KR100888668B1 - Ground reinforcement method - Google Patents

Abstract

The present invention relates to a ground reinforcing method, and to provide a ground reinforcing method having an improved ground reinforcing effect and not easily deformed even when the soil load fluctuations, the agent for mounting a fixed frame formed with a through hole at a fixed interval on a stationary ground Step 1; A second step of injecting the vertical member having the hollow portion into the ground through the through hole; A third step of separating and removing the fixing frame from the vertical member; A fourth step of coupling the truss structure to the vertical material penetrated into the ground; A fifth step of filling the hollow part of the vertical member with the horizontal member and the vertical member to form a rigid truss structure; The sixth step of filling and compacting the filling material in the truss structure; characterized in that, by combining the horizontal material on the top of the vertical material penetrated to the ground by using a method of forming a grid-shaped truss structure by the penetration vertical material on the ground This structure improves and reduces settlement, and adopts a structure that combines iron cores inside the vertical members and firmly fixes the horizontal members and vertical members to improve the strength of the truss structure itself. It is possible to provide a truss structure suitable for the field situation.

Truss structure Ground reinforcement frame Construction method Vertical member Horizontal member

Description

Method for improving ground intensity}

1 is a flow chart showing a ground reinforcement method according to a preferred embodiment of the present invention.

Figure 2 is a conceptual diagram showing the combination of the vertical member and the horizontal member according to an embodiment of the present invention.

3 is a perspective view showing a fixing frame used in the present invention.

4 is a cross-sectional view showing a reinforced ground in accordance with one embodiment of the present invention.

Figure 5 is a flow chart showing a ground reinforcement method according to a preferred embodiment of the present invention.

Figure 6 is a conceptual diagram showing the combination of the vertical member and the horizontal member according to a preferred embodiment of the present invention.

Figure 7 is a flow chart illustrating a ground reinforcement method according to a preferred embodiment of the present invention.

8 is a conceptual diagram showing the combination of the truss structure and the vertical member according to a preferred embodiment of the present invention.

9 is a conceptual diagram illustrating various embodiments of the present invention.

10 is an analysis diagram showing vertical displacement when no reinforcement work is performed on the lower part of the structure.

FIG. 11 is an analysis diagram showing the vertical displacement of the ground when the truss structure is installed without entering the ground under the structure. FIG.

12 is an analysis diagram showing the vertical displacement in the state where the structure is installed on the ground 0.5m above the ground is subjected to the reinforcement method according to the present invention.

Figure 13 is an analysis showing the vertical displacement in the state in which the structure is installed on the ground 1.0m above the ground reinforced method according to the present invention.

<Explanation of symbols for main parts of drawing>

10: vertical member 11: coupling groove

12: coupling hole 14: hollow part

16: upper vertical member 17a, 17b: upper and lower coupling grooves

18: cap 20: horizontal

22: iron core 30: truss structure

40: fixed frame 42: through hole

50: Fill 60: Floor Foundation Slab

The present invention relates to a ground reinforcement method, and more particularly, a ground reinforcement method characterized in that it penetrates a vertical member and strengthens the ground strength using a truss structure using a horizontal member and a vertical member on the top.

In general, the ground reinforcement method for reinforcing the fill slope or soft ground is to buy a truss-like structure in the ground or to plant a top-shaped pile in the ground to act as a resistor to withstand the loads of buildings or soil on the ground. To help.

The ground reinforcement method has been proposed in various forms, such as No. 10-0498126, Publication No. 2002-0065910, 10-2006-0064787 registered with the Korean Intellectual Property Office.

In particular, Korean Patent Publication No. 2002-0065910 "Unit-based civil structure, a unit for use in this, and a construction method of a unit-type civil structure" is formed by stacking or squeezing a plurality of blocks, and adjacent blocks are inserted into each other. There is proposed a technique for forming a block structure in the ground in such a way that it is directly connected by fitting or engaging or indirectly by a connecting member.

However, such a conventional technology is not expected to play a role as a rigid resistance to the deformation force in the ground.

In particular, the conventional ground reinforcement method has a problem that the connection part of the truss structure is lower than the strength of other structures, and when the vibration such as an earthquake occurs, the connection part is separated or loosened so that the function as a resistor decreases, and the soil load changes easily. There is a problem in use that the deformation does not provide sufficient ground strength.

