KR101981497B1 - Poor ground improvement method - Google Patents

Abstract

The present invention relates to an ultra-soft ground improvement method, comprising the following steps of: (a) constructing a primary reinforcing mat (210) on a surface of the ultra-soft ground and then fixing the mat on the ground; (b) installing a surface layer vertical drainer (150′) on the primary reinforcing mat (210) constructed in the (a) step; and (c) performing primary consolidation.

Description

{Poor ground improvement method}

TECHNICAL FIELD [0001] The present invention relates to a technique for improving the premixed ground by draining water contained in the ground.

Generally, when the foundation layer of soft construction is high in water content, first the ground water is discharged and the ground is consolidated and then the foundation is constructed.

In the construction of such soft ground, it is possible to discharge the groundwater in various ways. Generally, it is installed drainage material, and gravel and sand are laid on the ground layer, and the earth ground water is taken out from the ground layer.

However, it is very difficult to enter heavy equipment such as dredged landfill or muddy ground for the first soft ground.

In order to install drainage materials or to install aggregates, the heavy equipment should enter above the soft ground. However, the ground of the first superficial leaching such as dredged landfill or open is very low in strength of the ground and equipment driving ability is poor, so that soft ground handling equipment (PBD construction equipment, etc.) This is difficult.

As a method for ensuring the equipment running ability of heavy equipment, it is used such as spraying aggregate of sand or the like on the top of the premade superficial ground, or installing a bamboo mat.

However, the method of spraying the aggregate on the top of the prefabricated ground is difficult to approach the location of the prefabricated ground where the aggregate spreader is to be sprayed, and it is difficult to secure sufficient equipment running ability even if the aggregate is sprayed. The construction work was troublesome and the workability was poor.

Korean Patent Registration No. 10-1659608

In order to solve the problems of the prior art as described above, in the present invention, there is provided a prefabricated soil improvement method in which the surface water of the ground of the primary superheater is discharged first to secure the running property of the equipment, .

In the present invention, there is provided a method of manufacturing a pre-reinforcement mat, comprising the steps of: a) installing a primary reinforcement mat (210) on a surface of a pre- b) installing a surface layer vertical drainage material 150 'on the first reinforcing mat 210 installed in step a); and c) advancing the primary consolidation.

The step c) includes the steps of: c-1) installing a primary horizontal drainage material 100 'on the primary reinforcement mat 210; c-2) connecting the surface-layer vertical drainage material 150 'and the first horizontal drainage material 100'; c-3) progressing the consolidation of the surface layer by the surface-layer vertical drainage 150 'and the primary horizontal drainage 100'.

After the step c-3), d) a secondary reinforcing mat 220 is laid on the upper part of the primary horizontal drainage 100 'and fixed to the ground; e) forming a first filler layer (10) on the second reinforcing mat (220); f) conducting secondary consolidation; g) installing a deep vertical drainage (150 ") above the first clay layer (10).

(G), h) installing a second horizontal drainage (100 ") on the first clay layer (10); i) connecting the deep vertical drainage material (150 ") and the secondary horizontal drainage material (100"); j) forming a second embankment layer (20) on top of the second horizontal drainage (100 "); k) performing the third consolidation.

Installing g ') vacuum drainage device after step g); i ') secondary consolidation.

The h 'step may include coupling the connector 41 to the end of the deep vertical drainage member 150' and connecting the coupler 42, the drain pipe 43 and the vacuum pump 44 to the connector 41 .

And the length of the deep vertical drainage member 150 'is longer than that of the surface-layer vertical drainage member 150'.

The installation depth of the surface layer vertical drainage material 150 'in step b) is 1 to 5 m.

The first horizontal drainage member 100 'and the second horizontal drainage member 100' are provided with insertion guides 262. The upper end of the surface layered vertical drainage member 150 'is connected to the first horizontal drainage member 100' And the upper end of the deep vertical drainage material 150 "is connected through the insertion guide portion 262 of the second horizontal drainage material 100".

Wherein the step c-1) includes lapping the primary horizontal drainage materials 100 'in a lattice shape, and the step h) includes laminating the secondary drainage materials 100' 'in a lattice form .

The prefabricated ground improvement method of the present invention has the following effects.

First, the improvement process of prefabricated ground is progressed by the process of primary consolidation of surface by vertical surface drainage, secondary consolidation of surface by first subsoil, and third consolidation by deep vertical drainage and surface vertical drainage And thus provides a systematic and efficient way to improve the prefabricated ground.

Second, the surface drainage for forming the first embankment layer is performed by the first and second reinforcing mat and the surface layer vertical drainage material, thereby achieving an optimal drainage effect at a low cost.

Third, the surface vertical drainage and the deep vertical drainage are connected to the first and second horizontal drainage materials having the insertion guide, and the first and second horizontal drainage materials are overlapped by the overlapping portion, so that the vertical drainage and horizontal drainage can be quickly and efficiently .

