JP3623788B2 - Contaminated soil improvement method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for improving contaminated soil.
[0002]
[Prior art]
Conventionally, as a method for improving the contaminated soil of contaminated ground, for example, there is a method for improving contaminated soil performed in the following work procedure.
[0003]
(1) Earth retaining and impermeable work
A soil retaining and impermeable wall is constructed so as to surround a predetermined section of the contaminated ground.
[0004]
At this time, the earth retaining / water-impervious wall is a closed wall body in which a number of wall-forming pieces such as steel sheet piles are built to the required depth in the ground and are continuously built around the surrounding area to surround a predetermined section. Form.
[0005]
In this way, both the soil retaining function and the water shielding function can be secured by the soil retaining wall.
[0006]
(2) Pumping / pumping
Excavate contaminated soil in a section surrounded by earth retaining and impervious walls, and discharge contaminated soil and contaminated groundwater to the ground (landing and pumping).
[0007]
At this time, the depth of the contaminated soil to be excavated is set such that the surrounding ground can be prevented from collapsing by the earth retaining and water-impervious walls formed in the above process.
[0008]
(3) Retaining and water-impervious reinforcement work
When increasing the depth of the borehole formed by excavation by the above-mentioned pumping / pumping work, a bellows extending in the lateral direction is attached to the inner surface of the wall body in the borehole, A reinforcing machine frame is constructed by interposing a plurality of beam members extending in the lateral direction between opposing wall forming pieces in a lattice shape in a state of stretching in the front-rear and left-right directions.
[0009]
(4) The above operations (2) and (3) are repeated until the required depth is reached.
[0010]
(5) Bottom water stop work
The bottom plate of the hole formed by excavating to the required depth is water-stopped.
[0011]
(6) Purification treatment
Purify the contaminated soil and groundwater discharged to the ground.
[0012]
(7) Backfilling
The treated soil and treated groundwater purified on the ground are refilled in the pit.
[0013]
(8) Removal work
The structural members that make up the earth retaining and impermeable walls will be removed sequentially as the backfilling progresses.
[0014]
[Problems to be solved by the invention]
However, the above-mentioned method for improving contaminated soil is a method in which both the contaminated soil and the contaminated groundwater are once pumped and pumped to the ground, and the contaminated soil and the contaminated groundwater are purified on the ground, and then the purified treatment Since it is based on the technical idea of backfilling the soil and treated groundwater into the pit, there is a problem that the earth retaining / water-impervious work, the earth retaining / water-impervious reinforcement work, and the bottom-floor water stop work are time-consuming.
[0015]
In other words, in order to pump up and pump up contaminated soil and contaminated groundwater, it is necessary to perform soil retaining and water shielding works to prevent the collapse of the ground around the pit and the infiltration of groundwater, as well as excavation. As the depth of the pit increases, the soil pressure around the pit and the water pressure of the groundwater increase, so it is necessary to carry out soil retaining and water-impervious reinforcement works to counter this.
[0016]
At this time, the earth retaining / water-impervious reinforcement work has a problem that it takes a lot of labor since an operator enters the pit and has to be performed manually.
[0017]
In addition, after the earth retaining and reinforcement work, there is a need to carry out the earthing and pumping work between the beam members installed in a lattice in the wall. There is a problem that the size of the machine is limited and work efficiency cannot be increased.
[0018]
Furthermore, there is a problem that the urging material and the beam material used for the earth retaining / reinforcing work must be sequentially removed in accordance with the progress of the backfilling work, and the removal work requires time and effort.
[0019]
[Means for Solving the Problems]
Therefore, in the present invention, a soil wall at a certain depth is constructed in a closed state in the contaminated ground, a certain range of the ground is surrounded by the soil retaining wall, and the ground surrounded by the soil retaining wall is excavated, By discharging all or most of the excavated contaminated soil to the ground, a pit is formed in the earth retaining wall, and contaminated groundwater is retained in the pit, and the discharged contaminated soil is improved on the ground. Contaminated groundwater and excavated soil left in the pit are cleaned while the soil is treated, and then the treated soil improved on the ground is backfilled in the pit. A soil improvement method is provided.
[0020]
The present invention is also characterized by the following configuration.
[0021]
(1) Constructing a closed wall with a certain depth in the contaminated ground, surrounding a certain area of the ground with the retaining wall, and excavating the ground surrounded by the retaining wall By discharging all or most of the contaminated soil to the ground, a step of forming a pit in the retaining wall, a step of retaining contaminated groundwater in the pit, and the steps to the required depth After repeating the process until it reaches, the process of improving the contaminated soil discharged on the ground and the contaminated groundwater remaining in the pit and the excavated soil remaining in the pit are purified in the pit. And a step of backfilling the treated soil improved on the ground in the pit.
[0022]
(2) Excavating the contaminated ground and discharging the contaminated soil to the ground to form a pit that does not naturally collapse, and to build a retaining wall close to the periphery of the pit, and the retaining wall Excavating contaminated soil in the soil and discharging all or most of the excavated contaminated soil to the ground, forming a pit in the retaining wall, and retaining contaminated groundwater in the pit After repeating these processes until the required depth is reached, the process of improving the contaminated soil discharged on the ground and the contaminated groundwater remaining in the pit and left in the pit A step of purifying the excavated soil in the pit, and a step of filling the treated soil improved on the ground back into the pit.
[0023]
(3) The contaminated ground is excavated to a certain depth to discharge the contaminated soil to the ground, and the discharged soil is improved on the ground, while the groundwater contaminated in the pits formed in the ground is removed. It is allowed to stay, and the same hole is further drilled to a predetermined depth, and the contaminated excavated soil and the contaminated groundwater are purified while being mixed in the pothole, and then the soil that has been improved on the ground is potted. Backfill inside.
[0024]
(4) The retaining wall is built up to a predetermined depth in the contaminated ground, and a certain area of the ground is surrounded by the retaining wall, and the ground up to a certain depth surrounded by the retaining wall is excavated. By discharging all or most of the excavated contaminated soil to the ground, a pit is formed in the earth retaining wall, and contaminated groundwater is retained in the pit, and the discharged contaminated soil is discharged to the ground. On the other hand, the remaining ground up to a predetermined depth surrounded by the retaining wall is excavated, and the contaminated excavated soil and the contaminated groundwater are purified while being mixed in the pit, and then the ground surface Refill the treated soil that has been improved in step 1 into the pit.
[0025]
(5) The retaining wall is built up to a certain depth in the contaminated ground, and a certain area of the ground is surrounded by the retaining wall, and the ground to the certain depth surrounded by the retaining wall is excavated. By discharging all or most of the excavated contaminated soil to the ground, a pit is formed in the earth retaining wall, and contaminated groundwater is retained in the pit, and the discharged contaminated soil is discharged to the ground. On the other hand, after or after constructing the retaining wall in a closed state to a predetermined depth, excavate the ground to a predetermined depth and knead the contaminated excavated soil and the contaminated groundwater in the pit. Clean up the soil, and then return the treated soil improved on the ground to the pit.
[0026]
(6) When the soil improved on the ground is backfilled in the potholes, the soil that has been improved is backfilled while gradually moving upward from the bottom of the potholes, and in the soil and the potholes. Kneading excavated soil and groundwater that have been purified.
[0027]
(7) The retaining wall shall be removed while the treated soil improved on the ground is backfilled in the pit or after backfilling.
[0028]
(8) The retaining wall has an outer shape of a rectangular cylinder.
[0029]
(9) The retaining wall is provided with corner soil cutting means, and the soil in the corner of the retaining wall can be cut by the corner soil cutting means.
[0030]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below.
[0031]
That is, in the contaminated soil improvement method according to the present invention, the retaining wall at a certain depth is constructed in a closed state in the contaminated ground, and a certain range of the ground is surrounded by the retaining wall, and is surrounded by the retaining wall. By excavating the ground and discharging all or most of the excavated contaminated soil to the ground, a pit is formed in the earth retaining wall, and contaminated groundwater is retained in the pit and the discharged pollution. The soil is improved on the ground, while the contaminated groundwater and the excavated soil left in the pit are purified in the pit, and then the treated soil improved on the ground is backfilled in the pit. I am doing so.
[0032]
More specifically, in the contaminated soil improvement method according to the present invention, a soil wall at a certain depth is constructed in a closed state in the contaminated ground, and a certain range of the ground is surrounded by the soil wall; By excavating the ground surrounded by the retaining wall and discharging all or most of the excavated contaminated soil to the ground, a process of forming a pit in the retaining wall and groundwater contaminated in the retaining wall , The process of improving the contaminated soil discharged on the ground after repeating these processes until reaching the required depth, and the contaminated groundwater and pits remaining in the pit A step of purifying the excavated soil left inside in the pit, and a step of filling back the treated soil improved on the ground in the pit.
[0033]
In addition, the contaminated soil improvement method as another embodiment according to the present invention forms a pit that does not naturally collapse by excavating the contaminated ground and discharging the contaminated soil to the ground, and surroundings of the pit The construction of the retaining wall close to the ground, and excavating the contaminated soil in the retaining wall, and discharging all or most of the excavated contaminated soil to the ground, forming a pit in the retaining wall A process, a process of retaining contaminated groundwater in the same hole, a process of repeating these processes until reaching the required depth, and a process of improving the contaminated soil discharged on the ground, A process of purifying contaminated groundwater and excavated soil remaining in the pit in the pit, and a step of refilling the treated soil improved on the ground in the pit. ing.
[0034]
Furthermore, in the contaminated soil improvement method as another embodiment according to the present invention, the contaminated ground is excavated to a certain depth to discharge the contaminated soil to the ground, and the discharged soil is improved on the ground. On the other hand, contaminated groundwater is retained in the pit formed in the ground, the pit is further drilled to a predetermined depth, and the contaminated excavated soil and contaminated groundwater are mixed and purified in the pit. After that, the soil that has been improved on the ground is backfilled in the pit.
[0035]
Specifically, the retaining wall is built up to a predetermined depth in the contaminated ground, and a certain area of the ground is surrounded by the retaining wall, and the ground to the certain depth surrounded by the retaining wall is By excavating and discharging all or most of the excavated contaminated soil to the ground, a pit is formed in the retaining wall, and contaminated groundwater is retained in the pit and the discharged contaminated soil is While improving on the ground, excavating the remaining ground up to a predetermined depth surrounded by the retaining wall, purifying the contaminated excavated soil and contaminated groundwater while kneading in the pit, then The treated soil improved on the ground is backfilled in the potholes.
