KR20240067724A - Evaporation piping structure of vertical heat recovery steam generator and heat recovery steam generator including same - Google Patents

Abstract

The present invention relates to an evaporation piping structure of a vertical waste heat recovery boiler and a waste heat recovery boiler including the same. More specifically, it relates to an evaporation piping structure of a vertical waste heat recovery boiler including a backflow prevention device and a waste heat recovery boiler including the same. It's about.
The evaporation piping structure of the vertical waste heat recovery boiler according to the present invention and the waste heat recovery boiler including the same include a backflow prevention device, and can prevent reverse circulation of steam from occurring during initial startup.

Description

Evaporation piping structure of vertical heat recovery steam generator and heat recovery steam generator including same}

The present invention relates to an evaporation piping structure of a vertical waste heat recovery boiler and a waste heat recovery boiler including the same. More specifically, it relates to an evaporation piping structure of a vertical waste heat recovery boiler including a backflow prevention device and a waste heat recovery boiler including the same. It's about.

Combined cycle power generation is a power generation method that combines primary and secondary power generation facilities. In general, combined cycle power plants burn fuel inside a gas turbine to create high-temperature combustion gas, use this combustion gas to turn the gas turbine to generate primary power, and use the heat of the exhaust gas discharged during the primary power generation to produce high-temperature combustion gas. A steam turbine is driven by high-pressure steam to generate secondary power. This combined cycle power plant has high energy use efficiency by first using the combustion heat of the fuel in the gas turbine and reusing it in the heat recovery boiler, and has the advantage of shortening the time from starting operation to producing electricity. Additionally, it is environmentally friendly as it can use clean fuel.

The heat of the exhaust gas to produce high-temperature and high-pressure steam can be recovered by a heat recovery steam generator (HRSG), a type of heat exchange device.

Waste heat recovery boilers can be largely divided into horizontal and vertical types depending on the direction of exhaust gas flow. The horizontal method is a method in which the exhaust gas flows in a horizontal direction, and the vertical method is a method in which the exhaust gas flows in a vertical direction. The vertical method has the advantage of having a smaller installation area than the horizontal method.

In addition, waste heat recovery boilers can be largely divided into natural circulation and forced circulation types depending on the circulation method inside the boiler. The natural circulation method is a method in which the circulation of water or steam inside the boiler is formed by density difference and does not require a separate circulation pump. Unlike the natural circulation method, the forced circulation method is a method that is equipped with a separate circulation pump to circulate water or steam inside the boiler.

The internal evaporation piping of a vertical type waste heat recovery boiler may be provided in the form of horizontal pipes stacked in the vertical direction. This vertical waste heat recovery boiler has a problem in that steam generated in the horizontal pipe can flow in both directions during initial startup, which may cause reverse circulation of steam.

Based on the above technical background, the evaporation piping structure of the vertical waste heat recovery boiler according to the present invention and the waste heat recovery boiler including the same can prevent reverse steam circulation phenomenon from occurring during initial startup.

The evaporation piping structure of the vertical waste heat recovery boiler according to the embodiment of the present invention includes an upper drum, a downpipe, an evaporation pipe, a multiplier pipe, and a backflow prevention device. . The upper drum holds water and steam. The water pipe is connected to the upper drum, and water is supplied from the upper drum. In the evaporation pipe, water flowing in through the water pipe exchanges heat with the main gas flow and evaporates. The multiplier pipe is connected between the upper drum and the evaporation pipe, and supplies water and steam from the evaporation pipe to the upper drum. The backflow prevention device is connected between the downfall pipe and the evaporation pipe. At least a portion of the backflow prevention device is disposed at a position lower than the lowest end of the evaporation pipe.

Additionally, the backflow prevention device includes a bent portion, and the bent portion is connected between the down-water pipe and the inlet header of the evaporation pipe, and at least a portion of the bent portion may be disposed at a lower position than the inlet header.

Additionally, the bent portion may be formed in a U-shape.

Additionally, the bent portion may be formed in a P-type shape.

