KR102254076B1 - Method of calculating distributed loads and ground reinforcement method using it - Google Patents

Abstract

The present invention includes: a foundation constructed on weak ground; a load dispersion part supporting the foundation, and dispersing and delivering a load delivered from the foundation; and a reinforcement part supporting the load dispersion part, and providing a tensile force in a lateral direction to prevent the load dispersion part from being deformed or broken, and prevent a filler from being swept away from the load dispersion part. A load (ΔP2) reduced by the load dispersion part and the reinforcement part is calculated based on ΔP2 = p × (1-B / B + 2 × Hcell × tanβ), the p is a surface load applied to the foundation, the B is a width length of the foundation, the Hcell is the thickness of the load dispersion part, and the β is a surface load dispersion angle.

Description

{Method of calculating distributed loads and ground reinforcement method using it}

The present invention relates to a distributed load calculation method and a ground reinforcement method using the same, and more particularly, to support a foundation to be constructed on the ground, and to provide a load distribution unit constructed to widely distribute and transmit the load of the foundation, and the load Since the dispersion unit is provided with a reinforcement unit that prevents loss of the distribution unit and prevents the load distribution unit and the ground from being buried by providing a tensile force in the lateral direction, the size of the foundation can be reduced by providing an effect of reducing the load transmitted from the foundation. , It relates to a distributed load calculation method that can reduce the size and number of improved bodies constructed in the ground, and a ground reinforcement method using the same.

In general, since the soil condition of soft ground is high moisture content, the soil bearing capacity of the ground is weak. Therefore, in order to install a structure on the soft ground, water contained in the soft ground is drained over a long period of time, and the soft ground is consolidated and improved. You will build it later.

As a conventional technique for improving such soft ground, there is a sand drain method that improves the soft ground by sand piles, and in the sand drain method, the soft ground is excavated to a certain depth, and then an insulating layer of a certain thickness is laid on the top. A number of holes are drilled at regular intervals and sand is filled into the drilled holes to form sand piles, and a sand mat layer is formed on top of the sand mat layer with a certain thickness, and then a certain height is filled with sand on top of the sand mat layer. It is one of the consolidation methods in which the ground is solidly consolidated by draining the water contained in the soft ground over a long period of time through the sand pile and the sand mat layer by forming a layer.

In the above-described conventional technology, the sand mat layer is simply composed of a layer of sand, and the loading load of the embankment layer that is filled to a certain height above it and the traffic load of heavy equipment such as vehicles as a traffic path on the surface of the embankment layer are supported and transmitted to the ground. However, since there is no separate reinforcement structure in the ground, the supporting power of the ground is weak, causing differential settlement of the order layer, sand mat layer, and embankment layer. When this occurs, the water cannot escape and becomes a stagnant state, and thus a phenomenon in which drainage from the sand mat layer is not smoothly performed occurs.

Therefore, it is necessary to install a sturdy reinforcement structure in the ground in order to use the surface of the embankment layer as a transportation route for heavy equipment, while preventing the unequal settlement of the ground by distributing and supporting the overhead load transmitted to and acting on the drainage layer. There is.

In order to solve the above problems, a construction method of a reinforcing structure of soft ground using a grid-like structure of a cell structure has been developed, and the construction method according to the prior art includes the steps of excavating the soft ground to a certain depth and The steps of forming a water barrier layer by laying a nonwoven fabric mat on the top of the floor, forming a sand pile by filling sand bags into the drilled holes by forming perforated holes at regular intervals, and forming a sand pile with a certain thickness on the top of the sand pile In the soft ground improvement method including the step of forming a water permeable layer and forming an embankment layer over the permeable layer, a grid-type structure in which a drainage passage is formed so as to allow at least water permeation on the vertical wall of the grid-like structure of the cell structure when the permeable layer is formed It includes the steps of installing an integrated internal frame by assembling and connecting the top of the water barrier layer at the site, and filling the permeable granular aggregate inside the cell spaces of the lattice-like structures.

The background technology of the present invention is disclosed in Korean Registered Patent Publication No. 10-0243393 (announced on February 01, 2000, title of the invention: a soft ground reinforcement structure using a grid-like structure of a cell structure and its construction method).

