KR101852083B1 - Arch assembly with outrigger, arch structure using the same, and construction method thereof - Google Patents

Abstract

Since a plurality of panel members separated from each other can be connected together by an outrigger, it is possible to integrally construct the panel members. Therefore, it is possible to minimize the thickness of the member because it is possible to resist the bending occurring during construction and common use, The present invention relates to an arch assembly having an outrigger capable of reducing a construction cost, an arch structure using the arch assembly, and a construction method thereof.
The present invention relates to an outrigger assembly for an arch, comprising: a panel member formed in a plate shape and arranged in a row so that a plurality of the arcuate assemblies are spaced apart from each other according to an interval calculated according to a curvature of an arch barrel; A strip-shaped steel plate which is a continuous shaft member which is provided on the plurality of panel members so as to be spaced apart from the panel member by a predetermined distance in the longitudinal direction and receives a tensile force, or a plate-shaped steel plate having a constant width; And an outrigger for connecting the outrigger and the panel member, wherein the outrigger is formed in an inverted V-shape having a lower portion opened in the longitudinal direction of the outrigger, the upper end is integrally fixed to the outrigger and the lower end is fixed to the upper surface of a pair of adjacent panel members An eccentric connector for keeping the distance between the outrigger and the panel member constant when the panel member is rotated to prevent a step between adjacent panel members from being generated; . ≪ / RTI >

Description

Technical Field [0001] The present invention relates to an arch assembly having an outrigger, an arch structure using the same, and an arch structure using the same,

Since a plurality of panel members separated from each other can be connected together by an outrigger, it is possible to integrally construct the panel members. Therefore, it is possible to minimize the thickness of the member because it is possible to resist the bending occurring during construction and common use, The present invention relates to an arch assembly having an outrigger capable of reducing a construction cost, an arch structure using the arch assembly, and a construction method thereof.

The stone arch or precast concrete arch structure installed in the ground is designed to have a sufficient compressive force due to the overburden due to the back soil and to pass the center line of the compressive force through the inside of the arch section. Even if a fluctuating load is applied, due to the restraining effect of the back soil, the arch structure is constructed such that the center line of the compressive force still passes through the inside of the arch section to receive the axial force.

However, during the construction of the arch structure, the axial force due to the self weight of the arch structure itself is small, while the construction load acts unevenly, resulting in a moment due to this.

As a countermeasure against this problem, it is general that the moored arch structure separated by block units is supported by a building material such as a tiller until the embankment is completed. However, this method has a problem of construction period and cost increase due to the construction work.

Also, it is possible to consider a method of connecting the blocks together and installing them collectively (EP 1 560 986 B1). However, this method should use a thicker block than necessary to ensure that the compressive force line does not deviate from the thickness of the block during construction. Accordingly, the weight of the arch structure is inevitably increased, and there is a problem such as an increase in the material cost and an increase in the burden due to the increase in the quantity of the arch structure.

As another countermeasure, there is a method of making all or half of an arch structure as an integral precast concrete member without using a divided block. This method is a method to assemble on-site without any construction by allowing members to resist the bending that occurs during construction (KR10-555046).

However, these precast concrete members also require a minimum thickness of concrete to resist bending, excessive use of reinforcing bars, and manufacturing and transportation is not efficient due to the size and shape of members.

SUMMARY OF THE INVENTION In order to solve the above problems, the present invention provides an arch assembly having an outrigger capable of minimizing the thickness of a member and being bending resistant against a construction load, and an arch structure using the same and a method of constructing the same.

The present invention provides an arch assembly having an outrigger that does not require a temporary structure during construction, an arch structure using the arch assembly, and a method of constructing the arch assembly.

According to a preferred embodiment of the present invention, a plurality of panels are formed in a plate shape and arranged in a row so as to be spaced apart from each other according to a distance calculated according to a curvature of an arch barrel, In order to enable the panel member having the same shape to be used regardless of the radius of curvature of the arch structure to be able to maintain a constant ground plane, the one end in the longitudinal direction of the panel member is convexly formed in an arcuate shape, A panel member having an end portion concavely formed in an arc shape to correspond to the shape of one end portion; A strip-shaped steel plate which is a continuous shaft member which is provided on the plurality of panel members so as to be spaced apart from the panel member by a predetermined distance in the longitudinal direction and receives a tensile force, or a plate-shaped steel plate having a constant width; And an outrigger for connecting the outrigger and the panel member, wherein the outrigger is formed in an inverted V-shape having a lower portion opened in the longitudinal direction of the outrigger, the upper end is integrally fixed to the outrigger and the lower end is fixed to the upper surface of a pair of adjacent panel members An eccentric connector for keeping the distance between the outrigger and the panel member constant when the panel member is rotated to prevent a step between adjacent panel members from being generated; Wherein the outrigger, the panel member, and the eccentric connecting members on both sides are trapezoidal.

