KR101159823B1 - Thermal power station having chimney integrated in building - Google Patents

Abstract

The present invention relates to a stack integrated building provided in a thermal power plant, the stack is discharged gas discharged from the power generation unit; And a building part integrally formed with the stack.
The stack integrated building provided in the thermal power plant according to the present invention integrates the stack unit and the building unit, thereby changing the perception of the stack unit as a hate facility, and can increase the utilization of the site around the stack unit.

Description

Stacked building integrated in thermal power plant {THERMAL POWER STATION HAVING CHIMNEY INTEGRATED IN BUILDING}

The present invention relates to a stack integrated building provided in a thermal power plant, and more particularly, the stack and the building is integrated, the waste heat discharged through the stack is recycled in the building, and the ground is laid out step by step to build the height for the stack It relates to a stack of one-piece building provided in the thermal power plant to reduce.

In general, power plants have facilities for converting thermal energy and mechanical energy into electrical energy, and rotate the turbine using energy sources such as water, coal, natural gas or nuclear power, and generate electricity through a generator connected to the turbine.

Power plants are divided into hydroelectric power plants, thermal power plants, and nuclear power plants according to the type of energy source used and the power generation method.

These power plants are not only limited by location conditions but also have high initial investment.

For example, most of the thermal power plants adjacent to the sea are being built offshore. This is because fuels such as coal, petroleum, and liquefied natural gas, which are used as fuels, are transported from overseas, so it is easy to transport and easily obtain a large amount of water required for operation.

Most of these plants take into account the geological characteristics, considering the environmental impact, the possibility of disaster, the effects of accidents from industrial facilities or storage facilities, the ease of supply of fuel and water required for the operation of the plant, and the expected demand from the electricity demand source. Location will be selected.

The above technical configuration is a background art for helping understanding of the present invention, and does not mean a conventional technology well known in the art.

Exhaust gas generated from the use of raw materials in a conventional thermal power plant is discharged to the outside through the stack. Such stacks usually have a cylindrical shape and comprise a refractory material.

However, since the exhaust gas is discharged to the outside through the stack, the perception that the stack itself is non-environmental is strongly accepted as a hate facility. As a result, no commercial or residential facilities are built around the stack.

Therefore, there is a need to improve this.

The present invention has been made in order to improve the above problems, the stack and the commercial space to be made integrally, the stack is integrated with the coal-fired power plant that can change the perception of the stack and increase the utilization of the site around the stack The purpose is to provide a building.

In addition, an object of the present invention is to provide a stack-integrated building provided in the thermal power plant to reduce the construction height of the stack by arranging the ground in a step.

In order to achieve the above object, the present invention is installed in a high altitude above sea level than the power generation unit, the stack to discharge the gas disposed in the power generation unit; And it provides a stack integrated building provided in the thermal power plant comprising a building unit formed integrally with the stack.

The stack portion is disposed a pair is spaced apart, the building portion is characterized in that disposed between the stack portion.

The outer peripheral surface of the stack portion is characterized in that the display unit for providing information by changing the color.

The stack integrated building provided in the thermal power plant according to the invention is characterized in that it further comprises a temperature control unit for adjusting the temperature of the building using the heat of the stack.

The temperature control part according to the first embodiment of the present invention is a stack heat exchange unit provided in the stack; A building heat exchanger provided in the building unit; And a first circulation portion configured to circulate a refrigerant by connecting the stack heat exchanger and the building heat exchanger.

The temperature control unit according to the first embodiment of the present invention includes a ground heat exchanger provided on the ground; And a second circulation unit configured to circulate the refrigerant by connecting the ground heat exchange unit and the building heat exchange unit.

The temperature control unit according to the second embodiment of the present invention includes a heating unit provided in the stack; A cold water unit provided in the building unit and storing cold water; A hot water unit provided in the building unit and configured to heat and store the cold water passing through the heating unit; And a water supply unit through which the cold water and the hot water are discharged.

The power generation unit is a boiler unit installed in the first base unit; And a desulfurization part connected to the boiler part and installed at a second base part having a higher altitude above sea level than the first base part, wherein the stack is connected to the desulfurization part and has a higher altitude above sea level than the second base part. It is characterized in that it is installed in the third base portion.