The reinforcing structure of the soft ground according to the prior art and its construction method are not provided with a separate technical configuration that prevents the loss of the granular aggregate filled in the grid-like structure, so that the granular aggregate is lost from the grid-like structure. It is difficult to reduce the time and cost required for ground reinforcement because there is a problem that the support strength may be lowered, the shape of the lattice structure is complicated and construction is not easy, and the amount of reduction of the load sprayed by the lattice structure is accurately measured. Because it is difficult to do, it is difficult to accurately calculate the size and number of sand piles, and it is possible to construct a larger number of sand piles than necessary or to construct a larger number of sand piles than necessary, thereby reducing the time and cost required for the ground reinforcement method. There is a difficult problem.

Therefore, there is a need to improve this.

The present invention supports the foundation to be constructed on the ground, has a load distribution unit constructed to distribute and transmit the load of the foundation widely, prevents the load distribution unit from being lost, and provides a lateral tensile force to the load distribution unit and the ground. Distributed load calculation method that can reduce the size of the foundation by providing the effect of reducing the load transmitted from the foundation, and to reduce the size and number of improvements to be constructed in the ground since it has a reinforcing part that prevents this burial. And to provide a ground reinforcement method using the same.

The present invention, the foundation to be constructed on the soft ground; A load distribution unit supporting the foundation and distributing and transmitting a load transmitted from the foundation; And a reinforcing part supporting the load distributing part, preventing the load distributing part from being deformed or damaged by providing a tensile force in a lateral direction, and preventing the filler from being lost from the load distributing part, the load distributing part and the _{The load (ΔP 2} ) reduced by the reinforcement part is,

에 의해 계산되고, 상기 p는 상기 기초에 가해지는 상재하중이고, 상기 B는 상기 기초의 폭 길이이고, 상기 H_cell은 상기 하중분산부의 두께이고, 상기 β는 상재하중 분산각도인 것을 특징으로 한다.

It is calculated by, wherein p is the bed load applied to the base, B is the width and length of the base, the H _cell is the thickness of the load distribution unit, and β is the bed load distribution angle. .

In addition, the load distribution unit of the present invention, a geocell member seated on the reinforcing portion and formed in a honeycomb shape; A filling material filled in the storage space provided by the geocell member; And a connection fixing part fixed to the ground by connecting the geocell members adjacent to each other when the plurality of geocell members are continuously seated.

In addition, the reinforcing part of the present invention, the blocking member disposed in close contact with the geo-cell member to prevent the filling material accommodated in the geo-cell member from being lost to the ground side, the blocking member to block moisture flowing into the reinforcing part side; A tension member supporting the blocking member to prevent the blocking member from being damaged, and providing a lateral tensile force supporting the blocking member and the load distribution unit; And a reinforcing member interposed between the tension member and the ground and increasing the rigidity of the reinforcing earth body to prevent sagging of the tension member, the blocking member, and the load distribution portion toward the ground.

_{In addition, the tensile force (ΔP 3} ) generated by the tension member of the present invention is,

에 의해 계산되고, 상기 B는 상기 기초의 폭 길이이고, 상기 T는 상기 인장부재의 설계 인장강도이고, 상기 α는 인장력의 수평각도인 것을 특징으로 한다.

It is calculated by, wherein B is the width and length of the foundation, T is the design tensile strength of the tension member, and α is the horizontal angle of the tensile force.

In addition, the present invention, (a) proceeding to clean the foundation surface on the construction target ground, and the steps of constructing a reinforcement; (b) seating a geocell member of the load distribution unit on the reinforcement unit, and connecting a plurality of geocell members to the ground and fixing the geocell member; (c) installing and inserting a filler material into the storage space of the geocell member; And (d) providing vibration to the geocell member and the filling material to perform compaction fixing, wherein the load (ΔP ₂ ) reduced by the load distribution unit and the reinforcement unit is,

에 의해 계산되고, 상기 p는 상기 기초에 가해지는 상재하중이고, 상기 B는 상기 기초의 폭 길이이고, 상기 H_cell은 상기 하중분산부의 두께이고, 상기 β는 상재하중 분산각도이고, 상기 식에 의해 계산되는 설계하중에 따라 상기 하중분산부에 의해 지지되는 기초의 크기 및 지면에 시공되는 개량체의 크길 및 개수를 조절하는 것을 특징으로 한다.

Is calculated by, wherein p is the bed load applied to the base, B is the width and length of the base, the H _cell is the thickness of the load distribution unit, and β is the bed load distribution angle, According to the design load calculated by controlling the size of the foundation supported by the load distribution unit and the size and number of improvements installed on the ground.