Additionally, the bent portion may be formed in a circular shape.

Additionally, the backflow prevention device may include a lower drum in which water can be temporarily stored.

Additionally, the height of the precipitation pipe and the height of the evaporation pipe may be higher than the height of the bottom of the lower drum.

Additionally, the part where the water pipe is connected to the lower drum may be placed at a lower position than the part where the evaporation pipe is connected to the lower drum.

A vertical waste heat recovery boiler according to an embodiment of the present invention includes a casing, a duct, and an evaporation piping structure. The casing forms the outline. The duct connects the casing and the gas turbine, and main gas is supplied from the gas turbine. The evaporation piping structure is placed inside the casing. The evaporation piping structure consists of an upper drum in which water and steam are received, a downpipe connected to the upper drum and through which water is supplied from the upper drum, an evaporation pipe in which the water flowing in through the downpipe is evaporated by heat exchange with the main gas flow, and the upper part. It includes a multiplier pipe connected between the drum and the evaporation pipe and supplying water and steam from the evaporation pipe to the upper drum, and a backflow prevention device connected between the downfall pipe and the evaporation pipe, wherein at least a portion of the backflow prevention device is evaporated. It is placed lower than the bottom of the pipe.

Additionally, the backflow prevention device includes a bent portion, and the bent portion is connected between the down-water pipe and the inlet header of the evaporation pipe, and at least a portion of the bent portion may be disposed at a lower position than the inlet header.

Additionally, the bent portion may be formed in a U-shape.

Additionally, the bent portion may be formed in a P-type shape.

Additionally, the bent portion may be formed in a circular shape.

Additionally, the backflow prevention device may include a lower drum in which water can be temporarily stored.

Additionally, the height of the precipitation pipe and the height of the evaporation pipe may be higher than the height of the bottom of the lower drum.

Additionally, the part where the water pipe is connected to the lower drum may be placed at a lower position than the part where the evaporation pipe is connected to the lower drum.

The evaporation piping structure of the vertical waste heat recovery boiler according to the present invention and the waste heat recovery boiler including the same include a backflow prevention device, and can prevent reverse circulation of steam from occurring during initial startup.

Figure 1 is a schematic diagram showing a part of a combined cycle power generation system to which the vertical waste heat recovery boiler according to the present invention is applied.
Figure 2 is a conceptual diagram showing a cut-away vertical waste heat recovery boiler according to the present invention.
Figure 3 is a conceptual diagram showing the evaporation piping structure of a waste heat recovery boiler with a U-shaped bend according to the first embodiment of the present invention.
Figure 4 is a conceptual diagram showing the evaporation piping structure of a waste heat recovery boiler with a P-shaped bend according to the first embodiment of the present invention.
Figure 5 is a conceptual diagram showing the evaporation piping structure of a waste heat recovery boiler with a circular bend according to the first embodiment of the present invention.
Figure 6 is a conceptual diagram showing the evaporation piping structure of a waste heat recovery boiler with a lower drum according to the second embodiment of the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be exemplified and explained in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all transformations, equivalents, and substitutes included in the spirit and technical scope of the present invention.

The terms used in the present invention are only used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In the present invention, terms such as 'include' or 'have' are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. At this time, note that in the attached drawings, like components are indicated by the same symbols whenever possible. Additionally, detailed descriptions of well-known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some components are exaggerated, omitted, or schematically shown in the accompanying drawings.

Figure 1 is a schematic diagram showing a part of a combined cycle power generation system to which the vertical waste heat recovery boiler according to the present invention is applied, and Figure 2 is a conceptual diagram showing a cut-away vertical waste heat recovery boiler according to the present invention.

Hereinafter, with reference to FIGS. 1 and 2, the evaporation piping structure of the vertical waste heat recovery boiler according to an embodiment of the present invention and the overall process of the combined cycle power generation cycle to which the waste heat recovery boiler including the same is applied, and the vertical waste heat recovery boiler This is explained in detail. The combined cycle power generation cycle includes a gas turbine (100), a steam turbine (200), a condenser (300), and a waste heat recovery boiler (1000).

