JP2017101450A - Waterproof sheet and tunnel waterproof structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a waterproof sheet capable of ensuring excellent water permeability and a waterproof structure of a tunnel. SOLUTION: In a waterproof sheet 11, a water-impervious sheet 13 having a flat front and back surface extended on the ground side of a tunnel excavation tunnel 19 and having substantially the same area as the water-impervious sheet 13 on the ground side of the water-impervious sheet 13. The non-woven fabric 15 fixed to the surface of the membrane and the longitudinal direction are provided by the tunnel inner circumference length of the tunnel excavation tunnel 19, and the width direction is shorter than the length along the tunnel excavation tunnel 19 of the water-impervious sheet 13. A water flow space forming material 17 is provided, which is sandwiched between the water-impervious sheet 13 and the non-woven fabric 15 to form a continuous water flow space 21 along the inner peripheral length of the tunnel. [Selection diagram] Fig. 2

Description

  The present invention relates to a waterproof sheet and a waterproof structure of a tunnel suitable for use in the FILM method and the NATM method.

A waterproof sheet is used at a construction site of a tunnel with a lot of spring water (see Patent Documents 1 and 2). In general, the waterproof sheet is often used by laminating a water shielding sheet and a nonwoven fabric. This waterproof sheet is used, for example, in the NATM method or the FILM method.
The NATM method is to fix a waterproof sheet on the ground or the surface of the sprayed concrete after spraying concrete on the ground, place a formwork at a predetermined distance from the waterproof sheet, and place concrete in the space. Build lining concrete.
The FILM method is to spread a waterproof sheet in advance on the outer peripheral surface of the formwork constructed in the mine, and fill the space between the waterproof sheet and the natural ground, so that the filler is entangled with the nonwoven fabric of the waterproof sheet. The waterproof sheet is stretched on the inner surface of the filler after curing.
In any of these methods, the nonwoven fabric constituting the waterproof sheet bears a buffering action and a water passing action. That is, the nonwoven fabric has a function as a cushioning material for preventing damage to the water-impervious sheet due to the protruding portion present on the construction surface, and a function of draining water leaking from the ground due to water permeability.

Utility Model Registration No. 3025160 JP 2001-214698 A

  However, the waterproof sheet may impair the original water permeability if the nonwoven fabric is compressed by the pressure of the concrete when the secondary lining concrete is placed from the back side opposite to the natural ground side. If there is a problem with the water permeability of the nonwoven fabric, the waterproof sheet cannot be drained well even if the amount of spring water is small, and there is a risk that it will be trapped or fall off. In particular, in the FILM method, a filler such as cement or mortar is filled with no gap between the natural ground side and the formwork. The filler penetrates into and penetrates the nonwoven fabric in order to obtain an adhesive action with the nonwoven fabric, that is, an anchor effect. As a result, in the waterproof sheet, the nonwoven fabric is cured, and a buffering action at the time of construction is obtained. However, the hardened nonwoven fabric makes it difficult for water to flow.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a waterproof sheet and a tunnel waterproof structure that can ensure excellent water permeability.

Next, means for solving the above problems will be described with reference to the drawings corresponding to the embodiments.
The waterproof sheet 11 according to claim 1 of the present invention is a water-impervious sheet 13 that is flat on the front and back and is stretched on the natural mountain side of the tunnel digging tunnel 19;
A non-woven fabric 15 having substantially the same area as the water-impervious sheet 13 and fixed to the ground-side surface of the water-impervious sheet 13;
The longitudinal direction is provided by the tunnel inner peripheral length of the tunnel digging tunnel 19, and the width direction is provided by a length shorter than the length of the water shielding sheet 13 in the direction along the tunnel digging tunnel 19. A raising material 17 sandwiched between the water sheet 13 and the nonwoven fabric 15 to form a continuous water passage space 21 along the inner circumferential length of the tunnel;
It is characterized by comprising.

  In this waterproof sheet 11, the nonwoven fabric 15 provided on the ground mountain side of the water-impervious sheet 13 has a buffering effect on the unevenness on the ground mountain side and an anchor effect on the placed concrete. Moreover, this nonwoven fabric 15 has water permeability. The non-woven fabric 15 having water permeability guides water from the natural mountain side to a water flow space 21 formed by the raising material 17. On the other hand, the nonwoven fabric 15 may be compressed by the pressure of the concrete when the secondary lining concrete is placed from above the water-impervious sheet 13, and may impair the original water permeability. Even in this case, the water soaks into the nonwoven fabric 15 not a little. The water soaked into the nonwoven fabric 15 is led to the water flow space 21 formed by the raising material 17 provided at a predetermined interval. That is, the nonwoven fabric 15 acts in a capillary way. The raising material 17 has a strength that is not crushed by the pressure of the concrete. Thereby, the waterproof sheet 11 can enable reliable drainage over a long period of time. Moreover, since the waterproof sheet 11 should just provide the raising material 17 locally, it can be manufactured in low cost.

The waterproof sheet according to claim 2 of the present invention is the waterproof sheet 11 according to claim 1,
The raising members 17, 57, 61 are provided with a front and back flat belt body 29 made of thermoplastic resin and having flexibility and water shielding properties, and opposed to the natural mountain side of the tunnel digging tunnel 19 of the belt body 29. The water flow space 21 is formed on the surface side.

