JP2022125587A - Compressed boring system - Google Patents

Abstract

To provide a boring system capable of balancing a groundwater pressure, a drilling water pressure, and a drainage pressure during ground boring.SOLUTION: A boring system 1 includes: drilling means 2 that bores a ground; water supply means 5 that supplies drilling water to the drilling means 2; drainage means 3 that drains drained mud water W2 generated due to boring of the ground G; and drained mud processing means 4 interposed between the water supply means 5 and the drainage means 3. The drained mud processing means 4 separates the drained mud water W2 into slime and drilling water under pressure and supplies the drilling water to the water supply means 5.SELECTED DRAWING: Figure 1

Description

The present invention relates to pressure drilling systems.

BACKGROUND ART In the construction of underground structures such as tunnels, there are cases in which holes are drilled into the ground under pressure from within the underground structure for the purpose of soil improvement work. When drilling a hole in the confined ground, groundwater spouts out from the drilling hole, causing excessive discharge of earth and sand, which affects the surrounding ground and may lead to subsidence of the ground surface. Therefore, when drilling a hole in the confined ground, the water pressure inside the drilled hole is kept equal to or higher than the groundwater pressure in the surrounding ground, thereby controlling the amount of sediment that is discharged with the groundwater. A common method is to prevent the impact on

For example, Patent Document 1 discloses a drilling system for drilling a pressurized ground, which includes drilling means, water supply means for supplying drilling water to the drilling means, and drainage for discharging mud water generated by drilling. means and control means for controlling the amount of water supplied by the water supply means and the amount of water discharged from the drainage means. According to the drilling system of Patent Document 1, since the amount of water supply and the amount of drainage are controlled by the control means, the lowering of the groundwater level is suppressed by discharging the sludge water according to the amount of water supply. Further, the drilling system of Patent Document 1 circulates the drilling water by reusing the water from which the soil is separated in the soil separation tank as the drilling water.

JP 2008-069531 A

In the drilling system of Patent Document 1, since the sludge is discharged from the excavating means into the sediment separation tank in the atmosphere, the sediment in the surrounding ground loosened during drilling is combined with the pressure difference between the excavation means and the sediment separation tank. may also be discharged. When excess earth and sand are discharged from the ground, there is a risk of forming cavities in the ground. When cavities are formed in the ground, the amount of filling material to be filled in the cavities increases, which may increase the work and cost of construction.

From this point of view, an object of the present invention is to propose a drilling system capable of balancing groundwater pressure, excavation water pressure and drainage pressure during ground drilling.

In order to solve the above problems, the present invention provides an excavating means for drilling a ground, a water supply means for supplying excavating water to the excavating means, a drainage means for draining mud water generated by drilling the ground, The drilling system is provided with sludge treatment means interposed between the water supply means and the drainage means. The mud discharge treatment means separates the mud discharge water into excavation soil or excavation waste soil (hereinafter referred to as slime) and the excavation water under pressure, and supplies the excavation water to the water supply means.

According to this drilling system, the sludge water discharged from the drilling means is supplied to the sludge treatment means for separating the sludge water into slime and the drilling water under pressure. Water pressure can be balanced between the treatment means. In other words, it is possible to minimize the intake of earth and sand and groundwater from the ground around the excavated hole that has been loosened during drilling. Therefore, it is possible to suppress the formation of cavities in the ground.

When the drilling system drills the ground from inside the tunnel pit, it is preferable to provide the excavating means, the drainage means and the sludge disposal means inside the tunnel pit. In this way, only the excavated water needs to be sent to a plant (hereinafter referred to as a plant) that discharges mud outside the tunnel. A water pipe (sludge pipe) can be used. Moreover, even if the distance from the excavating means to the plant is long, it is possible to omit or reduce the size of the pump used for conveying water to the plant, which is economical.

According to the drilling system of the present invention, by stabilizing the balance of groundwater pressure, drilling water pressure, and drainage pressure during ground drilling, it is possible to minimize the intake of groundwater and earth and sand from the drilling hole. Become.

1 is a schematic diagram of a drilling system according to an embodiment of the invention; FIG.

In this embodiment, the drilling system 1 for drilling the ground G from the inside of the tunnel T to form the excavated hole H during construction of the watertight tunnel (tunnel T) will be described. The tunnel T of this embodiment is a shield tunnel, and is formed by excavating the ground G and arranging segments.
A drilling system 1 of the present embodiment includes, as shown in FIG.

The excavating means 2 is a device for drilling the ground G, and is provided in a tunnel pit. The excavating means 2 of this embodiment includes an excavator main body 21 , a casing pipe (or drilling rod) 22 , a bit 23 and a water stop box 24 .
The excavator main body 21 applies rotational force to the casing pipe 22 and supplies the casing pipe 22 with drilling water (mud water W ₁ ) supplied from the water supply means 5 .

The casing pipe 22 is made of a pipe material. The casing pipe 22 is made to have a predetermined length by appropriately connecting pipe materials according to the depth of the drilled hole H to be formed. A bit 23 is fixed to the tip of the casing pipe 22 . Mud water W ₁ supplied from the excavator main body 21 is supplied to the bit 23 through the casing pipe 22 .

