KR102092826B1 - Apparatus and method for controlling steam flow - Google Patents

Abstract

The present invention relates to an apparatus and a method for controlling a steam flow rate of a turbine, to control the flow rate of steam extracted from the turbine to increase the output of the turbine, and to protect the condenser by controlling the flow rate of the cooled steam supplied from the condenser to the heater. Steam flow control device and method.
Steam flow control device according to an embodiment of the present invention is a boiler that generates steam, a turbine that receives steam, extracts a portion of the steam, a first valve that controls the flow rate of steam extracted from the turbine, and a turbine A condenser for cooling the incoming steam, a heater for reheating the cooled steam flowing from the condenser using steam extracted from the turbine, a second valve for controlling the flow rate of the cooled steam flowing from the condenser to the heater, and It includes a control unit for controlling the opening degree of the first valve and the second valve.

Description

Apparatus and method for controlling steam flow}

The present invention relates to a steam flow control device and method, and more specifically, to regulate the output of the turbine by controlling the flow rate of steam extracted from the turbine, and to control the flow rate of the cooled steam supplied from the condenser to the water heater to heat the water supply. It relates to a steam flow control device and method for protecting the gas.

In general, a turbine is a machine that converts the energy of a fluid such as water, gas, steam, etc. into mechanical work. Usually, several feathers or wings are planted on the circumference of a rotating body, and steam or gas is blown therein to impulse or reaction force. It is a spinning turbo type machine.

The steam flow of the turbine is high temperature and high pressure steam generated in the boiler is injected into the turbine, the steam injected into the turbine is cooled through a condenser, and the cooled steam is reheated in a heater and injected back into the boiler. In addition, a portion of the steam injected into the turbine is extracted and used as a heat source for the heater.

In this process, a valve for extracting steam from the turbine to the heater is installed, and this valve has a problem in that it is impossible to control the amount of steam extracted by the heater by performing an open-close.

The present invention is to solve the problems described above, by adjusting the flow rate of the steam extracted from the turbine to the water supply heater to control the output of the turbine, and by controlling the flow rate of the cooled steam supplied to the water supply heater from a plurality of water supply heaters It is an object of the present invention to provide an apparatus and method for controlling a vapor flow rate to be protected.

In addition to the technical problems of the present invention mentioned above, other features and advantages of the present invention will be described below, or it will be clearly understood by those skilled in the art from the description and description.

A steam flow control device for a turbine according to an embodiment of the present invention for achieving the above-described object includes a boiler generating steam, a turbine for receiving steam, and a condenser for cooling steam introduced from the turbine and a turbine for extracting a part of the steam And, the water supply heater for reheating the cooled steam flowing from the condenser by using the steam extracted from the turbine, a first valve for controlling the flow rate of the steam extracted from the turbine to the water supply heater, and cooling from the condenser to the water heater It includes a second valve for controlling the flow rate of the steam, and a control unit for controlling the opening degree of the first valve and the second valve.

Here, the control unit reduces the opening of the first valve to increase the output of the turbine, thereby reducing the flow rate of steam extracted from the turbine to the feed water heater.

In addition, the control unit increases the opening of the first valve to reduce the output of the turbine, thereby increasing the flow rate of steam extracted from the turbine to the feed water heater.

In addition, the control unit determines the flow rate of steam extracted from the turbine to the water heater by the opening of the first valve, and adjusts the opening of the second valve based on the flow rate of steam extracted from the turbine to the water heater.

In addition, when the flow rate of steam to be added is increased due to the increase in the opening degree of the first valve, the opening degree of the second valve is decreased to increase the amount of steam delivered from the condenser to the feed water heater.

In addition, the control unit increases the opening degree of the second valve to decrease the amount of steam delivered from the condenser to the feed water heater by increasing the opening degree of the second valve when the opening amount of the first valve is reduced.

In addition, the second valve is arranged in a bypass pipe connecting a plurality of pipes connecting the condenser and the feed water heater and a return pipe connecting the feed water heater and the boiler.