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According to another preferred embodiment of the present invention, the outrigger is a plate-shaped steel plate having a constant width, and the outrigger and the panel member are coupled by at least two rows of eccentric connection members.

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According to another preferred embodiment of the present invention, there is provided an arch assembly having an outrigger, wherein elastic pads are coupled to both longitudinal ends of the panel member.

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According to another preferred embodiment of the present invention, slip pads are coupled to both end portions of the panel member in the longitudinal direction along an end shape, thereby providing an arch assembly having an outrigger.

According to another preferred embodiment of the present invention, there is provided an arch assembly provided with an outrigger, characterized in that an upper part of the plurality of panel members is provided with a dowel bar transverse to the longitudinal direction.

According to another preferred embodiment of the present invention, there is provided an arch assembly provided with an outrigger, wherein a guide hole for restricting movement of the multiwall bar in the width direction and the vertical direction is coupled to the upper surface of the panel member.

According to another preferred embodiment of the present invention, there is provided a structure comprising: a base provided at both ends of a position where an arch structure is to be installed; An arch barrel in which both ends are respectively mounted on and supported on an upper portion of the foundation, and an arch assembly having the outrigger is deformed into an arch shape by its own weight; And soil backfilled on top of the arch barrel; And an outrigger provided on the outer surface of the arch structure.

According to another preferred embodiment of the present invention, the outrigger is a plate-shaped steel plate having the same width as the panel member, and concrete is filled between the outrigger and the panel member, and the gravel- The present invention provides an arch structure using an arch assembly provided with an arch structure.

According to another preferred embodiment of the present invention, there is provided an arch structure using an arch assembly provided with the outrigger, comprising: (a) a foundation is provided at both ends of a position where an arch structure is to be installed, And assembling the arch assembly by coupling the outriggers to the upper portion of the panel members arranged in a row in the longitudinal direction with the eccentric linkage; (b) mounting both ends of an arch-shaped barrel deformed in an arcuate shape to the upper portion of the foundation by pivoting the center of the arch assembly; And (c) backfilling the topsoil of the arch barrel; The present invention provides an arch construction method using an arch assembly having an outrigger.

According to another preferred embodiment of the present invention, the outrigger is a plate-like steel plate having the same width as the panel member. In the step (c), concrete is filled between the outrigger and the panel member before embedding of the backfill, The present invention provides a method of constructing an arch structure using an arch assembly provided with an outrigger, wherein the gravel is filled in an upper portion of the outrigger.

According to another preferred embodiment of the present invention, in the step (b), both ends of the arch barrel are pulled together with tension wires to introduce a compressive force to the panel member, a tension force is applied to the outrigger, The present invention provides a method of constructing an arch structure using an arch assembly provided with an outrigger, wherein the tension wire is removed.

According to another preferred embodiment of the present invention, the upper surface of the foundation is provided with an insertion groove into which the lower end of the arch barrel is inserted, and in the step (b), the arch barrel is inserted into the insertion groove of the foundation, And a wedge member is inserted into a space between the lower end of the arch barrel and the insertion groove after the upper portion is mounted on the upper portion of the arch barrel.

According to the present invention, the lower part is formed of a divided panel member which receives a compressive force, and the upper part is formed of an outrigger which is a continuous shaft member subjected to a tensile force, and the panel member spaced apart by a certain distance from the upper part is connected to the outrigger by an eccentric connection member, Can be configured.

Accordingly, since the separated plurality of panel members are connected to each other by the outriggers, the arch assembly can be collectively lifted and installed, so that the installation structure is not required.

It is also possible to maximize the structural utilization of the back soil by inducing the ductility behavior like the corrugated steel sheet underground structure by having only the minimum bending stiffness which is necessary for the common use while being able to withstand the bending moment during construction, It can be configured as thin as possible based on the required minimum cross-sectional area.

