KR102256414B1 - Heat recovery boiler system - Google Patents

Abstract

The present invention is configured to supply high-temperature water heated by the first economizer and steam supplied from the outside to the deaerator, so that it is possible to stably supply high-temperature water in a certain temperature range to the deaerator at all times regardless of changes in the temperature of the exhaust gas. Because of this, the performance of the deaerator can be ensured. In addition, by guiding some of the water supply flowing through the water supply passage to the hot water supply passage according to the temperature of the hot water supplied to the deaerator, the temperature of the hot water supplied to the deaerator may be kept constant.

Description

Heat recovery boiler system

The present invention relates to a heat recovery boiler system, and more particularly, to a heat recovery boiler system capable of stably operating a deaerator and improving durability by supplying high temperature water in a certain temperature range to a deaerator. About.

In general, the heat recovery boiler system is a system that produces steam and hot water by passing high-temperature exhaust gas generated in a cooling facility of a sintering plant through a boiler.

A conventional heat recovery boiler system includes a dust collector for removing iron ore dust contained in exhaust gas discharged from the sintering plant, and a deaerator for removing oxygen and gas contained in water supplied to the boiler. Includes.

In the conventional deaerator, a method of degassing by raising water to a saturated temperature by introducing high-temperature steam produced in a boiler has been used.

However, since the high-temperature steam introduced into the deaerator is irregularly produced according to the temperature of the exhaust gas, there is a limit to stably operating the deaerator because the amount of steam introduced into the deaerator cannot be kept constant.

Korean Patent Publication No. 10-2008-0090359

An object of the present invention is to provide a heat recovery boiler system capable of stably operating a deaerator and improving durability.

An exhaust heat recovery boiler system according to the present invention includes a feed water pump; A first economizer connected to the feed water pump to heat the low-temperature demiwater pumped by the feed pump using high-temperature exhaust gas supplied from the outside, and discharge water to the high-temperature water in a first preset temperature range. Wow; It is connected to the first economizer and heats the high-temperature water supplied from the first economizer using high-temperature steam supplied from the outside to remove dissolved oxygen contained in the hot water, and is higher than the first set temperature range. A deaerator for discharging with high-temperature water within a set deaerator discharge temperature range; A water supply passage connecting the water supply pump and the first economizer to guide the water supply from the water supply pump to the first economizer; A hot water supply passage connecting the first economizer and the deaerator to guide the hot water from the first economizer to the deaerator; A hot water discharge passage connected to a lower portion of the deaerator to discharge hot water from which dissolved oxygen is removed from the deaerator; It is connected to the upper portion of the deaerator and includes a steam supply passage for supplying the high-temperature steam.

The present invention is configured to supply high-temperature water heated by the first economizer and steam supplied from the outside to the deaerator, so that it is possible to stably supply high-temperature water in a certain temperature range to the deaerator at all times regardless of changes in the temperature of the exhaust gas. Because of this, the performance of the deaerator can be ensured.

In addition, by guiding some of the water supply flowing through the water supply passage to the hot water supply passage according to the temperature of the hot water supplied to the deaerator, the temperature of the hot water supplied to the deaerator may be kept constant.

1 is a diagram schematically showing the configuration of a heat recovery boiler system according to a first embodiment of the present invention.
2 is a diagram schematically showing the configuration of a heat recovery boiler system according to a second embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings as follows.

1 is a diagram schematically showing the configuration of a heat recovery boiler system according to a first embodiment of the present invention.

Referring to FIG. 1, the heat recovery boiler system according to the first embodiment of the present invention includes a centrifugal dust collector 11, a superheater 20, an evaporator 30, a first economizer 41, and a second economizer 42. ), deaerator 50, water supply flow path 60, water supply pump 62, hot water supply flow path 70, hot water discharge flow path 71, hot water pump 72, steam supply flow path 51, A temperature sensor 74, a temperature control flow path 80, and a temperature control valve 82 are included.

In the heat recovery boiler system, the exhaust gas passes through the centrifugal dust collector 11, the superheater 20, the evaporator 30, the second economizer 42, and the first economizer 41 in turn. Heat exchange with water.

In the heat recovery boiler system, water is supplied with the feed water pump 62, the first economizer 41, the deaerator 50, the hot water storage tank 52, the hot water pump 72, and the second While passing through the economizer 42, the evaporator 30, and the superheater 20 in sequence, heat exchange with the exhaust gas is performed.

The centrifugal dust collector (Cyclone) 11 is a dust collecting means for removing dust from exhaust gas from a sintering plant or a power plant. A plurality of centrifugal dust collectors 11 are arranged in parallel, so that the amount of exhaust gas that can be processed at one time is increased and dust collection efficiency can be improved. In this embodiment, a total of nine centrifugal dust collectors 11 are arranged in three rows and three columns. The centrifugal dust collector 11 is formed of a high-Mn steel hopper to which the separated dust is dropped and collected, so that durability may be improved.