The third base portion is characterized in that the elevation above sea level 60m than the first base.

The stack-type integrated building provided in the thermal power plant according to the present invention has an effect that the stack unit for discharging the exhaust gas is integrally formed with a building unit having a commercial space, so that the site around the stack unit can be efficiently used.

In addition, the stack integrated building provided in the thermal power plant according to the present invention is provided with a display unit for displaying information on the outer peripheral surface of the stack, there is an effect that can reduce the negative recognition of the stack.

In addition, the stack-integrated building provided in the thermal power plant according to the present invention by using the waste heat of the exhaust gas discharged through the stack portion by controlling the indoor temperature of the building portion and the water supply temperature, there is an effect of recycling the resources.

In addition, the stack-integrated building provided in the thermal power plant according to the present invention can reduce the construction height of the stack by laying the ground stepped, not only reduce the cost required to build the stack, but also shorten the construction period. It can be effective.

In addition, the chimney-integrated building provided in the thermal power plant according to the present invention can reduce the amount of earth work by arranging the ground in a step, it is possible to shorten the earthwork work period, thereby reducing the construction cost.

In addition, the chimney-integrated building provided in the thermal power plant according to the present invention has the effect of suppressing environmental damage due to the earthwork work by arranging the ground stepwise.

1 is a view schematically showing a stack integrated building provided in a thermal power plant according to a first embodiment of the present invention.
2 is a view schematically showing a stack-integrated building provided in a thermal power plant according to a second embodiment of the present invention.
3 is a view schematically showing a first embodiment of the temperature control unit in a stack integrated building provided in a thermal power plant according to the first and second embodiments of the present invention.
4 is a view schematically showing a second embodiment of the temperature control unit in the stack integrated building provided in the thermal power plant according to the first and second embodiments of the present invention.
5 is a view showing a state in which the third base portion is formed by the ground construction method in the stack-integrated building provided in the thermal power plant according to the first and second embodiments of the present invention.
6 is a view showing a state in which the second base portion is formed by the ground construction method in the stack-integrated building provided in the thermal power plant according to the first and second embodiments of the present invention.
FIG. 7 is a view showing a state in which a first base part is formed by a ground construction method in a stack integrated building provided in a thermal power plant according to the first and second embodiments of the present invention.
8 is a view schematically showing a state in which power generation facilities are arranged stepwise by a ground construction method in a stack integrated building provided in a thermal power plant according to the first and second embodiments of the present invention.
9 is a view showing the construction procedure of the ground construction method in the stack-integrated building provided in the thermal power plant according to the first and second embodiments of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the stack-integrated building provided in the thermal power plant according to the present invention. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, the terms described below are terms 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 the specification.

1 is a view schematically showing a stack integrated building provided in a thermal power plant according to a first embodiment of the present invention, Figure 2 is a schematic view showing a stack integrated building provided in a thermal power plant according to a second embodiment of the present invention It is a figure shown.

1 and 2, the chimney-integrated building (1, 2) provided in the thermal power plant according to the first and second embodiments of the present invention, the chimney portion (11, 21) and the building portion 12, 22).

The chimney parts 11 and 21 discharge the waste gas discarded by the power generation unit 13. That is, the power generation units 13 and 23 drive the turbine using the raw material as a heat source, and the exhaust gas discharged while burning the raw material is moved to the stack parts 11 and 21 through the pipes 14 and 24.

The chimneys 11 and 21 are formed of a refractory material resistant to heat, have a cylindrical shape, and have an upper opening.

The stacks 11 and 21 have a height sufficient to allow the discharged gas to be dispersed in the atmosphere without affecting the surroundings. For example, the stacks 11 and 21 have a height of 90 m to 150 m.

The building parts 12 and 22 are integrally formed with the stack parts 11 and 21. The building units 12 and 22 are buildings having commercial spaces or residential spaces, and are designed in two layers.

The building units 12 and 22 are used as control rooms for controlling thermal power plants, offices and restaurants of thermal power plant employees.

The observatory 22a is further provided in the building part 22. The gazebo 22a is disposed above the building part 22 or spaced apart from the building part 22.

Observation deck (22a) is disposed at the same height in the upper end of the chimney (11, 21), through the observation deck (22a) can view the thermal power plant located on the coast or to tour the beach. This gazebo 22a eliminates aversion to the stacks 11 and 21 that discharge the exhaust gas.

