KR20130001433A - Waste heat boiler separated exhaust gas chamber - Google Patents

Abstract

PURPOSE: A waste boiler with a separated exhaust gas chamber is provided to receives exhaust gas discharged from a power plant system even though a part of the power plant system is stopped, thereby continuously maintaining the operation of the waste boiler. CONSTITUTION: A waste boiler with a separated exhaust gas chamber comprises a body(10), an exhaust gas inlet chamber(30), an exhaust gas inlet pipe(40), an exhaust gas outlet chamber(50), and an exhaust gas outlet pipe(60). A plurality of tubes in which exhaust gas flows is horizontally arranged in the body and water is charged in the inside of the body. The exhaust gas inlet chamber is a structure of three or more exhaust gas inflow spaces and assembled in one side of the body. An end portion of the exhaust gas inlet pipe is connected to each entrance of the exhaust gas inflow spaces and the other end portion of the exhaust gas inlet pipe is connected to an exhaust gas discharging unit. The exhaust gas outlet chamber is a structure of three or more exhaust gas outflow spaces and assembled in the other side of the body. The exhaust gas outlet pipe is mounted in each entrance of the exhaust gas outflow spaces.

Description

Waste heat boiler separated exhaust gas chamber

The present invention relates to an exhaust gas chamber separated waste heat boiler, and more particularly, an exhaust gas inlet chamber and an exhaust chamber separated into a plurality of spaces are assembled at both sides of the waste heat boiler body to accommodate all the exhaust gases of the plurality of power generation system. An exhaust gas chamber separated waste heat boiler is provided.

In general, power generation facilities are being constructed in various forms using thermal power, hydropower, solar power, nuclear power, etc. These power generation facilities are desulfurization equipment, denitrification equipment, electrostatic precipitating equipment, which remove various pollutants generated in power plants and industrial plants, Waste heat recovery boilers are being constructed through various processes ranging from design to equipment production, installation and commissioning.

In recent years, a large number of power generation facilities have been constructed in overseas markets of developing countries, most of them are being constructed as power generation facilities using combined cycle power, and are being installed including waste heat recovery boilers capable of recovering waste heat.

The thermal power plant of the power generation facility is equipped with a waste heat recovery boiler and a gas turbine to recover the gas turbine and waste heat to produce steam, the gas turbine is a high-temperature, high-pressure combustion gas generated by the combustion of fuel The turbine is rotated, and the combustion gas that rotates the turbine is discharged to the outside of the gas turbine.

The waste heat recovery boiler is a kind of power generation boiler that produces steam, using the combustion gas (exhaust gas of high temperature) discharged to the outside to make the water steam, using the generated steam (for example, engine heating device, Gas turbines for power generation equipment).

In this way, the power generation system generates high-temperature waste combustion gas as it burns fuel and drives gas turbines to generate electric power. The waste heat is recovered from the waste heat recovery boiler to use the combustion gas again, and the recovered waste heat is recovered. The water can be converted into steam of high temperature and high pressure, and the steam turbine can be driven again to obtain power.

However, the waste heat recovery boilers installed in the conventional power generation facilities have the following problems as one is installed for each power generation system.

In other words, the exhaust gas duct of one power generation system is connected to the combustion gas inlet side of one waste heat recovery boiler, and thus it is not possible to continuously produce steam during sudden shutdown of the power generation system or maintenance and repair of the waste heat recovery boiler. There is this.

In other words, when several power generation systems are installed in one place, one waste heat recovery boiler is included in each power generation system, so that the steam generator fails or there is continuous steam during maintenance of the waste heat recovery boiler. There was a problem that can not produce.

In addition, as the waste heat recovery boiler is connected and installed in each of the power generation system, there is a problem that productivity and installation cost are not increased due to an increase in construction installation cost and labor cost.

The present invention has been made in view of the above problems, the waste heat recovery boiler so that the exhaust gas discharge ducts from a number (two to five) of the power generation system can be connected to one waste heat recovery boiler at once. By dividing the exhaust gas inlet and the chamber and the exhaust gas outlet and the chamber into two to five, an object of the present invention is to provide an exhaust gas chamber separate waste heat boiler which enables continuous steam generation even when each power generation system is stopped.

