KR101187765B1 - Feeding water device for generating system - Google Patents

Abstract

The present invention relates to a water supply device of a power plant, n boilers having an output corresponding to 1 / n times the set output of the turbine, is connected to each of the boilers start to pump the water supply stored in the water supply storage tank to the boiler N pumping unit consisting of a water supply pump and a main supply pump, and a switching unit for connecting a starting water supply pump to a plurality of boilers to induce a stable turbine output even in the event of a failure of some starting water supply pumps. It features.
The present invention simplifies the configuration and control of the water supply equipment of the power plant unlike the prior art, it is possible to start and operate a plurality of boilers at the same time, it is possible to realize the minimum flow rate of the boiler at the time of black-out (black-out) In addition, since a one-to-one starting water supply pump is connected in parallel to a plurality of boilers, it is possible to stably supply water to all boilers at all times.

Description

Feeding device for power plant {FEEDING WATER DEVICE FOR GENERATING SYSTEM}

The present invention relates to a water supply device of a power plant, and more particularly, to simplify the configuration and control of the water supply equipment of the power plant, and to enable the operation of a plurality of boilers at the same time, when black-out (black-out) The present invention relates to a water supply device for a power plant that can realize a minimum flow rate of a boiler and can stably supply water to all boilers by connecting a starting water supply pump corresponding to a plurality of boilers in parallel.

The water supply system of the existing power plant is connected to the starting water supply pump driven by an electric motor and the main water supply pump driven by the auxiliary turbine in parallel to supply water to the steam generator, and is used by appropriately switching according to the operating conditions.

In this usage, the water supply is supplied to the steam generator using a starting water supply pump driven by an electric motor at the beginning of the power plant plant, and after the steam generator is stabilized, it is supplied with additional air from the main turbine. Supply water to steam generator by operating feed water pump.

In particular, in a typical power plant, two main water supply pumps (50% capacity may be used) and one starting water supply pump having a capacity of 25% to 30% are often installed. The starting water supply pump is originally installed by means of a reserve or starting device.

In the water supply system of the existing power plant, two main feed water pumps and one starting feed water pump are connected to each boiler in a set, which leads to complex facility configuration and operation control. Since the water supply system of the existing power plant is installed two main water supply pump, there is a problem that the initial investment is excessive, and the installation area is increased. Therefore, there is a need to improve this.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a water supply system of the power plant and the water supply system of the power plant to simplify the control.

In addition, an object of the present invention is to provide a water supply device for a power plant that can enable a plurality of boilers to be started or operated simultaneously or separately to start a high power turbine in various ways.

In addition, an object of the present invention is to provide a water supply device for a power plant that can realize a minimum flow rate supply of the boiler at the time of black-out (black-out).

In addition, the present invention is connected to the starting water supply pump connected in one-to-one in parallel to the power generation to ensure that the water supply to all the boilers through the start of the adjacent starting water supply pump in case of failure of any one of the starting water supply pump The purpose is to provide a water supply system for the plant.

In addition, the present invention provides a water supply device of the power plant to enable a stable power production through the start of the neighboring main water pump in the case of any one of the main water pump failure by connecting the main water pump connected in parallel to the boiler one-to-one. Its purpose is to.

In addition, the present invention provides a water supply device of the power plant to increase the output of the generator by supplying the water supply to the corresponding boiler of the failed main water supply pump in parallel operation of two starting water supply pump when the boiler main water supply pump failure. There is a purpose.

In addition, the present invention can be maintained and maintained without boiler fire extinguishing (stopping) due to the failure of the main water supply pump by operating two water supply pumps in parallel when the main water supply pump connected to the boiler one-to-one failure, boiler The aim is to provide a water supply system for a power plant so as not to incur restart costs.

The water supply device of the power plant according to the present invention is: n boilers having an output corresponding to 1 / n times the set output of the turbine, connected to each of the boilers for starting to pump the water supply stored in the water supply storage tank to the boiler N pumping unit consisting of a water supply pump and a main water supply pump, and a switching unit for connecting one of the starting water supply pumps to the plurality of boilers to induce a stable output of the turbine even in the event of a failure of some starting water supply pumps. do.

Preferably, the starting water supply pump and the main water supply pump constituting each of the pumping units are provided one by one.