In the gas turbine 100, fuel and air are mixed and then combusted, and the power generated by combustion drives a generator connected to the gas turbine 100. Steam is supplied from the steam turbine 200. Steam supplied to the steam turbine 200 provides driving force to a generator connected to the steam turbine 200, thereby driving the generator. In the steam turbine 200, steam provides power to drive a generator and is then supplied to the condenser 300. In the condenser 300, the vapor is cooled and converted into condensate. In the condenser 300, steam may be cooled by a cooling means such as externally supplied cooling water and converted into condensate.

A waste heat recovery boiler 1000 is disposed between the gas turbine 100 and the steam turbine 200. Exhaust gas discharged from the gas turbine 100 is supplied to the waste heat recovery boiler 1000, and water, which is condensate or feed water supplied from the condenser 300, is also supplied. In the waste heat recovery boiler 1000, exhaust gas and water exchange heat with each other. The water supplied to the waste heat recovery boiler (1000) is heated by hot exhaust gas and evaporated into steam. The steam generated by evaporation in the waste heat recovery boiler (1000) is supplied to the steam turbine (200). Here, the steam generated in the waste heat recovery boiler 1000 may be superheated by additionally passing through a superheater before being supplied to the steam turbine 200.

The waste heat recovery boiler 1000 according to an embodiment of the present invention is a vertical waste heat recovery boiler 1000. The vertical waste heat recovery boiler 1000 is a waste heat recovery boiler 1000 in which the flow direction of the main gas flow (MF) is vertical. The waste heat recovery boiler 1000 according to an embodiment of the present invention includes a casing 1100, an upper drum 1200, a downpipe 1300, an evaporation pipe 1400, a multiplier pipe 1500, and a backflow prevention device 1600. Includes.

The casing 1100 forms the external shape of the waste heat recovery boiler 1000. The casing 1100 may be formed to extend long in the vertical direction. A duct 1110 connecting the casing 1100 and the gas turbine 100 may be disposed on the lower side of the casing 1100. The main gas flow (MF) of the gas turbine 100 is supplied through the duct 1110, and the cross-sectional area of the duct 1110 may be expanded along the flow direction of the main gas flow (MF). In the duct 1110, the main gas flow (MF) may flow in the horizontal direction and then switch to the vertical direction. Meanwhile, a stack 1120 may be placed on the upper side of the casing 1100.

An evaporation piping structure is disposed in the casing 1100. The evaporation piping structure refers to a structure that includes the upper drum 1200, downpipe 1300, evaporation pipe 1400, multiplier pipe 1500, and backflow prevention device 1600, excluding the casing 1100.

A line through which water is supplied from the condenser 300 is connected to the upper drum 1200, and a line through which steam is discharged to be supplied toward the steam turbine 200 or to the superheater before being supplied to the steam turbine 200 is connected. A water pipe 1300 and a multiplier pipe 1500 are connected to the upper drum 1200, and an evaporation pipe 1400 is connected between the water pipe 1300 and the multiplier pipe 1500. Liquid water stored in the upper drum 1200 moves downward through the downpipe 1300 and is supplied to the evaporation pipe 1400.

The evaporation pipe 1400 is disposed inside the casing 1100. The evaporation pipe 1400 may be formed as a zigzag-shaped pipe structure that is bent a plurality of times, and each pipe may be formed to extend in the horizontal direction except for the bent portion. That is, the evaporation pipe 1400 may be a once-through type evaporation pipe 1400 formed horizontally.

The main gas flow (MF) passes through the evaporation pipe 1400 disposed inside the casing 1100. As the main gas flow (MF) passes through the evaporation pipe 1400, it exchanges heat with the water flowing inside the evaporation pipe 1400, and in this process, at least some of the water flowing inside the evaporation pipe 1400 is It evaporates and turns into vapor. An inlet header 1410 is disposed at the inlet portion of the evaporation pipe 1400, and an outlet header 1420 is disposed at the outlet portion of the evaporation pipe 1400. Water flows in from the inlet header 1410, and water flows out from the outlet header 1420.