Fig. 1 is a view showing a first reinforcement mat of the present invention laid.
FIG. 2 is a view showing the primary reinforcing mat of the present invention.
FIG. 3 is a view showing the installation of the surface layer vertical drainage material of the present invention.
4 is a view showing a connection of a first horizontal drainage material to a surface layer vertical drainage material of the present invention.
Fig. 5 shows a secondary reinforcing mat laid on the primary horizontal drainage material.
6 is a view showing a first embankment layer formed on a secondary reinforcement mat.
FIG. 7 is a view showing the installation of the deep vertical drainage material in the first embankment layer.
8 shows a connection between a deep vertical drainage and a second horizontal drainage.
Fig. 9 shows a state in which the second embankment layer is formed.
Fig.
11 is a view showing a connection of a vacuum drainage to a deep vertical drainage material.
Fig. 12 is an enlarged view of C in Fig. 11 (vacuum drain connection diagram).
13 is a perspective view showing the horizontal drainage material of the present invention superimposed.
14 is an enlarged view of the water supply part of the present invention.
Fig. 15 is a view showing a state in which the horizontal drainage material having the cut-off portion is laminated in the present invention.
Fig. 16 is a view showing a water hole formed in the horizontal drainage core of the present invention.
Fig. 17 is a cross-sectional view showing the overlapping of the horizontal drainage material of the present invention. Fig.
FIG. 18 is a view showing a state in which a perforation is formed in the horizontal drainage material of the present invention and a support is inserted.
Figs. 19 and 20 are cross-sectional views illustrating the formation of a perforation in the horizontal drainage material of the present invention and inserting a support.
21 is a perspective view of a horizontal drainage material having an expansion part of the present invention.
22 is an enlarged view of the water supply part of the present invention.
23 is a cross-sectional view of a horizontal drainage material provided with an extension of the present invention.
Fig. 24 is an enlarged view of Fig. 4A and Fig. 8B.
Fig. 25 is a cross-sectional view of a horizontal drainage material having expanded portions of the present invention on both sides. Fig.
Fig. 26 is a cross-sectional view of the horizontal drainage material of the present invention covered with a cover. Fig.
FIG. 27 is a perspective view of a horizontal drainage material provided with an extension part of the present invention in a superimposed manner. FIG.
Figures 28 to 31 illustrate the prior art.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification. Throughout the specification, when an element is referred to as " comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In order to solve such a problem, firstly, a first reinforcing mat 210 is laid on the surface layer of the primary softening ground, The primary consolidation of the surface layer of the prefabricated ground should be carried out first so that the lightweight equipment that can install the vertical drainage material on the surface layer, not the equipment, can secure the supporting power to travel.

The primary reinforcement mat (210) laid on the surface layer of the primary superficial crack foundation secures the drivability of the lightweight equipment so that the surface water of the primary superficial ground is discharged first and then the heavy equipment is allowed to enter.

1 and 2, the first reinforcing mat 210 is pulled from one side to the other side by using a device such as a winch on the surface layer of the super-soft ground G, and after the first reinforcing mat covers the surface layer Fix the rim of the primary reinforcement mat to the ground.

The method of fixing the primary reinforcing mat to the ground can be achieved by embedding the end of the primary reinforcement mat in the ground E or by anchoring it on the ground.

A portion of the water exposed on the surface layer of the primary super softening layer is drained or dried to the side of the primary super softening layer through the primary reinforcing mat 210 so that the strength of the surface layer of the primary super softening layer is gradually increased and the equipment running ability is ensured.

As described above, since the rim of the primary reinforcing mat 210 is fixed to the ground via an anchor or the like, the load of the lightweight equipment traveling on the upper portion of the primary reinforcing mat is higher than the load of the super- As shown in Fig.

Although the load of the equipment capable of supporting with the tensile strength of the first reinforcing mat is not high, the surface layer vertical drainage material can not be installed at a deep depth, For the lightweight equipment that installs the vertical drainage 150 ', the primary reinforcement mat may be supported.

The material of the mat used herein may be any of PET, fiber mat, and nonwoven fabric depending on the situation of the site.

After the first reinforcing mat 210 is installed and fixed on the surface layer of the ultimate super softening base, the lightweight equipment for constructing the surface vertical drainage material 150 'runs while the surface layer vertical drainage material 150' is installed (FIG. 3) .

The surface-layer vertical drainage material 150 'is a vertical drainage material for draining the water contained in the surface layer of the ultimate softening ground in the vertical direction, and can support the equipment for forming the first clayey layer 10 by drying the surface- Thereby securing a supporting force.

The installation depth of the surface vertical drainage 150 'may be 1 to 5 m, which may vary depending on the water content of the primary superficial soil, physical properties of the ground, and the like.

After the surface layer vertical drainage member 150 'is installed, the water is drained along the vertical drainage member 150' horizontally along the surface vertical drainage member 150 ' Install the drainage material 100 '.

The first horizontal drainage members 100 'are disposed to overlap with each other at right angles to each other or inclined with respect to each other. The first horizontal drainage members 100' and the first horizontal drainage members 100 ' Thereby connecting the drainage 100 '.

A method of overlapping the first horizontal drainage materials 100 'and a method of connecting the surface layered vertical drainage material 150' and the first horizontal drainage material 100 'will be described later.

4 is a cross-sectional view of the first reinforcing mat 210 in which the first horizontal drainage members 100 'are overlapped and the surface-layer vertical drainage members 150' and the first horizontal drainage members 100 ' .

Since the upper ends of the surface layer vertical drainage materials 150 'are connected to the first horizontal drainage materials 100', primary consolidation starts from this point.

That is, the surface water drained upward in the vertical direction along the inside of the surface layer vertical drainage members 150 'is drained horizontally along the first horizontal drainage members 100' and begins to drain through the drainage path of the primary drainage grounds.

Thereafter, a second reinforcing mat 220 is laid over the installed first horizontal drainage materials 100 '.

The secondary reinforcement mat is also pulled from one side to the other using equipment such as a winch, as with the primary reinforcement mat, and the rim of the secondary reinforcement mat is fixed to the ground.

By the above process, first and second reinforcing mats are attached to the upper part of the pre-existing superficial ground with its rim fixed to the ground. Primary superficial layers of the superfine superficial ground are undergoing primary consolidation, It is possible to enter the equipment for forming the first embankment layer by the supporting force of the superficial weakening subsurface layer.