The switching unit, the water supply pumping to the boiler connected to the other one of the pumping unit by the start of the water supply pump for connecting the starting water supply pump to each other, and the connection pipe is provided to form any one of the pumping unit And a switching valve for inducing switching.

As described above, the water supply system of the power plant according to the present invention, unlike the prior art, the water supply system configuration of the power plant and these components can simplify the control.

In addition, the present invention can enable a plurality of boilers to be started or operated simultaneously or separately, and can start a high power turbine in various ways.

In addition, the present invention can realize the minimum flow rate supply of the boiler at the time of black-out (black-out).

In addition, the present invention can be connected to the starting water supply pump connected in one-to-one in parallel to the water supply to all the boilers through the start of the adjacent starting water supply pump in the event of failure of any one.

In addition, the present invention may be connected to the main water supply pump connected to the boiler in one-to-one in parallel can be a stable power production through the start of the adjacent main water supply pump in the event of a failure of the main water supply pump.

In addition, the present invention may be possible to increase the output of the generator by supplying the water supply to the corresponding boiler of the broken main water pump by operating two start water feed pumps in parallel when the main water pump connected to the boiler one-to-one.

In addition, the present invention can be maintained and maintained without boiler fire extinguishing (stop) due to a broken main water pump by operating two water supply pumps in parallel when the main water pump connected to the boiler one-to-one failure. You can avoid incurring restart costs.

1 is a block diagram of a water supply device of a power plant according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the water supply device of the power plant according to the present invention. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a block diagram of a water supply device of a power plant according to an embodiment of the present invention.

Referring to FIG. 1, a water supply device for a power plant according to an embodiment of the present invention includes a boiler 110 and 120, a pumping unit 200, and a switching unit 600.

In particular, a plurality of boilers 110 and 120 are provided and connected to a water storage tank 20 for storing water, respectively, and the pumping unit 200 is disposed in a one-to-one correspondence with each boiler 110 and 120 to correspond to the boiler 110 or 120) to pump the water supply.

In this case, the plurality of boilers 110 and 120 are connected to one turbine 10.

Here, the turbine 10 has a set output, and each of the boilers 110 or 120 among the n boilers 110 and 120 is 1 / n times the output of the turbine 10.

This is to shorten the starting time of each boiler 110 and 120 and the turbine 10 by starting n boilers 110 and 120 simultaneously and starting one turbine 10, and to implement | achieve facility operation economically.

The reason why the outputs of the boilers 110 and 120 are equal to 1 / n is to maintain or improve the durability of the turbine 10 by making the outputs simultaneously supplied to the turbine 10 the same.

For convenience, the boilers 110 and 120 are composed of the first boiler 110 and the second boiler 120.

In addition, the pumping unit 200 is connected to each of the first boiler 110 and the second boiler 120 to supply the water stored in the water storage tank 20 to the first boiler 110 or the second boiler 120. Pumps into the That is, the pumping unit 200 is the same number as the boiler (110, 120).

In this case, the pumping unit 200 connected to each of the first boiler 110 and the second boiler 120 may be connected to each of the water supply storage tanks 20, but is preferably connected to one water supply storage tank 20. Do.

On the other hand, the pumping unit 200 includes a starting water supply pump (210, 220) and the main water supply pump (230, 240).

The starting water supply pumps 210 and 220 are pumped to the boiler 110 or 120 corresponding to the water supply of the water supply storage tank 20 in a one-to-one correspondence at the initial start, and are provided with one.

In addition, the main water supply pumps 230 and 240 correspond to the water supply of the water supply storage tank 20 in a one-to-one manner by using additional gas in the turbine 10 after steam generation in the boiler 110 or 120. It is pumped by), and one is provided.

That is, the starting water supply pumps 210 and 220 and the main water supply pumps 230 and 240 are provided one by one and are connected to the corresponding first boiler 110 or the second boiler 120.

In more detail, the starting water supply pumps 210 and 220 are formed of the first starting water supply pump 210 and the second starting water supply pump 220, and the main water supply pumps 230 and 240 are formed of the first main water supply pump 230. The second main water supply pump 240 is formed.

In addition, the first starting water supply pump 210 serves to pump the water supply of the water supply storage tank 20 to the first boiler 110 at the beginning of the turbine 10 or the first boiler 110. The second starting water feed pump 220 serves to pump water from the water supply storage tank 20 to the second boiler 120 at the beginning of the turbine 10 or the second boiler 120.

