KR101611766B1 - Coke Dry Quenching Facility - Google Patents

Abstract

Provided in the present invention is a coke dry quenching facility, capable of solving the lack of suction air, which can be generated in the conventional facility. The coke dry quenching facility comprises: a prechamber for storing cokes inside; a cooling chamber connected to the lower part of the prechamber; a ring duct installed to cover the outside of the prechamber; a water gas generation device for spraying water to the inside of the prechamber; and a plurality of suction pipes connected to the ring duct and formed to introduce air from the outside by the negative pressure inside the prechamber, and suction valves installed to the suction pipes, respectively.

Description

Coke Dry Quenching Facility [0002]

The present invention relates to a coke dry type fire extinguishing device, specifically to a coke dry fire extinguishing device capable of increasing the amount of heat.

Coke Dry, Quenching Facility (CDQ) is a facility for digesting / cooling high-temperature coke of dry cargo and putting it into a shaft type chamber and then digesting / cooling the main component with nitrogen which is inert gas .

While conventional dry fire extinguishing systems have not recovered sensible heat from coke, dry fire extinguishing systems recover the sensible heat from the coke, and the recovered heat forms high pressure steam in the waste heat recovery boiler, It is used for production.

A technique for increasing the amount of heat recovered from a coke dry fire extinguishing system has been developed. In Patent Document 1, a technique for causing water gasification reaction of coke by spraying water through a nozzle at the top of the facility has been proposed.

(Patent Document 1) KR2013-0137980 A

It is an object of the present invention to provide a coke dry type fire extinguishing system capable of solving the shortage of suction air that can occur in the case of conventional facilities.

In order to achieve the above object, the present invention provides the following coke dry fire extinguishing system.

The present invention relates to a coke dry fire extinguishing system comprising: a prechamber for containing coke therein; A cooling chamber connected to the lower portion of the prechamber; A ring duct installed to surround the outside of the prechamber; A water gas generator for spraying water into the prechamber; And a plurality of suction valves connected to the ring duct and configured to allow air to flow from the outside by a negative pressure in the prechamber.

In one embodiment of the present invention, the suction valve may include a main suction valve connected to one side of the ring duct, and an auxiliary suction valve disposed at least one on each side in the circumferential direction around the main suction valve.

Also, in one embodiment of the present invention, the main suction valve may be configured as a butterfly valve capable of controlling the flow rate.

According to another aspect of the present invention, there is provided a water-gas generator including a water-gas generator and a control valve connected to the water-gas generator, wherein the controller controls the water- have.

At this time, the controller can maintain the water injection amount of the water-gas generator at 4.21 Kg-H ₂ O / t-coke or less.

The coke oven fire extinguishing system of the present invention may further include a heat utilization part which is connected to the opposite side of the suction duct of the ring duct and through which a circulating gas for recovering heat generated in the coke cooling is moved, The amount of air inflow through the suction valve can be adjusted based on the concentration.

And a control unit for controlling the opening and closing of the inlet port based on whether the inlet port is opened or closed or whether the coke is supplied to the prechamber, The amount of air inflow can be controlled.

The present invention can provide a coke dry fire extinguishing facility capable of increasing the amount of heat by eliminating the shortage of suction air that can occur in order to achieve an optimum effect in the case of a conventional facility.

1 is a schematic view of a coke dry fire extinguishing system of the present invention.
2 is a schematic cross-sectional view of a ring duct of a coke dry fire extinguishing system of the present invention.
3 is a flowchart of a suction valve control in a control unit of the coke dry type fire extinguishing system of the present invention.

Hereinafter, a specific embodiment of the present invention will be described with reference to the accompanying drawings.

Figure 1 shows a coke dry fire extinguishing system of the present invention. The coke dry type fire extinguishing system of the present invention comprises a prechamber 20 having an inlet 10 at the top and a cooling chamber 30 connected to a lower portion of the prechamber 20 and having a coke discharge port, A water gas generator 100 connected to the inlet 10 and injecting water into the prechamber 100, a ring surrounding the prechamber 20, A duct 40 and a gas valve 50 connected to the ring duct 40 to connect the ring duct 40 and the waste heat recovery boiler 60 to each other, And a recovery pipe 70 connected to the boiler 60 and the cooling chamber 30 and having a circulation blower 80 disposed therein.

The suction valve 150 is composed of a main suction valve 155 and an auxiliary suction valve 165, as shown in Fig. A main suction pipe 151 to which the main suction valve 155 is connected is connected to one side of the ring duct 40 and one end of the gas discharge pipe 50 is connected to the other side of the main suction pipe 151 .

An auxiliary suction pipe 160 is disposed in the ring duct 40 on both sides of the main suction pipe 151 in the circumferential direction and an auxiliary suction valve 165 is connected to the auxiliary suction pipe 160, Respectively.

In this embodiment, the suction of air through the main suction pipe 151 is performed by a method in which external air is introduced by a negative pressure inside the chamber, and the main suction pipe 151 is provided with a butterfly type flow control valve A main suction valve 155 is mounted.

Even if the opening degree of the main suction valve 155 increases when the air is introduced by the negative pressure, if it exceeds a certain range, for example, about 70% in the case of the butterfly type, the amount of air sucked increases even if the opening degree increases Do not. Therefore, even if the opening amount of the main suction valve 155 is increased to increase the air suction amount. The efficiency of the water gas reactor 100 is not improved because the amount of air sucked is not increased.

