JP5277925B2 - Method for preventing fluidization inhibition of groundwater and structure for preventing inhibition of flow of mountain retaining wall constructed by the method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for inhibiting and preventing a flow which enables inexpensive and safe construction. <P>SOLUTION: Round steel pipes 9 are embedded at spaces in a wall-surface direction in a soil cement column wall 1. A tubular filter material 24 is installed in the round steel pipe 9 in such a manner as to come into contact with an inner peripheral surface of the round steel pipe 9. A plurality of slits 6 are formed in the round steel pipe 9 and a depth portion corresponding to an aquifer 4 of the soil cement column wall 1, respectively. Groundwater in the ground is collected into the upstream-side round steel pipe 9 through the slits 6, and the groundwater in the round steel pipe 9 is discharged into the downstream-side ground through the slits 6. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a method for preventing flow inhibition of groundwater in a ground where a retaining wall is constructed, and a flow inhibition preventing structure constructed by the method.

  When constructing an underground structure by the open-cut method or the like, a water-proof mountain retaining wall is formed in the ground to prevent infiltration of groundwater into the work area. However, by forming a retaining wall, the flow of groundwater in the ground is obstructed, so that groundwater does not flow downstream of the retaining wall, and the water level of the well on the downstream side decreases or ground subsidence occurs. was there.

  Therefore, for example, in Patent Document 1, a crushed stone layer is provided around a well provided in an upstream retaining wall, and groundwater collected in the well through the crushed stone layer is surrounded by the retaining wall. A method of diffusing into the ground from a crushed stone layer around a well provided on the downstream side as well as on the upstream side through a water conduit laid on the bottom of the excavated space is disclosed.

Further, in Patent Document 2, a vertical working hole is formed at a desired interval on the mountain retaining wall made of soil cement at or after the construction, and an impact transmission material such as water is injected into the working hole. At the same time, a probe for supplying electric power for generating plasma is inserted, and electric power is supplied to this to generate a shock wave by the plasma to crush the impermeable mountain retaining wall, and the groundwater is taken downstream through the gap generated by this crushing. A method of running water to the side is disclosed.
JP 2000-186336 A JP 2004-124575 A

  However, in the method described in Patent Document 1, since the crushed stone layer is provided around the plurality of wells provided in the retaining wall, there is a problem that the construction work takes time and the construction cost is increased.

  Further, the method described in Patent Document 2 has a problem that the equipment investment cost is high because the apparatus for generating plasma power is expensive. In addition, there is a problem that electric leakage may occur in the vicinity when it rains.

  Then, this invention is made | formed in view of the above conventional problems, Comprising: It aims at providing the flow inhibition prevention method which can be constructed | assembled cheaply and safely.

In order to achieve the above object, the groundwater flow inhibition preventing method of the present invention is constructed to a depth deeper than the aquifer in the ground, and a pipe reaching a depth deeper than the aquifer is upstream of the groundwater flow. In the method for preventing groundwater flow inhibition in soil retaining walls made of soil cement , embedded in the side and downstream sides, respectively, a soil cement removing step for removing the soil cement in the pipe, and high-pressure water in the pipe from which the soil cement has been removed. An opening step for forming a through hole penetrating from the inside of the pipe to the aquifer by inserting a jettable crusher and injecting the high-pressure water at the position of the aquifer; A water supply means for supplying groundwater collected in the pipe on the upstream side to the pipe on the downstream side is formed by excavating the inner ground surrounded by the retaining wall. Space, characterized in that it comprises a water supply means mounting step of placing the bottom plate at a depth of impermeable layer beneath the aquifer.

  According to the groundwater flow prevention method according to the present invention, a crusher capable of injecting high-pressure water is inserted into a pipe, and through-holes penetrating to the aquifer by injecting high-pressure water from the crusher are formed. The groundwater can be collected into the pipe through this through hole, or the groundwater in the pipe can be discharged to the aquifer. Moreover, since the high pressure water is jetted in the pipe, the through hole can be formed safely in the retaining wall and the pipe. Furthermore, since the apparatus for producing high-pressure water is a general one, is readily available, and is inexpensive, the capital investment cost can be reduced.

