KR102410765B1 - Flange reinforced earth barrier facilities - Google Patents

Abstract

The present invention, the insertion grooves are formed on both sides, a plurality of pillar members are installed on the ground while maintaining a constant interval; Earth plate installed in a plurality of stacked portions in the insertion groove portion of the pillar member disposed adjacent to each other to prevent the surrounding soil from pouring into a space formed by excavation work; a reinforcement part installed to surround a flange provided on the front or rear surface of the pillar member to prevent the pillar member from being deformed or damaged by earth pressure; and a flow preventing part for pressing the earth plate inserted into the insertion groove part to prevent the earth plate from flowing inside the insertion groove part.

Description

Flange reinforced earth barrier facilities

The present invention relates to a temporary retaining facility that can be reinforced with a flange, and more particularly, by selecting a column member in a region where a load can be concentrated among the temporary retaining facilities to partially reinforce the strength, the column member made of an H-beam It relates to a temporary retaining facility with flange reinforcement that can prevent the earth plate inserted into the insertion groove from flowing inside the insertion groove and can provide a filling space in which the filler material can be filled in the flange of the column member requiring strength reinforcement will be.

In general, when excavating for new construction of various buildings or for reclaiming and replacing water and sewer pipes, retaining work is performed to support the earth pressure of the excavated ground and prevent the outflow of groundwater.

As the above-mentioned retaining method, the earth plate method, the CIP method, the SCW method, and the like are known.

Among them, in the earth plate method, H-beam piles are inserted into the ground at regular intervals, and a plurality of earth plates are stacked between adjacent H-beam piles, and then the ground is excavated.

The earth plate construction method described above has the advantage that the construction method is relatively simple and economical. The conventional earth plate construction method is usually composed of wooden boards, so it has a short service life. There is a problem with groundwater leaking.

Accordingly, there is a disadvantage in that it is difficult to use in the case of deep excavation of the ground or in the case of construction that requires a perfect degree.

In addition, the earth plate construction method described above has problems in that the construction period is delayed because a plurality of earth plates must be inserted and laminated one by one, and it is difficult to stabilize the ground behind the retaining plate, so that the ground may sink or collapse.

In order to solve the above problems, a method of assembling an angle with a bolt to the web of the H-beam pile and inserting an iron plate between the angle and the H-beam flange is also used.

However, the conventional retaining method has the following problems.

First, it is not easy to insert an iron plate into the narrow gap between the angle and the H-beam pile flange, so the working time is delayed.

Second, it is difficult to firmly grip the upper part of the iron plate with the clamping part of the vibrating hammer.

Third, it is difficult to balance the left and right by gripping the upper part of the iron plate with the clamping part of the vibrating hammer.

If the left and right balance is not met during the iron plate insertion operation, the iron plate is inclined to one side, making it difficult to insert the iron plate, and this problem is further aggravated when the width of the iron plate is wide.

In order to solve the above problem, the center line may be marked on the iron plate to make it easier to find the center, but the center line is covered with soil over time, making it difficult to visually confirm.

Fourth, it is difficult to withdraw the iron plate from the ground after the construction is completed.

That is, it takes a lot of time to grab the upper part of the flat iron plate with the hammer clamping part and raise it to the upper part.

On the other hand, the CIP (Cast In Place Pile) method is a method of drilling the ground with an Auger Machine, inserting a rebar or H-beam into the hole, pouring concrete, and then excavating the ground.

The above-described CIP method, since it forms a solid concrete wall, has an advantage in that the water-repellent effect is high and ground subsidence does not occur due to excavation, but there are disadvantages in that expensive equipment is required and the construction cost is increased.

And the SCW (Soil Cement Wall) method is a method similar to the CIP method, in which the cement wall is continuously formed with a 3-axis auger machine.

The SCW method also has disadvantages in that expensive equipment is required and construction costs are high.

