KR102043888B1 - retaining structure support method using tied-arch structure - Google Patents

Abstract

The present invention relates to a soil structure supporting method using a tide arch structure, and more particularly, to support the earth wall wall using a tide arch structure without using a support of earth pressure generated in the soil wall due to the ground excavation The present invention relates to an earthquake structure supporting method using a tide arch structure to efficiently support earth pressure acting on the structure, to increase the stability of the structure, and to secure a wide excavation space.
In addition, the arch structure member that receives the earth pressure acting on the excavating wall through the load transfer member and one or more tie members coupled to the arch structure member, the tie arch structure combined with the tie member and the arch structure member The horizontal load generated by the arch structure member is supported through the tensile resistance of the tie member, and the vertical load generated by the arch structure member is configured to be supported by another adjacent tide arch structure, and thus the tensile force generated by the adjacent tie member. It can also be reduced.

Description

Retaining structure support method using tied-arch structure}

The present invention relates to a support structure for earthquake structures using a tide arch structure, and more particularly, to support a earthquake wall using a tide arch structure without supporting the earth pressure generated in the earth wall due to the ground excavation. The present invention relates to an earthquake structure supporting method using a tide arch structure to efficiently support earth pressure acting on the structure, to increase the stability of the structure, and to secure a wide excavation space.

As shown in Fig. 1, the earth pressure acting on the conventional excavating wall has been generally used by a support or anchor, but the support method is various depending on work space limitation and installation problems at an inclined excavation site. There are difficulties, and the anchor support method helps to secure the working space, but the anchor is perforated to the back of the excavating wall to disturb the lower part of the adjacent facilities, causing settlement, etc. It raises many complaints.

In order to solve this problem, a prestressed method using steel wire (Korean Utility Model Registration 20-322945 (IPS method)) was developed as shown in FIG. 2. However, this method requires a brace or a similar support member at the corner portion for tensioning and fixing the tension member of the steel wire, which has a problem of limiting the construction space of the corner portion as well as the installation of the additional fixing support member. In addition, bending of the tension member of the steel wire in the triangular pedestal of the corner portion is settled by this, there is a structural problem that the tension angle of the tension member is limited, there is a limit in the size of the pre-stress to be introduced, which reduces the applicability to various sites. In addition, a method for resisting earth pressure generated by using the arc member as shown in FIG. 3 has been developed (Korea Patent No. 10-0998253). However, such a method is to excavate a wall by supporting the earth pressure delivered to the arc member through the excavation wall. The concentrated load acts not only to cause structural stability problems but also to cause unexpected buckling of arc-shaped members. In addition, due to earth pressure, a tensile force is generated on the lower surface of the arc member, and in order to minimize the influence of the tensile force, the member of the arc cross section must be increased, thereby increasing the size of the support member, which causes various problems in terms of constructability.

Korean Registered Patent No. 10-0998253 "Furniture Structure for Mud Block"

An object of the present invention is to solve the problems as described above, to solve the structural and construction problems of the conventional construction method of various earthquake structures to increase the structural stability of the earthquake structure and the efficiency of load transfer efficiency and excavation space It is to provide a support structure for the earth block structure using the tide arch structure to secure a wider to facilitate the excavation work.

It is another object of the present invention to provide a support method for retaining structures using a tide arch structure for simply installing a retaining structure for supporting an excavating wall.

Soil structure support method using the tide arch structure according to the present invention to achieve the above object is one or a plurality of tie coupled to the arch structure member and the arch structure member receives the earth pressure acting on the excavating wall through the load transfer member And a horizontal load generated on the arch structure member through the tie arch structure in which the tie member and the arch structure member are coupled to each other through the tensile resistance of the tie member. It is characterized in that it is possible to reduce the tensile force generated in the adjacent tie member through this configuration to support in other tide arch structure.

In addition, the arch structure member receiving the earth pressure acting on the excavating wall through the load transfer member and the coupling member disposed at both ends of the arch structure member and each coupling member or arch structure member disposed at both ends of the arch structure member. It includes one or a plurality of tie member to be coupled, the horizontal load generated on the arch structure member through the tie arch structure combined with the tie member and the arch structure member is supported through the tensile resistance of the tie member, the arch structure member The vertical load generated in the structure may be configured to support the adjacent tie arch structure while reducing the tensile force generated in the adjacent tie member.

In addition, it is installed in the excavating wall transversely, and includes a band length formed on both ends and the arch structure member receiving the earth pressure applied to the band through the load transfer member and one or a plurality of tie members coupled to the arch structure member. The horizontal load generated on the arch structure member through the tie arch structure in which the tie member and the arch structure member are coupled is supported by the tensile resistance of the tie member, and the vertical load generated on the arch structure member While being configured to support at the stepped portion it is characterized in that it can also reduce the tensile force generated in the adjacent tie member.

