JP2018091038A - Pipe drawing-out method of existing wellhole - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide pipe drawing-out method of an existing wellhole with respect to urban type civil engineering and construction work, the method having no influence of vibration on a residential area etc. around a narrow construction yard, capable of eliminating the possibility of a well pipe remaining, and drawing the well pipe without vibrations in a narrow urban area.SOLUTION: The method includes: removing the pumping facility installed in the well of an existing well; attaching an extrusion pipe closing lid and an extrusion hoisting jig to an upper part of a well pipe; and after washing the inside of the well pipe, injecting water from a water inlet into the well pipe and stopping water injection by filling the well pipe; pumping air from the air injection port into the well pipe to edge the well pipe with the ground; lifting the drawing suspending jig through the extruding wire by a crane to draw the well pipe; stopping the pressure feed of air into the well pipe after it is determined that the lifting load of the well pipe by the crane is the weight of the well pipe itself; continuing to pull out the well pipe by the crane; and drawing out the well pipe.SELECTED DRAWING: Figure 3

Description

  The present invention provides a well equipped with a strainer section such as a winding screen embedded in an existing well formed in the ground in a narrow construction yard where the surrounding area is a residential area and the influence of vibration on the surrounding area is a concern. The present invention relates to a method for extracting an existing well in which the tube is extracted without vibration.

In recent years, various civil engineering / architectural works, landslide countermeasures, underground wells for drinking dams, wells for drinking, swelling countermeasures, Dalai work, soft ground improvement rivers and coastal constructions, and soil improvement works In the field, the potage drainage method, the well point method, the deep well method, etc. are used as the groundwater level lowering method accompanying the root cutting work. Ultra Deep (which improves water handling and response to low-permeability ground, etc. and can be applied to the above fields, and realizes a larger volume of pumping and a wider range of lowering of water level with a small number of pumping wells ( UD) Proposed construction method.
In these groundwater level lowering methods, in particular, the deep well method, the ultra deep method, etc., a steel well pipe equipped with a strainer section that allows groundwater to pass inside is buried in the ground, and a well is installed. The groundwater level is lowered by pumping up the groundwater flowing into the well pipe with a pump (see Patent Documents 1 and 2).

In the construction of various fields where it is necessary to lower the groundwater level, such as urban civil engineering and construction mentioned above, once the construction is completed, the well pipes of existing wells installed in the ground are expensive, so they are collected. In many cases, they are left buried as they are, but due to various requests such as requests from landowners or owners, well pipes of existing wells are collected by various methods.
Examples of the conventional extubation method for extruding a well pipe of such an existing well include an extubation method by excavation of a full swivel casing, an extubation method by a vibro hammer, and an extubation method by a hydraulic jack.
A tube-extracting method by excavating all-swivel casing uses a fully-rotating all-casing excavator equipped with a gripping device, a rotation drive device, and a pushing / pulling-out device, and grips a casing constituting a well pipe embedded in the ground of an existing well And is pulled out by a push / pull-out device while being rotated by a rotary drive device. In the all-swivel casing excavation method, a casing equipped with a drilling bit at the tip is gripped by a gripping device in advance and buried in the ground by a push-pull-out device while being rotated by a rotary drive device. It is also carried out when construction work for installing wells is performed. Extubation is performed again using a full-rotation all-casing excavator after completion of the construction.

In the tube extraction method using a vibratory hammer, the casing that becomes the well pipe is gripped by the gripping device (chuck) of the vibratory hammer while the vibratory hammer is suspended from the crane, vibration is generated by the vibratory hammer, and the ground contacting the casing through the casing is vibrated. It is a construction method that causes a fluidization phenomenon or the like in the ground and pulls it out with a casing. The construction method using the vibratory hammer is that the casing that becomes the well pipe is gripped by the vibratory hammer gripping device (chuck) while the vibratory hammer is suspended from the crane, and vibration is generated by the vibratory hammer to vibrate the ground contacting the casing through the casing. This is also carried out when the work is carried out by installing a well having a casing as a well pipe by causing a fluidization phenomenon or the like in the ground and penetrating the casing into the ground. Extubation is performed again using a vibro hammer after the completion of construction.
The tube extraction method using a hydraulic jack is a method in which a casing and a jack constituting a well pipe of an existing well are connected by a wire or a shackle, and the casing is pulled out by a lifting force of a hydraulic cylinder of the hydraulic jack.

Japanese Patent No. 3243501 Japanese Patent No. 3595326

By the way, in recent years, the steel well pipe of the existing well disclosed in Patent Documents 1 and 2 described above is not buried and buried, but there is an increase in cases where it is necessary to recover from the ground from the request from the landowner and / or the owner. doing.
However, in the case of urban civil engineering and construction work, if the construction yard is narrow, for example, about 3 m x 5 m, or if the surrounding of the construction yard is a residential area or a densely packed building, the conventional extubation method, In particular, there has been a problem that a large-scale mechanical facility such as a full-rotation all-casing excavator cannot be installed in the tube-extracting method by excavating the entire swivel casing.
In addition, in the tube-extracting method using a vibro hammer, there is a problem that if the surrounding area of the construction yard is a residential area or a densely packed building, the influence of vibration on the surroundings is large and the tube-extracting operation cannot be performed.
Further, in the pipe extraction method using a hydraulic jack, the hydraulic cylinder of the hydraulic jack is pulled out by the driving force of the hydraulic jack. Therefore, the connection part of the well pipe, for example, the welded connection part between the casing pipe and the inner pipe or the water collecting pipe formed with the strainer part, and There has been a problem that there is a possibility of remaining well pipes due to breakage of the strainer part such as the winding screen part.

