KR102014493B1 - Cooling system for incinerator - Google Patents

Abstract

The present invention relates to a cooling system for an incinerator, which prevents a refractory forming a wall of an incinerator from being worn out or falling by being deteriorated by heat generated in the incinerator by cooling the wall of the incinerator. The present invention includes: an upper water jacket (100) installed on an upper portion of an incinerator (10); a side water jacket (200) installed on a side portion of the incinerator (10); a cooling water supply line (300) connected to one side of the upper water jacket and the side water jacket (200); a cooling water collecting line (400) connected to the other side of the upper water jacket (100) and the side water jacket (200); a cooling water tank (500) to which the cooling water supply line (300) and the cooling water collecting line (400) are connected; a supply pump (600) pumping the cooling water; an overflow pipe (700) through which the overflowed cooling water is discharged; an underground tank (800) in which the cooling water flowing through the overflow pipe (700) is filled; a supplementing pipe (900) connected to the underground tank (800); a supplementing tank (1000) to which the supplementing pipe (900) is connected; a supplementing pump (1100) pumping the cooling water; a water supply pipe (1200) connected to the cooling water tank (500) in the supplementing tank (1000); a water supply pump (1300) pumping the cooling water; and a control unit (1400) controlling the supply pump (600), the supplementing pump (1100) and the water supply pump (1300).

Description

Incinerator cooling system {Cooling system for incinerator}

The present invention relates to a cooling system for incinerators which can prevent a phenomenon in which the refractory constituting the walls of the incinerator are deteriorated due to the heat generated in the incinerator by cooling the walls of the incinerator, thereby preventing wear or dropping out.

As a by-product of continuous industrial development, various wastes are generated in large quantities. As a result, waste disposal issues are actively discussed.

In connection with the disposal of such wastes, in the past, wastes were buried or discharged to the sea. However, in accordance with the international trend of strictly prohibiting landfilling and discharge of wastes, domestic wastes are treated by incineration instead of landfilling.

Hereinafter, an incinerator for incineration of waste will be described.

As shown in FIG. 1, the incinerator 10 includes a hopper 11 through which waste 20 is supplied, an inlet 12 formed under the hopper 11, into which waste 20 is introduced, and an inlet ( A first combustion chamber 13 formed at the rear end of 12) to incinerate waste, a grate portion 14 installed in the first combustion chamber 13 in multiple stages to transfer waste, and an upper portion of the first combustion chamber 13; And a discharge port 16 formed at the rear end of the second combustion chamber 15 and the first combustion chamber 13 for burning the exhaust gas discharged from the first combustion chamber 13 to discharge the incineration ash.

In this state, the grate section 14 is divided into a drying stage 14a, a combustion stage 14b, and a post-combustion stage 14c. In general, the temperature of the drying stage 14a for removing water from waste is highest. Is formed.

Therefore, the upper wall U and the side wall of the incinerator 10 in which the drying stage 14a is located are inevitably exposed to high-temperature combustion gas and flame, so that the refractory constituting the upper wall U and the side wall is deteriorated and worn out. There was a problem that frequently occurs or fall out phenomenon.

In the background of the present invention, Korean Patent Office 10-1316202 has been registered on October 01, 2013.

The present invention provides a cooling system for incinerators which can prevent a phenomenon in which the refractory constituting the wall of the incinerator is deteriorated due to heat generated by the incinerator by cooling the walls of the incinerator.

Cooling system for an incinerator according to an embodiment of the present invention, the upper water jacket 100 is installed on the top of the incinerator 10 and the inner space is formed and the cooling water is filled, and installed on the side of the incinerator 10 and the inside A side water jacket 200 in which a space is formed to fill the cooling water, and a cooling water supply line 300 connected to one side of the upper water jacket 100 and the side water jacket 200 to supply the cooling water, and an upper water jacket Cooling water supply line 400 is connected to the other side of each of the 100 and the side water jacket 200 to recover the cooling water, and the cooling water supplied by the cooling water supply line 300 and the cooling water recovery line 400 are connected to the cooling water supply line. Cooling water tank 500 is supplied to the cooling water and the cooling water recovered through the cooling water recovery line 400 and the cooling water supply line 300 is installed in the cooling water supply line 300, the cooling water filled in the cooling water supply line (300) Coolant to be supplied through The supply pipe 600 to be pumped, the overflow pipe 700 is connected to the coolant tank 500, the overflow of the coolant is discharged, and the overflow pipe 700 is connected to the underground and the overflow pipe 700 Underground tank 800 through which the coolant flowing through the filled water, the supplemental pipe 900 connected to the underground tank 800 through which the coolant flows, and the supplemental pipe 900 connected to the fill water through Replenishment pump 1100 and the replenishment pipe 900 is installed in the replenishment pipe 900 to pump the cooling water of the underground tank 800 to be supplied to the replenishment tank 1000, the coolant tank 500 in the replenishment tank 1000 A water supply pipe 1200 connected to the cooling water and a water supply pipe 1200 installed in the water supply pipe 1200 to pump the cooling water of the supplement tank 1000 to the cooling water tank 500, and a supply pump 600. Replenishment pump 1100, characterized in that it comprises a control unit 1400 for controlling the feed water pump 1300 All.

