KR20180078048A - Blowdown system - Google Patents

Abstract

A blowdown system comprises: a blowdown tank containing water and steam which are discharged out of a boiler for a normal operation of the boiler; a drainpipe through which water stored in the blowdown tank drains to the outside of the blowdown tank, the drainpipe being connected to a lower portion of the blowdown tank; and a cooling pipe through which cooling water supplied to the drainpipe to lower the temperature of the water discharged through the drainpipe flows, the cooling pipe being connected to the drainpipe.

Description

Blowdown system {BLOWDOWN SYSTEM}

The present invention relates to a blowdown system.

1 is a configuration diagram showing a conventional blowdown system. The conventional blowdown system includes a blowdown tank 10, a drain pipe 11, a drain pipe 15 and a cooling pipe 13. Blowdown tank 10 refers to a tank in which water and steam drained from the boiler are stored for normal operation of the boiler. The drain pipe 11 is connected to the blowdown tank of the boiler and the drain pipe 15 is a pipe for draining the water stored in the blowdown tank 10 to the outside of the blowdown tank 10. The drain pipe 11, Refers to a pipe through which cooling water supplied to lower the temperature of water stored in the blowdown tank 10 flows.

In the boiler, the water is drained to the blowdown tank 10 to meet the water quality requirements of the steam required by the steam turbine. The water supplied to the blowdown tank 10 is changed into a state of steam gas and saturated water in the blowdown tank 10 and the water of the high temperature (saturated water) stored in the blowdown tank 10 It is necessary to cool the water to an appropriate temperature.

Conventionally, cooling water is supplied to the inside of the blowdown tank 10 through the cooling pipe 13 connected to the blowdown tank 10. When the cooling water at room temperature is injected into the blowdown tank 10 at a high temperature The temperature measuring device 12 installed inside the blowdown tank 10 temporarily recognizes that the temperature inside the blowdown tank 10 has risen due to the convection phenomenon of the hot steam gas generated due to the evaporation of the cooling water There was a problem.

When the temperature measuring device 12 recognizes that the temperature inside the blowdown tank 10 is raised, more cooling water is supplied to the blowdown tank 10 and the water level of the blowdown tank 10 rises, When the water level is reached, there is a problem that the operation of the boiler is stopped urgently.

In the prior art, when the drain valve (not shown) provided in the drain pipe 11 is opened, the cooling water is controlled to be supplied through the cooling pipe 13, and water supplied from the boiler is supplied to the blowdown tank 10 Even when the temperature of the stored water is not increased, that is, when the water stored in the blowdown tank 10 is not required to be further cooled, the cooling water is additionally supplied and wasted.

In addition, since unnecessary supply of cooling water increases the operating cost of the sewage system and leads to inefficient facility operation, it is necessary for the blowdown system to prevent the supply of unnecessary cooling water and to reduce the amount of water to be sewage- .

An object of the present invention is to provide a blowdown system for supplying optimal cooling water to stably maintain the level of the blowdown tank and to prevent occurrence of an emergency stop situation of the boiler.

Another object of the present invention is to provide a blowdown system that minimizes the amount of water drained and sewage treated in a blowdown tank, thereby economically using the boiler.

In one example, the blowdown system is connected to the bottom of the blowdown tank, where the water and steam are stored in the boiler for normal operation of the boiler, and the water stored in the blowdown tank is connected to the outside of the blowdown tank And a cooling pipe connected to the drain pipe and the drain pipe through which the cooling water supplied to the drain pipe flows to lower the temperature of the water drained through the drain pipe.

According to the present invention, since the cooling pipe is directly connected to the drain pipe to supply the cooling water, unnecessary supply of the cooling water can be prevented.

According to the present invention, since the cooling water is supplied based on the temperature of the water mixed with the water and the cooling water drained through the drain pipe, the cooling water is prevented from being unnecessarily supplied, the water level of the blowdown tank is appropriately maintained, It is possible to prevent the problem of emergency stop.

Further, according to the present invention, the water drained from the blowdown tank is cooled and recycled, whereby the amount of water to be sewage-treated is greatly reduced, so that the boiler can be economically used.

1 is a configuration diagram showing a conventional blowdown system.
2 is a configuration diagram illustrating a blowdown system according to an embodiment of the present invention.
3 is a schematic diagram showing a temporary processing unit according to an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the understanding of the embodiments of the present invention.