  And all the upstream groundwater can be sent downstream by installing the water supply means for sending the groundwater collected in the upstream pipe to the downstream pipe.

  In the present invention, the pipe has an opening at the position of the aquifer, and in the opening step, a through hole penetrating the mountain retaining wall is formed through the opening. A through hole can be easily formed in the wall.

  Further, in the present invention, if the crusher is moved in the pipe with the inner peripheral surface of the pipe as a guide, the crusher moves up and down and in the circumferential direction with the inner peripheral surface of the pipe as a guide. Therefore, the position and size of the through hole can be formed with high accuracy.

  Further, in the present invention, if the through-hole is formed in a size that makes it difficult for the earth and sand to flow according to the particle size of the earth and sand in the aquifer, the earth and sand in the aquifer is almost in the through-hole. Does not flow. Therefore, the through hole is not easily clogged.

  In the present invention, if the through hole is formed in a slit shape, the tube is not crushed by earth pressure.

  Further, in the present invention, if it is further provided with a filter installation step of installing a filter material capable of passing groundwater in the pipe, the soil in the aquifer is captured by this filter material, so only the groundwater is contained in the pipe. Can be introduced.

  In the present invention, if the water supply means is a water supply pipe having one end connected to the upstream pipe and the other end connected to the downstream pipe, All groundwater in the pipe can be sent to the pipe on the downstream side.

  Furthermore, in the present invention, if the water supply means is a water flow layer formed by laying stone or sand on the bottom plate so as to have a predetermined thickness, water flow made of stone or sand is used. Since the layer is laid on the bottom plate, a large amount of upstream groundwater can be sent downstream.

In addition, the flow blocking prevention structure of the retaining wall of the present invention is constructed to a depth deeper than the aquifer in the ground, and the pipe reaching the depth deeper than the aquifer is upstream and downstream with respect to the flow of groundwater In the soil retaining wall made of soil cement embedded in each, the soil cement in the pipe has been removed, and a crusher capable of injecting high-pressure water is inserted into the pipe, Formed by excavating a through-hole formed so as to penetrate from the inside of the pipe to the aquifer by injecting the high-pressure water at the position of the aquifer and an inner ground surrounded by the retaining wall A water supply means for supplying groundwater collected in the pipe on the upstream side through the through-hole to the pipe on the downstream side, installed in the bottom plate at a depth of the impermeable layer below the aquifer in the formed space With And wherein the door.

  According to the flow blocking prevention structure of the retaining wall according to the present invention, a crusher capable of injecting high-pressure water is inserted into the pipe, and the high-pressure water is injected from the crusher to penetrate to the aquifer. Since the hole is provided, the groundwater can be collected into the pipe through the through hole, or the groundwater in the pipe can be discharged to the aquifer. Moreover, since the high pressure water is jetted in the pipe, the through hole can be formed safely in the retaining wall and the pipe. Furthermore, since the apparatus for producing high-pressure water is a general one, is readily available, and is inexpensive, the capital investment cost can be reduced.

  And it is installed on the bottom of the space formed by excavating the inner ground surrounded by the retaining wall, and has water supply means for supplying the groundwater collected in the upstream pipe through the through hole to the downstream pipe As a result, all of the upstream groundwater can be sent downstream.

  By using the flow inhibition preventing method of the present invention, the groundwater blocked by the retaining wall can be flowed downstream at a low cost.

  Hereinafter, preferred embodiments of the flow inhibition preventing method of the present invention will be described in detail with reference to the drawings. In addition, although the following embodiment demonstrates the case where the soil cement pillar row wall which is a mountain retaining wall is installed in a natural ground, this invention is applicable also to mountain retaining walls, such as RC, in general.

  FIG. 1 is a perspective sectional view showing a soil cement column wall 1 according to a first embodiment of the present invention. 2 is a view taken in the direction of arrow A in FIG. 1, and FIG. 3 is a cross-sectional view taken along line BB in FIG.

As shown in FIGS. 1 to 3, the soil cement column wall 1 is constructed so as to penetrate the impermeable layer 3 and the aquifer 4 near the ground surface and reach the impermeable layer 5.
Round steel pipes 9 are embedded in the soil cement column wall 1 at intervals in the wall surface direction. The round steel pipe 9 is buried deeper than the aquifer 4 and slightly deeper than the bottom of the space 2 formed by excavating the ground surrounded by the soil cement column wall 1.
A cylindrical filter member 24 is installed in the round steel pipe 9 so as to be in contact with the inner peripheral surface of the round steel pipe 9.

