KR20180064959A - retaining structure support method using tied-arch structure - Google Patents

Abstract

The present invention relates to a method of supporting a retaining structure using a tied-arch structure that can effectively support earth pressure acting on the retaining structure, without using a strut, when a ground is excavated, thereby increasing stability of the structure and securing a wide excavation space. The tied-arch structure includes an arch structure member receiving the earth pressure acting on the wall to be excavated through a load transmitting member, and one or more tie members engaged to the arch structure member. A horizontal load applied to the arch structure member through the tied-arch structure, of which the tie member and the arch structure member are engaged to each other, is supported by tensile resistance of the tie member. A vertical load applied to the arch structure member is supported by other adjacent tied-arch structure, thereby decreasing a tensile force applied to adjacent tie member.

Description

[0001] The present invention relates to a retaining structure supporting structure using a tied arch structure,

More particularly, the present invention relates to a method of supporting a retaining structure using a tied arch structure, and more particularly, to a method of supporting a retaining structure using a tide arch structure without using a strut, The present invention relates to a method of supporting a retaining structure using a tide arch structure for increasing the stability of a structure and securing a wide excavation space to enhance workability.

Conventionally, the earth pressure acting on the excavation wall has been generally supported by a strut or anchor, as shown in FIG. 1. However, the strut support method is not suitable for various work environments The anchor support method is effective for securing the work space, but the anchor is perforated to the back side of the excavation wall, thereby disturbing the lower part of the adjacent facility, causing problems such as settlement, etc. Also, It causes multiple complaints.

In order to solve this problem, a prestress method using a steel wire (Korea Utility Model Registration 20-322945 (IPS method)) was developed as shown in Fig. However, this method requires a strut or similar support member at the corner for tensioning and fixing the tension member of the steel wire, which has a problem of not only the installation of the additional fixing support member but also the installation space of the corner portion. In addition, since the tensions of the steel wire are fixed by bending the tensions of the steel wire at the corners of the corners, there is a structural problem that the tension angle of the tensions is limited. In addition, a method (Korean Patent Registration No. 10-0998253) has been developed to resist the earth pressure generated by using an arc-shaped member as shown in FIG. 3. However, in such a method, the earth pressure transmitted to the arc-shaped member is supported through the excavation wall, There is a problem that not only the structural load may cause a problem in structural stability but also an unexpected buckling of the arc member may occur. In addition, tensile force is generated on the underside of the arc member due to the earth pressure, and in order to minimize the influence of the tensile force, it is necessary to increase the members of the arc section. As a result, the size of the support member increases.

Korean Patent No. 10-0998253 entitled "Protective Structure for Retaining Structure"

It is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to solve the structural and construction problems of various conventional methods of retaining structure to increase the structural stability and load transfer efficiency of the retaining structure, And to provide a method of supporting a retaining structure using a tide arch structure for securing a wide range of excavation operations.

Another object of the present invention is to provide a retaining structure supporting method using a tide arch structure for simply installing an earth retaining structure for supporting an excavation wall.

In order to accomplish the above object, the retaining structure supporting method using the tide arch structure according to the present invention comprises an arch structure member receiving the earth pressure acting on the excavation wall through the load transmission member, and one or a plurality of tie Wherein the horizontal load generated in the arch structure member through the tied arch structure coupled with the tie member and the arch structure member is supported through the tensile resistance of the tie member and the vertical load generated in the arch structure member is transmitted to the adjacent It is possible to reduce the tensile force generated in the adjacent tie members by constituting the tie arch structure in such a manner as to be supported.

Further, it is also possible to provide an arch structure member which receives the earth pressure acting on the excavation wall through the load transmission member, a joining member which is arranged at both side ends of the arch structure member, and a joining member or an arch structure member which are arranged at both ends of the arch structure member Wherein a horizontal load generated in the arch structure member through the tied arch structure in which the tie member and the arch structure member are combined is supported through the tensile resistance of the tie member, The vertical load generated in the tie arch structure is structured to be supported in the adjacent tie arch structure, thereby reducing the tensile force generated in the adjacent tie members.