In addition, the control unit controls the opening degree of the second valve so that no more than a predetermined amount of cooled steam is supplied to the water heater.

In addition, the second valve transmits a part of the cooled steam supplied from the condenser to a recuperation pipe connecting the water heater and the boiler with a controlled opening degree based on the control signal of the control unit.

In addition, the turbine includes a high pressure turbine and a low pressure turbine, the water heater includes a high pressure water heater and a low pressure water heater, and the first valve is a high pressure duct and a low pressure turbine and a low pressure water heater heating connecting the high pressure turbine and the high pressure water heater Each is placed in a low-pressure thrust pipe connecting the groups.

Steam flow control method of the steam flow control device of a turbine according to an embodiment of the present invention for achieving the above-described object is a step of extracting a part of the steam supplied from the boiler, and transferring a part of the remaining steam to a condenser, a control unit In the step of controlling the opening of the first valve to control the flow rate of the steam to be extracted, and the control unit controls the opening of the second valve to deliver a portion of the steam cooled in the condenser to the intake pipe connecting the water heater and boiler, And reheating a portion of the remaining cooled steam using steam that is extracted.

Here, in the step of controlling the flow rate of the steam to be extracted, when the output of the turbine is reduced, the opening of the first valve is reduced to decrease the flow rate of the steam to be extracted.

In addition, in the step of controlling the flow rate of the steam to be extracted, when the output of the turbine is increased, the opening of the first valve is increased to increase the flow rate of the steam to be extracted.

In addition, in the step of reheating using the steam to be extracted, the flow rate of the steam to be extracted is determined by the opening degree of the first valve, and the opening degree of the second valve is adjusted based on the flow rate of the extracted steam.

In addition, in the step of reheating using the steam that is extracted, when the opening degree of the first valve increases and the flow rate of the extracted steam increases, the opening degree of the second valve is decreased to increase the amount of steam cooled in the condenser.

In addition, in the step of reheating using the steam to be extracted, when the opening degree of the first valve is reduced and the flow rate of the steam to be extracted is decreased, the opening degree of the second valve is increased to decrease the amount of steam cooled in the condenser.

In addition, in the step of reheating by using the extracted steam, the opening degree of the second valve is controlled so that no more than a predetermined amount of cooled steam is supplied to the feed water heater, and a part of the cooled steam is transferred to the exhaust pipe at the controlled opening degree. .

Boiler for generating steam according to an embodiment of the present invention for achieving the above-described object, a turbine for receiving the steam and extracting a part of the steam, a condenser for cooling the steam flowing from the turbine, and extracted by the turbine A steam flow rate control device for controlling the steam flow rate of a steam system including a water supply heater that reheats the cooled steam flowing from the condenser using steam, controls the flow rate of the steam extracted from the turbine to the water supply heater It includes a first valve, a second valve to control the flow rate of the cooled steam flowing into the feed water heater from the condenser, and a control unit to control the opening degree of the first valve and the second valve, wherein the control unit includes: In accordance with the increase or decrease of the flow rate of steam extracted by the feed water heater according to the opening degree of the first valve By controlling the opening degree of the second valve, the amount of the steam delivered from the condenser to the feed water heater is increased or decreased.

Steam flow control method of the steam flow control apparatus according to an embodiment of the present invention for achieving the above-described object is to transfer a part of the steam supplied from the boiler to the turbine to the feed water heater, and the remaining part of the steam to the condenser Cooling the steam flowing from the turbine, supplying the cooled steam to the feed water heater, reheating the cooled steam flowing from the condenser, and the flow rate of steam delivered from the turbine to the feed water heater And controlling the opening of the second valve to control the amount of steam delivered from the condenser to the feed water heater, and controlling the opening of the second valve. In the controlling step, the oil of the steam extracted by the feed water heater according to the opening degree of the first valve And controlling the opening degree of the second valve to increase or decrease the amount of the steam delivered from the condenser to the feed water heater according to the increase or decrease of the amount.

