JP2012087501A - Well, well construction method, groundwater level lowering method, method for constructing earth retaining wall, and sheet pile - Google Patents

Abstract

PROBLEM TO BE SOLVED: To shorten a construction period required for earth retaining wall construction steps and column pipe installation steps, by improving workability during the installation of the column pipe and reducing the number of man-hours required for the steps.SOLUTION: In a groundwater level lowering method, an earth retaining wall 10 is constructed by installing a sheet pile 20 around a target area 2 for lowering a groundwater level, and groundwater in the target area 2 is lifted. Characteristically, a sheet pipe 20, in which a lifting pipe 30 for lifting the groundwater is integrated with a surface on the side of the target area 2, is installed around the target area 2. The sheet pipe 20 has a U-shaped cross-section and forms longitudinally-elongated groove space 20C. The lifting pipe 30 is disposed in the groove space 20C of the sheet pile 20.

Description

  The present invention relates to a well, a well construction method, a groundwater level lowering method, a retaining wall construction method, and a sheet pile.

  In the case of ground excavation work, if the root excavation bottom reaches below the groundwater level, it is necessary to pump up the groundwater in the area to be drilled and lower the groundwater level in the area. Well point method, deep well method, etc. are performed. When carrying out such a construction method, first, the earth retaining wall is constructed by placing sheet piles (steel sheet piles) around the area where the groundwater is pumped up, and then the groundwater is pumped up. Install pumping pipes (pumping wells) and water injection pipes (pouring wells).

  Here, it is desired to improve the workability when constructing the retaining wall and when installing the pumping pipe or water injection pipe, and a method for improving the workability when constructing the retaining wall has been devised. (For example, refer to Patent Document 1). In the method described in Patent Document 1, a nozzle is provided at the lower end of a water pipe fixed to a sheet pile, and high pressure water is jetted from the nozzle.

Japanese Patent Laid-Open No. 2004-60163

  However, for workability when installing a pumping pipe or a water injection pipe, a support mechanism such as a beam or a raising member for supporting the water pumping pipe or the water injection pipe is installed, or a pumping pipe or a water injection pipe is passed. There is a point that needs to be improved, for example, it is necessary to make a hole and fill the hole with sand or gravel to fix the pumping pipe or water injection pipe. In addition, it is desired to reduce the man-hours required for construction of earth retaining walls and installation of pumping pipes and water injection pipes, and to shorten the construction period required for these.

  The present invention has been made in view of the above circumstances, and improves the workability when installing a pumping pipe or a water injection pipe, and constructs a retaining wall and a process of installing a water pumping pipe or a water injection pipe. The object is to reduce the number of man-hours required and to shorten the time required for these steps.

  In order to solve the above problems, a well according to the present invention is a well constructed by inserting a pumping pipe or a water injection pipe into a region where a retaining wall is constructed by a sheet pile, and the pumping pipe or The water injection pipe is integrated with the sheet pile.

  Moreover, in order to solve the said subject, the construction method of the well which concerns on this invention constructs a well by inserting a pumping pipe or a water injection pipe in the area | region which constructs a retaining wall by driving a sheet pile. It is a method, Comprising: The said sheet pile which integrated the said pumping-up pipe or the said water injection pipe is laid down, It is characterized by the above-mentioned.

  In order to solve the above-mentioned problems, the groundwater level lowering method according to the present invention constructs a retaining wall by placing a sheet pile around a target area where the groundwater level is reduced, and pumps groundwater in the target area. The groundwater level lowering method is characterized in that the sheet pile in which a pumping pipe for pumping up groundwater is integrated on the surface of the target area is driven around the target area.

  In order to solve the above-mentioned problems, the groundwater level lowering method according to the present invention constructs a retaining wall by placing a sheet pile around a target area where the groundwater level is reduced, and pumps groundwater in the target area. A groundwater level lowering method for returning to the ground outside the target area, wherein the sheet pile integrated with a pumping pipe for pumping groundwater on the surface of the target area and the groundwater pumped into the ground The sheet pile in which the water injection pipe for returning is integrated on the surface opposite to the target area side is driven around the target area.