  A plurality of slits 6 are formed in a depth portion corresponding to the aquifer 4 of the round steel pipe 9 and the soil cement column wall 1. Ground water in the ground is collected in the upstream round steel pipe 9 through the slit 6 and the filter material 24, and ground water in the round steel pipe 9 is collected in the downstream ground through the filter material 24 and the slit 6. Released.

  Further, below the bottom plate of the space 2, a water supply means 7 for supplying the groundwater collected in the upstream round steel pipe 9 to the downstream round steel pipe 9 is installed. In the present embodiment, the water supply means 7 uses a water pipe having one end connected to the lower end of the upstream round steel pipe 9 and the other end connected to the lower end of the downstream round steel pipe 9.

Therefore, the groundwater in the aquifer 4 located on the upstream side of the soil cement column wall 1 passes through the slit 6 and the filter material 24 formed on the upstream side of the round steel pipe 9 and enters the round steel pipe 9. Then, the water passes through the water pipe 7 and is led to the downstream round steel pipe 9, passes through the filter material 24 and the slit 6 formed on the downstream side of the round steel pipe 9, and passes through the soil. It flows out into the aquifer 4 located on the downstream side of the cement column wall 1a.
In addition, the installation number etc. of the water flow pipe 7 and the round steel pipe 9 are determined by design etc., and differ with each field.

Next, the construction method of the groundwater fluidization inhibition preventing structure 12 according to the present embodiment will be described.
4-8 is a figure which shows the construction | assembly procedure of the fluidization inhibition prevention structure 12 of the groundwater which concerns on this embodiment.

First, as shown in FIG. 4, cement milk is filled in a column-arranged excavation hole formed by a single-axis or multi-axis earth auger, and a soil cement column wall 1 having soil as an aggregate in the soil is formed. To construct.
The lower end of the soil cement column wall 1 is constructed so as to penetrate the impermeable layer 3 and the aquifer layer 4 and reach a predetermined depth in the impermeable layer 5.

  Next, the round steel pipe 9 is installed at a predetermined position of the soil cement column wall 1 with the crane 8 installed on the ground. The round steel pipe 9 is installed until the lower end of the round steel pipe 9 reaches a depth slightly deeper than the lower end depth of the space 2. Moreover, the round steel pipe 9 is built only in the soil cement pillar 1a where the slit 6 is to be formed.

  Next, the H-shaped steel 10 is built in the soil cement pillar 1b adjacent to the soil cement pillar 1a in which the round steel pipe 9 is built. The H-shaped steel 10 is built until the lower end of the H-shaped steel 10 reaches a slightly shallower depth than the lower end of the soil cement column wall 1.

  Next, as shown in FIG. 5, after the soil cement is hardened, the soil cement in the round steel pipe 9 is crushed and removed by the excavator 11. After the soil cement is removed by the excavator 11, the inside of the round steel pipe 9 is further cleaned so that the soil cement does not remain on the inner peripheral surface of the round steel pipe 9.

Next, as shown in FIG. 6, a water flow pipe 7 is laid on the bottom plate of the space 2, one end being the lower end of the upstream round steel pipe 9 and the other end being the lower end of the downstream round steel pipe 9. To the cable by welding. When connecting both ends of the water flow pipe 7 to the round steel pipe 9, the soil cement column which becomes a connecting portion in advance so that the end of the water flow pipe 7 can be inserted into the soil cement pillar 1 a and the round steel pipe 9. A part of the side surface of 1a and the round steel pipe 9 is opened. In the present embodiment, the water pipe 7 is a round steel pipe having a diameter similar to that of the round steel pipe 9.
After the water pipe 7 is installed, the backfill material 23 is laid so as to cover the periphery of the water pipe 7.