The distributed load calculation method according to the present invention and the ground reinforcement method using the same include a tension member and a reinforcing member that prevents sagging of the blocking member and prevents the loss of the fill material from the load spraying part, in addition to the blocking member providing the order function. Since it is provided, it is possible to effectively prevent the filling material from being lost from the load distribution unit, thereby preventing sagging occurring in the load distribution unit, and preventing deformation or damage of the load distribution unit from the foundation supported by the load distribution unit. There is an advantage in that the transmitted load can be effectively distributed and transmitted.

In addition, the distributed load calculation method according to the present invention and the ground reinforcement method using the same can accurately calculate the load reduced by the reinforcement unit and the load distribution unit, so the size of the foundation, the size and number of the improved body according to the reduced load. Since it can be accurately calculated, the size of the foundation to be constructed more than necessary, the size or number of improved bodies can be reduced, and accordingly, there is an advantage that the time and cost required for the ground reinforcement method can be significantly reduced.

In addition, the distributed load calculation method and the ground reinforcement method using the same according to the present invention include a connection fixing unit that connects the geocell members constituting the load distribution unit to the ground and fixes a plurality of geocell members made of a synthetic resin material to the ground. It is upright on the ground and can be constructed on the ground so that a plurality of geocell members are continuously connected to each other, so that the construction of the reinforcement part can be easily proceeded, and the time and cost required for the ground reinforcement method can be further significantly reduced. There is this.

In addition, the distributed load calculation method and the ground reinforcement method using the same according to the present invention are provided with a column member and a cap member for fixing to the ground by connecting ends of geocell members disposed adjacent to each other. A plurality of geocell member ends are inserted into one column member to be fixed, and a plurality of geocell member ends can be simultaneously constrained by coupling a cap member to the fitting groove of the column portion into which the plurality of geocell member ends are inserted. There is an advantage that it is possible to easily connect the ends of the geocell members and fix a portion to which the ends of the plurality of geocell members are connected to the ground, so that the time and cost required for construction of the geocell members can be remarkably reduced.

1 is a cross-sectional view showing a ground reinforcement structure constructed by a ground reinforcement method using a distributed load calculation method according to a first embodiment of the present invention.
2 is a view showing the horizontal resistance effect of the load distribution unit by the base reinforcement method using the distributed load calculation method according to the first embodiment of the present invention.
3 is a view showing the effect of distributing the load by the base reinforcement method using the distributed load calculation method according to the first embodiment of the present invention.
4 is a view showing the tensile resistance effect of the ground reinforcement method using the distributed load calculation method according to the first embodiment of the present invention.
5 is a photograph showing a ground reinforcement method using the distributed load calculation method according to the first embodiment of the present invention.
6 is an exploded perspective view illustrating a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to a first embodiment of the present invention.
7 is a cross-sectional view illustrating a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to a second embodiment of the present invention.
8 is a cross-sectional view illustrating a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to a third embodiment of the present invention.
9 is an exploded cross-sectional view showing a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to a fourth embodiment of the present invention.
10 is a cross-sectional view illustrating a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to a fifth embodiment of the present invention.
11 is a cross-sectional view illustrating a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to a sixth embodiment of the present invention.
12 is a cross-sectional view illustrating a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to a seventh embodiment of the present invention.

Hereinafter, an embodiment of a distributed load calculation method and a ground reinforcement method using the same according to the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators.

Therefore, definitions of these terms should be made based on the contents throughout the present specification.

1 is a cross-sectional view showing a ground reinforcement structure constructed by a ground reinforcement method using a distributed load calculation method according to a first embodiment of the present invention, and FIG. 2 is a distributed load according to the first embodiment of the present invention. It is a diagram showing the horizontal resistance effect of the load distribution unit by the foundation reinforcement method using the calculation method, and Fig. 3 shows the load distribution effect by the foundation reinforcement method using the distributed load calculation method according to the first embodiment of the present invention. It is a drawing.

In addition, Figure 4 is a view showing the tensile resistance effect by the ground reinforcement method using the distributed load calculation method according to the first embodiment of the present invention, Figure 5 is a distributed load according to the first embodiment of the present invention A photograph showing a ground reinforcement method using a calculation method is shown, and FIG. 6 is an exploded perspective view illustrating a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to the first embodiment of the present invention.