The outlet header 1420 and the upper drum 1200 may be connected by a multiplier pipe 1500. In the multiplier pipe 1500, steam and water can rise and move. Steam and water that passed through the multiplier pipe (1500) are returned to the upper drum (1200). Among the steam and water recovered to the upper drum 1200 through the multiplier pipe 1500, steam may be discharged toward the steam turbine 200 or a superheater. And, the remaining water can be supplied back to the downpipe 1300. In this way, in the waste heat recovery boiler 1000 according to an embodiment of the present invention, water or steam flows through the upper drum 1200, the downpipe 1300, the evaporation pipe 1400, and the multiplier pipe 1500 due to the density difference. It circulates, and this method is called a natural circulation method.

A backflow prevention device 1600 is disposed in the evaporation piping structure according to an embodiment of the present invention. The backflow prevention device 1600 is connected between the precipitation pipe 1300 and the evaporation pipe 1400. The backflow prevention device 1600 may be connected between the downflow pipe 1300 and the inlet header 1410 of the evaporation pipe 1400. In the case of the vertical waste heat recovery boiler 1000, as discussed above, the piping structure of the evaporation pipe 1400 may be horizontally extended. In such a vertical waste heat recovery boiler (1000), during initial startup, water evaporates in the evaporation pipe (1400) and flows in both directions, which may cause a problem in which water or steam may flow back through the downfall pipe (1300). . The backflow prevention device 1600 is configured to prevent water or steam from flowing back through the downpipe 1300 during initial startup. At least a portion of the backflow prevention device 1600 is disposed at a position lower than the bottom of the evaporation pipe 1400. That is, at least a portion of the backflow prevention device 1600 may be placed at a lower position than the pipe disposed at the lowest end of the evaporation pipe 1400. In this case, since water accumulates in the backflow prevention device 1600, even if steam is generated in the evaporation pipe 1400 during initial startup, it does not pass through the backflow prevention device 1600 due to the density difference, and the backflow prevention device 1600 flows in the opposite direction.

Figure 3 is a conceptual diagram showing the evaporation piping structure of a waste heat recovery boiler having a U-shaped bend according to the first embodiment of the present invention, and Figure 4 is a conceptual diagram showing the evaporation piping structure of the waste heat recovery boiler having a P-shaped bend according to the first embodiment of the present invention. This is a conceptual diagram showing the evaporation piping structure, and Figure 5 is a conceptual diagram showing the evaporation piping structure of a waste heat recovery boiler with a circular bend according to the first embodiment of the present invention.

Hereinafter, with reference to FIGS. 3 to 5, the evaporation piping structure of the vertical waste heat recovery boiler according to the first embodiment of the present invention and the waste heat recovery boiler including the same will be described in detail. In the evaporation piping structure of the vertical waste heat recovery boiler according to the first embodiment of the present invention and the waste heat recovery boiler including the same, the backflow prevention device 1600 includes a bent portion 1610. The bent portion 1610 is formed in a curved shape between the inlet header 1410 of the downflow pipe 1300 and the evaporation pipe 1400 in the backflow prevention device 1600. At least a portion of the bent portion 1610 is disposed at a lower position than the inlet header 1410. Through this, it is possible to prevent water or steam from the evaporation pipe 1400 from flowing back into the precipitation pipe 1300.

The evaporation piping structure of the vertical waste heat recovery boiler according to the first embodiment of the present invention and the shape of the bent portion 1610 of the waste heat recovery boiler including the same can be formed in a U-shape, as shown in FIG. 3. there is. A U band may be applied to the bent portion 1610 formed in a U-shaped shape. The U-shaped bent portion 1610 may be formed to be convexly curved downward at the central portion between the rear end of the downpipe 1300 and the inlet header 1410.

