KR102049292B1 - System for ventilating underground structures - Google Patents

Abstract

The present invention relates to a ventilation system of an underground structure, which can continuously perform ventilation by using outdoor winds. The ventilation system comprises: an extension unit connected to the underground structure, having an upper side extending in the direction of a ground, and enabling a drive hole to be formed on an outer circumference of an upper side exposed in the direction of the ground; and a ventilation member including a rotary shaft formed in the inner longitudinal direction of the extension unit, an impeller rotatably mounted on an upper side of the rotary shaft facing the drive hole, and a propeller rotatably mounted on a lower side of the rotary shaft.

Description

Ventilation system for underground structures

The present invention relates to a ventilation system of an underground structure, and more particularly to a ventilation system of an underground structure to enable continuous ventilation using the outside wind.

In general, as the industry is developed and the city's population concentration is accelerated, underground structures such as waterworks, sewerage, electricity, district heating, gas stoves, and electric wires are installed in the underground of the city. Since these underground structures are sealed underground, specific ventilation measures are required in terms of maintaining and managing the underground structures, as well as preventing worker safety accidents.

Looking at the ventilation system of the underground structure, depending on the power source can be divided into natural ventilation and mechanical ventilation. Natural ventilation is a method of ventilation by using natural force such as wind, temperature difference, pressure difference, etc. without using a machine. The structure is simple and does not occupy a lot of space. Since the ventilation is not constant compared to the mechanical ventilation because it is affected a lot, there is a disadvantage that the external temperature is particularly affected in summer and winter. Mechanical ventilation is a method of forcibly ventilating by using a machine. The ventilation amount can be controlled without being influenced by the outside, but since the structure is complicated, it takes up a lot of space, which leads to encroachment on the sidewalk and is not good in appearance. There is a disadvantage that occurs.

1 is a view showing a ventilation system of a conventional underground structure. Referring to FIG. 1, the ventilation system 10 of a conventional underground structure is provided with a first manhole unit 20 and an electronic device or a precision mechanical device for forming a cavity 21 in the basement, and in the underground cavity 21. Circulating means 40 for circulating the second manhole unit 30 having the closed space portion 31 and the air inside the closed space portion 31 of the second manhole unit 30 with the outside air due to the difference in density. It includes.

The circulation means 40 includes first and second vents 41 and 42 formed on the upper and lower portions of the sealed space 31 and first and second connection ducts connected to the first and second vents 41 and 42. (43, 44). In addition, the air, which is heated by electronic equipment or the like accommodated in the enclosed space 31 and has a relatively low temperature and has a low density, is discharged to the outside through the first vent 41 and the first connection duct 43, and the temperature is relatively high. Low and dense external air flows into the sealed space 31 through the second vent 42 and the second connection duct 44.

The conventional ventilation system 10 of the underground structure has the advantage that it can be ventilated in a simple manner without using mechanical power, but the disadvantages of the conventional natural ventilation method, that is, in the season of high outside temperature, such as hot summer There is a problem that ventilation is not progressed properly.

Domestic Patent Publication No. 10-0753688

An object of the present invention for solving the problems of the prior art as described above is to provide a ventilation system of the underground structure to enable continuous ventilation using the outside wind.