  In the groundwater level lowering method, the sheet pile may be U-shaped or hat-shaped in cross section, and a groove space extending in a longitudinal direction may be formed, and the pumping pipe is arranged in the groove space of the sheet pile. May be.

  In order to solve the above-mentioned problem, a method for constructing a retaining wall according to the present invention is a method for constructing a retaining wall that constructs a retaining wall by placing a sheet pile around a target region for lowering a groundwater level. And the said sheet pile which integrated the pumping pipe for pumping up ground water on the surface by the side of the said target area | region is driven around the said target area | region.

  In order to solve the above-mentioned problem, a sheet pile according to the present invention is a sheet pile constituting a retaining wall constructed around a target region for lowering a groundwater level, and a pumping pipe for pumping ground water is the target. It is characterized by being integrated with the area side surface.

  According to the present invention, it is possible to improve workability when installing a pumping pipe and a water injection pipe, reduce the man-hour required for the process of constructing a retaining wall and the process of installing the water pumping pipe and the water injection pipe. The required construction period can be shortened.

It is a schematic sectional drawing for demonstrating the well point construction method concerning one Embodiment. It is a schematic plan view for demonstrating the well point construction method which concerns on one Embodiment. It is a top view which expands and shows the principal part of FIG. It is a schematic sectional drawing for demonstrating the well point construction method which concerns on other embodiment. It is a schematic plan view for demonstrating the well point construction method which concerns on other embodiment. It is a top view which expands and shows the principal part of FIG. It is a principal part enlarged plan view for demonstrating the well point construction method which concerns on other embodiment. It is a principal part enlarged plan view for demonstrating the well point construction method which concerns on other embodiment.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic cross-sectional view for explaining a well point method (forced drainage method) according to an embodiment of the present invention, and FIG. 2 is a schematic plan view for explaining the well point method. As shown in these drawings, the well point method according to the present embodiment is carried out in order to lower the groundwater level (indicated by WL in FIG. 1) in the area where the underground frame 1 is constructed.

  In this construction method, a large number of sheet piles (steel sheet piles) are formed up to a position deeper than the root bottom surface 3 so that the earth retaining wall 10 is constructed around a region 2 in which the groundwater level is lowered (hereinafter referred to as a target region). ) 20 is performed. The process is performed using an auger combined press-in method such as the HAS method, a hydraulic press-in method, a silent master (silent pile) method, or another method such as a water jet method. Here, about half of the large number of sheet piles 20 constituting the earth retaining wall 10 are integrated with the pumping pipes 30, and the large number of pumping pipes 30 are embedded in the construction area 2 together with the large number of sheet piles 20. It is. This point will be described in detail later. In addition, after constructing the earth retaining wall 10 by placing a large number of sheet piles 20, the underground frame 1 is constructed by excavating the underground region surrounded by the earth retaining wall 10.

  Further, the heads of a number of pumping pipes 30 are connected to the header pipe 34 via the swing joint 32, and the header pipe 34 is connected to the vacuum pump 36. Further, a drain pipe 38 is connected to the vacuum pump 36. This drain pipe 38 is extended to the discharge destination (for example, sewer etc.) of the pumped-up groundwater.

  The pumping pipe 30 is a riser pipe having a pipe diameter of about 30 to 40 mm, and a well point 31 is attached to the tip (lower end) thereof. The well point 31 is a water-permeable tube material in which a punching metal, a mesh material, or the like is laminated, and a nozzle that houses a ball valve is provided at the tip (lower end). This nozzle is opened when water is jetted and closed when pumping water.

  When the vacuum pump 36 is operated, the groundwater in the target area 2 flows into the pumping pipe 30 from the well point 31 and is pumped up to the ground, and is discharged through the drain pipe 38. Thereby, the groundwater level WL of the target area 2 is lowered.

  FIG. 3 is an enlarged plan view showing a main part of FIG. As shown in this figure, each sheet pile 20 is a U-shaped steel sheet pile having a U-shaped cross section, and joints 22 are formed at both edges. The earth retaining wall 10 is configured by arranging a large number of sheet piles 20 so that unevenness is alternately repeated, and connecting adjacent objects with joints 22. Moreover, the earth retaining wall 10 is configured by alternately arranging and connecting sheet piles 20 with integrated pumping pipes 30 and sheet piles 20 without integrated pumping pipes 30. Note that a steel sheet pile having a hat-shaped cross section may be used as the sheet pile 20.