1 to 6, the distributed load calculation method according to an embodiment of the present invention includes a foundation constructed on a soft ground, and a load distribution unit that supports the foundation and distributes and transmits the load transmitted from the foundation. (30) And, by supporting the load distribution unit 30, and by providing a tensile force in the lateral direction, the load distribution unit 30 is prevented from being deformed or damaged, and the filling material 34 is lost from the load distribution unit 30 It includes a reinforcing portion 10 to prevent it from becoming.

The ground reinforcement structure of this embodiment provides an equal load distribution effect, simplifies the ground reinforcement method in the field and minimizes weight work, so that a reinforcement part 10 made of a fiber material, a synthetic resin material, and a metal material is installed on the ground. After that, a load distribution part 30 was installed on the upper surface of the reinforcing part 10 to improve the integrity and rigidity of the ground reinforcement structure.

The reinforcing part 10 of this embodiment is disposed in close contact with the geo-cell member 32 to prevent the filling material 34 accommodated in the geo-cell member 32 from being lost to the ground side, and flows into the reinforcing part 10 side. A blocking member 12 that blocks moisture and supports the blocking member 12 to prevent the blocking member 12 from being damaged, and a lateral tensile force that supports the blocking member 12 and the load distribution unit 30 The reinforcing earth body is interposed between the tension member 14 and the tension member 14 and the ground, and the tension member 14, the blocking member 12, and the load distribution part 30 are prevented from sagging toward the ground. It includes a reinforcing member 16 to increase the rigidity.

Here, since the blocking member 12 is made of a fibrous material such as a nonwoven fabric, when the blocking member 12 is disposed in close contact with the bottom surface of the geocell member 32, the filling member 34 accommodated in the geocell member 32 It is possible to prevent is lost to the bottom surface of the geocell member 32.

The tension member 14 of this embodiment is made of a sheet of a lattice structure made of a synthetic resin material such as a geogrid or a geomat, and the blocking member 12 while supporting the bottom surface of the blocking member 12 having a good ordering effect but weak stiffness. Is prevented from being deformed or damaged, and the end of the tension member 14 is fixed by a fixing member such as an anchor to the rim of the construction target surface, thereby providing a tensile force that pulls the reinforcing part 10 in the lateral direction.

The reinforcing member 16 of this embodiment is made of a metal material such as a metal mesh, and is seated on the ground by supporting the bottom surface of the tension member 14, so that the load applied to the blocking member 12 and the tension member 14 The support strength is improved to prevent the reinforcing portion 10 from sagging downward.

In addition, the load distribution unit 30 of this embodiment is seated on the reinforcing unit 10 and filled in the storage space provided by the geocell member 32 and the geocell member 32 formed in a honeycomb shape. It includes a filling member 34 and a connection fixing part 50 fixed to the ground by connecting the geocell members 32 adjacent to each other when the plurality of geocell members 32 are continuously seated.

Here, the geocell member 32 is made of a synthetic resin material, and is joined while maintaining a constant distance in a state in which a plurality of long synthetic resin panels are disposed to overlap, and since adjacent joints are arranged to be spaced apart from each other, a plurality of synthetic resin panels are formed. When it is spread out, the other parts except the bonding area are opened to form a honeycomb-shaped grid.

Geocell member 32 spread out in a honeycomb shape over the entire construction target surface by placing the expanded geocell member 32 on the upper surface of the reinforcing part 10 and continuously arranging a plurality of geocell members 32 ) Can be settled.

As described above, a storage space is formed inside the geocell member 32 while being unfolded, the filling material 34 is injected into the storage space of the geocell member 32, and a compaction process is performed to remove the load distribution unit 30. It will be constructed.

The filling material 34 may be made of gravel, crushed stone aggregate, concrete, site-generated soil and middle-layer slime, and the filling material 34 filled in the geocell member 32 is in close contact with the bottom surface of the geocell member 32 The blocking member 12 is blocked so as not to be lost to the lower side of the geocell member 32 by the blocking member 12 arranged to be disposed, and the blocking member 12 by the tension member 14 and the reinforcing member 16 disposed on the bottom of the blocking member 12 ) Can be prevented from sagging or being damaged to the lower side, so that the filling material 34 can be more effectively prevented from being lost to the outside of the geocell member 32.

The foundation is constructed on the upper surface of the load distribution unit 30 constructed as described above. Since the load distribution unit 30 distributes the load applied to the foundation and transmits it to the ground, the effect of reducing the load on the ground where the load is concentrated. Even if the size of the foundation is reduced, it is possible to stably support the structure to be constructed on the foundation.