Accordingly, it is possible to provide an arch assembly having an outrigger capable of improving the workability by reducing the weight of the member and reducing the construction cost, the arch structure using the arch assembly, and the method of constructing the arch assembly.

1 is a side view of an assembly for an arch with an inventive outrigger.
2 is a perspective view of an arch assembly having an outrigger, which is a strip steel plate.
Figure 3 is a perspective view of an arch barrel formed by the arch assembly of Figure 2;
4 is a perspective view of an arch assembly having an outrigger, which is a plate-shaped steel plate.
Figure 5 is a perspective view of an arch barrel formed by the arch assembly of Figure 4;
6 is a side view of an arch barrel showing an embodiment of a panel member;
Figure 7 is a side view of an arch barrel with an elastic pad.
8 is a side view of an assembly for an arch showing another embodiment of a panel member.
9 is a side view of an assembly for an arch showing another embodiment of a panel member.
10 is a side view of an arch barrel with a slip pad;
11 is a perspective view of an arch assembly having a dowel bar;
Figure 12 is a side view of an arch barrel formed by the arch assembly of Figure 11;
13 is a side cross-sectional view of an arch structure using an arch assembly having an outrigger according to one embodiment of the present invention.
14 is a side cross-sectional view of an arch structure using an arch assembly having an outrigger according to another embodiment of the present invention.
15 is a view showing a construction process of an arch structure using tensile wires;
16 is a side cross-sectional view showing the coupling details of the bottom of the arch barrel and the foundation.

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

1 is a side view of an assembly for an arch with an outrigger of the present invention.

As shown in FIG. 1, an arch assembly having an outrigger according to the present invention is formed in a plate shape, and a plurality of the arch assemblies are arranged in a row so as to be spaced apart from each other according to a distance calculated according to the curvature of the arch barrel 1 ' So that even when the adjacent panel members 11 are joined at any angle, the mutually facing surfaces of the joint portions can maintain a constant ground surface, so that the panel member 11 of the same shape can be used regardless of the radius of curvature of the arch structure A panel member 11 having one end in the longitudinal direction of the panel member 11 convexly formed in an arc shape and the other end being concave in an arc shape corresponding to the shape of one end portion; An outrigger (12) which is a strip-shaped steel plate or a plate-shaped steel plate having a predetermined width, which is a continuous shaft member provided on the plurality of panel members (11) and spaced apart from the panel member (11) by a predetermined distance in the longitudinal direction; And an outrigger 12 for connecting the outrigger 12 and the panel member 11. The outrigger 12 is formed in an inverted V shape whose lower portion is opened in the longitudinal direction and the upper end is integrally fixed to the outrigger 12, The distance between the outrigger 12 and the panel member 11 is kept constant when the panel member 11 is rotated and the distance between the adjacent panel members 11 is fixed to the upper surface of the adjacent pair of panel members 11, An eccentric linkage 13 for preventing the occurrence of an accident; , And the outrigger (12), the panel member (11), and the eccentric linkage (13) on both sides are trapezoidal.

The panel members 11 are arranged in a line so that a plurality of the panel members 11 are spaced apart from each other.

The panel member 11 may be a precast concrete member. However, the panel member 11 may be any material capable of supporting a compressive force such as wood or synthetic resin.

The interval between the panel members 11 can be calculated according to the curvature of the arched barrel 1 '. That is, when the curvature of the arch barrel 1 'is large, the interval between the neighboring panel members 11 is widened. When the curvature of the arch barrel 1' is small, Can be narrowly formed.

The panel member (11) is constituted by a plurality of parts which are located at the lower part of the arch assembly (1) and are divided into a member receiving a compressive force.

The outrigger 12 is provided on the plurality of panel members 11 in a longitudinal direction so as to be spaced apart from the panel member 11 by a predetermined distance.

The outrigger 12 preferably has an elastic material which has flexural rigidity and is flexible.

The outrigger (12) is composed of one continuous shaft member, which is located on the upper part of the arch assembly (1) and receives a tensile force.

The eccentric coupling member 13 connects the outrigger 12 and the panel member 11.

The eccentric connection member 13 is provided between the panel member 11 and the outrigger 12 such that the panel member 11 and the outrigger 12 are spaced apart from each other.