Also, the present invention includes a wale band provided transversely to the excavation wall, having stepped portions at both ends, an arch structure member received through the load transmitting member and a earth pressure applied by the wale band, and one or more tie members coupled to the arch structure member The horizontal load generated in the arch structure member through the tied arch structure coupled with the tie member and the arch structure member is supported through the tensile resistance of the tie member and the vertical load generated in the arch structure member is transmitted to the adjacent And the tensile force generated on the adjacent tie members can be reduced through the structure.

The material constituting the arch structure member of the load transfer member and the tied arch structure may be composed of a steel material, a steel wire, a steel bar, a steel material, a high strength plastic, a synthetic material and a hybrid material. And the material forming the tie member of the tied arch structure may be composed of a steel material, a steel wire, a steel bar, a steel material, a high strength plastic, a synthetic material, a hybrid material, And the like.

Further, the present invention is further characterized by 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 on one side of the arch structure member and a second coupling member integrally formed on the other side of the arch structure member and corresponding to the first coupling member, And the first engaging member is coupled to the second engaging member of another adjacent arch structure member.

The first engaging member may include a plurality of protrusive engaging projections, and the second engaging member may include a plurality of engaging holes for receiving the plurality of engaging projections.

The first engaging member and the second engaging member may be formed of a combination of a plurality of projecting engaging projections and a plurality of engaging holes.

A plurality of fixing holes may be formed in the first engaging member and the second engaging member, and a bolt, a nut, or a fixing pin inserted into the fixing hole to couple the first engaging member and the second engaging member together And a fixing member of a fixing member.

The coupling member may include a first coupling member detachably formed at one side of the arch structure member and a second coupling member detachably formed at the other side of the arch structure member and corresponding to the first coupling member And the first engaging member is engaged with the second engaging member of another adjacent arch structure member.

The first engaging member may include a plurality of protrusive engaging projections, and the second engaging member may include a plurality of engaging holes for receiving the plurality of engaging projections.

The first engaging member and the second engaging member may be formed of a combination of a plurality of projecting engaging projections and a plurality of engaging holes.

A plurality of fixing holes may be formed in the first engaging member and the second engaging member, and a bolt, a nut, or a fixing pin inserted into the fixing hole to couple the first engaging member and the second engaging member together And a fixing member of a fixing member.

In addition, the arch structure member is installed after being divided into a plurality of parts, and is integrally joined through welding, or a fixing member such as a plurality of brackets, bolts, nuts, or fixing pins.

The tie load transmitting member may further include a tie load transmitting member for transmitting a part of the load transmitted to the arch structure member between the arch structure member and the tie member to the tie member.

The horizontal load transmitted from the arch structure member and the vertical load transmitted from another adjacent arch structure member between the opposite end portions of the arch structure member to which the arch structure member and the adjoining other arch structure member are coupled and the corner portion of the excavation wall, And a corner load transmission member for transmitting a load generated by the load transferring member to an edge portion of the excavation wall to generate an additional resistance against the earth pressure of the excavation wall.

Further, the horizontal load transmitted from the arch structure member and the vertical load transmitted from the adjacent other arch structure member between the coupling member to which the arch structure member and another adjacent arch structure member are coupled and the edge portion of the excavation wall, And an edge load transmission member for transmitting the load to the edge of the excavation wall to generate an additional resistance against the earth pressure of the excavation wall.

The arch structure member is divided into two structures on one side and the other side, and the divided arch structure members are hinged to each other.

Further, the first engaging member is provided with an engaging and fixing shaft, and the second engaging member is provided with an engaging and fixing hole for engaging and rotating the engaging and securing shaft formed on the first engaging member of the adjacent arch structure member, To be combined with each other.

Further, according to the shape or the width of the excavation space, at least one of the arch structure members is provided with a plurality of arcuate structural members arranged in series along the excavation wall, Or the connecting member, and the fastened portion between the arch structure members provided in a row is supported by the plurality of supporting members.

As described above, according to the retaining structure supporting method using the tide arch structure according to the present invention, the earth pressure applied to the retaining structure can be efficiently supported, thereby increasing the stability of the structure and securing a wide excavation space. .

Also, according to the retaining structure supporting method using the tide arch structure according to the present invention, the retaining structure for supporting the excavation wall can be easily installed.