[0036]
Furthermore, in the contaminated soil improvement method according to the present invention, the retaining wall is constructed in a closed state to a certain depth in the contaminated ground, and a certain range of the ground is surrounded by the retaining wall, and is surrounded by the retaining wall. By excavating the ground up to a certain depth and discharging all or most of the excavated contaminated soil to the ground, a pit is formed in the earth retaining wall and contaminated groundwater is retained in the pit. In addition, the discharged contaminated soil is improved on the ground, while the earth retaining wall is further closed or built to a predetermined depth, and the ground is excavated to a predetermined depth, and the contaminated excavated soil and the contaminated soil are contaminated. The treated groundwater is purified while being kneaded in the pothole, and then the treated soil improved on the ground is returned to the pothole.
[0037]
And when the above-mentioned contaminated soil improvement construction method backfills the soil improved on the ground into the pit, it is backfilled while gradually moving the improved soil upward from the bottom in the pit. The soil is kneaded with the excavated soil and groundwater purified in the pit.
[0038]
Further, in the above-described contaminated soil improving method, the retaining wall is removed while the treated soil improved on the ground is backfilled in the pit or after being backfilled.
[0039]
In addition, the retaining wall is formed in a rectangular cylindrical shape, and includes corner soil cutting means, and the soil in the corner of the retaining wall can be cut by the corner soil cutting means.
[0040]
【Example】
Embodiments of the present invention will be described below with reference to the drawings.
[0041]
FIG. 1 is a process explanatory diagram of a contaminated soil improvement method as a first embodiment according to the present invention. The gist of the contaminated soil improvement method according to the present invention is a retaining wall 1 having a certain depth in a contaminated ground G. Is constructed in a closed state, surrounding a certain range of the ground G by the retaining wall 1, excavating the ground G surrounded by the retaining wall 1, and excavating contaminated soil (hereinafter referred to as “contaminated soil”) ) By discharging all or most of g1 to the ground, a pit H is formed in the earth retaining wall 1 and contaminated groundwater (hereinafter referred to as “contaminated groundwater”) W1 is retained in the pit H. The discharged contaminated soil g1 is improved on the ground, while the contaminated groundwater W1 is purified in the pit H, and then the improved soil (hereinafter referred to as “treated soil”) g2 is put in the pit H. There is to backfill.
[0042]
Here, the retaining wall 1 only needs to have a strength sufficient to resist the earth pressure at a required depth, and is constructed by variously retaining the retaining wall 1 (for example, steel sheet piles or the like). The retaining wall, the retaining wall that is constructed by forming a continuous wall by ground improvement, the retaining wall that is constructed by building a cylindrical casing body, etc.) can be used as appropriate.
[0043]
And the fixed range of the contaminated ground G surrounded by the retaining wall 1 can be set broadly or narrowly according to the working conditions and the like, and if it is set narrowly, the improvement work is continued. Thus, the required range of the contaminated ground G can be reliably improved.
[0044]
Below, the structure of the contaminated soil improvement apparatus A (refer FIG. 1) used for the contaminated soil improvement construction method as 1st Example is demonstrated first, and the 1st carried out using the same contaminated soil improvement apparatus A following it. The contaminated soil improvement construction method as an example will be described.
[0045]
And the transformation example of the retaining wall 1 as a part of the contaminated soil improvement apparatus A is demonstrated, Then, the drilling body 11 as 2nd Example used for the contaminated soil improvement construction method as 2nd Example is demonstrated. Subsequently, the contaminated soil improvement method as the second embodiment performed using the drilled body 11 will be described, and then the contaminated soil improvement method as the third embodiment will be described.
[0046]
[Description of Contaminated Soil Improvement Device as First Example]
As shown in FIG. 1, a contaminated soil improvement apparatus A as a first embodiment drills a rectangular cylindrical retaining wall 1 to be built in a contaminated ground G and a contaminated soil g1 in the retaining wall 1. The soil discharging means 2 for discharging to the ground, the soil improvement processing means 3 for improving the contaminated soil g1 discharged to the ground by the soil discharging means 2, and the ground G being drilled and formed by the soil discharging means 2 The groundwater purification process means 4 for retaining the contaminated groundwater W1 in the pothole H and purifying the contaminated groundwater W1 in the pothole H, and the groundwater purified by the groundwater purification process means 4 (hereinafter “treated groundwater”). The backfilling means 5 for backfilling the treated soil g2 improved by the soil improvement processing means 3 and backfilling the treated soil g2 by the backfilling means 5 in the pit H where the W2 stays. Or soil After backfilling the treated soil g2 in the wall 1, and a pull-out means 6 is pulled out of the same earth retaining wall 1 from the ground G.
[0047]
As shown in FIGS. 3 to 5, the retaining wall 1 includes a retaining wall main body 7 formed in a rectangular tube shape extending in the vertical direction, and corner soil cutting means provided at an inner lower portion of the retaining wall main body 7. A corner soil cutting blade 8 is provided.
[0048]
The corner soil cutting blade body 8 includes a cutting blade main piece 8 a formed along the lower end edge of the retaining wall body 7 and a cutting soil inside formed along the lower inner peripheral surface of the retaining wall body 7. The cutting soil inner side approaching piece 8b is formed with a curved inner side approaching guide surface 8c, and the soil cut by the cutting blade main piece 8a is formed on the inner approaching guide surface 8c. Along with this, a drilling body 11 to be described later is brought within a circular drilling range Z that can be drilled.
[0049]
In this way, the soil in the corner of the retaining wall body 7 formed in the shape of a rectangular cylinder is cut by the corner soil cutting blade 8 and within the circular drilling range Z in which the drilling body 11 can drill. Therefore, when the ground G surrounded by the retaining wall 1 is excavated by the drilling body 11 to be described later and the contaminated soil g1 is discharged to the ground, the contaminated soil g1 at the corner which is difficult to excavate. In addition, it can be cut easily and reliably and moved toward the inside, and can be discharged by the holed body 11. As a result, the entire inside of the retaining wall 1 can be quickly and surely made into the hole H.
[0050]
The shape of the retaining wall 1 is not limited to a rectangular tube shape, but may be a polygonal shape such as a hexagonal tube shape.
[0051]
The retaining wall 1 is constructed by a construction device (not shown) at a predetermined position of the ground G to be improved.
[0052]
As shown in FIG. 1A, the soil discharging means 2 has a drilling body 11 detachably attached to the base machine 10.
[0053]
The base machine 10 includes a self-propelled base machine main body 12 provided with a leader 13 extending in the vertical direction. A motor support 14 is attached to the reader 13 so as to be movable up and down, and a driving motor 15 is attached to the motor support 14. Is mounted on the driving motor 15 in an up-down direction so as to be detachable via a counter-rotating gear mechanism 17, and the drilling body 11 is attached to the lower end of the excavating shaft 16. Is attached.
[0054]
Further, as shown in FIG. 2, the excavation shaft body 16 is formed by extending in the vertical direction so as to surround the outer periphery of the cylindrical inner shaft 18 and the inner shaft 18 that are formed by extending in the vertical direction. The cylindrical outer shaft 19 forms an inner / outer double shaft structure, and the inner shaft 18 and the outer shaft 19 are mutually rotated around the same axis by a drive motor 15 via a counter rotating gear mechanism 17. To rotate in the opposite direction.
[0055]
And as shown in FIG.2 and FIG.3, while forming the processed soil supply path 20 in the inner side axis | shaft 18, while making the lower end opening part of the inner side axis | shaft 18 into the processed soil discharge part 21, the inner side axis | shaft A plurality of purifying material discharge sections 23 that communicate with the purifying material supply path 22 at the lower end of the outer shaft 19, by forming a purifying material supply path 22 between the outer peripheral surface of 18 and the inner peripheral surface of the outer shaft 19; 23 is provided.
[0056]
Furthermore, as shown in FIG. 2, the inner and outer shafts 18 and 19 are each formed into a so-called bamboo shoot cylinder shape that expands and contracts in three stages, and can be expanded and contracted in the axial direction. 19a is a first outer shaft forming piece, 19b is a second outer shaft forming piece, and 19c is a third outer shaft forming piece.
[0057]
Further, as shown in FIGS. 2 and 3, the tip end portion 18a of the inner shaft 18 is extended downward from the third outer shaft forming piece 19c, and the inner shaft mounting stirring blade 24 is radiated to the tip end portion 18a. The inner shaft-attached stirring blade 24 is disposed in the hole drilling body 11 so as to project in the direction (radial direction).
[0058]
As shown in FIG. 2, on the outer peripheral surface of the third outer shaft forming piece 19c, which is the tip of the outer shaft 19, a plurality of outer shaft mounting stirring blades 25 are arranged in the axial direction of the third outer shaft forming piece 19c. Projections are provided in the radial direction (radial direction) at intervals.
[0059]
In this way, in conjunction with the rotation of the inner shaft 18, the inner shaft mounting stirring blade 24 is rotated in the drilling body 11 and the outer shaft 19 is rotated in the direction opposite to the inner shaft 18. In conjunction with this rotation, the outer shaft-mounted stirring blade 25 is rotated at a position above the inner shaft-mounted stirring blade 24.
[0060]
As shown in FIGS. 2 and 3, the drilling body 11 is attached to a cylindrical drilling hole piece 26 and a lower edge of the drilling hole piece 26 via a pivotal support 39 so as to be opened and closed. The bottom forming piece 27 is provided with an excavating blade 28 and an excavating soil intake 29.
[0061]
And the drilling body 11 attaches the drilling hole piece 26 to the outer peripheral surface of the tip part (lower end part) of the above-described third outer shaft forming piece 19c via the attachment arms 30, 30, 30, and The main piece 26 can be rotated integrally with the outer shaft 19 about the axis of the outer shaft 19.
[0062]
In this way, the drilling body 11 is arranged at a position directly above the contaminated soil g1 in the retaining wall 1 built to the ground G to a certain depth, and the drilling shaft body 16 is driven by the driving motor 15 with the drilling shaft body 16. , The contaminated soil g1 in the soil retaining wall 1 is excavated by the excavating blade 28, and the excavated contaminated soil g1 is taken into the drill hole main piece 26 from the excavated soil intake port 29. I can do it.