When one stack unit 11 is installed in the stack integrated building 1 provided in the thermal power plant, the building unit 12 is disposed on one side or the other side of the stack 11 (see FIG. 1). On the other hand, when a pair of stack parts 21 are installed in the stack integrated building 2 provided in a thermal power plant, the building parts 22 are arrange | positioned between the stack parts 21 (refer FIG. 2).

The chimney part 11 and 21 and the building part 12 and 22 are integrally formed in the construction process, and may be formed as a separate building and the outer wall may be integrally formed.

Display portions 15 and 25 are provided on the outer circumferential surfaces of the stack portions 11 and 21. Such display units 15 and 25 are artificially changed in their color by an LED lamp or the like.

The display units 15 and 25 can be easily identified in the neighboring area by the height of the stacks 11 and 21, thereby allowing the neighbors to recognize the information. For example, the display units 15 and 25 may change color according to the weather to inform the weather information, and other letters or promotional images are displayed to provide various information.

3 is a view schematically showing a first embodiment of the temperature control unit in the stack integrated building provided in the thermal power plant according to the first and second embodiments of the present invention, Figure 4 is a first, 2 is a diagram schematically illustrating a second embodiment of a temperature control unit in a stack integrated building provided in a thermal power plant according to a second embodiment.

Referring to Figures 3 and 4, the chimney integrated building (1, 2) provided in the thermal power plant according to the first and second embodiments of the present invention is provided with a temperature control unit (100, 200). The temperature control unit (100, 200) controls the temperature of the building unit (12, 22) by using the waste heat discarded from the stack (11, 21).

The temperature control unit 100 according to the first embodiment of the present invention relates to an air conditioner, and the temperature control unit 200 according to the second embodiment of the present invention relates to a cold and hot water machine.

Referring to Figure 3, the temperature control unit 100 according to the first embodiment of the present invention is provided with a stack heat exchanger 110, a building heat exchanger 120 and the first circulation 130.

The stack heat exchange unit 110 is provided at the stacks 11 and 21. The stack heat exchanger 110 absorbs the heat of the exhaust gas in accordance with the movement direction of the refrigerant to form a high temperature refrigerant or discharges heat to the exhaust gas to form a low temperature refrigerant.

The building heat exchange part 120 is provided in the building parts 12 and 22. The building heat exchange parts 12 and 22 discharge hot or cold air into the building parts 12 and 22 according to the moving direction of the refrigerant.

The first circulation unit 130 connects the stack heat exchanger 110 and the building heat exchanger 120 to circulate the refrigerant. One end of the first circulation unit 130 is in communication with the stack heat exchange unit 110, and the other end is a pair of communication with the building heat exchange unit 120, respectively.

A compressor, a condenser, and the like are installed in the first circulation unit 130, whereby the refrigerant is compressed or condensed.

The temperature controller 100 functions as a heat pump and discharges cold or warm air to the building units 12 and 22 according to the moving direction of the refrigerant.

For example, the refrigerant absorbing heat while passing through the stack heat exchange unit 110 discharges high-temperature air while passing through the building units 12 and 22, and the refrigerant cooled while passing through the stack heat exchange unit 110. Low temperature air is discharged while passing through the building parts 12 and 22.

On the other hand, the temperature control unit 100 according to the first embodiment of the present invention is further provided with a ground heat exchange unit 140 and the second circulation unit 150.

The ground heat exchanger 140 is provided on the ground. The ground heat exchanger 140 performs heat exchange using geothermal heat and cools the heated refrigerant.

The second circulation unit 150 connects the ground heat exchanger 140 and the building heat exchanger 120 to circulate the refrigerant. One end of each of the second circulation parts 150 communicates with the ground heat exchange part 140, and the other end of the second circulation part 150 communicates with the building heat exchange part 120.

In this case, the first circulation unit 130 and the second circulation unit 150 may communicate with each other so that the refrigerant may cross-circulate, and a valve (not shown) may be mounted on the first circulation unit 130 and the second circulation unit 150. To change the movement path of the refrigerant.

The second circulation unit 150 is provided with a compressor, a condenser, etc. Due to this, the refrigerant is compressed or condensed.

