JP2021120522A - Water stopping method along crack - Google Patents

Abstract

To provide a water stopping method that can prevent water leakage from bent or distorted cracks generated intermittently in a hollow concrete structure for a long period of time.SOLUTION: A water stopping method of the present invention comprises a base layer forming step of applying a resin adhesive around cracks 4 to form a base layer 141, a waterproof sheet installation step of providing a stretchable waterproof sheet 11 on the base layer 141 so as to cover the cracks 4, a fixing step of fixing the waterproof sheet 11 to the hollow concrete structure via the base layer 141 by a fixture 13, and a topcoat layer forming step of covering the fixture 13 and applying the resin adhesive so as to sandwich at least the peripheral edge of the waterproof sheet 11 with the base layer 141 to form a topcoat layer 142 integrated with the base layer 141.SELECTED DRAWING: Figure 4

Description

Water leakage along cracks to prevent water leakage from bent or distorted cracks that occur intermittently in the hollow concrete structure, or water leakage from cracks that are bent or curved so as to go around the hollow concrete structure. Regarding the construction method.

Patent Document 1 discloses a water stopping method for stopping water in the through gap K (existing joint) of the hollow concrete structure 100 by using a waterproof sheet 101 (see FIG. 13). In the water blocking method of Patent Document 1, after the base layer is formed by applying a resin adhesive around the through gap K, the waterproof sheet 101 is placed on the base layer to form the through gap K. It is said that it is covered with the waterproof sheet 101. Then, the protective film 102 is placed on the waterproof sheet 101, and the waterproof sheet 101 and the protective film 102 are fixed to the hollow concrete structure 100 by using a fixture. Then, by applying a resin adhesive so as to sandwich the peripheral edges of the waterproof sheet 101 and the protective film 102 and cover the fixture to form the topcoat layer, the resin fixing portion 103 composed of the topcoat layer and the base layer is formed. Will be done.

Further, conventionally, in order to prevent water leakage from cracks generated in a hollow concrete structure, an injection material such as urethane has been injected into the cracks. The injection material reacts with water that invades the cracks and foams.

Patent No. 5377715

By the way, in the water stopping method of Patent Document 1, the object of water stopping is extended in the circumferential direction of the hollow concrete structure 100 (the direction orthogonal to the longitudinal direction of the hollow concrete structure 100), and the hollow concrete structure 100 is set to 1. Although the penetrating gap K is set to go around, the cracks generated in the hollow concrete structure do not always go around once in the circumferential direction of the hollow concrete structure as described above, and are bent with respect to the circumferential direction. Alternatively, distorted cracks and intermittent cracks (cracks that do not go around the hollow concrete structure once) may occur.

In addition, in the conventional method of injecting the injection material into cracks, the injection material deteriorates over time (bubbles generated by foaming, hydrolysis, etc.), and the shape of the injection material changes due to changes in the shape of the cracks. It was not possible to prevent water leakage from cracks in the long term because the injection material did not follow and the adhesion was removed (the above-mentioned "change in the shape of cracks" caused shearing force to be applied to the hollow concrete structure during an earthquake. It is caused by the fact that the hollow concrete structure changes in temperature).

The present invention has been made to solve the above problems, and water leaks from bent or distorted cracks that occur around the hollow concrete structure, or intermittently occurs in the hollow concrete structure. It is an object of the present invention to provide a water stopping method capable of preventing water leakage from a bent or distorted crack in a long period of time.

In order to achieve the above object, the present invention includes the subjects described in the following sections.

Item 1. It is a water-stopping method along the cracks to prevent water leakage from the cracks that occur in the hollow concrete structure.
The crack is a bent or distorted crack that occurs intermittently in the hollow concrete structure, or a crack that is bent or curved so as to go around the hollow concrete structure.
The water-stopping method is
A step of forming a base layer around the cracks by applying a resin adhesive around the cracks on the inner surface of the hollow concrete structure, and a step of forming the base layer.
A waterproof sheet for installing a waterproof sheet along the cracks on the base layer so that the cracks are covered with a stretchable waterproof sheet and the peripheral edge of the base layer extends to the outside of the waterproof sheet. Installation steps and
A fixing step of fixing the tarpaulin to the hollow concrete structure via the base layer by a fixture, and
By applying a resin adhesive so as to cover the fixture and sandwich the peripheral edge of the waterproof sheet together with the base layer to form an integral topcoat layer with the base layer, the base layer and the base layer and A water stopping method along a crack including a topcoat layer forming step in which the waterproof sheet and the fixture are fixed in a resin portion having the topcoat layer.