The present invention for achieving the above object is a plurality of tubes in which the exhaust gas flow is arranged horizontally, the boiler body is filled with water; An exhaust gas inlet chamber having a structure divided into three or more exhaust gas inlet spaces by three or more dividing walls and assembled to one side of the boiler body; Three or more exhaust gas inlet pipes having one end connected to an inlet of each exhaust gas inlet space of the exhaust gas inlet chamber and the other end connected to an exhaust gas outlet of each power generation facility; An exhaust gas outlet chamber having a structure divided into three or more exhaust gas outlet spaces by three or more dividing walls, and assembled to the other side of the boiler body; It provides an exhaust gas chamber separated waste heat boiler comprising: three or more exhaust gas outlet pipes mounted to the inlet of each exhaust gas outlet space of the exhaust gas outlet chamber.

In the present invention, the exhaust gas inlet chamber is divided into three by three partition walls, the first exhaust gas inlet space located on the upper side, the second exhaust gas inlet space located on the front side, and the third exhaust gas located on the rear side The exhaust gas inlet pipe includes a first exhaust gas inlet pipe vertically connected to an upper portion of the first exhaust gas inlet space, and a second exhaust gas inlet pipe horizontally connected to the front side of the second exhaust gas inlet space. And a third exhaust gas inlet pipe horizontally connected to the rear side of the third exhaust gas inlet space.

Preferably, the first exhaust gas inlet space, the second exhaust gas inlet space of the exhaust gas inlet chamber, and the outer wall surface of the third exhaust gas inlet space is characterized in that the opening and closing door having an inspection window is mounted.

In the present invention, the exhaust gas outlet chamber is divided into three by three partition walls, the first exhaust gas outlet space located on the upper side, the second exhaust gas outlet space located on the front side and the third exhaust gas located on the rear side The exhaust gas outlet pipe includes a first exhaust gas outlet pipe vertically connected to an upper portion of the first exhaust gas outlet space, and a second exhaust gas outlet pipe horizontally connected to the front side of the second exhaust gas outlet space. And a third exhaust gas outlet pipe connected horizontally to the rear side of the third exhaust gas outlet space.

Preferably, the first and second exhaust gas outlet space, the second exhaust gas outlet space and the third exhaust gas outlet space of the exhaust gas outlet chamber is characterized in that the opening and closing door having a check window is mounted.

In particular, one end of the tube protrudes through one side wall of the boiler body and is exposed in each exhaust gas inlet chamber, and the other end of the tube also protrudes through the other side wall of the boiler body and is exposed in each exhaust gas outlet chamber. It features.

The present invention provides the following effects through the above-mentioned problem solving means.

First, the combustion gas inlet and outlet of the waste heat recovery boiler are separated into two to five spaces, and each separated space is connected to the exhaust gas outlets of the various power generation systems, so that the rest of the power generation system is stopped even if the power generation system is stopped. It is possible to continuously maintain the operation of the waste heat recovery boiler while accommodating the exhaust gas discharged from the facility system, thereby enabling continuous steam generation supply.

Second, by installing each component of the waste heat recovery boiler system, that is, the combustion gas inlet and outlet, the boiler body, the water supply and recovery, the steam supply and recovery in a structure manufactured in the manufacturing plant in advance, The workability and productivity of the boiler installation can be greatly improved.

1 is a plan view showing an exhaust gas chamber separated waste heat boiler according to the present invention.
Figure 2 is a front view showing a waste gas boiler separate type waste heat boiler according to the present invention.
3a and 3b is a right side cross-sectional view and a left cross-sectional view showing an exhaust gas chamber separated waste heat boiler according to the present invention.
Figure 4 is a side view showing the opening and closing doors of the waste gas chamber separated waste heat boiler according to the present invention.

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

The present invention connects several power generation system to one waste heat recovery boiler to accommodate the high temperature exhaust gas discharged from each power generation system in one waste heat recovery boiler to continuously operate the waste heat recovery boiler for steaming. The focus is on one point so that it can be maintained.

1 and 2, the waste heat recovery boiler of the present invention includes a boiler body 10, an exhaust gas inlet chamber 30 and an exhaust gas outlet chamber 50 mounted on both sides thereof. do.