As described above, it is possible to provide an effect of reducing the load transmitted to the ground by the reinforcement part 10 and the load distribution part 30 of this embodiment, so that the size of the foundation can be reduced, and an improved body constructed on the ground It is possible to reduce the size and number of construction, thereby reducing the time required for the ground reinforcement method, and it is possible to reduce the construction cost required for the ground reinforcement method.

The load reduced by the reinforcing part 10 and the load distributing part 30 of this embodiment is the horizontal resistance of the load distributing part 30, the load distributing effect of the load distributing part 30, and the reinforcing part 10 It can be calculated by the sum of the tensile resistance effect of, and the horizontal resistance effect (ΔP ₁ ) of the load distribution unit 30 is calculated by Equation 1.

[Equation 1]

Here, p is the upper load applied to the foundation, Φ is the internal friction angle of the filler 34, and σ is the friction angle between the geocell member 32 and the filler 34.

Accordingly, a plurality of storage spaces are filled with a load distribution unit 30 to form a load distribution unit 30, and when a load is transmitted to the load distribution unit 30 by constructing a foundation at the center of the load distribution unit 30, the load is transmitted from the foundation. Since horizontal resistance is generated from the storage space disposed adjacent to the center of the load distribution unit 30, horizontal resistance is provided from all directions to the center of the load distribution unit 30 on which the foundation is constructed, thereby supporting the bottom surface of the foundation upward. Resistance is generated.

In addition, the load distribution effect (ΔP ₂ ) generated by the load distribution unit 30 is calculated by Equation 2.

[Equation 2]

Here, p is the bed load applied to the base, B is the width of the base, H _cell is the thickness of the load distribution unit 30, and β is the distribution angle of the bed load.

After the filling material 34 is filled in the geocell member 32, the compaction process proceeds to complete the load distribution unit 30, which has the same effect as an increase in the depth of _{entry of the foundation (D f) and the width of the foundation.} Since it is provided, it provides the effect of reducing the overhead load.

_{In addition, the tensile force (ΔP 3} ) generated by the tension member 14 of the present embodiment is calculated by Equation 3.

[Equation 3]

Here, B is the width and length of the foundation, T is the design tensile strength of the tension member 14, and α is the horizontal angle of the tensile force.

As described above, since the reinforcing part 10 of this embodiment is integrated in a film shape on the bottom of the load distribution part 30, it provides the same effect as that of constructing a beam in a grid shape on the bottom of the foundation, thereby increasing the stiffness of the ground. The effect of improving appears, and when the foundation is constructed on the upper surface of the load distributing unit 30, the tensile resistance according to the equation 3 is generated by the action of the load distributing unit 30 and the reinforcing unit 10.

As described above, the load (ΔP) is reduced without being transmitted to the ground by the sum of _{the horizontal resistance effect (ΔP 1} ), the load distribution effect (ΔP ₂ ), and the tensile resistance effect (ΔP ₃ ) of the load distribution unit 30 as described above. =ΔP ₁ +ΔP ₂ +ΔP ₃ ) can be calculated.

The connection fixing part 50 of this embodiment includes a fitting groove 54 into which ends of a plurality of geocell members 32 are simultaneously inserted, and includes a column member 52 inserted into the ground, so that a plurality of geocell members When spreading out 32 and continuously seating on the upper surface of the reinforcing part 10, the column member 52 is inserted into the ground at the connection part where the ends of the geocell members 32 are disposed to face each other, and are disposed adjacent to each other. The ends of the pair of geocell members 32 are inserted into the fitting grooves 54 to connect the ends of the geocell members 32 to each other.

Therefore, even if a plurality of geo-cell members 32 are continuously constructed, a plurality of column members 52 are inserted into the ground along the rim of the geo-cell member 32, and geo- The fitting groove portion of the column member 52 is disposed upright on the ground in a state where the end of the cell member 32 is inserted and the geocell member 32 is unfolded, and is installed at a portion to which the end of the geocell member 32 is connected A pair of geocell members 32 are simultaneously inserted into 54 to connect the geocell members 32 disposed adjacent to each other.

Referring to the ground reinforcement method using the distributed load calculation method according to an embodiment of the present invention configured as described above is as follows.

In the ground reinforcement method using the distributed load calculation method according to an embodiment of the present invention, the steps of arranging the foundation surface on the ground to be constructed, constructing the reinforcing part 10, and distributing the load to the reinforcing part 10 Mounting the geocell member 32 of the part 30, connecting the plurality of geocell members 32 to the ground, and installing a filler 34 in the storage space of the geocell member 32 Inserting and providing vibration to the geocell member 32 and the filling material 34 to perform compaction and fixation.

