KR101329720B1 - Apparatus for preheating supplying water of boiler using collecting dust in coke dry quenching units - Google Patents

Abstract

The present invention relates to a boiler feed water preheating apparatus using CDQ (Coke Dry Quenching) dust collection dust, which is provided in a CDQ (Coke Dry Quenching) facility and installed in a water cooling unit for catching dust. The inner cylinder and the outer cylinder to perform a cooling function, the inner cylinder is divided into a first inner cylinder cooling water channel and a second inner cylinder cooling water channel, the first inner cylinder cooling water channel is located above; The outer cylinder constitutes the outer cylinder cooling water passage in a form surrounding the outer circumferential surface of the dust catcher; Provided is a boiler feed water preheating apparatus using the CDQ dust collecting dust characterized in that the cooling water passed through the first inner cylinder cooling water flow passage to the intermittent to be used as boiler feed water.
According to the present invention, the pure water passing through the water cooling unit in the CDQ facility enables a sufficient high temperature heat exchange to have a preheating function, thereby reducing the temperature difference between the pure water and the circulating gas passing through the coal mill, thereby reducing condensation occurring on the outer surface of the coal mill. It is possible to achieve the effect of preventing the long life of the economizer and solving the poor breathability of the circulating gas.

Description

Boiler feedwater preheater using CD dust collection dust {APPARATUS FOR PREHEATING SUPPLYING WATER OF BOILER USING COLLECTING DUST IN COKE DRY QUENCHING UNITS}

The present invention relates to a boiler feed water preheating apparatus using CDQ (Coke Dry Quenching) dust collection dust, and more particularly, to prevent condensation by reducing the temperature variation of the feed water supplied to the side of the coal mill and the temperature of the circulating gas passing through the coal mill. The present invention relates to a boiler feed water preheating device using an improved CDQ dust collection.

In general, CDQ (Coke Dry Quenching) equipment refers to the equipment used for cooling and extinguishing the red coke produced in the coke oven (COKE OVEN) by the circulating gas (nitrogen: 75%, air: 25%).

For example, FIG. 1 schematically shows such a CDQ facility, in which the water cooling unit A provided in the CDQ facility collects dust of rather coarse particles contained in the circulating gas circulated by the circulation fan C in a gravity settling manner. The collected dust is cooled (about 900 ° C. to 25 ° C.) using cooling water, and then stored and discharged into a dust bin.

And, the coal mill B is a boiler feed water preheater, and is provided to help save energy by preheating the boiler feed water supplied to the deaerator to reduce the amount of steam used to increase the boiler feed water temperature in the deaerator.

Thus, the boiler feed water is carried out with the flow as shown in FIG. 2, for example, the pure water stored in the pure water storage tank 10 is supplied to the side of the crusher B by the pure water supply pump 12, and the crusher B ) Is sent to the deaerator 16 to remove the dissolved oxygen by preheating the pure water, the boiler feed water degassed from the deaerator 16 is pumped through the feed water pump 18 is supplied to the primary preheating tube (20), A part of the boiler feed water passing through the primary preheating tube 20 is supplied to the evaporator 26 via the steam drum 22 and the circulation pump 24, and the other part is supplied to the turbine via the superheater 28.

At this time, the temperature of the circulating gas flowing into the coal mill (B) is about 100-150 ° C, while the pure water passing through the water cooling unit (A) is only about 20-30 ° C. Due to the temperature difference between the condensation (B) tube condensation phenomenon is caused, and the dust is stuck to the dust to promote the corrosion of the tube, not only shorten the life, but also poor ventilation of the circulating gas, deaerator 16 In order to heat up the boiler water supplied by the steam consumption to increase the disadvantage that the energy loss increases.

This phenomenon can be seen from the water cooling unit (A) having a structure as shown in Figure 3, for example, the inner cylinder 40 at the bottom of the dust catcher (Dust Catcher) refractory (30) where the pure water is a passage of the circulating gas It is because it is configured to move through the flow path of the double pipe structure of the outer cylinder 50, and having such a structure, the temperature of approximately 90 ℃ outside the refractory 30 side drops sharply toward the lower side, the outer cylinder (40, 50) has a distribution of about 30 ℃ in the middle portion, and approximately 20 ℃ in the lower portion of the dust is cooled and then cut through the dust extractor 60, so that the pure water discharged after circulating the whole as a whole though the inner cylinder (40) Heat exchange was performed while separating and circulating the outer cylinder 50, but it has a structural limitation that cannot maintain a high temperature.

The present invention was created in order to solve this problem in view of the above-described limitations of the prior art, and the line supplied to the water-cooled coal crusher passing through the structure of the water cooling unit in the CDQ facility passes through at least sufficient heat exchange. CDQ dust collection to prevent the condensation occurring on the outer surface of the tube forming the breaker and to achieve longer life of the breaker by reducing the temperature difference between the pure water and the circulating gas passing through the coal mill Its main purpose is to provide a boiler feedwater preheater using dust.