2 is a configuration diagram illustrating a blowdown system according to an embodiment of the present invention. Hereinafter, a blowdown system according to an embodiment of the present invention will be described with reference to FIG.

The blowdown system according to an embodiment of the present invention includes a blowdown tank 20, a drain pipe 21, a drain pipe 25, and a cooling pipe 23.

Blowdown tank 20 refers to a tank in which water and steam drained from the boiler are stored for normal operation of the boiler. For example, if the water quality requirements (pH, dissolved solids, dissolved gas, etc.) of the steam required by the steam turbine of the boiler are not met, or if the water stored in the drum of the boiler contains solids or foreign matter, It is necessary to discharge the air to the blowdown tank 20.

The drain pipe 21 refers to a pipe connected to the blowdown tank 20 from the boiler. The drain pipe 21 may be provided with a drain valve (not shown), and water may be drained from the boiler to the blowdown tank 20 by opening and closing the drain valve.

The drain pipe 25 refers to a pipe through which the water stored in the blowdown tank 20 is drained to the outside of the blowdown tank 20. The drain pipe 25 is connected to the lower portion of the blowdown tank 20. The water drained into the blowdown tank 20 can be drained through the drain pipe 25 if it can not be recycled or drained to the temporary treatment unit 50 for recycling as described later.

The drain pipe 25 may be provided with a drain pump 24 for sucking water from the blowdown tank 20 and discharging the water to the drain pipe 25. The drain pump 24 may be connected to the blowdown tank 20 can be drained to the drain pipe 25.

The cooling pipe 23 refers to a pipe through which the cooling water supplied to the drain pipe 25 flows to lower the temperature of the water drained through the drain pipe 25. When water is drained from the boiler to the blowdown tank 20, the water changes in the form of steam gas and saturated water or steam gas and water that is not separated by saturating water due to the pressure drop and can be drained to the blowdown tank 20 have. At this time, since water such as saturated water has a very high temperature, it is necessary to cool the water drained to the outside from the blowdown tank 20 for sewage treatment or recycling of water such as saturated water.

 At this time, the cooling pipe 23 is directly connected to the drain pipe 25, and the cooling water is supplied to the drain pipe 25. The cooling pipe 23 is directly connected to the drain pipe 25 so that the water level rise of the blowdown tank 20 caused by the supply of the cooling water to the inside of the blowdown tank 20 and the emergency stop situation of the boiler It is possible to prevent a problem caused.

More preferably, the cooling pipe 23 may be connected to the drain pipe 25 at a position spaced apart from the bottom of the blowdown tank 20 by twice the diameter of the cooling pipe 23.

When the cooling pipe 23 is connected to the lower portion of the blowdown tank 20 at a position within two times the diameter of the cooling pipe 23 the cooling water supplied from the cooling pipe 23 flows to the bottom of the blowdown tank 20 It is possible to lower the temperature of the water drained through the drain pipe 25 by using a smaller amount of cooling water.

However, if the supply position of the cooling water is too close to the blowdown tank 20, the water drained into the blowdown tank 20 may be prevented from being separated into steam and saturated water. In view of the design characteristics of the blowdown tank 20 The lower portion of the blowdown tank 20 is provided with a thermal insulating material, so that the approach of the cooling pipe 23 to the blowdown tank 20 may be limited.

On the other hand, when the cooling pipe 23 is connected to the lower portion of the blowdown tank 20 at a position twice or more the diameter of the cooling pipe 23, the cooling water supplied from the cooling pipe 23 flows into the lower portion of the blowdown tank 20 It is necessary to supply a larger amount of cooling water.

It is therefore preferable that the cooling pipe 23 is connected to the drain pipe 25 at a position spaced from the bottom of the blowdown tank 20 by at most 30 times the diameter of the cooling pipe 23. The blowdown system may further include a first temperature measuring device 22. [

The first temperature measuring device 22 can measure the temperature of the water mixed with the water and the cooling water drained through the drain pipe 25. And the cooling pipe 23 can be opened or closed based on the temperature measured by the first temperature measuring device 22. [

More specifically, the first temperature measuring device 22 is connected to a drain pump (not shown) provided in the drain pipe 25 so as to be spaced apart from the blowdown tank 20 rather than the mixing position M at which the cooling water is supplied from the drain pipe 25 24 and the mixing position M, the inlet side temperature of the drain pump 24 can be measured. More preferably, the temperature measuring device may be provided at a position separated from the mixing position M by 1 m or more.