  Here, the pumping pipe 30 is arranged in the groove space 20C between the bottom piece 20A constituting the groove bottom portion of the U-shaped, that is, the groove-shaped sheet pile 20, and the left and right side pieces 20B rising from both sides in the width direction. The pump 30 is welded to the surface of the bottom piece 20A on the groove space 20C side. For this reason, the water pump 30 is located outside the wall axis (center in the thickness direction) 10D of the earth retaining wall 10 (that is, on the opposite side of the underground enclosure 1).

  In the process of placing the sheet pile 20, when the hydraulic press-fitting method is used, the upper end of the sheet pile 20 is gripped by a chuck, so that a pumping pipe 30 is provided to secure a space for the upper end of the sheet pile 20. Is disposed below the upper end of the sheet pile 20. Further, in the step of placing the sheet pile 20, when the auger combined press-fitting method is used, the auger is passed through the groove space 20C of the sheet pile 20, so that the groove space 20C is secured in the groove space 20C. The depth and the diameter of the pumping pipe 30 are set.

  As described above, in the well point method according to the present embodiment, the earth retaining wall 10 is constructed by driving the sheet pile 20 integrated with the pumping pipe 30 around the target region 2, and the pumping pipe 30 is inserted. Build a pumping well. As a result, a support mechanism such as a cut beam or a raised member for supporting the pumping pipe 30 is installed, or a hole through which the pumping pipe 30 is passed, and sand or gravel is buried in the hole to fix the pumping pipe 30. It is not necessary to fix it. Therefore, workability at the time of installing the water pump 30 can be improved. Moreover, compared with the conventional method in which the process of constructing the retaining wall 10 and the process of installing the pumping pipe 30 are performed separately, the man-hours required for these processes can be reduced, and these processes are required. The construction period can be shortened.

  By the way, the underground frame 1 is constructed adjacent to the earth retaining wall 10, and concrete is placed between them to fix the underground frame 1 to the earth retaining wall 10. Here, the distance between the retaining wall 10 and the underground frame 1 is the narrowest at the position where the sheet pile 20 protrudes toward the underground frame 1 from the wall axis 10D, and the concrete thickness at this position is the smallest.

  In this embodiment, the pumping pipe 30 is arranged in the groove space 20 </ b> C of the seat pile 20, so that the above-described interval is not the narrowest position, but the underground shaft 1 is more than the wall axis 10 </ b> D of the retaining wall 10. It is distribute | arranged to the other side, ie, the position where the space | interval of the earth retaining wall 10 and the underground frame 1 becomes the largest. Thereby, the pumping-up pipe 30 can be prevented from being embedded at the position where the thickness of the concrete is the smallest, and the influence given to the concrete by the pumping-up pipe 30 being embedded can be reduced.

  FIG. 4 is a schematic cross-sectional view for explaining a well point method (forced drainage method) according to another embodiment, and FIG. 5 is a schematic plan view for explaining the well point method. As shown in these drawings, in the present construction method, a large number of sheet piles 20 are placed to a position deeper than the root bottom surface 3 so that the earth retaining wall 100 having a self-supporting structure is constructed around the target region 2. Implement the process of placing. This process is performed using an auger combined press-in method such as the HAS method, a hydraulic press-in method, other methods such as a silent pillar method, a water jet method, etc., as in the above embodiment. Here, the pumping pipe 30 is integrated in about half of the many sheet piles 20 constituting the earth retaining wall 100, and the water injection pipe 40 is integrated in the remaining half of the piles. Along with the sheet pile 20, the pumping pipe 30 is embedded in the target area 2 and the water injection pipe 40 is embedded outside the target area 2. This point will be described in detail later.

  The water injection pipe 40 is a riser pipe provided with a nozzle at the tip, and its head is connected to the header pipe 44 via a swing joint 42. Further, the header pipes 34 and 44 are connected to a not-illustrated not titanium.