The apparatus and method for controlling the steam flow rate of a turbine according to an embodiment of the present invention may control the output of the turbine by controlling the flow rate of steam extracted from the turbine to the feed water heater.

In addition, it is possible to prevent the water heater from being damaged by the cooled steam by adjusting the flow rate of the cooled steam supplied from the condenser to the water heater.

In addition, other features and advantages of the present invention may be newly identified through embodiments of the present invention.

1 is a view showing the configuration of a steam flow rate control device according to an embodiment of the present invention.
2 is a view showing a steam flow control method of the first valve according to an embodiment of the present invention.
3 is a view showing a modification of the method for controlling the steam flow rate of the second valve according to the embodiment of the present invention.
4 is a view showing a modification of the method for controlling the steam flow rate of the second valve according to the embodiment of the present invention.
FIG. 5 is a diagram illustrating the relief of a steam flow control device according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice. The present invention can be implemented in many different forms and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar elements throughout the specification.

Throughout the specification, when a part is "connected" to another part, this includes not only "directly connected" but also "electrically connected" with another element in between. . Also, when a part “includes” a certain component, this means that other components may be further included rather than excluding other components, unless otherwise specified.

When one part is said to be "above" another part, it may be directly on top of the other part or another part may be involved in between. In contrast, if one part is said to be "just above" another part, no other part is involved in between.

Terms such as first, second and third are used to describe various parts, components, regions, layers and / or sections, but are not limited thereto. These terms are only used to distinguish one part, component, region, layer or section from another part, component, region, layer or section. Accordingly, a first portion, component, region, layer or section described below may be referred to as a second portion, component, region, layer or section without departing from the scope of the present invention.

The terminology used herein is only for referring to a specific embodiment, and is not intended to limit the present invention. The singular forms used herein include plural forms unless the phrases clearly indicate the opposite. As used herein, the meaning of “comprising” embodies a particular property, region, integer, step, action, element, and / or component, and the presence or presence of other properties, regions, integers, steps, action, element, and / or component. It does not exclude addition.

Terms referring to relative spaces such as "below", "above", etc. may be used to more easily describe the relationship of one part to another part shown in the drawings. These terms are intended to include other meanings or actions of the device in use in conjunction with the intended meaning in the drawings. For example, if the device in the figure is turned over, some parts described as being “below” other parts are described as being “above” other parts. Thus, the exemplary term “below” includes both the up and down directions. The device can be rotated 90 degrees or rotated at different angles, and terms indicating relative space are also interpreted accordingly.

Although not defined differently, all terms including technical terms and scientific terms used herein have the same meaning as those generally understood by those skilled in the art to which the present invention pertains. Commonly used dictionary-defined terms are further interpreted as having meanings consistent with related technical documents and currently disclosed contents, and are not to be interpreted as ideal or very formal meanings unless defined.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein.

1 is a view showing the configuration of a steam flow rate control device according to an embodiment of the present invention.

1, the steam flow control apparatus 100 according to an embodiment of the present invention includes a boiler 110, a turbine 120, a condenser 130, a feed water heater 140, a first valve 150, and 2 may include a valve 160 and a control unit 170.

Boiler 110 may generate steam. Steam generated in the boiler 110 may be introduced into the turbine 120. Here, a valve to supply steam to the turbine 120 may be disposed between the boiler 110 and the turbine 120. The valve may control the flow rate of steam supplied from the boiler 110 to the turbine 120.

Steam introduced into the turbine 120 may be used as an energy source to generate the turbine 120, the rotational energy may be converted to electrical energy by rotating the generator. The steam discharged from the turbine 120 flows into the condenser 130, and a part of the steam may be extracted and flowed into the feed water heater 140. A steam pipe 230 that allows steam to be added between the turbine 120 and the feed water heater 140 to flow into the feed water heater 140 may be connected. The extraction pipe 230 may be provided with a first valve 150 that controls the amount of extracted steam supplied to the feed water heater 140.