In addition, the material for forming the load transfer member and the arch structure member of the tide arch structure may be composed of steel, steel wire, steel bar, steel, high-strength plastic, synthetic material, hybrid material, etc. The cross-sectional shape is circular, H-beam type, square, etc. The material forming the tie member of the tide arch structure may be composed of steel, steel wire, steel bar, steel, high-strength plastic, synthetic material, hybrid material, etc. The cross-sectional shape is circular, H-beam, rectangular It is characterized by consisting of any one.

In addition, it characterized in that it further comprises a coupling member for fixing each end of the arch structure member of the tide arch structure.

The coupling member may include a first coupling member integrally formed at one side of the arch structure member and a second coupling member having a shape corresponding to the first coupling member, which is integrally formed at the other side of the arch structure member. The first coupling member is coupled to the second coupling member of another adjacent arch structure member.

The first coupling member may include a plurality of protruding coupling protrusions, and the second coupling member may include a plurality of coupling holes in which the plurality of coupling protrusions are accommodated.

In addition, the first coupling member and the second coupling member is characterized in that composed of a combination of a plurality of protruding coupling projections and a plurality of coupling holes.

In addition, a plurality of fixing holes are formed in the first coupling member and the second coupling member, and bolts and nuts or fixing pins are inserted into the fixing holes to couple the first coupling member and the second coupling member to each other. Characterized in that it further comprises a fixing member.

In addition, the coupling member is formed of a first coupling member detachably formed on one side of the arch structure member and a second coupling member of a shape corresponding to the first coupling member, which is detachably formed on the other side of the arch structure member. The first coupling member is coupled to the second coupling member of another adjacent arch structure member.

The first coupling member may include a plurality of protruding coupling protrusions, and the second coupling member may include a plurality of coupling holes in which the plurality of coupling protrusions are accommodated.

In addition, the first coupling member and the second coupling member is characterized in that composed of a combination of a plurality of protruding coupling projections and a plurality of coupling holes.

In addition, a plurality of fixing holes are formed in the first coupling member and the second coupling member, and bolts and nuts or fixing pins are inserted into the fixing holes to couple the first coupling member and the second coupling member to each other. Characterized in that it further comprises a fixing member.

In addition, the arch structure member is pre-manufactured and installed after being divided into a plurality, characterized in that the welding, a plurality of brackets and bolts and nuts or through a fixing member such as fixing pins are integrally coupled.

In addition, it characterized in that it further comprises a tie load transmitting member for transferring a portion of the load transmitted to the arch structure member between the arch structure member and the tie member to the tie member.

In addition, the difference between the horizontal load transmitted from the arch structure member and the vertical load transmitted from the adjacent arch structure member between both ends of the arch structure member and the edge of the excavating wall to which the other arch structure member is coupled to the arch structure member. It characterized in that it further comprises an edge load transfer member for generating an additional resistance to the earth pressure of the excavating wall to transmit the load that can be generated by the edge of the excavating wall.

In addition, due to the difference between the horizontal load transmitted from the arch structure member and the vertical load transmitted from the other arch structure member between the coupling member and the edge of the excavating wall to which the other arch structure member is coupled to the arch structure member. It is characterized in that it further comprises an edge load transfer member for generating an additional resistance to earth pressure of the excavating wall to transmit the load to the edge of the excavating wall.

In addition, the arch structure member is divided into two structures on one side and the other side, characterized in that the divided arch structure member is configured to be hinged.

In addition, a coupling fixed shaft is formed in the first coupling member, and a coupling fixing hole formed in the first coupling member of another adjacent arch structure member is inserted into the second coupling member, and a coupling fixing hole is formed to rotate. Characterized in that configured to be combined.

In addition, any one or more of the arch structure members, depending on the shape or width of the excavation space, a plurality of arch structure members are installed in a row in succession along the excavating wall, the fastening between the successive arch structures in a row is directly fastened Or the fastening is made through a row coupling member, the fastened portion between the arch structure member installed in a line is characterized in that supported by a plurality of support members.

As described above, according to the earthquake structure support method using the tide arch structure according to the present invention, by effectively supporting the earth pressure acting on the earthquake structure to increase the stability of the structure and secure a wide excavation space to increase the workability There is.

In addition, according to the support method of the earthquake structure using the tide arch structure according to the present invention, there is an effect that can easily install the earthquake structure for supporting the excavating wall.