Item 2. The crack is a bent or distorted crack that occurs intermittently in the hollow concrete structure.
In the base layer forming step, by applying the resin adhesive so as to surround the cracks, the annular base layer surrounding the cracks is formed.
In the topcoat layer forming step, by forming the annular topcoat layer integrated with the base layer, the cracks are surrounded by the base layer and the annular resin portion having the topcoat layer. Item 1. The water stopping method along the cracks according to Item 1.

Item 3. The crack is a crack that is bent or curved so as to go around the hollow concrete structure.
In the waterproof sheet installation step, a strip-shaped waterproof sheet is arranged along the inner wall of the hollow concrete structure so that the strip-shaped waterproof sheet goes around the inner circumference of the hollow concrete structure once and the strip-shaped waterproof sheet. Item 2. The water-stopping method according to item 1, wherein the cracks are covered with the waterproof sheet by connecting both ends of the waterproof sheet in the longitudinal direction by heat fusion or adhesion.

Item 4. The fixture includes a stainless bar extending along the peripheral edge of the tarpaulin and a plurality of fixing bolts installed at intervals in the extending direction of the stainless bar, and in the fixing step, the stainless bar is used. While holding the peripheral edge of the waterproof sheet, the stainless bar and the plurality of fixing bolts penetrating the waterproof sheet are screwed into the hollow concrete structure, so that the waterproof sheet passes through the base layer. Item 4. The method for stopping water along a crack according to any one of Items 1 to 3 fixed to a hollow concrete structure.

Item 5. After the waterproof sheet installation step, a protective film installation step of installing a protective film having less stretchability than the waterproof sheet on the waterproof sheet is further provided.
In the fixing step, the stainless bar, the protective film, and the plurality of fixing bolts penetrating the waterproof sheet are hollowed out while the peripheral portions of the waterproof sheet and the protective film are pressed by the stainless bar. By screwing into the concrete structure, the protective film and the tarpaulin waterproof sheet are fixed to the hollow concrete structure via the base layer, and in the topcoat layer forming step, the fixture is covered and the fixture is covered. Item 1 to 4, wherein the topcoat layer integrated with the base layer is formed by applying a resin adhesive so as to sandwich at least the peripheral edge of the waterproof sheet and the protective film with the base layer. A tarpaulin method along the cracks described in either.

Item 6. Item 8. The water-stopping method along the crack according to any one of Items 1 to 5, wherein the tarpaulin has a bent or curved shape that covers the crack.

Item 7. The waterproof sheet is a series of a plurality of sheet materials.
Each of the plurality of sheet materials is installed in a state where the orientation is adjusted so as to cover a part of the cracks, and the two sheet materials installed adjacent to each other are heat-sealed or bonded. The water stopping method along the crack according to any one of Items 1 to 6.

According to the water-stopping method and the water-stopping method according to the present invention, the bending or distorted cracks generated around the hollow concrete structure or the bending or distorted cracks intermittently generated in the hollow concrete structure are covered. , The tarpaulin is placed and fixed. Therefore, water leakage from the cracks can be prevented. Furthermore, since the waterproof sheet has stretchability, even if the shape of the cracks changes due to a temperature change of the hollow concrete structure or a shearing force applied to the hollow concrete structure due to an earthquake or the like, the waterproof sheet can be used. By stretching following the deformation of the crack, the waterproof sheet will continue to cover the crack. Therefore, the effect of preventing water leakage from the cracks can be maintained for a long period of time.

It is a perspective view which shows the state which applied the water-stopping method of this invention to the crack which was bent or distorted intermittently generated in the hollow concrete structure. It is a cross-sectional view of AA of the hollow concrete structure of FIG. It is a BB cross-sectional view of the hollow concrete structure of FIG. FIG. 5 is a cross-sectional view taken along the line CC of the hollow concrete structure of FIG. It is sectional drawing which shows the expanded state of the waterproof sheet provided in the waterproof structure of FIG. It is a perspective view which shows the procedure of the water stop method which concerns on embodiment of this invention. It is a perspective view which shows the procedure of the water stop method which concerns on embodiment of this invention. It is a perspective view which shows the procedure of the water stop method which concerns on embodiment of this invention. (A) and (b) are plan views which show the water-stopping structure which concerns on embodiment for bending or distorted crack which occurred intermittently in the inner wall of a hollow concrete structure. It is a perspective view which shows the state which applied the water-stopping method of this invention to the bending or distorted crack which occurred intermittently in the inner wall of a hollow concrete structure. It is a perspective view which shows the state which applied this invention to the crack which was bent or distorted generated so as to go around the inner wall of a hollow concrete structure. It is a perspective view which shows the state which applied this invention to the crack which was bent or distorted generated so as to go around the inner wall of a hollow concrete structure. It is a perspective view which shows the state which applied one Embodiment of the water-stopping structure which concerns on Patent Document 1 to the joint of the hollow concrete structure.

