CN210087404U - Steam turbine radiating component and power generation system - Google Patents

Abstract

The utility model relates to a thermal power field discloses a steam turbine radiator unit and power generation system, wherein, steam turbine radiator unit includes boiler workshop (1), steam turbine workshop (2), air cooling platform (3) and exhaust steam pipe way (4), exhaust steam pipe way (4) connect in the steam vent of steam turbine supports on the air cooling platform (3), air cooling platform (3) orientation one side of steam turbine workshop (2) is provided with the orientation prevent wind that steam turbine workshop (2) extend, prevent wind and can block partially at least air cooling platform (3) with the air current along vertical direction between the steam turbine workshop (2). Through above-mentioned technical scheme, through setting up in one side in the air cooling platform towards the steam turbine workshop and prevent wind the piece, can partially block that the hot-blast air that blocks the air cooling platform upside flows to the air cooling platform downside from air cooling platform and steam turbine workshop to avoid hot-blast backward flow, guarantee the radiating efficiency of air cooling platform.

Description

Steam turbine radiating component and power generation system

Technical Field

The utility model relates to a thermal power field specifically relates to steam turbine radiator unit and power generation system.

Background

The thermal power plant includes boiler factory building and steam turbine factory building, in order to reduce the length of pipeline between steam turbine and the boiler and turn round, can be with the steam turbine design for roughly as high as the boiler.

The steam exhausted by the steam turbine can be cooled by a direct air cooling system, a height difference exists between the air cooling platform and the steam turbine plant, the steam turbine plant can cause certain adverse effect on the air cooling platform system, when wind blows to the steam turbine plant from the air cooling platform, the cooling unit close to the steam turbine plant is not smooth in heat dissipation, a hot wind backflow phenomenon exists, the cooling capacity of the air cooling system is reduced, and the unit backpressure is increased; when wind comes from the side of the boiler plant, the cooling unit close to the side of the turbine plant is not smooth in heat dissipation due to the blockage of the turbine plant, and is influenced by the backflow of hot wind, so that the cooling capacity of the air cooling system is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a steam turbine radiator unit to solve the air cooling platform and appear hot-blast backward flow, the problem that cooling heat-sinking capability descends easily.

In order to achieve the above object, the present invention provides, in one aspect, a heat dissipating assembly for a steam turbine, wherein, the steam turbine heat radiation component comprises a boiler workshop provided with a boiler, a steam turbine workshop provided with a steam turbine, an air cooling platform and a steam exhaust pipeline, the steam outlet of the boiler is arranged at the same height as the steam inlet of the steam turbine and is connected with the steam inlet of the steam turbine through a steam pipeline, the air cooling platform is horizontally spaced from the steam turbine workshop and comprises a fan array at the lower part and a heat dissipation unit array at the upper part, the exhaust duct is connected to the exhaust port of the steam turbine and supported on the heat dissipation unit array, a wind-proof piece extending towards the steam turbine workshop is arranged on one side of the air cooling platform facing the steam turbine workshop, the windbreak is capable of at least partially blocking airflow in a vertical direction between the air-cooled platform and the turbine plant.

Preferably, the wind guard includes a wind guard plate including an inclined portion having a first end connected to the air-cooling platform and a second end inclined downward with respect to the first end of the inclined portion, and a vertical portion connected to the second end of the inclined portion and extending downward.

Preferably, the inclined portion has an inclination angle of 45 ° to 90 ° with respect to a horizontal plane, a length of the inclined portion from the air-cooling platform toward the steam turbine plant is 0m to 5m, and a length of the vertical portion in a vertical direction is 6m to 14 m.

Preferably, the wind guard includes a wind guard plate including a slope portion having a first end connected to the air-cooling platform and a second end inclined downward with respect to the first end of the slope portion, and a horizontal portion connected to the second end of the slope portion and extending toward the turbine plant.

Preferably, the inclined portion has an inclination angle of 45 ° to 90 ° with respect to a horizontal plane, the length of the inclined portion from the air cooling platform toward the turbine shop is 0m to 5m, and the length of the horizontal portion from the air cooling platform toward the turbine shop is 6m to 14 m.

Preferably, the wind guard plate is a grating plate.