In order to achieve the above object of the present invention, the lower side is buried in the basement and connected to an underground structure having a space formed therein, and the upper side extends in the ground direction, and an extension portion in which a driving hole is formed at the upper outer periphery exposed in the ground direction ; And a ventilation member including a rotating shaft formed along an inner longitudinal direction of the extension part, an impeller mounted on the upper side of the rotating shaft facing the driving hole, and a propeller mounted on the lower side of the rotating shaft. , The extension portion, the first side is connected to the side of the base structure and the other side extends in the ground direction, the second side is connected to the first extension and the other side extends in the ground direction away from the ground An extension portion, one side is connected to the second extension portion, the other side includes a third extension extending upward from the second extension portion, the upper side is closed, the impeller is provided in the third extension portion, An extension upper side portion having a diameter smaller than the second extension portion protrudes from the upper side of the second extension portion, and the extension image below the third extension portion. An extended lower side portion having a diameter larger than the extended upper side portion is formed so that the side portion is inserted, and a plurality of vent holes penetrate through the outer periphery of the extended lower side portion. Air is supplied to the underground structure through the air or the exhaust of the underground structure to the outside through the ventilation hole, the driving hole is formed on the outer periphery of the third extension, the ground wind through the driving hole When the impeller is rotated and the outside air is supplied to the underground structure through the ventilation hole, the outside air introduced into the space between the extending upper side and the extending lower side through the ventilation hole is the first air. It is supplied to the underground structure through the extension, the air of the underground structure through the vent hole When it is exhausted to the negative, the underground air, characterized in that the internal air of the first extension portion is moved to the space between the extension upper side and the extension lower portion by the pressure of the propeller and then exhausted to the outside through the ventilation hole Provide a ventilation system for the structure.

The ventilation member may further include a rotation guide member configured to guide the rotation of the rotation shaft while being supported by the extension part.

The rotation guide member may include: a fixed support plate inserted into the extension part to face the lower side of the impeller and having an outer periphery fixed to an inner periphery of the extension part; A support cover mounted to cover the center of the fixed support plate and having an inner circumference greater than an outer circumference of the rotation shaft; And a plurality of bearings provided between an inner circumference of the support cover and an outer circumference of the rotation shaft. The rotating shaft, the lower side is connected to the propeller and the upper side is a first rotating shaft penetrating the fixed support plate, the lower side is connected to the first rotating shaft and the upper side is a second rotating shaft for supporting the lower side of the impeller through the support cover And a lower side is connected to the second rotating shaft and an upper side is connected to the impeller, and a third rotating shaft is connected to the impeller.

In addition, the outer ring portion which is located inside the support cover to support one side of the bearing in a state mounted on the inner circumference of the support cover; And an inner ring part positioned inside the support cover to support the other side of the bearing in a state of being mounted on an outer circumference of the second rotation shaft. When the impeller is rotated, the second rotation shaft rotates along the impeller. Underground structure, characterized in that for rotating the inner ring portion, the inner ring portion is rotated along the second axis of rotation to support the rotation of the bearing, the outer ring portion to support the rotation of the bearing in a fixed state to the support cover To provide ventilation systems.

In addition, the upper support portion which is located inside the support cover for supporting the upper side of the bearing in a state mounted on the upper side of the support cover; And a lower support part positioned in the support cover and supporting the lower side of the bearing in a state of being mounted on the fixed support plate. When the impeller is rotated, the upper support part and the lower support part are respectively fixed. It provides a ventilation system of the underground structure, characterized in that for supporting the rotation of the bearing.

In addition, there is provided a ventilation system of the underground structure further comprises a lock nut through the support cover in the state inserted into the second rotary shaft to press the inner ring portion downward.

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In addition, it provides a ventilation system of the underground structure, characterized in that the blocking portion protrudes formed on the inner circumferential upper side of the drive hole.

In addition, the blocking unit provides a ventilation system of the underground structure, characterized in that formed downwardly inclined.

The impeller may include a rotary plate connected to an upper end of the rotary shaft and a plurality of rotary blades arranged radially on the rotary plate, and a guide hole may be formed at a position opposite to the rotary blade of the rotary plate. The rotary blade is connected to one side of the inner circumference of the hole, the outer side of the rotary blade provides a ventilation system of the underground structure, characterized in that positioned to face the drive hole.

In addition, it provides a ventilation system of the underground structure, characterized in that the intake or exhaust is selected according to the inclined angle of the propeller.

The present invention has an impeller for rotating the rotating shaft while rotating itself while receiving the pressure of the outside wind, and a propeller for generating wind by receiving the rotational force of the rotating shaft, so that the inside of the underground structure can be easily ventilated without additional mechanical power. In this way, the interior space of the underground structure can be comfortably maintained.

In addition, it is possible to continuously ventilate, it is possible to eliminate the condensation phenomenon, it is possible to increase the service life of various equipment installed in the underground structure, it is possible to secure the safety of the installation product.

