JP7089912B2 - Vertical pipe structure - Google Patents

Description

The present invention relates to a vertical pipe structure arranged in a vertical shaft connecting an upper waterway and a lower waterway.

Various underground structures have been proposed for head treatment of sewage and rainwater. For example, Patent Document 1 discloses a vertical pipe structure arranged in a vertical shaft connecting an upper pipe and a lower pipe below the upper pipe. This vertical pipe structure has a vertical pipe arranged in the vertical shaft, a shaft pipe arranged inside the vertical pipe, and a spiral guide plate attached to the outer peripheral surface of the shaft pipe. There is. The water that has flowed from the upper horizontal pipe into the vertical pipe flows from the vertical pipe to the lower pipe while drawing a spiral along the guide plate. Since the water flows downward through such a spiral guide plate, it is possible to prevent the vertical pipe, the vertical shaft, and the like from being damaged by the impact of the falling water.

Further, in such a vertical pipe structure, for maintenance, a passage through which a worker can pass may be provided in the shaft pipe, and a ladder for the worker to move up and down is provided in the shaft pipe. Therefore, the worker can reach the lower surface of the shaft through the ladder.

JP-A-2015-166522

By the way, in the vertical pipe structure as described above, the shaft pipe may not reach the lower surface of the vertical shaft, and a gap may be formed between the lower end portion of the shaft pipe and the vertical shaft. In such a case, the worker has to jump from the lower end of the shaft pipe to the lower surface of the shaft, which may make the work difficult. The present invention has been made to solve the above problems, and an object of the present invention is to provide a vertical pipe structure capable of easily performing a work of descending from the inside of a shaft pipe to the lower surface of a vertical shaft.

The present invention is a vertical pipe structure arranged in a vertical shaft connecting an upper water channel and a lower water channel, and has a cylindrical shape having an upper end portion communicating with the upper water channel and a lower end portion communicating with the lower water channel. A vertical pipe, a cylindrical shaft pipe arranged in the vertical pipe and having a lower end portion at a position separated by a predetermined length upward from the lower surface of the vertical shaft, an outer peripheral surface of the shaft pipe, and the inside of the vertical pipe. A guide plate spirally extending in the axial direction of the shaft tube so as to connect the peripheral surface, and a first ladder arranged on the inner wall surface of the shaft tube so as to extend in the axial direction of the shaft tube. A plurality of scaffolding members attached at predetermined intervals in the axial direction of the shaft tube, a first aspect arranged in the shaft tube, and detachable between the lower end portion of the shaft tube and the lower surface of the vertical shaft. A first holding means for holding the second ladder and the second ladder in the first aspect in the shaft tube, which are configured to selectively take any one of the second aspects to be hung on the shaft tube. And have.

In the vertical pipe structure, the first holding means may have a regulating portion for restricting the movement of the second ladder in the vertical direction.

In the vertical pipe structure, the second ladder can be arranged on the inner peripheral surface of the shaft pipe, which is displaced from the first ladder by 45 degrees to 135 degrees in the circumferential direction by the first holding means. ..

The vertical pipe structure may further include a second holding means for holding the second ladder according to the second aspect between the lower end of the shaft pipe and the lower surface of the vertical shaft.

In the vertical pipe structure, the second holding means can be provided at a position in the shaft pipe where the guide plate is not attached.

The vertical pipe structure may further include a plurality of scaffolding members that are attached at predetermined intervals in the axial direction of the shaft pipe.

In the vertical pipe structure, the lowest scaffolding member arranged at the lowermost position among the plurality of scaffolding members is arranged near the lower end of the shaft pipe, and the first holding means holds the second ladder. , Can be configured to be held above the bottom scaffolding member.

In the vertical pipe structure, the lowest scaffolding member arranged at the lowest position among the plurality of scaffolding members is arranged near the lower end of the shaft pipe, and the second holding means is the lowest scaffolding member. It is arranged above and can be configured to hold the upper end of the second ladder.