The boiler body 10 has a sealed space filled with water, but the upper space in which the water is not filled becomes a space filled with steam.

In particular, the inside of the boiler body 10 is arranged a plurality of tubes 20 through which the high-temperature exhaust gas flows for heat exchange with water, each tube 20 as shown in Figure 3a and 3b attached Both ends of the) protrude through the side wall 19 of the boiler body 10 is exposed to the exhaust gas inlet chamber 30 and the exhaust gas outlet chamber 50, respectively.

On the other hand, the upper and front surfaces of the boiler body 10, the main steam valve 12 for discharging steam to the place of use, the safety valve 13 for discharging the steam pressure for safety when the steam is above the reference pressure, and Pressure switch valve 14 and pressure gauge 15 for regulating pressure in boiler body 10, air vent valve 16 for air discharge, and level gauge 17 for measuring the water level in boiler body 10. ), And a water supply valve 18 for supplying water into the boiler body 10.

The exhaust gas inlet chamber 30 is integrally assembled and mounted on one side of the boiler body 10, and is provided in a structure divided into three or more exhaust gas inlet spaces 34 by three or more partition walls 32. do.

Preferably, the exhaust gas inlet chamber 30 is a space divided into three by the three partition walls 32, that is, the first exhaust gas inlet space 34a located above and the second exhaust gas located in the front side. The inlet space 34b and the third exhaust gas inlet space 34c positioned on the rear side are integrally assembled to one side of the boiler body 10.

Accordingly, one end of each tube 20 arranged horizontally in the boiler body 10 protrudes through one side wall 19 of the boiler body 10, so that some of the tubes 20 receive exhaust gas. Exposed to the first exhaust gas inlet space (34a) so that the other part of the tube 20 is also exposed to the second exhaust gas inlet space (34b) to accommodate the exhaust gas, and another part of the tube ( 20 is also exposed to the third exhaust gas inlet space (34c) to accommodate the exhaust gas.

In particular, each inlet of the first, second, and third exhaust gas inlet spaces 34a, 34b, and 34c constituting the exhaust gas inlet chamber 30 is integrally mounted with the exhaust gas inlet pipe 40, respectively. The exhaust gas inlet pipe 40 is connected in communication with each exhaust gas discharge part (not shown) of various power generation facilities.

In more detail, the exhaust gas inlet pipe 40 includes a first exhaust gas inlet pipe 40a vertically connected to an upper portion of the first exhaust gas inlet space 34a and a second exhaust gas inlet space 34b. The second exhaust gas inlet pipe 40b connected horizontally to the front side, and the third exhaust gas inlet pipe 40c connected horizontally to the rear side of the third exhaust gas inlet space 34c, the first exhaust gas inlet pipe 40a, the second exhaust gas inlet pipe 40b, and the third exhaust gas inlet pipe 40c are connected in communication with each of the exhaust gas outlets (not shown) of different power generation facilities.

At this time, as shown in Figure 4, the first exhaust gas inlet space 34a, the second exhaust gas inlet space 34b of the exhaust gas inlet chamber 30, and the third exhaust gas inlet space ( On the outer side wall surface of 34c), an opening / closing door 70 having an inspection window 72 is mounted as a means for observing the flow state of the exhaust gas and for internal maintenance and cleaning.

The exhaust gas outlet chamber 50 is integrally assembled and mounted on the other side of the boiler body 10 and is provided in a structure divided into three or more exhaust gas outlet spaces 54 by three or more partition walls 32. do.

Preferably, the exhaust gas outlet chamber 50 is a space divided into three by the three partition walls 32, that is, the first exhaust gas outlet space 54a located above and the second exhaust gas located on the front side. It consists of an outlet space 54b and the 3rd exhaust gas outlet space 54c located in the back side, and is integrally assembled and mounted in the other side of the boiler body 10. As shown in FIG.

Accordingly, the other end of each tube 20 arranged horizontally in the boiler body 10 protrudes through the other side wall 19 of the boiler body 10, so that some of the tubes 20 discharge exhaust gas. So that the first exhaust gas outlet space 54a is exposed, and the other part of the tube 20 is exposed to the second exhaust gas outlet space 54b so as to discharge the exhaust gas, and the other part of the tube ( 20 is also exposed to the third exhaust gas outlet space 54c to discharge the exhaust gas.