Since the cooling pipe 23 is opened and closed based on the temperature of the water mixed with the water and the cooling water discharged through the drain pipe 25, Can be prevented from being supplied.

The cooling pipe 23 is opened when the water and steam discharged from the boiler to the blowdown tank 20 cause a rise in the temperature of the water drained through the drain pipe 25 and is discharged from the boiler to the blowdown tank 20 Even if water and steam are drained through the drain pipe 25, it may not be opened unless the temperature of the water drained through the drain pipe 25 rises.

Conventionally, as long as water and steam are discharged from the boiler to the blowdown tank 20, cooling water is basically supplied to the inside of the blowdown tank 20. [ However, in the cooling pipe 23 of the present invention, the temperature of the water drained to the blowdown tank 20 from the boiler and the water drained through the drain pipe 25, that is, the water drained through the drain pipe 25, Since the cooling water is supplied only when the temperature of the mixed water is raised, the amount of cooling water unnecessarily used can be reduced.

The blowdown system may further include a temporary processing unit 50. [ 3 is a schematic diagram showing a temporary processing unit according to an embodiment of the present invention. Hereinafter, a temporary processing unit 50 according to an embodiment of the present invention will be described with reference to FIG.

The temporary processing unit 50 can temporarily process the water that has been drained to the outside of the blowdown tank 20 through the drain pipe 25 and has not been immediately subjected to the sewage treatment. The temporary processing unit 50 may include a storage tank 30 and a distributor 40.

At least a part of the storage tank 30 is provided below the ground (e), and the upper side is opened to communicate with the atmosphere and can store the water drained through the drain pipe 25. The reservoir 30 may be provided in the basement, at least a portion of which is lower in temperature than the atmosphere, so that the water stored in the reservoir 30 may cool more rapidly. In addition, it can communicate with the atmosphere without being hermetically sealed, so that the water stored therein can be heat-exchanged with the atmosphere and cooled more quickly.

The temporary processing unit 50 may further include a rotary fan 31 for injecting air into the water stored in the storage tank 30 and a plurality of air injection nozzles 33 provided at a lower portion of the storage tank 30.

A fan 31 installed on the ground injects air into the air injection nozzle 33 provided at the lower part of the storage tank 30 to generate bubbles.

When air is sprayed from the air injection nozzle 33 to the water stored in the storage tank 30, aeration occurs due to bubbling at the water surface, and the area of the water stored in the storage tank 30 By spreading, the temperature of the water stored in the reservoir 30 can be cooled more quickly. That is, the temperature of the water stored in the storage tank 30 may be lowered by the air injection by the rotation of the fan 31.

The temporary treatment unit 50 may further include a dispensing pump 35 for recovering the water stored in the reservoir 30. [ The dispenser 40 can receive the water recovered from the dispensing pump 35 and inject it back into the reservoir 30. The distributor 40 may be provided on the ground.

The water recovered by the distributor 40 and injected into the storage tank 30 is heat-exchanged with the atmosphere and is stored again in the storage tank 30 after the temperature is lowered. As a result, the temperature of the water stored in the storage tank 30 may be lowered have.

More specifically, the distributor 40 includes a pipe 41 through which the water recovered in the reservoir 30 flows, a plurality of nozzles (not shown) supplied with water through the pipe 41 and then injected into the reservoir 30 42 and a plurality of heat sinks 43 formed on the outer periphery of the pipe 41.

The heat sinks 43 facilitate the heat exchange between the pipe 41 and the atmosphere to lower the temperature of the water flowing through the pipe 41. The plurality of nozzles 42 are connected to the pipe 41 through a pipe And the water sprayed from the nozzle 42 into the interior of the storage tank 30 can be secondarily heat-exchanged with the atmosphere to further lower the temperature. The temperature of the water stored in the reservoir 30 can be further lowered.