  The object of the present invention is to solve the above-mentioned problems of the prior art, and even if the construction yard is narrow in urban civil engineering and construction work, the surrounding area of the construction yard is a residential area or a densely packed building. However, it is only necessary to install a relatively small mechanical facility such as a rough terrain crane, and there is no influence of vibration on the surroundings such as a residential area, and a strainer portion such as a welded connection portion of a well pipe and / or a winding screen portion. It is an object of the present invention to provide a method for extracting existing wells that can eliminate the possibility of remaining well pipes due to breakage of the wells and can extract the well pipes without vibration in urban narrow areas.

  In order to achieve the above-described object, the method for extracting an existing well according to the present invention is an existing well extracting method for extracting a well pipe buried in an existing well formed in the ground in a construction yard. Has a casing pipe part and a strainer pipe part having a strainer material on its outer periphery, and has a filter layer containing pebbles and gravel between the inner periphery of the well borehole and the outer periphery of the well pipe. The pumping equipment installed in the well pipe of the existing well is removed, and a draining closure lid with a water inlet and an air inlet and a pipe lifting jig are attached to the upper end of the well pipe. After attaching the cleaning hose and injecting water into the well pipe to inject and wash the strainer material of the well pipe, stop water injection, connect the water injection line to the water inlet, connect the air injection line to the air inlet, And crane and extubation wire Therefore, water is poured into the well pipe from the water inlet to fill the well pipe to stop water injection, and the pump is suspended from the air inlet through the wire for pipe removal while pumping air into the well pipe. After lifting the well pipe and starting the extraction of the well pipe, cutting the well pipe from the natural ground, and then lifting the extraction pipe lifting jig with a crane and continuing the extraction of the well pipe, the lifting load of the well pipe by the crane is After being determined to be the weight of itself, the pumping of the air into the well pipe is stopped, and the well pipe is continuously lifted and pulled out by a crane, and the well pipe is pulled out. In addition, it is preferable that the said construction yard is a narrow construction yard, for example.

Here, the strainer material is preferably a winding screen or a slit screen.
Moreover, it is preferable that a pumping equipment is a well cover, a flow control valve, a water injection pipe, a water pumping pipe, and a water pump.
Also, one end of the cleaning hose is attached to the water inlet, and the other end of the cleaning hose is attached to a cleaning pump located in the construction yard near the existing well. The cleaning pump is driven, and the strainer material of the well pipe is preferably discharged and cleaned from the strainer material.
Moreover, it is preferable that the water injection pressure of the water injection cleaning is 1.0 MPa or less.

In addition, one end of the water injection line is connected to a water injection port, and the other end of the water injection line is connected to a water injection pump installed in a water injection tank located in a construction yard near the existing well. Water injection from the water inlet into the well pipe is preferably performed by driving a water injection pump.
Moreover, it is preferable that the water injection pressure of the water injection line is 1.0 MPa or less.
In addition, the closing lid for extubation further has a confirmation window for confirming the state in the well pipe of the existing well,
It is preferable that the water injection by the water injection line is stopped after the confirmation window confirms that the inside of the well pipe is filled with water by the water injection line.

One end of the air injection line is connected to the air injection port, and the other end of the air injection line is connected to a compressor arranged in the construction yard near the existing well,
It is preferable that the air is fed from the air inlet into the well pipe by the air injection line by driving the compressor and blowing air.
Moreover, it is preferable that the ventilation pressure by the drive of a compressor is 1.0 Mpa or less.
In addition, the draining closure lid further has a confirmation window for confirming the state in the well pipe of the existing well, and it is confirmed that the well pipe is cut off from the ground by pumping air through the air injection line. It is preferable that the lifting and pulling of the well pipe by the crane is started after being confirmed by the window.

In at least one of water injection cleaning, water injection by the water injection line, and air pumping by the air injection line, the turbid water that overflows from the filter layer in the borehole of the existing well to the ground is in the construction yard near the existing well. It is preferably recovered and processed by a sand pump arranged in
Moreover, it is preferable that the extubation hanging jig is welded and attached to the lower side of the flange portion at the upper end of the casing pipe of the well pipe, and is connected to the hook of the crane by an extubation wire.
Moreover, it is preferable that the lifting load at the time of extracting the well pipe with a crane is 15 t or less.
Moreover, it is preferable that a crane is a rough terrain crane, a truck crane, or a crawler crane.

The weight of the well pipe itself is preferably determined when the lifting load at the time of extracting the well pipe becomes 150% or less of the weight of the well pipe before being installed in the existing well.
Moreover, the lifting of the well pipe by the crane is stopped again before the well strainer pipe comes out on the ground, and a Kanzashi is attached to the casing pipe of the well pipe to prevent the well pipe from falling. Cut the casing pipe with a gas cutting machine etc. in the upper part of the Kanzashi, re-extract the cut well pipe with Kanzashi, extract the well pipe from the drilling hole, complete the extraction, and the well pipe is extracted It is preferable to backfill the drilled holes.

  According to the present invention, even if the construction yard is narrow in urban civil engineering and construction work, and even if the surrounding of the construction yard is a residential area or a densely packed building, it is relatively small such as a rough terrain crane. The possibility of residual well pipe due to damage to the welded connection part of the well pipe and / or the strainer part such as the winding screen part, etc. Can be eliminated and the well pipe can be extracted without vibration in a narrow urban area.

