KR101435368B1 - Apparatus for condensing steam in turbine power generation system - Google Patents

Abstract

The present invention relates to a steam condensing system for turbine of a thermal power generation, and comprises a cold water cyclone type condensing means which primarily condenses steam released from a steam turbine; and a cold water pipe type condensing means which secondarily condenses the steam being discharged from the cold water cyclone type condensing means. The present invention increases condensing efficiency of steam for the following reasons: the cold water cyclone type condensing means′ separation of steam from water using centrifugal force; and a freezing-condensing process for condensing steam using cold water which circulates a cold water jacket. By operating the second condensing process of the cold water pipe type condensing means together with the first condensing process of the cold water cyclone type condensing means, the condensing efficiency can be more enhanced.

Description

TECHNICAL FIELD [0001] The present invention relates to a steam condensing system for a turbine thermal power generation system,

The present invention relates to a steam condensing system of a turbine thermal power generation system, and more particularly, to a steam condensing system of a turbine thermal power generation system, which comprises a first condensation process comprising condensation by cooling and separation of steam and water by centrifugal force, The present invention relates to a steam condensing system of a turbine thermal power generation system capable of condensing steam more efficiently by performing secondary condensation processing.

Generally, in a hydroelectric power generation system, a hydraulic turbine is used to generate electricity by rotating a generator, and in a thermal power generation system and a nuclear power generation system, a steam turbine is used to rotate a generator to produce electricity.

The thermal power generation system and the nuclear power generation system are different from the fossil fuel (coal, oil, gas, or the like) as the raw material used for the thermal energy generating device that generates heat energy. There is a common point that a boiler for generating high-temperature and high-pressure steam is used and a steam turbine for rotating by high-temperature and high-pressure steam is used as a mechanical energy generating device.

FIG. 6 shows a steam condenser used in a turbine thermal power generation system according to an embodiment of the prior art.

The conventional steam condensing apparatus includes a boiler 1 for generating high temperature and high pressure steam, a steam turbine 2 rotated by high temperature and high pressure steam supplied from the boiler 1, A condenser 4 for cooling and condensing the steam discharged from the steam turbine 2, a cooling water for cooling the steam introduced into the condenser 4, (4), and the condenser (4) is provided with a plurality of tubes (4a) for cooling.

However, in the conventional steam condensing apparatus according to the related art, since the tube 4a through which the cooling water circulates is simply formed in the form of a coil, the contact area between the steam introduced into the condenser 4 and the tube 4a is insufficient, There is a problem that the efficiency is lowered.

In addition, another prior art apparatus for recovering and condensing condensed water of a steam pipe includes a main steam engine; A condensate collecting pipe connected to the main engine and separating the condensed water formed in the main engine from the main engine; A drain pocket for storing condensed water collected through the condensate collection pipe; A re-heater formed inside or outside the drain pocket; And a steam return pipe connected to the other end of the drain pocket for transferring the steam reheated by the reheater to the main engine, wherein the condensed water generated in the steam pipe is discharged to the outside during operation of the power generation system Quot; steam condensing water non-discharge recycling apparatus " is disclosed in Korean Patent Registration No. 10-1285880 (July 20, 2013).

However, the above-mentioned Korean Patent Registration No. 10-1285880 entitled " Condensate-free discharge recycling apparatus " of the present invention bypasses high-temperature and high-pressure steam transferred through a main engine to a drain pocket, reheats the steam, The condensed water can be recycled without discharging the condensed water to the outside. Therefore, there is a problem in that it can not function as a steam condensing system for condensing the discharged steam after operating the steam turbine.

The present invention also relates to a vapor condensing apparatus and method for increasing the efficiency of generation of steam by condensing the discharged steam after operating a turbine for power generation in a turbine power generation system, , The steam discharged from the turbine is uniformly introduced into the vertical cylindrical housing and the introduced steam is placed in a predetermined space inside the housing such that the surface area of the steam in contact with the cooled condensed water is maximized, Spraying the cooled condensed water to a predetermined space in which the steam is condensed in a direct-contact condensing manner; And a condenser of direct-contact condensing type, in which the condensed water generated by the condensation of the steam is cooled in a separate cooling tower to become the cooled condensed water and the extra condensate generated by the steam condensation is returned to the boiler feedwater system A low-cost, high-efficiency "steam condensing apparatus and method for a turbine power generation system" is disclosed in Korean Patent Publication No. 10-2010-01220915 (Nov. 17, 2010).