The condenser 130 may cool the steam flowing from the turbine 120. The condenser 130 may reduce the steam that rotates the turbine 120 to water through heat exchange. Steam cooled in the condenser 130 may be supplied to the feed water heater 140. Between the condenser 130 and the water supply heater 140, a plurality of pipes 220 allowing the cooled steam to flow into the water supply heater 140 may be connected. Steam cooled in the condenser 130 through the conduit 220 may be supplied to the feed water heater 140, and the conduit 220 is a second valve 160 that controls the degree of opening and closing of the conduit 220 It is possible to control the amount of cooled steam supplied to the feed water heater 140, including.

The feed water heater 140 may reheat the cooled steam flowing from the condenser 130 using steam extracted from the turbine 120. That is, steam extracted from the turbine 120 may be introduced into the feed water heater 140, and steam cooled by the condenser 130 may be introduced. At this time, the water supply heater 140 may reheat the steam introduced from the water supply heater 140 using the extracted steam introduced from the turbine 120 as a heat source. The reheated steam may be introduced back into the boiler 110. In addition, the water supply heater 140 may transfer the heated steam back to the condenser 130 to cool it. At this time, the water supply heater 140 may supply the steam heated by the condenser 130 through a separate tube different from the plurality of tubes 220 where the steam cooled in the condenser 130 is delivered to the water supply heater 140.

The first valve 150 may control the flow rate of steam extracted from the turbine 120 to the feed water heater 140. The first valve 150 may be a control valve capable of adjusting the opening degree. The opening degree of the valve may be adjusted in the first valve 150 based on the control of the control unit 170. Here, when the opening degree of the first valve 150 is reduced, the flow rate of steam extracted into the feed water heater 140 may be reduced, and accordingly, the amount of steam flowing into the turbine 120 increases, and the output of the turbine 120 is increased. Can increase. In addition, when the opening degree of the first valve 150 is increased, the flow rate of steam extracted to the feed water heater 140 may be increased, and accordingly, the output of the turbine 120 may be reduced by reducing the amount of steam flowing into the turbine 120. Can decrease.

The second valve 160 is a bypass pipe connecting a plurality of pipes 220 connecting the condenser 130 and the feed water heater 140 and a recirculation pipe 240 connecting the feed water heater 140 and the boiler 110. 250. The second valve 160 may control the flow rate of the cooled steam flowing into the feed water heater 140 from the condenser 130. The second valve 160 may be a control valve capable of adjusting the opening degree. The second valve 160 may adjust the opening degree of the valve based on the control of the control unit 170. Here, when the opening degree of the second valve 160 is decreased, the flow rate of the cooled steam flowing into the water supply heater 140 may be increased, and when the opening degree of the second valve 160 is increased, the flow rate of the cooled steam flowing into the water supply heater 140 may be increased. The flow rate of the cooled steam can be reduced.

The control unit 170 may adjust the opening degree of the first valve 150 and the second valve 160. When it is determined that the output of the turbine 120 is reduced, the control unit 170 may control the opening degree of the first valve 150 to adjust the flow rate of steam extracted from the turbine 120 to the feed water heater 140 to be lowered. have. Accordingly, the amount of steam of the turbine 120 may increase, and the output of the turbine 120 may increase. In addition, when it is determined that the output of the turbine 120 is increased, the control unit 170 controls the opening of the first valve 150 to adjust the flow rate of steam extracted from the turbine 120 to the feed water heater 140. can do. Accordingly, the amount of steam in the turbine 120 may decrease, and the output of the turbine 120 may decrease.