1 is a view showing a conventional support method.
Figure 2 is a view showing a prestressed method using a conventional steel wire.
3 is a view showing a method for resisting the earth pressure generated by using a conventional arc-shaped member.
Figure 4 is a plan view showing a soil structure supporting method using a tide arch structure according to the present invention.
Figure 5 is a view showing another embodiment of the soil structure supporting method using the tide arch structure according to the present invention.
Figure 6 is a view showing a first embodiment of a soil structure supporting method using a tide arch structure according to the present invention.
Figure 7 is a view showing a second embodiment of the soil structure supporting method using the tide arch structure according to the present invention.
8 is a view showing a third embodiment of the soil structure supporting method using the tide arch structure according to the present invention.
Figure 9 is a view showing a fourth embodiment of the soil structure supporting method using the tide arch structure according to the present invention.
10 is a view showing a fifth embodiment of the soil structure supporting method using the tide arch structure according to the present invention.
11 is a view showing a sixth embodiment and a seventh embodiment of a soil structure supporting method using a tide arch structure according to the present invention.
12 is a view showing an eighth embodiment of a soil structure supporting method using a tide arch structure according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

Figure 4 is a plan view showing a support structure of the earth block structure using the tide arch structure according to the present invention, Figure 5 is a view showing another embodiment of the support structure of the earth block structure using a tide arch structure according to the present invention, Figure 6 FIG. 7 is a view showing a first embodiment of the soil structure supporting method using a tide arch structure according to the present invention, Figure 7 is a view showing a second embodiment of the soil structure supporting method using a tide arch structure according to the present invention 8 is a view showing a third embodiment of the soil structure supporting method using a tide arch structure according to the present invention, Figure 9 is a fourth embodiment of the soil structure supporting method using a tide arch structure according to the present invention 10 is a view showing a fifth embodiment of the soil structure supporting method using the tide arch structure according to the present invention, Figure 11 Figure 6 shows a sixth embodiment and a seventh embodiment of the soil structure supporting method using a tide arch structure according to the invention, Figure 12 is an eighth embodiment of the soil structure supporting method using a tide arch structure according to the present invention Figure is shown.

Figure 4 illustrates the earthquake structure support method using the tide arch structure according to the present invention, the H pile and earth plate, CIP wall, steel sheet pile wall used in the trench construction for the construction of new facilities or structures And resistance to earth pressure F1 acting on the excavation wall 1 such as slurry walls.

According to the present invention, the support structure of the clam structure using the tide arch structure is an arch structure member (3) and the arch structure member for receiving the earth pressure (F1) acting on the excavating wall (1) through a plurality of load transfer member (2) It comprises one or a plurality of tie members (4) coupled to (3).

Since the tide arch structure has a shape that is more spaced apart from the excavating wall 1 toward the corner portion at the center portion, the banding or excavation for efficiently transmitting the earth pressure F1 applied from the excavating wall 1 to the tide arch structure. A plurality of load transfer members 2 are provided between the wall 1 and the arch structure member 3 of the tide arch structure.

In addition, the arch structure member 3 receiving the earth pressure F1 acting on the excavating wall 1 through the load transfer member 2 and the coupling member 6 disposed at both ends of the arch structure member 3. And one or a plurality of tie members 4 coupled to each coupling member 6 or the arch structure members disposed at both ends of the arch structure member 3.

In addition, the earth pressure (F1) transmitted through the load transfer member (2) acts as a load on the tide arch structure and the horizontal load (F2) of both ends of the tide arch structure generated by these loads is the arch structure member (3) Or it is resisted by the tensile force of the tie member 4 provided on the coupling member (6).

At this time, the tie member 4 may be composed of steel, steel wire, steel rod, steel, high-strength plastic, synthetic material, hybrid material, etc., which can resist tensile force, the cross-sectional shape is composed of any one of circular, H-beam type, square, etc. Can be.

The tie member 4 is coupled to the arch structure member 3 or the coupling member 6 by various fastening methods such as bolt and nut, pin, ring, welding, and socket coupling, and prestressing coupling. Thus, the horizontal load F2 generated by the earth pressure transmitted to the arch structure member 3 is configured to resist as the tensile force of the tie member 4.

In other words, the horizontal load F2 generated in the arch structure member 3 through the tie arch structure in which the tie member 4 and the arch structure member 3 are coupled is the tensile resistance F4 of the tie member 4. ), And the vertical load (F3) generated in the arch structure member (3) is configured to support in the other adjacent arch arch structure (3), through which the tensile force generated in the tie member of another adjacent arch structure member Can be reduced.

In more detail, the arch structure member 3 supports the excavating wall 1 or the strip having the earth pressure F1 through a plurality of load transfer members 2, and the horizontal structure acting on the arch structure member 3. The load F2 is made to resist as the tensile force F4 of the tie member 4 provided across the arch structure member 3.

Therefore, according to the soil support structure supporting method using the tide arch structure according to the present invention, only the support for the vertical load (F3) generated in the arch structure member 3 has the advantage of increasing the efficiency of the load supporting structure. .