In order to solve the above problems, a retaining method using an H-beam pile and a wing-type iron plate was developed, and the retaining method according to the prior art, when excavating the ground for a new building construction or a pipeline reclaiming construction, an H-beam pile and an iron plate In the method of retaining the earth using Inserting the H-beam pile into the ground, and after step S20, holding the jig for holding the wing-type iron plate with the clamping part of the vibrating hammer, and then inserting the wing-type iron plate on the flange of the H-beam pile adjacent to each other; After the construction is completed, the clamping part of the vibrating hammer hangs the horizontal part of the gripping jig to take out the wing-type iron plate from the ground.

The background technology of the present invention is disclosed in Republic of Korea Patent Publication No. 10-2134366 (published on July 15, 2020, title of invention: retaining method using H-beam pile and wing-type iron plate).

In the retaining method according to the prior art, a separate technical configuration for reinforcing the strength of the H-beam pile is not provided, and in particular, there is a separate technical configuration for preventing the earth plate inserted into the groove of the H-beam pile from flowing inside the groove. Because it is not provided, it is not easy to install the earth plates installed in a vertical direction so that they are not spaced apart from each other. There is a problem in that the soil may be lost due to the gap between the earth plates as a plurality of earth plates are spaced apart.

Therefore, there is a need to improve it.

The present invention can partially reinforce the strength by selecting a pillar member in a part where the load can be concentrated among the temporary retaining facilities, and prevents the earth plate inserted into the insertion groove of the pillar member made of H-beam from flowing inside the insertion groove The purpose is to provide a temporary retaining facility capable of flange reinforcement that can provide a filling space that can be filled with a filler in the flange of the column member requiring strength reinforcement.

The present invention, the insertion grooves are formed on both sides, a plurality of pillar members are installed on the ground while maintaining a constant interval; Earth plate installed in a plurality of stacked portions in the insertion groove portion of the pillar member disposed adjacent to each other to prevent the surrounding soil from pouring into a space formed by excavation work; a reinforcing part installed to surround a flange provided on the front or rear surface of the pillar member to prevent the pillar member from being deformed or damaged by earth pressure; and a flow preventing part for pressing the earth plate inserted into the insertion groove part to prevent the earth plate from flowing inside the insertion groove part.

In addition, the reinforcing part of the present invention, a first cover member surrounding one end of the flange of the pillar member; and a second cover member surrounding the other end of the flange of the pillar member and one side of the first cover member.

In addition, the flow prevention part of the present invention comprises a bending member extending from the reinforcement part, extending toward the flange of the pillar member and pressing the earth plate inserted into the insertion groove toward the flange side of the pillar member. do.

In addition, the bending member of the present invention is formed integrally with the reinforcing part, characterized in that it is integrally connected to the pillar member by the coupling part.

In addition, the reinforcing part and the flow preventing part of the present invention are characterized in that they are respectively installed on a pair of flanges provided on the front and rear surfaces of the pillar member.

In addition, the present invention, insertion grooves are formed on both sides, a plurality of pillar members to be installed on the ground while maintaining a constant interval; Earth plate installed in a plurality of stacked portions in the insertion groove portion of the pillar member disposed adjacent to each other to prevent the surrounding soil from pouring into a space formed by excavation work; and a reinforcement part installed to surround a flange provided on the front or rear surface of the pillar member to prevent the pillar member from being deformed or damaged by earth pressure, wherein the reinforcement part is installed on the flange of the pillar member, a accommodating part providing a accommodating space extending along the flange; And it characterized in that it comprises a filling material to be filled in the accommodating part.

The temporary retaining facility capable of reinforcing a flange according to the present invention is installed to surround the flange of the column member and provided with a reinforcing part for reinforcing the strength of the column member, so that the column member can be prevented from being deformed or damaged by earth pressure, and the column member Since the earth plate inserted into the insertion groove of the flow prevention part is provided to prevent the earth plate from flowing, it is possible to prevent the earth plate installed vertically stacked from being spaced apart from each other, thereby preventing the earth and sand from being lost in the gap between the earth plates, and the column member. It has the advantage of improving the support strength of the temporary retaining facility by reinforcing the strength of the earth plate and preventing the flow of the earth plate.