  In this waterproof sheet, the water flow space 21 is disposed on the natural mountain side of the belt 29. The water flow space 21 is covered with the nonwoven fabric 15 on the natural mountain side. By arranging the band 29 on the surface of the water passage space 21 on the side of the mine shaft 19, water from the natural mountain side is guided along the band 29. Moreover, since the surface on the mine shaft side of the water flow space 21 becomes a flat surface in the belt body 29, the surface on the secondary lining side of the water shielding sheet 13, that is, the waterproof sheet construction surface can be smoothed.

The waterproof sheet 11 according to claim 3 of the present invention is the waterproof sheet 11 according to claim 1,
The raised material is made of a thermoplastic resin and has a flexible and water-blocking flat body 29 on the surface facing the natural mountain side of the tunnel digging pit 19 and a plurality of the water-passing spaces 21 therebetween. It is the water flow space formation material 17 in which the convex part 31 of this is formed integrally.

  In this waterproof sheet 11, a water flow space 21 is disposed on the natural mountain side of the water flow space forming member 17. The water flow space 21 is covered with the nonwoven fabric 15 on the natural mountain side. The free lime flowing from the natural mountain side such as the inner surface of the primary lining is captured by the nonwoven fabric 15, and the intrusion into the water flow space 21 is suppressed. Thereby, clogging of the water flow space 21 is suppressed over a long period of time. Moreover, since the surface on the mine shaft side becomes a flat surface in the belt body 29, the surface on the secondary lining side of the water shielding sheet 13, that is, the waterproof sheet construction surface can be smoothed.

The waterproof sheet 11 according to claim 4 of the present invention is the waterproof sheet 11 according to claim 3,
The convex portion is a plurality of protrusions 53.

  In the waterproof sheet 11, the protrusions are, for example, a plurality of protrusions 53 that are discontinuous island-shaped, and therefore, the waterproof sheet 11 is less likely to be crushed or collapsed than in the case of a continuously formed rib shape or the like. Moreover, since the protrusion 53 enables water to be passed vertically and horizontally as compared to a rib shape or the like continuous in the inner circumferential direction of the tunnel, the drainage can be improved.

The waterproof sheet 55 according to claim 5 of the present invention is the waterproof sheet 11 according to claim 1 or 2,
The raising material is at least one long body 57 provided along the longitudinal direction.

  In this waterproof sheet 55, for example, a rod-like or rail-like long body 57 is provided between the water-impervious sheet 13 and the nonwoven fabric 15 along the inner periphery of the tunnel. The long body 57 may be at least one. A gap is formed between the water shielding sheet 13 and the nonwoven fabric 15 by the long body 57 on both sides of the long body 57. This gap becomes the water flow space 21. The long body 57 can weld or bond another member to the water shielding sheet 13. In addition, the long body 57 can be integrally formed with the water-impervious sheet 13 by changing the shape of the die for extruding the water-impervious sheet 13 in the manufacturing process of the water-impervious sheet 13.

The waterproof sheet 59 according to claim 6 of the present invention is the waterproof sheet 11 according to claim 1 or 2,
The said raising material is provided along the said longitudinal direction, It is any one of the linear aggregate material 61 which has the said water flow space 21, a porous material, or an open-cell material, It is characterized by the above-mentioned.

  In the waterproof sheet 59, any one of the linear assembly material 61, the porous material, and the open cell material is provided between the water shielding sheet 13 and the nonwoven fabric 15 along the inner periphery of the tunnel. The outer periphery of the linear assembly material 61, the porous material, or the open cell material may be surrounded by the water shielding sheet 13 and the nonwoven fabric 15. When the water penetrates into the nonwoven fabric 15 and reaches the linear assembly material 61, the porous material, or the open cell material, the water is guided to the side bottom 25 of the tunnel 27 by the water passing space 21 included therein.

The waterproof sheet 11 according to claim 7 of the present invention is the waterproof sheet 11 according to any one of claims 1 to 6,
A plurality of the water shielding sheets 13 and the nonwoven fabric 15 formed with a predetermined length in a direction along the tunnel digging passage 19 are joined together by joining adjacent edges in the direction along the tunnel digging passage 19. Formed,
The raising material 17 is sandwiched between joint portions of the water shielding sheet 13 and the nonwoven fabric 15.

  In this waterproof sheet 11, a plurality of short nonwoven fabrics 15 and water shielding sheets 13 are joined to form a wide waterproof sheet 11. This is because, for example, it is difficult to produce a wide sheet of 6 m with a uniform thickness. Since the waterproof sheet 11 has a width of 6 m or more, for example, in the FILM method, the waterproof sheet construction surface can be smoothed and work efficiency can be improved. Even when the waterproof sheet 11 has such a wide width, the raising member 17 can be provided at a predetermined interval between the joint portions of the short water-impervious sheet 13 and the nonwoven fabric 15, so that stable water flow performance can be achieved. Can be secured.