In addition, the control unit 170 may control the opening of the second valve 160 to be increased when it is determined that a certain amount of steam is introduced from the condenser 130 to the feed water heater 140. That is, the control unit 170 may adjust the opening degree of the second valve 160 so that only the amount of steam to be reheated from the water supply heater 140 flows into the water supply heater 140. Accordingly, the amount of steam exceeded in a predetermined amount may be delivered to the return pipe 240 along the bypass pipe 250, and the water supply heater 140 may be prevented from supplying more than a certain amount of steam to the water supply heater 140 Can protect. Here, steam that has passed through the second valve 160 and steam that has been reheated and discharged from the feed water heater 140 may be introduced back into the boiler 110.

For example, when the amount of cooled steam discharged from the condenser 130 is 100 and the amount of steam to be reheated in the feed water heater 140 is 60, the second valve 160 is the amount of cooled steam discharged from the condenser 130. 40 of 100 may be passed to the trachea 240. Accordingly, the water supply heater 140 may be protected by preventing the amount of steam flowing into the water supply heater 140 from exceeding a predetermined amount or more that can be reheated in the water supply heater 140.

In addition, the control unit 170 determines the flow rate of steam delivered from the turbine 120 to the feed water heater 140 by the opening of the first valve 150, and flows from the turbine 120 to the feed water heater 140. The opening degree of the second valve 160 may be adjusted based on the flow rate of steam.

Specifically, when the opening degree of the first valve 150 is increased by the control of the control unit 170 and the flow rate of steam extracted by the water supply heater 140 is increased, the control unit 170 increases the opening degree of the second valve 160. The amount of steam delivered from the condenser 130 to the feed water heater 140 may be increased. As the steam added to the feed water heater 140 increases, the feed water heater 140 may heat a larger amount of steam using the extracted steam. Accordingly, the control unit 170 may increase the amount of steam flowing into the water supply heater 140 by reducing the opening degree of the second valve 160 so that the water supply heater 140 may heat more steam. In addition, when the opening degree of the first valve 150 is reduced by the control of the control unit 170 and the flow rate of steam extracted to the water heater 140 decreases, the control unit 170 increases the opening degree of the second valve 160. The amount of steam delivered from the condenser 130 to the feed water heater 140 may be reduced. As the steam added to the water supply heater 140 decreases, the water supply heater 140 may heat only a small amount of steam using the extracted steam. Accordingly, the control unit 170 increases the opening degree of the second valve 160 to reduce the amount of steam flowing into the water supply heater 140, so that the water supply heater 140 is capable of heating more steam. It is possible to prevent steam from entering. Therefore, the water supply heater 140 can be protected by not exceeding a predetermined amount or more that can be reheated in the water supply heater 140.

2 is a view showing a steam flow control method of the first valve according to an embodiment of the present invention.

1 and 2, the turbine 120 extracts a portion of the steam supplied from the boiler 110 (S11). The turbine 120 may extract a portion of steam and supply it to the feed water heater 140. Here, between the turbine 120 and the water supply heater 140, a weight pipe 230 for transferring the extracted steam to the water supply heater 140 may be connected. A first valve 150 that adjusts the amount of steam to be extracted may be disposed in the extraction pipe 230.

Next, it is determined whether the output of the turbine 120 is reduced (S12).

When the output of the turbine 120 is reduced, the control unit 170 lowers the opening degree of the first valve 150 (S13). When the output of the turbine 120 is reduced, the control unit 170 may lower the opening degree of the first valve 130 to reduce the amount of steam added. Accordingly, the amount of steam increases in the turbine 120, so that the output of the turbine 120 may be increased.

On the other hand, if the output of the turbine 120 is not reduced, the control unit 170 increases the opening degree of the first valve 150 (S14). When the output of the turbine 120 is increased, the control unit 170 may increase the opening degree of the first valve 130 to increase the amount of steam that is extracted. Accordingly, the amount of steam is reduced in the turbine 120, so that the output of the turbine 120 may be reduced.

The water supply heater 140 uses the steam extracted by the water supply heater 140 to heat the steam introduced from the condenser 130 (S15). The amount of steam adjusted in accordance with the opening degree may be introduced into the feed water heater 140 and the steam cooled in the condenser 130 may be introduced into the first valve 150. The feed water heater 140 may use the extracted steam as a heat source to heat the cooled steam introduced from the condenser 130.