1 is a perspective view showing a temporary retaining system capable of flange reinforcement according to a first embodiment of the present invention.
2 is a cross-sectional view showing a temporary retaining facility capable of flange reinforcement according to the first embodiment of the present invention.
Figure 3 is an exploded cross-sectional view showing a temporary retaining facility capable of flange reinforcement according to the first embodiment of the present invention.
4 is a cross-sectional view showing a temporary retaining system capable of flange reinforcement according to a second embodiment of the present invention.
5 is a cross-sectional view showing a temporary retaining facility capable of flange reinforcement according to a third embodiment of the present invention.
6 is a perspective view showing a temporary retaining facility capable of flange reinforcement according to a third embodiment of the present invention.

Hereinafter, an embodiment of a temporary retaining facility capable of flange reinforcement 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 the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

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

Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is a perspective view showing a retaining temporary facility capable of flange reinforcement according to a first embodiment of the present invention; is an exploded cross-sectional view showing a temporary retaining facility capable of flange reinforcement according to the first embodiment of the present invention.

1 to 3, in the temporary retaining facility capable of flange reinforcement according to an embodiment of the present invention, insertion grooves 12 are formed on both sides of the pillar member ( 10) and the earth plate 14 which is installed to be stacked in plurality in the insertion groove portion 12 of the column member 10 disposed adjacent to each other and prevents the surrounding soil from pouring into the space where the excavation construction is made, and; The reinforcement part 30 installed to surround the flange provided on the front or rear surface of the pillar member 10 to prevent the pillar member 10 from being deformed or damaged by earth pressure, and the earth plate inserted into the insertion groove portion 12 . It includes a flow preventing part 50 for preventing the earth plate 14 from flowing inside the insertion groove part 12 by pressing (14).

Therefore, a plurality of column members 10 are constructed on the ground, and a plurality of earth plates 14 are inserted in the gap between the column members 10, and any one column member 10 on which earth pressure is concentrated when constructing a temporary retaining facility. Alternatively, the reinforcement part 30 and the flow prevention part 50 are installed in all of the plurality of pillar members 10 to improve the flange support strength of the pillar member 10, and the insertion groove portion 12 of the pillar member 10 ) to prevent the earth plate 14 being inserted into the flow, it is possible to improve the support strength of the temporary retaining facility.

The reinforcing part 30 of this embodiment includes a first cover member 32 surrounding one end of the flange of the column member 10 , the other end of the flange of the column member 10 and a first cover member surrounding one side of the first cover member 32 . Since the second cover member 34 is included, a panel having a cross-sectional shape bent in a 'c' shape can be inserted into one end of the flange to prevent deformation or damage of one end of the flange, and a 'c' at the other end of the flange The second cover member 34 bent in a shape is inserted and installed so as to surround the other end of the flange and the front surface of the first cover member 32 .

Therefore, it can be seen that the flange of the pillar member 10 is double-wrapped by the first cover member 32 and the second cover member 34, so that the flange support strength of the pillar member 10 is remarkably improved.

In addition, the first cover member 32 and the second cover member 34 are bent in a 'C' shape so that the inner end is inserted into the insertion groove portion 12 of the column member 10, and the insertion groove portion 12 inside The flow prevention part 50 is connected to the ends of the first cover member 32 and the second cover member 34 inserted into the .

As described above, since the flange of the pillar member 10 is surrounded by the first cover member 32 and the second cover member 34 on the front, back and side surfaces, the flange of the pillar member 10 is caused by earth pressure. It is possible to effectively prevent deformation.

The flow prevention part 50 of this embodiment extends from the reinforcing part 30 and extends toward the flange of the column member 10 and inserts the earth plate 14 inserted into the insertion groove part 12 into the flange of the column member 10 . It includes a bending member 52 for pressing to the side.

Accordingly, the bending member 52 extending from the inner end of the first cover member 32 and the second cover member 34 inserted into the insertion groove 12 is bent in a 'C' shape to form the first cover member 32 . ) and the flexural member 52 extending from the second cover member 34 forms a 'L' shape.