In particular, each inlet of the first, second, and third exhaust gas outlet spaces 54a, 54b, and 54c constituting the exhaust gas outlet chamber 50 is integrally mounted with an exhaust gas outlet pipe 60. The exhaust gas outlet pipe 60 is in a state of communicating with the outside air.

In more detail, the exhaust gas outlet pipe 60 includes a first exhaust gas outlet pipe 60a vertically connected to an upper portion of the first exhaust gas outlet space 54a and a second exhaust gas outlet space 54b. The second exhaust gas outlet pipe 60b connected horizontally to the front side, and the third exhaust gas outlet pipe 60c connected horizontally to the rear side of the third exhaust gas outlet space 54c, the first exhaust gas outlet pipe Both the 60a, the second exhaust gas outlet pipe 60b, and the third exhaust gas outlet pipe 60c are in communication with the outside air.

Similarly, the exhaust gas flows on the outer sidewalls of the first exhaust gas outlet space 54a, the second exhaust gas outlet space 54b and the third exhaust gas outlet space 54c of the exhaust gas outlet chamber 50. An opening / closing door 70 having an inspection window 72 is mounted as a means for observing a state and performing internal maintenance and cleaning.

Here, the operation of the waste gas chamber separate type waste heat boiler having the above configuration will be described.

At the same time, the power plant gas turbine is rotated by the high temperature and high pressure combustion gas generated by the combustion of the fuel, and the high temperature combustion gas rotating the turbine is the exhaust gas inlet pipe 40. Is supplied.

If the three power generation system is operated, the exhaust gas discharged from the first power generation system is supplied to the first exhaust gas inlet pipe 40a, and the exhaust gas discharged from the second power generation system is discharged from the second exhaust system. It is supplied to the gas inlet pipe 40b, and the exhaust gas discharged from the third power generation system is supplied to the third exhaust gas inlet pipe 40c.

Subsequently, the exhaust gas supplied to each of the exhaust gas inflow pipes 40 flows into the exhaust gas inflow chamber 30.

That is, the exhaust gas flows from the first exhaust gas inlet pipe 40a to the first exhaust gas inlet space 34a of the exhaust gas inlet chamber 30 and at the same time from the second exhaust gas inlet pipe 40b. 30 flows into the second exhaust gas inflow space 34b and from the third exhaust gas inflow pipe 40c to the third exhaust gas inflow space 34c of the exhaust gas inflow chamber 30.

Subsequently, the exhaust gas flowed independently through the first exhaust gas inflow space 34a, the second exhaust gas inflow space 34b, and the third exhaust gas inflow space 34c, that is, the three power generation systems, respectively. The exhaust gas flows along the inside of each tube 20 arranged in the boiler body 10.

At this time, since the high-temperature exhaust gas flows inside each of the tubes 20, heat is transferred to the water filled in the boiler body 10, that is, the water located at the outer diameter of the tube 20. The steamed and steamed steam is collected in the upper space (steam chamber) of the boiler body 10 and then sent to the place of use through the main steam valve 12 mounted on the upper surface of the boiler body 10.

If any one of the three power generation system is in operation and the exhaust gas is not supplied to the first exhaust gas inlet pipe 40a due to a failure of the power generation system, the exhaust gas discharged from the other two power generation system is discharged. Since the water can be steamed by being accommodated in the second exhaust gas inlet pipe 40b and the third exhaust gas inlet pipe 40c, it is possible to continuously maintain the operation of the waste heat recovery boiler and continuously produce steam at the same time. .

On the other hand, the exhaust gas exiting the heat exchange after passing through the tube 20 is the first exhaust gas outlet space (54a) of the exhaust gas outlet chamber 50 and the first exhaust gas outlet pipe (60a) connected thereto, and the second The exhaust gas outlet space 54b and the second exhaust gas outlet pipe 60b connected thereto and the third exhaust gas outlet space 54c and the third exhaust gas outlet pipe 60c connected thereto are all discharged to outside air.