The temperature control unit 100 including the ground heat exchanger 140 heats the refrigerant through the high temperature stacks 11 and 21 and cools the refrigerant through the ground. The coolant temperature control cools the coolant through the ground rather than cooling the coolant in the high temperature stacks 11 and 21.

For example, the refrigerant absorbing heat while passing through the stack heat exchange unit 110 discharges high-temperature air while passing through the building units 12 and 22, and the refrigerant cooled while passing through the ground heat exchange unit 140. Low temperature air is discharged while passing through the building parts 12 and 22.

Referring to the operation of the temperature control unit 100 according to the first embodiment of the present invention.

When the building units 12 and 22 need to be heated, the refrigerant heated while passing through the stack heat exchange unit 110 is cooled while passing through the building heat exchange unit 120, whereby the building heat exchange unit 120 is constructed as a building unit ( 12,22) to discharge hot air into the interior.

The refrigerant passing through the building heat exchange unit 120 is heated while passing through the stack heat exchange unit 110 and then cooled while passing through the building heat exchange unit 120, whereby the building heat exchange unit 120 is the building unit 12 and 22. ) The process of discharging hot air into the interior is repeated.

When cooling is required for the building parts 12 and 22, the refrigerant cooled while passing through the stack heat exchange part 110 is heated while absorbing the surrounding heat while passing through the building heat exchange part 120, thereby causing the building heat exchange part ( 120 discharges low-temperature air into the building parts 12 and 22.

The refrigerant passing through the building heat exchange unit 120 is cooled while passing through the stack heat exchange unit 110, and then heated while passing through the building heat exchange unit 120, whereby the building heat exchange unit 120 is the building unit 12 and 22. ) The process of discharging low temperature air is repeated.

On the other hand, the refrigerant passing through the building heat exchanger 120 may be cooled while passing through the ground heat exchanger 140 and then heated while passing through the building heat exchanger 120, whereby the building heat exchanger 120 is a building part. The process of discharging low temperature air into (12,22) is repeated.

Referring to FIG. 4, the temperature controller 200 according to the second embodiment of the present invention includes a heating unit 210, a cold water unit 220, a hot water unit 230, and a water supply unit 240.

The heating unit 210 is provided in the stacks 11 and 21, and heat of exhaust gas discharged to the outside through the stacks 11 and 21 is conducted.

The cold water unit 220 is provided in the building units 12 and 22 and cold water is stored. The cold water unit 220 is supplied with cold water through the water supply source 250.

The hot water unit 230 is provided in the building units 12 and 22 and hot water is stored. That is, when cold water becomes hot water through the heating unit 210, it is stored in the hot water unit 230.

The water supply unit 240 is provided in the building units 12 and 22, and the cold water stored in the cold water unit 220 and the hot water stored in the hot water unit 230 are discharged. The water supply unit 240 may be a faucet of a shower room or a bathroom.

The temperature control unit 200 according to the second embodiment of the present invention is moved through the first to sixth feed pipes 261, 262, 263, 264, 265, and 266, and they may be equipped with a valve or a pump to control the movement of cold or hot water.

The first water supply pipe 261 connects the water supply source 250 and the cold water unit 220 to guide the cold water of the water supply source 250 to the cold water unit 220. The second water supply pipe 262 connects the heating unit 210 and the cold water unit 220 to guide a part of the cold water of the cold water unit 220 to the heating unit 210.

The third water supply pipe 263 connects the heating unit 210 and the hot water unit 230 to guide the hot water heated by the heating unit 210 to the hot water unit 230. The fourth water supply pipe 264 connects the hot water unit 230 and the heating unit 210 to guide the hot water that is less warmed from the hot water unit 230 to the heating unit 210.

The fifth water supply pipe 265 connects the cold water part 220 and the water supply part 240 to guide the cold water to the water supply part 240, and the sixth water supply pipe 266 is the hot water part 230 and the water supply part 240. Connect the hot water to the water supply unit 240.

Referring to the operation of the temperature control unit 200 according to the second embodiment of the present invention.

Cold water from the water supply source 250 is supplied to the cold water unit 220 through the first water supply pipe 261, and some of the cold water stored in the cold water unit 220 is supplied to the water supply unit 240 through the fifth water supply pipe 265. It is moved and discharged to the outside.

