KR101103549B1 - Steam turbine system and method for increasing the efficiency of steam turbine system - Google Patents

Abstract

The present invention relates to a steam turbine system and a method for increasing energy efficiency of a steam turbine system, wherein the steam turbine system includes a boiler for generating steam, an inlet and an outlet, and inflows the generated steam through the inlet. A steam turbine that generates power using steam flowing from the inlet to the outlet, a condenser connected to the outlet and condensing the outgoing steam to reduce the volume of the vapor exiting through the outlet; And a compressor connected to the condenser to introduce a portion of the outflowing steam and compressing the inflowing steam to a higher temperature and a higher pressure. This results in a more energy efficient steam turbine system.

Steam turbine, energy efficiency, condenser, compressor

Description

STEAM TURBINE SYSTEM AND METHOD FOR INCREASING THE EFFICIENCY OF STEAM TURBINE SYSTEM}

The present invention relates to a steam turbine system for generating turbine power using steam and a method for increasing energy efficiency of the steam turbine system.

A steam turbine is a device that converts thermal energy stored in high-temperature, high-pressure steam into kinetic energy. The steam generating kinetic energy in the steam turbine is discharged to the outside of the turbine at low temperature and low pressure. Therefore, the steam turbine can recover more thermal energy as kinetic energy as the inflow and outflow pressure difference is larger.

One type of steam turbine is the condensation turbine. Condensing turbines condense steam by circulating large quantities of coolant through the condenser's tubes, which maintains low pressure in the condenser, thereby increasing the turbine's efficiency.

Steam turbines mainly use condensed turbines directly connected to large generators in major power plants, as they have to maintain the maximum possible efficiency, and therefore, research on condensed turbines has been actively conducted in recent years. As part of the research, a method of further improving the energy efficiency of the condensation turbine may be considered.

One object of the present invention is to provide a steam turbine system with higher energy efficiency.

Another object of the present invention is to provide an apparatus and method for recycling the effluent steam of a condensation turbine.

In order to solve the above problems, a steam turbine system according to an embodiment of the present invention is provided with a boiler for generating steam, an inlet and an outlet and inlet the generated steam through the inlet and at the inlet. A steam turbine that generates power using the steam flowing to the outlet, a condenser condensing the outgoing steam to reduce the volume of the outflow connected to the outlet and out through the outlet, and the outgoing steam And a compressor connected to the condenser to introduce a portion of the compressor and compressing the incoming steam to convert to a higher temperature and a higher pressure.

In one aspect related to the embodiment, the compressor may be a mechanical vapor recompression (MVR) compressor. The compressor may be connected to a transfer unit for transferring the converted steam to the spaced place so that the thermal energy of the steam converted to high temperature and high pressure in the compressor is available at a place spaced from the compressor.

In one aspect related to the above embodiment, the steam turbine system includes an integrator. An integrator is connected to the boiler and the compressor, respectively, to integrate some of the steam generated in the boiler with steam converted to high temperature and high pressure in the compressor. The steam turbine system may include a conveyance. The transfer unit is connected to the integrator, and transfers the integrated steam to a place spaced apart from the integrator.

In one aspect associated with the embodiment, the steam turbine system includes a control unit. The control unit senses the pressure in the condenser and increases the amount of cooling water flowing into the condenser when the pressure in the condenser is higher than a predetermined pressure. The control unit is configured to reduce the amount of coolant flowing into the condenser when the compressor is driven than when the compressor is not driven.

In one aspect associated with the embodiment, the steam turbine system includes a regulating device. The regulating device regulates the amount of some of the outflowing steam entering the compressor. The regulating device may be configured to adjust the flow area of the connecting pipe connecting the condenser and the compressor.

In one aspect associated with the embodiment, the steam turbine system includes an ejector. An ejector is connected with the condenser and discharges steam remaining in the condenser.

A steam turbine system according to another embodiment of the present invention includes a steam turbine having an inlet and an outlet and generating power by using steam flowing into the inlet and exiting the outlet, and connected to the outlet and the outlet A branch for branching the steam flowing through the section into first and second steam, a condenser connected to the branch and condensing the first steam to reduce the volume of the first steam, and a branch; And a compressor for compressing the second steam to convert it to a higher temperature and a higher pressure than the outflowing steam. The singer compressor may be a mechanical vapor recompression (MVR) compressor.