However, according to the above-mentioned partially improved other prior art, the " apparatus and method for condensing steam of a turbine power generation system " according to the open patent has a problem in that the structure of the apparatus for condensing steam is very complicated and inexpensive.

Thus, there is a need to develop a steam condensing system of a turbine thermal power generation system that allows for a very simple structure but more efficient condensation of the steam.

Korea Registered Patent No. 10-1285880 (Registered on July 20, 2013) "Condensate-free discharge recycling device for steam pipes" Korean Patent Publication No. 10-2010-0120915 (Nov. 17, 2010) "Steam condensing device and method of turbine power generation system"

Accordingly, an object of the present invention is to provide a method of efficiently condensing a vapor by simultaneously performing a primary condensation process including condensation by cooling and separation of steam and water by centrifugal force, and a secondary condensation process by condensation by cooling To provide a steam condensing system of a turbine thermal power generation system.

In order to achieve the above object, the steam condensing system of the turbine thermal power generation system of the present invention includes: a boiler for discharging high-temperature and high-pressure steam; A steam turbine rotated by high-temperature, high-pressure steam discharged from the boiler; A generator for generating electricity by converting rotational kinetic energy of the steam turbine into electric energy; A water-cooled cyclonic condensate stage for primarily condensing the steam discharged from the steam turbine; A cooling water tubular condensate stage for secondarily condensing the steam passing through the water-cooled cyclonic condensation means; A cooling tower for supplying cooling water to the water-cooled cyclone type condensate and the cooling water tubular condensation means; Condensing process selecting means for selecting the condensing process to be performed by the water-cooled cyclone condensing means so that the steam subjected to the first condensation treatment is discharged to the atmosphere or the second condensation process is performed by the cooling water tubular condensing means and then discharged to the atmosphere; And a condensed water storage tank for condensing the condensed water in the water-cooled cyclone condensed water stage and the cooling water tubular condensing means, wherein the water-cooled cyclonic condensation means comprises a cylindrical portion formed on the upper portion and a cylindrical portion formed integrally on the lower portion of the cylindrical portion A cooling water jacket for circulating cooling water provided over the outer circumferential surface of the cylindrical portion and the conical cylindrical portion of the annular portion; a cooling water jacket connected to the steam exhaust pipe of the steam turbine and for spraying steam in a tangential direction inside the upper end of the cylindrical portion; And a lower end of the steam discharging induction portion is located on the upper side of the boundary between the cylindrical portion and the conical tubular portion and is connected to the final steam discharging pipe A steam discharge pipe formed as a steam discharge portion and a steam discharge pipe Wherein the cooling water pipe type condensing means comprises a condensing tank, a plurality of cooling water pipes installed inside the condensing tank, and a plurality of cooling water pipes connected to both ends of the plurality of cooling water pipes A cooling water header connected to the cooling tower so that the cooling water circulates a plurality of cooling water pipes; a steam inlet pipe connecting the steam discharge pipe of the water-cooled cyclone type condensing means and one side of the condensation tank; And a condensing water discharge pipe connected to the lower surface of the condensing tank and discharging the condensed condensed water, wherein the condensation processing selecting means has one end connected to the steam discharge pipe of the water-cooled cyclone type condensing means And the other end is commonly connected to the steam inlet pipe of the cooling water tubular condensing means, A condenser connected to a steam outlet pipe of the bypass pipe and a steam inlet pipe to be condensed in the water-cooled cyclone condenser to discharge steam discharged from the steam discharge pipe, And a selector valve for directly discharging the condensed steam through the steam inlet pipe to the cooling water pipe type condensing means and discharging the second condensed steam through the steam discharge pipe and the final steam discharge pipe, Thereby providing a condensation system.

According to the present invention, there are provided a water-cooled cyclone type condensate stage for primarily condensing the steam discharged from the steam turbine and a cooling water tubular condensation means for condensing the steam passing through the water-cooled cyclone type condensation means, The means for separating steam and water by centrifugal force and the cooling-condensing action by the cooling water circulating in the cooling water jacket condenses the steam, thereby improving the condensation efficiency of the steam and the primary condensation treatment by the water- And the secondary condensation treatment by the cooling water tubular condensing means are performed concurrently, the condensation efficiency of the steam is further improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flow diagram illustrating a preferred embodiment of a steam condensing system of a turbine thermal power generation system according to the present invention;
2 is an enlarged sectional view showing a water-cooled cyclone type condensing means,
3 is a sectional view taken along the line AA in Fig. 2,
4 is an enlarged cross-sectional view of the cooling water tubular condensing means,
Fig. 5 is a sectional view taken along line BB of Fig. 4,
And
6 is a schematic diagram showing a steam condenser used in a conventional turbine thermal power generation system.