The evaporation piping structure of the vertical waste heat recovery boiler according to the first embodiment of the present invention and the shape of the bent portion 1610 of the waste heat recovery boiler including the same can be formed in a P-type shape, as shown in FIG. 4. there is. The bent portion 1610 formed in a P-shaped shape is directly connected to the rear end of the downpipe 1300 and may be formed to be convexly curved downward.

The evaporation piping structure of the vertical waste heat recovery boiler according to the first embodiment of the present invention and the shape of the bent portion 1610 of the waste heat recovery boiler including the same are formed in a circular ring shape, as shown in FIG. 5. You can. The bent portion 1610 formed in a circular shape may be directly connected to the rear end of the downpipe 1300. In some cases, the portion formed by rotating the circular ring shape may be biased toward the evaporation pipe 1400 or in the opposite direction. When the bent portion 1610 is formed in a circular shape, the space occupied by the bent portion 1610 can be reduced.

Figure 6 is a conceptual diagram showing the evaporation piping structure of a waste heat recovery boiler with a lower drum according to the second embodiment of the present invention.

Hereinafter, with reference to FIG. 6, the evaporation piping structure of the vertical waste heat recovery boiler according to the second embodiment of the present invention and the waste heat recovery boiler including the same will be described in detail. The evaporation piping structure of the vertical waste heat recovery boiler according to the second embodiment of the present invention and the waste heat recovery boiler including the same differ from the second embodiment of the present invention in the backflow prevention device 1600. Hereinafter, for convenience of explanation, descriptions that overlap with the first embodiment of the present invention will be omitted.

The evaporation piping structure of the vertical waste heat recovery boiler according to the second embodiment of the present invention and the backflow prevention device 1600 of the waste heat recovery boiler including the same include a lower drum 1620. Water may temporarily accumulate and be stored in the lower drum 1620. A space in which water can be stored may be formed inside the lower drum 1620. One side of the lower drum 1620 may be connected to the downwater pipe 1300, and the other side may be connected to the inlet header 1410 of the evaporation pipe 1400. The bottom 1623 of the lower drum 1620 may be disposed at a lower position than the bottom of the evaporation pipe 1400 or the inlet header 1410. Additionally, the height of the precipitation pipe 1300 and the height of the evaporation pipe 1400 may be formed to be higher than the height of the bottom 1623 of the lower drum 1620. In this case, water may accumulate between the downfall pipe 1300 and the evaporation pipe 1400.

Additionally, the portion of the lower drum 1620 where the precipitation pipe 1300 is connected may be placed at a lower position than the portion of the lower drum 1620 where the evaporation pipe 1400 is connected. An upper connection part 1621 and a lower connection part 1622 may be formed in the lower drum 1620. A precipitation pipe 1300 and an evaporation pipe 1400 are connected to one side and the other side of the lower drum 1620, respectively. The part where the precipitation pipe 1300 is connected is the lower connection portion 1622, and the evaporation pipe 1400 is connected thereto. The part is the upper connection part 1621. The lower connection part 1622 may be disposed below the upper connection part 1621. Here, the bottom portion 1623 of the lower drum 1620 may be disposed lower than the lower connection portion 1622. In this case, even if steam flows in from the evaporation pipe 1400, the steam stays on the upper side of the lower drum 1620, and the water supplied from the downwater pipe 1300 or the already accumulated water is on the lower side of the lower drum 1620. As it becomes stagnant, it is possible to effectively prevent steam or water from flowing back from the evaporation pipe 1400 into the precipitation pipe 1300.

Although embodiments of the present invention have been described above, this is merely an example and the present invention is not limited thereto, and should be construed as having the widest scope following the basic ideas disclosed in this specification. A person skilled in the art may combine and substitute the disclosed embodiments to implement embodiments not specified, but this also does not deviate from the scope of the present invention. In addition, a person skilled in the art can easily change or modify the embodiments disclosed based on the present specification, and it is clear that such changes or modifications also fall within the scope of the present invention.