BRIEF DESCRIPTION OF THE DRAWINGS Fig.
2 is a view showing a prestressing method using a conventional steel wire.
3 is a view showing a construction method for resisting the earth pressure generated by using a conventional arc-shaped member.
4 is a plan view showing a retaining structure supporting method using a tide arch structure according to the present invention.
5 is a view showing another embodiment of a retaining structure supporting method using a tide arch structure according to the present invention.
6 is a view showing a first embodiment of a retaining structure supporting method using a tide arch structure according to the present invention.
7 is a view showing a second embodiment of a retaining structure supporting method using a tide arch structure according to the present invention.
8 is a view showing a third embodiment of a retaining structure supporting method using a tide arch structure according to the present invention.
9 is a view showing a fourth embodiment of a retaining structure supporting method using a tide arch structure according to the present invention.
10 is a view showing a fifth embodiment of a retaining structure supporting method using a tide arch structure according to the present invention.
11 is a view showing sixth and seventh embodiments of a retaining structure supporting method using a tide arch structure according to the present invention.
12 is a view showing an eighth embodiment of a retaining 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.

FIG. 4 is a plan view showing a retaining structure supporting method using a tide arch structure according to the present invention, FIG. 5 is a view showing another embodiment of a retaining structure supporting method using a tide arch structure according to the present invention, and FIG. 7 is a view illustrating a second embodiment of a retaining structure supporting method using a tide arch structure according to the present invention. And FIG. 8 is a view showing a third embodiment of the retaining structure supporting method using the tide arch structure according to the present invention. FIG. 9 is a sectional view of the fourth embodiment of the retaining structure supporting method using the tide arch structure according to the present invention 10 is a view showing a fifth embodiment of the retaining structure supporting method using the tide arch structure according to the present invention, FIG. 12 is a sectional view showing an eighth embodiment of a retaining structure supporting method using a tide arch structure according to the present invention. FIG. 12 is a perspective view showing a sixth embodiment of a retaining structure supporting method using a tide arch structure according to the present invention. Fig.

FIG. 4 is a view illustrating a method of supporting a retaining structure using a tied arch structure according to the present invention. The retaining structure used in the construction of a new facility or structure includes a H file and a soil plate, a CIP wall, To resist the earth pressure F1 acting on the excavation wall 1 such as a slurry wall.

The retaining structure supporting method using the tide arch structure according to the present invention is characterized in that the arch structure member 3 receives the earth pressure F1 acting on the excavation wall 1 through the plurality of load transmission members 2, And one or a plurality of tie members (4) coupled to the base member (3).

Since the tide arch structure has a shape that is more spaced apart from the excavation wall 1 toward the corner portion in the central portion, a wedge or excavation is required to efficiently transmit the earth pressure F1 applied from the excavation wall 1 to the tide arch structure A plurality of load transmission members 2 are provided between the wall 1 and the arch structure member 3 of the tied arch structure.

The arch structure member 3 receiving the earth pressure F1 acting on the excavation wall 1 through the load transmission member 2 and the engaging member 6 disposed at both side ends of the arch structure member 3, And one or more tie members 4 coupled to the engagement members 6 or the arch structure members disposed at both ends of the arch structure member 3.

The earth pressure F1 transmitted through the load transmission member 2 acts as a load on the tide arch structure and the horizontal load F2 at both ends of the tide arch structure generated by the loads acts on the arch structure member 3. [ Or by the tensile force of the tie member 4 provided on the engaging member 6.

At this time, the tie member 4 may be composed of a steel material, a steel wire, a steel bar, a steel material, a high strength plastic, a synthetic material, a hybrid material or the like which can resist a tensile force. .

The tie member 4 can be 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 the horizontal load F2 generated by the earth pressure transmitted to the arch structure member 3 is constituted to resist as a tensile force of the tie member 4. [

In other words, the lateral load F2 generated in the arch structure member 3 through the tied arch structure in which the tie member 4 and the arch structure member 3 are combined is smaller than the tensile resistance F4 of the tie member 4 And the vertical load F3 generated in the arch structure member 3 is configured to be supported by the adjoining tide arch structure 3 and also the tensile force generated in the tie member of the adjacent adjacent arch structure member .