The present invention is a means for achieving the above object, in the boiler feed water preheating device provided in the CDQ (Coke Dry Quenching) facility to catch the dust is installed in the water cooling unit, passing through the upper portion of the dust catcher Cylindrical dust catcher refractory, the upper and lower portions are open so that dust contained in the circulating gas is collected and lowered; It is installed in a form surrounding the outer circumferential surface of the dust catcher in the open lower portion of the dust catcher refractory, and provides an inner space in communication with the inside of the dust catcher refractory, the outer cylinder cooling water flow path flowing coolant supplied from the outside An outer cylinder is formed along the vertical direction therein; An inner cylinder spaced apart from an inner circumferential surface of the outer cylinder at a central portion of the inner space and installed in an up and down direction, and an inner cylinder coolant flow path through which coolant supplied from the outside flows; And a dust cutting machine installed at an open lower portion of the outer cylinder and cutting out the dust lowered along the inner space between the outer cylinder and the inner cylinder,
The inner cylinder cooling water flow passage is divided into a first inner cylinder cooling water flow passage and a second inner cylinder cooling water flow passage disposed up and down and blocked from each other; The cooling water having passed through the second inner cylinder cooling water flow passage continues to circulate for dust cooling; The heated cooling water passed through the first inner cylinder cooling water flow passage is provided to a blower for use as boiler feed water to provide a boiler feed water preheating apparatus using CDQ dust collecting dust.

In this case, the height of the second inner cylinder cooling water channel is also characterized by being twice the height of the first inner cylinder cooling water channel.

In addition, a separate fresh water supply line that can be used in an emergency is connected to the supply pipe for supplying the cooling water to the first inner cylinder cooling water flow passage, and a separate fresh water discharge line is further connected to the discharge pipe for discharging the cooling water.

In addition, the fresh water supply line is further provided with a fresh water opening and closing valve to selectively supply the supplied fresh water, the fresh water discharge line is also characterized in that the drain opening and closing valve is further provided to selectively discharge the discharged drainage have.

According to the present invention, the pure water passing through the water cooling unit in the CDQ facility enables a sufficient high temperature heat exchange to have a preheating function, thereby reducing the temperature difference between the pure water and the circulating gas passing through the coal mill, thereby reducing condensation occurring on the outer surface of the coal mill. It is possible to achieve the effect of preventing the long life of the economizer and solving the poor breathability of the circulating gas.

1 is an exemplary view showing a process of a general CDQ facility.
2 is an exemplary view showing a flow of boiler water using a conventional CDQ facility.
3 is an exemplary cross-sectional view of a water cooling unit implemented in a conventional CDQ facility.
4 is an exemplary cross-sectional view showing the water cooling unit of the CDQ facility constituting the device according to the present invention.
5 is an exemplary process diagram showing an example of boiler water supply with a water cooling unit according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Boiler feedwater preheater according to the present invention is to improve the structure of the water cooling unit in the CDQ facility to duplicate the flow path through which pure water passes, divided into a high temperature heat exchanger and a low temperature heat exchanger and configured to allow the pure water to be preheated to a predetermined temperature or more in advance. will be.

For example, as illustrated in FIGS. 4 and 5, the temperature of the circulating gas passing through the side of the dust catcher 100, which is a passage of the circulating gas, is about 800-900 ° C.

Therefore, the dust collected in the dust catcher 100 also has a temperature distribution in a similar range but not the same temperature.

However, when the temperature is measured at a predetermined interval from the top to the bottom with respect to the outer shell constituting the dust catcher 100, the temperature is rapidly increased as the upper end is about 90 ℃, the middle portion is about 30 ℃, the lower end is about 20 ℃ You can see the fall.

In view of the above advantages, the present invention implements a cooling water flow path that can induce heat exchange of pure water supplied to the economizer 200 (refer to FIG. 5) at the upper end side maintained at a relatively high temperature, thereby inducing pure water closer to preheating. ) To minimize the temperature difference with the circulating gas flowing into

To this end, in the present invention, the inner cylinder 110 of the dust catcher 100, which is maintained at a relatively high temperature, is divided into 1/3 in the vertical direction to make a first inner cylinder cooling water flow passage 112, and the remaining 2/3 is The second inner cylinder cooling water passage 114 is made, and the outer cylinder 120 is configured to make the outer cylinder cooling water passage 122 the same as the existing one so as to sufficiently increase the heat exchange efficiency.