Hereinafter, preferred embodiments of a steam condensing system of a turbine thermal power generation system according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the steam condensing system of the turbine thermal power generation system according to the present invention comprises a boiler 10 for discharging high-temperature and high-pressure steam; A steam turbine 20 rotated by high-temperature, high-pressure steam discharged from the boiler 10; A generator (30) for generating electricity by converting rotational kinetic energy of the steam turbine (20) into electric energy; A water-cooled cyclone type condensing means (40) for primarily condensing the steam discharged from the steam turbine (20); A cooling water tubular condensing means (50) for secondarily condensing the steam passing through the water-cooled cyclonic condensing means (40); A cooling tower 60 for supplying cooling water to the water-cooled cyclonic condenser 40 and the cooling water tubular condenser 50; Condensation processing means (70) for selecting the steam to be discharged to the atmosphere by the water-cooled cyclone type condensing means (40) or to be discharged to the atmosphere after being subjected to secondary condensation processing by the cooling water tube type condensing means ); And a condensate water storage tank (80) for condensing the condensed water in the water-cooled cyclonic condensation means (40) and the cooling water tubular condensation means (50).

The boiler 10 uses a conventional boiler for heating water by fossil fuel (coal, oil, gas, or the like) or nuclear fuel to generate high temperature and high pressure steam. The steam turbine 20 is installed in the boiler 10, And a generator that rotates by the steam turbine 20 to generate electricity is used. The boiler 10 (10) is a conventional steam turbine that is rotated by high temperature and high pressure steam generated in the steam turbine 20, ), The steam turbine 20 and the generator 30 will be omitted.

2 and 3, the water-cooled cyclone type condensing means 40 includes a cylindrical portion 41 formed at an upper portion thereof and an inverted conical tube portion 42 integrally formed at a lower portion of the cylindrical portion 41 A cooling water jacket 43 through which the cooling water W1 installed over the outer circumferential surface of the cylindrical portion 41 and the conical cylindrical portion 42 is circulated and a cooling water jacket 43 connected to the steam discharge pipe 21 of the steam turbine 20 A steam injection pipe 44 for injecting steam in a tangential direction inside the upper end of the cylindrical portion 41 and a steam injection pipe 44 which is concentrically provided in the cylindrical portion 41, A steam discharge pipe 45 formed by the steam discharge portion 45a and a steam discharge portion 45b located outside the cylindrical portion 41 and connected to the final steam discharge pipe 90, And a condensed water discharge pipe 46 connected to the lower end of the condensed water discharge pipe 40 and discharging the condensed condensed water W2.

The upper and lower ends of the cooling water jacket 43 are provided with cooling water circulation pipes 43a and 43b connected to the cooling tower 60, respectively.

It is preferable that the ejection port 44a of the steam injection pipe 44 is provided so as not to protrude from the inner circumferential surface of the cylindrical portion 41 but coincide with the inner circumferential surface.

The inner diameter of the steam discharge pipe 45 is preferably set to about 1/2 of the inner diameter of the cylindrical portion 41 and the lower end of the steam discharge inducing portion 45a is connected to the cylindrical portion 41 and the conical- It is preferable to be located above the boundary.

4 and 5, the cooling water tubular condensing means 50 includes a condensing tank 51, a plurality of cooling water pipes 52 provided inside the condensing tank 51, A cooling water header 53 and 54 connecting both ends of the cooling water pipe 52 and connected to the cooling tower 60 so that the cooling water W1 circulates the plurality of cooling water pipes 52, A steam inlet pipe 55 for connecting the steam discharge pipe 45 of the condensing tank 51 to one side of the condensing tank 51 and a steam discharge pipe 56 for connecting the other side of the condensation tank 51 to the final steam discharge pipe 90 And a condensed water discharge pipe 57 connected to the lower surface of the condensation tank 51 and discharging the condensed water W3.

The cooling water header (53, 54) is provided with cooling water circulation pipes (53a, 54a) connected to the cooling tower (60), respectively.

The condensing process selecting means 70 is connected in common to the steam discharge pipe 45 of the water-cooled cyclone condenser 40 and the steam inlet pipe 55 of the cooling water pipe type condensing means 50, A condenser 71 connected to the final steam discharge pipe 90 and a common connection part for the steam discharge pipe 45 and the steam inlet pipe 55 of the bypass pipe 71, The steam discharged from the steam discharge pipe 45 is directly discharged to the final steam discharge pipe 90 or introduced into the cooling water pipe type condensing means 50 through the steam inlet pipe 55, And a selection valve (72) for allowing the steam condensed to be discharged through the steam discharge pipe (56) and the final steam discharge pipe (90).