More specifically, the excavation wall 1 or wale receiving the earth pressure F1 is supported by the arch structure member 3 via a plurality of load transmission members 2, The load F2 is resisted as the tensile force F4 of the tie member 4 installed across the arch structure member 3. [

Therefore, according to the retaining structure supporting method using the tide arch structure according to the present invention, although the vertical load F3 generated in the arch structure member 3 is taken into account, it is advantageous to increase the efficiency of the load supporting structure .

Particularly, since the vertical load F3 acts in a direction opposite to the horizontal load F2 generated through the adjacent other arch structure member 3, the respective loads can be canceled out or greatly reduced , Which makes it possible to form the structure very simply without the use of complicated additional members.

Also, the earth pressure F1 acting on the excavation wall 1 is supported by a vertical wall such as a H-file or a soil plate wall previously installed by performing excavation work, but the earth pressure F1 acts unevenly depending on the position, There is a possibility that the excavation wall 1 at the position is damaged.

This allows the tide arch structure to more efficiently move the excavation wall 1 efficiently while distributing the load so that the earth pressure is not concentrated on the excavating wall 1 at a specific position through the wale 5 installed horizontally in the excavation wall 1 Or the like.

The load transmitting member 2 is disposed between the excavating wall 1 and the excavating wall 1 and between the excavating wall 1 and the excavating wall 1 and between the excavating wall 1 and the tie arch 5, The material forming the load transmission member 2 and the arch structure member 3 having the tied arch structure may be composed of a steel material, a steel wire, a steel bar, a steel material, a high strength plastic, a synthetic material, And the cross-sectional shape may be any of circular, H-beam, and rectangular.

The coupling of the load transmission member 2 with the excavation wall 1 or the wale 5 and the coupling of the load transmission member 2 with the arch structure member 3 are performed by bolts and nuts, And other auxiliary members that can be used for fastening can be used.

The material for the tie member 4 of the tied arch structure may be any one of a steel material, a steel wire, a steel bar, a steel material, a high strength plastic material, a synthetic material and a hybrid material, and the shape thereof may be any one of circular, H- Lt; / RTI >

As described above, the vertical load F3 transmitted to the tide arch structure by the earth pressure F1 is transmitted to other tide arch structures adjacent to each other, so that the horizontal load F2 of the tide arch structure and the horizontal load F2 The tensile force F4 generated in the corresponding tie member 4 can be reduced through the vertical load F3 'transmitted to the other tied arch structure.

At this time, in order to stably and efficiently transfer the vertical load F3 generated in each tide arch structure to adjacent tide arch structures, a plurality of engagement members 6 ). ≪ / RTI >

The engaging member 6 is configured to engage the end portions of adjacent arch structure members 3 with each other.

The shape of the coupling member 6 can be any shape that can be efficiently combined according to the sectional shape of the arch structure member 3 of the tied arch structure and the coupling member 6 and the tied arch structure 3 A bolt and a nut, a pin, a ring, a welding, a socket type, or the like.

The coupling member 6 can also be constructed in the form of a single body with the arch structure member 3 or in a form that can be separated from the arch structure member 3 3, a variety of coupling methods such as bolts, nuts, pins, rings, welds, and sockets can be used for coupling with the arch structure member 3. [

5 is a view showing another embodiment of the retaining structure supporting method using the tide arch structure according to the present invention. It is shown in FIG. 5 that the tile 5 is installed horizontally on the excavating wall 1 receiving the earth pressure F1, The arch structure member 3 of the tide arch structure is installed between the wale 5 and the arch structure member 3 so as to efficiently support the excavation wall 1 while dispersing the load so that the earth pressure is not concentrated on the excavation wall 1 A reinforcing member 2a may be additionally provided between the load transmitting member 2 and the load transmitting member 2. [

Depending on the site conditions, the wale 5 may not be installed, at which time the load transfer member 2 is installed directly between the excavation wall 1 and the arch structure member 3.

The load transmitting member 2 and the reinforcing member 2a may be formed in any one of a "Y" shape, an "I" shape, an "X" shape, and a zigzag shape or a combined shape.

Since the tie load transfer member 2b is provided between the tie member 4 and the arch structure member 3 for supporting the arch structure member 3 or the coupling member 6 as a tensile force, The tie load transfer member 2b provided between the tie member 4 and the arch structure member 3 may be configured to transmit a part of the load transmitted to the member 3 to the tie member 4, Quot; type, " I " type, " X " type or zigzag type.