As described above, in the arch assembly 1 according to the present invention, the plurality of panel members 11 separated from each other are connected to one outrigger 12 by the eccentric connector 13, respectively. Accordingly, the arch assembly 1 can be collectively lifted and installed.

The arch assembly 1 can be manufactured in a linear state by arranging the panel members 11 in a line in a work place and connecting the outrigger 12 to the upper portion of the panel member 11 with the eccentric connector 13. [

When the center portion of the outrigger 12 is lifted, both ends of the center portion are bent by the weight of the outrigger assembly 12. [ At the same time, the end portions of the neighboring panel members 11 come into contact with each other to form an arch shape as a whole, thereby forming an arch barrel 1 '.

The outrigger 12 and the eccentric link 13 are embedded in the soil 3 backed up to enhance the integrated behavior of the arch structure and the surrounding ground.

The panel member 11, the outrigger 12, and the eccentric link 13 may be separated and assembled in the field after they are brought into the field. As a result, transportation and transportation costs can be reduced, and construction is possible regardless of the size of the arch structure.

As described above, the arch assembly having the outrigger according to the present invention is formed by the divided panel member 11 which receives the compressive force, and the upper portion is formed by the outrigger 12 which is a continuous shaft member receiving the tensile force, And the separated panel member (11) and the outrigger (12) are connected by an eccentric connecting member (13).

Therefore, it can resist bending moment during installation. In addition, it is possible to maximize the structural utilization of the backhoe, which plays a role of the earth pressure redistribution according to the load variation, by inducing the ductility behavior like the corrugated steel sheet underground structure by having only the minimum bending stiffness necessary for the common use, It is possible to constitute as thin as possible on the basis of the minimum cross-sectional area necessary for the light-emitting device.

Accordingly, it is possible to provide the arch assembly 1 in which the thickness of the member is minimized and lightweight, and the bending resistance against the installation load is possible, thereby eliminating the need for a temporary structure at the time of construction.

The eccentric connector 13 is formed in an inverted V-shape having a lower portion opened in the longitudinal direction of the outrigger 12, and the upper end thereof is fixedly coupled to the outrigger 12 and the lower end thereof is fixed to the upper surface of a pair of adjacent panel members 11 Respectively.

When the eccentric coupling member 13 connects the outrigger 12 and the panel member 11 at a position within each panel member 11, that is, when the lower end of the eccentric coupling member 13 is coupled to one panel member 11 Local deformation of the outrigger 12 occurs between the eccentric linking members 13 when lifting the arch assembly 1, resulting in a large step in the joining portion of the adjacent panel member 11, resulting in poor construction accuracy and stability.

Therefore, the lower end of the eccentric connector 13 formed in the inverted V-shape is connected to the adjacent panel member 11, while the upper end of the eccentric connector 13 is connected to the outrigger The distance between the outrigger 12 and the panel member 11 is kept constant even when the panel members 11 are rotated due to lifting of the arched assembly 1 by connecting the panel members 11 to each other, It is possible to prevent a step from occurring.

In other words, the inverted V-shaped eccentric connecting member 13 becomes the center of rotation of the upper corner point, and when the panel member 11 is rotated according to lifting of the arch assembly 1, the inverted V-

Since the outrigger 12, the lower panel member 11 and the eccentric connecting members 13 on both sides of the panel member 11 are trapezoidal in shape by the shape of the eccentric connection member 13, can do.

The eccentric coupling member 13 may be formed by bending a steel plate.

The eccentric coupling member 13 can be coupled to the outrigger 12 and the panel member 11 by bolts.

FIG. 2 is a perspective view of an arch assembly having an outrigger, which is a strip steel plate, and FIG. 3 is a perspective view of an arch barrel formed by the arch assembly of FIG.

As shown in FIGS. 2 and 3, the outrigger 12 may be a strip-shaped steel plate.

2, when the arched assembly 1 is assembled using the outrigger 12 as a narrow band steel plate and then the center of the arch assembly 1 is lifted, So that the arch barrel 1 'is formed.

At this time, due to the sufficient elasticity of the strip-shaped steel plate, the arch assembly 1 is elastically deformed by its own weight.

It is preferable that the outrigger 12 using the strip steel plate is arranged in two or more rows for stability during lifting of the arch assembly 1. [

In this case, each outrigger 12 is engaged with the panel member 11 by the eccentric link 13.

