JP5307257B2 - Ground improvement method - Google Patents

Description

  The present invention relates to a method for improving soft ground by promoting vacuum vaporization.

The present applicant has proposed a ground improvement method in Patent Document 1.
In this construction method, the saturated groundwater is pumped up by negative pressure propagation using SWP (Super Well Point), so that only the target area is concentrated and the water level can be lowered spotwise to create an unsaturated zone. After that, using a SWP vacuum pump or vortex pump, it promotes vacuum vaporization in the range of the unsaturated zone to remove moisture, VOCs (volatile organic compounds), and vaporizable substances such as oil from the ground. And promote ground improvement and soil purification.

JP2007-303095 (Patent No. 4114944)

An object of the present invention is to provide an auxiliary method for promoting an improvement effect and purification of a whole improved area without unevenness by a method used as an auxiliary to a soft ground improvement method and a soil purification method by promoting vacuum vaporization.
In addition, as a supplement to a large-scale well by the SWP method, the present invention uses a small well having a diameter of about φ = 50 to 50 mm, creates a water channel under pressure, improves the apparent hydraulic conductivity, reduces the well loss (well Another challenge is to reduce the difference between the inland water level and the ground water level.

The invention according to claim 1 is the ground in which two small wells are installed at a predetermined interval on the ground, air is pumped from one small well into the ground, and air in the ground is sucked from the other small well. It features an improved construction method.

Furthermore, the invention described in claim 1 is characterized in that an intake hole is formed at a predetermined depth interval in the other small well, and intake by a vortex pump is applied to the other small well.

According to the present invention, the improvement effect and purification can be promoted as soon as possible without any unevenness in the entire improvement area as an aid to the soft ground improvement method and the soil purification method by promoting vacuum vaporization.
In addition, as a supplement to large-scale wells by the SWP method, it is possible to improve the apparent hydraulic conductivity and reduce the well loss by creating a water well under pressure using a small well with a diameter of φ = 40-50mm. it can.

It is sectional drawing which shows the construction method of Embodiment 1 to which this invention is applied. It is the top view (a) and sectional drawing (b) which show the construction method of Embodiment 2 to which this invention is applied. It is sectional drawing which shows the construction method of Embodiment 3 to which this invention is applied. It is sectional drawing which shows the construction method of Embodiment 4 to which this invention is applied. It is sectional drawing which shows the construction method of Embodiment 5 to which this invention is applied. It is sectional drawing which shows the construction method of Embodiment 6 to which this invention is applied. It is an enlarged view of the ground part of FIG.

DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.
<First invention>
The present invention is a construction method used as an auxiliary to the soft ground improvement method and the soil purification method by promoting vacuum vaporization, and is an auxiliary method for promoting the improvement effect and purification of the entire improvement area as soon as possible without unevenness.

"Mutual pressure suction cleaning"
Using two large-scale wells by SWP, vacuum suction is performed on one side, and a large compressor is used on the other side, and purification and water paths are created by pumping to promote improvement and purification of the hydraulic conductivity K ′.

(Embodiment 1)
FIG. 1 shows a construction method of Embodiment 1 to which the present invention is applied. 1 is a well for water supply pressure air, 10 is a strainer, 11 is a water tank, 12 is a water supply pump, 13 is a water supply pipe, 15 is a large compressor, 16 is an air supply pipe, 2 is a well for intake and intake of pumping water, 20 is a strainer, 21 is a pumping pump, 22 is an inner pipe, 23 is a pumping pipe, 25 is a vacuum pump, and 26 is a suction pipe.

  As shown in the figure, wells 1 and 2 by two SWPs are installed on the target ground at a predetermined interval.

A water supply pipe 13 connected to a water supply pump 12 installed in a water tank 11 on the ground is connected to a well 1 for water supply pressure air, and an air supply pipe 16 connected to a large compressor 15 on the ground.
The well 1 is supplied with water by a water supply pump 12 and is also supplied with air by a large compressor 15, and the water and air are pumped into the ground through a lower strainer 10.

The pumping intake well 2 is connected to a ground pumping pipe 23 connected to an inner pipe 22 connected to a pumping pump 21 installed at the bottom thereof, and to a suction pipe 26 connected to a vacuum pump 25 on the ground. ing.
Water and air in the ground are sucked into the well 2 by the pumping pump 21 and the vacuum pump 25 through the lower strainer 20.

  As described above, the pumping of water and air into the ground by the well 1 and the suction of water and air in the ground by the well 2 are repeated.