The present invention has been made to solve the above problems, the present invention has an improved ground reinforcement effect than the conventional method, and an object of the present invention is to provide a ground reinforcement method that is not easily deformed even in the variation of soil load.

In order to achieve the above object, the present invention includes a first step of mounting a fixed frame formed with a through hole at a fixed interval on a stationary ground; A second step of injecting the vertical member having the hollow portion into the ground through the through hole; A third step of separating and removing the fixing frame from the vertical member; A fourth step of coupling the truss structure to the vertical material penetrated into the ground; A fifth step of filling the hollow part of the vertical member with the horizontal member and the vertical member to form a rigid truss structure; And a sixth step of filling and compacting the filler in the truss structure.

Here, the fourth step is characterized in that the truss structure is formed by combining the rod-shaped horizontal member with the coupling hole formed in the vertical member inserted into the ground.

In addition, the fourth step is to combine the horizontal member with the coupling groove formed in the upper end of the vertical member protruding on the ground; Coupling a hollow upper vertical member having a lower coupling groove to the vertical member; Coupling a horizontal member to an upper coupling groove formed at an upper end of the upper vertical member; And fixing the cap to the upper end of the upper vertical member.

In the fourth step, the truss structure forming the lattice shape is coupled to the vertical member protruding from the ground by using the rod-shaped horizontal member and the hollow upper member.

The horizontal member may be coupled to the vertical member in multiple stages, and the fourth step may include a process of coupling an iron core for strength reinforcement to the hollow portion of the vertical member.

Hereinafter, the ground reinforcement method of the present invention will be described in detail with reference to the accompanying drawings.

1 is a flowchart showing a ground reinforcement method according to a preferred embodiment of the present invention, Figure 2 is a conceptual diagram showing a combination of a vertical member and a horizontal member according to a preferred embodiment of the present invention, Figure 3 is a present invention It is a perspective view which shows the fixing frame used.

As shown in FIG. 1, the present invention includes a first step of mounting a fixed frame having a through hole formed on a stationary ground at a predetermined interval, and a second step of introducing a vertical member having a hollow portion into the ground through the through hole. A third step of separating and removing the vertical member and a fourth step of coupling the truss structure to the vertical member penetrated into the ground, and a fifth step of filling the hollow part of the vertical member to form a rigid truss structure of the horizontal member and the vertical member. It consists of a sixth step of filling the truss structure and compacting the soil.

The first step is to stop the work to be reinforced on the ground to be fixed to the fixing frame, the fixing frame 40 is formed in a flat shape as shown in Figure 3 and the through-holes 42 are formed at regular intervals.

Here, the through holes 42 are formed to penetrate the vertical members to be described later into the ground at regular intervals, and may be formed in a circular or square shape according to the shape of the vertical members, and the intervals between the through holes may be deformed according to the ground conditions. It is possible.

In addition, as shown in Figure 3, the lower portion of the fixing frame 40, it is preferable that the base 44 is formed to facilitate horizontal adjustment when mounted on the ground.

The second step is a step of injecting the vertical member 10 having a hollow portion into the ground through the through hole 42, and the third step is to separate and remove the fixing frame 40 from the vertical member (10).

Here, in the second step in order to easily penetrate the vertical member 10 to the ground to form a penetration hole through which the vertical member is to be inserted at regular intervals on the ground and then combine the vertical member and fill the mortar in the empty space of the penetration hole by It is also possible to use a method of fixing the vertical member firmly.

And the vertical member is made in the form of a tube of a circular or square cross section having a hollow portion 14, as shown in Figure 2, such as metal or FRP (Fiber Reinforced Plastic) material to have a sufficient rigidity according to the ground conditions and the support force Can be used.

Next, the fourth step will be described.

The fourth step is a step of coupling the truss structure to the vertical member 10 introduced into the ground, as shown in Figure 2 is coupled to the coupling hole 12 formed in the vertical member 10 of the rod-shaped horizontal member 20 The truss structure 30 can be formed.

Here, the horizontal member 20 is preferably made of reinforcing bar or FRP as a material having rigidity against tension and compression.

The coupling hole 12 formed in the vertical member is preferably formed in four directions on the outer circumferential surface of the hollow vertical member so that the horizontal member 20 can pass therethrough, and the horizontal member 20 is multistage with the vertical member 10. Since it can be coupled to, as shown in Figure 2 may be formed in each of the upper and lower portions or spaced in multiple stages at regular intervals.