Next, as shown in FIG. 7, a crusher 22 capable of injecting high-pressure water is inserted into the round steel pipe 9 from which the soil cement has been removed, and the round steel pipe 9 and the soil cement having a depth corresponding to the aquifer 4 are inserted. High pressure water is sprayed onto the columnar wall 1a to form a slit 6 that is long in the vertical direction.
The crusher 22 includes a nozzle 14 that can inject high-pressure water, a water supply unit 18 that supplies high-pressure water to the nozzle 14, and an abrasive supply unit 13 that supplies an abrasive to the nozzle 14.

The water supply means 18 includes a water tank 19 for storing water, and a press-fitting pump 20 for pressure-feeding the water in the water tank 19 to the nozzle 14 via the feed pipe 21.
The abrasive material supply means 13 includes an abrasive material tank 16 for storing the abrasive material, and an air compressor 15 for pressure-feeding the abrasive material in the abrasive material tank 16 to the nozzle 14 via the supply pipe 17. It is configured.

  Next, a method of forming the slit 6 in the round steel pipe 9 and the soil cement column wall 1a having a depth corresponding to the aquifer 4 will be described.

  First, the nozzle 14 inserted to the vicinity of the lower end depth of the aquifer 4 in the round steel pipe 9 is pulled up to the ground side at a constant speed, and the high-pressure water is moved toward the ground side at a predetermined time interval for a predetermined time. A plurality of slits 6 penetrating through the round steel pipe 9 and the soil cement column wall 1a are formed by spraying only. The high-pressure water is jetted from the round steel pipe 9 toward the ground side, and the slit 6 is formed only on the ground side.

In this embodiment, since the slit 6 penetrating the round steel pipe 9 and the soil cement column wall 1a is formed, the injection pressure of the high-pressure water is, for example, 2000 kg / cm ² , but is limited to this value. Instead, it is appropriately determined depending on the thickness of the round steel pipe 9 and the thickness of the soil cement column wall 1a.

Next, as shown in FIG. 8, when the nozzle 14 reaches the vicinity of the upper end depth of the aquifer 4, the nozzle 14 is rotated by a predetermined angle (for example, 15 °) in the circumferential direction of the round steel pipe 9. Thereafter, while lowering the nozzle 14 toward the bottom of the round steel pipe 9 at a constant speed, a plurality of slits 6 are formed by injecting high-pressure water at a predetermined time interval for a predetermined time as in the case of pulling up. .
When the nozzle 14 reaches the vicinity of the lower end depth of the aquifer 4, the nozzle 14 is rotated by the above-mentioned angle, and the high-pressure water is jetted again at a constant speed to form the slit 6. .

  As described above, the round steel pipe 9 and the soil cement column are rotated by a predetermined angle in the circumferential direction of the round steel pipe 9 while moving the nozzle 14 up and down within the depth portion corresponding to the aquifer 4. The operation of forming the slit 6 in the wall 1a is repeated until the opening ratio of the slit 6 determined by design or the like is reached based on the flow rate of groundwater obtained in advance by geological survey or the like.

Further, the width of the slit 6 is appropriately determined based on the design and the like at the same time when the opening ratio is determined to a size that makes it difficult for the sediment to flow in accordance with the particle size of the sediment in the aquifer 4. The width of the slit 6 is adjusted by the degree of opening and closing of the nozzle 14.
Further, the slit 6 is formed on all of the upstream round steel pipe 9 and the downstream round steel pipe 9 determined by design or the like.

And by providing the several slit 6 in the depth part corresponded to the aquifer 4, the groundwater in the aquifer 4 located in the upstream of the soil cement column wall 1 is the upstream of the round steel pipe 9 In the round steel pipe 9 and the slit 6 in the soil cement column wall 1a, the gas flows into the round steel pipe 9, and then passes through the water pipe 7 to be downstream of the round steel pipe. 9 passes through the slit 6 in the round steel pipe 9 and the soil cement column wall 1a formed on the downstream side of the round steel pipe 9 and is located on the downstream side of the soil cement column wall 1 Is released into the aquifer 4.
Finally, the cylindrical filter member 24 is installed so that the outer peripheral surface thereof is in contact with the inner peripheral surface of the round steel pipe 9.