In addition, since a driving hole for driving the impeller and a ventilation hole for venting, ie, supplying or exhausting air by the rotation of the propeller are separately provided, the air moved through the driving hole and the air moved through the ventilation hole are separately provided. There is an effect that a collision does not occur.

In addition, since no mechanical power is used, construction cost is greatly reduced, maintenance costs are reduced, and economic and stability effects are excellent.

1 is a view showing a ventilation system of a conventional underground structure.
2 is a plan view schematically illustrating a ventilation system of an underground structure according to a preferred embodiment of the present invention.
3 is a view schematically showing the interior of the ventilation system of the underground structure according to a preferred embodiment of the present invention.
4 is a view schematically illustrating a ventilation member provided in a ventilation system of an underground structure according to a preferred embodiment of the present invention.
5 is a view schematically illustrating a rotating shaft provided in the ventilation system of the underground structure according to the preferred embodiment of the present invention.
6 is a plan view schematically illustrating an impeller provided in a ventilation system of an underground structure according to a preferred embodiment of the present invention.
7 is a plan view schematically illustrating a rotation guide member provided in the ventilation system of an underground structure according to a preferred embodiment of the present invention.
8 is a view showing for explaining the operation of the ventilation system of the underground structure according to a preferred embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail the ventilation system of the underground structure according to an embodiment of the present invention.

2 is a plan view schematically illustrating a ventilation system of an underground structure according to a preferred embodiment of the present invention, Figure 3 schematically shows the interior of the ventilation system of an underground structure according to a preferred embodiment of the present invention Drawing.

2 and 3, the ventilation system of an underground structure according to a preferred embodiment of the present invention includes an underground structure 100, an extension 200, and a ventilation member 300.

Underground structure 100 is buried underground, the space is formed inside. Various facilities such as water supply, sewage, electricity, district heating, gas stove, electric wire, etc. may be installed inside the underground structure 100, and a predetermined space may be formed for a smooth operation of the worker. The underground structure 100 may be composed of an underground joint hole connected to the manhole, an underground parking lot, an underground warehouse, an underground facility, and the like.

Extension portion 200 is formed in a pipe shape, one side is connected to the side of the underground structure 100, the other side extends in the direction of the ground 210, and one side is the first extension 210 A second extension part 220 connected to the other side and extending in the ground direction away from the ground, one side of which is connected to the second extension part 220, and the other side of which is upward from the second extension part 220. The extended but upper side includes a third extension 230 that is closed. The first extension part 210 is formed to be bent upward, and the second extension part 220 is elongated upwardly along the longitudinal direction. A plurality of driving holes 232 are formed through the upper outer circumference of the third extension part 230 exposed in the ground direction. The plurality of driving holes 232 are for driving the impeller 320, and may be configured in multiple rows on the upper outer periphery of the third extension part 230. The driving hole 232 is formed along the outer circumference of the third extension part 230, and the blocking part 234 protrudes from the inner circumference of the driving hole 232. The blocking portion 234 is formed in a plate shape and the outside of the blocking portion 234 is formed to be inclined downward. Accordingly, when it rains, rain water cannot flow into the third extension 230 through the driving hole 232, and copper and plants also penetrate into the third extension 230 by the blocking part 234. There is the effect that we cannot do. In addition, a lamp (not shown) is provided at an upper portion of the third extension part 230 exposed to the outside, and may serve as a safety indicator when the vehicle is moved or a person walks at night. In some cases, the first extension part 210, the second extension part 220, and the third extension part 230 may be integrally formed with each other, or may be separately formed and then coupled to each other. to be.

The ventilation member 300 is provided in the third extension part 230 and exhausts the air inside the underground structure 100 contaminated by using the wind of the ground, that is, the wind, to the outside or the fresh air from the outside. The air is supplied into the structure 100. The ventilation member 300 will be described with reference to FIG. 4.

