KR102560842B1 - a functional groundwater level lowering device and the groundwater level lowering method using thereof - Google Patents

Abstract

The present invention relates to an underground water level lowering device and an underground water level lowering method using the same and, more specifically, to a functional underground water level lowering device and an underground water level lowering method using the same, which can efficiently pump and remove underground water or percolating water mixed in the ground in a stratum structure consisting of soil and sand with a low permeability coefficient such as nonplastic silt or a weathered zone layer. The present invention provides a water intake pipe (100) including a pipe body part (110), a suction water intake part (120), and a flow velocity uniformity part (130). Also, the underground water level lowering device (1000) comprises the water intake pipe (100) and further comprises a suction pump (200) including a vacuum pump (230), an underwater pump (240), and a control device (250). In addition, the underground water level lowering method comprises: a process (first process) of forming an insertion port into which a water intake pipe (100) is to be inserted in a target area of which the underground water level is to be reduced; a process (second process) of inserting the water intake pipe (100) into an insertion pipe formed in the target area; a process (third process) of connecting the water intake pipe (100) to a header pipe (211); and a process (fourth process) of discharging underground water of the target area by operating a suction pump (200).

Description

Functional groundwater level lowering device and the groundwater level lowering method using the same {a functional groundwater level lowering device and the groundwater level lowering method using it}

The present invention relates to a device for lowering the groundwater level and a method for lowering the groundwater level using the same, and more specifically, infiltration that is mixed in the ground in a stratum structure made of soil having a low permeability coefficient such as a weathered zone layer or non-calcined silt. It relates to a functional groundwater level reduction device capable of efficiently pumping and removing water or groundwater, and a groundwater level reduction method using the same.

When constructing a structure at a location lower than the groundwater level, infiltration water such as groundwater seeping out from the ground or rainwater pooling into the excavation ground can act as a cause of collapse of the excavation slope and make the work site very poor conditions, so it must be excluded.

In particular, the granite weathering zone layer is distributed throughout the country to a considerable depth throughout the country, and in the case of coastal areas or dredged reclamation areas, it consists of a fine-grained sedimentary layer. It has a characteristic of 1×10-4cm/sec or less, so if the ground is excavated below the groundwater level, infiltrate or groundwater will inevitably accumulate at the excavation point, hindering the progress of the construction.

As a method of draining the infiltrated water or groundwater generated in this way to the ground, a well-collecting well method and a well point method have been conventionally known.

The collecting well construction method is carried out by building a collecting well near the construction site and discharging the water collected in it to the outside using a submersible pump. In the ground with a low coefficient of permeability, the amount of water collected is small, making it inefficient.

In the well point method, a number of water intake pipes are vertically buried at approximately 15m intervals at the excavation point, and the top of the water intake pipes exposed to the ground is connected to a header laid on the ground, so that groundwater pumped by a vacuum pump is forcibly drained through the header. As a method for making it, unlike the above-mentioned collection method, it has the advantage of being able to be carried out regardless of the type or property of the stratum.

1 is a view showing a conventional well point method, in which water intake pipes 2 are vertically buried at regular intervals according to a construction site, and the ground end of each water intake pipe 2 is connected to a header 4 disposed on the ground. Also, the header 4 is connected to a vacuum pump not shown.

The vacuum pressure of the header 4 pumps underground water through the filter 6 disposed at the lower end of the water intake pipe 2 and collects and drains water through the header 4 to one place.

In the well point with such a configuration, the theoretical vacuum pressure acting on the water intake pipe 2 reaches 10 m in head, but when applied to the actual well point method, it is impossible to pump water more than 6 m with the vacuum pressure, so the depth of the ground water level drop is usually planned and constructed within a range of 5m or less.

For this reason, in the well point method, whenever the excavation surface 8 is excavated at a location lower than the underground depth of 5 m at the construction site, a new well point having the same configuration is additionally installed to exclude groundwater at a low underground depth.

However, this method is inconvenient to install additional well points as the excavation depth of the construction site increases, resulting in a longer construction period and higher construction costs. This has not been established and is being implemented as it is.