It is a block diagram which shows typically an example of the groundwater level fall apparatus installed in the existing well which implements the extubation method of the existing well which concerns on one Embodiment of this invention. It is sectional drawing which shows typically the structure of the groundwater level fall apparatus shown in FIG. It is a flowchart which shows an example of the extubation method of the existing well which concerns on one Embodiment of this invention. FIG. 2 is a structural diagram schematically showing a state in which an extruding obstruction lid and an extruding jig are attached to the well pipe of the existing well shown in FIG. 1. It is a block diagram for demonstrating an example of the system configuration | structure for implementing the water injection washing process of the well pipe of the existing well shown in FIG. It is a block diagram which shows an example of the structure of the existing well pipe extraction system in order to implement the pipe extraction method of this invention with respect to the well pipe of the existing well shown in FIG. It is explanatory drawing for demonstrating the water pouring process in the well pipe implemented in the existing pipe extraction system shown in FIG. It is explanatory drawing for demonstrating the pneumatic feeding process into the well pipe implemented in the extubation system of the existing well shown in FIG. It is explanatory drawing for demonstrating the drawing process of the well pipe implemented in the pipe extraction system of the existing well shown in FIG. It is explanatory drawing for demonstrating the cutting process of the well pipe by which the existing well shown in FIG. 9 was extracted.

Hereinafter, a method for extruding an existing well according to the present invention will be described in detail with reference to a preferred embodiment shown in the accompanying drawings.
FIG. 1 is a structural diagram schematically showing an example of a groundwater level lowering device installed in an existing well that performs the method of extracting an existing well according to an embodiment of the present invention. FIG. 2 is a cross-sectional view schematically showing the structure of the groundwater level lowering apparatus shown in FIG.
The groundwater level lowering apparatus 10 shown in FIGS. 1 and 2 is used for the deep well method, the ultra deep method proposed by the applicant, and the like, and is provided in the excavation hole 11 excavated in the ground E. A well pipe 14, a well lid 16, a pumping pump 18, a pumping pipe 20, a flow rate adjusting valve 22, a pumping tank 24, a vacuum pump 26, an intake hose 28, and a cleaning water injection pipe constituting the well 12. 30.
The well pipe 14 includes a casing pipe 32 and a strainer pipe 34.
In the existing well 12, a filter layer F filled with gravel is provided between the excavation hole 11 in the ground E and the outer periphery of the well pipe 14.
Here, on the basis of the time when the existing well 12 is used as a pumping well for pumping, it is called a pumping pump 18 and a pumping pipe 20, but the present invention is not limited to this, and the existing well 12 is used for water injection as a water injection well. When used, the pump may be referred to as a cleaning pump and the pumping pipe as a cleaning pump. The cleaning water injection pipe 30 is used at the time of the water injection well, not at the time of the pumping well.

The groundwater level lowering device 10 is for carrying out a groundwater level lowering method for lowering the groundwater level by draining groundwater to the ground as a countermeasure against groundwater, and the ground around the well pipe 14 embedded in the ground E The groundwater contained in E is caused to flow into the well pipe 14 through the strainer pipe 34 of the well pipe 14, and the groundwater that has flowed in is pumped up by the pump 18, and is then grounded via the pump 20 and the flow rate adjusting valve 22. It is for draining to the pumping tank 24. At this time, in the groundwater level lowering device 10, the inside of the well pipe 14 is set to a negative pressure by the vacuum pump 26 to promote drainage of the groundwater to the ground.
In the existing well 12, a well pipe 14 is buried in the ground E, and in the well pipe 14 and the periphery thereof, a ground water level lowering device 10 is constructed, for example, a well lid 16 constituting a pumping facility, A pump 18, a pumping pipe 20, a flow rate adjusting valve 22, a pumping tank 24, a vacuum pump 26, an intake hose 28, a cleaning water injection pipe 30, and the like are arranged.

The well pipe 14 is stored by flowing only the ground water around the well pipe 14 into the well pipe 14 without being separated from the surrounding debris and gravel by the filter layer F and the strainer pipe 34 and mixing them. 14 is used for draining the stored groundwater to the ground, and has the casing pipe 32 and the strainer pipe 34 as described above.
The casing pipe 32 constitutes the upper part of the well pipe 14 and is made of, for example, a steel circular pipe, a so-called steel pipe. The casing pipe 32 connects from the ground surface to the strainer pipe 34 so that the casing pipe 32 is within the range of the strainer pipe 34 even if the groundwater level of the ground E fluctuates.
As shown in FIGS. 1 and 2, the strainer pipe 34 is provided at the lower end of the casing pipe 32, and has a water collecting pipe 36 made of a cylindrical steel pipe and a gap 37 with a predetermined interval on the outer periphery of the water collecting pipe 36. And a tubular strainer material 38 provided to form.