The waterproof structure of the tunnel 27 according to claim 8 of the present invention is a waterproof structure of the tunnel 27 having the waterproof sheet 11 according to any one of claims 1 to 7,
The waterproof sheet 11 is embedded between the primary lining 33 and the secondary lining 35,
The water flow space 21 is formed on the surface of the waterproof sheet 11 facing the primary lining 33 along the circumferential direction from at least the ceiling portion 23 to the side bottom portion 25 of the tunnel 27.

  In the waterproof structure of the tunnel 27, the water flow space 21 is simultaneously formed on the natural mountain side of the water shielding sheet 13 by spreading the waterproof sheet 11 on the natural mountain side. That is, in the waterproof structure of the tunnel 27, before the waterproof sheet 11 is constructed, there is no need for a process such as constructing a sheet-like drainage material on the entire surface of the natural ground, and the construction work can be saved. The waterproof sheet 11 has an anchor effect because the nonwoven fabric 15 is embedded in the cast concrete, particularly in the FILM method. For this reason, the waterproof structure of the tunnel 27 can prevent the waterproof sheet 11 from being lifted or peeled off, and can obtain a smoothed waterproof sheet construction surface, and the drainage to the side bottom 25 in the water flow space 21. Is done.

  According to the waterproof sheet of the first aspect of the present invention, excellent water permeability can be secured by the water flow space formed by the raising material.

  According to the waterproof sheet of the second aspect of the present invention, the water from the natural ground passing through the water passing space by the belt can be drained along the belt. Moreover, a water flow space can be arrange | positioned to the natural ground side by fixing a belt | band | zone to a water-impervious sheet.

  According to the waterproof sheet of the third aspect of the present invention, the surface on the mine shaft side can be smoothed by the belt, and the construction quality of the secondary lining can be improved.

  According to the waterproof sheet of the fourth aspect of the present invention, the compressive strength of the convex portion can be increased.

  According to the waterproof sheet of the fifth aspect of the present invention, water permeability can be secured at a low cost with a simple structure.

  According to the waterproof sheet of the sixth aspect of the present invention, the water passage space can be reliably ensured without allowing the nonwoven fabric to enter the water passage space.

  According to the waterproof sheet according to claim 7 of the present invention, in the waterproof structure of the tunnel using the waterproof sheet having a wide width by joining the short-width waterproof sheet and the nonwoven fabric, the short-width waterproof sheet and the nonwoven fabric are joined. Raising materials can be provided at equal intervals between the parts.

  According to the waterproof structure of the tunnel according to claim 8 of the present invention, the drainage function can be ensured reliably and for a long time by the raising material, the construction quality of the secondary lining can be improved, and the raising material Can be built at low cost.

It is a schematic perspective view of the tunnel provided with the waterproof sheet which concerns on embodiment of this invention. It is sectional drawing of the direction orthogonal to the longitudinal direction of the raising material in the waterproof sheet shown in FIG. (A) is a plane cross-sectional view of a waterproof sheet formed by joining a plurality of pieces, and (b) is an enlarged view of part A of (a). It is a plane sectional view explaining a construction example of the NATM construction method using a waterproof sheet. It is a plane sectional view explaining the example of construction of the FILM method using a waterproof sheet. It is sectional drawing of the direction orthogonal to the longitudinal direction of the raising material of the waterproof sheet which concerns on the modification which provided the raising material in the width direction center part of the water-impervious sheet. It is sectional drawing of the direction orthogonal to the longitudinal direction of the raising material of the waterproof sheet which concerns on the modification provided with the several raising material in the width direction of the water-impervious sheet. It is a perspective view of the raising material whose convex part is a protrusion with a cross-sectional triangle. It is a perspective view of the raising material which concerns on the modification whose convex part is a protrusion with a semicircular cross section. (A) is a perspective view of the raising material which concerns on the modification by which the protrusion was formed intermittently, (b) is a perspective view of the raising material which concerns on the modification whose convex part is a some hemispherical protrusion. It is a perspective view of the waterproof sheet which concerns on the modification whose raising material is a long body. It is sectional drawing of the direction orthogonal to the longitudinal direction of the linear aggregate material of the waterproof sheet which concerns on the modification whose raising material is a linear aggregate material.

Embodiments according to the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic perspective view of a tunnel provided with a waterproof sheet according to an embodiment of the present invention.
The waterproof sheet 11 according to the present embodiment includes a water-impervious sheet 13, a nonwoven fabric 15, and a raising material, for example, a water passage space forming material 17 described later. The water-impervious sheet 13 has a predetermined length, that is, a length along the inner circumference of the tunnel, and a width, that is, a length in a direction along the tunnel, and is stretched on the natural mountain side of the tunnel digging tunnel 19. The water-impervious sheet 13 is formed as a flat surface. The water shielding sheet 13 is made of, for example, EVA (ethylene vinyl acetate copolymer). The water shielding sheet 13 is formed with a thickness of, for example, 0.8 mm or more (conforming to JIS A 6008).