[0063]
When a predetermined amount of contaminated soil g1 is taken into the drill hole main piece 26, the bamboo shoot cylinder-shaped excavation shaft body 16 is contracted and moved upward by a necessary amount, thereby lowering the lower end of the excavation shaft body 16. The drilling body 11 attached to the section is pulled up to the ground, and the bottom forming piece 27 of the drilling body 11 is opened via the pivotal support 39 to discharge the contaminated soil g1 from the drilling main piece 26. be able to.
[0064]
Therefore, by repeatedly performing the soil discharging operation, as shown in FIG. 1A, the contaminated soil g1 in the retaining wall 1 built up to a certain depth is discharged, and then shown in FIG. 1B. As described above, the retaining wall 1 is further built up to the integrated depth, and the soil discharging operation in the retaining wall 1 by the drilling body 11 is repeatedly performed. By repeatedly performing the soil discharging operation up to a required depth, a pothole H having a required depth can be formed as shown in FIG.
[0065]
Here, as shown in FIG.1 (c), in the earth retaining wall 1 which discharged | emitted the contaminated soil g1, the contaminated groundwater W1 permeates from below and stays.
[0066]
The soil improvement processing means 3 improves the contaminated soil g1 discharged to the ground by the soil discharging means 2, and as shown in FIG. 1 (e), the discharged soil storage for storing the discharged contaminated soil g1 A tank 31, an improvement material supply tank 32 for supplying an improvement material for improving the contaminated soil g1, a mixer 33 for mixing and kneading the improvement material and the contaminated soil g1, and a process for kneading and improving the mixer 33 A treated soil storage tank 34 for storing the finished soil g2 and a pumping pump 35 for pumping the treated soil g2 in the treated soil storage tank 34 are arranged close to each other on the ground.
[0067]
In this way, the discharged contaminated soil g1 is temporarily stored in the discharged soil storage tank 31, and the contaminated soil g1 in the discharged soil storage tank 31 is supplied into the mixer 33, and the improvement material supply tank 32 is supplied. The improved material inside is supplied into the mixer 33, the contaminated soil g1 and the improved material are kneaded by the mixer 33, the contaminated soil g1 is improved to be treated soil g2, and the treated soil g2 is treated. It stores in the processed soil storage tank 34, and the processed soil g2 in the processed soil storage tank 34 is supplied with the pumping pump 35 as needed.
[0068]
Here, as an improvement material, a purification material that purifies soil containing contaminated / hazardous substances can be used, and a solidified material such as cement milk that solidifies soil containing contaminated / hazardous substances can be used. In this embodiment, a case where a purification material is used will be described.
[0069]
As shown in FIG. 1 (d), the groundwater purification treatment means 4 is connected to the improvement material supply tank 32 (containing the purification material in this embodiment) via the purification material supply pipe 37. The purification material supply path 22 formed inside is connected in communication.
[0070]
In this way, in a state where the drilling body 11 is disposed in the vicinity of the surface of the contaminated groundwater W1, the purification material is introduced into the contaminated groundwater W1 from the plurality of purification material discharge portions 23, 23 communicating with the purification material supply path 22. While discharging, the drilling body 11 is rotated through the excavation shaft body 16 and moved to the bottom position of the hole H.
[0071]
At this time, the inner shaft-attached stirring blade 24 projecting from the inner shaft 18 of the excavation shaft body 16 and the outer shaft-attached stirring blade 25 projecting from the outer shaft 19 rotate in opposite directions, respectively, and contaminated groundwater. Since W1 is agitated, the purification material can be uniformly dissolved in the contaminated groundwater W1, and the contaminated groundwater W1 can be purified or rendered harmless. As a result, the contaminated groundwater W1 can be treated as the treated groundwater W2.
[0072]
As shown in FIG. 1 (e), the backfilling unit 5 is configured by connecting the treated soil supply path 20 formed in the excavation shaft body 16 to the pressure feed pump 35 via the treated soil supply pipe 36. doing.
[0073]
In this way, the treated soil supply path formed in the excavated shaft body 16 by the pressure feed pump 35 through the treated soil supply pipe 36 for the treated soil g2 stored in the treated soil storage tank 34. 20 is pumped / supplied into the inside 20 and discharged from the treated soil discharge unit 21.
[0074]
At this time, the discharge of the treated soil g2 from the treated soil discharge unit 21 is performed in a state where the drilling body 11 is located at the bottom of the pit H, as shown in FIG. From the state where the purification treatment work is completed, as shown in FIG. 1 (f), the drilling body 11 is continuously rotated and moved upward, and the treated soil g <b> 2 is backfilled in the pothole H. At the same time, the treated soil g2 and the treated groundwater W2 are kneaded.
[0075]
Thus, the purification treatment work of the contaminated groundwater W1 and the backfilling work of the treated soil g2 can be performed efficiently and continuously.
[0076]
At this time, the treated soil g2 that has been backfilled without overflowing the treated groundwater W2 from the well H by mixing with the treated groundwater W2 while gradually refilling the treated soil g2 from the bottom of the well H. Can be reliably kneaded.
[0077]
Therefore, when the treated groundwater W2 overflows from the pit H, the overflowed treated groundwater W2 must be treated, but the work of such work can be saved, and as a result, the contaminated soil improvement treatment work Can be performed efficiently.
[0078]
As shown in FIG. 1 (g), the pulling means 6 connects the retaining wall 1 to the base machine 10 via a hanging wire 38, thereby pulling the retaining wall 1 upward from the ground G by the base machine 10. To be able to.
[0079]
At this time, the extraction work of the retaining wall 1 can be performed while the treated soil g2 is backfilled by the backfilling means 5 as described above, or after the treated soil g2 is backfilled in the retaining wall 1.
[0080]
[Description of Contaminated Soil Improvement Method as First Example]
Next, the contaminated soil improvement construction method for performing the contaminated soil improvement work by the contaminated soil improvement apparatus A as the first embodiment configured as described above will be described with reference to FIG.
[0081]
That is, the contaminated soil improvement method as the first example is [construction process], [soil discharge process], [soil improvement treatment process], [groundwater purification treatment process], [backfill process], and [drawing process]. It consists of.
[0082]
(1) [Embedded process]
The erection process is a process in which the retaining wall 1 at a certain depth is constructed in a closed state in the contaminated ground G, and a certain range of the ground G is surrounded by the retaining wall 1.
[0083]
In other words, the erection process is a process of erected a square cylindrical retaining wall 1 on the ground G, and the erected wall 1 is erected at a predetermined position of the ground G to be improved by an erection device (not shown). (See FIG. 1 (a)).
[0084]
(2) [Soil discharge process]
The soil discharging step is a step of excavating the ground G surrounded by the retaining wall 1 and discharging all or most of the excavated contaminated soil g1 to the ground, thereby forming a pit H in the retaining wall 1. is there.
[0085]
That is, in the soil discharging step, as shown in FIG. 1A, a drilling body 11 is arranged at a position immediately above the contaminated soil g1 in the earth retaining wall 1 built in the ground G up to a certain depth, The body 11 is rotated by the drive motor 15 through the excavation shaft body 16 to excavate the contaminated soil g1 in the soil retaining wall 1 with the excavating blade 28 and the excavated soil g1 to the excavated soil intake port. 29, when the predetermined amount of contaminated soil g1 is taken into the drilling body 11, the excavation shaft body 16 is contracted and the drilling body 11 is positioned above the ground surface. The drilling body 11 attached to the lower end portion of the excavation shaft body 16 is lifted to the ground by moving it up to the height required to cause the contaminated soil g1 to be discharged from the drilling body 11. Yes.
[0086]
Then, as shown in FIG. 1B, after the retaining wall 1 is further built to a certain depth, the contaminated soil g1 in the retaining wall 1 is discharged, so that the retaining wall 1 becomes a pit H. I have to.
[0087]
In such a process, the contaminated groundwater W1 naturally enters and stays in the pit H, and naturally, the process includes a process of retaining the contaminated groundwater W1.
[0088]
(3) [Soil improvement treatment process]
The soil improvement treatment step is a step of improving the contaminated soil g1 discharged to the ground after repeatedly performing the above-described steps until reaching a required depth.
[0089]
That is, in the soil improvement processing step, as shown in FIGS. 1B and 1E, the discharged contaminated soil g1 is temporarily stored in the discharged soil storage tank 31, and the contaminated soil in the discharged soil storage tank 31 is stored. While supplying the soil g1 into the mixer 33, the improvement material (purification material in this embodiment) in the improvement material supply tank 32 is supplied into the mixer 33, and the contaminated soil g1 and the improvement material are kneaded by the mixer 33. Thus, the treated soil g2 is formed by the improvement treatment, and the treated soil g2 is stored in the treated soil storage tank 34.
[0090]
And the processed soil g2 in the processed soil storage tank 34 is supplied with the pumping pump 35 as needed.
[0091]
(4) [Groundwater purification treatment process]
The groundwater purification treatment step is a step of purifying the contaminated groundwater W1 staying in the pit H formed by discharging the contaminated soil g1 in the retaining wall 1 in the pit H.
[0092]
That is, in the groundwater purification treatment step, as shown in FIG. 1 (d), a plurality of purification material discharge sections communicating with the purification material supply path 22 in a state where the drilling body 11 is disposed near the water surface of the contaminated groundwater W1. While the purifying material is discharged into the contaminated groundwater W <b> 1 from 23 and 23, the drilling body 11 is rotated through the excavation shaft body 16, and is settled and moved to the bottom position of the borehole H.
[0093]
At this time, the inner shaft-attached stirring blade 24 projecting from the inner shaft 18 of the excavation shaft body 16 and the outer shaft-attached stirring blade 25 projecting from the outer shaft 19 rotate in opposite directions, respectively, to contaminate the groundwater W1. Because of the agitation, the purification material can be uniformly dissolved in the contaminated groundwater W1, and the contaminated groundwater W1 can be reliably purified or neutralized to be detoxified. As a result, the contaminated groundwater W1 can be treated as the treated groundwater W2.
[0094]
(5) [Backfill process]
The backfilling step is a step of backfilling the treated soil g2 in the pit H and kneading with the treated groundwater W2.
[0095]
That is, in the backfilling step, the treated soil g2 stored in the treated soil storage tank 34 is formed in the excavated shaft body 16 by the pumping pump 35 via the treated soil supply pipe 36. It is a step of pumping and supplying into the supply path 20 and discharging the processed soil supply path 20 from the processed soil discharge section 21 connected to the terminal section.