The upper end of the water collecting pipe 36 is joined to the lower end of the casing pipe 32 by welding, for example, and a predetermined area on the lower end side is a sand reservoir 40, and a predetermined area on the upper side of the sand reservoir 40 is In this region, there are a plurality of water holes 42 through which the groundwater that has passed through the strainer material 38 and flows into the gap 37 between the strainer material 38 and the water collection pipe 36 is introduced into the water collection pipe 36. It is formed so as to penetrate the tube wall. The bottom of the water collecting pipe 36 which is the lower end of the sand reservoir 40 is closed with a bottom lid 41 for sand reservoir.
The water passage holes 42 are rectangular slits that are long in the vertical direction. One or more rows in the vertical direction of the water collecting pipe 36 and a plurality of lines arranged in the circumferential direction of the water collecting pipe 36 at regular intervals, for example, Or it is arranged in a staggered pattern.
In the circular strainer material 38, the soil in the surrounding ground E is separated by the filter layer F, and only the groundwater is collected from the groundwater containing the gravel and the like without separating the gravel and the like from the collecting pipe 36 and the strainer material 38. A plurality of windings in which steel wires are continuously wound around spacers (not shown) made of elongated steel pipes arranged at equal intervals on the outer periphery of the water collecting pipe 36, for example. It is a special screen consisting of the so-called winding screen. The spacing between the windings of this special screen is set to a predetermined value that can ensure the required water permeability that allows only water such as groundwater to pass through without allowing air to pass through, and that can prevent entry of foreign matter such as sand and dirt. Is set. As such strainer material 38, a special screen for a well used in a deep well method or the like, for example, a winding screen such as an ultra deep special screen or the like used in the ultra deep method proposed by the present applicant, a slit screen or the like Can be mentioned.

In the example shown in FIG. 2, the water collection pipe 36 and the casing pipe 32 are preferably made of a steel pipe having the same outer diameter and wall thickness from the viewpoint of cost and manufacturing. Therefore, the outer diameter of the strainer pipe 34 is It becomes larger than the outer diameter of the casing tube 32.
For example, the casing pipe 32 and the water collecting pipe 36 are steel pipes having an outer diameter of 406.4 mm and a wall thickness of 6.4 mm, and a spacer (not shown) is an elongated steel pipe having an outer diameter of 21.7 mm and a wall thickness of 1.9 mm. The winding of the material 38 can use the well pipe 14 which is a steel wire plated with zinc having a width of 4.0 mm and a thickness of 3.2 mm, and the outer diameter of the strainer pipe 34 is 456.2 mm. The outer diameter of the tube 32 is thicker by 49.8 mm and by a radius of 24.9 mm.

As described above, the strainer pipe 34 and the casing pipe 32 have different outer diameters, but the difference is small. Therefore, in the drawings of the present application, in FIGS. 1 and 4 to 10 other than FIG. The strainer tube 34 and the casing tube 32 are shown with the same outer diameter.
The casing pipe 32 of the well pipe 14 and the water collecting pipe 36 of the strainer pipe 34 of the present invention have the same outer diameter and wall thickness, and the outer diameter of the strainer pipe 34 is limited to be larger than the outer diameter of the casing pipe 32. That is, the present invention is not limited to the example shown in FIG. 2, and any combination of sizes may be used. For example, like the groundwater level lowering device described in Patent Document 1, the outer diameter of the water collecting pipe (inner cylinder pipe) is made smaller than the outer diameter of the casing pipe, and the outer diameters of the casing pipe and the strainer pipe are made the same. Also good.

The well lid 16 is attached to the upper end of the well pipe 14 so as to close the upper end of the well pipe 14 (for example, by a fastener (not shown) such as a bolt and a nut on the flange 33 at the upper end of the casing pipe 32). Thus, the internal space (intra-pipe space) S above the water surface in the well pipe 14 is sealed. The in-pipe space S is depressurized by the vacuum pump 26 and maintained at a negative pressure. The well cover 16 is attached so that the upper part of the pumping pipe 20 passes therethrough, and the intake 16a to which the intake hose 28 is connected and the cleaning inlet 16b to which the cleaning injection pipe 30 is connected. Is attached. Further, the well lid 16 may be provided with a vacuum gauge 27 for detecting the negative pressure in the above-described pipe inner space S.
The pump 18 is a submersible pump for pumping the groundwater flowing into the well pipe 14 to the ground. For example, the pump body and the motor unit are integrated, and the water collection pipe 36 of the strainer pipe 34 of the well pipe 14 is passed through. The water inlet is arranged slightly above the water hole 42 and is connected to the pumping pipe 20.

The pump 20 is connected to the pump 18 and extends through the well 14, i.e., through the strainer 34 and the casing 32, is attached to the well lid 16 and extends to the ground. A flow rate adjustment valve 22 is provided.
The flow rate adjusting valve 22 is provided in the pumping pipe 20, is for adjusting the amount of groundwater pumped by the pumping pump 18, and is connected to the pumping tank 24.
The pumping tank 24 is for storing the groundwater pumped up by the pumping pump 18 and drained to the ground, and is disposed on the ground E in the vicinity of the 12 well pipes 14 of the existing well. In addition, the groundwater stored in the pumping tank 24 is purified by precipitating and separating solid contents (soil components: for example, sand, silt, clay, etc.) contained therein. After that, clean water is discharged into rivers.

The vacuum pump 26 introduces a negative pressure into the sealed pipe space S formed in the well pipe 14 (the casing pipe 32 and the water collection pipe 36), and the groundwater in the ground E is introduced into the pipe space S by the vacuum effect. As a result, the pumping of water by the pump 18 is promoted and the groundwater level is lowered efficiently. Note that the negative pressure in the pipe space S is measured and monitored by the vacuum gauge 27.
The intake hose 28 is for connecting the vacuum pump 26 and the intake port 16 a of the well lid 16.
The washing water injection pipe 30 is a narrow pipe that is disposed in the casing pipe 32 of the well pipe 14 and connected to the well lid 16 at the time of the water injection well, and is used to wash the inside of the well pipe 14. To wash water, for example, clean water, into the well pipe 14.
The groundwater level lowering device 10, the existing well 12 and the well pipe 14 shown in FIGS. 1 and 2, which are the target of the existing well draining method of the present invention, are basically configured as described above. It is not limited to the above, and any existing well that is formed in the ground and needs to be pulled out from the buried well pipe, and any well that constitutes the existing well. It may be a tube.