Some of the cold water stored in the cold water unit 220 is moved to the heating unit 210 through the second water supply pipe 262 and heated, and the hot water passing through the heating unit 210 is the hot water unit through the third water supply pipe 263. It is moved to 230 and stored.

When the temperature of the hot water stored in the hot water unit 230 is low, it is moved to the heating unit 210 through the fourth water supply pipe 264 and reheated.

The hot water stored in the hot water unit 230 is moved to the water supply unit 240 through the sixth water supply pipe 266 and discharged to the outside.

5 is a view showing a state in which the third base portion is formed by the ground construction method in the stack integrated building provided in the thermal power plant according to the first and second embodiments of the present invention, Figure 6 is a first, second embodiment of the present invention 2 is a view illustrating a state in which a second base part is formed by a ground construction method in a stack integrated building provided in a thermal power plant according to a second embodiment.

7 is a view showing a state in which the first base portion is formed by the ground construction method in the stack-integrated building provided in the thermal power plant according to the first and second embodiments of the present invention, Figure 8 is a first, second embodiment of the present invention 2 is a diagram schematically illustrating a state in which power generation facilities are arranged stepwise by a ground construction method in a stack integrated building provided in a thermal power plant according to an embodiment.

9 is a view showing the construction procedure of the ground construction method in the stack-integrated building provided in the thermal power plant according to the first and second embodiments of the present invention.

5 to 9, prior to the construction of the stack-integrated building (1, 2) provided in the thermal power plant, the first base portion 31, the second base portion 32, the third base portion 33 Form. To this end, the ground (E) is carried out using a variety of equipment, such as excavators are carried out earthwork.

This basic part manufacturing step is to form a third base portion 33 by earthworking the third earthwork part 43 (S10), the second earthwork part 32 by earthworking the second earthwork part 42 Forming step (S20), the first earthworking part 41 is earthworked to form a first base portion 31 is subdivided into step (S30).

Step (S10) of forming the third base portion 33 is made by earthworking the site of the highest elevation above sea level (E). As a result, the third base portion 33 is disposed at a higher altitude than the first base portion 31 and the second base portion 32.

That is, the third base portion 33 is formed by earthworking the third earth hole 43 so that the altitude above sea level is higher than the joined second base portion 32. When the formation of the third base portion 33 is completed, the earth work of the ground E for forming the second base portion 32 is performed.

The step S20 of forming the second base part 32 is performed by earthworking a part of the ground E connected to the third base part 33. As a result, the second base portion 32 is disposed at a lower altitude than the third base portion 33.

That is, the second base portion 32 is formed by earthworking the second earth hole 42 so that the altitude above sea level is lower than that of the joined third base portion 33 and the altitude above sea level is higher than that of the first base portion 31. do. In the present embodiment, the second base portion 32 is formed at an altitude of 30 m lower than the third base portion 33, and is formed at an altitude of 30 m higher than the first base portion 31.

The portion where the third base portion 33 and the second base portion 32 are in contact, that is, the second connection portion 35 is formed to be inclined. At this time, the angle formed by the inclined surface of the second connecting portion 35 may be formed at an angle such that the ground E does not collapse. Typically this angle is determined around 60 degrees, referred to as the angle of repose. Of course, the size of the angle of repose can be properly adjusted according to the working environment.

When the formation of the second base portion 32 is completed, the earth work of the ground E for forming the first base portion 31 is performed.

The step S30 of forming the first base part 31 is performed by earthworking a part of the ground E connected to the second base part 32. As a result, the first base portion 31 is disposed at a lower elevation than the second base portion 32 as well as the third base portion 33.

That is, the first base portion 31 is formed by earthworking the first earth hole 41 so that the altitude above sea level is lower than the second base portion 32 in contact with each other.

The portion where the second base portion 32 and the first base portion 31 are connected, that is, the first connection portion 34 is formed to be inclined. At this time, the angle formed by the inclined surface of the first connecting portion 34 may be formed at an angle such that the ground E does not collapse. Typically this angle is determined around 60 degrees, referred to as the angle of repose. Of course, the size of the angle of repose can be properly adjusted according to the working environment.