[0096]
And the discharge of the processed soil g2 from the processed soil discharge part 21 is the state which located the drilling body 11 in the bottom part of the pit H, as shown in FIG.1 (e), ie, purification | cleaning of the contaminated groundwater W1 From the state where the treatment work is completed, as shown in FIG. 1 (f), the drilling body 11 is gradually rotated and moved upward to refill the treated soil g2 in the pit H, The treated soil g2 and the treated groundwater W2 are kneaded.
[0097]
Thus, the treated groundwater W2 is backfilled without overflowing the treated groundwater W2 from the wellhole H by mixing with the treated groundwater W2 while gradually refilling the treated soil g2 from the bottom of the well H. It can be reliably kneaded with the soil g2.
[0098]
(6) [Pulling process]
The drawing step is a step of pulling out the soil retaining wall 1 from the ground G while backfilling the treated soil g2 in the above-described backfilling step or after backfilling the treated soil g2 in the soil retaining wall 1.
[0099]
That is, in the drawing process, as shown in FIG. 1 (g), the retaining wall 1 is connected to the base machine 10 via the hanging wire 38, so that the retaining wall 1 is moved upward from the ground G by the base machine 10. This is a drawing process.
[0100]
And, as shown in FIG. 6, by continuously forming such columnar treated soil g2 in the ground G, the ground G can be improved with high accuracy and efficiency.
[0101]
At this time, since the outer wall of the retaining wall body 7 is formed in the shape of a square cylinder, the retaining wall 1 is formed so that the side surfaces 7a, 7a of the neighboring retaining wall bodies 7, 7 are brought into surface contact with each other. By continuously building the wall 1 without overlapping the preceding retaining wall 1, the work for improving the contaminated soil g1 can be efficiently performed without duplication.
[0102]
Moreover, as shown in FIG. 6 (a), after the three retaining walls 1, 1, 1 are continuously built, the first retaining wall 1 is pulled out as shown in FIG. 6 (b). Thus, by continuously building the fourth retaining wall 1 adjacent to the third retaining wall 1, the three retaining walls 1, 1, 1 can be used repeatedly and continuously. Can be efficiently performed.
[0103]
[Description of the retaining wall as a first transformation example]
7 to 9 show a retaining wall 1 as a first modification example. The retaining wall 1 has the same basic structure as the retaining wall 1 as the first embodiment described above, but has a corner. In addition to the partial soil cutting blade body 8, the difference is that cutting nozzles 40, 40, 40, 40 are disposed in the four corners at the bottom of the retaining wall body 7, respectively.
[0104]
That is, as shown in FIGS. 7 to 9, the nozzle placement recess 41 is formed in the portion of the cutting soil inner side approaching piece 8 b located at the corner of the retaining wall body 7, and the nozzle placement recess 41 is formed in the nozzle placement recess 41. The cutting nozzle 40 is disposed, the ejection hole 40a of the cutting nozzle 40 is disposed downward, the distal end portion of the high pressure water supply pipe 42 is connected to the base end portion of the cutting nozzle 40, and The high-pressure water supply pipe 42 is extended upward along the corners of the retaining wall body 7, and the base end portion of the high-pressure water supply pipe 42 is disposed on the ground. Reference numeral 49 denotes a pipe guide.
[0105]
In this way, by supplying high-pressure water from the ground to the cutting nozzle 40 through the high-pressure water supply pipe 42, the high-pressure water Wa is ejected from the ejection hole 40a of the cutting nozzle 40, and the contamination located immediately below is discharged. The soil g1 can be cut by water pressure.
[0106]
Therefore, when the retaining wall 1 is built, the contaminated soil g1 is cut into a square shape by the cutting blade main piece 8a formed at the lower end edge of the retaining wall body 7, and the cutting disposed at the corner of the retaining wall body 7 is performed. The cutting blade main piece 8a and the high-pressure water Wa cooperate with each other even in the hard contaminated soil g1 by cutting the contaminated soil g1 located immediately below with the high-pressure water Wa ejected from the nozzles 40, 40, 40, 40 for use. And can be easily cut.
[0107]
And the soil in the corner of the retaining wall main body 7 formed in the square cylinder shape is cut by the corner soil cutting blade 8 and the circular drilling range Z in which the drilling body 11 can drill the cutting soil g3. It can be brought in.
[0108]
At this time, since the cutting nozzle 40 is disposed in the nozzle arrangement recess 41 formed in the cutting soil inner approaching piece 8b, the cutting that is brought into the cutting range Z along the cutting soil inner approaching piece 8b. The soil g3 is smoothly slid and guided inward without interfering with the cutting nozzle 40.
[0109]
As a result, when the ground G surrounded by the retaining wall 1 is excavated by the drilling body 11 to discharge the contaminated soil g1 to the ground, the contaminated soil g1 at the corner which is difficult to excavate is easily and reliably cut to the inside. Therefore, the entire inside of the retaining wall 1 can be quickly and surely made into the hole H.
[0110]
[Description of retaining wall as a second example of transformation]
10 to 12 show a retaining wall 1 as a second modification example. The retaining wall 1 has the same basic structure as the retaining wall 1 as the first embodiment described above, but has a corner. It differs in the point which comprised the cutting soil inner side approach piece 8b of the partial soil cutting blade body 8 separately from the earth retaining wall main body 7. FIG.
[0111]
That is, as shown in FIGS. 10 to 12, the cutting soil inner side approaching piece 8 b is arranged at the lower part in the retaining wall main body 7 and suspended from the ground via the suspension string bodies 43, 43, 43, 43. In the lowered state, the cutting soil g3 can be brought into the drilling range Z. 48 is a string connecting bracket.
[0112]
In this way, by forming the cut soil inner approach piece 8b separately from the retaining wall main body 7, after the contaminated soil g1 is discharged to the ground by the drilling body 11, the cut soil inner approach piece 8b is suspended. The earth retaining wall 1 is grounded while being backfilled with the treated soil g2 in the pit H or backfilled with the treated soil g2 in the pit H by pulling it up to the ground via the lowering string 43. When it pulls out from G, the cutting soil inner side approaching piece 8b does not become a pulling resistance, and the retaining wall 1 can be pulled out smoothly.
[0113]
[Description of retaining wall as a third example of transformation]
FIG. 13 shows a retaining wall 1 as a third modification example. The retaining wall 1 has the same basic structure as the retaining wall 1 as the first modification example described above, but includes a cutting nozzle 40. The tip end portion 42a of the high-pressure water supply pipe 42 connected to the base end portion of the cutting portion is formed of an elastic material having an elastic force that can be restored to a straight state, while the cutting nozzle 40 is cut through the pivot body 44 to the cutting soil. It is different in that it is pivotally supported by the inner approaching piece 8b. 45 is a pivot pin.
[0114]
That is, as shown in FIG. 13, insertion holes 46, 46, 46, 46 are formed by extending vertically in the portions of the cutting soil inner side approaching pieces 8 b located at the four corners of the retaining wall main body 7. The tip portions 42a, 42a, 42a, 42a of the high-pressure water supply pipes 42, 42, 42, 42 are slidably inserted in the respective insertion holes 46, 46, 46, 46, and connected to the respective tip portions 42a. When the cutting nozzle 40 is pivotally supported on the cutting soil inner edge 8 b via the pivot 44 and the high-pressure water supply pipe 42 is slid downward, the cutting nozzle 40 is moved by the pivot 44. The nozzle 40 is turned about 90 degrees around the pivot pin 45 so that the ejection hole 40a of the cutting nozzle 40 facing directly downward can be directed inward.
[0115]
Thus, when the earth retaining wall 1 is built to a required depth, the ejection hole 40a of the cutting nozzle 40 is directed directly downward, and high pressure water is ejected from the ejection hole 40a. The contaminated soil g1 located in can be cut.
[0116]
And after building the earth retaining wall 1 to a required depth, the high pressure water supply pipe 42 is slid downward, and the ejection hole 40a of the cutting nozzle 40 is directed inward, and in the same state. By ejecting high-pressure water from the ejection hole 40a, the cutting soil g3 at the bottom in the pit H can be actively brought into the drilling range Z from the lateral direction.
[0117]
Therefore, the cutting soil g3 can be reliably discharged to the ground by the hole drilling body 11, and the hole H can be reliably formed.
[0118]
[Description of retaining wall as a fourth example of transformation]
FIG. 14 shows a retaining wall 1 as a fourth modification example. The retaining wall 1 has the same basic structure as the retaining wall 1 as the second modification example described above, but the inside of the cut soil The difference is that the piece 8b can be moved forward and backward in the lower part of the retaining wall body 7 by the forward and backward operation cylinders 47 and 47.
[0119]
That is, the advancing / retreating operation cylinders 47, 47 are attached to the lower inner wall of the retaining wall main body 7, and the piston rods 47a, 47a of the advancing / retreating operation cylinders 47, 47 are extended downward so that both piston rods 47a, 47a The upper end part of the cutting soil inner side approach piece 8b is connected with the front-end | tip part (lower end part).
[0120]
In this way, by moving the piston rods 47a, 47a of the forward / backward moving cylinders 47, 47 in the vertical direction, the cutting soil inner approaching piece 8b connected to the tip portions of the piston rods 47a, 47a It is possible to advance and retract between a retracted position accommodated in the wall body 7 and an advanced position that protrudes downward from the lower end of the retaining wall body 7.
[0121]
Therefore, by moving the cutting soil inner approaching piece 8b to the advance position, the contaminated soil g1 can be brought into the drilling range Z while cutting, and the cutting soil inner approaching piece is appropriately selected according to the soil quality and the like of the contaminated soil g1. By moving 8b back and forth, the contaminated soil g1 can be discharged efficiently.
[0122]
[Description of retaining wall as a second embodiment]
15 and 16 show a retaining wall 1 as a second embodiment. The retaining wall 1 has the same basic structure as the retaining wall 1 as the first embodiment. The difference is that the retaining wall body 7 is made larger than the retaining wall body 7 as an example, and a reinforcing frame 50 is provided inside the retaining wall body 7.
[0123]
That is, the retaining wall 1 as the second embodiment is provided with the reinforcing frame 50 inside the retaining wall body 7, so that the retaining wall body 7 is made to resist the earth pressure by the size of the retaining wall body 7 which is enlarged. The reinforcing frame 50 includes a cylindrical reinforcing cylinder 51 extending in the vertical direction, and an outer peripheral surface of the reinforcing cylindrical body 51 and an inner peripheral surface of the retaining wall main body 7. It forms from the support body 52 interposed between.