In the vertical pipe structure, each scaffolding member is formed so as to partition the inside of the shaft pipe in the axial direction and is configured to allow liquid to pass through, and the scaffolding member can be passed by a person. It may have a through hole of a size and a lid member that detachably closes the through hole.

In the vertical pipe structure, the lid member can be detachably attached to the first ladder.

In the vertical pipe structure, the center of the through hole can be formed so as to be closer to the first ladder than the center of the scaffolding member.

According to the present invention, the durability is high and the design can be maintained.

It is sectional drawing which shows one Embodiment of the vertical pipe structure which concerns on this invention. FIG. 3 is a cross-sectional view taken along the line AA of FIG. FIG. 2 is a sectional view taken along line DD of FIG. It is a top view of the scaffolding member. FIG. 4 is a cross-sectional view taken along the line BB of FIG. FIG. 4 is a cross-sectional view taken along the line CC of FIG. It is a side view which shows the state which the 2nd ladder is attached to the shaft tube. It is a cross-sectional view of a vertical pipe structure. It is a perspective view of the 2nd holding member. It is sectional drawing which shows the vicinity of the lower part of a vertical pipe structure.

Hereinafter, an embodiment of the vertical pipe structure according to the present invention will be described with reference to the drawings.

<1. Overview of vertical pipe structure>
Hereinafter, the vertical pipe structure according to the embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a cross-sectional view of a vertical pipe structure, and FIG. 2 is a cross-sectional view taken along the line AA of FIG. In these drawings, the inside of the vertical pipe structure is partially shown transparently for convenience of explanation.

As shown in FIGS. 1 and 2, this vertical pipe structure is also called a drop shaft and is provided in a concrete underground structure. More specifically, in the vertical shaft 300 connecting the upper pipe line 100 through which water such as sewage and rainwater flows and extending horizontally and the lower pipe line 200 arranged below the upper pipe line 100 and extending horizontally. Is located in. The shaft 300 extends above the upper pipeline 100 and is connected to a manhole 400 provided on the ground. Then, from this manhole 400, an inspection worker enters the shaft structure. This vertical pipe structure has a cylindrical vertical pipe 1 extending in the vertical direction in the vertical shaft 300. The vertical pipe 1 extends downward from the lower end of the upper pipe line 100 and extends to the lower surface of the vertical shaft 300. Further, a filler 500 such as air mortar is filled between the outer peripheral surface of the vertical pipe 1 and the inner peripheral surface of the vertical shaft 300, whereby the vertical pipe 1 is fixed to the vertical shaft 300. There is. Further, at the lower end of the vertical pipe 1, a circular communication hole 11 communicating with the lower pipe line 200 is formed.

Inside the shaft 300, a cylindrical shaft tube 2 and a spiral guide plate 3 attached to the outer peripheral surface of the shaft tube 2 are provided. Further, inside the shaft tube 2, a plurality of scaffolding members 4, a first ladder 5 extending in the axial direction in the shaft tube 2, and a second ladder 6 detachably attached near the lower end portion of the shaft tube 2 are provided. Is provided. Hereinafter, these members will be described in detail.

<2. Shaft tube and guide plate>
The shaft pipe 2 extends along the central axis inside the vertical pipe 1, and has an internal space inside the shaft pipe 2 so that a worker can pass through the shaft pipe 2. Further, the upper and lower ends of the shaft tube 2 are open. The upper end portion of the shaft pipe 2 projects upward from the vertical pipe 1 and extends slightly above the upper pipe line 100. On the other hand, the lower end portion of the shaft pipe 2 is not in contact with the lower surface of the vertical shaft 300, and is located at a position separated upward from the lower surface of the vertical shaft 300 by a predetermined distance (for example, about 2 m). The communication hole 11 of the vertical pipe 1 described above is formed below the shaft pipe 2. Further, the radial outer edge of the guide plate 3 is fixed to the inner peripheral surface of the vertical pipe 1 without a gap.