4 is a view schematically showing a ventilation member provided in the ventilation system of the underground structure according to a preferred embodiment of the present invention, Figure 5 is provided in the ventilation system of the underground structure according to a preferred embodiment of the present invention Figure is a schematic diagram for explaining the rotation axis.

4 and 5, an extension upper side portion 221 having a diameter smaller than the second extension portion 220 is formed on the upper side of the second extension portion 220. The lower side of the third extension part 230 is provided with an extension lower part 231 having the same diameter as the third extension part 230. In addition, when the second extension part 220 and the third extension part 230 are coupled to each other, the extension upper side part 221 is coupled in the inserted state to the extension lower part 231. At this time, a plurality of ventilation holes 231a are formed through the outer circumference of the extended lower portion 231. In addition, the air inside the first extension part 210 is moved to the space g between the extension upper side part 221 and the extension lower part part 231 by the pressure of the propeller 330 which will be described later. Exhaust through the outside). On the contrary, the outside air flowing into the space g between the extended upper side portion 221 and the extended lower side portion 231 through the ventilation hole 231a is directed toward the underground structure 100 through the first extension portion 210. Inflow, that is, air supply.

The ventilation member 300 may include a rotation shaft 310, an impeller 320, and a propeller 330, and further include a rotation guide member 350.

The rotating shaft 310 is positioned inside the second extension part 220 and the third extension part 230, and has a long shape along the longitudinal direction of the second extension part 220 and the third extension part 230. It is formed in a columnar shape. The rotary shaft 310 has a first rotary shaft 312 formed in an elongated pillar shape along the second extension portion 220, and a second rotary shaft extended upwardly in a state connected to an upper side of the first rotary shaft 312 ( 314 and a third rotation shaft 316 extending upwardly while being connected to an upper side of the second rotation shaft 314. The first, second, third, and rotation shafts 312, 314, and 316 may be formed integrally with each other, or may be separately formed and then welded to each other. The second rotation shaft 314 may be formed to have a larger diameter than the first and third rotation shafts 312 and 316. The upper side of the third rotation shaft 316 is positioned to face the driving hole 232.

The impeller 320 is mounted on the third rotation shaft 316 and is configured to rotate by receiving pressure of air introduced into the driving hole 232 from the outside. And as the impeller 320 is rotated, the rotating shaft 310 is rotated. The detailed structure of the impeller 320 will be described with reference to FIG. 6.

The propeller 330 is mounted to be rotated below the first rotation shaft 312, and may be configured as a conventional propeller 330 that can cause wind. And as the impeller 320 rotates the rotation shaft 310, the propeller 330 connected to the rotation shaft 310 is rotated. That is, the impeller 320 rotates the rotary shaft 310 while receiving the pressure of the external wind and rotates itself, and the propeller 330 receives the rotary force of the rotary shaft 310 to generate wind. The propeller 330 is mounted to the first rotating shaft 312 to be spaced below the impeller 320. In addition, the propeller 330 causes the wind upward or downward according to the angle of the inclined wing, and intake or exhaust may be selected according to the inclined angle of the wing of the propeller 330.

The rotation guide member 350 guides the rotation of the rotation shaft 310 in a state supported by the extension 200, and will be described with reference to FIG.

6 is a plan view schematically illustrating an impeller provided in a ventilation system of an underground structure according to a preferred embodiment of the present invention.

4 to 6, the impeller 320 rotates by receiving external wind energy, and is mounted on an upper side of the third rotation shaft 316 facing the driving hole 232. The impeller 320 includes a rotating plate 322 connected to the upper end of the third rotating shaft 316, and a plurality of rotating blades 324 radially arranged on the rotating plate 322.

The rotating plate 322 may be formed, for example, in a plate shape such as a disc, and a plurality of guide holes 322b are formed in the center of the rotating plate 322, and the rotating plate 322 is opposed to the rotating blade 324 of the rotating plate 322. A guide hole 322a is formed at the position. The guide hole 322b and the guide hole 322a are used as passages through which air moves. At this time, the rotary blade 324 is configured to be connected to one side of the inner circumference of the guide hole (322a). And the outer side of the rotary blade 324 is positioned to face the drive hole 232, when the outside air flows in the direction of the rotary blade 324 through the drive hole 232, the rotary blade 324 is external Due to the pressure by the air is rotated in the direction in which the air passes, which rotates the rotary plate 322 and the third rotary shaft 316 connected to the rotary blade 324.