The nonwoven fabric 15 has substantially the same area as the water-impervious sheet 13 and is fixed to the ground-side surface of the water-impervious sheet 13. Fixing is performed by welding or adhesion. The nonwoven fabric 15 is formed with a thickness of 3 mm or more (JIS L 1096). The nonwoven fabric 15 is obtained by depositing organic synthetic fiber filaments such as polyester, polyamide, and polypropylene. The non-woven fabric 15 is formed by stretching a large number of filaments spun from a spinning nozzle having a large number of orifices by a so-called spunbonding method with an air jet or the like, and blowing them downward. It can be deposited on the surface of the moving wire mesh conveyor with a predetermined basis weight to obtain a web. However, in this case, the nonwoven fabric 15, in order to enhance the supplemental of free lime, basis weight is preferably in the range of 20 to 150 g / m ^2, more preferably in the range of 30 to 80 g / m ² It is desirable. If the basis weight of the nonwoven fabric 15 is less than 20 g / m ² , free lime is likely to permeate, and if the basis weight is greater than 150 g / m ² , the water permeability to the water-passing space described later decreases.

  The water-impervious sheet 13 and the nonwoven fabric 15 have the length of the inner periphery of the tunnel digging tunnel 19 and are formed integrally by joining a plurality of sheets in the width direction (direction along the tunnel). In the present embodiment, as will be described later, three pieces are joined in the width direction, that is, three pieces are joined, and a predetermined width, for example, a width of about 6 m is obtained. The wide waterproof sheet 11 is joined at the connecting portion in the direction along the tunnel.

  In this embodiment, the raising material is the water flow space forming material 17. The water flow space forming member 17 is sandwiched between the water shielding sheet 13 and the nonwoven fabric 15 to form a water flow space 21 (see FIG. 2) continuous along the inner circumferential length of the tunnel. In the water flow space forming member 17, the longitudinal direction continuously has at least a length from the ceiling portion 23 to the side bottom portion 25 in the circumferential direction of the tunnel boring channel 19. Of course, the water flow space forming member 17 may have a length twice as long as that described above, that is, a tunnel inner circumferential length. Further, the water flow space forming member 17 may have a length from an arbitrary position from the ceiling portion 23 to the vicinity of the side bottom portion to the side bottom portion 25. In this embodiment, the water flow space forming member 17 is provided with the inner circumferential length of the tunnel in the longitudinal direction. The water flow space forming member 17 is provided with a length that is shorter than the length of the water impervious sheet 13 in the direction along the tunnel pier 19. That is, in the waterproof sheet 11, the water flow space forming member 17 is arranged with a predetermined interval in the extending direction of the tunnel 27 with the inner circumference of the tunnel digging hole as a full length.

2 is a cross-sectional view in a direction orthogonal to the longitudinal direction of the raising material in the waterproof sheet shown in FIG.
The water flow space forming member 17 has a band 29. The belt 29 is made of a thermoplastic resin and has flexibility and water shielding. The band 29 has a flat surface on the front and back, and a plurality of convex portions are integrally formed on the surface facing the natural mountain side of the tunnel digging tunnel 19. That is, in the water flow space forming member 17 having the band 29 as a constituent element, the surface facing the natural mountain side of the tunnel boring road 19 becomes an uneven surface due to the convex portion. In the present embodiment, the convex portion is the ridge 31. The protrusions 31 extend along the longitudinal direction of the belt body 29, and a plurality of protrusions 31 are integrally formed in parallel in a direction orthogonal to the longitudinal direction (band width direction). The protrusion 31 has a cross-sectional shape orthogonal to the extending direction, for example, a triangle. In addition, the cross-sectional shape of this protrusion 31 may be formed in other shapes, for example, a rectangle, a trapezoid, or a rib shape. In the water flow space forming material 17, the space between the protrusions 31 is a water flow space 21. Therefore, the water that has flowed down from the ceiling 23 of the tunnel digging channel 19 to the water flow space forming member 17 is guided to the water flow space 21 between the ridges 31 and drained to the side bottom 25. That is, the water flow space forming member 17 has a function as a ridge.

  The water flow space forming member 17 is preferably about 600 to 1300 mm with respect to the width of about 2000 mm of the water-impervious sheet 13. The height of the ridge 31 is preferably 1 to 30 mm. The water flow portion of the water flow space forming member 17 is preferably 20 to 80% in terms of the area ratio with respect to the band 29. Moreover, it is preferable that the ratio with respect to the whole width of the water flow part of the water flow space forming material 17 is 5 to 80%.

  In the water flow space forming material 17, the band 29 is fixed to the water shielding sheet 13 by welding or adhesion. Further, the non-woven fabric 15 is fixed to the tip of the protrusion 31 in the water flow space forming member 17. The nonwoven fabric 15 and the water flow space forming material 17 are fixed by welding, adhesion, or the like. The nonwoven fabric 15 has water permeability and covers the water flow space 21.

  The nonwoven fabric 15 allows water to pass through, but effectively supplements free lime and the like flowing out from the primary lining inner surface on the natural mountain side. For example, a porous material may be substituted for the nonwoven fabric 15. Moreover, the below-mentioned wire aggregate | assembly material which has what is called a noodle block structure may be substituted for the nonwoven fabric 15. The nonwoven fabric 15 may be substituted with open-cell sponge such as urethane sponge.