Referring to FIG. 8, the altitude difference between the first base part 31 and the third base part 33 is 60 m. At this time, the power generation parts 13 and 23 are installed in the first base part 31 and the second base part 32, and the stack parts 11 and 21 and the building part 12, respectively, in the third base part 33. 22) is installed. Therefore, the height of the stacks 11 and 21 itself can be reduced by 60 m.

The stacks 11 and 21 are designed to continuously burn fuel by discharging the exhaust gas generated after combustion in the furnace to the outside, and buoyancy is generated due to the difference in density because the exhaust gas has a higher temperature than the surrounding air. Rises up and is released into the atmosphere.

Regarding the construction height of the stacks (11, 21), Article 56 of the Enforcement Regulations of the Atmospheric Environment Conservation Act and [Installation Table 12] of the Solid Fuel Utilization Facility stipulate the height of the chimney of the coal use facility to be 100 m or more. The United States Environmental Protection Agency (USEPA) prevents down washes and down drafts that prevent air from spreading pollutants from stacks (11,21). For this purpose, the "Guideline for Determination of Good Engineering Practice Stack Height" is recommended to determine the minimum stack height by considering the tallest building around the stack and the width of the building.

However, the theoretical final stack heights (11, 21) were calculated using the Gaussian diffusion model above the heights determined by both of the above, and the maximum landing concentration of pollutants was calculated. It should not exceed. In other words, the height of the stacks 11 and 21 by the Gaussian diffusion model increases the maximum landing concentration of pollutants (SO ₂ , NO ₂ , PM _10, etc.) and the vicinity of the power plant when diffusing the exhaust gas discharged from the stacks 11 and 21. The sum of the air quality concentrations in the region should be designed so that it does not exceed the air environmental standards of the Framework Act on Environmental Policy.

In consideration of the various criteria, the construction height of the stack parts 11 and 21 according to the present embodiment is estimated to be 150 m based on the first base part 31 on which the power generation unit 13 is installed.

Therefore, since the height of the third base portion 33 on which the stack portions 11 and 21 are constructed is already 60 m higher than the first base portion 31, the height of the stack portions 11 and 21 may be increased. The height difference between the base portion 33 and the first base portion 31 can be reduced by 60 m.

As such, when the third base portion 33 is formed higher than the first base portion 31, the height of the stack portions 11 and 21 by the height difference can be reduced, so that the stack portions 11 and 21 are constructed. In addition to reducing the cost, the construction period can also be shortened.

In addition, the third base portion 33 is formed by earthworking the existing ground E, since the third base portion 33 is formed higher than the second base portion 32 and the first base portion 31, There is an advantage that can reduce the amount of earthwork required to form the third base portion (33). The reduction in the amount of earthwork is linked with the shortening of the earthwork period, so that a cost reduction can be achieved.

In addition, since the first base portion 31, the second base portion 32 and the third base portion 33 are formed to gradually increase in height stepwise, it is advantageous to minimize the environmental damage than to form a flat There is this.

When formation of the first base portion 31, the second base portion 32, and the third base portion 33 is completed, the power generation portion 13 may be formed in the first base portion 31 and the second base portion 32. 23) and the stack 11, 21 and the building portion 12, 22 to the third base portion 33.

In the earthwork work, the third base part 33, the second base part 32, and the first base part 31 were carried out in order, but the power generation parts 13 and 23, the stack parts 11 and 21, and the building The parts 12 and 22 may be constructed simultaneously or sequentially, which may be performed in various orders depending on the working environment.

In one embodiment of the present invention, the power generation unit 13, 23 is provided with a boiler 51 and the desulfurization unit 52. The boiler unit 51 includes a boiler, and the desulfurization unit 52 includes a dust collector and a desulfurization facility.

The boiler unit 51 is a device that burns fuel such as coal and transmits the combustion heat to water to generate steam, and the exhaust gas generated from the boiler unit 51 passes through the dust collector through the first pipe line 61. The included dust is removed, and the sulfur oxide contained in the inside is removed while passing through a desulfurization facility such as an absorption tower, and then discharged to the outside through the stacks 11 and 21 through the second pipe 62. In this process, the exhaust gas passes through a gas-gas heat exchanger (not shown) in which heat exchange is performed between the flue gas before the desulfurization process and the flue gas undergoing the desulfurization process.