Rotating blade 324 is formed in a plate shape is disposed so as to stand on the rotary shaft 310, the upper side of the rotary blade 324 may be formed to be inclined so that its height becomes smaller toward the center direction of the rotating plate 322. .

The third rotating shaft 316 is positioned to penetrate the center of the rotating plate 322. At this time, the fixing part 317 protrudes from the upper end of the third rotating shaft 316, and the fixing part 317 is the rotating plate 322. ), The third rotating shaft 316 and the rotating plate 322 are firmly coupled to each other.

7 is a plan view schematically illustrating a rotation guide member provided in the ventilation system of an underground structure according to a preferred embodiment of the present invention.

4 to 7, the rotation guide member 350 includes a fixed support plate 351, a support cover 352, a bearing 353, an outer ring part 354, an inner ring part 355, and an upper support part 356. And a lower support part 357 and a lock nut 358.

The fixed support plate 351 is formed in a plate shape, for example, a disc shape, and is disposed below the inner side of the third extension part 230 so as to face a lower side of the rotating plate 322 positioned above the third extension part 230. Is inserted. The outer circumference of the fixed support plate 351 is fixed to the inner circumference of the third extension part 230. And the center of the fixed support plate 351 is positioned so that the connecting portion of the third rotary shaft 316 and the second rotary shaft 314 penetrates.

The support cover 352 is mounted to cover the center of the fixed support plate 351, the space is formed therein, the inner circumference is formed to be larger than the outer circumference of the rotary shaft (310). The second rotation shaft 314 is connected to the third rotation shaft 316 in a state of passing through the fixed support plate 351 and the support cover 352. At this time, since the diameter of the second rotary shaft 314 is formed to be larger than the diameter of the third rotary shaft 316, the rotary plate 322 located below the third rotary shaft 316 is located on the upper side of the second rotary shaft 314 Positioned to be supported.

The bearing 353 is provided between the inner circumference of the support cover 352 and the outer circumference of the rotation shaft 310, and is composed of a ball bearing. A plurality of such bearings 353 are provided between the outer ring portion 354 and the inner ring portion 355 which will be described later.

The outer ring portion 354 is formed in a ring-shaped groove on the inner circumference and is positioned inside the support cover 352 to support one side of the bearing 353 in a state of being mounted on the inner circumference of the support cover 352. It is configured to. The inner ring portion 355 is formed in a ring shape smaller than the outer ring portion 354 and is formed so that grooves are formed in the outer circumference. The inner ring part 355 is positioned inside the support cover 352 and is configured to support the other side of the bearing 353 in a state of being mounted on the outer circumference of the second rotation shaft 314. When the impeller 320 is rotated, the second rotation shaft 314 rotates along the impeller 320 to rotate the inner ring part 355. The inner ring portion 355 rotates along the second rotation shaft 314 to support rotation of the bearing 353, and the outer ring portion 354 is fixed to the support cover 352 in the bearing state. Support the rotation of (353).

The upper support part 356 is formed in a ring-shaped groove in the lower side, is located inside the support cover 352, the upper side of the bearing 353 in a state mounted on the upper side of the support cover 352 Configured to support. The lower support part 357 is formed to have a groove-shaped ring on the upper side, and positioned inside the support cover 352 to support the lower side of the bearing 353 while being mounted on the fixed support plate 351. It is composed. When the impeller 320 is rotated, the upper support part 356 and the lower support part 357 respectively support the rotation of the bearing 353 in a fixed state.

The lock nut 358 is formed of a conventional lock nut 358, and presses the inner ring part 355 downward through the support cover 352 while being inserted into the second rotation shaft 314. .