2, the cooled water stored in the storage tank 30 can be recovered to the water tank 90 and recycled in the boiler. The blowdown system includes a water tank 90 for recovering and storing water in the storage tank 30 for recycling water stored in the storage tank 30 and a recovery pipe 55 for connecting the storage tank 30 and the water tank 90 ). ≪ / RTI >

The blowdown system may further include a recovery pump 56 and a filter 70 provided in the recovery pipe 55. The recovery pump 56 can recover the water in the reservoir 30 and supply it to the tank 90. The filter 70 can filter the foreign substances contained in the water recovered in the reservoir 30. [

Since the water that has been drained to the blowdown tank 20 from the boiler and is cooled in the storage tank 30 may contain foreign matter such as floating matters, the filter 70 may remove foreign substances contained in the water recovered in the storage tank 30 Can be removed.

Also, the water stored in the water tank 90 and recycled is desirably at a temperature of 30 DEG C to 40 DEG C, and can not be recycled in the boiler if it has too high a temperature. Therefore, the filter 70 can prevent water from being collected in the reservoir tank 30 from the reservoir tank 90 when the temperature of the water supplied to the water tank 90 is equal to or higher than the reference temperature. To this end, the storage tank 30 may be provided with a second temperature measuring device (not shown) for measuring the temperature of the water stored in the storage tank 30.

At this time, the reference temperature is the lowest temperature of the water stored in the storage tank 30 in which the boiler is judged to operate abnormally when the water stored in the storage tank 30 is recovered to the water tank 90 from the storage tank 30, As the temperature, it may be, for example, 60 캜.

The water stored in the water tank 90 can be used as raw water for a pure water treatment plant that removes positive and negative ion components to match the quality of water and steam required by the boiler. However, when the ionic liquid used to remove the ion component exceeds 45 캜, the ion exchange performance is deteriorated and the life of the resin is shortened.

In addition, the water stored in the water tank 90 may be used as cooling water supplied to the blowdown tank 20.

When the temperature of the water stored in the storage tank 30 is 60 ° C., the temperature of the water recovered to the water tank 90 through the filter 70 is about 57 ° C. When the water is mixed with the existing water stored in the water tank 90 The water stored in the water tank 90 can be maintained at about 30 ° C to 40 ° C. Therefore, the water stored in the reservoir 30 is preferably 60 DEG C or less.

At this time, the filter 70 may be a vertical cylinder type. The filter 70 is a drainage step for draining the water inside the filter 70 to clean the filter 70, a stirring step for stirring the air inside the filter 70, a filter 70 A backwash process may be performed through the backwashing step for cleaning the filter 70 and the air phase for supplying water into the filter 70.

The filter 70 may be a manual backwash process as well as an automatic backwash process. The filter 70 may be provided with a water quality analyzer (not shown). The water quality analyzer measures the amount of the suspended matter in the filter 70 It is possible to present the working standards of the backwash process. The backwash water backwashed by the filter 70 can be supplied to the sewage treatment facility.

On the other hand, the cooling pipe 23 can supply the cooling water to the drain pipe 25 considering the temperature of the water stored in the storage tank 30 so as to recycle the water discharged from the blowdown tank 20 sooner.

That is, when it is determined that it takes a long time to cool the water stored in the storage tank 30 through the fan 31, the distributor 40, and the like and recycle the water, the blow- The cooling water is supplied to the drain pipe 25 so that the water supplied to the storage tank 30 can be supplied to the storage tank 30 in a cooled state to some extent.

The blowdown system may further include a sewer pipe (29). The sewage pipe 29 refers to a pipe which is bypassed at the drain pipe 25 and connected to the sewage treatment facility.

When the water level of the storage tank 30 is equal to or higher than the reference water level, the water supplied to the storage tank 30 can be bypassed to the sewage pipe 29 and sewage-treated. The reference water level refers to the limit water level of the predetermined storage tank 30 determined that no further water can be stored in the storage tank 30.