Next, as a representative example of pulling out the well pipe constituting the existing well of the groundwater level lowering apparatus shown in FIG. 1 and FIG. Of course, the present invention is not limited to the extraction of such a well pipe.
FIG. 3 is a flowchart illustrating an example of a method for extracting an existing well according to an embodiment of the present invention.
In step S10 shown in FIG. 3, first, the pumping equipment of the groundwater level lowering device 10 installed inside and outside the well pipe 14 of the existing well 12 of the groundwater level lowering device 10 is removed. Here, examples of the pumping equipment include a well lid 16, a pumping pump 18, a pumping pipe 20, a flow rate adjusting valve 22, a pumping tank 24, a vacuum pump 26, an intake hose 28, a cleaning water injection pipe 30, and the like. . Here, the pump 18, the pump 20, the irrigation pipe 30, etc. are removed from the upper end of the well pipe 14, that is, from the flange 33 of the casing pipe 32 by fixing fixtures (not shown) such as bolts and nuts. After the well lid 16 is removed, the well lid 16 is lifted and collected from the well pipe 14 and removed. The flow rate adjustment valve 22 and the intake hose 28 may be removed from the well lid 16 and removed in advance, or may be removed together with the well lid 16. The pumping tank 24 and the vacuum pump 26 may be removed from the installation location.

Next, in step S12, as shown in FIG. 4, a water injection port 44a, an air injection port 44b, and a confirmation port 44c are provided on the upper end of the well pipe 14 from which the well cover 16 has been removed, that is, the flange 33 of the casing pipe 32. The extubation closing lid 44 provided is attached and fixed by a fixing tool (not shown) such as a bolt and a nut. The tube closing cover 44 may be fixed to the upper end (flange 33) of the well tube 14 by welding such as arc welding.
Next, an extraction pipe hanging jig 46 is attached to the upper end side of the well pipe 14, that is, the outer peripheral portion of the casing pipe 32 just below the flange 33 by arc welding or the like. In the example shown in the figure, the two extraction pipe hanging jigs 46 are provided at two outer peripheral portions in the diameter direction of the casing pipe 32, but three or more may be provided on the point object with respect to the center of the casing pipe 32. good.

Next, in step S14, as shown in FIG. 5, one end of the cleaning hose 48 is attached to the water inlet 44a of the tube closing cover 44 attached to the upper end of the well tube 14. The other end of the cleaning hose 48 is connected to a cleaning pump 52 disposed in a cleaning water tank 50 installed near the periphery of the existing well 12.
Thereafter, the cleaning pump 52 is driven to inject the cleaning water in the cleaning water tank 50 into the well pipe 14 from the water injection port 44 a via the cleaning hose 48. The washing water thus poured into the well pipe 14 passes through the casing pipe 32 and fills the water collecting pipe 36 of the strainer pipe 34 as shown in FIG. The cleaning water filled in the water collecting pipe 36 flows back to the clearance 37 around the water collecting pipe 36 from the water passage hole 42, and the cleaning water that flows back to the clearance 37 passes through the screen of the strainer material 38 and passes through the filter layer F. Vomited inside. In this way, the strainer material 38 of the strainer pipe 34 of the well pipe 14 is cleaned. When the strainer material 38 is sufficiently cleaned, the injection of cleaning water for water injection cleaning is stopped. In addition, the water injection pressure in the water injection cleaning is preferably 1.0 MPa at the maximum, and more preferably 0.8 MPa or less. The reason why the water injection pressure is preferably 1.0 MPa or less is that JIS 10K flanges are used for the well lid 16 and the draining closure lid 44, and the pressure is 10 kgf / cm ² (= 1.0 MPa) or less. This is necessary. The water injection pressure for the water injection cleaning may be set according to the pressure resistance of the well lid 16 and the draining closure lid 44.
At this time, the wash water poured into the well pipe 14 passes through the screen of the strainer material 38 of the well pipe 14 and is washed and discharged into the filter layer F to become turbid water and filter in the excavation hole 11. Overflow from layer F to the ground. The muddy water that has overflowed to the surface of the earth is collected and processed by the sand pump 54 installed around the existing well 12.

Next, in step S <b> 16, as shown in FIG. 6, one end of the water injection hose 56 is attached to the water injection port 44 a of the drainage closing lid 44 attached to the upper end portion of the well pipe 14. At this time, the other end of the water injection hose 56 is connected to a water injection pump 60 disposed in a water injection tank 58 installed near the periphery of the existing well 12. In this way, the water injection line from the water injection pump 60 in the water injection tank 58 to the water injection port 44a of the draining closure lid 44 and further into the well pipe 14 is connected.
Further, as shown in FIG. 6, one end of the air hose 62 is attached to the air inlet 44 b of the tube closing cover 44 attached to the upper end of the well tube 14. At this time, the other end of the air hose 62 is connected to a compressor 64 installed near the periphery of the existing well 12. In this way, an air line is connected from the compressor 64 to the air inlet 44b of the tube closing cover 44 and further into the well tube 14.
Further, as shown in FIG. 6, a crane hook (not shown), for example, a crane hook of a rough terrain crane (not shown), is attached to a pipe suspending jig 46 attached to the outer peripheral portion on the upper end side of the well pipe 14 by a pipe 66. 68. In the example shown in the drawing, the two tube pulling wires 66 are passed through the hole portions 46 a of the two tube pulling hanging jigs 46, and the two tube pulling wires 66 are engaged with the hooks 68. Are connected by two extruding wires 66.