In order to solve the above problems, as a related technology, the registered patent (No. 10-0719444, hereinafter referred to as Prior art 1) "a method for lowering the ground water level and a well point system suitable for this" is,

As shown in FIG. 1B, "an outer casing with a ball valve disposed at the bottom and a packer installed on the outer circumference, an inner casing concentrically disposed at the center to form a circulation passage and a suction passage, and a wide side accommodated in the lower portion of the outer casing A water intake pipe assembly composed of a venturi tube with an inlet and a narrow outlet is placed vertically on the surface of the earth, and pressurized water is supplied to the suction passage at the center of the inner casing, and a water jet ejected to the lower end of the outer casing is projected from the surface of the earth. It is drilled to the depth and buried, and the upper sides of the inner and outer casings are connected to the supply-side header and the drainage-side header on the ground through the supply-side conduit and the drain-side conduit, respectively, and then the packer is inflated to form a space between the perforation on the surface and the outer casing. is blocked, and the pressure water generated by the feed water pump disposed between the supply-side header and the drain-side header is supplied through the circulation passage of the outer casing, and the surroundings of the lower negative pressure passage of the inner casing are evacuated while passing through the venturi tube. Thus, a well point system having a configuration in which groundwater penetrating into the lower portion of the outer casing is pumped through the suction passage of the inner casing has been provided.

In addition, in order to solve the above problems, a registered patent (No. 10-1841511, hereinafter Prior Art 2) is a "groundwater forced drainage device" as a related technology,

As shown in FIG. 1c, "a double cylindrical structure in which drilling water transport pipes are vertically embedded, and a ball valve built-in injection nozzle for spraying high-temperature and high-pressure drilling water is provided at the end to spray drilling water at high pressure in the form of a water jet to excavate. A venturi-type water intake structure that vertically punctures the site and forcibly suctions and discharges groundwater taken in by a vacuum pump on the ground to the ground via a groundwater drainage passage formed in the space between the built-in pipe and the exterior casing,

A well point that suctions and pumps groundwater to the outer circumference with a length that evenly covers the entire range of soil layers buried in the ground where the aquifer, sand layer, clay layer, and silt layer are mixed and stacked. The compound synergistic effect of the pump's pumping suction power, in which the strong suction power is added, can be applied to all soil types, realizing the target ground expansion effect that can be carried out regardless of the type or property of the stratum, thereby covering the entire range of soil layers in the construction area. A groundwater forced drainage device that enables dry work by lowering the groundwater level has been provided.

In addition, as shown in FIG. 1d, the intake pipe of the groundwater forced drainage device used in the conventional well point is made of metal, so it is heavy and inconvenient to construct, and the strainer of the intake pipe Through this, when the groundwater inflows, the flow rate rapidly increases, sand flows in together, and internal cavities are generated, resulting in the problem of accumulation of internal sludge, which causes the inconvenience of surging work, which delays work and improves work efficiency. There is a problem that significantly deteriorates.

In the present invention, the intake pipe of the groundwater forced drainage device used in the foregoing prior art and prior art forced drainage method (well point) is made of a metal material, so it is heavy and inconvenient to construct, and it is difficult to perform surging work. If you had to do it, there were a lot of difficulties in the work,

It is intended to provide a water intake pipe for a groundwater level lowering device to solve this problem,

In addition, the above prior art and prior art have a problem in that when groundwater flows in through the strainer of the water intake pipe of the groundwater level lowering device, the flow rate rapidly increases, sand is introduced together, and an internal cavity is generated, causing internal sludge to accumulate, resulting in surging ( There was a problem of delaying work and significantly reducing work efficiency due to the inconvenience of having to do surging work.

To solve this problem, it is intended to provide a groundwater level lowering device and a groundwater level lowering method using the same.

In addition, in the above prior art and prior art, since the water intake pipe of the groundwater level lowering device is made of metal (iron material), the cost and construction time are high, so there are many problems in terms of cost and time.

To solve this problem, it is intended to provide a groundwater level lowering device and a groundwater level lowering method using the same.