However, in this embodiment, the auxiliary suction pipe 160 is connected to both sides in the circumferential direction around the main suction pipe 151 as well as the main suction pipe 151, and an auxiliary suction pipe 160 is connected to each of the auxiliary suction pipes 151 It is possible to increase the amount of intake air by operating the auxiliary intake valve 165 when the main intake valve 155 of the main intake pipe 151 does not function because the intake valve 165 is mounted, By operating the valve 155 and the auxiliary intake valve 165 together, it is possible to control the amount of intake air accurately.

FIG. 3 is a flowchart of a suction valve control in the control unit of the coke dry fire extinguishing system of the present invention.

The control unit is disposed in the heat utilization portion including the gas discharge pipe 50 and the boiler 60 and the recovery pipe 70 so as to supply the gas recovered from the ring duct 40 to the boiler 50 to utilize sensible heat A measurement unit for measuring the CO concentration of the circulating gas circulating through the coke dry fire extinguishing facility and the heat utilization part, an opening / closing sensor connected to the inlet port 10 to judge opening / closing of the inlet port, An amount of air inflow through the suction valve is controlled based on the CO amount of the circulating gas or an amount of air inflow through the suction valve is controlled based on the opening and closing information of the inlet.

Specifically, as shown in FIG. 3, the control unit measures the CO concentration through the CO concentration measuring unit disposed in the heat utilizing unit (S100), compares the CO concentration obtained by the CO concentration measuring unit with the CO setting value (S110) If the CO concentration is low, it is determined that the intake air is sufficient and the suction valve 150 is closed (S130). If the CO concentration is greater than or equal to the set value, the suction valve 150 is opened at the set opening degree, (S120).

Thereafter, a signal is received from the opening / closing sensor connected to the inlet port 10 to indicate that the inlet port is opened (S140). When the signal indicating that the inlet port is opened is opened, the opening degree of the inlet valve 150 is adjusted to be smaller than the previous one S150).

In the present invention, the controller determines whether the air intake amount is appropriate or excessive based on the CO concentration or the CO amount of the circulating gas, and determines whether the suction valve 150 is open or closed.

When the inlet 10 is opened to supply the coke to the inside of the coke dry digestion facility, not only the coke but also the outside air is introduced through the inlet 10 so that the inlet valve 150 is connected to the inlet 10 The opening of the inlet port 10 is measured and if the inlet port 10 is opened, the opening degree of the inlet valve 150 is set to be larger than the opening of the inlet port 10 Adjust.

It is possible to control the intake air such that the intake air is not excessive or insufficient by the control unit, and thus the heat recovery can be increased while maintaining the water gasification reaction.

The controller of the present invention is connected to the water gas generator 100 and controls the water supply amount of the water gas generator 100 according to the amount of coke supplied into the coke dry fire extinguishing device through the intestinal inlet 10 Can be adjusted. At this time, the amount of coke can be determined on the basis of the amount of coke to be supplied and the amount of coke to be discharged, or the amount of coke of the equipment can be calculated through the load cell.

When the ratio of the amount of water supplied to the water gas generator 100 to the amount of coke exceeds 4.21 kg-H ₂ O / t-coke, it is difficult to control the pressure in the prechamber 20, The temperature of the cooling water is lowered, which is disadvantageous to heat recovery. Accordingly, the control unit can increase the heat recovery rate of the coke dry type fire extinguishing system by adjusting the water supply amount of the water gas generator 100 as well as the opening of the suction valve 150.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: entry opening 20: free chamber
30: Cooling chamber 40: Ring duct
150: Suction valve 151: Main suction pipe
155: main suction valve 160: auxiliary suction pipe
165: auxiliary suction valve

Claims (7)

As a coke dry fire extinguishing system,
A prechamber for containing the coke therein;
A cooling chamber connected to the lower portion of the prechamber;
A ring duct installed to surround the outside of the prechamber;
A water gas generator for spraying water into the prechamber; And
A plurality of suction pipes connected to the ring duct and configured to allow air to flow in from the outside by a negative pressure in the prechamber and suction valves respectively mounted on the suction pipes,
The suction valve
A main suction valve mounted on the main suction pipe connected to one side of the ring duct; And
An auxiliary suction valve mounted on an auxiliary suction pipe disposed on both sides in the circumferential direction around the main suction pipe;
/ RTI >
Wherein the auxiliary suction pipe is smaller in diameter than the main suction pipe.
delete The method according to claim 1,
Wherein the main suction valve comprises a flow rate adjustable butterfly valve.
The method according to claim 1 or 3,
And a control unit connected to the water gas generator and the intake valve,
Wherein the control unit adjusts the water injection amount of the water-gas generator based on the amount of coke in the pre-chamber.
5. The method of claim 4,
Wherein the control unit maintains the water injection amount of the water gas generator at 4.21 Kg-H ₂ O / t-coke or less.
5. The method of claim 4,
Further comprising a heat utilization part connected to the suction side of the ring duct, the circulation gas being used to recover heat generated in the coke cooling,
Wherein the control unit controls the amount of air inflow through the suction valve based on the CO concentration of the circulating gas.
5. The method of claim 4,
Further comprising a field inlet disposed above the prechamber, wherein the water gas generator is mounted,
Wherein the control unit adjusts an inflow amount of air through the suction valve based on the opening / closing information of the entrance opening of the coke oven.

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