In one aspect associated with the other embodiment, the steam turbine system includes a branch regulating device. A branch control device is disposed in the branch, and is configured to adjust the amount of branching of the first and second steam.

The present invention also discloses a method for increasing energy efficiency of a steam turbine system. A method of increasing energy efficiency of a steam turbine system includes the steps of introducing steam into a steam turbine, withdrawing the steam from the steam turbine, and generating power in the steam turbine using the difference between the inflow and outflow pressures of the steam, and the outflow pressure. Condensing the outflowing steam through heat exchange in a condenser so as to be below atmospheric pressure, and a portion of the outflowing steam is introduced into a compressor to control the amount of the condensed vapor, and the inflowed steam in the compressor is heated to a higher temperature. And compressing to convert to high pressure.

As an aspect related to the energy efficiency increasing method, the energy efficiency increasing method includes at least one of a recycling step and an adjusting step. The recycling step is a step of recycling the compressed steam to use the compressed steam as an energy source. The adjusting step is to adjust the amount of cooling water flowing into the condenser for the heat exchange using at least one of whether the compressor is driven and the pressure in the condenser.

An energy efficiency increasing method and a steam turbine system of the steam turbine system according to the present invention configured as described above may introduce some of the outflow steam into the compressor to adjust the amount of steam condensed in the condenser. In addition, through this, the outlet pressure of the steam turbine is maintained at a low pressure, and the steam converted to high temperature and high pressure in the compressor can be recycled as a thermal energy source.

In addition, the steam turbine system according to the present invention uses a steam recompression compressor to convert the steam flowing out of the compressor to a higher temperature. This makes it easier to recycle the steam.

In addition, the steam turbine system according to the present invention, through the regulating device and the control unit, selectively drives the compressor, and adjusts the amount of vapor condensed to improve energy efficiency.

Hereinafter, a steam turbine system and a method of increasing energy efficiency of a steam turbine system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the same or similar reference numerals are assigned to the same or similar configurations in different embodiments, and the description thereof is replaced with the first description. As used herein, the singular forms "a", "an" and "the" include plural forms unless the context clearly indicates otherwise.

1 to 3 are schematic structural diagrams of steam turbine systems 100, 200, 300 according to embodiments of the present invention.

Referring to FIG. 1, the steam turbine system 100 includes a steam turbine 110, a condenser 120, and a compressor 130.

The steam turbine 110 includes an inlet 111 and an outlet 112, and generates power 113 using steam flowing from the inlet 111 to the outlet 112.

The steam turbine 110 consists of, for example, a shaft (rotor) supported by a bearing and surrounded by a cylindrical casing. The steam is ejected from the nozzles around the turbine cylinder and then impinges on the blades or buckets attached to the shaft to rotate the shaft, and the rotational energy of the shaft can be used as a driving source for various rotating machines.

The steam 101 flowing into the steam turbine 110 may be generated by, for example, changing the water into a high temperature and high pressure steam in the boiler 140. The boiler 140 may be formed to heat water using, for example, combustion heat of the burner 141.

The condenser 120 is connected to the outlet 112 and condenses the outgoing steam to reduce the volume of the steam outflowing through the outlet 112.

The condenser 120 is formed so that the supplied cooling water 102 exchanges heat with the outflowing steam. The coolant 102 flows through a tube across the condenser 120 and absorbs heat from the outflowing steam.

The outflowing vapor phase changes into water while transferring the latent heat of condensation from the condenser 120 to the cooling water 102. At this time, the same mass but the volume of the steam but the volume of water is small, so that the vacuum is generated by the reduced volume. Due to the vacuum, the pressure in the condenser 120 is lower than the atmospheric pressure, whereby the difference between the steam inlet and outlet pressure of the steam turbine 110 is greater than without the condenser 120.

The compressor 130 is connected to the condenser 120 to introduce a portion of the outflowing steam, and compresses the inflowing steam to convert to a higher temperature and a higher pressure. That is, part of the steam flowing out from the steam turbine 110 is recovered without condensing the entire amount. Through this, the amount of condensation of the condenser 120 may be reduced, and a portion of the steam flowing out may be used as a new heat energy source.

2, the steam turbine system 200 includes a steam turbine 210, a condenser 220, a compressor 230, and a branch 250.

The steam turbine 210 includes an inlet portion 211 and an outlet portion 212, and generates power 213 using steam flowing into the inlet portion 211 and exiting the outlet portion 212. .

