RU79285U1 - INSTALL DRY EXTINGUISHING OF COX - Google Patents

Abstract

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

a) coke quenching chamber 1,

b) a cooling agent circulation system 2, comprising a recovery boiler 3 and means for draining an excess volume of the cooling agent from the cooling agent circulation system 2,

c) means for discharging coke 4 from the coke quenching chamber 1,

d) an additional waste heat boiler 5 connected to the cooling agent circulation system 2. In a private embodiment, the additional recovery boiler 5 is equipped with a smoke exhauster 6 ₁ , and also contains a heat exchanger 7 and a reactor 8, which includes a burner 9. The reactor 8 of the additional recovery boiler 5 is connected to the circulation system 2 of the cooling agent, and the burner 9 connected to a means for continuous unloading of coke 4. The technical result of the claimed utility model is to increase the efficiency of utilization of heat contained in the coke and reduce environmental pollution by carbon monoxide genus (CO). 1 s.p.f., 1 tablet, 1 silt

Description

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

BACKGROUND

Dry coke quenching plants are based on cooling coke in the coke quenching chamber with a cooling agent that circulates in the cooling agent circulation system (see Teplitsky MG et al. Dry quenching of coke, M., Metallurgy, 1971, p.52 -59). 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 a coke quenching chamber is carried out by passing a cooling agent through the coke layer, 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 the excess volume of the cooling agent from the circulation system of the cooling agent.

After the recovery boiler, a fine filter of the cooling agent, made in the form of a cyclone, is installed, 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 for venting excess volume

cooling agent, which is formed in the circulation system of the cooling agent as a result of air suction.

As a result, the CCPF operates in a specific aerodynamic mode, namely, in the upper part of the coke quenching chamber, a pressure close to atmospheric pressure (the so-called aerodynamic zero) is maintained, which prevents the release of a cooling agent during coke loading into the coke quenching chamber, and also prevents into the cooling agent of air, 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 dumping the excess volume of the cooling agent into the atmosphere through the candle 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 , due to the high resistance of coke during passage of the cooling agent through the coke, which leads to emissions of the cooling agent from the quenching chamber at the time of coke unloading a vehicle, such as a conveyor. In order to prevent the release of the cooling agent from the bottom of the coke quenching chamber, a means for continuously discharging coke is installed, which usually consists of a dispenser and an intermediate hopper.

The determination of the amount of air suction in the circulation system of the cooling agent is carried out in the process of operation of the CCP. So, during the operation of the CCP, the pressure sensor, which is located in the upper part of the CCP, constantly monitors the pressure value in the upper part of the coke quenching chamber. With increasing pressure in the upper part of the coke quenching chamber, excess coolant is discharged from the cooling agent circulation system through a candle into the atmosphere. During the discharge of the excess volume of the cooling agent through a candle into the atmosphere, measurements of the amount of cooling agent are carried out using known means, for example, flowmeters. Then determine what excess volume of the cooling agent was discharged into the atmosphere per unit time (hour). Then divide the resulting value by the value of the quantity

cooling agent, which had to quench coke in the coke quenching chamber for the same period of time (hour), after which the coefficient of air suction is obtained. On the basis of the coefficient of air suction, the effectiveness of the USTK is judged. The coefficient of air suction in the USTK should be no more than 15%. When the coefficient of air suction is equal to 15% or more, the unit is stopped for major repairs.

ANALOGUE

A known installation of dry quenching of coke (US patent No. 3895448, C10B 39/02, publ. 07/22/1975).

Dry coke quenching unit, contains:

a) a coke quenching chamber,

b) a cooling agent circulation system comprising a recovery boiler and means for draining an excess volume of the cooling agent from the cooling agent circulation system,

c) means for discharging coke from the coke quenching chamber.

A disadvantage of the known CCCP is that the aerodynamic zero is maintained in the upper part of the coke quenching chamber by dumping an excess volume of the cooling agent into the atmosphere through a candle, which leads to environmental pollution. It is known that the cooling agent contains about 6% carbon monoxide, whose calorific value is 3270 kcal / m ³ . Thus, in the well-known CCCT, chemical heat that is contained in the cooling agent is not used. The removal of the cooling agent to the atmosphere leads to inefficient utilization of the heat contained in the cooling agent and environmental pollution.