  Here, a clay layer 4 is present at a position deeper than the rooted bottom surface 3 in the target region 2 and its periphery, and this clay layer 4 is shielded by the earth retaining wall 10 on the target region 2 side and the outside thereof. Separated in water. For this reason, groundwater does not flow into the target area 2 from the outside. Therefore, in this embodiment, the vacuum pump 36 is operated to pump up the groundwater in the target area 2 with the pumping pipe 30 and return the pumped groundwater to the ground around the target area 2 with the water injection pipe 40.

  When the vacuum pump 36 is operated, the groundwater in the target area 2 flows into the pumping pipe 30 from the well point 31 and is pumped up. Then, the pumped-up water is sent to the water injection pipe 40, descends to the well point 41 at the tip of the water injection pipe 40 by its own weight, and is returned to the ground outside the target region 2 from the nozzle of the well point 41. Thereby, in the target area 2, the groundwater level WL is lowered. Further, the groundwater returned to the ground outside the target area 2 is blocked by the clay layer 4 and the retaining wall 100, so that it does not flow into the target area 2 and flows into the ground outside the target area 2. stay.

  6 is an enlarged plan view showing the main part of FIG. As shown in this figure, the earth retaining wall 100 is configured by alternately arranging and connecting the sheet pile 20 integrated with the pumping pipe 30 and the sheet pile 20 integrated with the water injection pipe 40. Yes.

  Here, the pumping pipe 30 and the water injection pipe 40 are arranged in the groove space 20C of the sheet pile 20, and the water pumping pipe 30 and the water injection pipe 40 are welded to the surface of the bottom piece 20A on the groove space 20C side. . For this reason, the pumping pipe 30 is located in the groove space 20C located outside the wall axis (center in the thickness direction) 100D of the earth retaining wall 100 (that is, on the opposite side of the underground enclosure 1). It is located in the groove space 20C located inside the wall axis 100D of the earth retaining wall 100 (that is, on the underground frame 1 side).

  As described above, in the well point method according to the present embodiment, the earth retaining wall is formed by placing the sheet pile 20 integrated with the pumping pipe 30 and the sheet pile 20 integrated with the water injection pipe 40 around the target region 2. 10 is constructed, and a pumping well in which the pumping pipe 30 is inserted and a water injection well in which the water pouring pipe 40 is inserted are constructed. Thereby, a support mechanism for supporting the pumping pipe 30 and the water injection pipe 40 is installed, or a hole through which the water pumping pipe 30 and the water injection pipe 40 is passed, and sand, gravel, viscosity and the like are buried in the hole, and the water pumping pipe 30 Or fixing the water injection pipe 40 becomes unnecessary. Therefore, workability at the time of installing the pumping pipe 30 and the water injection pipe 40 can be improved. Moreover, compared with the conventional method in which the process of constructing the retaining wall 100 and the process of installing the pumping pipe 30 and the water injection pipe 40 are performed separately, the man-hours required for these processes can be reduced. The construction period required for this process can be shortened.

  In this embodiment, the groundwater pumped by the pumping pipe 30 is returned to the ground by the water injection pipe 40, but drainage from other construction sites and facilities may be injected into the ground by the water injection pipe 40. . Moreover, in this embodiment, although the pumping pipe 30 and the water injection pipe 40 were comprised so that it might extend from the lower end of the earth retaining wall 10 to the deep layer side, it comprised so that it might cut | disconnect on the shallower layer side from the lower end of the earth retaining wall 10 etc. The lengths of the pumping pipe 30 and the water injection pipe 40 and the positions of the well points 31 and 41 may be set as appropriate.

  FIG. 7 is an enlarged plan view of a main part for explaining a well point method according to another embodiment. As shown in this figure, in the well point method according to the present embodiment, the sheet pile 20 integrated with the pumping pipe 30 and the sheet pile 20 integrated with the water injection pipe 40 are driven around the target region 2. Thus, the retaining wall 200 is constructed.

  Here, in this embodiment, the pumping pipe 30 and the water injection pipe 40 are welded to the surface of the outer side of the bottom piece 20A (the back side on the groove space 20C side), and the water pumping pipe 30 and the water injection pipe 40 are the groove space of the seat pile 20. It is located outside 20C. Thereby, in the case of using the auger combined press-fitting method, it is not necessary to determine the diameters of the pumping pipe 30 and the water injection pipe 40 in relation to the auger passed through the groove space 20C. The degree of freedom of design can be expanded.