The branch part 250 is connected to the outlet part 212, and branches the vapor flowing out through the outlet part 212 into first and second vapors. One end of the branch 250 is connected to the outlet 112 and split into two branches so that the branch 250 is connected to the condenser 220 and the compressor 230 at the other end. The first steam flows into the condenser 220 and the second steam flows into the compressor 230 through the branch 250.

Condenser 220 condenses the first vapor to reduce the volume of the first vapor, and compressor 230 compresses the second vapor to convert to higher temperature and pressure than the outflowing vapor. Through the branch 250, it is possible to easily control the distribution of the first and second steam flowing out of the steam turbine 210.

Referring to FIG. 3, some of the steam generated by the boiler 340 is transferred to a place spaced apart from the boiler 340 to be used as a heat energy source. This may be implemented by branching and transporting some of the steam 301 flowing into the steam turbine 310.

Hereinafter, a method of increasing energy efficiency of a steam turbine system applicable to the steam turbine systems 100, 200, and 300 will be described with reference to FIG. 4. 4 is a flowchart illustrating a method of increasing energy efficiency of a steam turbine system according to the present invention.

First, the steam is introduced into the steam turbine and the steam is discharged from the steam turbine, and power is generated in the steam turbine by using the difference between the inflow and outflow pressure of the steam (S100).

The steam turbine may be connected to the inlet pipe and the outlet pipe so that the steam inlet and outlet, respectively, the inlet pipe may be connected to a device for generating steam by applying energy to the water, for example, a boiler.

In the power generation step S100, steam, which is a working fluid that rotates the shaft of the steam turbine, may be formed by absorbing latent heat of evaporation from water. The phase change of 100 ° C water to 100 ° C vapor requires 539 kcal of latent heat of evaporation per kg of water. Therefore, the thermal energy required to generate power using 1 kg of steam is 539 kcal.

Next, to condense the outflowing steam through heat exchange in a condenser so that the outflow pressure is below atmospheric pressure (S200).

The outlet pipe of the steam turbine may be connected to the condenser so that the outflowing steam flows into the condenser. A condenser condenses the outgoing steam through heat exchange between cooling water and the outgoing steam. The condensation of steam maintains a low pressure in the condenser to increase the expansion ratio of the steam (ratio of expanded volume to the original volume of steam). As a result, the efficiency and work output of the steam turbine are increased.

At this time, in order to condense the steam back into water, the latent heat of condensation having the same size as the latent heat of evaporation is required, and the latent heat of condensation is transferred to the cooling water. That is, in order to use it as a working fluid in the power generation step (S100), the latent heat of evaporation applied to the steam is discharged to the outside through the cooling water. For example, if the vapor condensed is 30 ton / hr, the energy released to the outside is about 16,170 Mcal / hr.

Referring to FIG. 4, a method of increasing energy efficiency of a steam turbine system includes a compression step S300. Compression step (S300) is a step of introducing a portion of the outgoing steam to the compressor to adjust the amount of the condensed steam, and compressing the inlet steam in the compressor to convert to higher temperature and higher pressure.

The amount of steam supplied to the condenser is reduced by the amount of steam entering the compressor, but the low pressure in the condenser is maintained. This is because the decrease in the amount of steam supplied to the condenser does not affect the degree of vacuum inside the condenser. Therefore, the amount of condensed vapor is reduced, and the amount of energy released to the outside is also reduced.

Since the compressed steam is a high temperature and a high pressure, it can be used as an energy source and recycled (S400). For example, it is reused as a heating source of latent heat of evaporation, or is used as a working fluid for heating in surrounding buildings.

For example, if the compressor compresses 15 ton / hr and the condenser condenses 15 ton / hr, the latent heat of about 8,085 Mcal / hr is reduced compared to the total condensation of 30 ton / hr in the condenser.

Referring to FIG. 4, the method of increasing energy efficiency of the steam turbine system may include adjusting step S500.

The adjusting step (S500) is a step of adjusting the amount of cooling water flowing into the condenser for the heat exchange using at least one of whether the compressor is driven and the pressure in the condenser.

The method of adjusting the quantity of cooling water is demonstrated, for example.

First, when the compressor is not driven, the amount of cooling water is adjusted to condense all of the outflowing steam. At this time, the amount of cooling water may be a predetermined amount by calculation or experiment.