[0124]
And the reinforcement cylinder 51 has an internal diameter which can penetrate the drilling body 11 as 2nd Example mentioned later, and has arrange | positioned a lower end part in the upper position rather than the cutting soil inner side approaching piece 8b.
[0125]
[Description of Drilling Body as Second Example]
17 and 18 show a drilling body 11 as a second embodiment, and the drilling body 11 has the same basic structure as the drilling body 11 as the first embodiment. A part of the peripheral wall of the hole drilling piece 26 is made into scraping pieces 53, 53, 53 so that the contaminated soil g 1 can be scraped into the drilling hole piece 26 by the respective scraping pieces 53, 53, 53. It differs in that it is.
[0126]
In other words, the hole drilling body 11 is formed by extending the perforations 54, 54, 54 in the circumferential direction on the peripheral wall of the perforation main piece 26, and vertically extending at one side edge of each of the perforations 54, 54, 54. The one side edge of each of the scraping pieces 53, 53, 53 is pivotally supported via the pivots 55, 55, 55 whose axis is directed in the direction, and the other side end of each of the scraping pieces 53, 53, 53 Cutting blades 56, 56, 56 are provided at the edge.
[0127]
Each of the scraping pieces 53, 53, 53 is formed in a plate shape that is curved and extended in the circumferential direction of the hole-cutting piece 26, and the open / close cylinders 57, 57, 57 are interlocked and connected to the respective tip portions. The closing positions where the respective opening 54, 54, 54 are closed by the open / close cylinders 57, 57, 57 to form the peripheral wall of the hole-cutting piece 26, and the respective opening 54, 54, 54 are opened. It can be opened and closed between an open position projecting outward from the drilling piece 26.
[0128]
In this way, by rotating the drilling hole piece 26 with the scraping pieces 53, 53, 53 arranged at the open position, the contaminated soil g 1 on the outer periphery of the drilling hole piece 26 is removed from each of the scraping pieces. Cutting is performed by the cutting blades 56, 56, 56 provided at the leading ends of the cutting pieces 53, 53, 53, and the respective cutting openings 54 are arranged along the inner peripheral surfaces of the curved cutting pieces 53, 53, 53. , 54, 54, and is raked into each of the rake holes 54, 54, 54.
[0129]
Accordingly, as shown in FIG. 18, each of the contaminated soil g1 positioned between the outer peripheral surface of the drill hole main piece 26 and the virtual inscribed circle C inscribed with the cut soil inner approaching piece 8b provided on the retaining wall 1 is removed. The cutting pieces 53, 53, 53 can be surely scraped into the drill hole main piece 26 through the respective cutting openings 54, 54, 54.
[0130]
[Description of Contaminated Soil Improvement Method as Second Example]
FIG. 19 is a plan explanatory view showing the procedure of the contaminated soil improvement method as the second example, and the contaminated soil improvement method as the second example is similar to the contaminated soil improvement method as the first example. [Embedded process], [Soil discharge process], [Soil improvement treatment process], [Groundwater purification process], [Backfill process] and [Drawing process], and the basic work process is the same, It is different in [Building process] and [Soil discharging process].
[0131]
Therefore, the [building process] and [soil discharging process] different from the contaminated soil improvement method as the first embodiment will be described below with reference to FIG.
[0132]
(1) [Embedded process]
In the erection process, the contaminated ground G is excavated to discharge the contaminated soil g1 to the ground to form a pit h that does not naturally collapse, and the earth retaining wall 1 is built in the vicinity of the pit h. It is a process that builds.
[0133]
At this time, as shown in FIG. 19 (a), four pits h that are not naturally collapsed are formed at substantially the same interval, and as shown in FIG. 19 (b), these four pits h are formed. The retaining wall 1 as the second embodiment described above is built by a building device (not shown) so as to be close to the periphery of the wall.
[0134]
(2) [Soil discharge process]
The soil discharging step is a step of excavating the ground G surrounded by the retaining wall 1 and discharging all or most of the excavated contaminated soil g1 to the ground, thereby forming a pit H in the retaining wall 1. .
[0135]
That is, as shown in FIG. 19 (c), the soil discharging step is performed at a position immediately above the contaminated soil g1 in the reinforcing cylinder 51 provided on the earth retaining wall 1 built in the ground G to a certain depth. As an example, the drilling body 11 is arranged, and the drilling body 11 is rotated by the driving motor 15 through the excavation shaft body 16 so that the contaminated soil g1 in the earth retaining wall 1 is excavated by the excavating blade 28. At the same time, the excavated contaminated soil g1 is taken into the drilled body 11 through the excavated soil intake port 29, and when a predetermined amount of contaminated soil g1 is taken into the drilled soil body 11, the excavated shaft body 16 is contracted. At the same time, the drilling body 11 attached to the lower end of the excavation shaft body 16 is pulled up to the ground by moving up the drilling body 11 to a height required to position the drilling body 11 above the ground surface. Drain the contaminated soil g1 from the pore 11 It is way.
[0136]
Thus, excavation is performed up to the lower end portion of the built-in retaining wall 1 by repeatedly discharging the contaminated soil g1 by the drilling body 11.
[0137]
Then, as shown in FIG. 19 (d), the hole drilling body 11 is disposed in a position below the reinforcing cylinder 51 and the scraping pieces 53, 53, 53 are slightly opened. By rotating 26, the contaminated soil g1 located between the four perforations h, h, h, h formed on the outer periphery of the hole-cutting piece 26 and formed in advance so as not to naturally collapse, and the hole The cutting soil g3 brought within the range Z is cut from the lateral direction by the cutting blade bodies 56, 56, 56 provided at the tip portions of the respective scraping pieces 53, 53, 53, and each curved scraping piece 53 is curved. , 53 and 53 are guided along the inner peripheral surface of each of the scraping ports 54, 54, 54 and scraped into the drilling hole piece 26.
[0138]
Further, over time, the scraping pieces 53, 53, 53 are gradually opened by the open / close cylinders 57, 57, 57, and the contaminated soil g1 on the outer periphery of the drilling hole piece 26 is scraped into the drilling hole piece 26. As shown in FIG. 19 (d), the contaminated soil g1 located between the outer peripheral surface of the drill hole main piece 26 and the virtual inscribed circle C inscribed with the cutting soil inner approach piece 8b provided on the retaining wall 1 is provided. Each of the scraping pieces 53, 53, 53 is scraped into the drill hole main piece 26 through each of the scraping ports 54, 54, 54 and discharged to the ground, whereby the entire retaining wall 1 is Eggplant.
[0139]
In addition, in the above-described scraping operation, when the drilling hole piece 26 is full, each time the drilling hole piece 26 is pulled up to the ground, the contaminated soil g1 is discharged, and then, Continue the scraping operation again.
[0140]
In addition, after the retaining wall 1 is further built to a certain depth, the contaminated soil g1 in the retaining wall 1 is discharged to the ground in the same manner as described above, so that the entire retaining wall 1 becomes a pit H.
[0141]
These [building process] and [soil discharging process] are repeated until the required depth is reached. Such a process includes a process of retaining the contaminated groundwater W1 in the pit H.
[0142]
[Description of Contaminated Soil Improvement Method as Third Example]
FIG. 20 is an explanatory diagram showing the work process of the contaminated soil improvement method as the third embodiment. The contaminated soil improvement method as the third embodiment excavates the contaminated ground G to a certain depth to contaminate soil. While discharging g1 to the ground and improving the discharged contaminated soil g1 on the ground, contaminated groundwater W1 is retained in the pit H formed in the ground G, and the pit H is further excavated to a predetermined depth. The contaminated soil g1 and the contaminated groundwater W1 are purified while being kneaded in the pit H, and then the treated soil g2 is backfilled in the pit H on the ground. In the figure, parts corresponding to those shown in FIG.
[0143]
That is, the contaminated soil improvement method as the third embodiment is the [Embedding process], [Soil discharge process], [Soil improvement treatment process], [Groundwater and excavated soil treatment process], [Backfill process] and [Extraction process]. Each step will be described below with reference to FIG.
[0144]
(1) [Embedded process]
The erection process is a process in which the retaining wall 1 is constructed in a closed state in the contaminated ground G to a certain depth, and a certain range of the ground G is surrounded by the retaining wall 1.
[0145]
That is, the erection process is a process of erected a square cylindrical retaining wall 1 on the ground G, as in [Embedding process] of the first embodiment. The retaining wall 1 is a predetermined of the ground G to be improved. Is built by an erection device (not shown) at the position (see FIG. 20A).
[0146]
(2) [Soil discharge process]
The soil discharging process is similar to the [building process] of the first embodiment, by excavating the ground G surrounded by the retaining wall 1 and discharging all or most of the excavated contaminated soil g1 to the ground. This is a step of forming a hole H in the earth retaining wall 1 (see FIGS. 20A and 20B).
[0147]
Such a process includes a process of retaining the contaminated groundwater W1 in the pit H.
[0148]
(3) [Soil improvement treatment process]
The soil improvement treatment step is a step of improving the contaminated soil g1 discharged to the ground after repeatedly performing the above-described steps until reaching a certain depth in the same manner as the [Embedding step] of the first embodiment. (See FIG. 20 (b)).
[0149]
(4) [Groundwater and excavated soil treatment process]
In the groundwater and excavated soil treatment process, the ground G is excavated to a predetermined depth after or while the retaining wall 1 is constructed in a closed state to a predetermined depth, and the contaminated soil g1 and the contaminated groundwater W1 are put into the pit H. And purifying while kneading.
[0150]
At this time, excavation work of the ground G and kneading work of the contaminated soil g1 and the contaminated groundwater W1 are performed by the excavation / stirring body B described later (see FIG. 20C).
[0151]
That is, in the groundwater and excavated soil purification treatment step, as shown in FIG. 20 (c), a plurality of discharge portions 23 communicating with the supply path 22 from the state where the excavation / stirring body B is disposed near the surface of the contaminated groundwater W1. , 23 (see FIG. 21), the excavating / stirring body B is rotated through the excavating shaft body 16 while being discharged into the contaminated groundwater W1, and is also settled and moved to the bottom position of the pit H. ing.
[0152]
At this time, the inner shaft agitating blade body 62 projecting from the inner shaft 18 of the excavation shaft body 16 and the outer shaft agitating blade body 63 projecting from the outer shaft 19 rotate in opposite directions, respectively, and contaminated groundwater W1 is collected. Because of the agitation, the purification material can be uniformly dissolved in the contaminated groundwater W1, and the contaminated groundwater W1 can be reliably purified or neutralized to be detoxified.