In order to solve the above problems and needs, the present invention

A water intake pipe 100 configured to include a pipe main body 110, a suction intake unit 120, and a flow rate homogenization unit 130 is provided.

In addition, the present invention includes the above water intake pipe 100,

A groundwater level lowering device 1000 including a suction pump 200 including a vacuum pump 230, a submersible pump 240, and a control device 250 is provided.

In addition, the present invention is a process of forming an insertion hole into which the water intake pipe 100 is to be inserted in the target area in which the groundwater level needs to be reduced (step 1);

The process of inserting the water intake pipe 100 into the insertion tube formed in the target area (step 2);

The process of connecting the intake pipe 100 to the header pipe 211 (step 3);

The process of discharging groundwater in the target area by operating the suction pump 200 (step 4);

It provides a groundwater level reduction method comprising a.

The intake pipe of the groundwater forced drainage device used in the foregoing prior art and prior art forced drainage method (well point) is made of metal and is heavy, which is inconvenient and inconvenient to construct and requires surging work. While there are a lot of difficulties in the work if you have to,

Since the water intake pipe of the groundwater level lowering device according to the present invention is made of a polymer material resin and is light in weight, it is very easy to construct, so the work efficiency is remarkably improved.

In addition, the water intake pipe of the groundwater level lowering device according to the present invention is additionally configured with a flow rate homogenization portion to make the flow rate inside the pipe body portion uniform, so there is no problem of internal sludge such as sand, clay, etc. It has the effect of significantly increasing efficiency.

In addition, in the above prior art and prior art, since the water intake pipe of the groundwater level lowering device is made of metal (iron material), it is expensive and heavy, so there are many difficulties in construction and a lot of construction time, so there are many cost and time problems. bar,

The functional groundwater level lowering device according to the present invention is made of a polymer material (plastic material), so the weight is significantly smaller than that of the prior art made of metal (iron material), so the operator's convenience in construction is significantly improved, and in addition, the polymer material material (Plastic material), the manufacturing cost is remarkably low, so it is very economical and has the effect of remarkably increasing the efficiency of construction by shortening the construction time.

1 to 1d show a conventional well point method and a water intake pipe used therein.
Figure 2 is a structural diagram of the water intake pipe of the ground water level lowering device according to the present invention.
Figure 2b is a detailed structural view of the intake pipe of the groundwater level lowering device according to the present invention.
Figure 2c is a structure diagram of the water intake of the intake pipe of the groundwater level lowering device according to the present invention.
3 is a cross-sectional structure diagram of a water intake pipe of the groundwater level lowering device according to the present invention (a detailed view of a flow rate homogeneous part).
Figure 3b is a working diagram (groundwater flow diagram) of the flow rate homogenization part in the intake pipe of the groundwater level lowering device according to the present invention.
4 is a structural diagram of a groundwater level lowering device according to the present invention.
5 is a flow chart of a ground water level lowering method using the ground water level lowering device according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

The present invention is a ground improvement device for preventing collapse of an excavated surface due to water flowing out from soft ground during various constructions such as excavation work, using high pressure water and vacuum to form a vacuum and forcibly drain underground water by a mechanical method. A water intake pipe 100 used in a groundwater level lowering device is provided.

In addition, the present invention provides a functional groundwater level lowering device 1000 including the above-described water intake pipe 100.

In addition, the present invention provides a groundwater level lowering method using the functional groundwater level lowering device 1000 described above.

The water intake pipe 100 of the present invention is configured to include a pipe body portion 110, a suction intake portion 120, and a flow rate homogenization portion 130.

The pipe main body 110 of the present invention refers to a device or means such as a pipe or pipe that performs a function of sucking in and discharging groundwater.

As shown in FIG. 2, the pipe main body 110 is connected to the suction hose 210 of the suction pump 200 and is inserted into the ground to lower the groundwater to suck in the groundwater and discharge it to the outside. Do it.

The distal end 111 of the pipe main body 110 is blocked, and thus groundwater flows only into the suction intake 120.

A technical feature of the present invention is that the material of the pipe body portion 110 is made of a polymer material resin such as PVC, PE, or PP.