The first pipe line 61 is disposed to be exposed to the ground and is supported by the first base part 31, the first connecting part 34, and the second base part 32. That is, even if a separate support member for supporting the first pipe line 61 is not configured, the first pipe line 61 is stably supported by the ground E. Therefore, it is not necessary to separately configure the support member for supporting the first pipe line 61 can shorten the construction period, it is possible to reduce the construction cost.

Meanwhile, the first pipe line 61 may be buried in the basement of the first joint part 34 and the second base part 32 without being exposed to the ground, and in this case, may be completely protected from external impact. . As such, even when the first pipe line 61 is buried underground, the first pipe line 61 is supported by the lower ground of the first connecting portion 34 and the second base portion 32, thereby forming a separate supporting member. You do not have to do.

The desulfurization unit 52 and the stacks 11 and 21 are connected by the second pipe line 62, and the exhaust gas from which sulfur oxides are removed from the desulfurization facility is discharged to the atmosphere through the stacks 11 and 21.

The second conduit 62 is disposed to be exposed to the ground and is supported by the second base part 32, the second connecting part 35, and the third base part 33. That is, even if a separate support member for supporting the second conduit 62 is not configured, the second conduit 62 is stably supported by the ground E. Therefore, it is not necessary to separately configure a support member for supporting the second pipe 62 can shorten the construction period, it is possible to reduce the construction cost.

On the other hand, the second conduit 62 may be buried in the basement of the second connecting portion 35, the third base portion 33 without being exposed to the ground, in this case it can be completely protected from external impact. . As such, even when the second conduit 62 is buried underground, the second conduit 62 is supported by the lower ground of the second joint part 35 and the third base part 33. It is not necessary to configure a separate support member for supporting.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. I will understand.

Therefore, the true technical protection scope of the present invention will be defined by the claims below.

1,2: All-in-one building with thermal power plant
11,21: stack part 12,22: building part
110: stack heat exchanger 120: building heat exchanger
130: first circulation part 140: ground heat exchanger
150: second circulation portion 210: heating portion
220: cold water part 230: hot water part
240: water supply

Claims (9)

A chimney part installed at a higher elevation than the power generation part and discharging the gas disposed in the power generation part; And
The stack integrated building provided in the thermal power plant, characterized in that it comprises a building unit formed integrally with the stack. The method of claim 1,
The stack has a pair of spaced apart,
The building unit is a stack integral building provided in the thermal power plant, characterized in that disposed between the stack. 3. The method according to claim 1 or 2,
The chimney-integrated building provided in the thermal power plant, characterized in that the display unit for providing information by changing the color on the outer peripheral surface of the stack. 3. The method according to claim 1 or 2,
The stack integrated building provided in the thermal power plant, characterized in that it further comprises a temperature control unit for controlling the temperature of the building unit by using the heat of the stack. The method of claim 4, wherein the temperature control unit
Stack heat exchange unit provided in the stack;
A building heat exchanger provided in the building unit; And
A stack integrated building provided in the thermal power plant, characterized in that it comprises a first circulation portion for circulating the refrigerant by connecting the stack heat exchange unit and the building heat exchange unit. 6. The method of claim 5,
A ground heat exchanger provided on the ground; And
The stack integrated building provided in the thermal power plant characterized in that it further comprises a second circulation unit for circulating the refrigerant by connecting the ground heat exchange unit and the building heat exchange unit. The method of claim 4, wherein the temperature control unit
A heating unit provided in the stack;
A cold water unit provided in the building unit and storing cold water;
A hot water unit provided in the building unit and configured to heat and store the cold water passing through the heating unit; And
A stack integrated building provided in the thermal power plant, characterized in that it comprises a water supply unit for discharging the cold water and the hot water. The method of claim 1,
The power generation unit
A boiler unit installed on the first base unit;
A desulfurization unit connected to the boiler unit and installed on a second base unit having a higher altitude above sea level than the first base unit;
The stack is connected to the desulfurization unit, the stack integrated building provided in the thermal power plant, characterized in that installed in the third base portion having a higher elevation than the second base portion. The method of claim 8,
The third base unit is a stack integrated building provided in the thermal power plant, characterized in that the elevation above sea level 60m than the first base.

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