PROTOTYPE

A known installation of dry quenching of coke (US patent No. 4141795, C10B 39/02, publ. 02.27.1979).

Dry coke quenching unit contains:

a) a coke quenching chamber,

b) a cooling agent circulation system comprising a recovery boiler and means for draining an excess volume of the cooling agent from the circulation system,

c) means for discharging coke from the coke quenching chamber.

The means for draining the excess volume of the cooling agent is made in the form of a candle for discharging the cooling agent from the cooling agent circulation system.

A disadvantage of the known USTK is that when the excess volume of the cooling agent is vented to the atmosphere through a candle, the known USTK does not use the chemical heat contained in the cooling agent, and the environment is also polluted, since the cooling agent contains about 6% oxide carbon.

ESSENCE OF A USEFUL MODEL

The objective of the utility model is to develop a dry coke quenching unit, which allows to increase the efficiency of heat recovery contained in coke and reduce environmental pollution by carbon monoxide.

The problem is achieved in that in the known installation of dry quenching of coke, containing:

a) a coke quenching chamber,

b) a cooling agent circulation system comprising a recovery boiler and means for draining an excess volume of the cooling agent from the cooling agent circulation system,

c) means for discharging coke from the coke quenching chamber, according to the claimed utility model,

d) the dry coke quenching unit contains an additional recovery boiler, which is connected to the cooling agent circulation system.

The use of an additional recovery boiler provides an increase in the efficiency of utilization of the heat contained in the coke by using chemical heat contained in the cooling agent, which is removed through the means for removing the excess volume of the cooling agent from the circulation system of the cooling agent to the additional recovery boiler, in which the cooling the agent is heat treated.

In a particular embodiment of the dry coke extinguishing installation, the additional waste heat boiler comprises a heat exchanger and a reactor containing at least one burner device and also equipped with a smoke exhauster.

BLUEPRINTS

The figure attached to the present description, shows the installation of dry quenching of coke.

EXECUTING A DRY EXTINGUISHING COX EXTINGUISHING

The dry coke quenching installation includes a coke quenching chamber 1, a cooling agent circulation system 2, including a recovery boiler 3 and adjacent to the coke quenching chamber 1, as well as means for discharging coke 4 from the coke quenching chamber 1.

Also, the dry coke quenching unit contains an additional waste heat boiler 5, which is connected to the cooling agent circulation system 2.

An additional waste heat boiler 5 is equipped with a smoke exhauster 6 ₁ . In this case, the recovery boiler 5 includes a heat exchanger 7 and a reactor 8 containing at least one burner device 9.

The reactor 8 of the additional recovery boiler 5 is connected to the cooling agent circulation system 2 by a pipe 10, which serves as a means for draining the excess volume of the cooling agent from the cooling agent circulation system 2.

At the same time, the pipeline 10 is equipped with a regulator 11 for supplying a cooling agent from the circulation system 2 of the cooling agent to the reactor 8 of the additional waste heat boiler 5.

A pressure sensor 12 is installed in the upper part of the coke quenching chamber 1, and a vehicle 13 is placed under the means for unloading coke 4 to remove chilled coke from the CCP.

In the dry coke quenching unit, the additional waste heat boiler 5 is equipped with a gas duct 14 installed after the smoke exhauster 6 ₁ to remove exhaust gases from the additional heat recovery boiler 5.

To dedust the cooling agent supplied to the additional waste heat boiler 5, the dry coke quenching unit is equipped with a dust cleaner 15.

Also, the circulation system 2 of the cooling agent is equipped with a smoke exhauster 6 ₂ .

DRY EXTINGUISHING COX EXTINGUISHING INSTALLATION

The operation of the inventive installation of dry quenching of coke (see Fig.) Is as follows.

Coke obtained by coking in coke ovens using loaders (not shown) is loaded into the coke quenching chamber 1. In the coke quenching chamber 1, dry quenching of coke is carried out by passing a cooling agent through the coke layer. The cooling agent is circulated in the coke quenching chamber 1 by means of the cooling agent circulation system 2, which is equipped with a recovery boiler 3 and a smoke exhauster 6 ₂ . Coke, due to the action of gravity, from the quenching chamber of coke 1 enters the means for unloading coke 4, from which coke is discharged onto the vehicle 13.