Hereinafter, the vapor condensation process of the steam condensing system of the turbine thermal power generation system according to the present invention will be described.

The high temperature and high pressure steam generated in the boiler 10 is supplied to the steam turbine 20 and the steam turbine 20 is rotated to rotate the steam generator 30 to generate electricity, The high temperature, high pressure steam is discharged from the steam discharge end of the steam turbine (20).

The steam discharged from the steam discharge end of the steam turbine 20 is injected in a tangential direction to the inner upper end of the cylindrical portion 41 through the steam injection pipe 44 of the water-cooled cyclonic condensation means 40.

The steam injected in the tangential direction to the inner upper end of the cylindrical portion 41 is lowered while turning inside the cylindrical portion 41 and is lowered while turning inside the conical cylindrical portion 42 again. In this process, the relatively heavy water particles are lowered while being rotated by the centrifugal force along the inner circumferential surfaces of the cylindrical portion 41 and the inverted conical tubular portion 42, and the relatively light vapor particles pass through the cylindrical portion 41 and the inverted conical tubular portion 42).

The water particles descending and rotating along the inner circumferential surfaces of the cylindrical portion 41 and the inverted conical tube portion 42 collide with the inner peripheral surface of the cylindrical portion 41 and the conical cylindrical portion 42. The water particles flow along the inner peripheral surface of the cylindrical conical tube portion 42, (46) and stored in the condensate storage tank (80).

The water molecules in contact with the inner circumferential surface of the cylindrical portion 41 and the conical cylindrical portion 42 in this process are cooled by the cooling water circulating inside the cooling water jacket 43 provided in the cylindrical portion 41 and the conical cylindrical portion 42 And the condensation effect is increased.

On the other hand, the steam particles descending while rotating at the center of the cylindrical portion 41 and the inverted conical tube portion 42 are reversed at the lower end of the inverted conical tube portion 42 and are lifted up to the steam discharge inducing portion 45a of the steam discharge pipe 45, And the steam discharging portion 45b.

Only the primary condensation process by the water-cooled cyclone type condensation means 40 is performed in accordance with the selection of the condensation process selection means 70 or the primary condensation process by the water-cooled cyclone type condensation means 40 and the cooling process by the cooling water tubular condensation means 50) can be performed.

The condensing process selection means 70 is connected to the steam discharge port 45 of the water-cooled cyclonic condensation means 40 and the bypass pipe 71 so that the steam discharge port 45 and the cooling water tubular condensation means The steam discharged from the steam outlet 45 is subjected to the first condensation treatment in the water-cooled cyclonic condenser 40 and then immediately discharged to the final steam discharge pipe 90 do. In this case, the secondary condensation process by the cooling water tubular condensation means 50 is not performed.

The condensing process selection means 70 is connected to the steam outlet pipe 45 of the water-cooled cyclonic condensation means 40 and the steam inlet pipe 55 of the cooling water tubular condensation means 50, The steam that has been subjected to the first condensation treatment in the water-cooled cyclone type condensing means 40 and discharged through the middle stage discharge port 45 is supplied to the steam inlet pipe 55 through the steam inlet pipe 55 And flows into the condensing tank 51 of the cooling water tubular condensing means 50.

The primary condensed steam introduced into the condensing tank 51 is cooled by heat exchange with the cooling water circulating in the cooling means 52 in contact with the plurality of cooling water pipes 52 in the condensing tank 51, Condensation treatment.

The steam V4 subjected to the second condensation treatment in the cooling water tubular condensing means 50 is discharged through the steam discharge pipe 56 and the final steam discharge pipe 90 connected thereto.

The condensed water W3 condensed in the cooling water tubular condensing means 50 is discharged through the condensed water discharge pipe 57 connected to the lower portion of the condensation tank 51 and stored in the condensate water storage tank 80.

When the steam pressure measured by the pressure sensor (S) is normal, a pressure sensor (S) for measuring the steam pressure is installed at the steam discharge end of the steam turbine (20) And the secondary condensation process by the cooling water tubular condensing means 50 is performed. When the steam pressure measured by the pressure sensor 100 is higher than the normal pressure, the steam turbine It is preferable that the secondary condensation treatment by the cooling water tubular condensing means 50 is not performed in order to prevent the efficiency of the cooling water tube 20 from deteriorating.

