JP2019157471A - Waterproof sheet for tunnel - Google Patents

Abstract

To provide a waterproof sheet for a tunnel that facilitates the management of the concrete placement height in a lining space.SOLUTION: A tunnel waterproof sheet 4 disposed between a primary lining 2 and a secondary lining 3 of a tunnel 1 is a tunnel waterproof sheet in which a marking 41 indicating the concrete placement height of the secondary lining 2 is printed on the waterproof sheet 4. In the tunnel waterproof sheet 4, for the marking 41, the same pattern or the same color marking is arranged for each predetermined concrete placement height, different patterns or colors are arranged at arbitrary intervals, and the waterproof sheet 4 can be cut and used for each different pattern or color.SELECTED DRAWING: Figure 1

Description

The present invention relates to a waterproof sheet for a tunnel.

In a mountain tunnel constructed by the NATM method, a waterproof sheet is provided around the tunnel lining to prevent water from penetrating into the tunnel.
In the NATM method, a waterproof sheet is fixed to the surface of the sprayed concrete (primary lining) after the concrete is sprayed on the ground, and a formwork called a centle is placed at a predetermined distance from the surface of the waterproof sheet to create a lining space. Form concrete and place concrete in the lining space to construct lining concrete (secondary lining).
When placing concrete in the lining space, a concrete placement pipe is inserted into an opening such as a placement hole provided in the top end portion or side wall portion of the centle, and the concrete is pumped.
Furthermore, the concrete poured into the lining space needs to be compacted by inserting a vibrator into the concrete through a placement hole or an inspection window. The vibrator has a range that can be compacted by the output of the vibrator and must be inserted at an appropriate interval. Therefore, it is necessary to press the concrete at every predetermined concrete placement height, insert a vibrator at a predetermined interval in both the horizontal and vertical directions, and appropriately compact the concrete.
Conventionally, the concrete placement height was hit with a wooden mallet from the inside with a wooden mallet, and the filling height was confirmed from the difference in sound. This confirmation method takes time because it cannot be confirmed without hitting, and the construction becomes complicated.
Moreover, although the lining space can be visually recognized from the inspection window, the exact height cannot be confirmed.
Patent Document 1 discloses a device in which a sensor that senses the filling of concrete is arranged in the centle and can grasp the filling state. However, a device that places a large number of sensors in a centle mold and controls them, PC In addition to the need for a display or the like, since the sensor touches the concrete, there is a possibility that accurate measurement cannot be performed without careful cleaning after the centle is removed from the concrete.

JP, 2006-030900, A

  The object of the present invention is to facilitate the management of the concrete placement height in the lining space.

1. A tunnel waterproof sheet disposed between a primary lining and a secondary lining of a tunnel, the marking indicating the concrete placement height of the secondary lining being printed on the sheet Waterproof sheet for tunnels.
2. For the marking, markings of the same pattern or the same color are arranged at every predetermined concrete placement height, different patterns or colors are arranged at arbitrary intervals, and the waterproof sheet is cut and used for each different pattern or color. 2. The tunnel waterproof sheet according to 1, wherein the waterproof sheet for tunnel is provided.
3. The waterproof sheet for tunnel according to 1 or 2, wherein a fluorescent paint is used for the marking.

According to the waterproof sheet for tunnel of the present invention, it is possible to easily manage the placement height of the tunnel secondary lining concrete.

It is sectional drawing which shows the tunnel structure in connection with embodiment of this invention. It is a general-view figure which shows the construction condition in connection with embodiment of this invention. It is a perspective view which shows the construction condition in connection with embodiment of this invention. It is a top view which shows the waterproof sheet in connection with embodiment of this invention. 1 is an overview diagram showing a printing apparatus according to an embodiment of the present invention.

Details of the present invention will be described below.
According to the waterproof sheet for tunnel of the present invention, the concrete placement height can be easily managed.
In the waterproof sheet for tunnel of the present invention, a marking indicating the concrete placement height of the secondary lining is printed on the sheet. When the waterproof sheet is fixed to the primary lining surface after the primary lining is completed, the marking position becomes the placement height.
After placing the centle, a lining space is formed between the waterproof sheet and the centle, and when placing concrete in the lining space, a vibrator is applied to each marking printed on the waterproof sheet and compacted. Just do it.
When an operator places concrete, the operator can adjust the pumping amount of the concrete while visually checking the markings printed on the waterproof sheet, so that the placement height can be easily managed.