Next, in step S18, as shown in FIG. 7, the water injection pump 58 is driven, and the water in the water injection tank 60 is supplied through the water injection line including the water injection hose 56 to the water injection port 44a of the tube closing closure 44. Then, water is poured into the well pipe 14 to fill the well pipe 14 with water. Note that the water injection pressure at this time is preferably 1.0 MPa at the maximum, and more preferably 0.8 MPa or less. The reason is as described above.
Here, when it is confirmed that the inside of the well pipe 14 is full from the confirmation port 44c of the closing lid 44 for draining pipe, the driving of the water injection pump 58 is stopped and water is injected into the well pipe 14 from the water inlet 44a. Is stopped.
At this time, the water injected into the well pipe 14 passes through the screen of the strainer material 38 of the well pipe 14 and is discharged into the filter layer F in the same manner as in the case of the water injection cleaning, and is excavated as muddy water. Since it overflows from the filter layer F in the hole 11 to the ground surface, the muddy water that has overflowed to the ground surface is collected and processed by the sand pump 54 installed around the existing well 12.
Here, the water in the water injection hose 56, the water injection tank 58, the water injection pump 60, and the water injection tank 58 shown in FIG. 6 and FIG. 7 are the washing hose 48, the water washing tank 50, the water washing pump 52, and the water shown in FIG. The cleaning water in the cleaning water tank 50 may be the same as or different from the cleaning water.

Next, in step S20, as shown in FIG. 8, the compressor 64 is driven, and the air from the compressor 64 through the air line including the air hose 62 to the inside of the well pipe 14 from the air inlet 44b of the tube closing cover 44 is obtained. While the air is being pumped (air blown), the tube pulling jig 46 is lifted by the crane hook 68 through the tube 66 for tube pulling, and the tube pulling of the well tube 14 is started. In addition, it is preferable that it is 1.0 MPa at the maximum, and it is more preferable that the pressure (air blowing) pressure at this time is 0.7 MPa or less. The reason is that if a high-pressure compressor is used, the maximum pressure of the compressor (engine) can be reached. However, the pressure resistance of the well cover 16 and the closing cover 44 for exhaust pipe, the back pressure, the water injection pressure at the time of water injection cleaning (step 14), This is because the water injection pressure at the time of water injection (step 20) is 1.0 MPa (10 kgf / cm ² ). The high-pressure compressor is often used for special purposes and is expensive, and therefore it is usually preferable to use a compressor. Thus, when using a normal compressor, since the maximum pressure of a normal compressor (engine) is 0.7 MPa, it is more preferable that the blowing pressure is 0.7 MPa. Here, the compressor 64 is not particularly limited as long as the pumping (air blowing) pressure can be preferably set to 1.0 MPa at the maximum, more preferably 0.7 MPa at the maximum, for example, about 50 HP (horsepower). It is preferable that it has the power of. Of course, a compressor 64 having a power of 50 HP or more may be used depending on the inner diameter of the well lid 16 and the tube closing closure 44, the depth of the existing well 12, and the like.
Moreover, it is preferable that the lifting load of the extraction pipe hanging jig 46 by the crane hook 68, that is, the well pipe 14, is 15 t or less, and more preferably 5 t to 10 t. The reason for this is that in consideration of the cutting strength of the welded portion of the tube hanger 46 attached by arc welding or the like, it is necessary to pay close attention to the installation of the tube hanger 46 when the load exceeds 15 t. is there.
At this time, the water filled in the well pipe 14 is screened by the strainer material 38 of the well pipe 14 in the same manner as in the case of water injection into the well pipe 14 by the air pressure feeding into the well pipe 14. The water is discharged into the filter layer F and becomes turbid water and overflows from the filter layer F in the excavation hole 11 to the ground surface. Therefore, the turbid water overflowing to the ground surface is a sand pump installed around the existing well 12. 54 is collected and processed.

Next, in step S22, as shown in FIG. 9, for example, a rough terrain crane (not shown) while air is pumped into the well pipe 14 at a blowing pressure of preferably 1.0 MPa or less, more preferably 0.7 MPa or less. When the lifting and pulling out of the well pipe 14 is continued at a lifting load of preferably 15 t or less, more preferably 5 to 10 t by the crane hook 68, the edge of the well pipe 14 from the ground is generated. Here, when it is confirmed that the well pipe 14 has been cut off from the natural ground, the lifting load is reduced. With the lifting load, the well pipe is connected by a crane hook 68 such as a rough terrain crane (not shown). When the lifting and extracting pipe 14 is carried out and further continued, the well pipe 14 is pulled out little by little from the cutting hole 11 in the ground E. As the extraction of the well pipe 14 progresses, the lifting load decreases. The crane used for this invention is not limited to the said rough terrain crane, A truck crane or a crawler crane may be sufficient.
Next, in step S24, as shown in FIG. 9, the lifting load of the well pipe 14 by the crane hook 68 is about the weight of the well pipe 14 itself, for example, preferably 150% or less of the weight of the well pipe 14 itself. Load), it is determined that the weight of the well pipe 14 itself is about the weight, and the pumping of the air into the well pipe 14 is stopped, and the lifting and pulling of the well pipe 14 by the crane hook 68 is continued. In this way, the pipe is pulled out until a predetermined position of the casing pipe 32 of the well pipe 14 (cutting position determined according to the length of the well pipe 14 and the size of the construction yard) comes out on the ground surface of the ground E.
That is, in steps S22 and S24, buoyancy is generated by the air pressure, and the load of lifting and extracting the well pipe 14 by the crane, so-called lifting load, is reduced. The supply of air is stopped at the drawing load of the well pipe 14 by the crane.