  In the waterproof structure of the tunnel 27 according to the present embodiment, the waterproof sheet 11 is embedded between the primary lining 33 and the secondary lining 35. A filler 37 is filled between the waterproof sheet 11 and the ground (or primary lining 33). A coagulant is mixed in the filler 37. The coagulant is various adhesives such as a synthetic resin type, a bond type, and a cement type. In the waterproof sheet 11, the nonwoven fabric 15 in which the filler 37 soaks has an anchor effect, and is fixed to the filler 37. Thereby, the waterproof structure of the tunnel 27 forms a continuous water flow space 21 along the circumferential direction from at least the ceiling portion 23 to the side bottom portion 25 of the tunnel 27 on the surface side facing the primary lining 33 of the waterproof sheet 11. To do.

FIG. 3A is a plan sectional view of a waterproof sheet formed by joining a plurality of pieces, and FIG. 3B is an enlarged view of a portion A of FIG.
The waterproof sheet 11 includes a plurality of water shielding sheets 13 and non-woven fabrics 15 formed in a predetermined length in a direction along the tunnel digging passage 19 and joining adjacent edges in a direction along the tunnel digging passage 19 together. Formed. In the present embodiment, the waterproof sheet 13 and the nonwoven fabric 15 formed with a short width of about 2 m are joined in the width direction, that is, three sheets are joined together to form a wide (about 6 m) waterproof sheet 11. The water flow space forming member 17 is sandwiched between the joint portions of the water shielding sheet 13 and the nonwoven fabric 15.

  In the FILM method, in order to improve the work efficiency and smoothness of the finish, the waterproof sheet 11 has a structure of the waterproof sheet 11 in which three sheets having a width of about 2 m are connected in the width direction and a sheet having a width of about 6 m is used. ing. In the manufacturing process, the water flow space forming member 17 is arranged and fixed at the joint. Therefore, two drainage structures are provided in the waterproof sheet 11 having a width of about 6 m before the construction site is carried in.

  Further, at the time of tunnel construction, when the waterproof sheet 11 having a width of about 6 m is stretched, the rear end of the waterproof sheet 11 in the previous process is welded and connected to the front end of the waterproof sheet 11 to be stretched next. At this time, the nonwoven fabric 15 is a nonwoven fabric, and the water shielding sheet 13 is a water shielding sheet, and is connected by welding or adhesion. At this time, the water flow space forming member 17 is disposed between the water-impervious sheet 13 and the nonwoven fabric 15 and fixed by welding or adhesion, and then each part is connected and fixed. Thereby, the water flow space forming material 17 can be arranged at an interval of about 2 m.

  Note that the number of joints between the short waterproof sheet 11 and the short waterproof sheet 11 is not limited to this, and may be two joints, or three or more four joints or multiple joints of five or more joints. Also good.

Next, the example of the construction method in the waterproof structure of the tunnel 27 using the waterproof sheet 11 is demonstrated.
FIG. 4 is a plan sectional view for explaining a construction example of the NATM construction method using a waterproof sheet.
The waterproof structure of the tunnel 27 is provided with a primary lining 33, a filler 37, the waterproof sheet 11 and a secondary lining 35 in order from the ground surface of the tunnel 27. In the rock bolt / sprayed concrete tunnel construction method, so-called NATM construction method, between the primary lining 33 sprayed to the natural ground via the rock bolt and the secondary lining 35 which becomes the inner peripheral surface of the tunnel 27, A waterproof sheet 11 is interposed. When the waterproof sheet 11 is stretched, first, the nonwoven fabrics 15 are overlapped at the rear end of the waterproof sheet 11 in the previous step and the front end of the waterproof sheet 11 to be stretched next, and the primary lining is performed using the concrete nails 39 or the like. Fix to 33.

  Subsequently, the water flow space forming material 17 is fixed to the rear end of the water-impervious sheet 13 in the previous step by welding or adhesion. The front end of the water-impervious sheet 13 of the next process is connected to the opposite surface of the water-impervious sheet forming sheet 17 of the previous process to which the water-permeable space forming material 17 is fixed by welding or bonding. As a result, the water flow space forming members 17 are arranged at intervals of about 2 m. This prevents spring water from the primary lining side from leaking to the secondary lining side.

FIG. 5 is a plan sectional view for explaining a construction example of the FILM method using a waterproof sheet.
In the FILM method, the formwork carriage provided with the formwork 41 along the inner peripheral surface of the tunnel pier 19 is moved along the tunnel pier 19, and the waterproof sheets 11 are sequentially spread on the inner peripheral surface of the tunnel. Go. First, the waterproof sheet 11 is installed on the formwork carriage. In order to prevent the leakage of the filler 37, a filler sealing member (air bulk) is installed in the inner circumferential direction of the tunnel. Next, a filler 37 is filled between the natural ground side and the waterproof sheet 11. After curing the filler 37, the air bulk gap generated by removing the mold 41 can be used for the installation space of the water flow space forming material 17.

The formwork carriage is moved to the position of the next process after finishing the expansion of the waterproof sheet 11 of the previous process. The waterproof sheet 11 of the next process is installed in the formwork cart.
Next, the front end of the nonwoven fabric 15 in the next step is fixed to the rear end of the nonwoven fabric 15 in the previous step by welding or adhesion. The water flow space forming material 17 is fixed to the rear end of the water-impervious sheet 13 in the previous step by welding or adhesion. The front end of the water-impervious sheet 13 of the next process is connected to the opposite surface of the water-impervious sheet forming sheet 17 of the previous process to which the water-permeable space forming material 17 is fixed by welding or bonding. Again, the front end of the waterproof sheet 11 in the next step is closed with air bulk. Similarly, the filler 37 is filled between the natural ground side and the waterproof sheet 11, and the waterproof sheet 11 is spread on the inner peripheral surface of the tunnel. As a result, the water flow space forming member 17 is arranged at intervals of connection portions for each process. Thereby, the spring water from the primary lining side is prevented from leaking to the secondary lining side, and the spring water can be drained to the side bottom 25.