The superheater 20 is a heat exchanger for exchanging the exhaust gas from the centrifugal dust collector 11 and the steam from the evaporator 30. The superheater 20 generates superheated steam by heating the steam from the evaporator 30 again using a heat source of the exhaust gas. The superheated steam produced by the superheater 20 may be supplied to a steam turbine or the like. The superheater 20 is connected to a superheater supply passage 21 for receiving saturated steam from the evaporator 30 and a superheater discharge passage 22 for discharging the superheated steam to the outside or a steam turbine. .

The evaporator 30 is a heat exchanger that heat-exchanges the exhaust gas from the superheater 20 and hot water from the second economizer 42. The evaporator 30 generates saturated steam by heating hot water from the second economizer 42 using a heat source of the exhaust gas. The evaporator 30 includes an evaporator supply passage 31 for receiving the hot water from the second economizer 42, and an evaporator for discharging the saturated steam produced by the evaporator 30 to the superheater 20. The discharge passage 32 is connected. The evaporator discharge passage 32 is connected to the superheater supply passage 21.

The second economizer 42 is a heat exchanger that heat-exchanges the exhaust gas from the evaporator 30 and the hot water from the deaerator 50. The second economizer 42 is a high pressure economizer that heats the hot water pressurized by the hot water pump 72 from the deaerator 50. The second economizer 42 produces hot water in a second preset temperature range. Here, the second set temperature range is set higher than the first set temperature range described later.

Low-temperature demiwater pumped from the feed water pump 62 is directly introduced into the first economizer 41. The first economizer 41 is a heat exchanger for exchanging the water supply with high-temperature exhaust gas supplied from the outside. The first economizer 41 heats the low-temperature water supply by using the exhaust gas from the second economizer 42. The first economizer 41 generates and discharges hot water in a first preset temperature range. The first set temperature range is set to a range in which the temperature of the hot water flowing into the deaerator 50 can be maintained within a preset deaerator supply temperature range.

The deaerator 50 is connected to the first economizer 41 to heat the hot water heated by the first economizer 41 using high temperature steam, and is contained in the hot water. Remove dissolved oxygen. The high-temperature water supply passage 70 is connected to the deaerator 50 to receive high-temperature water from the first economizer 41 through the high-temperature water supply passage 70. In addition, the steam supply flow path 51 is connected to the deaerator 50 to receive high-temperature steam from the outside through the steam supply flow path 51. In this embodiment, the deaerator 50 is described as being supplied with high-temperature steam from the outside of the boiler system, but is not limited thereto, and among the steam emitted from the superheater 20 or the evaporator 30 Of course it is also possible to receive a partial supply.

The water supply flow path 60 is a flow path connecting the water supply pump 62 and the first economizer 41. The water supply passage 60 directly guides water supplied from the outside to the first economizer 41.

The water supply pump 62 is installed in the water supply passage 60 to pump the water supply.

The hot water supply passage 70 is a passage connecting the first economizer 41 and the deaerator 50. The hot water supply passage 70 guides the hot water heated by the first economizer 41 to the deaerator 50.

The high-temperature water discharge passage 71 is a passage connecting the high-temperature water storage tank 53 connected to the lower portion of the deaerator 50 and the second economizer 42. The hot water discharge passage 71 guides the hot water from which dissolved oxygen has been removed from the deaerator 50 to the second economizer 42.

The high-temperature water pump 72 is installed in the high-temperature water discharge passage 71 to pump and pressurize the high-temperature water from the deaerator 50.

The steam supply passage 51 is a passage connected to the upper portion of the deaerator 50 to supply high-temperature steam to the deaerator 50.

The temperature sensor 74 is installed in the hot water supply passage 70 and measures the temperature of the hot water supplied to the deaerator 50. The temperature sensor 74 is installed at a position close to the inlet side of the deaerator 50 in the hot water supply passage 70.

The temperature control passage 80 is a passage formed to connect the water supply passage 60 and the hot water supply passage 70. The temperature control flow path 80 guides some of the water supplied to the first economizer 41 through the water supply flow path 60 to the hot water supply flow path 70 to the deaerator 50. It is a flow path for adjusting the temperature of the supplied hot water to the temperature range of the deaerator supply.

The temperature control valve 82 is a valve that is installed in the temperature control flow path 80 and controls an opening degree according to the temperature measured by the temperature sensor 74. In the present embodiment, the temperature control valve 82 will be described as an example as a valve in which the opening degree is automatically controlled according to the temperature measured by the temperature sensor 74. However, the present invention is not limited thereto, and of course, a separate control unit for controlling the opening degree of the temperature control valve 82 may be provided.