A shielding plate 31 extending upward from the guide plate 3 is attached to the upper end of the shaft tube 2. As shown in FIG. 3, the shielding plate 31 is attached to the outer peripheral surface of the shaft pipe 2 so as to face the upper pipe line 100. More specifically, the shielding plate 31 extends radially so as to connect the outer peripheral surface of the shaft tube 2 and the inner peripheral surface of the shaft 300, and extends to the vicinity of the upper end of the guide plate 3.

Here, as shown in FIG. 3, in a plan view, the water flowing out from the upper pipe line 100 flows into both sides of the shaft pipe 2, but one side portion of the shaft pipe 2 is closed by the shielding plate 31. Therefore, the water that has flowed to one side of the shaft tube 2 is repelled by the shielding plate 31 and flows downward from the other side of the shaft tube 2. Further, the water that has flowed to the other side of the shaft tube 2 is flowing downward as it is. In this way, the water that has flowed downward flows downward while drawing a spiral along the guide plate 3, and flows to the lower pipeline 200 through the communication hole 11.

<3. Scaffolding member>
Next, the scaffolding member will be described. 4 is a plan view of the scaffolding member, FIG. 5 is a sectional view taken along line BB of FIG. 4, and FIG. 6 is a sectional view taken along line CC of FIG. Scaffolding members 4 are arranged in the internal space of the shaft tube 2 at predetermined intervals in the axial direction. As shown in FIG. 4, the scaffolding member 4 is formed in a disk shape that partitions the shaft tube 2 in the axial direction. More specifically, the scaffolding member 4 has a main body 41 having a circular plate-like outer shape and a circular through hole 411, and a circle that is detachably fitted into the through hole 411 of the main body 41. It is provided with a plate-shaped lid member 42. The main body 41 and the lid member 42 have a mesh structure so that water can pass through them.

The center of the through hole 411 is deviated from the center of the main body 41 and is close to the first ladder 5 on the inner peripheral surface of the shaft tube 2. That is, on the outer edge of the through hole 411, the portion closest to the first ladder 5 is arranged near the outer edge of the main body portion 41.

The outer circumference of the main body 41 is in contact with the inner peripheral surface of the shaft tube 2. Further, as shown in FIG. 5, an annular support member 412 that supports the lid member 42 from below is arranged on the inner circumference of the through hole 411. The support member 412 has a support surface 413 arranged along the inner circumference of the through hole 411, and the peripheral edge of the lower surface of the lid member 42 is supported by the support surface 413. That is, the lid member 42 is supported by the support member 412 so as not to fall downward from the through hole 411.

As shown in FIG. 6, on the upper surface of the main body 41, plate-shaped regulation plates 43 are attached to the peripheral edges of the through holes 411 at a plurality of locations (four locations in the present embodiment). The regulation plate 43 is rotatably attached to the upper surface of the main body 41 via a shaft member 44, and is arranged from a first position so as to cover the upper surface of the lid member 42 and from the upper surface of the lid member 42. It can rotate between the second position to be evacuated. Therefore, when the regulation plate 43 is in the first position, the lid member 42 is restricted from moving upward and cannot be removed from the main body 41. On the other hand, when the regulation plate 43 is in the second position, the lid member 42 can be removed from the main body 41. Further, a hook 45 is attached to the lower surface of the lid member 42, and as will be described later, the hook 45 allows the lid member 42 to be hooked on the first ladder 5.

The scaffolding member 4 allows the worker to take a rest when the through hole 411 is closed by the lid member 42, and when the lid member 42 is removed, the worker enters the shaft tube 2 through the through hole 411. Can be moved in the axial direction. A plurality of such scaffolding members 4 are provided in the shaft tube (four places in the present embodiment), and here, the scaffolding member 4 arranged at the lowest position is referred to as the lowest scaffolding member 40. do. The lowermost scaffolding member 40 is attached near the lower end of the shaft tube 2.