The equipment enters the upper part of the secondary reinforcement mat 220 to form the first embankment layer 10. When the first embankment layer is completed, secondary consolidation is performed by the upper load of the first embankment layer 10 It proceeds.

When the first embankment layer is completed, the heavy embankment is fully secured by the first embankment layer 10, so the deep vertical drainage material 150 '' is installed by the large vertical drainage installation equipment.

Deep vertical drainage (150 ") is preferably installed over the entire ground stratum, but when the depth of the earthquake ground is too deep, it may not cover the entire stratum.

After the installation of the deep vertical drainage material 150 '', a second horizontal drainage material 100 '' is installed and the overlapping joints between the second horizontal drainage materials 100 '' and the overlapping joints between the second horizontal drainage material 100 ' The vertical drainage 150 " is connected (see Fig. 8).

The second embankment layer 20 is formed above the first embankment layer 10 to progress the third consolidation. The third consolidation is performed not only by the deep vertical drainage material but also by the second embankment layer As the overburden load is increased, the consolidation by the surface layer vertical drainage installed above will proceed.

Through the organic consolidation process of the surface layer vertical drainage material and the deep vertical drainage material by the first and second embankment layers, an efficient improvement process is performed for the entire ground layer.

When the consolidation process is performed for a certain period of time, the refinement work for the premade superficial ground is completed (see FIG. 9).

In addition, in the present invention, it is possible to perform vacuum drainage using the deep vertical drainage material 150 'installed in the first embankment layer 10 without forming the second embankment layer 20, 12, the connector 41 is connected to the end of the deep vertical drainage member 150 ", the coupler 42 and the drain pipe 43 are connected to the connector 41, and the vacuum pump 44 is connected to the connector 41. [ To generate negative pressure inside the soft ground to promote drainage and consolidation.

Hereinafter, the connection method of the horizontal drainage material used in the above process, the structure of the horizontal drainage material, and the connection method of the vertical drainage material and the horizontal drainage material will be described. The horizontal drainage material 100 described above includes the first horizontal drainage material 100 'and the second horizontal drainage material 100 "described above. The vertical drainage material 150 includes the surface layer vertical drainage material 150' (150 ").

The description of the overlapping method between the horizontal drainage materials 100 to be described later is applied to the first horizontal drainage material 100 'and the second horizontal drainage material 100 ", respectively. The horizontal drainage material 100 and the vertical drainage material 100 150 is applied to connection between the first horizontal drainage 100 'and the surface layer vertical drainage 150' and to the connection between the second horizontal drainage 100 'and the deep vertical drainage 150', respectively .

<Overlapping method of horizontal drainage material>

The configuration of a preferred embodiment of the present invention will be described below with reference to Figs. 13 and 14 attached hereto.

FIG. 13 is a perspective view showing a combined state of an embodiment in which a lap joint method of a horizontal drainage material according to the present invention is applied, FIG. 14 is a perspective view showing a structure of a horizontal drainage material used in a lap joint method of a horizontal drainage material according to the present invention 13 is an enlarged view of the " A "

As shown in the drawings, the present invention provides a method for connecting a plurality of horizontal drainage members 100 for drainage of pore water (or groundwater) in a longitudinal direction, comprising the steps of: overlapping a plurality of horizontal drainage members And then they are fixed to each other and shielded by using the earth / sand inflow blocking member 160.

Before describing the lap joint method in detail, the construction and operation of the horizontal drainage material 100 and the earth / soil inflow blocking member 160 applied thereto will be described.

The horizontal drainage material 100 is a structure for draining the fluid in the longitudinal direction. The horizontal drainage material 100 includes a filter 140 for selectively passing the fluid only in contact with the earthy soil, a filter 140 disposed inside the filter 140, And a core 120 for guiding one fluid in the longitudinal direction.

The filter 140 is configured to selectively pass only the fluid while blocking the contact between the core 120 and the gravel. It is preferable that the filter 140 is formed to surround the outer surface of the core 120 and have fine holes.

The core 120 has a plate shape in which a plurality of partition walls are formed on the upper and lower surfaces, and a plurality of layers may be stacked and used.

The number of the cores 120 may be variously changed according to the drainage amount of the fluid or the installation environment of the horizontal drainage material 100. That is, a single-layer core using one core may be used depending on the situation, or a plurality of layers may be formed using a plurality of cores.

The core 120 is provided with a water passing part 122. The flow-through part 122 flows in the upward / downward direction and the left / right direction of the core 120, that is, in the three-dimensional direction when the fluid flowing into the filter 140 flows in the longitudinal direction of the core 120 .

In addition, a plurality of the water passing portions 122 may be formed in the core 120 so as to smoothly guide fluid and regularly arrange the fluid to prevent the strength from being lowered.

Referring to FIG. 14, the core 120 may include a plurality of cores 120. The core 120 may include a plate-like partition plate 120 corresponding to the projected area when viewed from above, And a partition wall 127 protruding outwardly from the upper and lower surfaces of the partition plate 125 in the longitudinal direction of the core 120 and having a predetermined height in the thickness direction of the core 120, .

The partition plate 125 is positioned at the center of the core 120 and is divided into upper and lower portions to support a plurality of partition walls 127. The partition plate 125 is divided into upper and lower spaces Thereby guiding the flow of the fluid.

Partitions 127 are formed on the upper and lower surfaces of the partition plate 125 at regular intervals. The partition walls 127 are formed to have the same thickness and height and are spaced apart from one another at regular intervals so as to guide fluids located on the upper and lower sides of the partition plate 125 in the longitudinal direction of the core 120.