[0153]
As a result, the treated mud water W3 in a state where the contaminated soil g1, the contaminated groundwater W1, and the purification material are kneaded can be obtained (see FIG. 20 (d)).
[0154]
(5) [Backfill process]
The backfilling step is a step of backfilling the treated soil g2 in the pit H and kneading with the treated mud water W3.
[0155]
That is, in the backfilling process, as shown in FIG. 20 (e), the treated soil g2 is supplied from the ground through the supply path to the excavation / stirring body B that has been excavated to a predetermined depth. The discharged soil g2 is discharged from the discharge portion provided in the digging unit, and the excavation / stirring body B is pulled up while kneading the processed soil g2 and the processed mud water W3.
[0156]
Thus, the treated muddy water W3 is kneaded with the treated muddy water W3 while gradually refilling the treated soil g2 from the bottom of the pit H, so that the treated muddy water W3 is refilled without overflowing from the pit H. It can be reliably kneaded with the soil g2.
[0157]
(6) [Pulling process]
Similarly to the [drawing step] of the first embodiment, the drawing step is performed while the treated soil g2 is backfilled in the above-described backfilling step, or after the treated soil g2 is backfilled in the retaining wall 1, This is a step of pulling out the retaining wall 1 from the ground G.
[0158]
That is, in the drawing process, as shown in FIG. 20 (f), the retaining wall 1 is connected to the base machine 10 via the hanging wire 38, so that the retaining wall 1 is moved upward from the ground G by the base machine 10. Pull out.
[0159]
Next, the digging / stirring body B will be described. The digging / stirring body B includes a plurality of excavating blade bodies 27a attached to the tip 18a of the inner shaft 18, as shown in FIG. A plurality of excavation blades 28 project from the lower surface of each excavation blade body 27a. In the figure, parts corresponding to those shown in FIG.
[0160]
The relative stirring blade body 60 is configured such that the innermost stirring blade body 61, the inner stirring blade body 62 rotating in the opposite direction around the outer periphery of the innermost stirring blade body 61, and the outer periphery of the inner stirring blade body 62 are relative to each other. The outer agitating blade body 63 and the outer agitating blade body 63 are formed in a substantially similar shape and formed between the two agitating blade bodies 62, 63. By making the gaps to be substantially equal across the entire area of the two stirring blades 62, 63, it is possible to prevent the swirling phenomenon of the excavated soil and to exhibit a precise stirring function. ing.
[0161]
The innermost stirring blade body 61 is formed so as to protrude radially from the lower end portion of the outer shaft 19. A pair of the innermost stirring blade bodies 61 are provided at the line-symmetrical positions of the lower end portion of the outer shaft 19, and integrally with the outer shaft 19 in one direction. I try to rotate.
[0162]
Further, the inner stirring blade body 62 includes a pair of upper and lower horizontal blade pieces 62a and 62b and a pair of upper and lower horizontal blade pieces 62a and 62b extending in a projecting manner in a direction intersecting the axial length direction of the outer shaft 19. It is formed in an arc shape from a vertical wing piece 62c interposed between the outer end portions so as to extend in the vertical direction, and is attached to a ring-like wing piece support 70 that is freely loosely fitted on the outer peripheral surface of the outer shaft 19. While attaching the front-end | tip part of the horizontal wing piece 62a, the front-end | tip part of the lower horizontal wing piece 62b is attached to the lower end part of the inner side axis | shaft 18, and it rotates to the other direction integrally with the inner side axis | shaft 18.
[0163]
A pair of inner stirring blades 62 is provided at a line-symmetrical position below the inner shaft 18. Reference numeral 71 denotes a small blade piece that is formed to protrude outward from the middle portion of the vertical blade piece 62c.
[0164]
The outer stirring blade body 63 includes upper and lower pair of upper and lower horizontal blade pieces 63a and 63b extending in a protruding manner in a direction intersecting with the axial length direction of the outer shaft 19, and outer ends of both upper and lower horizontal blade pieces 63a and 63b. It is formed in an arc shape from a vertical wing piece 63c that is vertically extended between the parts, and the tip of the upper horizontal wing piece 63a is attached to the lower end of the outer shaft 19, while the outer peripheral surface of the inner shaft 18 A tip end portion of the lower horizontal wing piece 63b is attached to a ring-like wing piece support 74 that is freely loosely fitted to the outer wing 19 so as to rotate integrally with the outer shaft 19 in one direction.
[0165]
Three outer agitating blade bodies 63 are provided around the outer shaft 19 at regular intervals. 75 is a small blade piece formed by projecting inwardly at the upper and lower portions of the vertical blade piece 63 c, and the rotation trajectory of these small blade pieces 75, 75 is the small blade piece provided on the inner stirring blade body 62. It arrange | positions so that it may overlap with the rotation locus | trajectory of 71 to an up-down direction, and it can be made to perform stirring of excavated soil reliably between the inner and outer side stirring blade bodies 62 and 63 which rotate relatively reversely.
[0166]
Here, the vertical blade piece 63c of the outer agitating blade body 63 is provided with an improved material discharge portion 73 for discharging the improved material, and the improved material discharge portion 73 is provided on the back surface (rotation direction side) of the vertical blade piece 63c. An improvement material discharge hole 73a extending in the vertical direction is formed on a surface opposite to the surface).
[0167]
The improvement material discharge hole 73a is connected to the purification material supply path 22 through the improvement material introduction path 77 formed over the vertical blade piece 63c and the upper horizontal blade piece 63a, and the improvement material is supplied vertically from the improvement material discharge hole 73a. It is made to discharge in the tangential direction of the rotation locus which wing piece 63c draws.
[0168]
【The invention's effect】
(1) According to the present invention described in claim 1, a certain depth of the retaining wall is closed in the contaminated ground, and a certain range of the ground is surrounded by the retaining wall and surrounded by the retaining wall. By excavating the ground and discharging all or most of the excavated contaminated soil to the ground, a pit is formed in the retaining wall, and contaminated groundwater is retained in the pit and the discharged pollution. The soil is improved on the ground, while the contaminated groundwater and excavated soil left in the pit are purified in the pit, and then the treated soil improved on the ground is backfilled in the pit. I am doing so.
[0169]
In this way, in the contaminated ground, a closed retaining wall that surrounds a certain area of the ground is constructed, a pit is formed in the retaining wall, and contaminated groundwater is retained in the retaining hole. Therefore, the water pressure of the groundwater retained in the pit can be countered with the water pressure around the retaining wall, and only the earth pressure acts on the retaining wall from the surroundings. A substantially similar state can be obtained.
[0170]
Therefore, as the retaining wall, it is only necessary to secure a strength that can counteract the surrounding earth pressure, and it is not necessary to consider the water shielding function. Well, it is no longer necessary to perform conventional water-impervious work, earth retaining / water-impervious reinforcement work, and bottom-floor water stop work.
[0171]
As a result, the structure of the retaining wall can be simplified, a wide variety of retaining walls can be adopted as the retaining wall, and the work for improving contaminated soil can be made more efficient and the cost can be reduced. .
[0172]
In addition, the retaining wall can be left buried in the ground without being removed depending on the situation of the ground, etc. In this case, the labor and cost of the removal work can be reduced.
[0173]
In addition, since the contaminated soil is once discharged to the ground and improved on the ground, which is not subject to restrictions compared to the ground, it is possible to ensure the quality control of the improved state of such soil. And the required improvement processing accuracy can be ensured.
[0174]
On the other hand, the contaminated groundwater retained in the pit and the excavated soil left in the pit are purified in the pit. At this time, the groundwater and the excavated soil in the pit, By spraying and stirring, the purification treatment can be performed easily and reliably.
[0175]
As a result, the soil that has been reliably improved on the ground can be backfilled in the pit where the groundwater that has been reliably purified remains, and a certain range of contaminated ground can be reliably improved. it can.
[0176]
In addition, the groundwater pumped up with the contaminated soil can be purified in the pothole by separating it from the contaminated soil on the ground and returning it to the pothole.
[0177]
In addition, when the amount of groundwater pumped together with the contaminated soil is small, the groundwater can be improved with the contaminated soil on the ground and buried in the pit.
[0178]
Here, the fixed range of the contaminated ground surrounded by the retaining wall can be set broadly or narrowly according to the working conditions, etc. By performing continuously, the required range of the contaminated ground can be reliably improved.
[0179]
(2) In the present invention according to claim 2, a step of constructing a closed wall of a certain depth in the contaminated ground in a closed state and surrounding a certain range of the ground by the soil retaining wall, and surrounding by the soil retaining wall Excavating the ground, and discharging all or most of the excavated contaminated soil to the ground, forming a pit in the retaining wall, and retaining contaminated groundwater in the pit , After repeating these processes until the required depth is reached, the process of improving the contaminated soil discharged on the ground and the contaminated groundwater remaining in the pit and left in the pit A step of purifying the excavated soil in the pit, and a step of filling the treated soil improved on the ground back into the pit.
[0180]
In this way, a certain depth of the retaining wall is preliminarily closed in the contaminated ground, and a certain area of the ground is surrounded by the retaining wall, and then all or all of the contaminated soil within the retaining wall is A large pothole can be efficiently formed because most of the earth is discharged to the ground and the entire inside of the retaining wall is made a pothole.
[0181]
In addition, since the contaminated groundwater is retained in the pit formed in the retaining wall, the water pressure of the groundwater retained in the pit can be countered with the water pressure around the retaining wall. Thus, the earth retaining wall can be brought into a state substantially similar to the state in which only earth pressure acts from the surroundings.
[0182]
Therefore, as the retaining wall, it is only necessary to secure a strength that can counteract the surrounding earth pressure, and it is not necessary to consider the water shielding function. Well, it is no longer necessary to perform conventional water-impervious work, earth retaining / water-impervious reinforcement work, and bottom-floor water stop work.
[0183]
As a result, the structure of the retaining wall can be simplified, a wide variety of retaining walls can be adopted as the retaining wall, and the work for improving contaminated soil can be made more efficient and the cost can be reduced. .
[0184]
The retaining wall can be left buried in the ground without being removed depending on the situation such as the ground. In this case, the labor and cost of the removal work can be reduced.
[0185]
In addition, since the contaminated soil is once discharged to the ground and improved on the ground, which is not subject to restrictions compared to the ground, it is possible to ensure the quality control of the improved state of such soil. And the required improvement processing accuracy can be ensured.