In particular, the vertical load (F3) has the effect of canceling each other or greatly reduced by acting in the opposite direction to the horizontal load (F2`) generated through the other adjacent arch structure member (3) This makes it possible to form the structure very simply without the use of complicated additional members.

In addition, the earth pressure (F1) acting on the excavating wall (1) is supported by a vertical wall, such as H pile and earth plate wall pre-installed by performing excavation work, but the earth pressure (F1) acts non-uniformly depending on the position There is a possibility that the excavation wall 1 at the position is damaged.

As a result, the tide arch structure efficiently distributes the excavating wall 1 while distributing the load so that the earth pressure is not concentrated on the excavating wall 1 at a specific position through the band 5 installed horizontally in the excavating wall 1. It can also be configured to support.

In addition, the load transfer member 2 is disposed between the banding 5 and the tide arch structure which are laterally installed on the drilling wall 1 or the drilling wall 1, and the tide is formed with the drilling wall 1 or the belting 5. Each material coupled to the arch structure and forming the load transfer member 2 and the arch arch member 3 of the tide arch structure may be made of steel, steel wire, steel bar, steel, high-strength plastic, synthetic materials, hybrid materials, and the like. The cross-sectional shape may be formed of any one of a circular shape, an H beam shape, and a quadrangle.

The coupling between the load transfer member 2 and the excavating wall 1 or the strip 5 and the coupling between the load transfer member 2 and the arch structure member 3 are bolts and nuts, pins, rings, welding, socket type coupling, and the like. Various fastening methods are available, and other auxiliary members may be used to assist in fastening.

In addition, the material for the tie member 4 of the tide arch structure may be made of any one of steel, steel wire, steel bar, steel, high-strength plastic, synthetic material, hybrid material and the shape is any one of circular, H-beam, square Can be configured.

As described above, the vertical load (F3) transmitted to the tide arch structure by the earth pressure (F1) is configured to be transferred to the other tide arch structure adjacent to each other to efficiently support the load while the horizontal load (F2) of the tide arch structure and the The tensile force F4 generated on the corresponding tie member 4 produces an effect that can be reduced through the vertical load F3 'transmitted to the other tie arch structure.

At this time, the adjacent arch arch structure is a plurality of coupling members (6) at the end of each arch structure member 3 in order to transfer the vertical load (F3) generated in each of the arch arch structure to the other adjacent arch arch structure stably and efficiently ) May be further included.

The coupling member 6 is configured to couple the ends of each adjacent arch structure member 3 to each other.

The coupling member 6 may have any shape in which the coupling can be efficiently performed according to the cross-sectional shape of the arch structure member 3 of the tie arch structure, and the coupling member 6 and the tie arch structure 3 may be formed. Bolts and nuts, pins, rings, welding, may be combined by any one of the socket method, or may be integrally configured.

In addition, the coupling member 6 may be configured in the form of one body with the arch structure member 3, or may be configured in a form that can be separated from the arch structure member 3 (see FIG. 8), the arch structure member ( The combination with the arch structure member (3) in the form that can be separated from 3) can be used in various coupling methods such as bolts and nuts, pins, rings, welding, socket method.

5 is a view showing another embodiment of the soil structure supporting method using the tide arch structure according to the present invention, the specific position of the through the strip (5) installed horizontally on the excavating wall (1) subjected to earth pressure (F1) The arch arch member 3 of the tide arch structure is installed between the belt strip 5 and the arch structure member 3 so as to efficiently support the excavation wall 1 while distributing the load so that the earth pressure is not concentrated on the excavation wall 1. A reinforcing member 2a may be further provided between the load transfer member 2 and the load transfer member 2.

Depending on the site conditions, the belt 5 may not be installed, and the load transfer member 2 is directly installed between the excavating wall 1 and the arch structure member 3.

The load transfer member 2 and the reinforcing member 2a may be configured in any one of the "Y" type, "I" type, "X" type, or zigzag shape or in a combined form.

In addition, a tie load transmission member 2b is provided between the tie member 4 and the arch structure member 3 to be supported on the arch structure member 3 or the coupling member 6 to support it as a tensile force. A portion of the load transmitted to the member 3 may be configured to be transmitted to the tie member 4, and the tie load transfer member 2b installed between the tie member 4 and the arch structure member 3 is “Y”. It can be composed of any one of the form of "", "I", "X", zigzag or combined form.

In addition, an edge load transfer member 2c is formed between both ends of the arch structure member 3 to which the arch structure member 3 and another arch structure member are coupled, or between the coupling member 6 and the edge of the excavating wall. It may be configured to include more.