The partition walls 127 are arranged to be equally spaced apart from each other with the same thickness and height in the embodiment of the present invention. However, the partition walls 127 may have different heights and thicknesses in consideration of the installation environment of the horizontal drainage materials 100, .

The core 120 is provided with the water passing part 122 described above. The water passing portion 122 is formed by puncturing the partition wall 127 and the partition plate 125 at the same time so that the upper and lower sides of the partition plate 125 can communicate with each other and a part of the partition plate 125 is cut And a partition wall 124 formed by removing a part of the partition wall 127. The partition wall 123 is formed by cutting a part of the partition wall 127,

Therefore, the partition plate cutout 123 is located on the same straight line as the partition cutout 124 located at the upper and lower sides, and when the partition 127 is formed on either the upper surface or the lower surface of the partition plate 125 The water passing part 122 can be formed at various positions in various sizes if the partition plate cutting part 123 and the partition wall cutting part 124 are located on a straight line.

The partitioning part 124 is formed in such a manner that a part of the partition wall 127 having a small thickness is completely cut off so that the left and right portions of the partition wall 127 can be opened. The partition plate cutout portion 123 is formed by cutting off part of the partition plate 125 so that the partition cutout portions 124 formed on the upper and lower sides can communicate with each other.

At this time, the partition plate cutout 123 is formed to have a width equal to or greater than the thickness of the partition cutout 124.

That is, the partition plate cutting unit 123 serves to guide the fluid flowing left and right along the partition wall cutting unit 124 to flow in the up / down direction (the thickness direction of the core 120) And is formed so as to have a width equal to or greater than the thickness of the partition wall 127.

This is to allow the fluid flowing along the core 120 to freely flow in the upward / downward direction and the left / right direction and the forward / backward direction, i.e., the three-dimensional direction of the core 120, If the width of the cut-off portion 123 is smaller than the thickness of the partition wall cutout portion 124, even if the fluid above the partition plate 125 flows downward through the partition cutout portion 124 and the partition cutout portion 123 It is trapped by the partition plate 125 and can not flow in the left / right direction.

Therefore, it is preferable that the partition plate cutting portion 123 is cut so as to have a width equal to or greater than the thickness of the partition wall 127.

On the other hand, a soil inflow blocking member 160 is provided on the upper and lower sides of the overlapped portion C of the horizontal drainage which is overlapped with each other. The groundwater inflow blocking member 160 is made of a material having the same or similar properties as the filter 140 described above. The groundwater inflow blocking member 160 is formed with fine holes so that the groundwater can pass but the soil does not pass through.

The soil inflow blocking member 160 is formed to have a size larger than the area of the overlapping region C so as to prevent the overlapping region C from being exposed to the outside and bound by the binding member 170.

Therefore, if the earth-sand intake blocking member 160 located at the upper side and the lower side of the horizontal drainage member 100 is bound by the binding member 170, the overlapping region C is positioned inside the soil- , The movement of the horizontal drainage material 100 is limited.

Hereinafter, the shape and the coupling structure of the horizontal drainage material and the earth-moving object blocking member applied to the lap joint method of one embodiment will be described with reference to FIG.

Fig. 15 is an exploded perspective view showing each configuration and arrangement state of the first embodiment of the lap joint method of the horizontal drainage according to the present invention.

As shown in the drawing, a part of the filter 140 of the horizontal drainage 100 must be cut off to form the cutout 142 for the overlapping method. The cut-off portion 142 is formed by cutting off a part of the filter 140 at the overlapping portion C of the horizontal drainage 100. The cut portion 142 is formed by cutting off the inner portion of the overlapping portion C, The filter 140 of the horizontal drainage material 100 of the upper horizontal layer 100 is cut off so that the inside of the horizontal drainage material 100 stacked on the upper and lower sides can communicate with each other.

Accordingly, when the two horizontal drainage materials are overlapped, the horizontal drainage material 100 located on the upper side is formed with the cutout portion 142, and the horizontal drainage material 100 located on the lower side is formed with the cutout portion 142 on the upper surface thereof. The groundwater inflow blocking member 160 is positioned above and below the horizontal drainage 100.

In the case of overlapping three or more horizontal drainage materials, the horizontal drainage material disposed on the uppermost side is formed with a cut-off portion on the lower surface thereof, the horizontal drainage material disposed on the bottom side has a cut-away portion formed on the upper surface thereof, The remaining horizontal drainage material except for the drainage material forms a cut-off portion on the upper and lower surfaces.

The configuration of another embodiment will be described below with reference to Fig. 16 attached hereto.

Fig. 16 is an exploded perspective view showing the arrangement and arrangement of the second embodiment in the lap joint method of the horizontal drainage according to the present invention.

As shown in the drawing, the overlapping portion C of the horizontal drainage material is cut off to form the cutout portion 142, and the cutout portion 142 of the core 120 exposed through the cutout portion 142 125 have a plurality of water holes 1222 formed therein. The water supply hole 1222 is configured to allow the water to flow in the upward / downward direction of the core 120, and it is preferable that the water supply hole 1222 is formed with a plurality of holes so as to increase the drainage performance.

16 to 18, a description will be made of a method of superimposing the horizontal drainage material using the horizontal drainage material and the earthy inlet blocking material constructed as described above.

17 is a cross-sectional view showing the arrangement state of each structure in the first embodiment in the overlapping construction method of the horizontal drainage material according to the present invention.

The overlapping construction method of the horizontal drainage material of the first embodiment proceeds as follows (1) to (4).