  According to the flow inhibition preventing method in the present embodiment described above, high-pressure water is injected into the round steel pipe 9 and the soil cement column wall 1a at the depth corresponding to the aquifer 4 to penetrate to the aquifer 4. By forming the slit 6, ground water can be collected into the round steel pipe 9 through the slit 6, or the ground water in the round steel pipe 9 can be discharged to the aquifer 4.

  Further, by using the upstream round steel pipe 9 and the water flow pipe 7 connected to the downstream round steel pipe 9, the groundwater collected on the upstream side can be reliably sent downstream.

  Furthermore, since the high-pressure water is jetted in the round steel pipe 9, the slit 6 can be safely formed in the round steel pipe 9 and the soil cement column wall 1a. In addition, the width of the slit 6 is opened to a size that makes it difficult for the earth and sand to flow according to the particle size of the earth and sand of the aquifer 4, and the earth and sand in the aquifer 4 hardly flows into the slit 6. The slit 6 is not easily clogged. And since the crusher 22 and the water supply means 18 used for preparation of the slit 6 are general things, they are highly available and inexpensive, they can reduce capital investment cost. And since the filter material 24 is installed in the round steel pipe 9, even if earth and sand pass the slit 6, it is captured by the filter material 24.

  In addition, in this embodiment, after connecting the water flow pipe 7 to the round steel pipe 9, although the procedure which inserts the crusher 22 in the round steel pipe 9 and forms the slit 6 was demonstrated, it is limited to this. It is good also as connecting the water flow pipe 7 to the round steel pipe 9 after forming the slit 6 instead of a thing.

  Next, another embodiment of the present invention will be described. In the following description, portions corresponding to the above-described embodiment are denoted by the same reference numerals, description thereof is omitted, and differences are mainly described.

FIG. 9 is a perspective view showing a soil cement column wall 31 according to the second embodiment of the present invention. FIG. 10 is a cross-sectional view taken along the line CC of FIG.
As shown in FIGS. 9 and 10, round steel pipes 32 having a diameter smaller than that of the round steel pipe 9 used in the first embodiment are embedded in the soil cement column wall 31 at intervals in the wall surface direction. Yes.

  A plurality of slits 33 a and 33 b are formed in depth portions corresponding to the aquifer 4 of the round steel pipe 32 and the soil cement column wall 31. The groundwater in the aquifer 4 is collected in the upstream round steel pipe 32 through the slits 33a and 33b, and the groundwater in the round steel pipe 32 is grounded in the downstream ground through the slits 33a and 33b. Released to layer 4.

  Further, below the bottom plate of the space 2, a water supply means 34 for supplying the groundwater collected in the upstream round steel pipe 32 to the downstream round steel pipe 32 is installed. In the present embodiment, the water supply means 34 is a water flow layer formed by laying earth and sand or crushed stone so as to have a predetermined thickness.

  A plurality of slits 33 c and 33 d are formed in depth portions corresponding to the water-permeable layer 34 of the round steel pipe 32 and the soil cement column wall 31. The groundwater in the round steel pipe 32 flows into the upstream portion of the water flow layer 34 through the slits 33c and 33d, and the groundwater is fed from the downstream portion of the water flow layer 34 into the round steel pipe 32 through the slits 33c and 33d. The

  In order to prevent the groundwater in the water flow layer 34 from flowing out to the outside, the water flow layer 34 is covered with a water shielding sheet 35 on the outer periphery, except for the connecting portion with the round steel pipe 32. Furthermore, after installing the water shielding sheet 35, the backfill material 23 is laid so as to cover the water shielding sheet 35.

Next, the construction method of the fluidization inhibition preventing structure 30 according to the present embodiment will be described.
FIGS. 11-17 is a figure which shows the construction procedure of the fluidization inhibition prevention structure 30 of the groundwater based on this embodiment.

  First, as shown in FIG. 11, the round steel pipe 32 is installed at a predetermined position of the soil cement column wall 31 with the crane 8. The round steel pipe 32 is smaller in diameter than the round steel pipe 9 described above, and a plurality of slits 33 a and 33 c are provided in advance in depth portions corresponding to the aquifer layer 4 and the water flow layer 34.