Therefore, since the first inner cylinder cooling water channel 112 exchanges heat with dust maintained at a relatively high temperature, the first inner cylinder cooling water channel 112 is preheated to a relatively high temperature, for example, a temperature distribution close to 90 ° C., and the first coolant preheated to the temperature range is cut off. By supplying the gas 200, it is possible to reduce the temperature difference with the circulating gas as much as possible.

In this case, the first inner cylinder cooling water channel 112 is introduced into the first inner cylinder cooling water channel 112 through the first inlet I1 and stays in the first inner cylinder cooling water channel 112 having a chamber shape. While being heat-exchanged with the high-temperature dust, the temperature is raised and then discharged through the first outlet (O1).

In addition, although the second inner cylinder cooling water passage 114 provided in the inner cylinder 110 is separated from the first inner cylinder cooling water passage 112 and provided in the inner cylinder 110, the second cooling water is passed through the second inlet port I2. After flowing into the inner cylinder cooling water passage 114, it is discharged through the second outlet (O2).

In addition, the outer cylinder cooling water flow passage 122 formed in the outer cylinder 120 is a kind of shell cooling, and after the third cooling water flows into the outer cylinder cooling water passage 122 through the third inlet I3, the third outlet ( Through O3).

In addition, as shown in Figure 5, it is necessary to provide a safety device to cope with emergencies of the CDQ, which is a state in which the boiler water supply is not possible when the operation of the CDQ is not smooth or stopped due to unavoidable causes Is to prevent this from happening.

To this end, the fresh water supply line 400 is connected to the first inlet (I1) of the first inner cylinder cooling water flow path 112 to separately supply the fresh water supply line 400 on the supply pipe 300 for supplying the first cooling water, and the fresh water supply line 400. The freshwater opening and closing valve 402 is provided to be selectively provided, and the supply pipe 300 to which the freshwater supply line 400 is connected is provided with a freshwater supply line 400 between the first and second valves ( 302 and 304 are respectively installed and configured to selectively open and close to respond to an emergency.

In addition, the discharge pipe 310 is connected to the first outlet (O1), the fresh water discharge line 410 is connected to the discharge pipe 310 separately.

At this time, the freshwater discharge line 410 is also provided with a drain opening and closing valve 412 to control the discharge water.

As described above, the apparatus according to the present invention can achieve the preheating function of the boiler feed water by improving the lower cooling structure of the dust catcher 100 constituting the water cooling unit (A, see FIG. The service life of the 200 can be extended.

100: dust catcher 110: inner cylinder
112: first inner cylinder cooling water channel 114: second inner cylinder cooling water channel
120: outer cylinder 122: outer cylinder cooling water flow path
200: coal mill 300: supply pipe
310: discharge pipe 400: fresh water supply line
410 freshwater discharge line

Claims (4)

In the boiler feed water preheater provided in the CDQ (Coke Dry Quenching) facility, the dust catcher for catching the dust is installed in the water cooling unit,
Cylindrical dust catcher refractory having an upper and a lower portion opened to collect and descend dust contained in the circulating gas passing through the upper portion of the dust catcher;
It is installed in a form surrounding the outer circumferential surface of the dust catcher in the open lower portion of the dust catcher refractory, and provides an inner space in communication with the inside of the dust catcher refractory, the outer cylinder cooling water flow path flowing coolant supplied from the outside An outer cylinder is formed along the vertical direction therein;
An inner cylinder spaced apart from an inner circumferential surface of the outer cylinder at a central portion of the inner space and installed in an up and down direction, and an inner cylinder coolant flow path through which coolant supplied from the outside flows; And
Is installed in the open lower portion of the outer cylinder, including a dust cutting machine for cutting out the dust descended along the inner space between the outer cylinder and the inner cylinder,
The inner cylinder cooling water flow passage is divided into a first inner cylinder cooling water flow passage and a second inner cylinder cooling water flow passage disposed up and down and blocked from each other;
The cooling water having passed through the second inner cylinder cooling water flow passage continues to circulate for dust cooling;
Boiler feed water preheating apparatus using the CDQ dust collecting dust, characterized in that the heated cooling water passed through the first inner cylinder cooling water flow channel to be used as boiler feed water.
The method of claim 1,
And a height of the second inner cylinder cooling water channel is twice the height of the first inner cylinder cooling water channel.
The method of claim 1,
CDQ dust collection boiler, characterized in that a separate fresh water supply line for emergency use is connected to the supply pipe for supplying cooling water to the first inner cylinder cooling water flow passage, and a separate fresh water discharge line is further connected to the discharge pipe for discharging the cooling water. Water feed preheater.
The method according to claim 3;
The fresh water supply line is further provided with a fresh water opening and closing valve to selectively supply the supplied fresh water, the fresh water discharge line CDQ dust collection, characterized in that the drain opening and closing valve is further provided to selectively discharge the discharged water Boiler feedwater preheater.

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