FIG. 6 is a cross-sectional view in a direction perpendicular to the longitudinal direction of the raising member of the waterproof sheet according to the modification in which the raising member is provided in the center portion in the width direction of the water-impervious sheet.
The waterproof sheet 11 may be provided with a water flow space forming member 17 at the center in the width direction of the short sheet. In this case, for example, in the example of the waterproof sheet 11 formed by joining the three short width sheets described above, the two water flow space forming members 17 are provided at two joint portions, that is, the joint portions of the adjacent short width sheets. In addition, a total of five water passage space forming members 17 including three water passage space forming members 17 provided at the center of each short-width sheet can be provided. Further, without providing the water passage space forming material 17 at the joint, it can be configured as the waterproof sheet 11 provided with the water passage space forming material 17 at each central portion. In this case, the water passage space forming material at the joint portion 17 fixing steps can be omitted.

FIG. 7 is a cross-sectional view in a direction perpendicular to the longitudinal direction of the raising material of the waterproof sheet according to the modification in which a plurality of raising materials are provided in the width direction of the water shielding sheet.
The waterproof sheet 11 may be provided with a plurality of (two in the illustrated example) water flow space forming members 17 in the width direction of the short sheet. In this case, in the example of the waterproof sheet 11 formed by joining the three short-width sheets described above, the two water flow space forming members 17 are provided at the two joint portions, and 6 provided at the center portion of each sheet. A total of eight water flow space forming members 17 including one water flow space forming member 17 are provided. Thus, the waterproof sheet 11 exhibits a superior drainage function even at the site of a mountain tunnel where there is a lot of spring water by providing a large number of water flow space forming members 17.

Next, the operation of the above configuration will be described.
In the waterproof sheet 11 according to this embodiment, the nonwoven fabric 15 provided on the ground mountain side of the water shielding sheet 13 has a buffering effect on the unevenness on the ground mountain side and an anchor effect on the placed concrete. Moreover, the nonwoven fabric 15 has water permeability. The nonwoven fabric 15 having water permeability guides water from the natural mountain side to the water flow space 21 formed by the water flow space forming material 17. On the other hand, the nonwoven fabric 15 may be compressed by the pressure of the concrete when the secondary lining concrete is placed from above the water-impervious sheet 13, and may impair the original water permeability. Even in this case, the water does not soak into the non-woven fabric 15 and does not completely lose water permeability. The water soaked into the nonwoven fabric 15 is guided to the water flow space 21 formed by the water flow space forming material 17 provided at a predetermined interval. That is, the nonwoven fabric 15 acts in a capillary way. The water flow space forming member 17 has a strength that is not crushed by the pressure of the concrete. Thereby, the waterproof sheet 11 can enable reliable drainage over a long period of time. Moreover, since the waterproof sheet 11 should just provide the water flow space formation material 17 locally, it can be manufactured in low cost.

  In the waterproof sheet 11, a water flow space 21 is disposed on the ground mountain side of the water flow space forming member 17. The water flow space 21 is covered with the nonwoven fabric 15 on the natural mountain side. The free lime flowing from the inner surface of the primary lining is supplemented by the nonwoven fabric 15 and the intrusion into the water passage space 21 is suppressed. For this reason, clogging of the water flow space 21 is suppressed over a long period of time. Moreover, since the water passage space forming material 17 has a flat surface on the mine shaft side, the surface on the secondary lining side of the water shielding sheet 13, that is, the waterproof sheet construction surface can be smoothed. As a result, the surface of the mine shaft side can be smoothed by the belt 29, and the construction quality of the secondary lining 35 can be improved.

  In the waterproof sheet 11, the wide waterproof sheet 11 is formed by joining a plurality of short nonwoven fabrics 15 and the water shielding sheet 13. This is because it is difficult to produce a wide sheet of about 6 m in a uniform thickness. Since the waterproof sheet 11 has a width of 6 m or more, for example, in the FILM method, the waterproof sheet construction surface can be smoothed and work efficiency can be improved. Even when the waterproof sheet 11 has such a wide width, the water-passing space forming material 17 can be provided at predetermined intervals between the joint portions of the short width water-impervious sheet 13 and the nonwoven fabric 15, so that Water performance can be ensured. As a result, in the waterproof structure of the tunnel 27 using the waterproof sheet 11 having a wide width by joining the short water-impervious sheet 13 and the nonwoven fabric 15, between the joints of the short water-impervious sheet 13 and the nonwoven fabric 15, The water flow space forming members 17 can be provided at equal intervals.