  As in the first embodiment, the round steel pipe 32 is built only on the soil cement column 31a where the water-permeable layer 34 is to be formed, and as shown in FIG. 12, the round steel pipe 32 is built. The H-shaped steel 10 is built in the soil cement column 31b adjacent to the soil cement column 31a. Then, the soil cement in the round steel pipe 32 is crushed and removed by the excavator 11 (not shown).

Next, as shown in FIG. 13, a bag-shaped water shielding sheet 35 is laid on the bottom plate of the space 2. Then, the water-permeable layer 34 is constructed by filling the water-impervious sheet 35 with earth and sand or crushed stone until a predetermined thickness is reached. The thickness of the water flow layer 34 is determined for each site depending on the flow rate of groundwater and the like.
In the present embodiment, the case where earth and sand or crushed stone is used has been described. However, the present invention is not limited to this, and spherical plastic or the like may be used.
Then, after laying the backfill material 23 so as to cover the water-impervious sheet 35, concrete or the like serving as the foundation of the structure is placed (not shown).

  Next, a method for forming the slits 33b and 33d in the soil cement column wall 31a will be described. First, a description will be given in the order in which the slit 33d is created at a position corresponding to the water-permeable layer 34, and then the slit 33b is created at a position corresponding to the aquifer 4.

First, as shown in FIG. 14, the nozzle 14 of the crusher 22 is inserted into the round steel pipe 32 from which the soil cement has been removed to the vicinity of the lower end depth of the water layer 34, and the nozzle 14 is inserted into the slit 33 c of the round steel pipe 32. The high-pressure water is sprayed to the soil cement column wall 31a through the slit 33c while being pulled up to the ground side so as to pass along the portion of the soil cement column wall 31a corresponding to the position where the slit 33c is provided. A plurality of slits 33d are formed. In the present embodiment, slits 33a and 33c are provided in advance in depth portions corresponding to the aquifer 4 and the water flow layer 34 of the round steel pipe 32, so that only the soil cement column wall 31c is penetrated. For example, the injection pressure of the high-pressure water is set to 500 kg / cm ² , but is not limited to this value, depending on the thickness of the soil cement column wall 31a. It is determined appropriately. In addition, since it is only necessary to penetrate the soil cement column wall 31c, it is not necessary to mix the abrasive with the high-pressure water.

  Next, as shown in FIG. 15, when the nozzle 14 reaches the vicinity of the upper end depth of the water flow layer 34, the nozzle 14 is rotated by a predetermined angle to the position of the adjacent slit 33c. Thereafter, while descending to the bottom of the round steel pipe 32 along the slit 33c, a plurality of slits 33d are formed by spraying high-pressure water onto the soil cement column wall 31a through the slits 33c in the same manner as when pulling up. Form.

  Then, when the nozzle 14 reaches the vicinity of the lower end depth of the water-permeable layer 34, the nozzle 14 is rotated by the above-mentioned angle, and the high-pressure water is jetted again to form the slit 33d while pulling up to the ground side again.

  As described above, the nozzle 14 is moved up and down within the range of the depth portion corresponding to the water-permeable layer 34 and is rotated by a predetermined angle in the circumferential direction of the round steel pipe 32 so that the high-pressure water is soiled through the slit 33c. The operation of spraying the cement column wall 31a to form the slit 33d is repeated.

  After creating the slit 33d at a position corresponding to the water flow layer 34, next, as shown in FIG. 16, the nozzle 14 of the crusher 22 is pulled up to the vicinity of the lower end depth of the aquifer 4, and this nozzle 14 is moved to the round steel pipe. The high-pressure water is sprayed to the soil cement column wall 31a through the slit 33a while being pulled up to the ground side along the 32 slits 33a, and the portion of the soil cement column corresponding to the position where the slit 33a is provided A plurality of slits 33b penetrating the wall 31a are formed.

  Next, as shown in FIG. 17, when the nozzle 14 reaches the vicinity of the upper end depth of the aquifer 4, the nozzle 14 is rotated by a predetermined angle to the position of the adjacent slit 33a. Thereafter, while descending to the bottom of the round steel pipe 32 along the slit 33a, a plurality of slits 33b are formed by injecting high-pressure water onto the soil cement column wall 31a through the slits 33a in the same manner as when pulling up. Form.