<4. 1st ladder>
As shown in FIGS. 1 and 2, the first ladder 5 used when a worker moves up and down in the shaft tube 2 is a known ladder, which is a pair of vertically extending columns and a plurality of columns extending therein. It consists of a ladder. Then, each support column is fixed to the inner wall surface of the shaft tube 2 by a bracket. The first ladder 5 is divided at a place where the scaffolding member 4 is arranged. However, as described above, since the through hole 411 of the scaffolding member 4 is formed so as to be close to the first ladder 5, when the worker passes through the through hole 411 of the scaffolding member 4, the first ladder 5 is used. The first ladder 5 can be smoothly moved up and down without being too far from. The lower end of the first ladder 5 is located slightly above the lowest scaffolding member 40.

<5. 2nd ladder and its holding mechanism>
Next, the second ladder will be described. FIG. 7 is a side view showing a state in which the second ladder is attached to the shaft pipe. As shown in FIG. 7, the second ladder 6 is a known ladder, and a plurality of treads 62 are attached between a pair of vertically extending columns 61. Hooks 63 are attached to the upper ends of both columns 61. Further, a non-slip member 64 made of rubber such as butyl rubber or plastic is attached to the lower ends of both columns. The second ladder 6 is hung between the lower end of the shaft pipe 2 and the lower surface of the shaft 300, and when a worker descends from the lower end of the shaft pipe 2 to the lower surface of the shaft 300. Used. However, as shown in FIG. 7, it is detachably held inside the shaft tube 2 except during work. Hereinafter, a mechanism for holding the second ladder 6 inside the shaft tube 2 when not working will be described.

FIG. 8 is a plan view of the shaft tube. As shown in FIG. 8, in the shaft tube 2, the first holding member 7 and the second holding member 8 that hold the second ladder 6 are above the lowest scaffolding member 40, and their center positions are the first. It is arranged on the inner wall surface displaced by 90 degrees in the circumferential direction around the pipe axis of the shaft pipe 2 from the center position of the ladder 5. Then, on the inner wall surface of the shaft tube 2, the first holding member 7 is a member formed in a U shape at a position where the second ladder 6 is held, and both ends thereof are inside the shaft tube 2. It is fixed to the wall surface and protrudes into the internal space of the shaft tube 2. Then, the hook 63 at the upper end of the second ladder 6 is hooked on the first holding member 7.

On the other hand, the second holding member 8 is attached to the inner wall surface of the shaft pipe 2 below the first holding member 7, and is hooked on one of the treads 62 of the second ladder 6. Hereinafter, the second holding member 8 will be described in detail.

FIG. 9 is a perspective view of the second holding member. As shown in FIG. 9, the second holding member 8 is a pair of support plates extending in parallel with an L-shaped substrate 81 protruding from the inner wall surface of the shaft tube 2 and a predetermined interval from the vicinity of the tip of the substrate 81. 82 and. The pair of support plates 82 are formed so as to extend upward from the substrate 81, and one of the treads 62 of the second ladder 6 is fitted between the support plates 82 from above. That is, the distance between the support plates 82 is long enough to fit the tread 62.

Further, a shaft member 83 arranged on the inner wall surface side of the shaft tube 2 with respect to the support plate 82 and extending upward is attached to the substrate 81, and a rectangular regulation plate 84 is attached to the upper end of the shaft member 83. Is rotatably attached. The regulation plate 84 rotates around the shaft member 83, and can selectively take a first position that covers between the support plates 82 from above and a second position that is retracted from the support plates 82. There is. Therefore, when the regulation plate 84 is in the second position, the tread 62 can be fitted or removed between the support plates 82. On the other hand, if the control plate 84 is arranged at the first position when the tread 62 is fitted between the two support plates 82, the control plate 84 covers the upper part of the tread 62, so that the tread 62 supports the tread 62. It is possible to prevent the plate 82 from being separated upward.

As described above, the first holding member 7 and the second holding member 8 are mechanisms for holding the second ladder 6 inside the shaft pipe 2.