The edge load transfer member 2c is a corner of the excavating wall 1 that is caused by the difference between the horizontal load transmitted from the arch structure member 3 and the vertical load transmitted from another adjacent arch structure member 3. It is to be transmitted to the negative to generate an additional resistance to the earth pressure (F1) of the excavating wall (1).

FIG. 6 illustrates a first embodiment of various embodiments of the coupling member 6, wherein the coupling member is formed on one side of the arch structure member 3a and the second coupling member 11 is formed on one side of the coupling member 6. It may be configured as a coupling member 12, the second coupling member 12 is configured in a form corresponding to the first coupling member 11 to be coupled to the first coupling member 11, A plurality of arch structure members 3a and 3b may be connected to each other in such a manner that the first coupling member 11 is coupled to the second coupling member 12 of another adjacent arch structure member 3b.

That is, the first coupling member 11 and the second coupling member 12 are configured to correspond to each other.

In addition, the first coupling member 11 further includes a plurality of protruding coupling protrusions 13, and the second coupling member 12 includes a plurality of coupling holes in which the plurality of coupling protrusions 13 are accommodated. 14 or the first coupling member 11 and the second coupling member 12 may be configured by a combination of a plurality of coupling protrusions 13 and a plurality of coupling holes 14 protruding from each other. .

In addition, as shown in (6-II) of FIG. 6, a plurality of engaging projections disposed on the second coupling member 12 formed on the other side of the other arch fixing member 3b is one side of the arch fixing member 3a. It is formed to penetrate through the coupling hole of the first coupling member 11 formed in the, and may be configured to be fixed to the penetrating coupling projection 13 by a plurality of fixing members 21, such as welding, nuts or pins. .

FIG. 7 illustrates a second embodiment of various embodiments of the coupling member 6, and a first protrusion forming a step in the first coupling member 11 formed at one side of the arch structure member 3. An end 15 is formed, and the first protruding end 15 is formed on the second coupling member 12 to correspond to the first coupling member 11 so as to be coupled to the first coupling member 11. It may be formed and manufactured in the form of mutual coupling.

In addition, it may further include a second protruding end 16 protruding from the first protruding end 15, the arch structure member 3b different from the first coupling member 11 of the arch structure member (3a) If the second coupling member 12 of the form that can be coupled, there is no restriction on the shape of the first protruding end 15 and the second protruding end (16).

In addition, a plurality of fixing holes 20 are formed in the first coupling member 11 and the second coupling member 12, and fixing members such as bolts and nuts or fixing pins inserted into the fixing holes 20 ( 21 may be combined with each other.

FIG. 8 shows a third embodiment of the various embodiments of the coupling member 6, wherein the first coupling member 11 and the second coupling member 12 are disposed at both ends of the arch structure member 3. It may be configured to be detachable from the arch structure member (3).

In addition, when detachably configured, a plurality of insertion ends 31 are disposed at the first coupling member 11 and the second coupling member 12, respectively, and the insertion ends (3) are formed at the arch structure member 3. It is preferable that a plurality of first insertion grooves 32 corresponding to 31 are disposed so that the first coupling member 11 and the second coupling member 12 can be accurately fixed to the arch structure member 3. Do.

In addition, a plurality of coupling holes 33 are respectively formed in the first insertion groove 32 of the arch structure member 3 and the insertion end 31 of the first coupling member 11 and the second coupling member 12. ) Is preferably formed to be coupled to each other through a fixing member 21, such as welding or bolts and nuts or fixing pins.

In addition, the arrangement position and the shape of the first insertion groove 32 and the insertion end 31 may be changed, as long as the configuration is detachable to the arch structure member 3, there is no particular limitation.

In addition, the arch structure member 3 may be preassembled after being manufactured in a plurality of divided states 201, 302, and 303 so as to be easily transported and installed according to the excavation space.

This enables easy installation without restriction of excavation space, the arch structure members 201, 302, 303 divided into a plurality of welding or a plurality of brackets 22 and fixing members such as bolts and nuts or fixing pins It is preferred to join via (21).

In addition, a plurality of fixing holes 20 are formed in the first coupling member 11 and the second coupling member 12, and fixing members such as bolts and nuts or fixing pins inserted into the fixing holes 20 ( 21 may be combined with each other.

That is, the first to third embodiments described above are one of various embodiments of the coupling form of the first coupling member 11 and the second coupling member 12, and its modifications and first to third embodiments. The combined form of the third embodiment is also possible.

Alternatively, as shown in FIG. 8, the tie member 4 may be coupled through the arch structure member 3 in a prestressing manner, and the tie member may be coupled through the arch structure member 3. The number of 4) may be configured in plural in different positions.

Alternatively, as shown in (9-I) of FIG. 9, the tie member 4 penetrates the coupling members (first coupling member and second coupling member) disposed at both ends of the arch structure member 3. May be installed.