Hereinafter, embodiments of the water blocking method and the water stopping structure according to the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing a state in which the water blocking method of the present invention is applied along the bent or distorted cracks that occur intermittently in the hollow concrete structure. 2 is a cross-sectional view taken along the line AA of the hollow concrete structure of FIG. 1, FIG. 3 is a cross-sectional view taken along the line BB of the hollow concrete structure of FIG. It is a cross-sectional view of an object). FIG. 4 is a CC sectional view of the hollow concrete structure of FIG. 1 (FIG. 1 is a vertical sectional view of the hollow concrete structure).

The water-stopping method and the water-stopping structure according to the embodiment of the present invention are used to prevent "water leakage from bending or distorted cracks that occur intermittently in a hollow concrete structure". "Hollow concrete structure" means a hollow structure formed by using concrete and mainly buried underground.

The "bent or distorted cracks generated intermittently in the hollow concrete structure" are the bent or distorted cracks generated in the range where it is recognized that the "hollow concrete structure" has edges in the circumferential direction and the longitudinal direction. .. The main reasons for "intermittent bending or distorted cracks in hollow concrete structures" are cracks due to drying shrinkage of concrete, temperature changes, uneven settlement, earthquakes, poor construction, and the like.

The "hollow concrete structure 1" of the present embodiment shown in FIGS. 1 to 3 is a shield tunnel through which a communication cable, a gas pipe, or the like is passed, and a plurality of shield segments 5 to be combined and a secondary lining are used. A concrete 6 is provided, and a sealing material (not shown) is arranged at the seam 7 of the shield segment 5. The secondary lining concrete 6 is formed by installing concrete and steel steel plates cast inside the shield segment 5, and constitutes the inner wall of the hollow concrete structure 1 (shield tunnel).

The secondary lining concrete 6 constituting the inner wall of the hollow concrete structure 1 has the above-mentioned "intermittently generated bent or distorted cracks 4" to prevent high water pressure from leaking from the cracks 4. A water blocking structure 10 is provided for this purpose.

In the water leakage from the above-mentioned "crack 4", groundwater flows into the seam 7 of the shield segment 5, flows through the interface 8 between the shield segment 5 and the secondary lining concrete 6, and then flows into the crack 4. It flows out to the space inside the secondary lining concrete 6, and the above-mentioned "groundwater flowing into the seam 7" means that, for example, the sealing material (not shown) arranged at the seam 7 deteriorates over time. It happens by that.

The waterproof structure 10 for preventing water leakage includes a waterproof sheet 11 that covers the crack 4, a protective film 12 that covers the waterproof sheet 11, a fixture 13 that fixes the waterproof sheet 11 and the protective film 12, and a waterproof sheet 11. A resin portion 14 for fixing the protective film 12 and the fixture 13 is provided.

The waterproof sheet 11 is a stretchable sheet, and has a size that allows the peripheral portion to be fixed to the hollow concrete structure 1 after completely covering the cracks 4. As the waterproof sheet 11, for example, olefin-based elastomer, styrene-based elastomer, vinyl chloride-based elastomer, urethane-based elastomer, ethylenepropylene-based elastomer, butyl-based elastomer, butadiene-based elastomer, (acrylic) nitrile-based elastomer, isoprene-based elastomer, and chloroprene-based A waterproof sheet such as an elastomer can be used.

The protective film 12 is a net or sheet having less stretchability than the waterproof sheet 11. Specifically, as the protective film 12, a stainless net, vinylon sheet, polyester sheet, nylon sheet, carbon fiber sheet, aramid sheet, fiber reinforced sheet, metal sheet and the like can be used.