Next, a mechanism for holding the second ladder 6 during work will be described. As shown in FIG. 10, on the inner wall surface of the shaft tube 2, a third holding member 9 formed in a U shape having the same structure as the first holding member 7 is attached below the second holding member 8. There is. The third holding member 9 is provided slightly above the lowest scaffolding member 40, directly below the first ladder 5, and slightly below the lower end of the first ladder 5. Then, the hook 63 of the second ladder 6 removed from the first and second holding members 7 and 8 is hooked on the third holding member 9. As a result, when the second ladder 6 is arranged between the lower end of the shaft pipe 2 and the lower surface of the shaft 300, the second ladder 6 is fixed so as not to move.

<6. Working with vertical pipe structures>
Next, the work in the vertical pipe structure configured as described above will be described. Workers enter the shaft 300 from the ground through the manhole 400. Then, it enters the shaft pipe 2 from the upper opening of the shaft pipe 2, and descends downward along the first ladder 5. Then, each time the scaffolding member 4 is reached, the regulation plate 43 of the scaffolding member 4 is rotated to the second position, and the lid member 42 is removed. Then, the removed lid member 42 is hooked on the first ladder 5 by the hook 45. Then, after removing the lid member 42 in the lowermost scaffolding member 40, the second ladder 6 is removed from the inner wall surface of the shaft pipe 2. That is, after rotating the regulation plate 84 of the second holding member 8 from the first position to the second position, the second ladder 6 is lifted upward, and the first and second holding members 7, 8 to the second ladder Remove 6

After that, the hook 63 at the upper end of the second ladder 6 is hooked on the third holding member 9 while lowering the second ladder 6 downward from the through hole 411 of the lowermost scaffolding member 40. As a result, the second ladder 6 is hung between the lower end of the shaft pipe 2 and the lower surface of the shaft 300. Further, the second ladder 6 is hung diagonally or vertically so as to be away from the first ladder 5 so that the lowermost scaffolding member 40 does not interfere with each other. Subsequently, the worker descends to the lower surface of the shaft 300 along the second ladder 6 to perform the work.

When the work is completed, the second ladder 6 is climbed and the bottom scaffolding member 40 enters the shaft pipe 2 through the through hole 411. Then, the second ladder 6 is lifted upward, removed from the third holding member 9, and pulled up into the shaft tube 2. Next, the hook 63 of the second ladder 6 is hooked on the first holding member 7, and one of the treads 62 is fitted between the support plates 82 of the second holding member 8. After that, the regulation plate 84 is rotated and arranged at the first position so as to cover the upper part of the tread 62. This restricts the second ladder 6 from moving upwards and downwards.

Subsequently, the lid member 42 hooked on the first ladder 5 is removed and fitted into the through hole 411 of the lowest scaffolding member 40. Then, the regulation plate 43 is rotated and arranged at the first position. As a result, the lid member 42 is restricted from moving upward and is fixed to the main body 41. Then, every time the first ladder 5 is climbed and the scaffolding member 4 passes through the through hole 411, the lid member 42 closes the through hole 411. In this way, after exiting from the upper opening of the shaft tube 2, it exits from the manhole 400 to the ground.

<7. Water flow in vertical pipe structure>
As described above, the water flowing from the upper pipe line 100 flows into the upper opening of the vertical pipe 1. Then, this water flows downward through the guide plate 3 and flows into the lower pipe line 200 from the communication hole 11 of the vertical pipe 1. A part of the internal air pushed by water is returned to the upper pipe line 100 through the shaft pipe 2 and the scaffolding member 4. Further, water may flow backward, but at this time, it may flow upward through the guide plate 3 and may enter the inside of the shaft tube 2 through the lower opening of the shaft tube 2. At this time, since the scaffolding member 4 is formed in a mesh shape, the water that has flowed into the shaft tube 2 passes through the scaffolding member 4 and flows upward. However, even if it flows backward, it is normal that the upper pipeline 100 is not reached. Further, the water generated from the lower part of the vertical pipe 1 and the shaft pipe 2 and the gas generated from the sewage by the water descending to the lower pipe line 200 are pushed upward through the scaffolding member 4.