[0186]
On the other hand, the contaminated groundwater retained in the pit and the excavated soil left in the pit are purified in the pit. At this time, the groundwater and the excavated soil in the pit, By spraying and stirring, the purification treatment can be performed easily and reliably.
[0187]
As a result, the soil that has been reliably improved on the ground can be backfilled in the pit where the groundwater that has been reliably purified remains, and a certain range of contaminated ground can be reliably improved. it can.
[0188]
In addition, the groundwater pumped up with the contaminated soil can be purified in the pothole by separating it from the contaminated soil on the ground and returning it to the pothole.
[0189]
In addition, when the amount of groundwater pumped together with the contaminated soil is small, the groundwater can be improved with the contaminated soil on the ground and buried in the pit.
[0190]
Here, the fixed range of the contaminated ground surrounded by the retaining wall can be set broadly or narrowly according to the working conditions, etc. By performing continuously, the required range of the contaminated ground can be reliably improved.
[0191]
(3) In the present invention described in claim 3, by forming a pit that does not naturally collapse by excavating the contaminated ground and discharging the contaminated soil to the ground, the retaining wall is placed in the vicinity of the pit. And excavating the contaminated soil in the retaining wall, and discharging all or most of the excavated contaminated soil to the ground, and forming a pit in the retaining wall, The process of retaining contaminated groundwater, the process of repeating these processes until the required depth is reached, the process of improving the contaminated soil discharged on the ground, and the contamination remaining in the pit A step of purifying the groundwater and the excavated soil left in the pothole in the pothole, and a step of filling the treated soil improved on the ground in the pothole.
[0192]
In this way, a pothole that does not naturally collapse is formed in the contaminated ground in advance, and then a retaining wall is built close to the periphery of the pothole, and all or most of the contaminated soil in the retaining wall is built. Since the earth is discharged to the ground so that the entire inside of the retaining wall becomes a pit, a large pit can be formed efficiently.
[0193]
In addition, since the contaminated groundwater is retained in the pit formed in the retaining wall, the water pressure of the groundwater retained in the pit can be countered with the water pressure around the retaining wall. Thus, the earth retaining wall can be brought into a state substantially similar to the state in which only earth pressure acts from the surroundings.
[0194]
Therefore, as the retaining wall, it is only necessary to secure a strength that can counteract the surrounding earth pressure, and it is not necessary to consider the water shielding function. Well, it is no longer necessary to perform conventional water-impervious work, earth retaining / water-impervious reinforcement work, and bottom-floor water stop work.
[0195]
As a result, the structure of the retaining wall can be simplified, a wide variety of retaining walls can be adopted as the retaining wall, and the work for improving contaminated soil can be made more efficient and the cost can be reduced. .
[0196]
The retaining wall can be left buried in the ground without being removed depending on the situation such as the ground. In this case, the labor and cost of the removal work can be reduced.
[0197]
In addition, since the contaminated soil is once discharged to the ground and improved on the ground, which is not subject to restrictions compared to the ground, it is possible to ensure the quality control of the improved state of such soil. And the required improvement processing accuracy can be ensured.
[0198]
On the other hand, the contaminated groundwater retained in the pit and the excavated soil left in the pit are purified in the pit. At this time, the groundwater and the excavated soil in the pit, By spraying and stirring, the purification treatment can be performed easily and reliably.
[0199]
As a result, the soil that has been reliably improved on the ground can be backfilled in the pit where the groundwater that has been reliably purified remains, and a certain range of contaminated ground can be reliably improved. it can.
[0200]
In addition, the groundwater pumped up with the contaminated soil can be purified in the pothole by separating it from the contaminated soil on the ground and returning it to the pothole.
[0201]
In addition, when the amount of groundwater pumped together with the contaminated soil is small, the groundwater can be improved with the contaminated soil on the ground and buried in the pit.
[0202]
Here, the potholes that are not naturally collapsed to be formed in the contaminated ground in advance can be singular or plural depending on the working conditions, etc.When forming a plurality of potholes, It is possible to form these pits close to each other, build a retaining wall so as to surround the outer periphery of these pits, discharge the contaminated soil inside the retaining wall to the ground, and make the whole inside the retaining wall a pit. it can.
[0203]
And the required range of the contaminated ground can be reliably improved by performing the above-described improvement work continuously.
[0204]
(4) In the present invention according to claim 4, the contaminated ground is excavated to a certain depth to discharge the contaminated soil to the ground, and the discharged soil is improved on the ground while being formed on the ground. The contaminated groundwater is retained in the pit, the pit is further drilled to a predetermined depth, and the contaminated excavated soil and the contaminated groundwater are purified while being mixed in the pit. The soil that has been improved in is refilled in the pit.
[0205]
In this way, the contaminated soil up to a certain depth is once discharged to the ground and improved on the ground, which is not restricted compared to the ground, so the quality of the improved processing status of such soil Management can be performed reliably, and required improvement processing accuracy can be ensured.
[0206]
Then, the contaminated groundwater is retained in the pit formed in the ground, the pit is further drilled to a predetermined depth, and the contaminated excavated soil and the contaminated groundwater are mixed and purified in the pit. At this time, the contaminated excavated soil and the contaminated groundwater in the pit can be purified easily and reliably by, for example, spraying a purifying material and stirring.
[0207]
Therefore, by refilling the soil that has been reliably improved on the ground into the pit where the excavated soil and groundwater that have been reliably purified have been kneaded, a part of the contaminated ground can be obtained. Improvement processing can be surely performed.
[0208]
And the required range of the contaminated ground can be reliably improved by performing such work continuously.
[0209]
In addition, the groundwater pumped up with the contaminated soil can be purified in the pothole by separating it from the contaminated soil on the ground and returning it to the pothole.
[0210]
In addition, when the amount of groundwater pumped together with the contaminated soil is small, the groundwater can be improved with the contaminated soil on the ground and buried in the pit.
[0211]
(5) In the present invention according to claim 5, the retaining wall is constructed in a closed state up to a predetermined depth in the contaminated ground, and a certain range of the ground is surrounded by the retaining wall, and is surrounded by the retaining wall. By excavating the ground up to a certain depth and discharging all or most of the excavated contaminated soil to the ground, a pit is formed in the earth retaining wall and contaminated groundwater is retained in the pit. The discharged contaminated soil is improved on the ground, while the remaining ground up to a predetermined depth surrounded by the retaining wall is excavated, and the contaminated excavated soil and contaminated groundwater are mixed in the pit. The treated soil that has been subjected to purification treatment and then improved on the ground is then backfilled in the pit.
[0212]
In this way, the contaminated soil up to a certain depth is once discharged to the ground and improved on the ground, which is not restricted compared to the ground, so the quality of the improved processing status of such soil Management can be performed reliably, and required improvement processing accuracy can be ensured.
[0213]
Then, the contaminated groundwater is retained in the pit formed in the ground, the pit is further drilled to a predetermined depth, and the contaminated excavated soil and the contaminated groundwater are mixed and purified in the pit. At this time, the contaminated excavated soil and the contaminated groundwater in the pit can be purified easily and reliably by, for example, spraying a purifying material and stirring.
[0214]
Therefore, by refilling the soil that has been reliably improved on the ground into the pit where the excavated soil and groundwater that have been reliably purified have been kneaded, a part of the contaminated ground can be obtained. Improvement processing can be surely performed.
[0215]
And the required range of the contaminated ground can be reliably improved by performing such work continuously.
[0216]
At this time, in the contaminated ground, a closed retaining wall surrounding a certain range of the ground is constructed, and a pit is formed in the retaining wall so that the contaminated groundwater is retained in the retaining hole. Therefore, the water pressure of the groundwater retained in the pit can be countered with the water pressure around the retaining wall, and it is almost the same as the state where only earth pressure acts on the retaining wall from the surroundings. It can be assumed that
[0217]
When excavating the remaining ground up to a predetermined depth surrounded by the retaining wall and purifying the contaminated excavated soil and the contaminated groundwater while mixing them in the pit, The pressure of the kneaded material (which has a greater specific gravity than groundwater) that is mixed with the groundwater and the groundwater is slightly affected by the water pressure around the retaining wall and the earth pressure acting around the retaining wall. Can be countered.
[0218]
Therefore, as the retaining wall, it is only necessary to secure a strength that can counteract the surrounding earth pressure, and it is not necessary to consider the water shielding function. Well, it is no longer necessary to perform conventional water-impervious work, earth retaining / water-impervious reinforcement work, and bottom-floor water stop work.
[0219]
As a result, the structure of the retaining wall can be simplified, a wide variety of retaining walls can be adopted as the retaining wall, and the work for improving contaminated soil can be made more efficient and the cost can be reduced. .
[0220]
In addition, the retaining wall can be left buried in the ground without being removed depending on the situation of the ground, etc. In this case, the labor and cost of the removal work can be reduced.
[0221]
In addition, the groundwater pumped up with the contaminated soil can be purified in the pothole by separating it from the contaminated soil on the ground and returning it to the pothole.
[0222]
In addition, when the amount of groundwater pumped together with the contaminated soil is small, the groundwater can be improved with the contaminated soil on the ground and buried in the pit.
[0223]
Here, the fixed range of the contaminated ground surrounded by the retaining wall can be set broadly or narrowly according to the working conditions, etc. By performing continuously, the required range of the contaminated ground can be reliably improved.
[0224]
(6) In the present invention according to claim 6, the retaining wall is constructed in a closed state in the contaminated ground to a certain depth, and a certain range of the ground is surrounded by the retaining wall, and is surrounded by the retaining wall. By excavating the ground up to a certain depth and discharging all or most of the excavated contaminated soil to the ground, a pit is formed in the earth retaining wall and contaminated groundwater is retained in the pit. In addition, the discharged contaminated soil is improved on the ground, while the earth retaining wall is further closed to a predetermined depth or while it is being built, the ground is excavated to a predetermined depth, and the contaminated excavated soil and the contaminated soil are contaminated. The treated groundwater is purified while being kneaded in the pothole, and then the treated soil improved on the ground is returned to the pothole.
[0225]
In this way, the contaminated soil up to a certain depth is once discharged to the ground and improved on the ground, which is not restricted compared to the ground, so the quality of the improved processing status of such soil Management can be performed reliably, and required improvement processing accuracy can be ensured.
[0226]
Then, the contaminated groundwater is retained in the pit formed in the ground, the pit is further drilled to a predetermined depth, and the contaminated excavated soil and the contaminated groundwater are mixed and purified in the pit. At this time, the contaminated excavated soil and the contaminated groundwater in the pit can be purified easily and reliably by, for example, spraying a purification material and stirring.