The fixture 13 includes a stainless bar (stainless steel bar) 131 extending along the periphery of the tarpaulin 11 and the protective film 12, and a plurality of fixing bolts 132 arranged at intervals in the extending direction of the stainless bar 131. The waterproof sheet 11 and the protective film 12 are fixed to the hollow concrete structure 1 by a plurality of fixing bolts 132 in a state where the peripheral edges of the waterproof sheet 11 and the protective film 12 are pressed by the stainless bar 131.

The resin portion 14 is composed of a base layer 141, a top coat layer 142 integrated with the base layer 141, and a weir filling portion 143, and is formed of a resin adhesive. The base layer 141 has an annular shape that surrounds the crack 4, and is interposed between the hollow concrete structure 1 and the waterproof sheet 11. The topcoat layer 142 also exhibits an annular shape, and is provided so as to cover the fixture 13 and to sandwich the peripheral portions of the waterproof sheet 11 and the protective film 12 together with the base layer 141. The filling portion 143 of the weir is formed by filling the recess 1a provided around the crack 4 of the hollow concrete structure 1 with a resin adhesive. Here, the base layer 141 is formed so as to spread in a direction away from the crack 4 from the filling portion 143 of the weir. By forming the base layer 141 in this way, the water flowing from the crack 4 between the hollow concrete structure 1 and the tarpaulin 11 is stopped by the filling portion 143 of the weir, and the hollow concrete structure 1 and the base layer 141 are stopped. Water does not get in between. As a result, it is possible to reliably prevent the base layer 141 from peeling off from the hollow concrete structure 1.

The base layer 141, the topcoat layer 142, and the filling portion 143 of the weir are all formed of the same resin adhesive. As described above, since the base layer 141, the topcoat layer 142, and the filling portion 143 of the weir are formed of the same resin adhesive, an interface cannot be formed in the resin portion 14, and the resin portion 14 is firmly integrated. .. Further, for example, a solvent-free epoxy resin or the like may be applied between the base layer 141 and the hollow concrete structure 1 to form a primer layer (not shown). When the primer layer is provided, the base layer 141 can be firmly fixed to the hollow concrete structure 1, and the adhesiveness between the resin portion 14 and the hollow concrete structure 1 can be improved.

According to the resin portion 14, at least the peripheral edge of the waterproof sheet 11 and the protective film 12 is sandwiched between the base layer 141 and the topcoat layer 142, and the fixture 13 is covered with the topcoat layer 142. Then, the waterproof sheet 11, the protective film 12, and the fixture 13 are integrally fixed in the resin portion 14. Further, since the base layer 141 is formed by directly applying the resin adhesive to the hollow concrete structure 1, the base layer 141 is fixed to the hollow concrete structure 1. As a result, the waterproof sheet 11 and the protective film 12 have a hollow concrete structure in the entire surface of the portion placed on the base layer 141 in addition to the portion fixed by the fixture 13, that is, the portion pressed by the stainless bar 131. Since it is fixed to the object 1, strong fixing can be obtained.

The waterproof structure 10 having the above characteristics is provided along the bent or distorted cracks 4 intermittently generated in the hollow concrete structure 1 (so that the above-mentioned "waterproof structure 10 is along the cracks 4". "Provided" means "installing the waterproof sheet 11 along the crack 4 so that the crack 4 is covered with the waterproof sheet 11"). At this time, the crack 4 can be filled with the filler 15 in advance. By filling the filler 15, water is prevented from entering the crack 4. Thereby, the water stopping effect can be improved. Further, since water is less likely to enter the cracks 4, the adhesive surface between the hollow concrete structure 1 and the resin portion 14 is wetted by groundwater during construction, which makes it difficult for the resin portion 14 to adhere to the hollow concrete structure 1. Can be prevented. As a result, the construction environment is greatly improved. As the filler 15, a general filler for filling joints and the like can be used, but it is particularly preferable to use an elastic epoxy resin. Since the elastic epoxy resin has excellent durability and flexibility, for example, even if the ground around the hollow concrete structure 1 moves in a different direction due to land subsidence or an earthquake, the elastic epoxy resin can be used. The flexibility allows the gaps in the cracks 4 to continue to be filled.

Next, a water-stopping method for providing the water-stopping structure 10 in the hollow concrete structure 1 will be described.