Preferably, the overflow tube 700 is formed with a bent portion 710 in which a portion exposed in the air is zigzag bent to increase the contact area of the air, and is located between the bent portions 710 bent in zigzag. Air guide plate 720 for guiding the movement of the air is characterized in that it is installed.

Preferably, the coolant tank 500 is provided with a first water level sensor 510 for measuring the high and low water levels of the coolant, and the supplement tank 1000 has a second water level sensor 1010 for measuring the high and low water levels of the coolant. Is provided, the control unit 1400 is a water level recognition unit 1410 and a water level recognition unit 1410 for recognizing the high and low water level detected by each of the first water level measurement sensor 510 and the second water level measurement sensor 1010 When the first water level sensor 510 detects the high water level, the water supply pump 1300 is stopped and the water level recognition unit 1410 recognizes that the first water level sensor 510 detects the low water level. When the water supply pump 1300 is operated and the second water level sensor 1010 recognizes that the second water level sensor 1010 detects the high water level, the supplementary pump 1100 is stopped and the water level recognition unit 1410 operates. When the second water level sensor 1010 recognizes that the low water level is detected, the pump for operating the supplemental pump 1100 It characterized in that it comprises an operating unit (1420).

Preferably, the present invention is the additional coolant tank 1500, the cooling water is filled, the additional line 1600 connected to the cooling water supply line 300 in the additional cooling water tank 1500, the cooling water flows through, and the additional line 1600 Installed in the additional coolant tank 1500 includes an additional pump 1700 for pumping the coolant from the cooling water supply line 300, the pump operation unit 1420 is a water level recognition unit 1410 in the first water level measurement sensor ( Recognizing that the 510 detects the low water level, and recognizes that the second water level sensor 1010 detects the low water level in the water level recognition unit 1410, while stopping the supplemental pump 1100 and the water supply pump 1300 It is characterized in that it is set to operate the pump 1700.

Preferably, the present invention is a constant tank 1800 filled with a constant, a constant supply line 1810 connected to the cooling water supply line 300 in the constant tank 1810 to supply the constant, and a constant supply line 1810 And a constant valve 1900 for opening and closing the pump abnormality detection unit 2000 for detecting an abnormality of the supply pump 600, and the controller 1400 detects the abnormality in the pump abnormality detection unit 2000. Characterized in that 1900 controls the constant valve 1900 to open the constant supply line 1810.

The cooling system for an incinerator according to the present invention has the advantage of preventing the phenomenon in which the refractory constituting the wall of the incinerator is deteriorated due to the heat generated in the incinerator by cooling the wall of the incinerator, thereby preventing wear or dropping out.

1 is a view showing a general incinerator.
2 is a view showing an incinerator to which a cooling system for an incinerator is applied according to an embodiment of the present invention.
Figure 3 schematically shows the overall configuration of the present invention.
4 is a view showing the main parts of the present invention.
5 is a view showing another main part of the present invention.
6 is a block diagram showing a control unit of the present invention.

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

2 to 6, the incinerator cooling system of the present invention, the upper water jacket 100, the side water jacket 200, the cooling water supply line 300, the cooling water recovery line 400 and , Cooling water tank 500, supply pump 600, overflow pipe 700, underground tank 800, replenishment pipe 900, replenishment tank 1000, replenishment pump 1100 and , A water supply pipe 1200, a water supply pump 1300, and a controller 1400.

First, the cooling water may be composed of water that is heat exchanged by the high temperature generated in the incinerator 10.

The upper water jacket 100 is installed on the upper part of the incinerator 10 and the inner space is formed to fill the cooling water. Can be. Therefore, when the upper portion of the incinerator 10 is formed to be curved, the lower surface of the upper water jacket 100 is formed to be curved. As a result, the contact area can be increased to facilitate heat transfer.