Next, in step S26, as shown in FIG. 10, up to a predetermined position of the casing pipe 32 of the well pipe 14 comes out on the ground E, but before the strainer pipe 34 of the well pipe 14 comes out on the ground, The re-continuation of lifting and extracting the well pipe 14 by the crane hook 68 is stopped. Note that the evacuation may be continued until the strainer pipe 34 of the well pipe 14 comes out on the ground. When the winding screen part of the strainer pipe 34 of the well pipe 14 is exposed to the ground, the water injected by the air pressure and the muddy water containing the water are scattered or pushed out from the winding screen part.
After this, the kanzashi 70 is attached to the casing pipe 32 of the well pipe 14, and the kanzashi 70 supports the well pipe 14 on the ground surface of the ground E to prevent the well pipe 14 from falling into the excavation hole 11. At this time, it is preferable to remove the water injection hose 56 and the air hose 62 from the water injection port 44a and the air injection port 44b of the tube closing cover 44, respectively.
Next, in step S28, as shown in FIG. 10, the casing tube 32 is gas-cut by a gas fusing machine (not shown) at the cutting position P above the casing 70 of the casing tube 32.

Here, the Kanzashi 70 is for making a hole (not shown) in the well pipe 14 of the existing well 12 and inserting the hole into the opened hole so that the well pipe 14 is skewered. The Kanzashi 70 may be anything as long as the well tube 14 can be supported in a skewered state, and for example, a square pipe or H-shaped steel can be used.
In addition, without pulling out the well pipe 14 at a time, the casing pipe 32 is once pulled out, and the casing pipe 32 is cut out again. The reason why the long pipe such as the long well pipe 14 is handled is as follows: Special care must be taken to avoid contact with surrounding structures in the construction yard due to overloading. Therefore, in consideration of prevention of contact with surrounding structures of the construction yard due to turning or load fluctuation, the risk of contact or the like can be reduced with a short object. Moreover, the crane used for extubation can also be handled by a small crane, and the suspension work of a long object such as a long pipe can be reduced.

Next, in step S30, the cut well pipe 14 with strainer 70 (strainer pipe 34) is re-extracted using a crane, for example, a rough terrain crane (not shown), and the well pipe 14 is completely removed from the borehole 11. To complete the extubation. At this time, before the tube is extracted by the crane, the tube-extracting jig 46 is re-welded and attached to the cut well pipe 14 with the Kanzashi 70, and the tube-extracting wire 66 is passed through the hole 46a of the tube-extracting jig 46, or A hole (not shown) is made in the cut well pipe 14 with the Kanzashi 70, and the extubation wire 66 is passed through the hole, and the extubation wire 66 is engaged with the crane hook 68.
Next, in step S32, after completion of the extraction of the well pipe 14, the excavation hole 11 from which the well pipe 14 has been extracted is backfilled, and the existing well extraction process of the present invention is completed.
In the above-described example, the excavation hole 11 from which the well pipe 14 has been extracted is backfilled after completion of the extraction of the well pipe 14, but the present invention is not limited to this, and the extraction of the well pipe 14 is not limited to the well pipe 14. Stopping halfway, boring (not shown) an injection hole (not shown) communicating with the excavation hole 11 beside or around the excavation hole 11 of the existing well 12, and injecting the injection agent from the injection hole to refill it. May be repeated.
In the above-described example, the well pipe 14 is once withdrawn halfway, the casing pipe 32 is cut, and the pipe is drawn again. However, the present invention is not limited to this, and the length of the well pipe 14 of the existing well 12 is increased. If the length of the construction yard is not so long compared to the size of the surrounding structure or the surrounding structure, or if the construction yard is wide and the surrounding structure is not obstructive Ordinarily, the well pipe 14 may be pulled out at once or at a stretch, and may be backfilled after being drawn out.

  As described above, the method for extruding an existing well according to the present invention has been described in detail with reference to various embodiments and examples. However, the present invention is not limited to these embodiments and examples, and the gist of the present invention. Of course, various improvements or changes may be made without departing from the scope of the invention.

DESCRIPTION OF SYMBOLS 10 Groundwater level lowering device 12 Existing well 14 Well pipe 16 Well cover 18 Pumping pump 20 Pumping pipe 22 Flow control valve 24 Pumping tank 26 Vacuum pump 28 Intake hose 30 Water injection pipe for cleaning 32 Casing pipe 34 Strainer pipe 36 Catchment pipe 38 Strainer material 40 Sand reservoir 42 Water passage hole 44 Exhaust tube closing lid 44a Water injection port 44b Air injection port 44c Confirmation port 46 Exhaust tube hanging jig 46a Hole 48 Washing hose 50 Washing water tank 52 Washing pump 54 Sand pump 56 Injection water hose 58 Injection water tank 60 Water injection pump 62 Air hose 64 Compressor 66 Extubation wire 68 (Crane) Hook 70 Kanzashi E Ground F Filter layer