In addition, the first main water supply pump 230 transfers the water supply of the water supply storage tank 20 to the first boiler 110 using the extraction of the turbine 10 after steam is generated in the first boiler 110. It serves to pump, the second main water supply pump 240 is a second boiler to feed water to the water supply storage tank 20 by using the extraction of the turbine 10 after steam generation in the second boiler (120). Pump 120.

That is, in order to supply water to the first boiler 110, one first starting water supply pump 210 and one first main water supply pump 230 are required. Similarly, in order to supply water to the second boiler 120, one second starting water supply pump 220 and one second main water supply pump 240 are required.

At this time, the output of the first boiler 110 is determined by the output of the first starting water supply pump 210 or the first main water supply pump 230, the output of the second boiler 120 is the second starting water supply It is determined by the output of the pump 220 or the second main water feed pump 240.

In particular, the output of the first start-up water supply pump 210 or the first main water supply pump 230 is the same as the output of the turbine 10, and usually the second start-up water supply pump 220 or the second main water supply It is desirable to produce half of the output when the pump 240 is started.

This is because when the failure or operation error of the second starting water supply pump 220 or the second main water supply pump 240, the first starting water supply pump 210 or the first main water supply pump 230, the turbine ( 10) to be able to start. Of course, it is preferable to allow the second starting water supply pump 220 or the second main water supply pump 240 to start the turbine 10 by a single start.

On the other hand, the main water supply pumps 230 and 240 are provided in the main pipes 310 and 320 connecting the water supply storage tank 20 and the corresponding boiler 110 or 120. More specifically, the first main water supply pump 230 is provided in the first main pipe 310 connecting the water supply storage tank 20 and the first boiler 110, the second main water supply pump 240 is a water supply storage tank A second main pipe 320 connecting the 20 and the second boiler 120 is provided.

In addition, the starting water supply pumps 210 and 220 are provided in auxiliary pipes 330 and 340 connecting the main pipes 310 and 320 corresponding to the water supply storage tank 20. More specifically, the first starting water supply pump 210 is provided in the first auxiliary pipe 330 connecting the water supply storage tank 20 and the first main pipe 310, the second starting water supply pump 220 is The second auxiliary pipe 340 is connected to the water supply storage tank 20 and the second main pipe 320.

That is, the first starting water supply pump 210 and the first main water supply pump 230 may supply water to the boilers 110 and 120 through independent pipes, but the first main pipe 310 and the first auxiliary pipe 330. Are arranged to be connected to each other. Likewise, the second starting water supply pump 220 and the second main water supply pump 240 may supply water to the boilers 110 and 120 through independent pipes, but the second main pipe 320 and the second auxiliary pipe 340 may be different from each other. Are arranged to be connected to each other. This is to simplify the configuration of the water supply system of the power generation system and to simplify the control.

In other words, at least one of the main pipes 310 and 320 and the auxiliary pipes 330 and 340 includes an intermittent valve 400 to control the flow of water.

For convenience, the control valve 400 is shown to be provided in each of the first main pipe 310, the second main pipe 320 and the first auxiliary pipe 330 and the second auxiliary pipe 340.

Therefore, the intermittent valve 400 may be controlled to be opened and closed automatically according to the initial start or after steam generation, and the automatic starting of the first starting water supply pump 210 and the first main water supply pump 230 may be controlled. It becomes possible. Of course, the intermittent valve 400 can automatically control the selective starting of the second starting water supply pump 220 and the second main water supply pump 240.

In addition, a heating member 500 is provided between the pumping unit 200 and the first boiler 110 to heat the water supply, and heating is performed between the pumping unit 200 and the second boiler 120 to heat the water supply. The member 500 is provided.

Thus, the heating element 500 heats the feed water flowing into the first boiler 110 and the second boiler 120, thereby improving the efficiency of the first boiler 110 and the second boiler 120.

At this time, the heating member 500 may be variously applied, and preferably provided in the first main pipe 310 and the second main pipe 320, respectively. Of course, the number of the heating member 500 is not limited.

Meanwhile, since the pumping unit 200 connected to the first boiler 110 and the pumping unit 200 connected to the second boiler 120 are not connected to each other, any one of the pumping units 200 different from each other. If the 200 is broken, the boiler 110 or 120 corresponding thereto is not supplied with water and is stopped or the output is lowered.