In summary, the impeller 320 is rotated while being supported by the second rotation shaft 314, and the outer circumference of the second rotation shaft 314 rotates the inner ring portion 355. The support cover 352 is coupled to the fixed guide plate, and the support cover 352 supports the outer ring part 354, the upper support part 356, and the lower support part 357. One side and the other side of the bearing 353 contact between the inner ring portion 355 and the outer ring portion 354, and the upper side and the lower side of the bearing 353 contact between the upper support 356 and the lower support 357. The bearing 353 reduces frictional resistance due to the rotation of the inner ring portion 355 without departing outward. As described above, the present invention includes a bearing 353 in the support cover 352, and the bearing 353 is formed by the outer ring part 354, the inner ring part 355, the upper support part 356, and the lower support part 357. Since it is supported, the frictional resistance due to the rotation of the impeller 320 and the second rotary shaft 314 is not transmitted to the support cover 352, so that the support cover 352 and the fixed support plate 351 are stably provided with the second rotary shaft 314. ) To guide the rotation.

8 is a view showing for explaining the operation of the ventilation system of the underground structure according to a preferred embodiment of the present invention.

2 to 8, the ground wind rotates the impeller 320 through the driving hole 232. Then, the impeller 320 rotates the rotating shaft 310 while the rotating shaft 310 rotates the propeller 330. When the propeller 330 is rotated as described above, the ground, that is, the outside air is moved toward the underground structure 100 according to the inclined angle of the propeller 330, so that the outside air extends through the ventilation hole 231a. After entering the (200), the intake in the direction of the underground structure 100, or by moving the air inside the underground structure 100 in the direction of the extension portion 200, the air of the underground structure 100 is extended ( It passes through the vent 200 to be exhausted to the outside through the ventilation hole (231a).

As such, the present invention is configured to rotate the impeller 320 using the pressure of the magnetic wind, without a separate mechanical power, the impeller 320 is configured to rotate the propeller 330, underground structure 100 The inside can be easily ventilated, and thus the space inside the underground structure 100 can be maintained comfortably. In addition, since it is possible to continue ventilation, condensation can be eliminated, it is possible to increase the service life of the various equipment installed in the underground structure 100, there is an effect that can ensure the safety of the installation product. In addition, since no mechanical power is used, construction cost is greatly reduced, maintenance costs are reduced, and economic and stability effects are excellent.

In addition, the present invention is provided with a driving hole for driving the impeller and a ventilation hole for separately venting, that is, supplying or exhausting the air by the rotation of the propeller, respectively, and moves through the air and the ventilation hole moved through the driving hole There is an effect that a collision does not occur between the air.

Although the present invention has been described in detail in the above embodiments, it is obvious that the present invention is not limited thereto, and it is obvious to those skilled in the art that various changes and modifications can be made within the technical scope of the present invention. If the technical scope falls within the scope of the claims, the technical spirit should also be regarded as belonging to the present invention.

100: underground structure 200: extension
210: first extension 220: second extension
221: extension upper side 230: third extension part
231: extension lower portion 231a: ventilation hole
232: driving hole
234: blocking unit 300: ventilation member
310: axis of rotation 312: first axis of rotation
314: second rotation axis 316: third rotation axis
317: fixed part 320: impeller
322: rotating plate 322a: guide hole
322b: guide hole 324: rotary wing
330: propeller 350: rotation guide member
351: fixed support plate 352: support cover
353: bearing 354: outer ring portion
355: inner ring portion 356: upper support portion
357: Lower support 358: Lock nut

Claims (12)