This will be described below with reference to the drawings.
FIG. 1 is a cross-sectional view showing a situation at the time of construction of a tunnel 1 using the waterproof sheet 4 for a tunnel of the present invention, and is a situation in the middle of placing concrete for secondary lining.
In the present embodiment, a case where construction is performed by a general NATM construction method as a tunnel excavation method will be described as an example. First, the natural ground G is excavated to form the tunnel 1. The excavation method is blasting or excavating with an excavating machine.
Immediately after excavation, an arch-shaped steel support (not shown) is built, and the primary lining 2 is formed by spraying concrete onto the tunnel wall surface with the steel support installed.
After forming the primary lining 2, the waterproof sheet 4 is stretched along the primary lining 2. The waterproof sheet 4 may be fixed by a known method, using an aerial work vehicle or the like using those disclosed in Japanese Patent Application Laid-Open Nos. 58-127900 and 2006-70656. And perform the construction.
After the waterproof sheet 4 is fixed, the centle mold 5 is arranged to form the lining space 3 and the placement of the concrete lining 31 for the secondary lining is started. In placing concrete, concrete is poured from a pipe previously attached to the centle mold 5, and a vibrator is inserted from an opening provided in the centle mold 5 to perform a compacting operation. At this time, the worker performing the concrete placement work needs to manage the amount of concrete poured from the opening (concrete placement height), and the concrete is poured while visually observing the marking 41 marked on the waterproof sheet 4. It is possible to easily manage the placement height by adjusting the amount.

FIG. 2 is a diagram showing a construction situation when the waterproof sheet 4 is fixed. A waterproof sheet 4 obtained by cutting a belt-like sheet into a predetermined length in accordance with the size of the tunnel 1 is brought into the construction site in a state of being wound from both ends toward the center.
First, it is fixed from the top end 11 of the tunnel 1 and is fixed while gradually unfolding from a state where both ends of the waterproof sheet 4 are wound. The entire tunnel 1 can be covered with the waterproof sheet 4 by repeating this operation in the tunnel axis direction of the tunnel 1 and welding adjacent ends of the waterproof sheet 4.

After the waterproof sheet 4 is fixed, concrete is poured into the lining space 3 formed by arranging the centle mold 5 at a predetermined location to form a secondary lining.
FIG. 3 is a perspective view showing details of the situation when placing concrete.
When pouring concrete into the lining space 3, the amount of concrete (placement height) is managed using the marking 41 marked on the waterproof sheet 4 as a mark. From an opening 51 provided in the centle mold 5, an operator can directly see the amount of concrete. After that, the vibrator 6 is inserted from the opening 51 and the concrete is compacted. When the compacting operation is completed, the concrete is poured into the lining space 3 again. In that case, the amount of concrete is managed while visually confirming the marking 41 in the same manner as in the construction of the lower layer. This is sequentially repeated to form a secondary lining.
The compacting operation is often performed every 50 cm of the placement height, and the interval between the markings 41 is preferably 50 cm. The placement height is not limited because it is determined according to the concrete used, construction conditions, and the like.
Further, since the concrete placement height is often managed at the tunnel leg 12 below the tunnel shoulder 13, the marking 41 may be within the range of the tunnel leg 12.
Further, the marking 41 does not have to be continuous in the tunnel axis direction. For example, even if the waterproof sheet 4 on which the marking 41 is printed and the waterproof sheet 4 on which the marking 41 is not printed are used alternately, There is no hindrance to the height management.

FIG. 4 shows an example of the marking 41 printed on the waterproof sheet 4.
As for the waterproof sheet 4, it is necessary to make the strip | belt-shaped sheet | seat into the length matched with the cross-sectional shape of the tunnel to construct. In the case of FIG. 4A, after the waterproof sheet 4 is cut to a predetermined length, the markings 41 are printed on the both ends of the waterproof sheet 4 at intervals of the placement height. In the embodiment, the marking 41 is written every 0.5 m.
In order to improve the visibility in the lining space, the marking 41 may use a fluorescent paint or a phosphorescent paint. There is no lighting in the lining space, and there is no choice but to rely on external lighting, so it is a dark place. Therefore, visibility can be improved by marking using a fluorescent paint.