An edge load transmission member 2c is provided between both ends of the arch structure member 3 to which the arch structure member 3 and the adjoining other arch structure member are coupled or between the joint member 6 and the edge portion of the excavation wall As shown in FIG.

The edge load transmission member 2c is provided with a load that can be generated by a difference in vertical load transmitted from the other arch structure member 3 adjacent to the horizontal load transmitted from the arch structure member 3 to the edge of the excavation wall 1 Thereby causing additional resistance to the earth pressure F1 of the excavation wall 1 to be generated.

6 shows a first embodiment among various embodiments of the engaging member 6, wherein the engaging member is composed of a first engaging member 11 integrally formed on one side of the arch structure member 3a, The second engaging member 12 may be configured to correspond to the first engaging member 11 so that the first engaging member 11 can be engaged with the first engaging member 11, A plurality of arch structural members 3a and 3b can be interconnected in such a manner that the first engaging member 11 is engaged with the second engaging member 12 of the adjoining other arch structure member 3b.

That is, the first engaging member 11 and the second engaging member 12 are formed in corresponding shapes.

The first engaging member 11 may further include a plurality of protruding engaging protrusions 13. The second engaging member 12 may include a plurality of engaging holes 13 for receiving the plurality of engaging protrusions 13, The first engaging member 11 and the second engaging member 12 may be formed of a combination of a plurality of projecting engaging projections 13 and a plurality of engaging holes 14 .

6, the plurality of engaging projections arranged on the second engaging member 12 formed on the other side of the other arch fixing member 3b are engaged with the arch fixing member 3a at one side And may be configured to be fixed by a plurality of fixing members 21 such as welds, nuts, or fins to the penetrating coupling projections 13 .

7 shows a second embodiment of the various embodiments of the engagement member 6, wherein the first engagement member 11 formed on one side of the arch structure member 3 has a first projection And a first protruding end 15 is formed on the second engaging member 12 so as to correspond to the first engaging member 11 for coupling with the first engaging member 11, And may be produced in a form that is mutually bonded.

The arch structure member 3a may further include a second protruding end 16 protruding from the first protruding end 15 and may include another arch structure member 3b different from the first engagement member 11 of the arch structure member 3a The first projecting end 15 and the second projecting end 16 are not limited in shape.

A plurality of fixing holes 20 are formed in the first engaging member 11 and the second engaging member 12 and a fixing member such as a bolt and a nut or a fixing pin inserted into the fixing hole 20 21, respectively.

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

A plurality of insertion ends 31 are respectively disposed on the first engagement member 11 and the second engagement member 12 and the arch structure member 3 is provided with the insertion end The first engaging member 11 and the second engaging member 12 can be accurately fixed to the arch structure member 3 by disposing a plurality of first insertion grooves 32 corresponding to the first, Do.

The first insertion groove 32 of the arch structure member 3 and the insertion end 31 of the first engagement member 11 and the second engagement member 12 are provided with a plurality of engagement holes 33 Are formed and welded to each other and fixed to each other through a fixing member 21 such as a bolt and a nut or a fixing pin.

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

In addition, the arch structure member 3 may be manufactured as a plurality of divided parts 201, 302, and 303 so as to be easily transported and installed according to the excavation space, and then assembled to be integrally formed.

The arch structure members 201, 302, and 303, which are divided into a plurality of pieces, can be welded or fixed to a plurality of brackets 22 and fixing members such as bolts and nuts or fixing pins, (21).

A plurality of fixing holes 20 are formed in the first engaging member 11 and the second engaging member 12 and a fixing member such as a bolt and a nut or a fixing pin inserted into the fixing hole 20 21, respectively.

That is, the above-described first to third embodiments described above are modified as one of various embodiments of the combination of the first engagement member 11 and the second engagement member 12, It is also possible to implement the combined form of the third embodiment.

Alternatively, as shown in FIG. 8, the tie member 4 can be coupled through the arch structure member 3 in a prestressing manner, and a tie member (not shown) coupled through the arch structure member 3 4 may be formed at a plurality of different positions.

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

In this way, when the arch member 3 or the coupling members 11 and 12 are inserted through the through holes, each end of the tie member 4 is preferably fastened and fixed through the tie fixing member 4a.