  In the waterproof structure of the tunnel 27, the waterproof sheet 11 is stretched on the ground mountain side, so that a water flow space 21 is simultaneously formed on the ground mountain side of the water shielding sheet 13. That is, in the waterproof structure of the tunnel 27, it is not necessary to construct a sheet-like drainage material on the entire surface of the natural ground before the waterproof sheet 11 is constructed, and the labor of the construction can be saved. Further, the waterproof sheet 11 has an anchor effect because the nonwoven fabric 15 is embedded in the cast concrete particularly in the FILM method. For this reason, the waterproof structure of the tunnel 27 can prevent the waterproof sheet 11 from being lifted or peeled off, and can obtain a smoothed high-quality waterproof sheet construction surface.

FIG. 8 is a perspective view of the raising member whose protrusion is a protrusion having a triangular cross section.
As shown in FIG. 8, the protrusion 31 having the above-described configuration has a cross-sectional shape orthogonal to the extending direction, for example, a triangle. The ridge 31 is formed with a triangular cross section, thereby having high compressive strength and enhanced durability.

Next, a modified example of the above configuration will be described.
FIG. 9 is a perspective view of a raising material according to a modification in which the protrusion is a protrusion having a semicircular cross section.
As another shape of the convex portion, as shown in FIG. 9, the convex portion of the water flow space forming member 43 may be a protrusion 45 having a semicircular cross-sectional shape orthogonal to the extending direction.
According to this protrusion 45, the fixed area with the nonwoven fabric 15 can be enlarged compared with the thing of a cross-sectional triangle. Further, the protrusion 45 can further increase the compressive strength as compared with a triangular one. Moreover, the protrusion 45 can also make the bending of the direction along a tunnel inner periphery easier than the thing of a cross-sectional triangle.

FIG. 10A is a perspective view of a raised material according to a modified example in which the protrusions are intermittently formed, and FIG. 10B is a perspective view of the raised material according to the modified example in which the convex portion is a plurality of hemispherical protrusions.
As shown to Fig.10 (a), the protrusion 49 of the water flow space formation material 47 may be the protrusion 49 which interrupts. That is, the protrusion 49 may not be formed continuously.
According to the protrusion 49, the water passing space 21 is also formed in the band width direction so that water can be passed in the band width direction, the drainage effect is enhanced, and clogging is less likely to occur. . Moreover, the water flow space forming material 47 can be easily bent along the curved surface of the natural ground surface, and the workability can be improved.

Further, as shown in FIG. 10B, the convex portion of the water flow space forming member 51 may be a plurality of protrusions 53.
In this water flow space forming member 51, the convex portion becomes a discontinuous island-shaped protrusion 53, so that it is less likely to be crushed or collapsed than in the case of a continuously formed rib shape or the like. As a result, the compressive strength of the convex portion can be further increased. Moreover, since the protrusion 53 has the water flow space 21 also in the width direction compared with the rib shape etc. which continue in the tunnel inner peripheral direction, and water can be passed vertically and horizontally, it can improve drainage. it can. Moreover, the water flow space forming material 51 can be easily bent along the curved surface of the natural ground surface, and can improve the workability.

FIG. 11 is a perspective view of a waterproof sheet according to a modification in which the raising material is a long body.
The waterproof sheet 55 may be at least one rail-like long body 57 in which the raising material is provided along the longitudinal direction. The long body 57 is formed, for example, in a quadrangular cross-sectional shape in a direction orthogonal to the longitudinal direction. In addition, the cross-sectional shape of the long body 57 may be a triangle or a semicircle. The bottom surface of the long body 57 is fixed to the water shielding sheet 13 by welding or adhesion. Two or more long bodies 57 are preferably provided. In the waterproof sheet 55, the water flow space 21 having a quadrangular cross section is formed by the nonwoven fabric 15 stretched around the upper ends of the two long bodies 57.

  In this waterproof sheet 55, for example, when there is one elongate body 57, a gap is formed between both sides of the elongate body 57 between the water shielding sheet 13 and the nonwoven fabric 15. This gap becomes the water flow space 21. As described above, two or more long bodies 57 are preferably provided. Thereby, the water flow space 21 having a square cross section surrounded by the water shielding sheet 13, the nonwoven fabric 15, and the long body 57 is formed. The long body 57 can weld or bond another member to the water shielding sheet 13. In addition, the long body 57 can be integrally formed with the water-impervious sheet 13 by changing the shape of the die for extruding the water-impervious sheet 13 in the manufacturing process of the water-impervious sheet 13. As a result, water permeability can be secured at a low cost with a simple structure. In addition, when this elongate body 57 is comprised with multiple, for example, these elongate bodies 57 consist of thermoplastic resins like the above-mentioned belt body 29, and the front and back flat belt | band | zone which has flexibility and water shielding It can be integrally arranged and fixed on one surface of the body by bonding or the like.

FIG. 12 is a cross-sectional view in a direction orthogonal to the longitudinal direction of the linear assembly of the waterproof sheet according to the modification in which the raising material is a linear assembly.
In the waterproof sheet 59, the raising material is any one of a linear assembly material 61 provided along the longitudinal direction and having a water passage space 21, a porous material (not shown), or an open cell material (not shown). May be. These linear aggregates 61, porous materials or open cells have good water permeability, compressive strength, and durability, and are integrated with the water shielding sheet 13 and the nonwoven fabric 15 by fixing means such as an adhesive. . As the material of the wire constituting the linear aggregate 61, vegetable fiber, glass fiber, synthetic fiber, metal or the like can be used. The linear assembly material 61, the porous material, or the open cell material is made of a thermoplastic resin such as the above-described band body 29, and is adhered to one surface of the front and back flat band bodies having flexibility and water shielding. It is good also as a structure fixed by etc.