In this way, when coupled through the arch structure member 3 or the coupling member (11, 12), each end of the tie member 4 is preferably fastened and fixed through the tie fixing member (4a).

Alternatively, as shown in (9-II) of FIG. 9, as one of the embodiments of the tie load transfer member 2b installed between the tie member 4 and the arch structure member 3 described above, the arch If a part of the load transmitted to the structural member 3 can be configured to be transmitted to the tie member 4, it may be configured in another form.

FIG. 10 illustrates a fifth embodiment of the soil structure supporting method using the tide arch structure according to the present invention, wherein the arch structure member 3 is divided into two structures to one side 3a and the other side 3b. The divided arch structure member 3 may be configured to be hinged.

More specifically, the arch fixing shaft 35c for the hinge configuration is formed at the central end of the divided arch structure member 3a on one side, and at the central end of the divided arch structure member 3b on the other side. Since the arch fixing hole 35d is inserted and the arch fixing shaft 35c is rotatable, the divided arch structure members 3a and 3b may be rotatable about the arch fixing shaft 35c. .

As such, the divided arch structure members 3a and 3b can reduce the moment generated in the arch structure members 3a and 3b and reduce the influence on the stress change due to the temperature change.

In addition, the position where the arch fixing shaft 35c and the arch fixing hole 35d are arranged may vary depending on the arrangement form of the excavating wall or the strip, or the magnitude and direction of the load.

That is, the position where the arch structure member 3 is divided may be changed to a position other than the vertex portion of the arch structure member 3.

In addition, the coupling member (first coupling member and the second coupling member) disposed at both ends of the arch structure member 3 may be configured to be hinged to each other.

For example, the first coupling member 11 disposed at the other end of the arch structure member 3 is provided with a coupling fixed shaft 11a, and the second coupling member 12 disposed at one end of the arch structure member 3. ) May be configured to be hinged to each other by forming a coupling fixing hole (12b) to be inserted and rotatable the coupling fixed shaft of another adjacent arch structure member.

As such, the first coupling member is configured to be hinged to the second coupling member of another adjacent arch structure member, thereby reducing the moment generated in the coupling members 11 and 12 and affecting the stress change due to the temperature change. Can be reduced.

In addition, each of the coupling members 11 and 12 may be configured to be separated from the arch structure member 3 by the fixing member 21 for ease of installation and transport.

11 (I-I) of FIG. 11 shows a sixth embodiment of the soil structure supporting method using the tide arch structure according to the present invention, and according to the shape or the width of the excavation space, among the plurality of arch structure members 3 Any one or more are continuously installed along the excavating wall (1), the coupling member (6) is disposed only at the corner portion in which the arch structure member (3) continuously installed at right angles, the other arch structure member (3) Coupling members may be omitted in the portion 6a in line with each other, and direct fastening may be made between the arch structure members 3.

In addition, a plurality of support members 40 for support are provided between the fastening portions 6a between fastening portions 6a opposite to the fastening portions 6a between the arch structural members 3. It may be arranged.

In other words, any one or more of the arch structure member (3) is a plurality of arch structure member 3 is provided in a row in series along the excavating wall, depending on the shape or size of the excavation space, the arch is provided in a row The fastening between the structural members 3 is a direct fastening, and the fastened portions 6a between the arch structural members 3 installed in a line may be configured to be supported by a plurality of support members 40.

As a result, the horizontal load generated by the arch structure member 3 is shared between each tie member 4 and the other arch structure members 3 coupled to each other in a row, while the vertical loads are adjacent to each other at right angles. As (3) and the support member 40 can be shared with each other, structurally more stable support is possible.

Alternatively, as in the seventh embodiment illustrated in (11-II) of FIG. 11, any one or more of the plurality of arch structure members 3 are continuously installed along the excavating wall 1, and the arch structures are continuously installed. Coupling member 6 is disposed at the corner portion where member 3 abuts at right angle, and other portions of arch structure member 3 in line contact line array member 6b for in-line engagement of arch structure member 3. ) May be arranged.

At this time, the row coupling member (6b) can be used a variety of fastening methods for continuously connecting the arch structure member 3 in a row, there is no limitation on the method and shape.

Furthermore, a plurality of supports for support are provided between the arch structures 3 between fastening portions 6b between the other arch structures members disposed opposite to the portions 6b fastened through the row coupling members 6b. Two bracing members 40 may be arranged.

In other words, any one or more of the arch structure member (3) is a plurality of arch structure member 3 is provided in a row in series along the excavating wall, depending on the shape or size of the excavation space, the arch is provided in a row The fastening between the structural members 3 is made through a row coupling member 6b, and the fastened portion 6b between the arch structural members 3 installed in a row may be configured to be supported by a plurality of support members 40. have.