Alternatively, as one of the embodiments of the tie load transfer member 2b provided between the tie member 4 and the arch structure member 3 described above, as shown in Fig. 9 (9-II) And may be configured in other forms as long as it can be configured to transmit a part of the load transferred to the structural member 3 to the tie member 4. [

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

More specifically, an arch fixing shaft 35c for constituting a hinge is formed at the center side end portion of the divided one of the arch structure members 3a, and at the center side end portion of the other divided arch structure member 3b, The divided arch structure members 3a and 3b can be configured to be rotatable around the arch fixed shaft 35c by forming the arch fixing hole 35d so that the arch fixing shaft 35c is inserted and rotatable .

Thus, 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 arrangement position of the arch fixing shaft 35c and the arch fixing hole 35d may vary depending on the arrangement of the excavation wall or the band, or the size and direction of the load.

That is, the position where the arch structure member 3 is divided may be different from the apex of the arch structure member 3.

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

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

As described above, since the first engaging member is configured to be hinged to the second engaging member of the adjacent other arch structure member, the moment generated in the engaging members 11 and 12 is reduced, and the influence on the stress change .

Each of the engaging members 11 and 12 may be configured to be detachable from the arch structure member 3 by a fixing member 21 for ease of installation and transportation.

(11-I) of FIG. 11 shows a sixth embodiment of a retaining structure supporting method using a tide arch structure according to the present invention. In accordance with the shape or the width of the excavation space, a plurality of arch structure members 3 At least one of which is provided continuously along the excavation wall 1 and in which the engaging member 6 is disposed only at an edge portion where the arch structure member 3 which is continuously provided is tangential to the engaging member 6 and the other arch structure member 3 The engaging member may be omitted in the row-contacting portion 6a and a direct fastening between the arch structure members 3 may be made.

Further, a plurality of supporting members 40 for supporting are provided between the portions 6a to be directly fastened between the arch structural members 3 and the portions 6a to be fastened between the other arch structural members on the opposite side arranged to face each other .

In other words, any one or more of the arch structure members 3 may be structured such that a plurality of arch structure members 3 are arranged in a row along the excavation wall in succession in line with the shape or the width of the excavation space, The fastening between the structural members 3 is achieved by direct fastening and the fastened portions 6a between the arch structural members 3 arranged in a row can be configured to be supported by the plurality of supporting members 40. [

As a result, the horizontal load generated in the arch structure member 3 is shared by the tie members 4 and the other arch structure members 3 which are adjacent to each other in a line while the vertical load is perpendicular to the other arch structure members 3, (3) and the stiffening member (40) can be shared by each other, structurally more stable support becomes possible.

Alternatively, as in the seventh embodiment shown in FIG. 11 (11-II), at least one of the plurality of arch structure members 3 is continuously provided along the excavation wall 1, A joining member 6 is disposed at an edge portion where the member 3 contacts at right angles and a joining member 6b for aligning the arch structure member 3 is provided at a portion where the other arch structure members 3 are in contact with each other May be disposed.

At this time, various joining methods for joining the arch structure members 3 in a row in series may be used, and there is no restriction on the method and the form.

Between the portions 6b of the arch structure members 3 which are fastened through the row joint members 6b and the other fastening portions 6b which are arranged opposite to each other and arranged to face each other, May be provided.

In other words, any one or more of the arch structure members 3 may be structured such that a plurality of arch structure members 3 are arranged in a row along the excavation wall in succession in line with the shape or the width of the excavation space, The fastening between the structural members 3 is carried out through a row of engagement members 6b and the fastened portions 6b between the arch structure members 3 arranged in a row can be configured to be supported by a plurality of strut members 40 have.

FIG. 12 shows an eighth embodiment of a retaining structure supporting method using a tide arch structure according to the present invention, in which each of the excavation walls is provided with wales 5a and 5b having stepped portions at both ends thereof, 5b are arranged in such a manner that the forming positions of the step portions are opposite to each other and the end portions of the arch structure members 3a, 3b are arranged at the respective step portions, The vertical load may be configured so that adjacent belt strips are supported.

For example, the arch structure member 3a on one side is configured to support the earth pressure F1 transmitted through the wale 5a on one side, while the other end of the arch structure member 3a on the other side is connected to the wale 5b on the other side. So that the vertical load applied to the arch structure member 3a on one side can be shared by the wale straps 5b on the other side.