Therefore, when the first cover member 32 and the second cover member 34 are inserted into both ends of the flange of the column member 10, the flange is surrounded by the first cover member 32 and the second cover member 34, and , a pair of bending members 52 disposed inside the insertion groove 12 form a structure in which the earth plate 14 is pressed against the flange on the opposite side of the column member 10 .

Since the bending member 52 of this embodiment is integrally formed with the reinforcing part 30, and is integrally connected to the column member 10 by the coupling part 70, the reinforcing part 30 and the bending part are manufactured separately. Thus, the bonding process can be omitted, and the column member ( 10), the pair of bending members 52 can be disposed in the insertion groove 12 while enclosing the flange of the column member 10 by fitting them to both ends of the flange.

As described above, the first cover member 32 and the second cover member 34 fitted to both ends of the flange are integrally coupled to the column member 10 by the coupling part 70, the coupling part ( 70, the through-hole portion 72 formed in the bending member 52, the coupling hole portion 74 formed in the column member 10 to face the through-hole portion 72, the through-hole portion 72 and the coupling hole portion It is fastened to the 74 and includes a fastening member 76 for integrally coupling the first cover member 32 , the second cover member 34 and the bending member 52 to the column member 10 .

Therefore, after inserting the first cover member 32 and the bending member 52 and the second cover member 34 and the bending member 52 to both ends of the flange of the column member 10, the fastening member 76 is inserted into the through hole portion ( 72) and the fastening member 76, when combined with the nut member, the first cover member 32, the second cover member 34, and the bending member 52 can be integrally coupled to the column member 10. do.

Thereafter, the earth plate 14 is inserted into the gap between the end of the bending member 52 and the other flange of the pillar member 10 to complete the construction of the temporary retaining facility, and a plurality of earth plates 14 are stacked while the pillar After being inserted into the insertion groove 12 of the member 10 , the first cover member 32 , the second cover member 34 , and the bending member 52 may be coupled to the column member 10 .

4 is a cross-sectional view showing a temporary retaining facility capable of flange reinforcement according to a second embodiment of the present invention.

Referring to FIG. 4 , the reinforcement part 30 and the flow prevention part 50 of the temporary retaining facility capable of flange reinforcement according to the second embodiment of the present invention are a pair of provided on the front and back surfaces of the column member 10 . There is a feature to be installed on each flange.

In this embodiment, since the first cover member 32 , the second cover member 34 and the bending member 52 are respectively installed on a pair of flanges provided on the pillar member 10 , the pillar member 10 is It is characterized in that both of the provided pair of flanges can be reinforced.

Therefore, the bending member 52 installed on the flange provided on the front side of the pillar member 10 and the bending member 52 installed on the flange provided on the rear surface of the pillar member 10 are in close contact with each other in the insertion groove portion 12 . The earth plate 14 which is arranged to be disposed and fitted into the insertion groove portion 12 is inserted and supported in the gap between the first cover member 32 or the second cover member 34 and the bending member 52 .

As described above, in this embodiment, the first cover member 32 , the second cover member 34 and the bending member 52 are all installed on each of a pair of flanges provided on the pillar member 10 , so the pillar member It becomes possible to improve the support strength of (10) more effectively.

5 is a cross-sectional view showing a temporary retaining facility capable of flange reinforcement according to a third embodiment of the present invention.

5 and 6, in the temporary retaining facility capable of flange reinforcement according to the third embodiment of the present invention, insertion grooves 12 are formed on both sides, and a plurality of pillar members are maintained at regular intervals and constructed on the ground. (10) and the earth plate 14 which is installed to be stacked in a plurality of insertion grooves 12 of the column member 10 disposed adjacent to each other and prevents the surrounding earth and soil from pouring into the space where the excavation construction is made, and , It is installed to surround the flange provided on the front or rear surface of the pillar member 10, and includes a reinforcement portion 130 to prevent the pillar member 10 from being deformed or damaged by earth pressure.