Steam heated in the feed water heater 140 flows into the boiler (S16). The boiler 110 may supply steam flowing from the feed water heater 140 to the turbine 120 to be used as energy to generate rotational energy in the turbine 120. Therefore, the above process can be executed repeatedly.

3 is a view showing a modification of the method for controlling the steam flow rate of the second valve according to the embodiment of the present invention.

1 and 3, the turbine 120 supplies a part of the steam supplied from the boiler 110 to the condenser 130 (S21). The turbine 120 extracts a part of the steam supplied from the boiler 110 and transfers a part of the remaining steam to the condenser 130.

The condenser 130 cools the supplied steam (S22).

Subsequently, it is determined whether the steam cooled in the condenser 130 is a predetermined amount or more (S23). Here, the predetermined amount may be the amount of steam to be heated in the water supply heater 140, which is the capacity to receive the cooled steam from the water supply heater 140, the capacity to heat the steam in the water supply heater 140, etc. Can be determined through.

If the steam cooled in the condenser 140 is a predetermined amount or more, the opening degree of the second valve 160 is controlled to transmit the amount of the steam exceeded in the predetermined amount to the exhaust pipe 240 (S24). If the steam cooled in the condenser 140 is a predetermined amount or more, the control unit 170 may control the opening degree of the second valve 160. Here, the control unit 170 may control the opening of the second valve 160 to be opened more when the cooled steam exceeds a certain amount, and when the cooled steam slightly exceeds the predetermined amount, the second valve 160 ) Can be controlled to open slightly. The cooled steam may be transferred to the return pipe 240 by the opening of the second valve 160, and may flow into the boiler 110 along the return pipe 240.

The feed water heater 140 heats the steam introduced from the condenser 130 (S25). The feed water heater 140 may heat the steam introduced by a predetermined amount by the opening of the second valve 160. In addition, when the steam cooled in the condenser 130 is not a predetermined amount or more, all of the cooled steam may be introduced into the water supply heater 140, and the water supply heater 140 may heat the introduced steam.

Steam heated in the feed water heater 140 flows into the boiler (S26). The boiler 110 may supply steam flowing from the feed water heater 140 to the turbine 120 to be used as energy to generate rotational energy in the turbine 120. Therefore, the above process can be executed repeatedly.

4 is a view showing a modification of the method for controlling the steam flow rate of the second valve according to the embodiment of the present invention.

1 and 4, it is determined whether the flow rate of steam extracted from the turbine 120 to the feed water heater 240 is increased (S31). Here, the flow rate of steam extracted by the feed water heater 240 may vary according to the opening degree of the first valve 150, and the control unit 270 adjusts the opening degree of the first valve 150 to output the turbine 120. Can be adjusted.

When the flow rate of steam extracted from the turbine 120 to the feed water heater 240 is increased, the control unit 270 reduces the opening degree of the second valve 160 (S32). When the flow rate of steam added to the water supply heater 240 is increased, the amount of steam that the water supply heater 240 can use as a heat source is increased, and a larger amount of steam can be heated using the extracted steam. . Accordingly, the control unit 270 decreases the opening of the second valve 160 and bypasses it, thereby reducing the flow rate of the steam flowing directly into the boiler 110, whereby a larger amount of steam is introduced into the feed water heater 240. It can be allowed to heat up.

On the other hand, if the flow rate of the steam extracted from the turbine 120 to the feed water heater 240 is not increased, the control unit 270 increases the opening degree of the second valve 160 (S33). When the flow rate of steam added to the water supply heater 240 is reduced, the amount of steam that the water supply heater 240 can use as a heat source is reduced, and the water supply heater 240 can heat the steam using only the extracted steam. do. Therefore, the control unit 270 increases the opening degree of the second valve 160 to increase the flow rate of the steam that is bypassed and flows directly into the boiler 110, thereby increasing the flow rate of the steam that the feed water heater 240 can heat. It can be prevented from being exceeded and flowing into the water heater 240.