Preferably, the inclined portion is connected to a joint position of the fan array and the heat dissipation unit array.

Preferably, a vertical air duct is arranged in the heat dissipation unit array.

Preferably, a wind shielding wall is disposed around the heat dissipation unit array, and the height of the wind shielding wall is greater than that of the heat dissipation unit array.

Preferably, the fan array includes a plurality of axial flow fans, each of which is disposed in an air duct extending in a vertical direction.

Preferably, the air-cooled platform includes a frame structure supporting the fan array, the frame structure being supported by a plurality of support columns.

Preferably, the horizontal distance between the steam turbine workshop and the air cooling platform is 13.5m-16m, the heights of the steam turbine workshop and the boiler workshop are 80m-90m respectively, and the height of the air cooling platform is 35m-45 m.

Additionally, the utility model discloses another aspect still provides a power generation system, wherein, power generation system includes above scheme steam turbine radiator unit.

Through above-mentioned technical scheme, through setting up in one side in the air cooling platform towards the steam turbine workshop and prevent wind the piece, can partially block that the hot-blast air that blocks the air cooling platform upside flows to the air cooling platform downside from air cooling platform and steam turbine workshop to avoid hot-blast backward flow, guarantee the radiating efficiency of air cooling platform.

Drawings

Fig. 1 is a schematic view of a steam turbine heat dissipating assembly according to an embodiment of the present invention, viewed in a horizontal direction;

FIG. 2 is a top view of a steam turbine heat sink assembly according to an embodiment of the present invention;

FIG. 3 is an enlarged view of a portion of the windbreak according to an embodiment of the present invention;

fig. 4 is an enlarged view of a portion of a wind guard according to another embodiment of the present invention.

Description of the reference numerals

1 boiler workshop 2 steam turbine workshop

3 air cooling platform 4 steam exhaust pipelines

5 wind-proof board 6 wind-proof wall

7 support column

51 inclined part 52 vertical part

53 horizontal part

Detailed Description

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings. It is to be understood that the description of the embodiments herein is for purposes of illustration and explanation only and is not intended to limit the invention.

The utility model provides a steam turbine heat radiation component, which comprises a boiler workshop 1 provided with a boiler, a steam turbine workshop 2 provided with a steam turbine, an air cooling platform 3 and a steam exhaust pipeline 4, the steam outlet of the boiler is arranged at the same height as the steam inlet of the steam turbine and is connected with the steam inlet of the steam turbine through a steam pipeline, the air cooling platform 3 is horizontally spaced from the steam turbine workshop 2, the air cooling platform 3 comprises a lower fan array 31 and an upper radiating unit array 32, the exhaust duct 4 is connected to the exhaust port of the steam turbine and supported on the radiating unit array 32, the side of the air cooling platform 3 facing the steam turbine workshop 2 is provided with a wind-proof piece extending towards the steam turbine workshop 2, the wind shield can at least partially block the air flow in the vertical direction between the air-cooled platform 3 and the turbine shop 2.

Boiler shop 1 is used for holding the boiler, steam turbine shop 2 is used for holding the steam turbine, wherein, the whole height of boiler is about 70 meters to 80 meters, its steam outlet sets up at the boiler top, in order to reduce or even eliminate the height drop between boiler and the steam turbine, can support the steam turbine at higher height (rather than putting at the position nearer apart from ground), make the steam inlet of steam turbine and the steam outlet of boiler be in the same height, the steam conduit who connects steam turbine steam inlet and steam outlet does not have height drop basically, the transport distance of steam has been reduced.

The steam is discharged through the steam outlet of the steam turbine after acting in the steam turbine, namely, the steam is discharged through the steam discharge pipeline 4, the steam discharge pipeline 4 is supported on the heat dissipation unit array 32 of the air cooling platform 3, and therefore the steam discharge pipeline 4 and the steam in the steam discharge pipeline are cooled through the air cooling platform 3. The heat dissipation unit array 32 includes a plurality of heat dissipation units having good heat conductivity, and the heat dissipation units have a large heat dissipation area, and the heat of the exhaust duct 4 can be transferred to the heat dissipation units to expand the heat dissipation area and the heat dissipation efficiency. Specifically, the fan array 31 is disposed on the lower side of the heat dissipation unit array 32, that is, a heat dissipation airflow is formed from bottom to top by the fan array 31, that is, the airflow on the lower side of the fan array 31 is conveyed to the heat dissipation unit array 32, so as to perform air cooling heat dissipation on the heat dissipation unit array 32.