The excess volume of the cooling agent from the circulation system 2 of the cooling agent is fed through a pipe 10 to the reactor 8 of the additional recovery boiler 5. In this case, the regulation of the excess volume

the cooling agent supplied to the reactor 8 from the cooling agent circulation system 2 is carried out by the cooling agent supply regulator 11 in accordance with the pressure in the upper part of the coke quenching chamber 1 detected by the pressure sensor 12.

When an excess volume of the cooling agent is supplied from the cooling agent circulation system 2 to the reactor 8, the cooling agent is dedusted by means of a dust cleaner 15. Fuel and air are supplied to the burner device 8 of the additional recovery boiler 5 to enrich the cooling agent.

In the additional waste heat boiler 5, the heat treatment of the cooling agent takes place, resulting in the formation of waste gases that give off heat to the heat exchanger 7 of the additional waste heat boiler 5, after which the exhaust gases are removed from the additional heat recovery boiler 5 with a smoke exhauster 6 ₁ into the atmosphere through the gas duct fourteen.

In USTK, the layout of which is presented in the attached drawing, the productivity was 52 t / h coke. The pressure value in the coke quenching chamber 1 was controlled using a pressure sensor 12 located in the upper part of the coke quenching chamber 1. The coefficient of air suction into the circulation system 2 of the cooling agent was 2%.

During the test installation of dry quenching of coke was performed:

a) dosed loading of coke into the coke quenching chamber 1 as coke ovens are unloaded (not shown in the drawing), in which coke was obtained by coking,

b) cooling the coke in the coke quenching chamber 1 with a cooling agent, for which 74,000 m ³ / h of cooling agent were supplied via the cooling agent circulation system 2 to the coke quenching chamber 1,

c) as coke with a temperature of 250 ° C arrives from the coke quenching chamber 1 into the coke unloading device 4, an excess volume of the cooling agent is withdrawn in an amount of 4300 m ³ / h with a temperature of 170 ° C from circuit 2

cooling agent into the reactor 8 of the additional recovery boiler 5,

d) in the process of removing the excess volume of the cooling agent in an amount of 4300 / h m ³ into the reactor 8 of the additional recovery boiler 5, fuel, for example, coke oven gas, and air were supplied to the burner 9 in order to maintain a stable temperature in the reactor 8 of the additional boiler -utilizer 5,

e) then the exhaust gases from the additional waste heat boiler 5 using a smoke exhauster 6 ₂ through the flue 14 were vented to the atmosphere,

f) produced the unloading of coke from the means for unloading coke 4 on the vehicle 13.

The table below presents the data obtained during the tests of the dry coke quenching unit.

TABLE Indicator Units measuring Value 1. The amount of excess volume of the cooling agent, which was removed from the circulation system 2 of the cooling agent in an additional waste heat boiler 5 m ³ / h 4300 2. The concentration of carbon monoxide (CO) contained in the excess volume of the cooling agent, which was discharged into the reactor 8 of an additional recovery boiler 5 from the circulation system 2 of the cooling agent % 12 3. The amount of superheated steam with a pressure of 4 MPa and a temperature of 440 ° C, additionally obtained during the hermetic treatment of carbon monoxide (CO) in an additional waste heat boiler 5 t / h 1.7 4. The increase in the efficiency of heat recovery in CCPF due to the combustion of a cooling agent containing carbon monoxide (СО) % 7.0 5. The amount of carbon monoxide (CO) contained in 1 m ^{3 of} gases from the additional waste heat boiler 6 % 0.01

As follows from the data given in the table, the use of the claimed utility model increases the efficiency of the CCCT due to the use of chemical heat during the combustion of carbon monoxide (CO) contained in the cooling agent, which provides an increase in the efficiency of utilization of the heat contained in the coke and reduces environmental pollution Wednesday.

Claims (2)

1. Installation of dry quenching of coke, containing a coke quenching chamber, a cooling agent circulation system including a recovery boiler and means for removing an excess volume of cooling agent from the cooling agent circulation system, means for discharging coke from a quenching quenching chamber, characterized in that the dry quenching installation Coke extinction contains an additional waste heat boiler, which is connected to the cooling agent circulation system. 2. Dry coke quenching apparatus according to claim 1, characterized in that the additional waste heat boiler includes a heat exchanger and a reactor including at least one burner device and also equipped with a smoke exhauster.