First, the filler 15 is filled in the crack 4 of the hollow concrete structure 1. After that, a recess 1a is provided around the crack 4 on the inner surface of the concrete structure 1. The recess 1a is filled with a resin adhesive to form a weir 143, and the resin adhesive is applied so as to surround the crack 4 on the inner surface of the hollow concrete structure 1, thereby forming a ring under the ring surrounding the crack 4. The stratum 141 is integrally formed with the weir 143 (FIG. 6 (a)). At this time, it is preferable to form the base layer 141 so as to spread away from the weir 143 in the direction away from the crack 4. Further, before forming the weir 143 and the base layer 141, for example, a solvent-free epoxy resin or the like can be applied to form a primer layer (not shown).

After forming the base layer 141, the waterproof sheet 11 is installed on the base layer 141 (FIG. 6 (b)). At this time, as shown in FIG. 6B, the waterproof sheet 11 is covered with the waterproof sheet 11 so that the peripheral portion 141a of the base layer 141 extends to the outside of the waterproof sheet 11. It is installed on the base layer 141.

Then, as shown in FIG. 7A, the protective film 12 having low stretchability is installed on the waterproof sheet 11 (in FIG. 7A, the waterproof sheet 11 is arranged under the protective film 12). The reference numeral 11 of the waterproof sheet is indicated by (). The same applies to FIGS. 7 (b), 8, 10, and 11 described later.) In the present embodiment, by arranging the waterproof sheet 11 under the protective film 12 as described above, the expansion of the waterproof sheet 11 caused by the water pressure of water entering the hollow concrete structure 1 from the ground (FIG. 5). (See) is suppressed by the protective film 12. ..

After the protective film 12 is installed, the waterproof sheet 11 and the protective film 12 are fixed to the hollow concrete structure 1 via the base layer 141 by the fixture 13 (FIGS. 7 (b), FIG. 7 (b), FIG. 8 (a)). Specifically, as shown in FIG. 7 (b), with the peripheral portions of the protective film 12 and the waterproof sheet 11 pressed by the stainless bar 131, the stainless bar 131 protects the stainless bar 131 as shown in FIG. 8 (a). A plurality of fixing bolts 132 penetrating the film 12 and the waterproof sheet 11 are screwed into the secondary lining concrete 6 of the hollow concrete structure 1. As a result, the waterproof sheet 11 and the protective film 12 are fixed to the hollow concrete structure 1 via the base layer 141.

After that, a resin adhesive is applied so as to cover the fixture 13 (stainless steel bar 131, a plurality of fixing bolts 132) and sandwich the peripheral portion of the waterproof sheet 11 and the protective film 12 together with the base layer 141 to apply the base layer. An annular topcoat layer 142 integrated with 141 is formed. As a result, the crack 4 is surrounded by the annular resin portion 14 having the base layer 141 and the topcoat layer 142, and the waterproof sheet 11, the protective film 12, and the fixture 13 are fixed in the resin portion 14. It is in a state (FIG. 8 (b)).

According to the waterproof construction method and the waterproof structure 10 of the present embodiment, the waterproof sheet 11 is arranged and fixed so as to cover the bent or distorted cracks 4 intermittently generated in the hollow concrete structure 1 ( That is, the waterproof sheet 11 is arranged and fixed along the intermittently bent or distorted cracks 4), and water leakage from the cracks 4 can be prevented. Further, since the waterproof sheet 11 has stretchability, even if the shape of the crack 4 changes due to a shearing force applied to the hollow concrete structure 1 at the time of an earthquake, a change in the temperature of the hollow concrete structure 1, or the like. As the waterproof sheet 11 stretches following the deformation of the crack 4, the waterproof sheet 11 continues to cover the crack 4. Therefore, the effect of preventing water leakage from the crack 4 can be maintained for a long period of time.

Further, according to the water-stopping method and the water-stopping structure 10 of the present embodiment, the annular resin portion 14 for fixing the waterproof sheet 1 surrounds the crack 4 so that water leakage from the crack 4 can be reliably prevented.

As shown in FIGS. 1 and 8B, when the resin portion 14 surrounding the crack 4 exhibits a rectangular annular shape extending in the extending direction of the crack 4, the end portion 14a of the resin portion 14 in the longitudinal direction is formed. , It may be formed by using an elastic adhesive (the above-mentioned "crack stretching direction" means the stretching direction of the "crack 4 opening" generated on the inner surface of the hollow concrete structure 1). By doing so, the flexibility of the end portion 14a in the longitudinal direction of the resin portion 14 can be imparted, so that the resin portion 14 can be deformed according to the width of the crack 4 (that is, the crack 4 can be deformed). When the width of the resin portion 14 is increased, the longitudinal end portion 14a of the resin portion 14 is lengthened, and when the width of the crack 4 is reduced, the longitudinal end portion 14a of the resin portion 14 is shortened. 14 can be made deformable).