Since the upper water jacket 100 has a coolant flowed into the lower part and discharged to the upper part, the high temperature generated in the upper part of the incinerator 10 is continuously cooled to prevent the refractory of the incinerator 10 from being worn or dropped. Can be.

Side water jacket 200 is installed on the side of the incinerator 10 and the inner space is formed to fill the cooling water, it may be formed in a shape corresponding to the side of the incinerator 10 to be in close contact with the side of the incinerator 10. have. Therefore, when the side surface of the incinerator 10 is formed in a plane, the side surface of the upper water jacket 100 is also formed in a plane. As a result, the contact area can be increased to facilitate heat transfer.

The side water jacket 200 is formed with the partition walls 210 spaced apart at regular intervals in the inner space, and the coolant inlet 220 through which the coolant flows into one side between the partition walls 210 is formed, and the partition wall 210 is formed. Cooling water outlet 230 through which the coolant is discharged to the other side is formed.

Here, the cooling water inlet 220 is formed in the lower portion of the side water jacket 200, the cooling water discharge port 230 is preferably formed in the upper portion of the side water jacket (200). Therefore, since the cooling water is supplied to the lower portion of the side water jacket 200, the filled cooling water may be discharged to the upper portion of the side water jacket 200 after sufficient heat exchange.

Therefore, the side water jacket 200 may be firmly maintained while the deformation is minimized by the partition walls 210. As a result, deformation of the side water jacket 200 may be minimized due to the high heat transmitted through the side of the incinerator 10.

Since the coolant inlet 220 and the coolant outlet 230 are formed between the partition walls 210, the coolant may be uniformly provided to the side water jacket 200. As a result, as the cooling water is provided to the side water jacket 200 as a whole, the side of the incinerator 10 may be cooled evenly as a whole.

Accordingly, the side water jackets 200 may cool the high temperature generated at both sides of the incinerator 10, thereby preventing the refractory of the incinerator 10 from being deteriorated and worn or dropped.

As described above, the upper water jacket 100 and the side water jacket 200 may be provided with a steam outlet (not shown) through which steam generated from the heated cooling water is discharged. Therefore, damage to the upper water jacket 100 and the side water jacket 200 due to excessive steam pressure can be prevented.

The cooling water supply line 300 is connected to the cooling water tank 500 at one side of each of the upper water jacket 100 and the side water jacket 200 to supply the cooling water, and includes a plurality of pipes. Therefore, the cooling water supply line 300 guides the cooling water supplied from the cooling water tank 500 to the upper water jacket 100 and the side water jacket 200.

The cooling water recovery line 400 is connected to the cooling water tank 500 at the other side of each of the upper water jacket 100 and the side water jacket 200 to recover the cooling water, and is composed of a plurality of pipes. Therefore, the coolant drained from the upper water jacket 100 and the side water jacket 200 is guided to the cooling water tank 500.

The cooling water tank 500 supplies the cooling water filled by the cooling water supply line 300 and the cooling water recovery line 400 to the cooling water supply line 300 and filled with the cooling water recovered through the cooling water recovery line 400.

In this way, the coolant is supplied to the upper water jacket 100 and the side water jacket 200 through the cooling water supply line 300 from the cooling water tank 500 and then heat exchanged, and then the cooling water tank 500 through the cooling water recovery line 400. ) Is recovered. Therefore, the cooling water is circulated to prevent overheating of the incinerator 10.

The supply pump 600 is installed in the cooling water supply line 300 to pump the cooling water such that the cooling water filled in the cooling water tank 500 is supplied through the cooling water supply line 300. Therefore, the cooling water recovery line 400 after the cooling water is guided to the upper water jacket 100 and the side water jacket 200 through the cooling water supply line 300 by the pumping of the supply pump 600. Through it is recovered to the cooling water tank 500 again.

The overflow pipe 700 is connected to the coolant tank 500 to discharge the coolant that overflows. As such, the overflow pipe 700 is connected to the upper portion in the cooling water tank 500 may overflow the coolant. As the high temperature coolant is discharged, the coolant tank 500 can be prevented from being damaged while the circulation of the coolant can be easily performed.