As described above, the waterproof sheet 4 needs to have a length that matches the cross-sectional shape of the tunnel. When printing is performed after the waterproof sheet 4 is cut, the manufacturing process may be complicated. When markings 41 with an interval of 0.5 m are written before cutting, the cut portion of the waterproof sheet 4 can be cut only every 0.5 m.
Therefore, when managing the concrete placement height at 0.5 m, as shown in FIG. 4B, the double line marking 41a and the wavy line marking 41b are written at intervals of 0.5 m, and the double line marking 41a and the wavy line are marked. If the interval between the markings 41b is written at intervals of 0.25 m, the waterproof sheet 4 can be cut at intervals of 0.25 m. In the case of FIG.3 (b), the case where the double line marking 41a is located in the edge part is shown, and at the time of management of placement height, the placement height of concrete is made using the double line marking 41a as a mark. Although it is only necessary to manage, although not shown, when the wavy marking 41b is located at the end, the placing height of the concrete is managed using the wavy marking 41b as a mark.
In the embodiment, the case where the waterproof sheet 4 can be cut every 0.25 m is shown. However, when cutting at intervals of 0.1 m, markings of different patterns or colors are printed at intervals of 0.1 m, and every 0.5 m. What is necessary is just to print the marking of the same pattern or color, and what is necessary is just to set the space | interval.

FIG. 5 shows a printing apparatus 7 as an embodiment of a method for printing the marking 41 on the waterproof sheet 4. The printing apparatus 7 includes a rotating body 8 for printing and a supporting rotating body 9 for supporting the waterproof sheet 4, and supports the rotating body by a mount 71.
The circumference of the rotating body for printing is the marking interval or a multiple of the marking interval.
The printing apparatus 7 shown in FIG. 5 is an apparatus for printing the double line marking 41a and the wavy line marking 42b shown in FIG. 4b. The printing rotator 8 includes stamp portions 81a and 81b. The stamp part 81 is made to soak ink using foamed rubber, for example. An ink replenishing mechanism may be provided inside the rotating body and on the back side of the stamp portion 81. The stamp portion 81a has a double line shape, and the stamp portion 81b has a wavy line.
Printing is performed by passing the waterproof sheet 4 between the printing rotator 8 and the supporting rotator 9. Therefore, in order to prevent idling, the rotating body is preferably covered with a material having a large amount of friction such as rubber so that friction can be obtained.
The entire circumference of the printing rotator 8 is 0.5 m, and the stamp portions 81a and 81b are arranged so as to be 0.25 m at equal intervals. The separation between the printing rotator 8 and the supporting rotator 9 is adjusted to sandwich the waterproof sheet 4.
The waterproof sheet 4 is passed between the printing rotator 8 and the supporting rotator 9, the printing rotator 8 rotates, and the stamp part 81 is marked by contacting the waterproof sheet 4, and the stamp part 81a and the stamp part are marked. 81b is alternately marked on the waterproof sheet 4 at intervals of 0.25 m, and the waterproof sheet 4 shown in FIG. 3B can be created.
The printing method is not limited to the above method, and printing can be performed by, for example, leaving the waterproof sheet 4 in a developed state and rotating the printing rotating body 8 on the upper part. .

DESCRIPTION OF SYMBOLS 1 Tunnel 2 Primary lining 3 Secondary lining 4 Waterproof sheet 41 Marking 5 Centr form 6 Vibrator 7 Printing device

Claims (3)

A tunnel waterproof sheet disposed between a primary lining and a secondary lining of a tunnel,
A waterproofing sheet for tunnels, wherein a marking indicating the concrete placement height of the secondary lining is printed on the sheet.   For the marking, markings of the same pattern or the same color are arranged at every predetermined concrete placement height, different patterns or colors are arranged at arbitrary intervals, and the waterproof sheet is cut and used for each different pattern or color. The tunnel waterproof sheet according to claim 1, wherein:   The tunnel waterproof sheet according to claim 1 or 2, wherein a fluorescent paint is used for the marking.

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