The bit 23 is fixed to the tip of the casing pipe 22 and rotates as the casing pipe 22 rotates. A plurality of injection holes (not shown) are formed in the bit 23, and the muddy water W1 supplied through the casing pipe 22 is injected toward the _ground G. The bit 23 is also provided with a check valve 25 to prevent the groundwater _WG from flowing back into the casing pipe 22 through the injection hole. Note that the check valve 25 does not necessarily have to be provided on the bit 23, and the mounting location of the check valve 25 is not limited.

The water stop box 24 is provided at the mouth of the excavation hole H. As shown in FIG. The casing pipe 22 is inserted through the water stop box 24 . The water stop box 24 is fixed to a partition wall S (a segment of the tunnel T in this embodiment) formed along the ground G. As shown in FIG. The water cutoff box 24 covers the base end of the drilled hole H (the opening of the hole mouth), passes through the gap between the drilled hole H and the casing pipe 22, and drains the mud water discharged along the casing pipe 22 ( Turbid water) Collect _W2 . The water stop box 24 is connected to the drainage means 3 and supplies the drainage means ₃ with the mud water W2 discharged from the excavation hole H.

The drainage means 3 is a pipeline provided between the excavation means 2 and the mud discharge treatment means 4, and drains mud water (turbid water) W2 ₍ muck, groundwater WG and muddy water) generated by drilling the ground _G. W ₁ , etc.) is transported to the sludge treatment means 4 . That is, the drainage means 3 is a pipeline provided in the pit of the tunnel T. As shown in FIG. The drainage means 3 is provided with a first valve 61 at a connection portion with the water stop box 24 and a second valve 62 at a connection portion with the sludge disposal means 4 . The first valve 61 and the second valve 62 are valves for opening and closing the flow path of the drainage means 3, and are centrally controlled by the control means 6 in this embodiment.

The mud discharge treatment means 4 is interposed between the drainage means ₃ and the water supply means 5, and separates the mud discharge water W2 into slime and separated water W3 ₍ drilling water). The sludge disposal means 4 of this embodiment is provided in the pit of the tunnel T. As shown in FIG. The sludge treatment means ₄ is hermetically sealed and separates the sludge water W2 into _slime and separated water W3 under pressure. The device that constitutes the sludge treatment means ₄ is not limited as long as it can separate the sludge water W2 into the separated water _W3 and the slime in a pressurized state. A sediment separator, sedimentation tank, etc. that are configured to be able to pressurize the inside can be used.

As shown in FIG. 1 , the sludge treatment means 4 is connected to the drainage means 3 via the second valve 62 and is connected to the water supply means 5 via the third valve 63 . Further, the sludge disposal means 4 of this embodiment is provided with a pressure control valve 64 for adjusting the internal pressure.

The water supply means 5 supplies drilling water to the drilling means 2 . The water supply means 5 may be provided inside the tunnel pit, or may be provided outside the tunnel pit. The water supply means 5 of this embodiment includes a pump 51, a mud tank 52, and a water pipe 53, as shown in FIG. A third valve 63 is provided at the junction between the water supply means 5 and the sludge treatment means 4 .

Separated water W ₃ supplied from the sludge treatment means 4 is supplied to the sludge making tank 52 through the water pipe 53 . _In the mud making tank 52 _, the separated water W3 and the mud addition material are mixed to generate mud water W1 (drilling water). Mud water W ₁ produced in the mud tank 52 is sent to the excavating means 2 via the pump 51 .

The control means 6 controls the first to third valves 61 to 63 and the pressure regulating valve 64 . That is, the control means 6 controls the first valve 61, the second valve 62, the third valve 63 and the pressure regulating valve 64 according to the measured value of the pressure gauge (not shown) provided in the sludge treatment means 4. to automatically adjust the pressure state of the drilling system 1.

When the drilling system 1 operates, drilling of the natural ground by the drilling means 2 is started. At this time, drilling water (muddy water) is supplied from the water supply means 5 to the drilling means 2 . That is, the excavating means 2 supplies muddy water W ₁ (drilling water) to the ground G and cuts the ground G with the bit 23 by rotating the casing pipe 22 .

When the ground G is drilled by the drilling means 2, the muck generated by drilling is discharged from the drilling hole _H as mud water W2 _together with groundwater WG and the like. The sludge water W ₂ is supplied to the sludge treatment means 4 via the drainage means 3 . At this time, the first valve 61 and the second valve 62 are opened, and the third valve 63 is closed. By doing so, the inside of the mud discharge treatment means 4 is filled with the mud water (drilling water and slime).