<8. Features>
The vertical pipe structure configured as described above has the following effects.
(1) Since the second ladder 6 can be hung in the space between the lower end of the shaft pipe 2 and the lower surface of the shaft 300, the work can be performed safely. Further, when the work is not performed, the second ladder 6 is held in the shaft tube 2 by the first and second holding members 7 and 8, so that the flow of water flowing downward through the guide plate 3 It is possible to prevent the second ladder 6 from being damaged.

(2) The second ladder 6 is held by the first and second holding members 7 and 8 on the inner wall surface of the shaft tube 2 so as not to move in the vertical direction. Therefore, it is possible to prevent the second ladder 6 from coming off the inner wall surface of the shaft tube 2 due to vibration or the like. Further, even when water flows back in the shaft tube 2, it is possible to prevent the second ladder 6 from flowing.

(3) Because the lower end of the first ladder 5 is located close to the lowermost scaffolding member 40, and the third holding member 9 is arranged between the lower end of the first ladder 5 and the lowermost scaffolding member 40. After descending the first ladder 5, the work of attaching the second ladder 6 to the third holding member 9 can be easily performed.

(4) The second ladder 6 is not arranged on the inner wall surface of the shaft tube 2 on the opposite side of the first ladder 5, but is arranged at a position shifted by 90 degrees in the circumferential direction from the first ladder 5. There is. Therefore, for example, when a worker carries a load on his back and moves up and down the first ladder 5, it is possible to prevent the worker from getting caught in the second ladder 6.

(5) The first to third holding members 7 to 9 are not attached to the positions where the guide plate 3 is attached in the shaft tube 2. Therefore, it is possible to prevent the strength of the shaft tube 2 from decreasing.

<9. Modification example>
Although one embodiment of the present invention has been described above, the present invention is not limited to this, and various modifications can be made without departing from the spirit of the present invention. The following modifications can be combined as appropriate.

<9-1>
The structures of the first and second holding members 7 and 8 are not particularly limited, and may have a structure capable of holding the second ladder 6 on the inner wall surface of the shaft tube 2. Therefore, for example, one or three or more holding members may be provided. Further, as long as the second ladder 6 can be held, the structure may be such that any position of the second ladder 6 is held. Further, a member such as the regulation plate 84 of the second holding member 8 may be provided on the first holding member 7 to prevent the second ladder 6 from moving upward. The first and second holding members 7 and 8 correspond to the first holding means of the present invention.

The first and second holding members 7 and 8 are attached at positions displaced by 90 degrees in the circumferential direction from the first ladder 5, but the first and second holding members 7 and 8 are not limited to this. For example, if the internal space of the shaft tube 2 is wide, it may be provided at any position, but if it is narrow, it is preferably attached at a position displaced by 45 to 135 degrees in the circumferential direction from the first ladder 5. In the above embodiment, the first ladder 5 is composed of a pair of vertically extending columns and a plurality of treads spanning the columns, but the first ladder 5 may be composed of U-shaped steps without providing the pair of columns.
<9-2>
The structure of the third holding member 9 is also not particularly limited, and any part of the second ladder 6 is fixed, and the second ladder 6 is hung between the lower end portion of the shaft pipe 2 and the lower surface of the vertical shaft 300. Any structure may be used as long as it can be fixed so that the second ladder 6 does not move when it is handed over.

<9-3>
The structure of the scaffolding member 4 is not particularly limited, and may be provided inside the shaft tube 2 at predetermined intervals so that the worker can take a rest. Therefore, it does not necessarily have to be a structure that partitions the inside of the shaft tube 2. Further, even in the structure for partitioning the shaft tube 2, the configuration of the through hole 411 and the lid member 42 is not particularly limited as described above. When the shaft tube 2 is short or the like, one scaffolding member 4 may or may not be provided below the shaft tube 2. A locking portion on which the hook 45 of the lid member 42 is hooked may be provided separately from the first ladder 5. It is preferable that the locking portion is attached at a position deviated from the center position of the first ladder 5 by 45 to 135 degrees, specifically 90 degrees, in the circumferential direction around the pipe axis of the shaft pipe 2. By hooking the lid member 42 to a place different from the first ladder 5, the lid member 42 does not get in the way and a plurality of workers can easily go up and down the first ladder 5.