It should be noted that the steam inlet of the steam turbine is located approximately at the top of the steam turbine, and the steam outlet is located at the bottom, so that the height of the air cooling platform 3 is smaller than that of the steam turbine, i.e., the steam turbine plant 2. A horizontal interval is kept between the air cooling platform 3 and the steam turbine workshop 2, when the wind direction is approximately from the air cooling platform 3 to the steam turbine workshop 2 (a certain angle can be formed with the direction), the airflow above the air cooling platform 3 reaches the steam turbine workshop 2 and then is blocked and flows downwards, so that the high-temperature airflow above the air cooling platform 3 can flow to the vicinity of the fan array 31, namely, hot wind flows back, and the heat dissipation capacity of the air cooling platform 3 is influenced; when the wind direction is roughly when following steam turbine workshop 2 towards air cooling platform 3 (can form certain angle with this direction), because sheltering from of boiler workshop 1 and steam turbine workshop 2, the partial radiating element array heat dissipation that is close to steam turbine workshop 2 one side is unfavorable, hot-blast backward flow also can appear, influences the radiating effect.

Consequently, this scheme sets up in one side of air cooling platform 3 towards steam turbine workshop 2 and prevent wind the piece, stops the air current from the top down flow between air cooling platform 3 and steam turbine workshop 2 at least partially through preventing wind, avoids the air current of 3 upsides of air cooling platform to flow its downside, avoids hot-blast backward flow phenomenon to appear, guarantees that air cooling platform 3 has sufficient radiating efficiency.

As for the wind-proof member, various solid structures may be included as long as they can block the flow of the air current.

According to a specific embodiment of the present invention, the wind-proof member includes a wind-proof plate 5, the wind-proof plate 5 includes an inclined portion 51 and a vertical portion 52, a first end of the inclined portion 51 is connected to the air-cooling platform 3, a second end of the inclined portion 51 is inclined downward with respect to the first end of the inclined portion 51, and the vertical portion 52 is connected to the second end of the inclined portion 51 and extends downward. The wind guard includes a wind guard plate 5 having a plate-like structure, as shown in fig. 3, the wind guard plate 5 includes an inclined portion 51 inclined downward, and the inclined portion 51 is connected with a vertical portion 52 extending downward, the inclined portion 51 is inclined in such a manner as to weaken a force with the vertically downward air flow, and the vertical portion 52 may further protect the air-cooling platform 3 (particularly, the fan array 31) against the air flow having a higher temperature toward the air-cooling platform 3.

Preferably, the inclined portion 51 is inclined at an angle of 45 ° to 90 ° with respect to a horizontal plane, a length of the inclined portion 51 from the air cooling platform toward the steam turbine workshop 2 is 0m to 5m, and a length of the vertical portion 52 in a vertical direction is 6m to 14 m. The lengths of the inclined portion 51 and the vertical portion 52 both refer to the lengths in the cross section shown in fig. 3, wherein when the inclined portion 51 is 0, it means that the inclined portion 51 is no longer provided, and the fan array 31 is protected from the hot air flow only by the vertical portion 52. The length of the inclined portion 51 may be 0, 1m, 2m, 3m, 4m, 5m, and the length of the vertical portion 52 may be 6m, 7m, 8m, 9m, 10m, 11m, 12m, 13m, 14 m.

According to another embodiment of the present invention, the wind guard comprises a wind guard plate 5, the wind guard plate 5 comprises an inclined portion 51 and a horizontal portion 53, a first end of the inclined portion 51 is connected to the air cooling platform 3, a second end of the inclined portion 51 is inclined downward with respect to the first end of the inclined portion 51, and the horizontal portion 53 is connected to the second end of the inclined portion 51 and extends toward the turbine workshop 2. The wind guard includes a wind guard plate 5 having a plate-shaped structure, as shown in fig. 4, the wind guard plate 5 includes an inclined portion 51 inclined downward, and the inclined portion 51 is connected with a horizontal portion 53 extending toward the turbine workshop 2, the inclined portion 51 is inclined in such a manner as to weaken the force between the air flow vertically downward, and the horizontal portion 53 increases the width occupied by the wind guard plate 5 between the air-cooling platform 3 and the turbine workshop 2, and reduces the air flow flowing from top to bottom, so that less air flow having a higher temperature reaches the fan array 31.