The feed water heater 140 heats the steam introduced from the condenser 130 (S34). The feed water heater 140 may heat the steam introduced by a predetermined amount by the opening of the second valve 160.

Steam heated in the feed water heater 140 flows into the boiler (S35). The boiler 110 may supply steam flowing from the feed water heater 140 to the turbine 120 to be used as energy to generate rotational energy in the turbine 120. Therefore, the above process can be executed repeatedly.

The present invention realizes a steam flow control device and method for a turbine that increases the output of a turbine by controlling the flow rate of steam extracted from the turbine, and protects the water supply heater by controlling the flow rate of the cooled steam supplied from the condenser to the water heater. You can.

FIG. 5 is a diagram illustrating the relief of a steam flow control device according to an embodiment of the present invention.

Referring to FIG. 5, the boiler 110 may generate steam by heating water with heat generated by burning fuel. Steam generated in the boiler 110 may be introduced into the high pressure turbine 122 through the steam pipe 210.

The high pressure turbine 122 may generate rotational energy using the incoming steam. The high pressure turbine 122 may be operated by high pressure / high temperature steam delivered from the boiler 110. The high pressure turbine 122 may deliver a portion of the steam to the high pressure water heater 142. Here, the steam of the high-pressure turbine 122 may be delivered to the high-pressure feed water heater 142 through the high-pressure propulsion pipe 232, and the high-pressure propulsion pipe 230 may control the flow rate of steam delivered to the high-pressure feed water heater 142. A high pressure first valve 152 to adjust may be disposed.

The low pressure turbine 124 may generate rotational energy using steam flowing from the high pressure turbine 122. The low pressure turbine 124 may be operated by steam at a relatively low pressure / low temperature than the high pressure turbine 122. The generated rotational energy may be converted into electrical energy by rotating a generator connected to the low-pressure turbine 124. The low pressure turbine 124 may transfer a portion of the steam to the low pressure feed water heater 144. Here, the steam of the low-pressure turbine 124 may be delivered to the low-pressure feed water heater 144 through the low-pressure propulsion pipe 234, and the low-pressure propulsion pipe 234 may flow the steam flow to the low-pressure feed water heater 144. A low pressure first valve 154 to adjust may be disposed.

The condenser 130 may reduce the steam rotating the low pressure turbine 124 to water through heat exchange. The steam cooled in the condenser 130 may be supplied to the feed water heater 140 through the condenser tube 220. The plurality of pipes 220 may include a second valve 160 that controls the degree of opening and closing of the plurality of pipes 220.

The feed water heater 140 may include a low pressure water feed heater 144 and a high pressure water feed heater 142. Between the low pressure water heater 144 and the low pressure turbine 124, a low pressure steam pipe 234 to connect the low pressure steam to the low pressure water heater 144 may be connected. The cooled steam may be heated by using the steam vapor transmitted through the low-pressure thrust pipe 234 as a heat source. Steam heated through the low pressure water supply heater 144 may be stored in the water supply tank 180.

The heated steam stored in the water supply tank 180 may be boosted by the water supply pump 190 and supplied to the high pressure water supply heater 142. Between the high pressure turbine 122 and the high pressure water supply heater 142, a high pressure extractor 232 that allows high pressure steam vapor to be supplied to the high pressure water supply heater 142 may be connected. The steam supplied to the high-pressure feed water heater 142 may be heated using the high-pressure steam vapor transmitted through the high-pressure steam pipe 232 as a heat source. Steam heated by the high pressure feed water heater 142 may be supplied to the boiler 110.

Unlike the above-described example, the turbine 120 is described as being composed of a high pressure turbine 122 and a low pressure turbine 124, but is not limited thereto. A medium pressure turbine may be further included between the high pressure turbine 122 and the low pressure turbine 124.