  When the nozzle 14 reaches the vicinity of the lower end depth of the aquifer 4, the nozzle 14 is rotated by the above angle, and the high pressure water is jetted again to form the slit 33 b while being pulled up to the ground side again.

  As described above, the nozzle 14 is moved up and down within the range of the depth corresponding to the aquifer 4 and rotated at a predetermined angle in the circumferential direction of the round steel pipe 32 so that the high-pressure water is soiled through the slit 33a. The operation of spraying the cement column wall 31a to form the slit 33b is repeated.

  Finally, the cylindrical filter member 24 is installed so that the outer peripheral surface thereof is in contact with the inner peripheral surface of the round steel pipe 9.

  By providing a plurality of slits 33a, 33b in the depth portion corresponding to the aquifer 4 and providing a plurality of slits 33c, 33d in the depth portion corresponding to the water flow layer 34, the soil cement column wall 1 The groundwater in the aquifer 4 located on the upstream side passes through the slits 33a and 33b and the filter material 24 formed on the upstream side of the round steel pipe 32 and flows into the round steel pipe 32. The steel pipe 32 passes through the slits 33 c and 33 d formed on the downstream side at the lower end portion of the steel pipe 32 and the filter material 24 and flows into the water flow layer 34.

  Then, the groundwater passes through the water-passing layer 34, passes through the slits 33 c and 33 d formed at the lower end of the downstream round steel pipe 32, and the filter material 24, and then flows into the round steel pipe 32. Then, it passes through the slits 33 a and 33 b formed on the downstream side at the upper end portion of the round steel pipe 9 and the filter material 24 and is discharged into the aquifer 4.

  According to the flow inhibition preventing method in the present embodiment described above, the slit 33b penetrating to the aquifer 4 is formed by injecting high-pressure water onto the soil cement column wall 31a at the depth corresponding to the aquifer 4. Thus, groundwater can be collected into the round steel pipe 32 through the slit 33b, or the groundwater in the round steel pipe 32 can be discharged to the aquifer 4. Further, by forming a slit 33d penetrating to the water-permeable layer 34 by injecting high-pressure water into the soil cement column wall 31a at a depth corresponding to the water-permeable layer 34, the groundwater is passed through the slit 33d. Water can be fed into the layer 34, or groundwater in the water flow layer 34 can be fed to the round steel pipe 32.

  Further, the round steel pipe 32 is provided with slits 33a and 33c in advance, and the slits 33b and 33d are formed only in the soil cement column wall 31a, so that the discharge pressure of the high-pressure water is made lower than that in the first embodiment. be able to. Therefore, a small water supply means 18 can be used.

  Since the round steel pipe 32 has only to have a diameter that allows the nozzle 14 to be inserted, a steel pipe having a small diameter can be used. In addition, since the steel pipe having a small diameter is inexpensive, the material cost can be reduced.

  Further, the groundwater collected in the upstream round steel pipe 32 is formed with a water flow layer 34 for sending the groundwater to the downstream round steel pipe 32, so that the collected groundwater can be reliably sent downstream. can do.

  In addition, in this embodiment, after forming the water flow layer 34, although the procedure which inserts the crusher 22 in the round steel pipe 32 and forms the slits 33b and 33d was demonstrated, it is not limited to this. Alternatively, the slits 33b and 33d may be formed and then applied in the order in which the water-permeable layer 34 is formed.

  Moreover, in each embodiment mentioned above, although the case where the slits 6 and 33a-33d were formed in the vertical direction was demonstrated, it is not limited to this, As shown in FIG.18 and FIG.19, as shown to FIG. You may form the slit 41 and the slit 51 of the diagonal direction. The shapes of the slits 6, 33a to 33d, 41, 51 may be round or square, and the shape is not limited.

  And in each embodiment mentioned above, although the case where round steel pipes 9 and 32 were used as a pipe buried in soil cement column wall 1 and 31, material was not limited to steel materials, A tube made of polyvinyl chloride or plastic may be used.

  Furthermore, in each embodiment mentioned above, although the case where the round steel pipes 9 and 32 were used as a pipe embed | buried in the soil cement column wall 1 and 31 was demonstrated, a shape is not limited to a round shape. A polygonal tube such as a square may be used.