As described above, the intake pipe of the groundwater forced drainage device used in the conventional forced drainage method (well point) including the prior art is made of a metal material, so it is heavy and inconvenient to construct, especially clay, sand, etc. There was a problem that a lot of sludge was stuck inside, and there was a need for surging, so there was a problem that work was delayed and efficiency was greatly reduced.

The present invention has solved the above problems, and the material of the pipe body part 110 is made of a polymer material resin such as PVC, PE, PP, etc., so it is easy to manufacture and light, so it is easy to construct, thereby significantly increasing the work efficiency of the operator. There are technical features.

In the present invention, the material of the pipe body portion 110 may be a polymer material resin formed by mixing one or two or more materials selected from polyvinyl chloride (PVC), polyethylene, or polypropylene.

Preferably, it is very good in terms of specific gravity, strength and hardness to use a polymer material resin in which 20 to 30 parts by weight of polyethylene and 10 to 50 parts by weight of polypropylene are mixed with 100 parts by weight of polyvinyl chloride (PVC).

In the present invention, by including the composition for promoting resin reinforcement in the above-mentioned polymer material resin, the function of increasing the strength during the molding process of the pipe body portion 110 and performing the function of preventing cracks from occurring is performed.

It is very effective to mix 1 to 3 parts by weight of the composition for accelerating resin reinforcement based on 100 parts by weight of the polymer material resin.

The above composition for promoting resin reinforcement includes 10 to 20 parts by weight of polyoxyalkylenated alkyl ether, 10 to 20 parts by weight of polyoxyalkylenated sorbitan ester, and 10 to 20 parts by weight of polyoxyalkylenated ester in 100 parts by weight of alkylphenyl polyglycol ether. Part, means a composition prepared by mixing 1 to 5 parts by weight of polyoxyalkylenated alkylphenyl ether, 1 to 5 parts by weight of ethoxylated amide, and 1 to 5 parts by weight of polyvinyl alcohol.

The present invention performs a function of enhancing strength and hardness while lowering the specific gravity of the pipe body portion 110 by including a reinforcing agent in the polymeric material resin.

It is preferable to mix and use 0.1 to 1 part by weight of the above-described enhancer with 100 parts by weight of the polymer material resin.

As one implementation of the above enhancer, 20 to 80 parts by weight of a hydrophobic monomer having an unsaturated double bond such as stearyl methacrylate, 0.01 to 0.25 parts by weight of methylenebis acrylamide, glycidyl in 100 parts by weight of a hydrophilic monomer such as methacrylic acid An enhancer polymerized by mixing 0.05 to 0.5 parts by weight of methacrylate may be used.

In addition, the present invention increases the elasticity of the pipe main body 110 by adding a functional additive to the above-mentioned polymeric material resin and strengthens durability to significantly reduce breakage during construction.

It is preferable to include 0.5 to 5 parts by weight of the above functional additives based on 100 parts by weight of the polymer material resin.

The aforementioned functional additive is a composition containing sodium bicarbonate, ammonium phosphate, methylenebis acrylamide, glycidyl methacrylate, and methacrylic acid.

Preferably, functional additives include 100 parts by weight of sodium bicarbonate, 10 to 60 parts by weight of ammonium phosphate, 10 to 30 parts by weight of methylenebis acrylamide, 20 to 80 parts by weight of glycidyl methacrylate, and 5 to 40 parts by weight of methacrylate. It is effective to create with wealth.

The present invention enhances the acid resistance, base resistance and durability of the pipe body portion 110 by adding a reinforcing composition to the above-mentioned polymeric material resin to significantly reduce damage caused by weathering caused by acidic substances, basic substances, ultraviolet rays, temperature, etc. carry out

Preferably, the reinforcing composition includes 0.2 to 1 part by weight based on 100 parts by weight of the polymer material resin.

The reinforcing composition includes 100 parts by weight of methylmethacrylate, 80 to 130 parts by weight of Butylacrylmonomer, 1 to 20 parts by weight of Acrylonitrile, and ammonium persulfate ((NH ₄ ) ₂ S ₂ O ₈ ) 0.2 to 2 parts by weight, sodium bisulfite (NaHSO ₃ ) 0.2 to 2 parts by weight, and 2 to 10 parts by weight of an alkyl sulfonate.