In addition, the reinforcing part 130 of this embodiment is installed on the flange of the column member 10, and a receiving part 132 that provides a receiving space extending along the flange, and a filling material filled in the receiving part 132 ( 134).

In this embodiment, both ends of the receiving part 132 bent in a 'C' shape are welded to both ends of the flange to provide a storage space on the outer wall of the flange of the column member 10, which is required to be reinforced. is done

Therefore, a long storage space is formed in the vertical direction between the receiving part 132 and the flange, and when the filling material 134 is filled in the receiving space, the thickness of the flange is reinforced as thick as the thickness of the filling material 134 and the receiving part 132. effect can be provided.

In addition, in the present embodiment, a reinforcing rib 136 for reinforcing the outer wall of the receiving unit 132 is installed, and the reinforcing rib 136 of this embodiment is bent in a 'L' shape so that one end of the receiving unit 132 is bent. The first rib 137 is integrally welded to the center of the outer wall elongated in the vertical direction, and one end is bent in a 'L' shape and one end is integrally welded to the center of the outer wall of the accommodating part 132 in the vertical direction, so that the first rib ( 137) and a second rib 138 disposed in close contact.

Accordingly, a 'V'-shaped rib is formed in the center of the outer wall of the accommodating part 132 to be long in the vertical direction, thereby providing an effect of reinforcing the strength of the accommodating part 132 .

In this way, the strength can be partially reinforced by selecting the pillar member in the part where the load can be concentrated among the temporary retaining facilities, and the earth plate inserted into the insertion groove of the pillar member made of the H-beam can be prevented from flowing inside the insertion groove. It is possible to provide a temporary retaining facility capable of reinforcing a flange that can provide a filling space in which a filler can be filled in the flange of the column member requiring strength reinforcement.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and various modifications and equivalent other embodiments are possible by those skilled in the art to which the art pertains. will understand

In addition, although a temporary retaining facility capable of flange reinforcement has been described as an example, this is only an example, and the temporary retaining facility of the present invention may be used for products other than the flange reinforced temporary retaining facility.

Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

10: column member 12: insertion groove portion
14: earth plate 30, 130: reinforcement part
32: first cover member 34: second cover member
50: flow prevention part 52: bending member
70: coupling part 72: through hole part
74: coupling hole 76: fastening member
132: accommodating part 134: filling material
136: reinforcing rib 137: first rib
138: second rib

Claims (6)

Insertion grooves are formed on both sides, a plurality of pillar members are maintained at regular intervals and constructed on the ground; an earth plate installed in a plurality of stacked portions in the insertion groove portion of the pillar member disposed adjacent to each other to prevent the surrounding soil from pouring into a space formed by excavation work; a reinforcing part installed to surround a flange provided on the front or rear surface of the pillar member to prevent the pillar member from being deformed or damaged by earth pressure; and a flow preventing part for preventing the earth plate from flowing inside the insertion groove by pressing the earth plate inserted into the insertion groove, wherein the flange reinforcement is possible.
The reinforcement part,
a first cover member surrounding one end of the flange of the pillar member; and
and a second cover member surrounding the other end of the flange of the pillar member and one side of the first cover member,
and a bending member extending from the reinforcing part and extending toward the flange of the pillar member to press the earth plate inserted into the insertion groove toward the flange of the pillar member,
The bending member 52 extending from the inner end of the first cover member 32 and the second cover member 34 inserted into the insertion groove 12 is bent in a 'C' shape to form the first The cover member 32 and the bending member 52 extending from the second cover member 34 is a flange-reinforced temporary retaining device, characterized in that it forms a 'L' shape.
delete delete According to claim 1,
The bending member is formed integrally with the reinforcing part, and flange reinforcement is possible, characterized in that it is integrally connected to the column member by a coupling part.
According to claim 1,
The reinforcing part and the flow preventing part are temporary retaining facilities capable of reinforcing flanges, characterized in that they are respectively installed on a pair of flanges provided on the front and back surfaces of the pillar member.
delete

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