First, a reinforcing member 16 made of a metal mesh is installed after the planarization work is performed on the ground to be constructed and foreign substances are removed, and a tension member 14 made of a geogrid woven in a grid shape is installed on the upper surface of the reinforcing member 16. Thus, the rim of the tension member 14 is fixed with an anchor, field soil or filling stone, and a blocking member 12 made of a non-woven fabric is installed on the upper surface of the tension member 14.

Thereafter, a plurality of geocell members 32 are unfolded and installed upright on the ground while being continuously arranged, and the edge of the geocell member 32 penetrates the reinforcement part 10 and is fixed to the ground by a connection fixing part 50 It is installed to be supported by

Geocell members facing each other by simultaneously fastening the ends of the geocell members 32 disposed to face each other after the connection fixing part 50 is installed at the ends of the geocell member 32 at which the edges and the edges are disposed to face each other Make sure that the ends of 32 are connected to each other.

After that, the filling material 34 is installed and filled in the storage space formed by the geocell member 32, and the filling material 34 is compacted and hardened so that it is flattened using a compaction equipment, and the load distribution unit 30 is constructed. When the hardening of the load distribution unit 30 is completed, a foundation is constructed on the upper surface of the load distribution unit 30.

The basis of this embodiment is to reduce the size of the foundation supported by the load distribution unit 30 and the size and number of improvements installed on the ground according to the design load calculated by Equations 1 to 3 above. Therefore, it is possible to reduce the time and cost required for the ground reinforcement method.

The connection fixing part 50 of this embodiment includes a column member 52 that penetrates the reinforcement part 10 and is fixed to the ground, and has a fitting groove 54 into which the end of the geocell member 32 is inserted. Therefore, after pressing the column member 52 into the fixed part and the ground using a tool, insert the end of the geocell member 32 into the fitting groove 54 formed on the upper surface of the column member 52 to insert the geocell member ( 32) allows you to keep the unfolded state.

In addition, geocell members 32 disposed adjacent to each other while the ends of the plurality of geocell members 32 are inserted into one column member 52 at the connection portion where the ends of the plurality of geocell members 32 are disposed to face each other. ) Can be connected, and the depth of the fitting groove 54 is formed short compared to the height of the geocell member 32, so the end of the geocell member 32 protrudes to the top surface of the column member 52. do.

Therefore, it is possible to prevent deformation or damage while the pillar member 52 is pressed by a tool or equipment performing the compaction process when the filling material 34 is compacted.

7 is a cross-sectional view showing a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to a second embodiment of the present invention, and FIG. 8 is a distributed load calculation method according to a third embodiment of the present invention. It is a cross-sectional view showing the connection fixing part used in the ground reinforcement method using, and FIG. 9 is an exploded cross-sectional view showing the connection fixing part used in the ground reinforcement method using the distributed load calculation method according to the fourth embodiment of the present invention.

In addition, FIG. 10 is a cross-sectional view showing a connection fixing part used in a ground reinforcement method using a distributed load calculation method according to a fifth embodiment of the present invention, and FIG. 11 is a distributed load according to a sixth embodiment of the present invention. A cross-sectional view showing the connection fixing part used in the ground reinforcement method using the calculation method, and FIG. 12 is a cross-sectional view showing the connection fixing part used in the ground reinforcement method using the distributed load calculation method according to the seventh embodiment of the present invention. .

7 to 12, the connection fixing part 50 according to the second embodiment of the present invention is fitted to the upper end of the column member 52 and the column member 52, and the geocell member 32 It includes a cap member 70 for restraining the end of the.

Here, the opening formed at the lower end of the cap member 70 has the same cross-sectional area as compared to the upper end of the column member 52 or is formed finely, so that the column member 52 and the cap member 70 made of a synthetic resin material are pressed into each other. As it becomes, it is forced to fit.

The connection fixing part 50 according to the third embodiment of the present invention includes a column member 52 having a stepped step so that the cross-sectional area is narrowed at the bottom, so that the cross-sectional area when inserting the column member 52 into the fixing part and the ground is As the lower portion of the narrow pillar member 52 is inserted, it is possible to facilitate the insertion.