Thus, by connecting the starting water supply pumps 210 and 220 of one of the pumping units 200 to the plurality of boilers 110 and 120, the output of the turbine 10 that is stable even in the event of failure of some of the starting water supply pumps 210 or 220. Switching unit 600 is provided to guide.

That is, the switching unit 600 connects the first starting water supply pump 210 to the first main water supply pump 230 and the second water supply pump 230 when the second starting water supply pump 220 fails. By starting the first starting water supply pump 210 serves to enable water supply to the first boiler 110 and the second boiler 120 at the same time.

Similarly, the switching unit 600 connects the second starting water supply pump 220 to the first main water supply pump 230 and the second water supply pump 230 when the first starting water supply pump 210 fails. By starting the second starting water supply pump 220 serves to enable water supply to the first boiler 110 and the second boiler 120 at the same time.

For example, the switching unit 600 includes connection pipes 610 and 630 and switching valves 620 and 640.

For convenience, the connection pipes 610 and 630 connect the first connection pipe 610 connecting the second main pipe 320 and the first auxiliary pipe 330, and the first main pipe 310 and the second auxiliary pipe 340. The second connection pipe 620 is shown to be made.

In addition, the switching valves 620 and 640 include a first switching valve 620 provided in the first connection pipe 610, and a second switching valve 640 provided in the second connection pipe 630.

That is, one side of the first connection pipe 610 is connected to the first auxiliary pipe 330, the other side of the first connection pipe 610 is connected to the second main pipe 330.

In addition, the first switching valve 620 is provided in the first connection pipe 610 and the other pumping unit 200 by the start of the starting water supply pump 210 or 220 constituting any one pumping unit 200 It serves to induce water feed pumping to the boiler (120 or 110) connected to.

In other words, when the first starting water supply pump 210 and the second starting water supply pump 220 operate normally, the first switching valve 620 and the second switching valve 640 remain closed.

When the second starting water supply pump 220 fails, the first switching valve 620 is opened, and water is supplied to the first boiler 110 and the second boiler by starting the first starting water supply pump 210. 120 at the same time.

In addition, the starting water supply pump 210 or 220 constituting any one of the pumping unit 200 and the main water supply pump 240 or 230 constituting the other pumping unit 200 is connected to each other is the flow of water is switched desirable.

In more detail, when the first starting water supply pump 210 and the second starting water supply pump 220 operate normally, the first switching valve 620 and the second switching valve 640 remain closed.

Then, when the first starting water supply pump 210 is broken, the second switching valve 640 is opened, and water is supplied to the first boiler 110 and the second boiler by starting the second starting water supply pump 220. 120 at the same time.

In this case, after the first switching valve 620 or the second switching valve 640 is opened, the first main pipe 310 to have the same amount of water supplied to the first boiler 110 and the second boiler 120. ), The thickness of the second main pipe 320, the first auxiliary pipe 330, the second auxiliary pipe 340 and the connection pipe (610, 630) is preferably the same.

Of course, the switching valves 620 and 640 may be installed in the connection pipes 610 and 630 by various methods.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

10: turbine 20: water storage tank
110: first boiler 120: second boiler
200: pumping unit 210: first starting water supply pump
220: second starting water supply pump 230: first main water supply pump
240: 2nd main water supply pump 310,320: 1st and 2nd week piping
330,340: 1st and 2nd auxiliary pipe 400: intermittent valve
500: heating member 600: switching unit
610,630: first and second connection pipe 620,640: first and second switching valve

Claims (3)

N boilers having an output corresponding to 1 / n times the set output of the turbine;
N pumping units connected to each of the boilers and configured to include a starting water supply pump and a main water supply pump to pump water supplied in the water storage tank to the corresponding boiler; And
And a switching unit for connecting one of the starting water supply pumps to the plurality of boilers to induce a stable output of the turbine even in the event of a failure of some of the starting water supply pumps.
The method of claim 1,
The starting water supply pump and the main water supply pump constituting each of the pumping unit is provided with a water supply of the power plant, characterized in that provided one by one.
The method of claim 1, wherein the switching unit,
A connection pipe connecting the starting water supply pump to each other; And
And a switching valve provided in the connection pipe and configured to induce water supply pumping to the boiler connected to the other pumping unit by activating the starting water supply pump constituting any one of the pumping units.

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