Claims (18)

In the construction yard, a method for extruding an existing well that extrudes a well pipe buried in an existing well formed in the ground,
The well pipe has a casing pipe and a strainer pipe having a strainer material on its outer periphery,
Between the inner periphery of the borehole of the existing well and the outer periphery of the well pipe, it has a filter layer containing pebbles and gravel,
Remove the pumping equipment installed inside and outside the well pipe of the existing well,
At the upper end portion of the well pipe, a drainage closing lid and a drainage pipe hanging jig provided with a water inlet and an air inlet are attached,
A water hose is attached to the water injection port, water is injected into the well pipe, and the water injection is stopped after the strainer material of the well pipe is injected and washed,
A water injection line is connected to the water injection port, an air injection line is connected to the air injection port, the extubation hanging jig and the crane are connected by an extubation wire,
Water is poured into the well pipe from the water inlet to fill the well pipe and stop the water injection,
While pumping air from the air inlet into the well pipe, the pipe is lifted via the pipe for pulling out by the crane to start the pipe extraction of the well pipe,
After cutting the well pipe from the natural ground, the pipe is further lifted by the crane to continue the pipe extraction of the well pipe,
After it is determined that the lifting load of the well pipe by the crane is the weight of the well pipe itself, the pumping of the air into the well pipe is stopped, and then the well pipe is lifted by the crane. The method of extruding an existing well is characterized by continuing the process and excluding the well pipe.   The method of extracting a well from an existing well according to claim 1, wherein the strainer material is a winding screen or a slit screen.   3. The existing well draining method according to claim 1, wherein the pumping equipment is a well lid, a flow rate adjusting valve, a water injection pipe, a pumping pipe, and a pumping pump. One end of the washing hose is attached to the water injection port, and the other end of the washing hose is attached to a washing pump disposed in the construction yard near the existing well,
The water injection cleaning of the strainer material of the well pipe is performed by driving the cleaning pump, and the strainer material of the well pipe is discharged and cleaned from the strainer material. The extubation method for the existing well according to claim 1.   The method for extruding an existing well according to claim 4, wherein a water injection pressure in the water injection cleaning is 1.0 MPa or less. One end of the water injection line is connected to the water injection port, and the other end of the water injection line is connected to a water injection pump installed in a water injection tank disposed in the construction yard near the existing well,
6. The existing well draining method according to any one of claims 1 to 5, wherein the water injection from the water injection port into the well pipe by the water injection line is performed by driving the water injection pump.   The method for extruding an existing well according to claim 6, wherein a water injection pressure of the water injection by the water injection line is 1.0 MPa or less. The draining closure lid further has a confirmation window for confirming the state of the existing well in the well pipe,
The water injection according to any one of claims 1 to 7, wherein the water injection by the water injection line is stopped after the confirmation window confirms that the inside of the well pipe has become full due to the water injection by the water injection line. Extubation method for existing wells. One end of the air injection line is connected to the air injection port, and the other end of the air injection line is connected to a compressor disposed in the construction yard near the existing well,
The existing well according to any one of claims 1 to 8, wherein the air is pumped from the air inlet into the well pipe by the air injection line by driving the compressor and blowing air. Extubation method.   The method for extruding an existing well according to claim 9, wherein the blowing pressure by driving the compressor is 1.0 MPa or less. The draining closure lid further has a confirmation window for confirming the state of the existing well in the well pipe,
The lifting and unloading of the well pipe by the crane is started after the confirmation window confirms that the well pipe has been cut off from the natural ground by the air pumping of the air injection line. The extubation method of the existing well of any one of 1-10.   In at least one of the water injection cleaning, the water injection by the water injection line, and the air pumping by the air injection line, the turbid water overflowing from the filter layer in the excavation hole of the existing well to the ground is The pipe extraction method of the existing well of any one of Claims 1-11 collect | recovered and processed with the sand pump arrange | positioned in the said construction yard of the vicinity of a well.   The said extubation hanging jig is welded and attached to the lower side of the flange part of the upper end of the said casing pipe of the said well pipe, and is connected to the hook of the said crane by the said extubation wire. The method for extruding an existing well as described in item 1.   14. The method of extracting an existing well according to claim 13, wherein a lifting load when the well pipe is extracted by the crane is 15 t or less.   The said well crane is a rough terrain crane, a truck crane, or a crawler crane, The extubation method of the existing well of any one of Claims 1-14.   The determination that the weight is the weight of the well pipe itself is made when a lifting load at the time of extracting the well pipe becomes 150% or less of the weight of the well pipe before being installed in the existing well. The extubation method of the existing well of any one of 1-15. Further, the re-continuation of the lifting and pulling of the well pipe by the crane is stopped before the strainer pipe of the well pipe comes out on the ground, and a Kanzashi is attached to the casing pipe of the well pipe so that the well pipe is dropped. Prevent,
Cutting the casing tube by a gas fusing machine in the upper part of the casing tube than the Kanzashi,
Re-extracting the cut well pipe with the Kanzashi, and extracting the well pipe from the excavation hole to complete the extubation,
The method of extracting a well from any one of claims 1 to 16, wherein the excavation hole from which the well tube has been extracted is backfilled.   The lifting and unloading of the well pipe by the crane is stopped in the middle of the well pipe 1, an injection hole communicating with the drilling hole is drilled beside or around the drilling hole, and an injection is injected from the injection hole. The extubation method for an existing well according to any one of claims 1 to 17, wherein refilling is repeated.