In addition, the overflow pipe 700 may have a bent portion 710 in which a portion exposed in the air is bent in a zigzag manner so that the contact area of the air is increased. The cooling water flowing through the air in the state in which the bent portion 710 is exposed in the air may be cooled by air cooling. In this case, the bent portion 710 may be formed to a diameter smaller than the overflow tube 700. As a result, the coolant flowing through the bent portion 710 may be cooled faster than the coolant flowing through the overflow pipe 700.

In addition, the air guide plate 720 may be installed between the bent portion 710 bent in a zigzag to guide the movement of air. The air moved from the outside by the air guide plate 720 may be guided to the bent portion 710, so that the cooling water flowing through the bent portion 710 may be rapidly cooled. Here, a blowing fan 730 may be provided to forcibly provide wind to the bent portion 710. At this time, the air guide plate 720 may be made of a metal plate can be quickly cooled by the blowing fan 730 or the air supplied from the outside to guide the cold air to the bent portion 710.

Furthermore, the air guide plate 720 may be configured in plural and each end thereof may be connected by the connecting plate 721. By using the connecting plate 721, the plurality of air guide plates 720 may be conveniently transported or replaced at once.

Underground tank 800 is filled with the coolant flowing through the overflow pipe 700 is buried underground while the overflow pipe 700 is connected. The underground tank 800 is buried underground so that high temperature coolant can be cooled by underground cold air.

In addition, the underground tank 800 may have a heat dissipation part 810 formed outside to increase the heat dissipation area. Therefore, the heat dissipation unit 810 may be composed of a plurality of fins, it is possible to quickly cool the cooling water filled in the underground tank 800.

Replenishment pipe 900 is connected to the underground tank 800 may be configured as a pipe through which the cooling water flows.

Such, the supplementary tube 900 is a portion of the underground bent portion 910 is bent in a zigzag form. Therefore, since the heat dissipation area is increased by the underground bent portion 910, the coolant flowing through the underground bent portion 910 may be rapidly cooled by the cold air in the basement. At this time, the underground bent portion 910 is formed with a smaller diameter than the supplemental tube 900, the cooling of the cooling water can be accelerated than the supplementary tube (900).

The replenishment tank 1000 is filled with the cooling water flowing through the replenishment pipe 900 is connected.

The replenishment pump 1100 is installed in the replenishment pipe 900 to pump the cooling water of the underground tank 800 to the replenishment tank 1000.

The water supply pipe 1200 is connected to the cooling water tank 500 in the replenishment tank 1000 to allow the cooling water to flow through.

The water supply pump 1300 is installed in the water supply pipe 1200 to pump the cooling water of the replenishment tank 1000 to the cooling water tank 500.

The controller 1400 controls the supply pump 600, the supplemental pump 1100, and the feed water pump 1300.

Hereinafter, the operation of the present invention will be described.

First, when the control unit 1400 operates the supply pump 600 while the incinerator 10 is operated, the coolant is supplied to the upper water jacket 100 and the side water jacket from the cooling water tank 500 through the cooling water supply line 300. Supplied to 200. In addition, the supplied cooling water is heat-exchanged by the high temperature generated in the incinerator 10 while being filled in the upper water jacket 100 and the side water jacket 200 to prevent heating of the incinerator 10. The heated coolant is guided through the coolant recovery line 400 and recovered to the coolant tank 500.

When the high temperature coolant recovered by the coolant tank 500 overflows, the coolant tank 500 may be discharged through the overflow pipe 700 and filled in the underground tank 800. Then, the overflowed coolant may be cooled in a state filled in the underground tank 800 buried underground.

Cooling water filled in the underground tank 800 may be flown through the refill pipe 900 by pumping the refill pump 1100 to be filled in the refill tank 1000.

When the cooling water is insufficient in the cooling water tank 500, as the water supply pump 1300 is pumped, the cooling water filled in the supplement tank 1000 may flow through the water supply pipe 1200 to fill the cooling water tank 500.

In addition, another embodiment to be applied to the present invention will be described.

The coolant tank 500 is provided with a first water level sensor 510 for measuring the high and low water levels of the coolant. The first water level sensor 510 may be configured of a plurality of sensors spaced up and down. That is, the upper sensor measures the high level and the lower sensor measures the low level.

The replenishment tank 1000 is provided with a second water level sensor 1010 for measuring the high and low water levels of the cooling water. The second water level measurement sensor 1010 may be configured in the same manner as the first water level measurement sensor 510.