In particular, as shown in (b) of FIG. 2, in this step, a process of coupling the iron core 18 to the hollow portion 14 of the vertical member 10 to which the horizontal member 20 is coupled is added so that the truss structure itself is added. Strength can be improved.

Here, the iron core 18 is preferably formed in a U-shape as shown to be configured to be fitted in the space between the horizontal member crossing the hollow portion of the vertical member crosswise.

Next, the fifth step is to fill the mortar in the hollow portion 14 of the vertical member 10 to form a rigid truss structure of the horizontal member and the vertical member. Through the fourth step, the horizontal member is joined and crossed at the hollow part of the vertical member, and in this step, the mortar is filled in the hollow part 14 to be firmly fixed.

Finally, the sixth step is to fill and compact the filler in the truss structure (30).

4 is a cross-sectional view showing the reinforced ground according to one embodiment of the present invention.

As shown in FIG. 6, the filling 50 is filled in the space between the lattice structures of the truss structure and completed to be compacted. At this time, the filler is preferably using crushed stone or high quality soil, and when using the crushed stone is preferably limited to 40mm or less.

After the above process, the floor foundation slab 60, which is the bottom foundation of the structure, is installed to construct the structure.

In particular, Figure 4 (b) is coupled to the vertical member 10 in the penetration hole (2) formed at regular intervals in the ground in the second step and filling the mortar (3) in the empty space of the penetration hole (2) vertical material The cross section at the time of fixing 10 securely is shown.

Next, another embodiment will be described.

5 and 6 are a flow chart showing a ground reinforcement method according to a preferred embodiment of the present invention and a conceptual diagram showing the combination of the vertical member and the horizontal member.

As shown, this embodiment is the same as the above-described embodiment from the first step to the third and sixth step, but according to the present embodiment, the fourth step is a truss to form a grid using a horizontal member and an upper vertical member The structure 30 is coupled to the vertical member protruding from the ground.

In particular, as shown in Figure 6, the truss structure 30 is completed by combining the horizontal hole and the coupling hole (12a) formed in the upper vertical member 16, the vertical member intruding the truss structure 30 into the ground ( 10).

In addition, since the upper vertical member is coupled to the vertical member, the vertical member does not have to protrude sufficiently from the above-described embodiment in the second step of injecting the vertical member into the ground.

Next, another embodiment will be described.

7 and 8 are a flow chart illustrating a ground reinforcement method according to a third embodiment of the present invention and a conceptual diagram showing the combination of the truss structure and the vertical member.

As shown, this embodiment is the same as the above-described embodiment from the first step to the third step and the sixth step, but according to the present embodiment, the fourth step is formed in the upper end of the vertical material protruding the horizontal member on the ground Coupling a hollow upper vertical member having a lower coupling groove to the vertical member; coupling a horizontal member to an upper coupling groove formed at an upper end of the upper vertical member; and a cap at an upper end of the upper vertical member. It consists of a step of fixing.

As illustrated in FIG. 5, the vertical member used in the present embodiment has a coupling groove 11 having a concave groove shape formed in four directions at an upper end thereof so that the horizontal member 20 can be seated.

In addition, the upper vertical member 16 has upper and lower coupling grooves 17a and 17b formed at upper and lower ends thereof, respectively, to be coupled to the upper portion of the vertical member 10, and to restrict the horizontal member 20 to the upper portion of the upper vertical member 16. Cap 18 is coupled, it is preferable that the coupling groove (18a) is formed in the lower portion of the cap (18).

In addition, as shown in (a) and (b) of FIG. 5, the vertical member and the upper vertical member are preferably manufactured in the form of a hollow shaft having a rectangular or circular cross section.

Next, a specific embodiment of the present invention will be described.

Ground reinforcement method according to the present invention can be applied in various forms, such as to prevent scour of the bridge piers or to show the effect of reducing the weight when the back of the structure.

In particular, the truss structure used in the ground reinforcement method according to the present invention as described above can be produced in various forms, Figure 9 is a conceptual diagram showing various embodiments of the present invention.

Figure 9 (a) shows the truss structure manufactured in one stage, and as shown in (b), (c), (e) shows a form that is combined with the vertical member with three horizontal members, (d) is a cross section showing an embodiment in which a truss structure manufactured in advance in a factory is formed in two stages in advance.