The earth pressure F1 transmitted through the other wale band 5b is configured to support the other arch structure member 3b while one end of the other arch structure member 3a is connected to the other wale band 5a And the vertical load applied to the arch structure member 3b on the other side can be configured to be supported by the wale 5a on one side so as to be supported by the stepped portion located on the upper ends of the two ends.

That is, each of the wales 5a and 5b disposed so as to cross each other can share the loads transmitted through the adjacent arch structural members as well as the respective arch structural members.

Of course, when the vertical loads applied to the arch structural members 3a and 3b are shared by the respective wales 5a and 5b, the ends of the arch structural members 3a and 3b or the wales 5a and 5b, It is also apparent that a variety of reinforcing members can be attached to the endless belt.

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

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention. The scope of the invention should therefore be construed in light of the claims set forth to cover many of such variations.

1: Excavation wall
2: Load transfer member
2a: reinforcing member
2b: a tie load transfer member
3: Arch structure member
4: Tie member
5: Wale
6:
11: first coupling member
12: second coupling member
13:
14: Coupling hole
15: first protruding end
16: second protruding end
20: Fixing hole
21: Fixing member
22: Bracket
31: insertion end
32: insertion groove
33: Coupling hole
40:
F1: earth pressure
F2: Horizontal load
F3: Vertical load
F4: Tensile force

Claims (20)