10: boiler body 12: main steam valve
13: safety valve 14: pressure switch valve
15 pressure gauge 16: air vent valve
17: level gauge 18: water supply valve
19: side wall 20: tube
30: exhaust gas inlet chamber 32: partition wall
34: exhaust gas inlet space 34a: first exhaust gas inlet space
34b: 2nd exhaust gas inflow space 34c: 3rd exhaust gas inflow space
40: exhaust gas inlet pipe 40a: first exhaust gas inlet pipe
40b: second exhaust gas inlet pipe 40c: third exhaust gas inlet pipe
50 exhaust gas outlet chamber 52 partition wall
54 exhaust gas outlet space 54a: first exhaust gas outlet space
54b: second exhaust gas outlet space 54c: third exhaust gas outlet space
60: exhaust gas outlet pipe 60a: first exhaust gas outlet pipe
60b: second exhaust gas outlet pipe 60c: third exhaust gas outlet pipe
70: opening and closing door 72; Inspection window

Claims (6)

A plurality of tubes 20 in which exhaust gas flows are arranged horizontally, and a boiler body 10 filled with water;
An exhaust gas inlet chamber 30 having a structure divided into three or more exhaust gas inlet spaces 34 by three or more partition walls 32 and assembled to one side of the boiler body 10;
Three or more exhaust gas inlet pipes 40 having one end connected to an inlet of each exhaust gas inlet space 34 of the exhaust gas inlet chamber 30 and the other end connected to an exhaust gas outlet of each power generation facility;
An exhaust gas outlet chamber 50 having a structure divided into three or more exhaust gas outlet spaces 54 by three or more dividing walls 52 and assembled to the other side of the boiler body 10;
And three or more exhaust gas outlet pipes (60) mounted at the inlet of each exhaust gas outlet space (54) of the exhaust gas outlet chamber (50).
The method according to claim 1,
The exhaust gas inlet chamber 30 is divided into three by the three partition walls 32, the first exhaust gas inlet space (34a) located on the upper side, the second exhaust gas inlet space (34b) located on the front side and It is composed of a third exhaust gas inlet space (34c) located on the rear side;
The exhaust gas inlet pipe 40 is connected to the first exhaust gas inlet pipe 40a vertically connected to the upper portion of the first exhaust gas inlet space 34a and horizontally connected to the front side of the second exhaust gas inlet space 34b. The second exhaust gas inlet pipe (40b), and the third exhaust gas inlet pipe (40c) horizontally connected to the rear side of the third exhaust gas inlet space (34c) separated waste heat chamber characterized in that the boiler.
The method according to claim 2,
An inspection window 72 is provided on an outer wall surface of the first exhaust gas inflow space 34a, the second exhaust gas inflow space 34b and the third exhaust gas inflow space 34c of the exhaust gas inflow chamber 30. Waste gas chamber separated type waste heat boiler, characterized in that the opening and closing door having a 70.
The method according to claim 1,
The exhaust gas outlet chamber 50 includes a first exhaust gas outlet space 54a positioned upwardly and divided into three portions by three partition walls 52, and a second exhaust gas outlet space 54b positioned forwardly. A third exhaust gas outlet space 54c positioned at a rear side thereof;
The exhaust gas outlet pipe 60 is horizontally connected to the front side of the first exhaust gas outlet pipe 60a and the second exhaust gas outlet space 54b vertically connected to the upper portion of the first exhaust gas outlet space 54a. The second exhaust gas outlet pipe (60b), and the third exhaust gas outlet pipe (60c) horizontally connected to the rear side of the third exhaust gas outlet space (54c) separated waste heat chamber characterized in that the boiler.
The method of claim 4,
An inspection window 72 is also provided on the outer wall surface of the first exhaust gas outlet space 54a, the second exhaust gas outlet space 54b and the third exhaust gas outlet space 54c of the exhaust gas outlet chamber 50. Waste gas chamber separated type waste heat boiler, characterized in that the opening and closing door having a 70.
The method according to claim 1,
One end of the tube 20 protrudes through one side wall 19 of the boiler body 10 and is exposed in each exhaust gas inlet chamber 30, and the other end of the tube 20 is also the boiler body 10. The exhaust gas chamber separated type waste heat boiler, characterized in that protrudes through the other side wall (19) of the) and is exposed in each exhaust gas outlet chamber (50).

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