Preferably, the inclined portion 51 is inclined at an angle of 45 ° to 90 ° with respect to a horizontal plane, the length of the inclined portion 51 from the air cooling platform toward the turbine plant 2 is 0m to 5m, and the length of the horizontal portion 53 from the air cooling platform toward the turbine plant 2 is 6m to 14 m. The inclination angle of the inclined portion 51 may be 45 °, 60 °, 75 °, 90 °. The length of both the inclined portion 51 and the vertical portion 52 refers to the length in the cross section shown in fig. 3, wherein in an embodiment where the length of the inclined portion is 0, this means that the inclined portion 51 is no longer provided, but the fan array is protected from the hot air flow by blocking the hot air flow only by the horizontal portion 53. The length of the inclined part 51 may be 0, 1m, 2m, 3m, 4m, 5m, and the length of the horizontal part 52 may be 6m, 7m, 8m, 9m, 10m, 11m, 12m, 13m, 14 m.

Fig. 3 and 4 show enlarged views from the side, viewed horizontally, in which the wind deflector 5 can be arranged along one edge of the air cooling platform 3 adjacent to the turbine plant 2, i.e. extending perpendicularly to the plane of the paper in fig. 3 or 4, over a length which is approximately equal to the dimension of the edge of the air cooling platform 3 adjacent to the turbine plant.

The wind-proof plate 5 may be various, such as a solid plate, a plate with through holes, and preferably, the wind-proof plate 5 is a grid plate. That is, the inclined portion 51, the vertical portion 52, or the horizontal portion 53 described above may be formed in a lattice shape, and for example, a lattice shape having a gap may be composed of a plurality of strip-shaped plates. The wind deflector 5 can block a part of the air flow flowing from top to bottom, but does not completely close the space between the air-cooled platform 3 and the turbine workshop 2, so that on the one hand, the acting force applied to the wind deflector 5 can be reduced, and on the other hand, part of the air flow on the upper side and the lower side of the air-cooled platform 3 can be allowed to circulate.

Further, the inclined portion 51 is connected to a joint position of the fan array 31 and the heat radiating unit array 32. As shown in fig. 3 and 4, the inclined portion 51 is connected to the joint position of the fan array 31 and the heat dissipating unit array 32, i.e. the substantially planar interface between the fan array 31 and the heat dissipating unit array 32, i.e. the fan array 31 is protected by the wind guard 5, which prevents the air flow with higher temperature on the air cooling platform 3 from returning to the fan array 31, and ensures that the air flow delivered upward by the fan array 31 has lower temperature, and ensures the heat dissipating capability of the air cooling platform 3.

Further, a vertical air duct is disposed in the heat dissipation unit array 32. The fan array 31 is disposed at the lower side of the heat dissipation unit array 32, and can provide heat dissipation airflow from bottom to top to perform air cooling heat dissipation on the heat dissipation unit array 32, so that a vertical air duct can be disposed in the heat dissipation unit array 32 to allow the heat dissipation airflow to smoothly pass through the heat dissipation unit array 32. The heat dissipation unit array 32 may include a plurality of sets of heat dissipation fins (i.e., heat dissipation units) that are in sufficient contact with the exhaust pipe 4 to receive heat of the exhaust pipe 4 in a heat conduction manner, and may indirectly perform heat dissipation processing on the exhaust pipe 4 through air cooling processing on the heat dissipation unit array 32.

As shown in fig. 2, the heat dissipation unit array 32 is arranged as a substantially quadrangular support platform structure, and may be configured to support the steam exhaust duct 4, the steam exhaust duct 4 may include a main duct portion directly connected to the steam outlet of the steam turbine and a plurality of branch duct portions connected to the main duct portion, the plurality of branch duct portions are disposed on the heat dissipation unit array 32, and the plurality of branch duct portions are connected to the main duct portion, so that the overall heat dissipation area of the steam exhaust duct 4 may be increased, and the heat dissipation efficiency may be improved.