  Thus, by repeatedly performing pumping and suction in the mutual wells 1 and 2, the negative pressure suction effect is large, the hydraulic conductivity between the SWP wells 1 and 2 is greatly improved, and the water level lowering effect is increased. In addition, the effect of reducing the well loss can be greatly improved.

<Second invention>
In the present invention, the diameter φ = 40 to 50 mm without providing many large-scale wells by the SWP method.
By using a small well of the same size and creating a water channel under pressure, the apparent hydraulic conductivity is improved and the well loss is reduced.

"Ring pumping suction cleaning"
For SWP, with vacuum suction, after drilling to a specified depth with a boring machine, continue to send pressurized air with a large compressor, and continue to send air in steps of about 0.5m to improve hydraulic conductivity, well Promotes loss reduction and purification.

(Embodiment 2)
FIG. 2 shows the construction method of the second embodiment to which the present invention is applied. 3 is a large well, 30 is a strainer, 31 is a pumping pump, 32 is an inner pipe, 4 is a small well, 45 is a large compressor, and 46 is an air supply pipe. 5 is a boring machine.

  As shown in the figure, the target ground is provided with a large well 3 by one SWP and a plurality of (four in the illustrated example) small wells 4 at predetermined intervals in a concentric circle around the same. Yes.

The large well 3 is connected to a ground pump (not shown) connected to an inner pipe 32 connected to a pump 31 installed at the bottom, and to a suction pipe connected to a vacuum pump (not shown) on the ground. .
The large well 3 sucks underground water and air through the lower and middle strainers 30 by the pumping pump 31 and the vacuum pump.

An air pipe 46 connected to a large compressor 45 on the ground is connected to the small well 4.
The small well 4 is fed with air by a large compressor 45, and the air is pumped from the lower end into the ground.

The small well 4 is specifically an excavation pipe held by the boring machine 5, and after the excavation to a predetermined depth by the boring machine 5, the compressed air is continuously sent by the large compressor 45.
Thereafter, as indicated by the arrow, the small well 4 is slid by the boring machine 5 and pulled up by about 0.5 m while continuing to send air at the back step.

  As described above, the air is pumped into the ground by a plurality of (four in the illustrated example) small wells 4 at predetermined intervals in the surrounding concentric circles, and the water and air in the ground by the central large well 3 While performing suction repeatedly, air is pumped into the ground while raising the small well 4 stepwise.

  Thus, by using the small well 4 for pressurized air, as shown in the figure, the well loss L can be reduced and the amount of water level reduction can be increased.

<Third invention>
The present invention uses the air pressure of the compressor for the compaction of soft ground.
In addition, using the same well, it is also used as an intake pipe as an auxiliary to the construction method of Patent Document 1, and has the same effect as placing a large number of wells like the SWP construction method, and the entire target area can be uniformly vaporized by vacuum. We can expect effects such as being able to promote.
Moreover, since the effect can be expected without providing many large wells as in the SWP method, a large cost reduction can be expected.
With this method, one small well can exhale and inhale air.

"Installation of small wells"
The small well is basically drilled to a predetermined depth using a rod and used as it is as a small well.
For the material, boring rods and steel pipes of the same shape, such as gas pipes, are processed into rod specifications and used as a total loss.
Since the tip uses a metal crown, the hole is drilled with the same diameter.
(Φ≈40-50mm)
As a result, in the case of pressurized air and intake air, since there is no clearance from the natural ground, there is no need for a packer (blow prevention material) or the like, construction is easy, and cost performance can be achieved.
Moreover, since it can be used as it is as a pressure feed / intake pipe after drilling, time and cost can be reduced.

"Installation of mobile small wells"
(Embodiment 3)
FIG. 3 shows a construction method according to a third embodiment to which the present invention is applied. 6 is a small well (boring rod), 61 is a metal crown, 65 is a plunger pump, 66 is an air / water supply pipe, and 7 is a boring machine. .

Instead of the small well 4 of the second embodiment described above, a plurality of (two in the illustrated example) small wells are formed by the boring rod 6 as illustrated.
That is, the boring rod 6 is hollow and has a metal crown 61 at the lower end (tip), is held by the boring machine 7, and is screwed and added by the progress of excavation.

An air / water supply pipe 66 connected to a plunger pump 65 on the ground is connected to each of the plurality of boring rods 6.
The small well 6 formed by the plurality of boring rods is supplied with air and water by a plunger pump 65, and the air and water are respectively pumped from the lower end into the ground.

  As described above, after excavating to a predetermined depth with a plurality of small wells (boring rods) 6 with a plurality of small wells (boring rods) 6 and continuing to send pressurized air and water with the plunger pump 65, the boring machine 7 Slide the small well (boring rod) 6 and raise it by about 0.5m while continuing to send air and water in the back step.