The operation of the heat recovery boiler system according to the first embodiment of the present invention configured as described above will be described as follows.

Referring to FIG. 1, demiwater supplied from the outside is pumped by the water supply pump 62 and supplied to the first economizer 41.

The temperature of the feed water pumped by the feed water pump 62 is in the range of about 15°C to 20°C.

The water supplied to the first economizer 41 is heated through heat exchange with exhaust gas and discharged as hot water.

The temperature of the hot water heated and discharged from the first economizer 41 is within the first set temperature range. Here, the first set temperature range will be described as being the deaerator supply temperature range, and will be described as an example of about 90°C to 95°C.

The hot water discharged from the first economizer 41 is supplied to the deaerator 50.

At this time, the temperature sensor 74 measures the temperature of the hot water supplied to the deaerator 50.

The temperature control valve 82 adjusts the opening degree so that the temperature of the hot water measured by the temperature sensor 74 is within the range of the deaerator supply temperature.

For example, when the temperature of the hot water measured by the temperature sensor 74 increases, the temperature control valve 82 increases the opening degree, and the hot water supply flow path 70 through the temperature control flow path 80 ), it is possible to prevent in advance that the temperature of the hot water supplied to the deaerator 50 exceeds the range of the deaerator supply temperature.

In addition, when the temperature of the hot water measured by the temperature sensor 74 decreases, the temperature control valve 82 decreases the opening degree, so that the temperature control valve 82 passes through the temperature control flow path 80 to the hot water supply flow path 70. By reducing the amount of water introduced, the temperature of the hot water supplied to the deaerator 50 can be prevented from falling below the range of the deaerator supply temperature.

The temperature of the hot water supplied to the deaerator 50 by the temperature sensor 74 and the temperature control valve 82 may be stably maintained within the range of the deaerator supply temperature.

In the deaerator 50, the high-temperature water is heated by the high-temperature steam supplied through the steam supply passage 51, so that dissolved oxygen or other gases contained in the high-temperature water may be removed.

The high-temperature steam supplied through the steam supply passage 51 must be a condition in which the temperature of the hot water discharged from the deaerator 50 is within the range of the deaerator discharge temperature.

In this embodiment, since the temperature of the water supplied to the deaerator 50 is high in the range of about 90°C to 95°C and can be kept constant, the amount of high-temperature steam supplied through the steam supply flow path 51 Can be minimized.

That is, in the case of using a deaerator that is supplied with steam directly from an economizer in the related art, there is a problem in that the performance of the deaerator is deteriorated because the amount of steam produced by the economizer is irregular depending on the temperature of the exhaust gas.

However, in the present invention, even if the temperature of the exhaust gas is irregular, the temperature of the water supplied to the deaerator 50 can be kept constant, so that the deaerator 50 can always stably operate, and the deaerator 50 The temperature of the hot water discharged from 50 may also be maintained within the range of the deaerator discharge temperature.

When the deaerator 50 is stably operated, since the removal efficiency of dissolved oxygen is improved, the life of the facility may be improved.

The hot water from which the dissolved oxygen has been removed from the deaerator 50 is temporarily stored in the hot water storage tank 53 and then supplied to the second economizer 42 by the hot water pump 72.

The temperature of the hot water from the deaerator 50 is discharged within the range of the deaerator discharge temperature. Here, the exhaust temperature of the degassing device will be described as an example of about 110°C.

The high-temperature water discharged from the deaerator 50 is not circulated to the first economizer 41 and may be supplied entirely to the second economizer 42, so that the amount of steam produced by the boiler system can be improved.

2 is a diagram schematically showing the configuration of a heat recovery boiler system according to a second embodiment of the present invention.

Referring to FIG. 2, the heat recovery boiler system according to the second embodiment of the present invention supplies steam generated by at least one of the superheater 20 and the evaporator 30 to the deaerator 50. Since the first embodiment is different from the first embodiment, and the rest of the configuration and operation are similar to those of the first embodiment, a detailed description of the similar configuration will be omitted and different points will be mainly described.

A steam supply passage 101 for supplying steam is connected to the deaerator 50.

The steam supply passage 101 will be described as an example of supplying some of the steam from the evaporator 30 to the deaerator 50. That is, the steam supply passage 101 is a passage branched from the passage 100 connecting the evaporator discharge passage 32 and the superheater supply passage 21 and connected to the deaerator 50.

However, the present invention is not limited thereto, and the steam supply passage 101 may be connected to the superheater discharge rate 22 to supply steam from the superheater 20 to the deaerator 50.