The controller 1400 may include a water level recognition unit 1410 for recognizing high and low water levels detected by the first water level sensor 510 and the second water level sensor 1010, and a first water level at the water level recognition unit 1410. The water supply pump 1300 stops the water supply pump 1300 when it recognizes that the measurement sensor 510 detects the high water level, and the water supply pump 1300 when the water level recognition unit 1410 recognizes that the first water level measurement sensor 510 detects the low water level. When the second water level sensor 1010 recognizes that the second water level sensor 1010 detects the high water level, the supplementary pump 1100 is stopped and the second water level sensor 1410 detects the second water level sensor. Recognizing that the 1010 senses the low water level includes a pump operation unit 1420 for operating the refill pump 1100.

Therefore, the coolant is supplied from the replenishment tank 1000 to the coolant tank 500 only when the coolant tank 500 is at a low water level. In addition, the coolant is supplied from the underground tank 800 to the replenishment tank 1000 only when the replenishment tank 1000 has a low water level. As a result, the cooling water tank 500 and the replenishment tank 1000 may always be filled with the appropriate amount of cooling water.

In addition, the present invention is connected to the additional coolant tank 1500, the cooling water is filled, the additional line 1600 connected to the cooling water supply line 300 in the additional cooling water tank 1500, the cooling water flows through, and the additional line 1600 It is installed includes an additional pump 1700 for pumping the coolant from the additional coolant tank 1500 to the coolant supply line 300.

The additional pump 1700 is controlled by the controller 1400.

In addition, the pump operation unit 1420 recognizes that the first water level sensor 510 detects the low water level in the water level recognition unit 1410, and the second water level sensor 1010 in the water level recognition unit 1410 detects the low water level. Recognizing that it is detected, it is set to operate the additional pump 1700 while stopping the supplemental pump 1100 and feed water pump 1300.

Therefore, when the additional pump 1700 is operated while the cooling water tank 500 lacks the cooling water, the cooling water is supplied from the additional cooling water tank 1500 to the cooling water supply line 300.

On the other hand, the present invention is a constant tank 1800 is filled with constant, constant water supply line (1810) and a constant water supply line (1810) connected to the cooling water supply line 300 in the constant water tank (1810) to supply the constant It includes a constant valve 1900 for opening and closing, and a pump abnormality detecting unit 2000 for detecting an abnormality of the supply pump 600.

The water tank 1800 is always filled with constant water supplied through the water pipe. In addition, the water tank 1800 is installed at a position higher than the cooling water supply line 300 and the cooling water tank 500.

The water supply line 1810 may be configured as a pipe connected to the cooling water supply line 300 in the water tank 1800 in a standing state.

The constant valve 1900 may be configured as a solenoid valve remotely controlled by the controller 1400. Therefore, when the constant valve 1900 is opened, the constant of the constant tank 1800 may be supplied to the cooling water supply line 300 while descending through the constant supply line 1810.

The pump abnormality detecting unit 2000 may include a sensor for detecting an abnormality of the operation of the supply pump 600 and a sensor for detecting an abnormality of the power applied to the supply pump 600. That is, the pump abnormality detection unit 2000 detects a malfunction, an overvoltage, and an overcurrent of the supply pump 600.

The controller 1400 controls the constant valve 1900 such that the constant valve 1900 opens the constant supply line 1810 when the pump abnormality detector 2000 detects an abnormality.

Therefore, when the supply pump 600 is abnormal and the cooling water supply is stopped, the controller 1400 opens the constant valve 1900, so that the constant water supplied through the constant supply line 1810 is supplied through the cooling water supply line 300. The upper water jacket 100 and the side water jacket 200 may be supplied.

As a result, since the constant water is immediately supplied even when the supply of the cooling water is stopped, damage to the incinerator 10 due to high heat can be prevented.

As such, the coolant provided from the additional coolant tank 1500 may be recovered to the coolant tank 500 after being supplied to the upper water jacket 100 and the side water jacket 200 through the coolant supply line 300. That is, since the coolant supplied from the additional coolant tank 1500 is supplied, insufficient coolant may be replenished.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

10: incinerator 100: upper water jacket
200: side water jacket 300: cooling water supply line
400: cooling water recovery line 500: cooling water tank
510: first water level sensor 600: supply pump
700: overflow pipe 710: bend
720: air information board 730: blowing fan
800: underground tank 900: supplement pipe
1000: Supplement tank 1010: Second level sensor
1100: supplemental pump 1200: water supply pipe
1300: water supply pump 1400: control unit
1410: water level recognition unit 1420: pump operation unit
1500: additional coolant tank 1600: additional line
1700: additional pump 1800: water tank
1810: water supply line 1900: water supply valve
2000: Pump error detection part