The drain pipe 25 is provided with a drain valve 26 and the drain pipe 29 may be provided with a drain valve 28. The drainage valve 26 is closed and the drainage valve 28 is opened so that the water in the drainage pipe 25 can be immediately sewage-treated in the drainage pipe 25, The drain valve 26 is opened and the drain valve 28 is closed so that the water drained to the drain pipe 25 can be stored in the storage tank 30. [

As described above, when the blowdown system according to the first embodiment of the present invention is used, the amount of water that has been conventionally drained from the boiler to the blowdown tank and has been sewage-treated can be greatly reduced, thereby reducing the sewage treatment cost.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

20: Blowdown tank
21: drain pipe
22: first temperature measuring device
23: cooling pipe
25: Water pipe
26: Drain valve
28: Recovery valve
29: Recovery pipe
30: Storage tank
31: Fans
33: air injection nozzle
35: Distribution pump
40: Dispenser
41: Piping
42: Nozzle
43: heat sink
50: temporary processing unit
55: collection pipe
56: Return pump
70: Filter
90: Water tank

Claims (14)

A blowdown tank in which water and steam drained from the boiler are stored for normal operation of the boiler;
A drain pipe connected to a lower portion of the blowdown tank and discharging water stored in the blowdown tank to the outside of the blowdown tank; And
And a cooling pipe connected to the drain pipe and through which the cooling water supplied to the drain pipe flows to lower the temperature of the water drained through the drain pipe. The method according to claim 1,
Wherein the cooling tube is connected to the drain pipe at a location spaced apart from the bottom of the blowdown tank by two to thirty times the diameter of the cooling tube. The method according to claim 1,
Further comprising: a first temperature measuring device for measuring a temperature of water drained through the drain pipe and water mixed with the cooling water,
Wherein the cooling pipe is opened and closed based on a temperature measured by the first temperature measuring device. The method of claim 3,
Further comprising a drain pump provided in the drain pipe so as to be spaced apart from the blowdown tank at a position where the cooling water is supplied from the drain pipe and to drain the water stored in the blowdown tank to the drain pipe,
Wherein the first temperature measurement device measures the inlet side temperature of the drain pump between the mixing position and the drain pump. The method of claim 4,
Wherein the temperature measuring device is provided at a position separated by 1 m or more from the mixing position. The method according to claim 1,
Wherein the cooling pipe is opened when water and steam drained into the blowdown tank from the boiler cause a rise in temperature of water drained through the drain pipe and even if water and steam are drained from the boiler to the blowdown tank, The blowdown system does not open unless the temperature of the water drained through the drain pipe rises. The method according to claim 1,
Further comprising a temporary processing unit for temporarily processing the water drained through the drain pipe,
Wherein the temporary treatment section includes a reservoir for storing water drained through the drain pipe, at least a part of which is provided in the basement and the upper side is opened. The method of claim 7,
Wherein the temporary processing unit includes a plurality of air injection nozzles provided at a lower portion of the storage tank for injecting air into the water stored in the storage tank,
The bubbles generated by the air being injected into the water stored in the storage tank expand the area of the water stored in the storage tank in contact with the air, thereby lowering the temperature of the water stored in the storage tank. The method of claim 7,
The temporary treatment unit may further include a dispensing pump for recovering the water stored in the reservoir and a dispenser for receiving the water recovered from the dispensing pump and injecting the recovered water into the reservoir,
Wherein the water injected from the distributor exchanges heat with the atmosphere and is stored again in the reservoir after the temperature is lowered so that the temperature of the water stored in the reservoir is lowered. The method of claim 9,
Wherein the dispenser comprises a pipe through which the water recovered in the reservoir flows and a plurality of nozzles which receive water through the pipe and then inject into the reservoir again. The method of claim 10,
Wherein the distributor further comprises a plurality of heat sinks formed on an outer periphery of the pipe,
Wherein the heat sinks promote the heat exchange between the pipe and the atmosphere to reduce the temperature of the water flowing through the pipe. The method of claim 7,
A water tank for collecting and storing water in the storage tank for recycling the water stored in the storage tank, a recovery pipe connecting the storage tank and the water tank, and a foreign matter contained in the water recovered in the storage tank, Further comprising a filter to filter the blowdown system. The method of claim 12,
Wherein the filter blocks water stored in the reservoir from being collected from the reservoir into the reservoir tank if the temperature of water stored in the reservoir is above a reference temperature. The method of claim 7,
Further comprising a sewage pipe bypassed from the drain pipe and connected to a sewage treatment facility,
Wherein the water supplied to the storage tank is bypassed to the sewage pipe and sewage-treated when the water level of the storage tank is equal to or higher than the reference water level.

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