Those skilled in the art to which the present invention pertains should understand that the present invention is illustrative and not restrictive in all respects, as the present invention may be implemented in other specific forms without changing its technical spirit or essential features. Only. The scope of the present invention is indicated by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be interpreted to be included in the scope of the present invention. .

100: steam flow control device 110: boiler
120: turbine 130: condenser
140: water heater 150: first valve
160: second valve 170: control
180: water supply tank 190: gold water pump
210: steam pipe 220: multiple pipes
230: additional organ 240: assembly organ
250: bypass tube 122: high pressure turbine
124: low pressure turbine 232: high pressure thrust pipe
234: low pressure duct 142: high pressure water heater
144: low pressure water heater 152: high pressure first valve
154: low pressure first valve

Claims (10)

A boiler that generates steam, a turbine that receives the steam and extracts a part of the steam, a condenser that cools the steam flowing from the turbine, and reheats the cooled steam flowing from the condenser using the steam extracted from the turbine In the steam flow rate control device for controlling the steam flow rate of the steam system comprising a water heater,
A first valve for controlling the flow rate of the steam extracted from the turbine to the feed water heater;
A second valve controlling a flow rate of the cooled steam flowing into the feed water heater from the condenser; And
Includes; control unit for controlling the opening degree of the first valve and the second valve,
The control unit,
By controlling the opening degree of the second valve according to the increase or decrease in the flow rate of steam added to the feed water heater according to the opening degree of the first valve, the amount of the steam transferred from the condenser to the water heater is increased or decreased,
When the steam cooled in the condenser is a predetermined amount or more, a steam flow rate control device that controls the opening degree of the second valve so that the steam exceeded in the predetermined amount is not delivered to the feed water heater. According to claim 1,
The control unit is a steam flow rate control device for reducing the flow rate of the steam extracted from the turbine to the feed water heater by reducing the opening of the first valve to increase the output of the turbine. According to claim 1,
The control unit is a steam flow rate control device for increasing the opening of the first valve to decrease the output of the turbine to increase the flow rate of the steam extracted from the turbine to the feed water heater. delete According to claim 1,
The control unit increases the amount of steam delivered from the plurality to the feed water heater by decreasing the opening degree of the second valve when the opening of the first valve increases and the flow rate of the extracted steam increases. . According to claim 1,
The control unit increases the opening degree of the second valve when the opening degree of the first valve is reduced to decrease the amount of the steam delivered from the condenser to the feed water heater by increasing the opening degree of the second valve. . According to claim 1,
The second valve is a steam flow rate control device disposed in a bypass pipe connecting a plurality of pipes connecting the plurality of water heaters and the feed water heater and a return pipe connecting the water heaters and the boiler. According to claim 1,
The turbine includes a high pressure turbine and a low pressure turbine,
The water heater includes a high pressure water heater and a low pressure water heater,
The first valve is a high-pressure pulsating pipe connecting the high-pressure turbine and the high-pressure water heater, and a low-pressure pulsating pipe connecting the low-pressure turbine and the low-pressure water heater, respectively. In the steam flow control method of the steam flow control device,
Transferring a portion of the steam supplied from the boiler to the turbine to a feed water heater, and transferring the remaining portion of the steam to a condenser;
Cooling the steam flowing from the turbine and supplying the cooled steam to the feed water heater;
Reheating the cooled steam flowing from the condenser;
Controlling an opening degree of a first valve to control a flow rate of steam delivered from the turbine to the feed water heater; And
Including the step of controlling the opening of the second valve to adjust the amount of steam delivered from the condenser to the feed water heater;
Controlling the opening degree of the second valve,
Controlling the opening of the second valve to increase or decrease the amount of the steam delivered from the plurality to the water heater according to an increase or decrease in the flow rate of steam added to the water heater according to the opening degree of the first valve Including,
Controlling the opening degree of the second valve,
And controlling the opening of the second valve so that steam exceeded in the predetermined amount is not delivered to the feed water heater when the steam cooled in the condenser is a predetermined amount or more. delete

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