Further, a wind shield wall 6 is disposed around the heat dissipating unit array 32, and the height of the wind shield wall 6 is greater than the height of the heat dissipating unit array 32. As shown in fig. 1, the wind blocking wall 6 may be disposed at a side edge of the heat dissipation unit array 32, and has a height greater than that of the heat dissipation unit array 32, blocks horizontal airflow, and protects the airflow at the heat dissipation unit array 32 from the outside from the horizontal airflow, and particularly protects the airflow in the vertical direction discharged from the upper side of the heat dissipation unit array 32 from the impact of the horizontal airflow. Wherein, four wind-break walls 6 can be arranged to surround a cylindrical structure to protect the heat dissipation unit array 32.

Specifically, the fan array 31 includes a plurality of axial flow fans, each of which is disposed in an air duct extending in a vertical direction. The rotation axis of axial fan extends the setting along vertical direction, can be with the air current drive of fan downside for upwards flowing, forms the air current of axial flow to set up axial fan in the dryer, the dryer extends along vertical direction, also can play the restriction effect to the flow direction of air current, forms the air current that flows along vertical direction more concentrated, increases the air current velocity of flow, improves the radiating efficiency.

In addition, the air-cooled platform 3 includes a frame structure supporting the fan array 31, which is supported by a plurality of support columns 7. The frame structure can be a steel structure, can be formed by steel pipes, angle steel and other structures, can well support the fan array 31 and basically cannot block airflow; in addition, the air-cooled platform 3 has a certain height relative to the ground, so that the frame structure can be supported by the supporting columns 7, and also the supporting columns 7 do not substantially affect the flow of the air flow and have a relatively low production cost. The supporting column 7 may be made of metal or alloy material, or may be of concrete structure.

Specifically, the horizontal distance between the steam turbine workshop 2 and the air cooling platform 3 is 13.5m-16m, the heights of the steam turbine workshop and the boiler workshop are 80m-90m respectively, and the height of the air cooling platform 3 is 35m-45 m. The turbine workshop 2 and the air cooling platform 3 keep a proper horizontal spacing, and the windproof piece only occupies a part of the width between the two; further, since the steam inlet of the steam turbine and the steam outlet of the boiler are as high as each other and the maximum heights of the steam turbine and the boiler are substantially the same, the heights of the steam turbine plant 2 and the boiler plant 1 are substantially the same and are approximately 80m to 90 m. As described above, the steam inlet of the steam turbine is substantially disposed at the top, and the steam outlet is disposed at the bottom, so that the height of the steam exhaust duct 4 is substantially the same as the height of the steam outlet, and thus a drop is formed with the maximum height of the steam turbine, and the air cooling platform 3 is disposed at a position substantially identical to the height of the steam exhaust duct 4, and of course, in order to ensure the gas circulation on the air cooling platform 3, the air cooling platform 3 also needs to have a sufficient height, so that, as shown in fig. 1, after the steam exhaust duct 4 is extended from the steam turbine plant 2, the air cooling platform is bent upward and extended to a certain height, and then horizontally extended to the right side again, and the drop in height between the heat dissipation unit array 32 and the steam outlet of the steam turbine is compensated by.

Additionally, the utility model also provides a power generation system, wherein, power generation system includes above scheme steam turbine radiator unit. The power generation system is a thermal power generation system and comprises equipment such as a boiler, a steam turbine, a generator and the like, wherein steam from the boiler can work on the steam turbine so as to drive the generator connected with the steam turbine to operate and generate power, the steam which does work is discharged through a steam discharge pipeline 4 and cooled to form condensed water, and the condensed water can return to the boiler again to be heated to form steam to form complete circulation. In this scheme, for reducing the pipeline length between steam turbine and boiler, support the steam turbine in the position such as height with the boiler, the air cooling platform is also close with the steam exhaust port height of steam turbine simultaneously to carry out the heat dissipation to connecting in the exhaust steam pipeline of steam exhaust port and handle.

The preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited thereto. In the technical idea scope of the present invention, it is possible to provide the technical solution of the present invention with a plurality of simple modifications, including combining each specific technical feature in any suitable manner, and in order to avoid unnecessary repetition, the present invention does not provide additional description for various possible combinations. These simple variations and combinations should also be considered as disclosed in the present invention, all falling within the scope of protection of the present invention.

Claims (13)

1. The utility model provides a steam turbine heat radiation component, its characterized in that, steam turbine heat radiation component is including boiler workshop (1) that is provided with the boiler, steam turbine workshop (2), air cooling platform (3) and exhaust steam pipe way (4) that are provided with the steam turbine, the steam outlet of boiler with the equal altitude setting of steam inlet of steam turbine is connected through steam pipe, air cooling platform (3) with steam turbine workshop (2) horizontal separation, air cooling platform (3) are including fan array (31) and the radiating unit array (32) on upper portion of lower part, exhaust steam pipe way (4) connect in the exhaust steam port of steam turbine supports on the radiating unit array (32), air cooling platform (3) orientation one side of steam turbine workshop (2) is provided with the orientation the windbreak that steam turbine workshop (2) extends, windbreak can block partially at least air cooling platform (3) with the windbreak of steam turbine workshop (2) is in The air flow in the vertical direction.

2. The turbine heat removal assembly of claim 1, wherein the windbreak comprises a windbreak plate (5), the windbreak plate (5) comprising an inclined portion (51) and a vertical portion (52), a first end of the inclined portion (51) being connected to the air-cooled platform (3), a second end of the inclined portion (51) being inclined downwardly relative to the first end of the inclined portion (51), the vertical portion (52) being connected to the second end of the inclined portion (51) and extending downwardly.

3. The turbine heat removal assembly according to claim 2, characterized in that the inclined portion (51) is inclined at an angle of 45 ° to 90 ° with respect to a horizontal plane, the length of the inclined portion (51) from the air cooling platform towards the turbine plant (2) is 0m to 5m, and the length of the vertical portion (52) in the vertical direction is 6m to 14 m.

4. The turbine heat removal assembly of claim 1, wherein the windbreak comprises a windbreak plate (5), the windbreak plate (5) comprising an inclined portion (51) and a horizontal portion (53), a first end of the inclined portion (51) being connected to the air cooling platform (3), a second end of the inclined portion (51) being inclined downwardly relative to the first end of the inclined portion (51), the horizontal portion (53) being connected to the second end of the inclined portion (51) and extending towards the turbine plant (2).

5. The turbine heat removal assembly according to claim 4, characterized in that the inclined portion (51) is inclined at an angle of 45 ° to 90 ° with respect to a horizontal plane, the inclined portion (51) having a length of 0m to 5m from the air cooling platform towards the turbine plant (2), and the horizontal portion (53) having a length of 6m to 14m from the air cooling platform towards the turbine plant (2).

6. The turbine cooling assembly according to any of the claims 2 to 5, characterized in that the windbreak plate (5) is a grid plate.

7. The turbine heat removal assembly of any of claims 2 to 5 wherein the inclined portion (51) is connected to a junction of the fan array (31) and the heat removal unit array (32).

8. The turbine cooling assembly of claim 1 wherein a vertical air duct is provided in the array (32) of cooling units.

9. The turbine heat removal assembly of claim 8, wherein a wind shield wall (6) is disposed around the heat removal unit array (32), and a height of the wind shield wall (6) is greater than a height of the heat removal unit array (32).

10. The turbine cooling assembly of claim 1 wherein the fan array (31) comprises a plurality of axial fans, each of the axial fans being disposed in a duct extending in a vertical direction.

11. The turbine cooling assembly according to claim 10, wherein the air cooled platform (3) comprises a frame structure supporting the fan array (31), the frame structure being supported by a plurality of support columns (7).

12. The turbine cooling assembly according to claim 1, characterized in that the horizontal distance between the turbine shop (2) and the air-cooled platform (3) is 13.5m-16m, the height between the turbine shop (2) and the boiler shop (1) is 80m-90m, respectively, and the height between the air-cooled platform (3) is 35m-45 m.

13. A power generation system comprising the turbine heat sink assembly of any of claims 1-12.

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