It is a perspective view which shows the soil cement pillar row wall which concerns on 1st embodiment of this invention. It is A arrow directional view of FIG. It is BB sectional drawing of FIG. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a perspective view which shows the soil cement column wall which concerns on 2nd embodiment of this invention. It is CC sectional drawing of FIG. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the construction procedure of the fluidization inhibition prevention structure which concerns on this embodiment. It is a figure which shows the other shape of a slit. It is a figure which shows the other shape of a slit.

Explanation of symbols

1 soil cement column wall 1a, 1b soil cement column 2 space 3 impermeable layer 4 aquifer layer 5 impermeable layer 6 slit 7 water supply means (= water pipe)
DESCRIPTION OF SYMBOLS 8 Crane 9 Round type steel pipe 10 H type steel 11 Excavator 12 Prevention of fluidization inhibition of groundwater 13 Abrasive material supply means 14 Nozzle 15 Air compressor 16 Abrasive material tank 17 Feed pipe 18 Water supply means 19 Water tank 20 Press-fit pump 21 Feed pipe 22 Crusher 23 Backfill material 24 Filter material 30 Groundwater fluidization inhibition prevention structure 31 Soil cement column wall 31a, 31b Soil cement column 32 Round steel pipe 33a, 33b, 33c, 33d Slit 34 Water supply means ( = Water-permeable layer) 35 Water-impervious sheet 41, 51 Slit

Claims (9)

Groundwater in a soil-cemented mountain retaining wall constructed to a depth deeper than the aquifer in the ground, and pipes reaching deeper than the aquifer embedded in the upstream and downstream sides of the groundwater flow, respectively In the flow inhibition prevention method of
A soil cement removing step of removing the soil cement in the pipe;
Inserting a crusher capable of injecting high-pressure water into the pipe from which the soil cement has been removed, and injecting the high-pressure water at the position of the aquifer, penetrates from the inside of the pipe to the aquifer An opening step for forming a hole;
A water supply means for supplying groundwater collected in the pipe on the upstream side through the through-hole to the pipe on the downstream side, in a space formed by excavating the inner ground surrounded by the retaining wall , A method for preventing the inhibition of groundwater flow, comprising: a water supply means installation step of installing a bottom plate at a depth of an impermeable layer below the aquifer .   2. The groundwater according to claim 1, wherein the pipe has an opening at the position of the aquifer, and in the opening step, a through-hole penetrating the mountain retaining wall is formed through the opening. Flow inhibition prevention method.   The method for preventing the inhibition of groundwater flow according to claim 1 or 2, wherein the crusher is moved in the pipe using the inner peripheral surface of the pipe as a guide.   The flow inhibition of groundwater according to any one of claims 1 to 3, wherein the through hole is formed in a size that makes it difficult for sediment to flow in according to the particle size of the sediment in the aquifer. Prevention method.   The method for preventing the flow of groundwater according to any one of claims 1 to 4, wherein the through hole is formed in a slit shape.   The method for preventing inhibition of groundwater flow according to claim 1, further comprising a filter installation step of installing a filter material capable of passing groundwater into the pipe.   The method for preventing fluidization of groundwater according to claim 1, wherein the water supply means is a water supply pipe having one end connected to the upstream pipe and the other end connected to the downstream pipe. .   The method for preventing fluidization of groundwater according to claim 1, wherein the water supply means is a water-permeable layer formed by laying stones or sand on the bottom plate so as to have a predetermined thickness. . Groundwater in soil retaining walls made of soil cement , constructed to a depth deeper than the aquifer in the ground, and pipes reaching deeper than the aquifer embedded in the upstream and downstream, respectively, with respect to the flow of groundwater A flow inhibition structure,
The soil cement in the tube has been removed,
A through-hole formed so as to penetrate from the inside of the pipe to the aquifer by inserting a crusher capable of injecting high-pressure water into the pipe and injecting the high-pressure water at the position of the aquifer When,
A space formed by excavating the inner ground surrounded by the retaining wall is installed on the bottom plate at a depth of the impermeable layer below the aquifer and collected in the pipe on the upstream side through the through hole. A structure for preventing flow inhibition of a mountain retaining wall, comprising water supply means for supplying the groundwater that has been drained to the pipe on the downstream side.

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