Next, the case of the ground reinforcement method according to the present invention will be described for the vertical displacement distribution.

FIG. 10 is an analysis diagram showing vertical displacement when no reinforcing work is performed on the lower part of the structure, and FIG. 11 is an analysis diagram showing vertical displacement of the ground when the truss structure is installed without entering the ground.

12 and 13 are analytical diagrams showing vertical displacements in a state in which structures are installed at 0.5m and 1.0m above the ground where the ground reinforcement method according to the present invention is applied.

As shown in FIG. 10, the maximum vertical displacement is 4.15 cm when the load is applied from the upper part when no reinforcement is applied. When the truss structure is installed without intruding into the ground, the vertical maximum displacement is 3.12 cm and the truss structure is inserted into the ground by 0.5 m. The maximum vertical displacement was 2.82cm and the maximum vertical displacement was 2.23cm in the ground.

The experimental results were analyzed using MIDAS GTS (Trial ver 1.56), the load applied to the ground was 10tonf / m ² , and the truss structure embedded in the ground was 2.0m × 2.0m × 0.3m. Table 1 shows the specific conditions of the crushed stone, which is a filler filled in the clay layer and the truss structure that forms the ground during modeling.

Table 1

division γ _t (tf / m ³ ) γ _sat (tf / m ³ ) φ (°) c (tf / m ²⁾ υ E _s (tf / m ² ) Crushed stone 1.90 2.00 35 0 0.30 6,000 Clay layer 1.60 1.70 0 2.0 0.35 1,000

Through the above results, it can be seen that the vertical maximum displacement decreases as the vertical member is deeply inserted into the ground.

As described above, it can be seen that the present invention provides a ground reinforcing method for forming a truss structure having a lattice shape by coupling a horizontal member to an upper portion of a vertical member inserted into the ground. Of course, within the scope of the basic idea, many other variations are possible for those skilled in the art.

As described above, the present invention utilizes a method of forming a truss structure having a lattice shape by coupling a horizontal member to an upper portion of a vertical member inserted into the ground, so that the bearing capacity can be improved and the settlement can be reduced by the vertical member inserted into the ground. There is an advantage to providing a method.

In addition, by adopting a structure that couples the iron core inside the vertical member and firmly fixed the horizontal member and the vertical member has a ground reinforcement effect through improving the strength of the truss structure itself.

In particular, it is possible to assemble the horizontal and vertical members in the field has the advantage of providing a truss structure suitable for the field situation.

Claims (6)

A first step of mounting the fixed frame on which the through-hole is formed on the stationary ground at regular intervals; A second step of injecting the vertical member having the hollow portion into the ground through the through hole; A third step of separating and removing the fixing frame from the vertical member; A fourth step of coupling the truss structure to the vertical material penetrated into the ground; A fifth step of filling the hollow part of the vertical member with the horizontal member and the vertical member to form a rigid truss structure; And a sixth step of filling and compacting the filling material in the truss structure. A first step of mounting the fixed frame on which the through-hole is formed on the stationary ground at regular intervals; A second step of injecting the vertical member having the hollow portion into the ground through the through hole; A third step of separating and removing the fixing frame from the vertical member; A fourth step of forming a truss structure by combining a rod-shaped horizontal member with a coupling hole formed in the vertical member inserted into the ground; A fifth step of filling the hollow part of the vertical member with the horizontal member and the vertical member to form a rigid truss structure; And a sixth step of filling and compacting the filling material in the truss structure. The method of claim 1, The fourth step, Engaging the horizontal member with a coupling groove formed at an upper end of the vertical member protruding from the ground; Coupling a hollow upper vertical member having a lower coupling groove to the vertical member; Coupling a horizontal member to an upper coupling groove formed at an upper end of the upper vertical member; Fixing the cap on the upper end of the upper vertical member; Ground reinforcement method characterized in that consisting of. The method of claim 1, The fourth step, A ground reinforcement method comprising the use of a bar-shaped horizontal member and a hollow upper vertical member to combine a truss structure forming a lattice shape with a vertical member protruding from the ground. The method of claim 2, The horizontal member is ground reinforcement method, characterized in that coupled to the vertical member in multiple stages. The method according to claim 1 or 2, The fourth step is Ground reinforcement method comprising the step of coupling the iron core for strength reinforcement in the hollow portion of the vertical material.

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