a waste heat boiler 3, a cooling agent cleaning device 4, a blower device 5. Coke portioned discharge means 6 adjacent to the lower part of the quenching chamber 1 coke, while the batch unloading device 6 of coke contains three sequentially located shutters 7 ₁ , 7 ₂ and 7 ₃ , which form two sequentially connected bypass chambers 8 ₁ and 8 ₂ , while coke from the quenching chamber 1 of coke enters the bypass chamber 8 ₁ , and from the bypass chamber 8 _{1 the} coke enters the bypass chamber 8 ₂ . From the bypass chamber 8 _{2 the} coke is discharged onto the vehicle 9.

The means for batch unloading 6 of coke adjoins the means 10 of the excess volume of the cooling agent into the chimney 11.

In this case, the means for removing 10 excess volume of the cooling agent contains a regulator 12.

1 also shows a control unit 13, which is connected at the input to a pressure sensor 14 located at the top of the coke quenching chamber 1, and at the output, a control unit 13 is connected to a regulator 12. The control unit 13 maintains the value of aerodynamic zero at the top of the camera quenching 1 coke, and also regulates the volume of removal of the cooling agent through the removal means 10 of the excess volume of the cooling agent.

So according to the method of dry quenching of coke USTK carry out

- dosed loading of coke into the coke quenching chamber 1, cooling of coke in said quenching quenching chamber 1 by a cooling agent that circulates in the circulation system 2 of the cooling agent,

- the supply of coke from the quenching chamber of 1 coke in the means of batch unloading of 6 coke,

- removal of the excess volume of the cooling agent from the means of portioned discharge 6 of coke, while the removal of the excess volume of the cooling agent is carried out from the upper part of the bypass chamber 8 ₁ , into which the coke comes from the quenching chamber 1 of the coke,

- unloading coke from the means of portion unloading 6 coke on the vehicle 9.

The dry coke quenching unit operates as follows, namely, the coke obtained in coke ovens (not shown in the drawings) is loaded into the quenching chamber 1 of coke, in which coke is cooled by a cooling agent that circulates in the circulation system 2 of the cooling agent. In the process of contact of the cooling agent with coke, heat is transferred from coke to the cooling agent, which is then supplied to the recovery boiler 3, in which the cooling agent cools and gives off its heat to the working fluid. As a result of suction of air in the circulation system 2 of the cooling agent, an excess volume of the cooling agent is formed, which is discharged through the exhaust means 10 of the excess volume of the cooling agent.

Coke is unloaded from the dry quenching chamber 1 of coke by means of a portion coke unloading device 6, which is adjacent to the lower part of the dry quenching chamber 1 of coke, while using a shutter 7 _1, coke is dosed into the bypass chamber 8 ₁ . To the upper part of the bypass chamber 8 _{1 there} is adjacent a means 10 for removing the excess volume of the cooling agent formed in the circulation system 2 of the cooling agent as a result of air suction. The amount of removal of the excess volume of the cooling agent is regulated using the regulator 12.

From the bypass chamber 8 ₁ using the shutter 7 ₂ , a metered portion of coke is supplied to the bypass chamber 8 ₂ , from which coke is then unloaded to the vehicle 9.

Figure 2 shows the installation of dry quenching of coke, in which the means 10 of the excess volume of the cooling agent is connected to an additional waste heat boiler 15, in which the thermal neutralization of the cooling agent occurs. In order to reduce the contamination of the heating surfaces (not shown in the drawings) of the additional waste heat boiler 15, before supplying the cooling agent to the additional heat recovery boiler 15, it is cleaned in the filter 16. Also, the STCC (figure 2) additionally contains a bypass circuit 17, which connects the means of removal 10 of the excess volume of the cooling agent with the chimney 11. In the event of an emergency or planned shutdown of an additional waste heat boiler 15 or smoke exhauster 18, the cooling agent is discharged through the bypass circuit 17, for which the regulator 19 is closed and the regulator 20 is opened. The use of an additional waste heat boiler 15 increases the heat recovery efficiency of the cooling agent, and the use of the bypass circuit 17 increases the reliability of the continuous operation of the CCP, which is also an advantage of the claimed utility model.

It is clear that the above are two possible options for the implementation of the claimed utility model. The utility model is not limited to the options that were described above and depicted in the figures.

Technical result

The technical result of the utility model is to reduce the amount of emissions of the cooling agent in the process of unloading coke from the means of portioned unloading of coke in the vehicle area.

Reducing the pressure of the cooling agent in the means of batch unloading of coke and reducing the pressure drops of the cooling agent in the means of batch unloading of coke, which leads to an increase in the efficiency of the means of batch unloading of coke.

Also the technical result of the utility model is to increase the efficiency of dust removal of coke.

Claims (5)

1. Installation of dry quenching of coke, containing at least one coke quenching chamber, a cooling agent circulation system adjacent to the above coke quenching chamber, means for removing an excess volume of cooling agent, means for portioning discharge of coke from a quenching quenching chamber, containing at least at least three shutters that form at least two series-connected bypass chambers, characterized in that adjacent to the upper part of the bypass chamber, into which the coke enters from the coke quenching chamber, is adjacent redstvo removing excess volume of the cooling agent. 2. Installation according to claim 1, characterized in that the means for removing the excess volume of the cooling agent is connected to the chimney. 3. Installation according to any one of claims 1 or 2, characterized in that the means for removing the excess volume of the cooling agent contains an additional waste heat boiler. 4. The installation according to claim 3, characterized in that it further comprises a bypass circuit that connects the means for removing the excess volume of the cooling agent with the chimney. 5. Installation according to any one of claims 1 or 2, characterized in that the means for removing the excess volume of the cooling agent further comprises at least one filter for cleaning the cooling agent.