(S100) in which a plurality of horizontal drainage members (100) are arranged in different directions to confirm the overlapping region (C) and the filter is cut off to form a cutout portion (142) in the horizontal drainage (100)

The excision step S100 is a process of forming the excision part 142 by cutting out a part of the filter 140 located on the opposite side of the overlapping part C in the filter 140 forming the outer surface of the horizontal drainage material 100. [

At this time, the outer side of the overlapped portion (C) of the horizontal drainage material (100) is kept shielded by the filter (140).

At this time, a plurality of water holes 1222 can be drilled in the core 120 for drainage of the upper and lower cores of the horizontal drainage material.

A horizontal drainage lapping step S200 in which the horizontal drainage materials are brought into contact with each other so that the cut-off portions 142 of the horizontal drainage materials 100 formed in the cutting step S100 are placed at the same position,

(3) a horizontal drainage shielding step (S300) for disposing the earthy inlet blocking member (160) below and above the plurality of horizontal drainage materials (100) stacked and stacked in the horizontal drainage lining step (S200)

In the horizontal drainage shielding step S300, the cutouts 142 formed in the horizontal drainage members 100 located at the upper and lower sides are positioned at the same position, and then the earthy inlet andifices 100 ) To completely cover the overlap region (C).

(4) After the horizontal drainage material shielding step S300, a horizontal drainage material fixing step S400 for binding the pair of the earth-moving water intake blocking members 160 to each other and restricting the movement of the overlapping area C located therein is performed.

The horizontal drainage fixing step S400 is a process of binding the edge of the earth-moving member 160 to the binding member 170. [ The binding member 170 can be modified in various ways as long as it can confine the pair of the soil-inflow blocking members 160 such as a screw, a stapler or the like so as not to be separated from each other.

The configuration for the overlapping method of another embodiment will be described below with reference to Figs. 18 and 19. Fig.

FIG. 18 is a perspective view showing the arrangement state of each constitution of the third embodiment in the method of lap jointing of the horizontal drainage material according to the present invention, FIG. 19 is a perspective view of the horizontal overlapping method of the horizontal drainage material according to the present invention, A sectional view showing the arrangement state of the configuration is shown.

As shown in the drawing, in the third embodiment, a perforation 144 is formed in the horizontal drainage member 100 to be overlapped, and a support base 180 is installed in the perforation 144. Although not shown in FIG. 18, the earth-moving member 160 is also applied in the same manner as in the first and second embodiments.

The perforation 144 is formed by simultaneously removing the filter 140 and the core 120 in the region corresponding to the overlapping region C of the horizontal drainage 100 and is formed as shown in FIG. The support frame 180 is inserted into the interior of the pair of the soil intake / blocking members 160 to support the soil intake / So that the problem of pressing down is solved.

The support base 180 includes a plate-shaped body 182 having an area corresponding to the area of the perforation 144 and a plurality of support protrusions 184 protruding upward from the upper / And a hole 186 formed in the body 182 at a plurality of perforations.

The body 182 is formed integrally with the plurality of support protrusions 184 so that the support protrusions 184 can maintain a predetermined position, and has a thin thickness.

The support protrusions 184 are spaced apart from each other to be able to flow underground water and are not damaged or deformed by the earth pressure acting on the upper side of the earth /

The support protrusions 184 are formed on the upper and lower surfaces of the body so as to allow the ground water to flow upward / downward with respect to the body 182.

The support 180 may be designed to have a height equal to or slightly higher than the total height of the horizontal drains 100 where the total height of the body 182 and the support protrusions 184 is overlapped.

The method of the third embodiment will be described below with reference to FIG. 20 attached hereto.

In the third embodiment, as in the first embodiment, the disconnection step S100, the horizontal discharging material overlapping step S200, the horizontal discharging material shielding step S300, and the horizontal discharging material fixing step S400 are sequentially performed, A step of installing a support between the step S200 and the horizontal drainage shielding step S300 is further performed.

After the step of laminating the horizontal drains, the step of installing the support is progressed. In some cases, after the step of installing the supporting member 180 is inserted into the perforation 144 of the horizontal drainage material below the horizontal drainage member, A horizontal drainage overlapping step may be performed. At this time, a step of installing a support is carried out between the ablation step S100 and the horizontal drainage overlap step S200.

The cutting step S100 is a process of forming a filter 140 and a perforation 144 for cutting off a part of the core 120 instead of the cutter 142 having a part of the filter 140 removed, By inserting the supporter 180 into the workpiece 144, the supporter installation step S150 is completed.

When the support step S150 is completed, the supporter 180 is positioned within the perforation 144 as shown in FIG. 20, and the groundwater can flow in a plurality of directions.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention.

For example, in the embodiment of the present invention, the perforation 144 and the cut-off portion 142 are configured to have a rectangular shape. However, the perforation 144 and the cut-out portion 142 may be modified in various shapes.

In addition, in the embodiments of the present invention, the earth-sand inflow blocking member 160 is coupled to each other by using a plurality of mutually separated members. However, if necessary, the middle portion of the narrow and long- And a pair of horizontal drainage members 100 may be enclosed and shielded.

&Lt; Horizontal drainage material having extension part and connection method of vertical drainage material and horizontal drainage material &gt;

The configuration of the fourth embodiment of the present invention will be described with reference to FIGS. 21 and 22 attached hereto. The fourth embodiment relates to a method of connecting the vertical drainage material 150 to the horizontal drainage material 100 having the insertion guide portion 262.

21 is a perspective view showing the outer appearance of the horizontal drainage material 100 having the insertion guide part 262 and FIG. 22 shows a horizontal drainage material having the insertion guide part 262, An enlarged view is shown.