  FIG. 8 is an enlarged plan view of a main part for explaining a well point method according to another embodiment. As shown in this figure, in the well point construction method according to the present embodiment, the earth retaining wall 300 is formed by placing the sheet pile 20 in which the pumping pipe 30 and the water injection pipe 40 are integrated around the target area 2. To construct.

  For the sheet pile 20 arranged outside the wall shaft 300D, the pumping pipe 30 is welded to the surface of the sheet pile 20 on the side of the groove space 20C on the bottom piece 20A side, and the water injection pipe 40 is connected to the groove space 20C of the bottom piece 20A. Weld to the back side of the side. On the other hand, in the sheet pile 20 arranged inside the wall shaft 300D, the water injection pipe 40 is welded to the surface of the bottom piece 20A of the sheet pile 20 on the groove space 20C side, and the pumping pipe 30 is connected to the groove space 20C of the bottom piece 20A. Weld to the back side of the side.

  As described above, in each of the above-described embodiments, the present invention has been described by taking as an example the case where the well point method is used as the groundwater level lowering method. However, the present invention is a sheet pile in which a pumping pipe or a water injection pipe is integrated with a sheet pile. It can be applied to all groundwater level lowering methods that can be embedded in the ground. Moreover, it is not essential to join the pumping pipe 30 and the water injection pipe 40 to the bottom piece 20A of the sheet pile 20, and may be joined to the side piece 20B. Furthermore, it is not essential to construct the retaining wall with the sheet pile 20 integrated with the pumping pipe 30, and the retaining wall may be constructed with the sheet pile 20 integrated with only the water injection pipe 40.

DESCRIPTION OF SYMBOLS 1 Underground frame, 2 object area | region, 3 root cutting bottom, 4 clay layer, 10 earth retaining wall, 10D wall axis, 20 sheet pile (sheet pile), 20A bottom piece, 20B side piece, 20C groove space, 22 joint, 30 pumping pipe , 31 well point, 32 swing joint, 34 header pipe, 36 vacuum pump, 38 drain pipe, 40 water injection pipe, 42 swing joint, 44 header pipe, 100, 200, 300 earth retaining wall, 100D, 300D wall axis

Claims (7)

A well constructed by inserting a water pump or a water pipe into the area where the earth retaining wall is constructed by the sheet pile,
The well, wherein the pumping pipe or the water injection pipe is integrated with the sheet pile. A method of constructing a well by inserting a pumping pipe or a water injection pipe into an area where a retaining wall is constructed by placing a sheet pile,
A well construction method characterized by placing the sheet pile integrated with the pumping pipe or the water injection pipe. By constructing a retaining wall by placing a sheet pile around the target area to lower the groundwater level, the groundwater level lowering method to pump up the groundwater of the target area,
A groundwater level lowering method characterized in that the sheet pile in which a pumping pipe for pumping up groundwater is integrated on the surface of the target area is placed around the target area. A groundwater level lowering method that constructs a retaining wall by placing sheet piles around the target area where the groundwater level is lowered, pumps up the groundwater in the target area, and returns it to the ground outside the target area. And
The sheet pile integrated with the surface on the target area side for pumping the ground water and the water injection pipe for returning the pumped ground water to the ground are integrated on the surface opposite to the target area side. A groundwater level lowering method characterized by placing a sheet pile around the target area. The sheet pile is U-shaped or hat-shaped in cross section, and a groove space extending in the longitudinal direction is formed,
The groundwater level lowering method according to claim 3 or 4, wherein the pumping pipe is arranged in the groove space of the sheet pile. A method for constructing a retaining wall by constructing a retaining wall by placing a sheet pile around a target area that lowers the groundwater level,
A construction method of a retaining wall, characterized in that the sheet pile in which a pumping pipe for pumping up groundwater is integrated on the surface of the target area is placed around the target area. It is a sheet pile that constitutes a retaining wall built around the target area that lowers the groundwater level,
A sheet pile, wherein a pumping pipe for pumping up ground water is integrated with the surface on the target area side.

Images