The present invention adds natural additives to the polymeric material resin to significantly increase durability against fatigue due to the continuous external impact acting on the pipe body portion 110 and the action of the Chiba, and to prevent the polymer material from being oxidized and weakened. to show a high effect.

It is preferable to mix 0.001 to 0.005 parts by weight of the above natural additives based on 100 parts by weight of the polymer material resin.

The above natural additives are 80 to 120 parts by weight of Maekmundong, 80 to 120 parts by weight of Wiryeongseon, 80 to 120 parts by weight of Paeran, 10 to 30 parts by weight of Gwakhyang, 10 to 30 parts by weight of Jeolgukdae, 80 to 120 parts by weight of Suntoe, and 10 to 30 parts by weight of Banha. part, means a composition extracted by mixing 50 to 80 parts by weight of fast cutting.

As a method of extracting the above natural additives, 1000 parts by weight of 75 to 85% [mass%] ethanol was added to 100 parts by weight of the mixed raw materials, extracted under reflux for 2 to 4 hours, and the filtrate was decompressed using a rotary evaporator, It can be extracted by concentration method.

Such an extract may be extracted in a powder form in an amount of 5 to 25 parts by weight based on 100 parts by weight of the mixed raw materials, and it is preferable to add the extract in the form of a powder.

The suction water intake part 120 of the present invention is formed in the pipe body part 110 and means a structure or means that performs a function of allowing underground water to flow into the pipe body part 110.

As shown in FIGS. 2 to 2B, the intake intake 120 is formed at the distal end of the pipe body 110, and means a structure or means in which one or more intake ports 121 are formed. do.

The water intake 121 of the intake water intake 120 may be formed in various shapes such as circular, polygonal, and linear, and it is preferable to form at regular intervals along the circumference of the pipe main body 110 for inflow of ground water. do.

The intake port 121 of the present invention has a long rectangular shape so that groundwater can be stably introduced into the pipe main body 110.

As shown in FIG. 2C, preferably, the water intake 121 is formed in a rectangular shape, and the ratio (a:b) of the lengths of the width (a) and the length (b) is 1: 7 to 15. It is very effective in groundwater inflow.

It is effective that the horizontal length of the water intake port 121 is 0.4 to 0.6 mm, preferably 0.45 mm.

In addition, it is effective that two or more suction intake parts 120 of the present invention are formed from the distal end of the pipe body part 110 and are formed at a distance L in the longitudinal direction of the pipe body part 110.

In this case, the interval L is preferably formed in a size of 50 to 150% of the vertical length b of the water intake 121, which is very effective in constantly inflowing groundwater.

The technical feature of the present invention is that the water intake pipe 100 includes a flow rate homogenizing unit 130 to uniform the flow rate of groundwater flowing into the suction intake unit 120 so that sand is formed inside the pipe main body 110. The point is that it performs the function of preventing the accumulation of clay, silt, etc.

As described above, the intake pipe of the groundwater forced drainage device used in the conventional forced drainage method (well point), including the prior art, when the groundwater flows in through the strainer (intake port) of the intake pipe, the flow rate increases rapidly and sand is introduced together In addition, a cavity is generated due to the suction pressure of the suction pump 200, and sludge accumulates inside the water intake pipe, resulting in inconvenience of surging work. Accordingly, work delay and A problem that significantly reduces work efficiency occurs.

The present invention has been made to solve the above problems, and the flow rate homogenizing unit 130 is included in the water intake pipe 100 to solve such problems.

The flow rate homogenization part 130 of the present invention is formed inside the pipe body part 110 in which the suction intake part 120 is formed and means a structure or means formed in a cylindrical shape.

As shown in FIGS. 2 and 3, the flow rate homogenization part 130 is coupled to the end 111 of the suction intake part 120, and the suction intake part 120 is inside the pipe body part 110 It is formed at a height (H) greater than the height (I) of the pipe body portion 110 is formed.