<9-4>
The structure of the second ladder 6 is not particularly limited, and may be any structure that can be attached to the first to third holding members 7 to 9, for example.

<9-5>
The vertical pipe 1 may be arranged at any position of the vertical shaft 300, and the length and position in the vertical direction are not particularly limited. Therefore, for example, the vertical pipe 1 may extend to a position covering the upper pipe line 100, and in this case, a communication passage communicating with the upper pipe line 100 may be formed in the vertical pipe 1. Further, the length and position of the shaft tube 2 are not particularly limited, and can be appropriately set in the vertical tube 1. For example, the upper end portion of the shaft pipe 2 may be located at the upper end portion of the inner surface of the upper pipe line 100. In such a case, the shielding plate 31 may extend in the radial direction so as to connect the outer peripheral surface of the shaft tube 2 and the inner peripheral surface of the vertical tube 2. Further, the upper line 100 and the lower line 200 may not extend horizontally or may be inclined. As described above, the underground structure in which the vertical pipe structure is installed is not particularly limited. The guide plate 3 does not have to be a continuous spiral with a constant inclination, but may be a spiral as a whole. For example, the guide plate 3 may have a staircase shape.

1 Vertical pipe 2 Axial pipe 3 Guide plate 4 Scaffolding member 40 Bottom scaffolding member 5 1st ladder 6 2nd ladder 7 1st holding member (1st holding means)
8 Second holding member (first holding means)
84 Regulation board (Regulation Department)
9 Third holding member (second holding means)

Claims (6)

It is a vertical pipe structure arranged in a vertical shaft connecting the upper canal and the lower canal.
A cylindrical vertical pipe having an upper end portion communicating with the upper water channel and a lower end portion communicating with the lower water channel.
A cylindrical shaft tube arranged in the vertical tube and having a lower end portion at a position separated by a predetermined length upward from the lower surface of the vertical shaft,
A guide plate that spirally extends in the axial direction of the shaft tube so as to connect the outer peripheral surface of the shaft tube and the inner peripheral surface of the vertical tube.
A first ladder arranged on the inner wall surface of the shaft tube so as to extend in the axial direction of the shaft tube,
It is configured so that either the first aspect arranged in the shaft tube or the second aspect detachably hung between the lower end portion of the shaft tube and the lower surface of the shaft can be selectively taken. The second ladder and
The first holding means for holding the second ladder in the first aspect in the shaft tube,
A plurality of scaffolding members attached at predetermined intervals in the axial direction of the shaft tube, and
The vertical tube structure. Among the plurality of scaffolding members, the lowest scaffolding member arranged at the lowermost position is arranged near the lower end of the shaft tube.
The vertical pipe structure according to claim 1 , wherein the first holding means is configured to hold the second ladder above the lowermost scaffolding member. Among the plurality of scaffolding members, the lowest scaffolding member arranged at the lowermost position is arranged near the lower end of the shaft tube.
The vertical pipe structure according to claim 1 or 2 , wherein the second holding means is arranged above the lowermost scaffolding member and is configured to hold an upper end portion of the second ladder. Each of the scaffolding members is formed so as to partition the inside of the shaft tube in the axial direction, and is configured to allow gas or liquid to pass through.
The vertical pipe structure according to any one of claims 1 to 3 , wherein the scaffolding member has a through hole having a size that allows a person to pass through, and has a lid member that detachably closes the through hole. .. The vertical pipe structure according to claim 4 , wherein the lid member is configured to be detachably attached to the first ladder. The vertical pipe structure according to claim 4 or 5 , wherein the center of the through hole is closer to the first ladder than the center of the scaffolding member.

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