The connection fixing part 50 according to the fourth embodiment of the present invention engages the column member 52, the cap member 70, the cap member 70 and the column member 52, and engages the cap member ( It includes a restraining portion 72 that adjusts the insertion degree of the cap member 70 to the end of the geocell member 32 so that the cap member 70 is in close contact with each other.

In addition, the restraining portion 72 of the present embodiment has a plurality of locking protrusions 74 formed on the inner wall of the cap member 70 and the outer wall of the column member 52 so as to face the locking protrusion 74 at regular intervals. It includes an adjustment groove 76 that is formed while maintaining.

Therefore, when the cap member 70 is inserted into the end of the column member 52, the lower end of the cap member 70 is deformed in the outward direction and is inserted into the column member 52, and when the insertion of the cap member 70 is completed, a locking stone As the device 74 is inserted into the adjustment groove 76, the cap member 70 and the column member 52 are engaged with each other.

Thereafter, when the cap member 70 is further pressed toward the ground, the locking protrusion 74 slides outside the adjustment groove 76 and descends, and is inserted into the next adjustment groove 76, so that the upper end of the cap member 70 While inserting the cap member 70 into the column member 52 until the inner wall is in close contact with the top of the geocell member 32, it is possible to perform step-by-step engagement.

The connection fixing part 50 according to the fifth embodiment of the present invention includes a pin member 80 that penetrates the fixing part and is inserted into the ground to constrain the geocell member 32, and the pin member ( 80 includes an insertion pillar 82 inserted into the ground, and an elastic groove 84 that is bent from the corresponding insertion pillar 82 and surrounds the end of the geocell member 32.

Therefore, if the insertion pillar 82 is disposed adjacent to the end of the geocell member 32 so as to surround the top of one or more geocell members 32 and inserted into the ground, The curved elastic groove 84 surrounds the upper end of the geocell member 32 and restrains and supports the edge of the geocell member 32.

The connection fixing part 50 according to the sixth embodiment of the present invention includes the insertion column 82, the elastic groove part 84, and the insertion column 82 so as to change the bending direction of the elastic groove part 84 upward. And a bent portion 86 provided between the elastic groove portion 84.

Since the elastic groove portion 84 of this embodiment is provided with a bent portion 86 at the top of the insertion column 82 so that an opening is provided at the top, the insertion column 82 is fixed before the geocell member 32 is seated on the fixing unit. When inserted into the top and the ground, the elastic groove 84, whose direction is changed by the bent part 86, is opened upward, so that the geocell member 32 is inserted while inserting the end of the geocell member 32 into the elastic groove 84. You will be able to settle.

The connection fixing part 50 according to the seventh embodiment of the present invention is rotatably installed in the insertion pillar 82, the elastic groove part 84, the bent part 86, and the bent part 86, and the elastic groove part It includes a fixing cap (90) that is coupled to 84 to constrain the geocell member (32) inserted into the elastic groove (84).

The fixing cap 90 of this embodiment has one end rotatably installed on the bent part 86 by the hinge part 92, and the hook member 94 formed in the elastic groove part 84 at the other end of the fixing cap 90 A locking ring 96 that is engaged with and is formed.

Therefore, after inserting the end of the geocell member 32 into the elastic groove portion 84, when the fixing cap 90 is rotated around the hinge portion 92, the hook member 94 and the locking ring 96 are engaged. As the fixing cap 90 is coupled with the elastic groove 84, the geocell member 32 is constrained.

Thereby, it supports the foundation to be constructed on the ground, has a load distribution unit constructed to distribute and transmit the load of the foundation widely, prevents the loss of the load distribution unit, and provides a tensile force in the lateral direction, so that the load distribution unit and the ground are Distributed load calculation method that can reduce the size of the foundation by providing the effect of reducing the load transmitted from the foundation, and to reduce the size and number of improvements to be constructed in the ground because it has a reinforcing part that prevents it from being buried. It is possible to provide a ground reinforcement method using this.

The present invention has been described with reference to an embodiment shown in the drawings, but this is only exemplary, and various modifications and other equivalent embodiments are possible from those of ordinary skill in the field to which the technology belongs. Will understand.

In addition, the distributed load calculation method and the ground reinforcement method using the same have been described as an example, but this is only an example, and the calculation method of the present invention and the method using the same are used for other products other than the distributed load calculation method and the ground reinforcement method using the same. I can.

Therefore, the true technical protection scope of the present invention should be determined by the following claims.