The horizontal drainage material 100 of the fourth embodiment allows only the core of the vertical drainage material 150 (refer to reference numeral 152 in FIG. 24) to be inserted therein and directly contacts the core 120, (152) is kept in a state in which it is not in contact with the gravel.

To this end, an extension 260 is provided on the right side of the filter 140. The extension 260 extends from the end of the filter 140 to the outside of the core 120 to allow the core 152 of the vertical drain 150 to be inserted therein.

That is, the extension 260 is a portion that is further extended to have a predetermined width at the end of the filter 140 and is bound to the binding member so as not to be easily separated in the up / down direction, The insertion guide portion 262 is formed and is opened in the upward / downward direction, thereby guiding the core 152 of the vertical drainage material to be received therein.

The detailed structure of the extension portion 260 will be described with reference to FIG.

23 is a cross-sectional view showing the internal structure of the horizontal drainage material 100 having the insertion guide portion 262. As shown in FIG.

As shown in FIG. 23, the extension 260 is integrally formed with the filter 140 in the fourth embodiment, and corresponds to the remaining portion of the filter 140 surrounding the core 120. The horizontal drainage member 100 is formed of the core 120 and the filter 140 while the horizontal drainage member 100 is formed of the core 120 and the filter 140 in the first, And an expansion unit 260.

The extension portion 260 that is the remaining portion surrounding the core 120 is in a state of being bound by a binding member (for example, a stapler, a nail, a tack, a thermally fused portion, a sewing line, etc.) .

When the binding force of the binding member is released, the ends of the extending portion 260 can be separated from each other in the up / down direction, and the inside of the filter 140 is communicated with the outside so that the insertion guide portion 262 can be formed. .

That is, of the portions bound by the binding member in the extending portion 260, the portion where the binding force is removed in accordance with the binding position of the vertical drainage material serves as the insertion guide portion 262.

In addition, when the horizontal drainage material is manufactured in the factory, the insertion guide portion 262 may be formed in advance. In order to prevent the extension portion 260 from being separated in the upward / downward direction, a sewing line is formed along the longitudinal direction of the extension portion 260 The suture lines are formed at regular intervals along the longitudinal direction of the extension part 260 so that the insertion guide part 262 can be formed at regular intervals along the longitudinal direction of the extension part 260.

The operation of the extension portion 260 will be described with reference to FIG.

24 is a sectional view showing a state in which the horizontal drainage member 100 having the insertion guide unit 262 and the core 152 of the vertical drainage member 150 are connected.

24, the core 152 of the vertical drainage member 150 is laminated to the core 120 of the horizontal drainage member 100 by being inserted through the inside of the expansion portion 260 through the insertion guide portion 262.

In the fourth embodiment, the cores 120 are configured as a pair, the two cores 120 are stacked vertically, and the cores 152 of the vertical drains 150 are disposed between the pair of cores 120 Respectively.

Therefore, the groundwater in the ground G flows upward (refer to the arrow) along the core 152 of the vertical drainage material, and flows into the horizontal drainage material 100 via the expansion portion 260.

25 is a transverse sectional view showing the structure of the fifth embodiment of the horizontal drainage material 100 having the insertion guide part 262. The horizontal drainage material 100 of the fifth embodiment is similar to the horizontal drainage material 100 of the horizontal drainage material 100, And extend portions 260 on both left and right sides.

25, the horizontal drainage material 100 of the fifth embodiment easily forms the insertion guide portion 262 even when the vertical drainage material 150 is bent and connected from any left and / or right directions when the horizontal drainage material 100 is installed on the soft ground The filter 140 is formed so as to have the same width on the left and right sides of the filter 140.

The configuration of the sixth embodiment, which is another embodiment of the horizontal drainage 100, will be described below with reference to FIG. 26 is a cross-sectional view showing the construction of the sixth embodiment of the horizontal drainage material 100 provided with the insertion guide portion 262. As shown in FIG.

As shown in FIG. 26, the horizontal drainage member 100 has a width shorter than that of the fourth and fifth embodiments, and further includes a lid 280 on the outer side of the extension 260.

The lid 280 is made of a permeable material and accommodates the expansion part 260 therein to more effectively block the inflow of the fine particles into the filter 140.

The lid 280 also serves to guide the core 152 of the vertical drainage member 150 to be inserted into the insertion guide portion 262.

Therefore, the cover 280 is formed with an insertion hole 282 through which the core 152 of the vertical drainage member 150 can be inserted, and has a predetermined area to cover the extension 260.

A method of connecting the horizontal drainage material 100 and the vertical drainage material 150 will be described with reference to FIGS. 21 to 26 attached hereto.

The method of connecting the horizontal drainage material 100 and the vertical drainage material 150 is as follows.

(P100) for installing the vertical drainage material (150) and the horizontal drainage material (100)

A vertical drainage bending step (P200) for bending the vertical drainage material (150) toward the horizontal drainage material (100)

Vertical Drainage In the bending step (P200), the vertical drainage material is bent considering the width of the horizontal drainage material at the position where the vertical drainage material is connected to the horizontal drainage material.

(P300) for removing the binding member of the extension part (260) to form the insertion guide part (260)

At this time, when the vertical drainage member 150 is bent in the vertical drainage member bending step P200, the binding member at the position where the vertical drainage member 150 is to be inserted is removed.

This is a process of preliminarily preparing the vertical drainage material 150 to be inserted into the horizontal drainage material. However, the method may be performed by cutting out a part of the expansion part and communicating the inside of the filter and the outside of the expansion part.