As shown in FIG. 3, the flow rate homogenizing unit 130 is formed in a cylindrical shape having a diameter D1 and a height H.

Preferably, the diameter D1 of the flow rate homogenizing portion 130 is 25 to 80% of the inner diameter D2 of the pipe body portion 110, more preferably 40 to 60% It is effective to be formed. .

In particular, in the present invention, the inner diameter D2 of the pipe body portion 110 is formed to be 30 to 50 mm and the diameter D1 of the flow rate homogenization portion 130 is formed to be 15 to 30 mm. 110), the flow rate becomes constant when flowing into the inside, so that the action and effect of preventing clay and sand from flowing in appear.

Figure 3b shows the flow line (stream line) (S) of the underground water inside the pipe body portion 110 of the flow rate homogenizer 130 of the present invention.

Here, looking at the flow line S of groundwater, the water intake 121 of the flow rate homogenization part 130 has a rectangular shape, so that the groundwater flows into the pipe main body 110 in a linear form through the water intake, and the flow rate increases. Although it is rapidly accelerated, the inflowing groundwater collides with the flow rate homogenizer 130 and is bent at right angles in the upstream direction, forming a flow line and forming a vortex, so that the flow rate drops rapidly.

The action of the flow rate homogenizing unit 130 solves the problem of sludge accumulating inside the pipe body 110, thereby preventing work delay and significantly improving work efficiency.

The flow rate homogenizing part 130 of the present invention is preferably made of the same material as the material of the pipe body part 110 described above.

The present invention provides a groundwater level lowering device (1000) in which one or two or more of the water intake pipes (100) are configured, and the water intake pipes (100) and the suction pump (200) are connected.

The suction pump 200 of the present invention includes a vacuum pump 230, a submersible pump 240, and a control device 250.

The above-described suction pump 200 may further include a groundwater level detection sensor 260, and may be configured by being connected to the suction hose 210 and the discharge hose 220.

As shown in FIG. 4, the vacuum pump 230 is connected to the suction hose 210 and provides a vacuum function to the suction hose to pull up groundwater through the water intake pipe 100 connected to the suction hose. means a device or means for

The above-described vacuum pump 230 may be equipped with a vacuum pump backflow preventer 231 to perform a function of preventing water from flowing back to the vacuum pump.

The above-described submersible pump 240 is connected to the discharge hose 220, and is a device that functions to discharge groundwater in the tank 201 of the suction pump 200 pulled up by the vacuum pump 230 to the outside. or means.

A check valve 241 may be added to the submersible pump 240 to perform a function of allowing water to be discharged in one direction without flowing backward in the opposite direction.

The control device 250 refers to a device or means that performs a function of controlling components such as the vacuum pump 230 and the submersible pump 240 of the suction pump 200 .

The groundwater level detection sensor 260 of the present invention refers to a device or means that performs a sensor function of detecting the level of groundwater in a ground where groundwater is to be drawn up.

The groundwater level detection sensor 260 operates the groundwater level lowering device 1000 of the present invention to detect whether the desired groundwater level has been reached, transmits the result to the control device 250, and when the groundwater level is lowered to the target level, intake is performed. It controls whether the pump 200 operates.

The suction hose 210 of the present invention is connected to the header pipe 211, and the header pipe 211 is connected to one or more water intake pipes 100.

The diameter D of the suction hose 210 is 100 to 150 mm, preferably 120 to 130 mm, and the diameter D of the header pipe 211 is 130 to 170 mm, preferably 140 to 160 mm. It is good.

The technical feature of the present invention is that the above header pipe 211 is detachably connected to the connection part 140 of the water intake pipe 100, but in an inverted U shape on the upper part 211-1 of the header pipe 211 It is connected to increase the groundwater discharge effect.

In addition, the connection part 140 of the water intake pipe 100 is made of transparent polymer material resin, so it performs a function of recognizing whether groundwater is well discharged to the header pipe 211 through the water intake pipe 100. .

The present invention provides a groundwater level lowering method using the groundwater level lowering device 1000 as follows.