[0227]
Therefore, by refilling the soil that has been reliably improved on the ground into the pit where the excavated soil and groundwater that have been reliably purified have been kneaded, a part of the contaminated ground can be obtained. Improvement processing can be surely performed.
[0228]
And the required range of the contaminated ground can be reliably improved by performing such work continuously.
[0229]
At this time, in the contaminated ground, a closed retaining wall surrounding a certain range of the ground is constructed, and a pit is formed in the retaining wall so that the contaminated groundwater is retained in the retaining hole. Therefore, the water pressure of the groundwater retained in the pit can be countered with the water pressure around the retaining wall, and it is almost the same as the state where only earth pressure acts on the retaining wall from the surroundings. It can be assumed that
[0230]
Then, after or after constructing the retaining wall in a closed state to a predetermined depth, the ground is excavated to a predetermined depth, and the contaminated excavated soil and the contaminated groundwater are kneaded in the pit and purified. When excavating soil and groundwater, the pressure of the kneaded material (specific gravity greater than groundwater) is mixed with the water pressure around the retaining wall, and further around the retaining wall. Slightly counteracting earth pressure acting.
[0231]
Therefore, as the retaining wall, it is only necessary to secure a strength that can counteract the surrounding earth pressure, and it is not necessary to consider the water shielding function. Well, it is no longer necessary to perform conventional water-impervious work, earth retaining / water-impervious reinforcement work, and bottom-floor water stop work.
[0232]
As a result, the structure of the retaining wall can be simplified, a wide variety of retaining walls can be adopted as the retaining wall, and the work for improving contaminated soil can be made more efficient and the cost can be reduced. .
[0233]
In addition, the retaining wall can be left buried in the ground without being removed depending on the situation of the ground, etc. In this case, the labor and cost of the removal work can be reduced.
[0234]
In addition, the groundwater pumped up with the contaminated soil can be purified in the pothole by separating it from the contaminated soil on the ground and returning it to the pothole.
[0235]
In addition, when the amount of groundwater pumped together with the contaminated soil is small, the groundwater can be improved with the contaminated soil on the ground and buried in the pit.
[0236]
Here, the fixed range of the contaminated ground surrounded by the retaining wall can be set broadly or narrowly according to the working conditions, etc. By performing continuously, the required range of the contaminated ground can be reliably improved.
[0237]
(7) In the present invention described in claim 7, when the soil improved on the ground is backfilled in the pothole, the improved soil is buried while being gradually moved upward from the bottom in the pothole. At the same time, the soil and the excavated soil and groundwater purified in the pit are kneaded.
[0238]
In this way, the kneaded material excavated and groundwater purified in the pothole is not allowed to overflow from the pothole, and the kneaded product and the improved treated soil that has been backfilled are reliably kneaded, The improved soil can be made uniform.
[0239]
Therefore, when the kneaded material overflows, the overflowed kneaded material must be processed. However, such work can be saved, and as a result, the contaminated soil can be improved efficiently. Can do.
[0240]
(8) In the present invention described in claim 8, the retaining wall is removed while the treated soil improved on the ground is backfilled in the pit or after being backfilled.
[0241]
In this way, the retaining wall can be reused by removing it without leaving the retaining wall in the ground of the required area that has been improved, and when constructing a structure, etc. on the ground, the same It can be freely constructed at any position in the ground where the foundation of the structure is improved.
[0242]
(9) In the present invention according to claim 9, the earth retaining wall has an outer shape formed in a rectangular cylindrical shape.
[0243]
In this way, it is possible to overlap the improvement work of contaminated soil by continuously building the retaining wall without overlapping the side walls of the retaining wall having a rectangular cylindrical shape as the outer surface. Can be done efficiently.
[0244]
(10) In the present invention described in claim 10, the retaining wall includes corner soil cutting means, and the soil in the corner of the retaining wall can be cut by the corner soil cutting means.
[0245]
In this way, the soil in the corner of the retaining wall can be cut by the corner soil cutting means, so when excavating the ground surrounded by the retaining wall and discharging the contaminated soil to the ground In addition, it is possible to easily and reliably cut and discharge the soil at the corners that are difficult to excavate, and to quickly and surely make a hole in the retaining wall quickly or surely.
[Brief description of the drawings]
BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is an explanatory diagram of a work process of a contaminated soil improvement method as a first embodiment according to the present invention.
FIG. 2 is a partially cutaway front view of a drilling body used in the contaminated soil improvement method.
FIG. 3 is a bottom view of the drilled hole body and the retaining wall.
4 is a cross-sectional view taken along the line II of FIG.
FIG. 5 is a sectional view taken along line II-II in FIG. 3;
FIG. 6 is an explanatory plan view showing the procedure of the contaminated soil improvement method.
FIG. 7 is a bottom view of a drilling body and a retaining wall as a first modification example.
8 is a cross-sectional view taken along line III-III in FIG.
9 is a cross-sectional explanatory view taken along the line IV-IV in FIG.
FIG. 10 is a cross-sectional plan view of a drill hole and a retaining wall as a second modification example.
11 is a cross-sectional view taken along line VV in FIG.
12 is a sectional view taken along line VI-VI in FIG.
FIG. 13 is a cross-sectional side view of a drilling body and a retaining wall as a third modification example.
FIG. 14 is a cross-sectional side view of a drill hole and a retaining wall as a fourth modification example.
FIG. 15 is a plan view of a retaining wall as a second embodiment.
FIG. 16 is a cross-sectional front view of the lower part of the earth retaining wall.
FIG. 17 is a front explanatory view of a drilling body as a second embodiment.
FIG. 18 is an explanatory plan view of the hole drilling body.
FIG. 19 is an explanatory plan view showing the procedure of the contaminated soil improvement method as the second embodiment.
FIG. 20 is an explanatory view showing a work process of a contaminated soil improvement method as a third embodiment.
FIG. 21 is a partially cutaway front view of a digging / stirring body used in the contaminated soil improvement method.
[Explanation of symbols]
A Contaminated soil improvement device
1 retaining wall
2 soil discharge means
3 soil improvement treatment means
4 Groundwater purification treatment means
5 Backfilling means
6 Pulling means

Claims (10)

Construct a soil wall at a certain depth closed in the contaminated ground, surround a certain area of the ground by the soil retaining wall, excavate the ground surrounded by the soil retaining wall, and all the excavated contaminated soil By discharging most or most of it to the ground, a pit is formed in the earth retaining wall, and contaminated groundwater is retained in the pit and the discharged contaminated soil is improved on the ground while being contaminated. A contaminated soil improvement method characterized in that groundwater and excavated soil left in the pit are purified in the pit, and then the treated soil improved on the ground is backfilled in the pit. Constructing a closed wall of a certain depth in the contaminated ground in a closed state and surrounding a certain range of the ground by the retaining wall;
Excavating the ground surrounded by the retaining wall, and discharging all or most of the excavated contaminated soil to the ground, thereby forming a pit in the retaining wall;
A process of retaining contaminated groundwater in the same hole,
After repeating these steps until the required depth is reached, the step of improving the contaminated soil discharged on the ground on the ground,
Purifying the contaminated groundwater remaining in the pit and the excavated soil left in the pit in the pit,
A method for improving contaminated soil, comprising a step of backfilling treated soil, which has been improved on the ground, into a pit. Excavating the contaminated ground and discharging the contaminated soil to the ground to form a pothole that does not naturally collapse, and building a retaining wall in the vicinity of the pothole;
Excavating the contaminated soil in the retaining wall, and discharging all or most of the excavated contaminated soil to the ground to form a pit in the retaining wall;
A process of retaining contaminated groundwater in the same hole,
After repeating these steps until the required depth is reached, the step of improving the contaminated soil discharged on the ground on the ground,
Purifying the contaminated groundwater remaining in the pit and the excavated soil left in the pit in the pit,
A method for improving contaminated soil, comprising a step of backfilling treated soil, which has been improved on the ground, into a pit. While excavating the contaminated ground to a certain depth and discharging the contaminated soil to the ground, while improving the discharged soil on the ground, contaminated groundwater is retained in the pits formed in the ground, The same hole is further drilled to a predetermined depth, and the contaminated excavated soil and the contaminated groundwater are purified while being mixed in the pothole, and then the soil that has been improved on the ground is buried in the pothole. Contaminated soil improvement method characterized by returning. In the contaminated ground, the retaining wall is built up to a predetermined depth, and a certain area of the ground is surrounded by the retaining wall, and the ground up to a certain depth surrounded by the retaining wall is excavated. By discharging all or most of the contaminated soil to the ground, pits are formed in the retaining wall, and contaminated groundwater is retained in the pit, and the discharged contaminated soil is improved on the ground. On the other hand, the remaining ground up to a predetermined depth surrounded by the retaining wall is excavated, and the contaminated excavated soil and the contaminated groundwater are purified while kneading in the pit, and then improved on the ground. A contaminated soil improvement method characterized by backfilling treated soil in a pit. In the contaminated ground, the retaining wall is closed to a certain depth, and a certain area of the ground is surrounded by the retaining wall, and the ground to the certain depth surrounded by the retaining wall is excavated, and excavated By discharging all or most of the contaminated soil to the ground, pits are formed in the retaining wall, and contaminated groundwater is retained in the pit, and the discharged contaminated soil is improved on the ground. On the other hand, after or after constructing the retaining wall in a closed state to a predetermined depth, the ground is excavated to a predetermined depth, and the contaminated excavated soil and the contaminated groundwater are mixed and purified in the pit. A contaminated soil improvement method characterized by returning treated soil that has been treated and then improved on the ground to the inside of a pothole. When refilling soil that has been improved on the ground into the pit, the soil that has been improved is backfilled while gradually moving upward from the bottom of the pit, and the soil is purified within the pit. The contaminated soil improvement method according to any one of claims 4 to 6, wherein the excavated soil and groundwater are kneaded. The earth retaining wall is removed after refilling the treated soil that has been improved on the ground in the pit or after being backfilled. Contaminated soil improvement method described. The contaminated soil improvement method according to any one of claims 1 to 3, wherein the earth retaining wall has an outer shape formed in a rectangular cylindrical shape. The retaining wall comprises a corner soil cutting means, and the soil in the corner of the retaining wall can be cut by the corner soil cutting means. The method for improving contaminated soil according to any one of 9 above.

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