"Installation of fixed small wells"
The installation method is the same as that of the well type, but after installation, it is possible to perform pressure feeding by the step type using the inner pipe.

(Embodiment 4)
FIG. 4 shows a construction method according to a fourth embodiment to which the present invention is applied. 8 is a small well, 81 is a vent hole, 85 is a large compressor, and 86 is an air supply pipe.

Instead of the small well 4 of the second embodiment described above, a small well 8 is provided as illustrated.
In this small well 8, a plurality of vent holes 81 are formed stepwise in the depth direction, and a plurality of (two in the illustrated example) connected to the large compressor 85 on the ground are sent inside. A trachea 86 is introduced.
Air is pumped into the ground from the air vent 81 below the lower end of the air supply pipe 86.

  As described above, as in Embodiment 2 described above, in the small well 8, the air is continuously pumped into the ground from the vent hole 81 below the lower end of the air supply pipe 86 while gradually raising the plurality of air supply pipes 86. .

"Intake of fixed small well"
In the case of intake, the entire intake is performed.

(Embodiment 5)
FIG. 5 shows a construction method according to a fifth embodiment to which the present invention is applied, wherein 9 is a small well, 90 is a filter, 91 is a vent hole, 95 is a vortex pump, 96 is an intake pipe, and 97 is a lid.

Instead of the large well 3 of the second embodiment described above, a small well 9 is provided as shown.
The small well 9 is provided with a 3D (three-dimensional) filter 90 in the lower end opening, and a plurality of vent holes 91 are formed stepwise in the depth direction. It is closed with a lid 97 connected to an intake pipe 96 connected to a pump 95.

In addition, the small well 9 is provided with the 3D type filter 90 in the lower end opening, so that water can be fed during drilling and inflow of earth and sand can be prevented even during suction.
The vent hole 91 has a hole diameter of about φ = 1.5 to 3.5 mm in order to prevent sand inflow.

  As described above, as in the above-described second embodiment, the small well 9 continues to suck water and air in the ground from the 3D filter 90 in the lower end opening and the plurality of ventilation holes 91 step by step in the depth direction.

  As described above, the effects of the small well are as follows.

“Use small wells for suction vaporization”
Even if a large well is not used for promoting vaporization of vacuum, a small well can sufficiently suck in air to make a vacuum state, which can greatly reduce the cost.
Also, by installing a large number in the entire area, unevenness in vacuum drying and purification can be prevented.

“Use compressed air as a preload”
By using a compressor to pump the viscous soil and its lower sand layer, there is some blow to the ground surface, but it remains in the ground as residual pressure.
The residual pressure is P = 3.0 to 7.0 kg / cm ² , comparable to the embankment load of WP = 30 to 70 t / m ² , corresponding to the embankment height of loading embankment H = 18 to 41 m, The consolidation stress is very large and effective.
Since there is almost no pore water pressure in the soil after vacuum evaporation, it can be easily compressed.
Also, it can be compressed densely in order to step and consolidate.
In the case of embankment, although the stress load on the ground surface is large, the stress is reduced as the load becomes deeper because the load is dispersed.
As for purification, air can be blown directly at the place, so that the purification is fast and unevenness can be prevented.

“Effective as an anti-liquefaction measure”
1) In the sand layer, air trapping of 5% or more of the gap can be performed by evacuating the air once and then sending air pressure, which is effective for preventing liquefaction.
2) With the above work, the relative density of sand increases due to the cleaning effect, which is effective for preventing liquefaction.
Even in clay soil, the strength is increased by the effect of the construction method of Patent Document 1, which is effective in preventing liquefaction.

"problem"
Unsaturated ground after the water level has been lowered by SWP has pore water and adhering water, so if it is sucked from the suction hole (suction pipe of the ground) with a vortex blower or an oil-type vacuum pump, the water is vaporized and sucked As a result, cavitation occurs in the vortex blower and the pump is heated, the rotary fan expands and locks, the vortex blower and the vacuum pump fail, and the subsequent suction cannot be performed.

(Embodiment 6)
FIG. 6 shows the construction method of the sixth embodiment to which the present invention is applied. FIG. 7 is an enlarged view of the ground part. 101 is a large well, 102 is a strainer, 103 is a pump, 104 is an inner pipe, 105 is an intake pipe, 106 is a vacuum pump, 107 is a suction pipe, 108 is an intake pipe, 109 is a vortex blower, 111 is a small well, 112 is a suction pipe, 113 is a gas-liquid separator, 114 is a gas-liquid separation filter, 115 is An intake pipe 116 is a water supply pipe.