12 is a view illustrating an eighth embodiment of the soil structure supporting method using the tide arch structure according to the present invention, wherein the strips 5a and 5b having stepped portions are installed at each end of each excavating wall, and adjacent strips 5a and 5b are provided. 5b) is arranged so that the formation positions of the stepped portions are opposite to each other, and end portions of the arched structural members 3a and 3b are disposed at each stepped portion, and the horizontal load is the tie member of each of the arched structural members 3a and 3b. As supported by (4), the vertical load may be constructed such that adjacent bands are supported.

For example, one side arch structure member 3a is configured to support the earth pressure F1 transmitted through one side belt member 5a, and the other end of the arch member 3a of one side is the other side belt member 5b. It is disposed so as to support the stepped portions located at the lower end of both ends of the vertical load applied to the arch structure member (3a) of one side can be configured to share the support of the other side band (5b).

In addition, the earth pressure (F1) transmitted through the other side of the belt (5b) is configured to support the other arch structure member (3b), one end of the other arch structure member (3a) of one side of the length of the belt (5a) It is arranged to support the stepped portions located at both ends of the upper end can be configured to support the vertical load applied to the arch structure member (3b) of the other side by sharing the belt length (5a) of one side.

That is, the bands 5a and 5b arranged to intersect may be configured to share the loads transmitted through not only the respective arch structure members but also other adjacent arch structure members.

Of course, the end portions of the arch members 3a and 3b or the bands 5a and 5b when the belts 5a and 5b share the vertical load applied to the arch members 3a and 3b so as to be supported. It is also obvious that it can be carried out by adding a variety of additional reinforcing members.

In addition, the first to eighth embodiments described above may be implemented as one embodiment, or modifications thereof and a combined form of the first to eighth embodiments may be implemented.

As mentioned above, although this invention was described based on the preferred embodiment with reference to attached drawing, it is clear that those skilled in the art for many various modifications are possible for this, without leaving | separating the range of this invention. Therefore, the scope of the invention should be construed by the claims described to include examples of many such variations.

1: excavating wall
2: load transfer member
2a: reinforcing member
2b: tie load transmitting member
3: arch structure member
4: tie member
5: strip
6: coupling member
11: first coupling member
12: second coupling member
13: engaging protrusion
14: coupling hole
15: first protrusion
16: second protrusion
20: fixing hole
21: fixing member
22: bracket
31: insertion end
32: insertion groove
33: coupling hole
40: bracing member
F1: earth pressure
F2: Horizontal load
F3: Vertical load
F4: Tensile force

Claims (20)