10: reinforcement part 12: blocking member
14: tension member 16: reinforcing member
30: load distribution unit 32: geocell member
34: filling material 50: connection fixing unit
52: column member 54: fitting groove
70: cap member 72: restraint portion
74: locking hook 76: adjustable step

Claims (5)

A foundation constructed on soft ground; A load distribution unit supporting the foundation and distributing and transmitting a load transmitted from the foundation; And a reinforcing part supporting the load distributing part, preventing the load distributing part from being deformed or damaged by providing a tensile force in a lateral direction, and preventing the filler from being lost from the load distributing part, wherein the load distributing part comprises: A geocell member seated on the reinforcing portion and formed in a honeycomb shape; A filling material filled in the storage space provided by the geocell member; And a connection fixing unit fixed to the ground by connecting the geocell members adjacent to each other when the plurality of geocell members are continuously seated, wherein the reinforcing unit includes the filling material accommodated in the geocell member toward the ground. A blocking member disposed in close contact with the geocell member to prevent loss, and blocking moisture flowing into the reinforcing part; A tension member supporting the blocking member to prevent the blocking member from being damaged, and providing a lateral tensile force supporting the blocking member and the load distribution unit; And a reinforcing member interposed between the tension member and the ground, the tension member, the blocking member, and a reinforcing member for increasing the stiffness of the reinforcing earth body to prevent sagging toward the ground,
The load distribution effect (ΔP ₂ ) generated by the load distribution unit is,

Is calculated by,
Wherein p is the bed load applied to the base, B is the width and length of the base, the H _cell is the thickness of the load distribution unit, and β is the distribution angle of the bed load,
The tensile force (ΔP ₃ ) generated by the tension member is,

Is calculated by,
B is the width and length of the foundation, T is the design tensile strength of the tension member, α is the horizontal angle of the tensile force,
_{Because the load (ΔP = ΔP 2} +ΔP ₃ ) that is not transmitted to the ground and is reduced by the sum of the load distribution effect (ΔP ₂ ) of the load distribution unit and the tensile force (ΔP ₃ ) generated by the tension member can be calculated. It is possible to prevent the size of the foundation from being constructed more than necessary according to the reduced load,
Distributed load calculation method, characterized in that it is possible to accurately calculate the size and number of the improved body installed on the ground, thereby reducing the size or number of the improved body.
delete delete delete (a) arranging the foundation surface on the ground to be constructed, and constructing a reinforcement part; (b) seating a geocell member of the load distribution unit on the reinforcement unit, and connecting a plurality of geocell members to the ground and fixing the geocell member; (c) installing and inserting a filler material into the storage space of the geocell member; And (d) providing vibration to the geocell member and the filling material to perform compaction fixing, wherein the load distribution unit includes the geocell member seated on the reinforcing unit and formed in a honeycomb shape; The filling material filled in the storage space provided by the geocell member; And a connection fixing unit fixed to the ground by connecting the geocell members adjacent to each other when the plurality of geocell members are continuously seated, wherein the reinforcing unit includes the filling material accommodated in the geocell member toward the ground. A blocking member disposed in close contact with the geocell member to prevent loss, and blocking moisture flowing into the reinforcing part; A tension member supporting the blocking member to prevent the blocking member from being damaged, and providing a lateral tensile force supporting the blocking member and the load distribution unit; And a reinforcing member interposed between the tension member and the ground, the tension member, the blocking member, and a reinforcing member that increases the stiffness of the reinforcing soil body to prevent sagging toward the ground. In,
The load distribution effect (ΔP ₂ ) generated by the load distribution unit is,

Is calculated by,
Wherein p is the bed load applied to the base, B is the width and length of the base, the H _cell is the thickness of the load distribution unit, and β is the distribution angle of the bed load,
The tensile force (ΔP ₃ ) generated by the tension member is,

Is calculated by,
B is the width and length of the foundation, T is the design tensile strength of the tension member, α is the horizontal angle of the tensile force,
_{Because the load (ΔP = ΔP 2} +ΔP ₃ ) that is not transmitted to the ground and is reduced by the sum of the load distribution effect (ΔP ₂ ) of the load distribution unit and the tensile force (ΔP ₃ ) generated by the tension member can be calculated. It is possible to prevent the size of the foundation from being constructed more than necessary according to the reduced load,
Ground reinforcement method using a distributed load calculation method, characterized in that it is possible to accurately calculate the size and number of the improved body installed on the ground, thereby reducing the size or number of the improved body.

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