(P400) for removing a portion of the filter (154) at the bent portion of the vertical drainage (150)

The filter removing step P400 is a step of removing the filter 154 of the vertical drainage material 150 in order to allow the core 152 of the vertical drainage material 150 and the core 120 of the horizontal drainage material 100 to directly contact each other. A length equal to or slightly shorter than the width of the drainage member 100 is removed.

The upper end of the vertical drainage material 150 is bent and the length of the bent portion is adjusted so that the bent end portion can be received in the horizontal drainage material 100 and the filter 154 of the vertical drainage material 150 is removed, The filter 154 should be removed to such an extent that the fine particles do not flow on the connecting portion of the drainage member and the extension portion 260.

Therefore, the core 152 of the vertical drainage member 150 and the core 120 of the horizontal drainage member 100 can be directly in contact with the inside of the horizontal drainage member by the filter removing step P400.

(P500) for inserting the bent portion of the vertical drainage into the inside of the horizontal drainage material through the insertion guide portion (262)

When the core 120 of the horizontal drainage material 100 is one, the cores 152 of the vertical drainage material 150 are stacked on the upper side of the core 120 and the cores 120 of the horizontal drainage material 100 are stacked The cores 152 of the vertical drainage members 150 are stacked between the cores 120 of the plurality of layers. By this structure, the groundwater flowing upward through the vertical drainage material 150 is discharged in the horizontal direction through the horizontal drainage material 100.

Meanwhile, a lid penetration step P450 may be further performed between the filter removing step P400 and the vertical drainage inserting step P500.

The lid penetration step P450 is performed when an attempt is made to selectively connect the horizontal drainage member 100 and the core 152 of the vertical drainage member 150 using the cover 280 that is further configured.

The core 152 of the vertical drainage member 150 is inserted into the insertion hole 282 by the cover penetration step P450 and a vertical drainage member inserting step P500 is performed at a subsequent stage.

After the vertical drainage inserting step P500, the remaining part of the cover 280 (the left side of the insertion hole 282) is covered to cover the outer surface of the filter 140, and the drainage coupling step P600 is performed.

The draining material joining step P600 is a process of joining the horizontal drainage material 100 and the vertical drainage material 150 connected to each other through the processes of P100 to P500 by using a joining member.

The horizontal drainage member 100 and the vertical drainage member 150 are kept separated from each other by the action of the coupling member.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention.

For example, the cover 280 covers the upper and lower surfaces of the filter 140, but may cover only the upper surface of the filter 140 as long as it can block the inflow of the fine particles.

In the embodiments of the present invention, the cores 120 are stacked in a pair so that the core 152 of the vertical drainage member 150 is inserted therebetween. However, the cores 120 may be vertically / horizontally, Three or more cores 120 may be stacked so that the core 152 of the vertical drainage member 150 is inserted between the cores 120 that are different from each other.

In the case of the horizontal drainage material 100 in which the filter 140 is surrounded by the same dimensions as the core 120, the side surface of the filter 140 is opened by cutting or the like to form the insertion guide portion, As shown in FIG.

&Lt; Connection method of horizontal drainage material having extension part &gt;

In the above embodiments, the horizontal drainage members 100 are overlapped with each other using the earth-moving member 160, the structure of the horizontal drainage member having the extending portion 260, and the vertical drainage member and the extending portion 260 However, it is also possible to construct the horizontal drains having the extension 260 by overlapping using the earth / sand inlet / outlet blocking member 160.

This embodiment is shown in FIG. 27, and can be implemented in the same manner as in the first, second, and third embodiments except that the horizontal drainage 100 is provided with an extension 260. That is, the processes of S100 to S400 are performed in the same manner using the horizontal drains having the extension 260.

<Method of overlapping horizontal drainage with extension part and method of connecting drainage material using both horizontal drainage and vertical drainage material>

Here, a method of constructing the overall drainage material applying all the technical features of the present invention will be described.

As described above, the horizontal drainage material 100 is provided with the extension portion 260 and the insertion guide portion 262. The overlapping construction between the horizontal drainage materials uses the earthy inflow blocking member 160, When the drainage material is connected, the bent portion of the vertical drainage material is inserted through the insertion guide portion 262.

The overall construction method of the drainage material proceeds to the following steps.

And a horizontal drainage member (100) having a vertical drainage member (260) and an insertion guide (262).

A plurality of overlapping portions C of the horizontal drainage material 100 are observed and a cutout portion 142 is formed in the horizontal drainage material 100 by cutting off a part of the filter 140 located opposite to the overlapping portion C Ablation stage.

A horizontal drainage lapping step in which the horizontal drainage material is overlapped by bringing the cut-off portion 142 of each horizontal drainage material 100 formed in the cutting step into the same position.

A horizontal drainage shielding step of disposing the earth / sand intake blocking members 160 at the bottom and top of the plurality of horizontal drainage materials 100 stacked and stacked in the horizontal drainage overlapping step.

A horizontal drainage member fixing the movement of the overlapping region C located inside the horizontal drainage members 100 by sandwiching the groundwater inflow blocking members 160 disposed at the bottom and top of the horizontal drainage members 100 after the horizontal drainage member shielding step, step.

수직 Vertical drainage bending step to bend the vertical drainage in the direction of horizontal drainage.

(B) opening the inserting guide provided in the extended portion protruding outwardly of the core of the horizontal drainage material.

(D) a filter removing step of removing a portion of the filter at the bent portion of the vertical drainage.

(D) inserting the bent portion of the vertical drainage material into the horizontal drainage material through the insertion guide portion 262;

The process proceeds to a drainage joining step of joining the vertical drainage material and the horizontal drainage material with the joining member.