Claims (5)

An upper water jacket 100 installed at an upper portion of the incinerator 10 and having an internal space formed therein, and having a coolant filled therein;
Side water jacket 200 is installed on the side of the incinerator 10 and the inner space is formed to fill the cooling water,
A cooling water supply line 300 connected to one side of each of the upper water jacket 100 and the side water jacket 200 to supply the cooling water;
A cooling water recovery line 400 connected to the other side of the upper water jacket 100 and the side water jacket 200 to recover the cooling water;
A cooling water tank 500 in which the cooling water supply line 300 and the cooling water recovery line 400 are connected to supply the cooling water filled to the cooling water supply line 300, and the cooling water recovered through the cooling water recovery line 400 is filled;
A supply pump 600 installed in the cooling water supply line 300 to pump the cooling water so that the cooling water filled in the cooling water tank 500 is supplied through the cooling water supply line 300;
An overflow pipe 700 connected to the coolant tank 500 to discharge the coolant overflowed;
Underground tank 800 is filled with the cooling water flowing through the overflow pipe 700 is buried underground while the overflow pipe 700 is connected,
Replenishment pipe (900) connected to the underground tank (800) through which cooling water flows,
Replenishment tank (1000) is connected to the replenishment pipe 900 is filled with the cooling water flowing through,
A replenishment pump 1100 installed in the replenishment pipe 900 and pumping the cooling water of the underground tank 800 to be supplied to the replenishment tank 1000;
A water supply pipe 1200 connected to the cooling water tank 500 in the replenishment tank 1000, through which the cooling water flows;
A water supply pump 1300 installed in the water supply pipe 1200 and pumping the cooling water of the supplement tank 1000 to be supplied to the cooling water tank 500;
Cooling system for an incinerator, characterized in that it comprises a control unit (1400) for controlling the supply pump (600), replenishment pump (1100), feed water pump (1300).
The method according to claim 1,
The overflow pipe 700 is formed with a bent portion 710 in which a portion exposed in the air is bent in a zigzag to increase the contact area of the air,
Cooling system for an incinerator, characterized in that the air guide plate 720 is located between the bent portion 710 is zigzag bent to guide the movement of the air.
The method according to claim 1,
Cooling water tank 500 is provided with a first level sensor 510 for measuring the high and low water level of the coolant,
Replenishment tank 1000 is provided with a second water level sensor 1010 for measuring the high and low water level of the coolant,
The controller 1400 is
A level recognition unit 1410 for recognizing high and low water levels detected by each of the first water level sensor 510 and the second water level sensor 1010,
When the water level recognition unit 1410 recognizes that the first water level sensor 510 detects the high water level, the water supply pump 1300 is stopped, and the water level recognition unit 1410 detects the low water level. When the water level pump 1300 is recognized, the second water level sensor 1010 recognizes that the second water level sensor 1010 detects the high water level. Then, the supplemental pump 1100 is stopped and the water level is recognized. Cooling system for an incinerator, characterized in that it comprises a pump operating unit (1420) for operating the supplementary pump (1100) when it recognizes the second water level sensor 1010 detects the low water level in the unit (1410).
The method according to claim 3,
An additional coolant tank 1500 filled with coolant,
An additional line 1600 connected to the cooling water supply line 300 in the additional cooling water tank 1500, through which cooling water flows,
Installed in the additional line 1600 and includes an additional pump 1700 for pumping the coolant from the additional coolant tank 1500 to the coolant supply line 300,
The pump operation unit 1420 recognizes that the first water level measurement sensor 510 detects the low water level in the water level recognition unit 1410, and the second water level measurement sensor 1010 detects the low water level in the water level recognition unit 1410. Recognizing that the cooling system for an incinerator is set to operate the additional pump (1700) while stopping the supplemental pump (1100) and feed water pump (1300).
The method according to claim 1,
A constant tank (1800) filled with constants,
A water supply line 1810 connected to the cooling water supply line 300 in the water supply tank 1810 for supplying water,
A constant valve 1900 for opening and closing the constant supply line 1810,
It includes a pump abnormality detection unit 2000 for detecting an abnormality of the supply pump 600,
When the controller 1400 detects an abnormality in the pump abnormality sensing unit 2000, the water supply valve 1900 controls the constant valve 1900 to open the constant supply line 1810.

Images