Although one embodiment of the present invention has been described above, the present invention can be modified in various ways as long as it does not deviate from the gist thereof. For example, in the above embodiment, the waterproof structure 10 includes the waterproof sheet 11 and the protective film 12, but the protective film 12 may be omitted if sufficient water pressure resistance can be obtained only with the waterproof sheet 11. .. In this case, the fixture 13 is provided with a stainless bar 131 extending along the peripheral edge of the waterproof sheet 11 and a plurality of fixing bolts 132 installed at intervals in the extending direction of the stainless bar 131. Then, in the steps corresponding to FIGS. 7 (b) and 8 (a), a plurality of fixing bolts 132 that penetrate the stainless bar 131 and the waterproof sheet 11 while the peripheral edge of the waterproof sheet 11 is pressed by the stainless bar 131. Is screwed into the hollow concrete structure 1. As a result, the waterproof sheet 11 is fixed to the hollow concrete structure 1 via the base layer 141. Further, in the step corresponding to FIG. 8B, a resin adhesive is applied so as to cover the fixture 13 and sandwich at least the peripheral edge of the waterproof sheet 11 together with the base layer 141, thereby forming the base layer 141. An integral annular topcoat layer 142 is formed. As a result, the crack 4 is surrounded by the annular resin portion 14 having the base layer 141 and the topcoat layer 142, and the waterproof sheet 11 and the fixture 13 are fixed in the resin portion 14.

Further, in the above embodiment, the example in which the resin portion 14 is provided with the weir 143 is shown, but if the resin portion 14 can obtain sufficient adhesive force to the hollow concrete structure 1 without providing the weir 143, the weir 143 may be provided. It may be omitted.

Further, as shown in FIG. 9A, the waterproof sheet 11 may have a bent or distorted shape that covers the crack 4. In this way, even if cracks that bend or distort occur in a long range of the hollow concrete structure 1, the waterproof structure 10 can be formed along the cracks 4 (the tarpaulin 11 is installed along the cracks 4). The crack 4 can be covered with the waterproof sheet 11).

Further, as shown in FIG. 9B, the waterproof sheet 11 may be a series of a plurality of sheet materials 110. In this case, it is assumed that the orientations (angles) of the plurality of sheet materials 110 are adjusted so as to cover a part of the crack 4 respectively, and the two sheet materials 110 and 110 arranged adjacent to each other are arranged. It is heat fused or bonded. In this way, even if cracks 4 that bend or distort occur in a long range of the hollow concrete structure 1, a series of waterproof sheets 11 can be installed following the cracks 4.

Further, the cross-sectional shape of the hollow concrete structure 1 is not limited to the cross-sectional shape as shown in FIGS. 1 to 3, and the cross-sectional shape may be any various shapes such as a rectangle, a circle, an ellipse, and a horseshoe shape. ..

Further, in the above embodiment, an example in which the hollow concrete structure 1 is a shield tunnel is shown, but the hollow concrete structure 1 to which the water blocking method and the water blocking structure of the present invention can be applied is not limited to the shield tunnel. For example, it can be a mountain tunnel or an excavation tunnel.

FIG. 10 is a perspective view showing a state in which the water blocking structure 22 of the present invention is applied to the bent or distorted cracks 21 intermittently generated in the hollow concrete structure 20 having a rectangular cross section, which is an excavation tunnel. The water stop structure 22 shown in FIG. 10 also has the same structure as the water stop structure 10 shown in the above embodiment, and can be constructed by the same water stop method as the method shown in the above embodiment.

Further, as shown in FIG. 11, the water-stopping method and the water-stopping structure of the present invention are also applied to stop water from bent or distorted cracks 23 generated so as to make one round in the circumferential direction of the hollow concrete structure 20. Can be done. Hereinafter, the water stopping method implemented for constructing the water stopping structure 24 shown in FIG. 11 will be described. The configurations corresponding to those shown in the above embodiments are designated by the same reference numerals in the following description, and detailed description thereof will be omitted.