A steam flow control valve 102 may be installed in the steam supply passage 101. The steam flow control valve 102 may control a flow rate of steam supplied to the deaerator 50. The steam flow rate control valve 102 may be opened according to the internal pressure of the deaerator 50.

As described above, in the second embodiment of the present invention, the water supply is directly supplied to the first economizer 41, so that the deaerator 50 has high temperature water in a certain temperature range heated by the first economizer 41. Since it is supplied, the operation of the deaerator 50 can be stably performed.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

11: dust collector 20: superheater
30: evaporator 41: first economizer
42: second economizer 50: deaerator
51: steam supply flow path 53; Hot water storage tank
60: water supply flow path 62: water pump
70: high-temperature water supply passage 71: high-temperature water discharge passage
72: hot water pump 74: temperature sensor
80: temperature control flow path 82: temperature control valve

Claims (9)

A feed pump;
A first economizer connected to the feed water pump to heat the low-temperature demiwater pumped from the feed pump using high-temperature exhaust gas supplied from the outside, and discharge water to the high-temperature water in the first preset temperature range. Wow;
It is connected to the first economizer and heats the high-temperature water supplied from the first economizer using high-temperature steam supplied from the outside to remove the dissolved oxygen contained in the hot water, and is higher than the first set temperature range. A deaerator for discharging with hot water within a set deaerator discharge temperature range;
A water supply passage connecting the water supply pump and the first economizer to guide the water supply from the water supply pump to the first economizer;
A hot water supply passage connecting the first economizer and the deaerator to guide the hot water from the first economizer to the deaerator;
A hot water discharge passage connected to a lower portion of the deaerator to discharge hot water from which dissolved oxygen has been removed from the deaerator;
A steam supply passage connected to an upper portion of the deaerator to supply the high-temperature steam;
A high-temperature water pump installed in the high-temperature water discharge passage;
It is connected to the high-temperature water discharge passage and heats the high-pressure high-temperature water pumped by the high-temperature water pump out of the deaerator using the exhaust gas to have a second set temperature range higher than the first set temperature range A second economizer for producing hot water;
An evaporator connected to the second economizer and heating the hot water from the second economizer using the exhaust gas to produce steam,
The steam supply flow path,
A heat recovery boiler system configured to connect the evaporator and the deaerator to supply some of the steam generated by the evaporator to the deaerator. The method according to claim 1,
A temperature sensor installed in the hot water supply flow path and measuring the temperature of the hot water supplied to the deaerator;
A temperature control passage formed to connect the water supply passage and the hot water supply passage to guide some of the water supply flowing through the water supply passage to the hot water supply passage,
Temperature control that is installed in the temperature control channel and controls the opening of the temperature control channel according to the temperature measured by the temperature sensor so that the temperature of the hot water supplied to the deaerator is maintained within a preset range of the deaerator supply temperature Heat recovery boiler system further comprising a valve. delete delete The method according to claim 1,
Further comprising a superheater connected to the evaporator to heat the steam emitted from the evaporator again using the exhaust gas to produce superheated steam,
The steam supply flow path,
An exhaust heat recovery boiler system formed to connect the superheater and the deaerator to supply some of the superheated steam generated by the superheater to the deaerator. The method according to claim 1 or 5,
An exhaust heat recovery boiler system further comprising a steam flow rate control valve installed in the steam supply passage and controlling a flow rate of the steam supplied to the deaerator. A feed pump;
A first economizer connected to the feed water pump to heat the low-temperature demiwater pumped from the feed pump using high-temperature exhaust gas supplied from the outside, and discharge water to the high-temperature water in the first preset temperature range. Wow;
It is connected to the first economizer and heats the high-temperature water supplied from the first economizer using high-temperature steam supplied from the outside to remove the dissolved oxygen contained in the hot water, and is higher than the first set temperature range. A deaerator for discharging with hot water within a set deaerator discharge temperature range;
A water supply passage connecting the water supply pump and the first economizer to guide the water supply from the water supply pump to the first economizer;
A hot water supply passage connecting the first economizer and the deaerator to guide the hot water from the first economizer to the deaerator;
A hot water discharge passage connected to a lower portion of the deaerator to discharge hot water from which dissolved oxygen has been removed from the deaerator;
A steam supply passage connected to an upper portion of the deaerator to supply the high-temperature steam;
A heat recovery boiler system including a high-temperature water storage tank installed in the high-temperature water discharge passage and temporarily storing the high-temperature water discharged from the deaerator. The method according to claim 1,
Further comprising a dust collecting means for removing dust (dust) of the exhaust gas,
The dust collecting means includes a plurality of centrifugal dust collectors. delete

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