First, in the present invention, a process of forming an insertion hole into which the water intake pipe 100 is to be inserted is performed in a target area where the groundwater level needs to be reduced. (Step 1)

The process of forming the insertion port is performed by using an excavator and driving an excavation pipe suitable for the length and diameter of the water intake pipe into the large intestine area.

As an example, when the diameter of the water intake pipe 100 is 30 to 50 mm and the length is 5 to 10 mm, an excavation pipe of a size that fits or is slightly larger is selected and inserted into the target area to form an insertion hole.

When the drilling pipe is removed later, an insertion hole is formed in the target area.

It is effective to form two or more of the insertion holes in the target area, and to form them at regular intervals on the left and right.

In the present invention, the process of inserting the water intake pipe 100 into the insertion hole formed in the target area is performed. (Step 2)

As described above, since the water intake pipe 100 is made of a polymer material resin, it is very light and it is very simple and easy for a worker to perform such a task.

In the process of inserting the water intake pipe 100 into the insertion hole, first, the process of inserting the water intake pipe 100 into the drilling pipe embedded in the target area is performed to form the insertion hole. (Step 2-1)

After the above process, the process of removing the drilling pipe is performed to complete the process of inserting the water intake pipe 100 into the insertion hole. (Step 2-2)

In the present invention, a process of connecting the intake pipe 100 to the header pipe 211 is performed. (Step 3)

In the present invention, the above-mentioned suction pump 200 is operated to perform the process of discharging the groundwater in the target area. (Step 4)

The present invention provides a method for lowering the groundwater level composed of such processes and functions.

The present invention is useful for industries producing, manufacturing, selling, distributing, and researching devices that lower the groundwater level.

In particular, the present invention is useful for industries producing, manufacturing, selling, distributing, and researching a device for lowering the groundwater level using a water intake pipe having a special function, and is very useful for the groundwater level lowering method industry using the same.

water intake pipe 100,
A pipe body part 110, a suction intake part 120, a flow rate homogenization part 130,
Suction pump 200,
suction hose 210, discharge hose 220,
A vacuum pump 230, a submersible pump 240, a control device 250,
Ground water level lowering device (1000),

Claims (3)

It is composed of a pipe body part 110, a suction intake part 120, and a flow rate homogenization part 130,
The above-mentioned pipe body part 110 is connected to the suction hose 210 of the suction pump 200 in the shape of a pipe or pipe and performs a function of sucking and discharging groundwater,
The intake intake 120 is formed at the distal end of the pipe body 110, and has a structure in which one or more intake ports 121 are formed,
The end 111 of the pipe body 110 is blocked, and groundwater flows only into the suction intake 120,
The water intake 121 is formed in a rectangular shape, and the ratio (a: b) of the lengths of the horizontal (a) and vertical (b) is 1: 7 to 15,
The flow rate homogenizing unit 130 performs a function of equalizing the flow rate of groundwater flowing into the suction intake unit 120,
The flow rate homogenization part 130 is formed inside the pipe body part 110 and is coupled to the end 111 of the suction intake part 120, and is higher than the height (I) at which the intake intake part 120 is formed. It is formed with a large height (H),
The flow rate homogenization portion 130 is formed in a cylindrical shape formed with a diameter D1 and a height H, and the diameter D1 of the flow rate homogeneity portion 130 is the inner diameter D2 of the pipe body portion 110 The water intake pipe (100), characterized in that it is formed in a size of 25 to 80%.
Including the intake pipe 100 of claim 1,
A groundwater level lowering device (1000) including a suction pump (200) including a vacuum pump (230), a submersible pump (240), and a control device (250).
A process of forming an insertion hole into which the water intake pipe 100 is to be inserted in the target area where the groundwater level needs to be reduced (Step 1);
The process of inserting the intake pipe 100 of claim 1 into the insertion tube formed in the target area (step 2),
The process of connecting the intake pipe 100 to the header pipe 211 (step 3);
The process of discharging groundwater in the target area by operating the suction pump 200 (step 4);
Groundwater level reduction method comprising a.