The waterproof structure 24 shown in FIG. 11 includes a base layer forming step of forming a base layer 141 around the crack 23 by applying a resin adhesive around the crack 23 on the inner surface of the hollow concrete structure 20, and a crack. A waterproof sheet installation step for installing the waterproof sheet 11 on the base layer 141 and a fixture 13 so that the waterproof sheet 23 is covered with the waterproof sheet 11 and the peripheral edge portion of the base layer 141 extends to the outside of the waterproof sheet 11. A fixing step of fixing the waterproof sheet 11 to the hollow concrete structure 20 via the base layer 141, and a resin adhesive so as to cover the fixture 13 and sandwich the peripheral edge of the waterproof sheet 11 together with the base layer 141. By applying and forming the topcoat layer 142 integrated with the base layer 141, the waterproof sheet 11 and the fixture 13 are fixed in the resin portion 14 having the base layer 141 and the topcoat layer 142. It is provided with a topcoat layer forming step.

According to the water-stopping structure 24 constructed by the above-mentioned water-stopping method, the waterproof sheet 11 is arranged and fixed so as to cover the bent or distorted cracks 23 generated so as to make one round in the circumferential direction of the hollow concrete structure 20. By doing so (that is, by arranging and fixing the waterproof sheet 11 along the crack 23), it is possible to prevent the leakage of high water pressure generated from the crack 23. Further, since the waterproof sheet 11 has stretchability, the shape of the crack 23 changes due to the application of shearing force to the hollow concrete structure 20 at the time of an earthquake, the change in the temperature of the hollow concrete structure 20, and the like. Further, as the waterproof sheet 11 stretches following the deformation of the crack 23, the waterproof sheet 11 continues to cover the crack 23. Therefore, the effect of preventing water leakage from the crack 23 can be maintained for a long period of time.

In the above-mentioned waterproof sheet installation step, for example, by arranging the strip-shaped waterproof sheet 11 along the inner surface of the hollow concrete structure 20, the strip-shaped waterproof sheet 11 goes around the inner circumference of the hollow concrete structure 20 once. The crack 23 is covered with the waterproof sheet 11 by connecting both ends of the strip-shaped waterproof sheet 11 in the longitudinal direction by heat fusion or adhesion in the extended state. The strip-shaped waterproof sheet 11 is, for example, a sheet material provided in a roll shape having a constant width, cut to a length corresponding to the size of the inner space of the hollow concrete structure 20. The above-mentioned "connecting both ends of the strip-shaped waterproof sheet 11 in the longitudinal direction by heat fusion or adhesion" is performed, for example, on the bottom slab 20a of the hollow concrete structure 20. If the waterproof sheet installation step is carried out by the above method, it is easy to adjust the length of the waterproof sheet 11 to "the length extending one round of the hollow concrete structure 20", so that the hollow concrete structure 20 is made one round. It can be easily realized that the crack 23 is covered with the waterproof sheet 11.

Alternatively, in the above-mentioned waterproof sheet installation step, the annular waterproof sheet 11 is arranged along the inner wall of the hollow concrete structure 20, and the annular waterproof sheet 11 goes around the inner circumference of the hollow concrete structure 20 once. By doing so, the crack 23 may be covered with the annular waterproof sheet 11.

Alternatively, as in the waterproof structure 25 shown in FIG. 12, the waterproof sheet 11 may be a series of a plurality of sheet materials 110. The orientation (angle) of each of the plurality of sheet materials 110 is adjusted so as to cover a part of the crack 23, and the two sheet materials 110 and 110 installed adjacent to each other are heat-sealed or bonded to each other. By repeating this, an annular waterproof sheet 11 that goes around the inner circumference of the hollow concrete structure 20 is formed, and the crack 23 is covered by the waterproof sheet 11. By doing so, it is possible to cover the crack 23 without preparing a long waterproof sheet (by preparing a plurality of sheet materials 110 having a relatively short length, the crack 23 can be covered. It will be possible).

Further, also in the water-stopping structures 24 and 25 shown in FIGS. 11 and 12, similarly to the water-stopping structure shown in the embodiment, the stainless bar 131 extending along the peripheral edge of the waterproof sheet and the extension of the stainless bar 131 are used as fixtures. Those provided with a plurality of fixing bolts 132 installed at intervals in the direction can be used. Further, similarly to the above embodiment, after the tarpaulin installation step, a protective film installation step of installing the protective film 12 having less stretchability than the tarpaulin 11 on the tarpaulin 11 may be carried out (FIG. 11). , In FIG. 12, since the waterproof sheet 11 is arranged under the protective film 12, reference numeral 11 of the waterproof sheet and reference numeral 110 of the sheet material are marked with ().