  In this waterproof sheet 59, any one of a linear aggregate material 61 having a noodle mass structure, a porous material, or an open cell material is provided between the water shielding sheet 13 and the nonwoven fabric 15 along the inner periphery of the tunnel. The outer periphery of the linear assembly material 61, the porous material, or the open cell material may be surrounded by the water shielding sheet 13 and the nonwoven fabric 15. When the water penetrates into the nonwoven fabric 15 and reaches the linear assembly material 61, the porous material, or the open cell material, the water is guided to the side bottom 25 of the tunnel 27 by the water passing space 21 included therein. As a result, the water flow space 21 can be reliably secured without allowing the nonwoven fabric 15 to enter the water flow space 21.

In addition, the waterproof sheet 11 may provide the nonwoven fabric 15 of a different fabric weight in two layers on the opposite side of the water shielding sheet 13 on both sides of the raising material. That is, the nonwoven fabric 15 is configured as two sheets. In this case, the basis weight of the lower layer nonwoven fabric 15 fixed to the raising material is increased (20 to 150 g / m ² ), and the basis weight of the upper layer nonwoven fabric 15 on the surface side is decreased (20 g / m ² or less). Thereby, the complementary property of free lime can be enhanced by the lower layer nonwoven fabric 15 while the anchor effect is reliably obtained by the upper layer nonwoven fabric 15.

  Therefore, according to the waterproof sheets 11, 55, 59 according to the present embodiment, excellent water permeability can be secured.

  According to the waterproof structure of the tunnel 27 according to the present embodiment, the drainage function is reliably and long-termed by the water flow space forming materials 17, 43, 47, 51, the long body 57, and the linear assembly material 61 as the raising material. While being able to secure, the construction quality of the secondary lining 35 can be improved, and since the raising material is locally provided, the tunnel 27 can be constructed at low cost.

DESCRIPTION OF SYMBOLS 11,55,59 ... Waterproof sheet 13 ... Water shielding sheet 15 ... Nonwoven fabric 17 ... Raising material (water-permeable space forming material)
DESCRIPTION OF SYMBOLS 19 ... Tunnel digging passage 21 ... Water flow space 23 ... Ceiling part 25 ... Side bottom part 27 ... Tunnel 29 ... Band 31, 45, 49 ... Projection (projection)
33 ... Primary lining 35 ... Secondary lining 43, 47, 51 ... Raising material (water flow space forming material)
53. Projection (convex part)
57 ... Raising material (long body)
61 ... Raising material (linear assembly material)

Claims (8)

A flat and impermeable sheet spread on the ground side of the tunnel digging tunnel,
A non-woven fabric that has substantially the same area as the water-impervious sheet and is fixed to the ground-side surface of the water-impermeable sheet;
The longitudinal direction is provided by the inner circumferential length of the tunnel digging tunnel, and the width direction is provided by a length shorter than the length of the water shielding sheet along the tunnel digging tunnel, A raising material that is sandwiched between the nonwoven fabrics to form a continuous water passing space along the inner circumference of the tunnel;
A waterproof sheet comprising: The waterproof sheet according to claim 1,
The raising member is provided with a front and back flat belt made of thermoplastic resin and having flexibility and water shielding, and the water flow space is formed on the surface of the belt facing the natural mountain side of the tunnel digging tunnel. A waterproof sheet characterized by being formed. The waterproof sheet according to claim 1,
The raised material is made of a thermoplastic resin and has a plurality of convex portions that are flexible and water-blocking on the surface facing the natural ground side of the tunnel excavation road of the front and back flat strips, and between which the water passing space is formed. A waterproof sheet, characterized in that is a water flow space forming material formed integrally. The waterproof sheet according to claim 3,
The waterproof sheet, wherein the convex portion is a plurality of protrusions. The waterproof sheet according to claim 1 or 2,
The waterproof sheet, wherein the raising material is at least one long body provided along the longitudinal direction. The waterproof sheet according to claim 1 or 2,
The waterproof sheet, wherein the raising material is any one of a linear assembly material, a porous material, and an open-cell material provided along the longitudinal direction and having the water passage space. The waterproof sheet according to any one of claims 1 to 6,
The plurality of water shielding sheets and the non-woven fabric formed in a predetermined length in the direction along the tunnel digging tunnel are formed integrally by joining adjacent edges in the direction along the tunnel digging tunnel,
The waterproof sheet, wherein the raising material is sandwiched between joints of the water shielding sheet and the nonwoven fabric. A waterproof structure of a tunnel having the waterproof sheet according to any one of claims 1 to 7,
The waterproof sheet is embedded between the primary lining and the secondary lining,
A waterproof structure for a tunnel, wherein the water passage space along the circumferential direction from at least a ceiling portion to a side bottom portion of the tunnel is formed on a surface of the waterproof sheet facing the primary lining.

Images