An arch structure member receiving earth pressure acting on the excavating wall through a load transfer member;
Coupling members disposed at both ends of the arch structure member;
It includes one or a plurality of tie members coupled to each coupling member or the arch structure member disposed on both ends of the arch structure member,
The coupling member
A first coupling member integrally formed on one side of the arch structure member;
Is formed integrally with the other side of the arch structure member and consists of a second coupling member of a shape corresponding to the first coupling member,
The horizontal load generated on the arch structure member through the tie arch structure in which the tie member and the arch structure member are coupled to each other is supported through the tensile resistance of the tie member.
The first coupling member is coupled to the second coupling member of another adjacent arch structure member,
It is possible to reduce the tensile force generated in the adjacent tie member by supporting the vertical load generated in the arch structure member in another adjacent tide arch structure
Supporting structure of earth block structure using tide arch structure.
An arch structure member receiving earth pressure acting on the excavating wall through a load transfer member;
Coupling members disposed at both ends of the arch structure member;
It includes one or a plurality of tie members coupled to each coupling member or the arch structure member disposed on both ends of the arch structure member,
The coupling member
A first coupling member detachably formed at one side of the arch structure member;
Is formed detachably on the other side of the arch structure member and consists of a second coupling member of a shape corresponding to the first coupling member,
The horizontal load generated on the arch structure member through the tie arch structure in which the tie member and the arch structure member are coupled to each other is supported through the tensile resistance of the tie member.
The first coupling member is coupled to the second coupling member of another adjacent arch structure member,
It is possible to reduce the tensile force generated in the adjacent tie member by supporting the vertical load generated in the arch structure member in another adjacent tide arch structure
Supporting structure of earth block structure using tide arch structure.
A band long horizontally installed on the excavating wall and having stepped portions at both ends;
An arch structure member for receiving the earth pressure applied to the belt through a load transfer member;
It includes one or a plurality of tie members coupled to the arch structure member,
The band is arranged so that the formation position of the adjacent belt length and the stepped portion is opposite, the end of the arch structure member is disposed on each stepped portion,
The horizontal load generated on the arch structure member through the tie arch structure combined with the tie member and the arch structure member is supported by the tensile resistance of the tie member, and the vertical load generated on the arch structure member is stepped portion of another adjacent band. It is possible to reduce the tensile force generated in adjacent tie members through this structure.
Characterized in that each of the bands arranged to intersect is configured to share the loads transmitted through not only each arch structure member but also other adjacent arch structure members.
Supporting structure of earth block structure using tide arch structure.
The method according to any one of claims 1 to 3,
The material forming the load transfer member and the arch arch member of the tide arch structure can be composed of steel, steel wire, steel bar, steel, high strength plastic, synthetic material, hybrid material, etc. The material forming the tie member of the tide arch structure may be composed of steel, steel wire, steel bar, steel, high-strength plastic, synthetic material, hybrid material, etc. The cross-sectional shape is circular, H-beam type, square Characterized in that any one
Supporting structure of earth block structure using tide arch structure.
delete delete The method of claim 1,
The first coupling member is composed of a plurality of protruding coupling protrusions,
The second coupling member is characterized in that consisting of a plurality of coupling holes in which the plurality of coupling projections are accommodated.
Supporting structure of earth block structure using tide arch structure.
The method of claim 1,
The first coupling member and the second coupling member is characterized in that consisting of a combination of a plurality of protruding coupling projections and a plurality of coupling holes.
Supporting structure of earth block structure using tide arch structure.
The method of claim 1,
A plurality of fixing holes are formed in the first coupling member and the second coupling member,
And a fixing member such as a bolt and a nut or a fixing pin inserted into the fixing hole to couple the first coupling member and the second coupling member to each other.
Supporting structure of earth block structure using tide arch structure.
delete The method of claim 2,
The first coupling member is composed of a plurality of protruding coupling protrusions,
The second coupling member is characterized in that consisting of a plurality of coupling holes in which the plurality of coupling projections are accommodated.
Supporting structure of earth block structure using tide arch structure.
The method of claim 2,
The first coupling member and the second coupling member is characterized in that consisting of a combination of a plurality of protruding coupling projections and a plurality of coupling holes.
Supporting structure of earth block structure using tide arch structure.
The method of claim 2,
A plurality of fixing holes are formed in the first coupling member and the second coupling member,
And a fixing member such as a bolt and a nut or a fixing pin inserted into the fixing hole to couple the first coupling member and the second coupling member to each other.
Supporting structure of earth block structure using tide arch structure.
The method according to any one of claims 1 to 3,
The arch structure member is manufactured after being manufactured in a divided state into a plurality, and is welded or integrally coupled through a plurality of brackets and fixing members such as bolts and nuts or fixing pins.
Supporting structure of earth block structure using tide arch structure.
The method according to any one of claims 1 to 3,
And a tie load transfer member configured to transfer a portion of the load transmitted to the arch structure member between the arch structure member and the tie member to the tie member.
Supporting structure of earth block structure using tide arch structure.
The method of claim 1,
The difference between the horizontal load transmitted from the arch structure member and the vertical load transmitted from the adjacent arch structure member between both ends of the arch structure member and the edge of the excavating wall to which the other arch structure member is coupled to the arch structure member. Characterized in that it further comprises a corner load transfer member for generating an additional resistance to the earth pressure of the excavating wall to transmit the load that can be generated to the edge of the excavating wall
Supporting structure of earth block structure using tide arch structure.
The method of claim 2,
It may be caused by the difference between the horizontal load transmitted from the arch structural member and the vertical load transmitted from the adjacent arch structural member between the coupling member and the edge of the excavating wall to which the arch structural member and the other arch structural member are coupled. Characterized in that it further comprises an edge load transfer member for transmitting the load to the edge of the excavating wall to generate an additional resistance to earth pressure of the excavating wall
Supporting structure of earth block structure using tide arch structure.
The method according to any one of claims 1 to 3,
The arch structure member is divided into two structures on one side and the other side, characterized in that the divided arch structure member is configured to be hinged
Supporting structure of earth block structure using tide arch structure.
The method of claim 1,
The first coupling member is formed with a coupling fixed shaft,
The second coupling member is characterized in that the coupling fixed shaft formed in the first coupling member of another adjacent arch structure member is formed so that the coupling fixing hole is formed so as to be rotatable and hinged mutually.
Supporting structure of earth block structure using tide arch structure.
The method according to any one of claims 1 to 3,
Any one or more of the arch structure members are installed in a row in series along the excavation wall, depending on the shape or width of the excavation space,
The fastening between the arch structure members installed in a row in series is a direct fastening or a fastening through a line coupling member,
The fastened portions between the arch structures installed in a row are supported by a plurality of support members.
Supporting structure of earth block structure using tide arch structure.

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