A lower portion is embedded in the basement and connected to an underground structure having a space formed therein, and an upper portion extending in the ground direction, and an extension portion in which a driving hole is formed at the upper outer periphery exposed in the ground direction; And
A ventilation member including a rotating shaft formed along an inner longitudinal direction of the extension part, an impeller mounted to rotate on an upper side of the rotating shaft facing the driving hole, and a propeller mounted on a lower side of the rotating shaft,
The extension portion, one side is connected to the side of the underground structure and the other side is a first extension extending in the direction of the ground, and one side is connected to the first extension and the second extension is extended in the ground direction away from the ground And, one side is connected to the second extension portion, the other side includes a third extension extending upward from the second extension portion is closed,
The impeller is provided in the third extension portion,
An extended upper side portion having a diameter smaller than the second extended portion is protruded from the upper side of the second extension portion,
An extended lower side portion having a larger diameter than the extended upper side portion is formed under the third extension portion so that the extended upper side portion is inserted.
A plurality of ventilation holes are formed through the outer periphery of the lower portion of the extension part, and the outside air is supplied to the underground structure through the ventilation holes due to the pressure of the propeller, or the air of the underground structures passes through the ventilation holes. Through the outside,
The driving hole is formed on the outer periphery of the third extension, the wind of the ground rotates the impeller through the driving hole,
When the outside air is supplied to the underground structure through the ventilation hole, the outside air flowing into the space between the extended upper side portion and the extended lower side through the vent hole is the underground through the first extension portion. Air in the direction of the structure,
When the air of the underground structure is exhausted to the outside through the vent hole, the air inside the first extension portion is moved to the space between the upper upper portion and the lower lower portion by the pressure of the propeller and then the ventilation fan Ventilation system for underground structures, characterized in that the exhaust through the hole to the outside.
The method of claim 1,
The ventilation member, the ventilation system of the underground structure further comprises a rotation guide member for guiding the rotation of the rotary shaft in a state supported by the extension.
The method of claim 2,
The rotation guide member is:
A fixed support plate inserted into the extension part so as to face the lower side of the impeller and having an outer periphery fixed to the inner periphery of the extension part;
A support cover mounted to cover the center of the fixed support plate and having an inner circumference greater than an outer circumference of the rotation shaft; And
A plurality of bearings provided between an inner circumference of the support cover and an outer circumference of the rotation shaft;
The rotating shaft, the lower side is connected to the propeller and the upper side is a first rotating shaft penetrating the fixed support plate, the lower side is connected to the first rotating shaft and the upper side is a second rotating shaft for supporting the lower side of the impeller through the support cover And a lower third side connected to the second rotary shaft and an upper side connected to the impeller.
The method of claim 3, wherein
An outer ring part positioned inside the support cover to support one side of the bearing in a state of being mounted on an inner circumference of the support cover; And
It is located inside the support cover and further includes an inner ring portion for supporting the other side of the bearing in a state mounted on the outer periphery of the second rotary shaft,
When the impeller is rotated, the second rotation shaft rotates along the impeller to rotate the inner ring portion, the inner ring portion rotates along the second rotation shaft to support rotation of the bearing, and the outer ring portion is fixed to the support cover. Ventilation system of an underground structure, characterized in that for supporting the rotation of the bearing in the state.
The method of claim 4, wherein
An upper support part positioned inside the support cover to support an upper side of the bearing while being mounted on an upper side of the support cover; And
It is located inside the support cover but further includes a lower support for supporting the lower side of the bearing in a state mounted on the fixed support plate,
When the impeller is rotated, the upper support portion and the lower support portion, respectively, the ventilation system of the underground structure, characterized in that for supporting the rotation of the bearing in a fixed state.
The method of claim 4, wherein
And a lock nut penetrating the support cover and pressing the inner ring portion downward while being inserted into the second rotation shaft.
delete delete The method of claim 1,
Ventilation system of the underground structure, characterized in that the blocking portion protrudes formed on the inner circumferential upper side of the drive hole.
The method of claim 9,
Ventilation system of the underground structure, characterized in that the blocking portion is formed to be inclined downward.
The method of claim 1,
The impeller includes a rotary plate connected to an upper end of the rotary shaft, and a plurality of rotary blades radially arranged on the rotary plate,
A guide hole is formed at a position opposite to the rotary blade of the rotating plate, and the rotary blade is connected to one side of the inner circumference of the guide hole.
Ventilation system of the underground structure, characterized in that the outer side of the rotary blade is positioned to face the drive hole.
The method of claim 1,
Ventilation system of the underground structure, characterized in that the intake or exhaust is selected according to the inclined angle of the propeller.

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