In the embodiment according to the above-described steps, a horizontal cutter 142 is formed by cutting a part of the filter 140 of the horizontal cutter to overlap the horizontal cutter 142. Instead of cutting the cutter 142, ) Is carried out as follows.

A step of installing a drainage material for installing the horizontal drainage material 100 having the vertical drainage material and the extension part 260 and the insertion guide part 262, respectively.

The horizontal drainage member 100 is formed with a perforation 144 by inspecting a plurality of overlapping regions C of the horizontal drainage member 100 and cutting off the filter 140 and the core 120 of the overlapping region C. Ablation stage.

The horizontal drainage lapping step of overlapping the horizontal drainage material so that the perforations 144 of each horizontal drainage material 100 formed in the excavation step are placed in the same position.

D) a step of inserting the support 180 into the perforations 144 of the plurality of horizontal drainage materials 100 after the horizontal drainage lapping step.

(E) a horizontal drainage shielding step of disposing the earthy inlet blocking member (160) at the bottom and top of the plurality of horizontal drainage materials (100) stacked and stacked in the step of overlapping the horizontal drainage material and the step of installing the support.

A horizontal drainage member fixing the movement of the overlapping region C located inside the horizontal drainage members 100 by sandwiching the groundwater inflow blocking members 160 disposed at the bottom and top of the horizontal drainage members 100 after the horizontal drainage member shielding step, step.

수직 Vertical drainage bending step to bend the vertical drainage in the direction of horizontal drainage.

(B) opening the inserting guide provided in the extended portion protruding outwardly of the core of the horizontal drainage material.

(D) a filter removing step of removing a portion of the filter at the bent portion of the vertical drainage.

(D) inserting the bent portion of the vertical drainage material into the horizontal drainage material through the insertion guide portion 262;

The process proceeds to a drainage joining step of joining the vertical drainage material and the horizontal drainage material with the joining member.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100. Horizontal drainage
100 '. Primary horizontal drainage 100 ". Secondary horizontal drainage
120. Core
122. Water passing section 123. Separation section
124. Separation of partition wall 125. Separation plate
127. Bulkhead 140. Filter
142. Resection Section 144. Thinning
160. A soil inflow blocking member 170. A binding member
180. Support 182. Body
184. Support protrusions 186. Holes
C. Overlap region
150. Vertical drainage
150 '. Surface top vertical drainage 150 ". Deep vertical drainage
152. Core of vertical drainage
154. Vertical drainage filter 260. Extension
262. Insertion guide part 280. Cover
282. Insertion hole
210. Primary reinforcement mat 220. Secondary reinforcement mat
10. First buried layer 20. Second buried layer
30. Edit your house
41. Connector 42. Coupler
43. Drain pipe 44. Vacuum pump
G. Earthquake-resistant ground E. Ground

Claims (10)

delete delete a) laying a primary reinforcement mat (210) on the surface of the primary superficial crack and fixing it on the ground;
b) installing a surface layer vertical drainage material 150 'on the first reinforcing mat 210 installed in step a);
and c) advancing the primary consolidation. In the super-soft granular soil improvement method,
The step c)
c-1) installing a primary horizontal drainage material 100 'on the primary reinforcing mat 210;
c-2) connecting the surface-layer vertical drainage material 150 'and the first horizontal drainage material 100';
c-3) progressing the consolidation of the surface layer by the surface-layer vertical drainage 150 'and the primary horizontal drainage 100'
After the step c-3)
d) laying a secondary reinforcement mat (220) on the upper part of the primary horizontal drainage (100 ') and fixing it to the ground;
e) forming a first filler layer (10) on the second reinforcing mat (220);
f) conducting secondary consolidation;
g) installing a deep vertical drainage (150 &quot;) above said first clay layer (10)
And the length of the deep vertical drainage member 150 'is longer than that of the surface-layer vertical drainage member 150'
Prefabricated soil improvement method. The method of claim 3,
After step g)
h) installing a second horizontal drainage (100 &quot;) on the first clay layer (10);
i) connecting the deep vertical drainage material (150 ") and the secondary horizontal drainage material (100");
j) forming a second embankment layer (20) on top of the second horizontal drainage (100 &quot;);
k) &lt; / RTI &gt;
Prefabricated soil improvement method. The method of claim 3,
After step g)
h ') installing a vacuum drainage device;
i &apos;)&lt; / RTI &gt;
Prefabricated soil improvement method. 6. The method of claim 5,
The step h '
Connecting the connector 41 to the end of the deep vertical drainage member 150 "and connecting the coupler 42, the drain pipe 43 and the vacuum pump 44 to the connector 41
Prefabricated soil improvement method. delete The method of claim 3,
In the step b), the installation depth of the surface layer vertical drainage material 150 'is 1 to 5 m
Prefabricated soil improvement method. 5. The method of claim 4,
The first horizontal drainage member 100 'and the second horizontal drainage member 100' are provided with an insertion guide portion 262,
The upper end of the surface layer vertical drainage material 150 'is connected through the insertion guide portion 262 of the first horizontal drainage material 100'
And the upper end of the deep vertical drainage material 150 &quot; is connected through the insertion guide part 262 of the secondary drainage material 100 &quot;
Prefabricated soil improvement method. 5. The method of claim 4,
The step (c-1) includes overlapping the primary horizontal drainage materials 100 'in a lattice form,
Wherein said step h) comprises lapping said secondary horizontal drainage &lt; RTI ID = 0.0 &gt; 100 &quot;
Prefabricated soil improvement method.

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