Before the inside of the sludge treatment means ₄ is filled with the sludge water W2, the pressure control valve 64 is opened to exhaust the air in the sludge treatment means 4. FIG. Then, when the inside of the sludge disposal means ₄ is filled with the sludge water W2, the pressure regulating valve 64 is closed to put the inside of the sludge disposal means 4 into a pressurized state. At this time, the inside of the sludge treatment means 4 is made equal to or higher than the underground pressure of the ground G. In this way, the pressure in the drilling system 1, the pressure in the borehole H, and the subsurface pressure in the ground G are balanced, and drilling of the borehole H is performed in a state in which loosening of the ground is suppressed. It can be performed.

When the sludge treatment means ₄ is filled with the sludge water W2 (when the pressure in the sludge treatment means 4 becomes equal to the pressure under the ground G), the third valve 63 is opened to open the sludge treatment means. ₄ to discharge the separated water W3. At this time, the slime separated in the sludge disposal means 4 is stored in the sludge disposal means 4 or an attached device (not shown).

Separated water W ₃ drained from the sludge treatment means 4 is supplied to the water supply means 5 . In the water supply means 5 , mud is added to the separated water W ₃ in the mud making tank 52 to generate mud water W ₁ . Mud water W ₁ produced in the mud tank 52 is supplied to the excavating means 2 via the pump 51 . Thus, the drilling system 1 of this embodiment circulates the drilling water used for drilling the drilling hole H. As shown in FIG.

The slime stored in the mud discharge processing means 4 or attached equipment is removed after the drilling of the drilling hole H is completed. The timing of removing the slime is not limited, and may be done at the end of the day's work, for example.

As described above, according to the drilling system 1 of the present embodiment, the mud discharge treatment means ₄ separates the mud water W2 discharged by the drilling means ₂ into the slime and the separated water W3 under pressure. , the water pressure can be balanced between the ground water pressure in the ground G and the sludge treatment means 4 . That is, since the pressure balance is ensured between the inside of the borehole H and the ground _G around the borehole H, earth and sand and groundwater WG are taken in from the ground around the borehole H that is loosened during drilling. can be minimized. Therefore, it is possible to suppress the formation of cavities in the ground G, and to omit an auxiliary construction method such as filling work for filling the cavities.

In addition, since the excavation means ₂ , the drainage means 3, and the sludge treatment means 4 are provided in the tunnel pit, only the excavated water needs to be sent to the water supply means 5 (plant) outside the tunnel pit. As compared with the case of draining to the outside of the tunnel, a water pipe (sludge pipe) with a small diameter can be used as the drainage means 3. Moreover, even if the distance from the excavating means 2 to the water supply means 5 is long, the pump used for supplying water to the water supply means 5 can be omitted or scaled down, which is economical.

The flow of drilling water and the pressure in the drilling system 1 are adjusted by automatically adjusting the first valve 61, the second valve 62, the third valve 63, the pressure regulating valve 64, etc. by the control means 6. , which is superior in workability compared to manual operation. In addition, since the pressure balance is ensured via the control means ₆ , it is possible to suppress the ejection of groundwater WG, mud water _W2 , and the like.

Although the embodiment of the present invention has been described above, the present invention is not limited to the embodiment, and each component can be changed as appropriate without departing from the scope of the present invention.
_In the above embodiment, the case where the mud W1 is used as the drilling water has been described, but the drilling water is not limited to the mud _W1 , and may be fresh water. _In this case, the mud tank 52 may be omitted and the separated water W3 may be used as it is as the drilling water.

Further, in the above-described embodiment, the case of drilling the excavation hole H from inside the tunnel has been described, but the place where the drilling system 1 of the present invention is used is not limited.
Further, in the above-described embodiment, the case where the sludge disposal means 4 is arranged inside the tunnel pit has been described, but the sludge disposal means 4 may be arranged outside the tunnel pit. Further, although the water supply means 5 is arranged outside the tunnel pit, the water supply means 5 may also be arranged inside the tunnel pit.

A double pipe may also be used for the casing pipe 22 . When the casing pipe 22 is a _double pipe, the drilling water may be supplied from the gap between the inner pipe and the outer pipe while the mud water W2 may be discharged from the inner hollow portion of the inner pipe. _The mud water W2 may be drained from the gap between the inner pipe and the outer pipe while the drilling water is supplied from the empty portion.
Moreover, the drain means 3 and the water supply means 5 may be provided with pressure detectors as required. In this way, the pressure can be adjusted more reliably.

1 drilling system 2 drilling means 3 drainage means 4 sludge treatment means 5 water supply means 51 pump 52 mud tank 6 control means 61 first valve 62 second valve 63 third valve 64 pressure regulating valve G ground H drill hole T tunnel W ₁ muddy water (drilling water)
W2 _Drained water W3 Separated water ₍ drilling water)

Claims (2)

excavating means for drilling the ground;
water supply means for supplying drilling water to the drilling means;
Drainage means for draining mud water generated by drilling holes in the ground;
a drilling system comprising a sludge treatment means interposed between the water supply means and the drainage means,
The drilling system, wherein the mud discharge treatment means separates the mud discharge water into the slime and the drilling water under pressure, and supplies the drilling water to the water supply means. 2. The drilling system according to claim 1, wherein said drilling means, said drainage means and said mud discharge treatment means are provided in a tunnel pit.

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