100: gas turbine
200: Steam turbine
300: condenser
1000: Waste heat recovery boiler
1100: Casing
1110: duct
1120: stack
1200: Upper drum
1300: River water pipe
1400: Evaporation pipe
1410: Entrance header
1420: Exit header
1500: Seungsu-gwan
1600: Backflow prevention device
1610: bend part
1620: Lower drum
1621: Upper connection part
1622: Lower connection part
1623: bottom part
MF: Main gas flow

Claims (16)

In the evaporation piping structure applied to the vertical waste heat recovery boiler,
an upper drum containing water and steam;
a water pipe connected to the upper drum and supplying water from the upper drum;
An evaporation pipe in which the water flowing in through the water pipe is evaporated by heat exchange with the main gas flow;
a multiplier pipe connected between the upper drum and the evaporation pipe and supplying water and steam from the evaporation pipe to the upper drum; and
It includes a backflow prevention device connected between the downfall pipe and the evaporation pipe,
The backflow prevention device,
An evaporation piping structure for a vertical waste heat recovery boiler in which at least a portion is disposed at a lower position than the lowest end of the evaporation piping.
According to claim 1,
The backflow prevention device includes a bent portion,
The bend part,
Connected between the precipitation pipe and the inlet header of the evaporation pipe,
An evaporation piping structure for a vertical waste heat recovery boiler in which at least a portion is disposed at a position lower than the inlet header.
According to clause 2,
The bend part,
Evaporation piping structure of a vertical waste heat recovery boiler formed in a U-shape.
According to clause 2,
The bend part,
Evaporation piping structure of a vertical waste heat recovery boiler formed in a P-shaped shape.
According to clause 2,
The bend part,
Evaporation piping structure of a vertical waste heat recovery boiler formed in a circular shape.
According to claim 1,
The backflow prevention device,
Evaporation piping structure of a vertical waste heat recovery boiler including a lower drum where water can be temporarily stored.
According to clause 6,
The height of the precipitation pipe and the height of the evaporation pipe,
Evaporation piping structure of a vertical waste heat recovery boiler higher than the height of the bottom of the lower drum.
According to clause 6,
The part where the water pipe is connected to the lower drum is,
An evaporation piping structure of a vertical waste heat recovery boiler disposed at a lower position than the portion where the evaporation piping is connected to the lower drum.
Casing forming the outline;
A duct connecting the casing and a gas turbine and supplying main gas from the gas turbine; and
Includes an evaporation piping structure disposed inside the casing,
The evaporation piping structure is,
an upper drum containing water and steam;
a water pipe connected to the upper drum and supplying water from the upper drum;
An evaporation pipe in which the water flowing in through the water pipe is evaporated by heat exchange with the main gas flow;
a multiplier pipe connected between the upper drum and the evaporation pipe and supplying water and steam from the evaporation pipe to the upper drum; and
It includes a backflow prevention device connected between the downfall pipe and the evaporation pipe,
The backflow prevention device,
A vertical waste heat recovery boiler in which at least a portion of the boiler is located lower than the bottom of the evaporation pipe.
According to clause 9,
The backflow prevention device includes a bent portion,
The bend part,
Connected between the precipitation pipe and the inlet header of the evaporation pipe,
A vertical waste heat recovery boiler in which at least a portion is located lower than the inlet header.
According to claim 10,
The bend part,
A vertical waste heat recovery boiler formed in a U-shape.
According to claim 10,
The bend part,
A vertical waste heat recovery boiler formed in a P-shaped shape.
According to claim 10,
The bend part,
A vertical waste heat recovery boiler formed in a circular shape.
According to clause 9,
The backflow prevention device,
A vertical waste heat recovery boiler that includes a lower drum where water can be temporarily stored.
According to claim 14,
The height of the precipitation pipe and the height of the evaporation pipe,
A vertical waste heat recovery boiler that is higher than the height of the bottom of the lower drum.
According to claim 14,
The part where the water pipe is connected to the lower drum is,
A vertical waste heat recovery boiler disposed at a lower position than the portion where the evaporation pipe is connected to the lower drum.

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