Further, in the waterproof structures 24 and 25 shown in FIGS. 11 and 12, the waterproof sheet 11 may have a bent or curved shape covering the crack 23.

1,20 hollow concrete structure,
4 Cracks 10, 22, 24, 25 Water-stop structure,
11 Tarpaulin,
12 Protective film,
13 Fixtures,
14 Resin part,
110 sheet material,
131 stainless bar,
132 fixing bolts,
141 Underlayer,
142 Topcoat layer

Claims (7)

It is a water-stopping method along the cracks to prevent water leakage from the cracks that occur in the hollow concrete structure.
The crack is a bent or distorted crack that occurs intermittently in the hollow concrete structure, or a crack that is bent or curved so as to go around the hollow concrete structure.
The water-stopping method is
A step of forming a base layer around the cracks by applying a resin adhesive around the cracks on the inner surface of the hollow concrete structure, and a step of forming the base layer.
A waterproof sheet for installing a waterproof sheet along the cracks on the base layer so that the cracks are covered with a stretchable waterproof sheet and the peripheral edge of the base layer extends to the outside of the waterproof sheet. Installation steps and
A fixing step of fixing the tarpaulin to the hollow concrete structure via the base layer by a fixture, and
By applying a resin adhesive so as to cover the fixture and sandwich the peripheral edge of the waterproof sheet together with the base layer to form an integral topcoat layer with the base layer, the base layer and the base layer and A water stopping method along a crack including a topcoat layer forming step in which the waterproof sheet and the fixture are fixed in a resin portion having the topcoat layer. The crack is a bent or distorted crack that occurs intermittently in the hollow concrete structure.
In the base layer forming step, by applying the resin adhesive so as to surround the cracks, the annular base layer surrounding the cracks is formed.
In the topcoat layer forming step, by forming the annular topcoat layer integrated with the base layer, the cracks are surrounded by the base layer and the annular resin portion having the topcoat layer. The water stopping method along the crack according to claim 1. The crack is a crack that is bent or curved so as to go around the hollow concrete structure.
In the waterproof sheet installation step, a strip-shaped waterproof sheet is arranged along the inner wall of the hollow concrete structure so that the strip-shaped waterproof sheet goes around the inner circumference of the hollow concrete structure once and the strip-shaped waterproof sheet. The water-stopping method according to claim 1, wherein the cracks are covered with the waterproof sheet by connecting both ends of the waterproof sheet in the longitudinal direction by heat fusion or adhesion. The fixture includes a stainless bar extending along the peripheral edge of the tarpaulin and a plurality of fixing bolts installed at intervals in the extending direction of the stainless bar, and in the fixing step, the stainless bar is used. While holding the peripheral edge of the waterproof sheet, the stainless bar and the plurality of fixing bolts penetrating the waterproof sheet are screwed into the hollow concrete structure, so that the waterproof sheet passes through the base layer. The water-stopping method along a crack according to any one of claims 1 to 3, which is fixed to a hollow concrete structure. After the waterproof sheet installation step, a protective film installation step of installing a protective film having less stretchability than the waterproof sheet on the waterproof sheet is further provided.
In the fixing step, the stainless bar, the protective film, and the plurality of fixing bolts penetrating the waterproof sheet are hollowed out while the peripheral portions of the waterproof sheet and the protective film are pressed by the stainless bar. By screwing into the concrete structure, the protective film and the tarpaulin waterproof sheet are fixed to the hollow concrete structure via the base layer, and in the topcoat layer forming step, the fixture is covered and the fixture is covered. Claims 1 to 4 form the topcoat layer integrated with the base layer by applying a resin adhesive so as to sandwich at least the peripheral edge of the waterproof sheet and the protective film with the base layer. The tarpaulin method along the cracks described in any of. The water-stopping method according to any one of claims 1 to 5, wherein the tarpaulin has a bent or curved shape that covers the cracks. The waterproof sheet is a series of a plurality of sheet materials.
The plurality of sheet materials are respectively adjusted in orientation so as to cover a part of the cracks, and the two sheet materials installed adjacent to each other are heat-sealed or bonded to each other according to claims 1 to 6. Water-stopping method along the cracks described in any of.

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