As described above, according to the steam condensing system of the turbine thermal power generation system of the present invention, the water-cooled cyclonic type condensing means 40 is capable of separating steam and water by centrifugal force and cooling-condensing the cooling water circulating through the cooling water jacket 43 The condensation efficiency of the steam is improved because of the condensation treatment of the steam, and when the primary condensation treatment by the water-cooled cyclone type condensation means 40 and the secondary condensation treatment by the cooling water tube type condensation means 50 are performed in parallel, The efficiency is further improved.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or essential characteristics thereof. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

10: Boiler 20: Steam turbine
30: generator 40: water-cooled cyclone type condensing means
41: cylindrical portion 42: inverted conical barrel
43: cooling water jacket 44: steam jet pipe
45: steam discharge pipe 46: condensed water discharge pipe
50: cooling water tubular condensing means 51: condensing tank
52: cooling water pipe 53, 54: cooling water header
55: steam inlet pipe 56: steam outlet pipe
57: condensate discharge pipe 60: cooling tower
70: condensation processing selection means 71: bypass pipe
72: Selection valve 80: Condensate storage tank
90: Final steam outlet pipe

Claims (1)

A boiler 10 for discharging high-temperature and high-pressure steam;
A steam turbine 20 rotated by high-temperature, high-pressure steam discharged from the boiler 10;
A generator (30) for generating electricity by converting rotational kinetic energy of the steam turbine (20) into electric energy;
A water-cooled cyclone type condensing means (40) for primarily condensing the steam discharged from the steam turbine (20);
A cooling water tubular condensing means (50) for secondarily condensing the steam passing through the water-cooled cyclonic condensing means (40);
A cooling tower 60 for supplying cooling water to the water-cooled cyclonic condenser 40 and the cooling water tubular condenser 50;
Condensation processing means (70) for selecting the steam to be discharged to the atmosphere by the water-cooled cyclone type condensing means (40) or to be discharged to the atmosphere after being subjected to secondary condensation processing by the cooling water tube type condensing means ); And
And a condensed water storage tank (80) for storing the condensed water condensed in the water-cooled cyclonic condensation means (40) and the cooling water tubular condensation means (50)
The water-cooled cyclonic condensation means (40)
A cylindrical portion 41 formed on the upper portion,
An inverted cone-shaped cylindrical portion 42 integrally formed at the lower portion of the cylindrical portion 41,
A cooling water jacket 43 through which the cooling water W1 installed over the outer periphery of the cylindrical portion 41 and the conical cylindrical portion 42 is circulated,
A steam injection pipe (44) connected to the steam discharge pipe (21) of the steam turbine (20) and spraying steam in a tangential direction inside the upper end of the cylindrical part (41)
A steam discharge inducing portion 45a which is provided concentrically on the cylindrical portion 41 and which is located inside the cylindrical portion 41 and whose lower end is located above the boundary between the cylindrical portion 41 and the conical cylindrical portion 42, A steam discharge pipe 45 formed on the outside of the cylindrical portion 41 and formed as a steam discharge portion 45b connected to the final steam discharge pipe 90,
And a condensed water discharge pipe (46) connected to the lower end of the inverted conical tube portion (42) and discharging the condensed water (W2)
The cooling water tubular condensing means (50)
A condensation tank 51,
A plurality of cooling water pipes 52 provided inside the condensing tank 51,
A cooling water header 53 and 54 connected to the cooling tower 60 so as to connect both ends of the plurality of cooling water pipes 52 so that the cooling water W1 circulates the plurality of cooling water pipes 52,
A steam inlet pipe 55 connecting the steam discharge pipe 45 of the water-cooled cyclonic condensation means 40 and one side of the condensation tank 51,
A steam discharge pipe 56 for connecting the other end of the condensing tank 51 to the final steam discharge pipe 90 and a condensed water discharge pipe 57 connected to a lower surface of the condensation tank 51 for discharging the condensed water W3, And,
The condensing process selecting means 70 is connected in common to the steam discharge pipe 45 of the water-cooled cyclone condenser 40 and the steam inlet pipe 55 of the cooling water pipe type condensing means 50, A condenser 71 connected to the final steam discharge pipe 90 and a common connection part for the steam discharge pipe 45 and the steam inlet pipe 55 of the bypass pipe 71, The steam discharged from the steam discharge pipe 45 is directly discharged to the final steam discharge pipe 90 or introduced into the cooling water pipe type condensing means 50 through the steam inlet pipe 55, And a selector valve (72) for allowing the steam condensed to be discharged through the steam discharge pipe (56) and the final steam discharge pipe (90).

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