When the compressor is driven, the steam entering the condenser is reduced and the amount of cooling water is reduced to correspond to the reduction amount. To maintain the vacuum of the condenser, the pressure in the condenser senses the change and adjusts the amount of decrease in the cooling water in the range where the pressure does not increase. As described above, by adjusting the amount of cooling water, it is possible to minimize the amount of energy input to the steam turbine system.

Hereinafter, the steam turbine systems 100, 200, and 300 to which the energy efficiency increasing method of the steam turbine system described above is applied will be described with reference to FIGS. 1 to 3 again.

Referring to FIG. 1, the compressor 130 may be connected to the transfer unit 131. The transfer unit 131 transfers the converted steam to the spaced place so that the thermal energy of the steam converted to high temperature and high pressure in the compressor is available at a place spaced from the compressor. An apparatus 160 for recycling the steam may be disposed at the spaced place. The recycling apparatus 160 may be, for example, a heating apparatus using thermal energy of high temperature steam. As shown in the drawing, a plurality of heating devices may be provided.

The transfer unit 131 may be, for example, a transfer pipe connected to the compressor such that steam is discharged from the compressor 130. The transfer pipe extends to the spaced place, and the high pressure in the compressor 130 pushes the steam to the spaced place.

The compressor 130 may be a mechanical vapor recompression (MVR) compressor. The steam flowing out of the compressor 130 through the steam recompression may be a higher temperature. For example, if the recycling device 160 is a heating device, the steam used for the heating device can be utilized only when the temperature is above a certain temperature. Steam that is conveyed to the heating device through the steam recompression may be above the predetermined temperature.

Steam turbine system 100 may include a control unit 170.

The control unit 170 may be configured to control the driving of the compressor 130. Specifically, the control unit 170 controls the motor 132 driving the compressor. When the control unit 170 controls the compressor 130 not to operate, the steam flowing out of the steam turbine 110 is condensed in the total condenser 120. When the compressor 130 is driven, the control unit 170 reduces the amount of the coolant 102 flowing into the condenser 120 than when the compressor 130 is not driven.

The control unit 170 senses the pressure in the condenser 120, and when the pressure in the condenser 120 is higher than a predetermined pressure, the control unit 170 is configured to increase the amount of the coolant 102 flowing into the condenser 120. do.

The condenser 120 is equipped with a sensor for sensing the pressure, the control unit 170 processes the signal output from the sensor. For example, first, the amount of the coolant 102 is set to correspond to the case where the total amount is condensed, and the amount of the coolant 102 introduced into the condenser 120 is reduced according to the operation of the compressor 130. If the pressure in the condenser 120 is higher than the predetermined pressure, for example, the set pressure at the time of total condensation due to the decrease in the cooling water 102, the amount of the cooling water 102 is increased to increase the amount of condensation. Through this, the energy efficiency of the steam turbine system 100 may be further increased in a steady state.

Referring to FIG. 1, the steam turbine system 100 includes at least one of a regulating device 181 and an ejector 182.

The regulating device 181 adjusts an amount of some of the outflowing steam flows into the compressor 130.

The regulating device 181 is formed to adjust the flow area of the connecting pipe 131 connecting the condenser 120 and the compressor 130. For example, the adjusting device 181 may be a flow control valve installed in the connecting pipe 131. The adjustment of the flow rate may be controlled by the user or may be controlled by the control unit 170 through a predetermined algorithm.

The ejector 182 is connected to the condenser 130 and is formed to discharge steam remaining in the condenser 130. Ejector 182 is configured to, for example, create a higher degree of vacuum than inside condenser 130 to discharge steam that is not fully condensed at. Through this, the pressure in the condenser 130 can be maintained at a low pressure.

Referring to FIG. 2, the steam turbine system 200 distributes the steam flowing out of the steam turbine 210 through the branch 250 to the condenser 220 and the compressor 230.

Branch 250 is one end of the condenser 220 is connected to the outlet 212, and is branched to the first and second passage pipe (251, 252). The first and second passage pipes 251 and 252 are connected to the condenser 220 and the compressor 230, respectively, so that the first and second vapors flow.