An arch structure member that receives the earth pressure acting on the excavation wall through the load transmission member;
And one or more tie members coupled to the arch structure member,
The horizontal load generated in the arch structure member through the tied arch structure coupled with the tie member and the arch structure member is supported through the tensile resistance of the tie member and the vertical load generated in the arch structure member is transmitted to the adjacent tide arch structure So that tensile force generated in the adjacent tie members can be reduced.
Supporting Method of Retaining Structure using Tide Arch Structure.
An arch structure member that receives the earth pressure acting on the excavation wall through the load transmission member;
An engaging member disposed at both side ends of the arch structure member;
And one or more tie members coupled to respective engagement members or arch structure members disposed at both ends of the arch structure member,
The horizontal load generated in the arch structure member through the tied arch structure coupled with the tie member and the arch structure member is supported through the tensile resistance of the tie member and the vertical load generated in the arch structure member is transmitted to the adjacent tide arch structure So that tensile force generated in the adjacent tie members can be reduced.
Supporting Method of Retaining Structure using Tide Arch Structure.
A wale band which is installed transversely to the excavation wall and has steps at both ends thereof;
An arch structure member receiving the earth pressure applied to the wale band through the load transmission member;
And one or more tie members coupled to the arch structure member,
The horizontal load generated in the arch structure member through the tied arch structure coupled with the tie member and the arch structure member is supported through the tensile resistance of the tie member and the vertical load generated in the arch structure member is transmitted to the step portion So that the tensile force generated in the adjacent tie members can be reduced.
Supporting Method of Retaining Structure using Tide Arch Structure.
4. The method according to any one of claims 1 to 3,
The material constituting the arch structure member of the load transmitting member and the tied arch structure may be composed of a steel material, a steel wire, a steel bar, a steel material, a high strength plastic material, a synthetic material, a hybrid material, and the cross sectional shape may be circular, H beam, And the material forming the tie member of the tied arch structure may be composed of a steel material, a steel wire, a steel bar, a steel material, a high strength plastic, a synthetic material, a hybrid material and the like, and the cross section shape may be circular, H beam, Characterized in that it is constituted by any one of
Supporting Method of Retaining Structure using Tide Arch Structure.
The method according to claim 1,
And an engaging member for fixing each end of the arch structure member of the tide arch structure
Supporting Method of Retaining Structure using Tide Arch Structure.
6. The method according to claim 2 or 5,
The coupling member
A first coupling member integrally formed on one side of the arch structure member;
And a second engaging member integrally formed on the other side of the arch structure member and corresponding to the first engaging member,
Characterized in that the first engaging member is engaged with a second engaging member of another adjacent arch structure member
Supporting Method of Retaining Structure using Tide Arch Structure.
The method according to claim 6,
Wherein the first engaging member is composed of a plurality of projecting engaging projections,
And the second engagement member is composed of a plurality of engagement holes in which the plurality of engagement protrusions are received
Supporting Method of Retaining Structure using Tide Arch Structure.
The method according to claim 6,
Wherein the first engaging member and the second engaging member are formed of a combination of a plurality of projecting engaging projections and a plurality of engaging holes.
Supporting Method of Retaining Structure using Tide Arch Structure.
The method according to claim 6,
Wherein the first engaging member and the second engaging member are formed with a plurality of fixing holes,
And a fixing member such as a bolt and a nut or a fixing pin inserted into the fixing hole and coupling the first and second coupling members to each other.
Supporting Method of Retaining Structure using Tide Arch Structure.
6. The method according to claim 2 or 5,
The coupling member
A first engaging member detachably formed on one side of the arch structure member;
And a second engaging member detachably formed on the other side of the arch structure member and corresponding to the first engaging member,
Characterized in that the first engaging member is engaged with a second engaging member of another adjacent arch structure member
Supporting Method of Retaining Structure using Tide Arch Structure.
11. The method of claim 10,
Wherein the first engaging member is composed of a plurality of projecting engaging projections,
And the second engagement member is composed of a plurality of engagement holes in which the plurality of engagement protrusions are received
Supporting Method of Retaining Structure using Tide Arch Structure.
11. The method of claim 10,
Wherein the first engaging member and the second engaging member are formed of a combination of a plurality of projecting engaging projections and a plurality of engaging holes.
Supporting Method of Retaining Structure using Tide Arch Structure.
11. The method of claim 10,
Wherein the first engaging member and the second engaging member are formed with a plurality of fixing holes,
And a fixing member such as a bolt and a nut or a fixing pin inserted into the fixing hole and coupling the first and second coupling members to each other.
Supporting Method of Retaining Structure using Tide Arch Structure.
4. The method according to any one of claims 1 to 3,
Wherein the arch structure member is integrally joined through a plurality of brackets, bolts, nuts, fixing pins, or other fixing members.
Supporting Method of Retaining Structure using Tide Arch Structure.
4. The method according to any one of claims 1 to 3,
And a tie load transmission member for transmitting a part of the load transmitted to the arch structure member between the arch structure member and the tie member to the tie member
Supporting Method of Retaining Structure using Tide Arch Structure.
The method according to claim 1,
By the difference between the horizontal load transmitted from the arch structure member and the vertical load transmitted from the adjacent other arch structure member between the both ends of the arch structure member to which the arch structure member and the adjacent other arch structure member are coupled and the edge portion of the excavation wall And an edge load transmission member for transmitting the load that can be generated to the edge portion of the excavation wall to generate an additional resistance against the earth pressure of the excavation wall.
Supporting Method of Retaining Structure using Tide Arch Structure.
3. The method of claim 2,
The horizontal load transmitted from the arch structure member and the vertical load transmitted from another adjacent arch structure member between the coupling member to which the arch structure member and another adjacent arch structure member are coupled and the edge portion of the excavation wall, And an edge load transmission member for transmitting the load to the edge portion of the excavation wall to generate an additional resistance against the earth pressure of the excavation wall.
Supporting Method of Retaining Structure using Tide Arch Structure.
4. The method according to any one of claims 1 to 3,
Wherein the arch structure member is divided into two structures on one side and the other side, and the divided arch structure members are hinged to each other
Supporting Method of Retaining Structure using Tide Arch Structure.
The method according to claim 6,
Wherein the first engaging member is formed with an engaging and fixing shaft,
And the second engagement member is configured to be hinged to each other by forming an engagement fastening hole formed in the first engagement member of another adjacent arch structure member so as to be inserted and rotatable.
Supporting Method of Retaining Structure using Tide Arch Structure.
4. The method according to any one of claims 1 to 3,
Wherein at least one of the arch structure members has a plurality of arch structure members arranged in a row along the excavation wall in accordance with the shape or the width of the excavation space,
The fastening between the arch structure members arranged in a row in succession is performed through a direct fastening or a single row fastening member,
Characterized in that the fastened portion between the arch structure members provided in series is supported by a plurality of stiffening members
Supporting Method of Retaining Structure using Tide Arch Structure.

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