  As shown in the figure, a large well 101 made of one SWP and one small well 111 are installed at a predetermined interval on the target ground.

The large well 101 is provided with an inner pipe 104 having a strainer 102 and a pumping pump 103 at the bottom and a suction pipe 107 along the periphery thereof.
On the ground, a pumping pipe (not shown) is connected to the inner pipe 104, and a vacuum pump 106 is connected via a suction pipe 105.
Underground water and air are sucked into the large well 3 by the pumping pump 103 and the vacuum pump 106 via the lower and middle strainers 102.

  A vortex blower 109 is connected to the suction pipe 107 via an intake pipe 108 on the ground. The vortex blower 109 sucks only air.

In addition, a gas-liquid separation device 113 is connected to the small well 111 via a suction pipe 112 on the ground. The gas-liquid separation device 113 has a gas-liquid separation filter 114 built therein.
Furthermore, a vortex blower 109 is connected to the gas-liquid separator 113 via an intake pipe 115 at the top, and an inner pipe 104 is connected to the bottom via a water supply pipe 116.

“Suction around the large well (SWP) 101”
As gas-liquid separation, a suction pipe 107 is provided around the large well (SWP) 101 in advance, and the pressure inside the filter material (strainer 102) of the well is negative. Therefore, this filter part (strainer 102) is vortex blower 109. Inhalation can promote the vacuum evaporation of unsaturated ground.
Since the degree of vacuum in the SWP well is a high vacuum of about Pv = −0.04 to −0.085 MPa, moisture is sucked from the well and the degree of vacuum of the vortex is Pv = −0.02 to −0. As low as 0.035 MPa, the vortex blower 109 can mainly suck a large amount of air by this pressure difference, and the vacuum vaporization is promoted.

"Suction system for small well 111"
When the unsaturated ground is directly sucked by the suction pipe 107 or the small well 111, the vortex blower 109 or the like breaks down because it is sucked as water vapor as described above.
Therefore, a gas-liquid separation device 113 is provided between the small well 111 and the vortex blower 109, and air can be continuously sucked by a system that sucks air into the vortex blower 109 and moisture into the SWP and the vacuum pump.

Here, in a normal gas-liquid separator, when the water in the tank rises as a water level, water is directly sucked by a pump.
However, in the gas-liquid separator 113, water is sucked through the pinhole using a high negative pressure at the bottom of the tank, but the negative pressure does not affect the negative pressure of the vortex blower 109 because the amount of water absorption is small. .

As described above, according to the sixth embodiment, the heavens of the sand layer and the viscous soil are evacuated (negative pressure) by the vortex blower 109 by the suction pipe 107 and the small well 111.
As a result, the boiling point temperature of the water is lowered and the interstitial water expands as water vapor, and is sucked and discharged to the ground surface by the suction pipe 107 and the small well 111, and the ground is dried.
At this time, the pore water pressure is negative, and it does not become excessive pore water pressure at the time of an earthquake, and liquefaction can be prevented.

DESCRIPTION OF SYMBOLS 1 Well for pressure water supply 10 Strainer 11 Water tank 12 Water supply pump 13 Water supply pipe 15 Large compressor 16 Air supply pipe 2 Well for intake of pumping water 20 Strainer 21 Water pump 22 Inner pipe,
23 Pumping pipe 25 Vacuum pump 26 Suction pipe 3 Large well 30 Strainer 31 Pumping pump 32 Inner pipe 4 Small well 45 Large compressor 46 Air supply pipe 5 Boring machine 6 Small well (boring rod)
61 Metal Crown 65 Plunger Pump 66 Air / Water Supply Pipe 7 Boring Machine 8 Small Well 81 Ventilation Hole 85 Large Compressor 86 Air Supply Pipe 9 Small Well 90 Filter 91 Ventilation Hole 95 Vortex Pump 96 Intake Pipe 97 Lid 101 Large Well 102 Strainer 103 Pumping Pump 104 Inner pipe 105 Intake pipe 106 Vacuum pump 107 Suction pipe 108 Intake pipe 109 Vortex blower 111 Small well 112 Suction pipe 113 Gas-liquid separation device 114 Gas-liquid separation filter 115 Intake pipe 116 Water supply pipe

Claims (1)

Two small wells are installed on the ground at a predetermined interval,
While pumping air from one small well into the ground,
A ground improvement method that sucks air from the other small well ,
Forming air intake holes at predetermined depth intervals in the other small well;
A ground improvement method characterized in that a suction by a vortex pump is applied to the other small well .

Images