The steam turbine system may include branch regulating devices 291 and 292. Branch control devices 291 and 292 are disposed in the branch 250 to adjust the amount of branching of the first and second steam. The branch regulating device 290 is, for example, flow control valves 291 mounted to the first and second passage pipes 251 and 252, respectively, to regulate the flow rates of the first and second passage pipes 251 and 252, respectively. , 292). However, the present invention is not limited thereto, and the flow control valves 291 and 292 may be mounted only on any one of the first and second passage pipes 251 and 252. The flow regulating valves 291 and 292 may be controlled by the user or the control unit 270, through which the amount of branching of the first and second vapors is adjusted.

Referring to FIG. 2, the compressor 230 is connected to a device for recycling steam converted to high temperature and high pressure in the compressor. The apparatus for recycling the steam may be a boiler 240 for generating steam entering the steam turbine 210. In the boiler 240, water is heated using thermal energy of steam, which has become a high temperature in the compressor. The compressor 230 may be a mechanical vapor recompression (MVR) compressor. The steam flowing out of the compressor 130 through the steam recompression may be higher temperature, through which the steam flowing out of the compressor 130 may be used as a heating source of the boiler 240.

Referring to FIG. 3, the steam turbine system 300 includes an integrator 390.

The integrator 390 is connected to the boiler 340 and the compressor 330, respectively, to integrate some of the steam generated by the boiler 340 with steam converted to high temperature and high pressure in the compressor 330.

The integrator 390 may include a pressure reducer 391 and an integrator 392. The pressure reducer 391 is formed to reduce the pressure of some of the steam generated in the boiler 340. The pressure reducer 391 may be an expansion valve or the like, for example.

An integrator 392 is connected to the pressure reducer 391 and the compressor 330, respectively, to introduce the reduced pressure and the converted steam into a steam in the same state. A transfer unit 331 is connected to the integrator to transfer the integrated steam to a place spaced apart from the integrator. The transfer unit 331 may be, for example, a transfer pipe connected to the compressor such that steam is discharged from the compressor 330.

In the spaced apart location, the utilization device 360 utilizing the integrated steam may be disposed. The utilization device 360 using the integrated steam may be, for example, a heating device using a thermal energy of a high temperature steam, a boiler, or the like. If 30 ton / hr of steam is required in the utilization device 360 and the compressor is not provided, the boiler 340 should generate a total amount of 30 ton / hr of steam. In contrast, some of the steam flowing out of the steam turbine 310, for example, 15 ton / hr of the steam is compressed through the compressor 330, and integrated with the steam generated in the boiler 340 ) Only needs to generate 15 ton / hr of steam. This can reduce the energy consumption of the boiler.

The steam turbine system and the method of increasing the energy efficiency of the steam turbine system are not limited to the configuration and method of the embodiments related to the present invention described above, but all of the embodiments so that various modifications of the embodiments can be made. Or some may be selectively combined.

1 to 3 are schematic structural diagrams of steam turbine systems according to embodiments of the present invention.

4 is a flowchart illustrating a method of increasing energy efficiency of a steam turbine system related to the present invention.

Claims (14)

Boilers for generating steam; A steam turbine having an inlet and an outlet, for introducing the generated steam through the inlet, and generating power using steam flowing from the inlet to the outlet; A condenser connected to the outlet and condensing the outlet steam to reduce the volume of vapor exiting through the outlet; And And a compressor coupled to the condenser to introduce some of the outgoing steam and to compress the incoming steam to convert to higher temperatures and pressures. The method of claim 1, The compressor is a steam turbine system, characterized in that the mechanical vapor recompression (MVR) compressor. The method of claim 1, And a control unit that senses the pressure in the condenser and increases the amount of coolant flowing into the condenser if the pressure in the condenser is higher than a predetermined pressure. The method of claim 1, And an integrator connected to the boiler and the compressor, respectively, for integrating some of the steam generated by the boiler with steam converted to high temperature and high pressure in the compressor. 5. The method of claim 4, And a transfer unit connected to the integrator to transfer the integrated steam to a place spaced apart from the integrator. The method of claim 1, And a regulating device for controlling an amount of a portion of the outflowing steam flowing into the compressor by adjusting a flow area of a connection pipe connecting the condenser and the compressor. The method of claim 1, And an ejector, connected to the condenser, for ejecting steam remaining in the condenser. The method of claim 1, The compressor, And a transfer part for transferring the converted steam to the spaced place so that the thermal energy of the steam converted to high temperature and high pressure in the compressor is available at a place spaced from the compressor. delete delete delete delete delete delete

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