Since the band-shaped steel sheet is relatively narrow in width, the upper portion of the panel member 11 is opened and it is advantageous to cover the gravel-like material 3 on the outrigger 12.

FIG. 4 is a perspective view of an arch assembly having an outrigger, which is a plate steel plate, and FIG. 5 is a perspective view of an arch barrel formed by the arch assembly of FIG.

4 and 5, the outrigger 12 is a plate-shaped steel plate having a constant width, and the outrigger 12 and the panel member 11 are configured to be coupled by at least two rows of eccentric linking members 13 can do.

The outrigger 12 may be formed of one plate-shaped steel plate.

In this case, the outrigger 12 may be formed to have the same width as that of the panel member 11 to cover the entire panel member 11.

At least two or more rows of eccentric linking members 13 are arranged for stable engagement between the outrigger 12 and the panel member 11.

The space between the panel member 11 and the outrigger 12 may be filled with concrete 4 to form a rigid structure.

Accordingly, it is possible to support the load without backfilling of the soil (3), so that it can be used for a protection facility.

The outrigger 12 formed of the plate-like steel plate may be provided with a casting hole for casting the concrete 4.

6 is a side view of an arch barrel showing an embodiment of a panel member.

As shown in FIG. 6, both end portions of the panel member 11 in the longitudinal direction may be inclined so that the width thereof becomes narrower toward the bottom.

Each panel member 11 rotates during the lifting of the arch assembly 1 to form an arch-shaped arch barrel 1 'as a whole. When the panel member 11 constituting the arch barrel 1' So that both ends of the panel member 11 can be inclined.

For example, the panel members 11 may be formed in an inverted trapezoidal shape having a narrower width toward the bottom.

The inclination angle of the end portion of the panel member 11 is calculated according to the curvature of the arch barrel 1 '.

7 is a side view of an arch barrel with an elastic pad.

As shown in FIG. 7, elastic pads 111 may be coupled to both longitudinal ends of the panel member 11.

The elastic pad 111 prevents the end of the panel member 11 from being damaged by collision between neighboring panel members 11 when the arch assembly 1 is lifted and absorbs manufacturing errors.

In addition, the elastic pad 111 contributes to smoothly move the arch barrel 1 'during the arch structure, and seals the joint surfaces between adjacent panel members 11 to secure a waterproof function.

The elastic pad 111 may be made of a flexible material such as a rubber plate.

The elastic pad 111 may serve as a permanent mold on the edge of the panel member 11 when the panel member 11 is manufactured.

Fig. 8 is a side view of an assembly for an arch showing another embodiment of a panel member; and Fig. 9 is a side view of an assembly for an arch showing another embodiment of the panel member.

8 (a) and 8 (b), one end portion in the longitudinal direction of the panel member 11 is convexly formed in an arcuate shape, and the other end portion is concave in a circular arc shape so as to correspond to the shape of one end portion .

8A shows a state in which the arch assembly 1 is assembled on the working surface and FIG. 8B shows a state in which the arch barrel 1 'is lifted after lifting the arch assembly 1 Respectively.

Even if the panel member 11 meets at any angle, it is possible to prevent mutual contact of the panel members 11 at the joining portions of the adjacent panel members 11 as shown in FIG. 8 (b) It is possible to maintain a constant ground plane.

Accordingly, since the panel member 11 having the same shape can be used regardless of the radius of curvature of the arch structure to be applied, a sufficient amount of the panel member 11 can be manufactured in advance and used promptly for urgent construction.

8A and 8B, the end portion of the panel member 11 may be formed in an arc shape as a whole, or only a part of a central portion of the end portion may be formed as an arc shape or a concave shape as shown in Fig. 9 It is possible.

The eccentric connecting member 13 serves as a work of trusses to limit the rotation angle between the panel members 11. [ Therefore, even if the end portion of the panel member 11 is formed into an arc shape, the arch curvature designed when the arch assembly 1 is lifted can be maintained.

10 is a side view of an arch barrel with a slip pad.

10, the slip pads 112 may be coupled to both end portions of the panel member 11 in the longitudinal direction along an end shape thereof.

7, the above-described elastic pad 111 is coupled to the end portion of the panel member 11 so as to be free to rotate between the panel members 11.

The slip pad 112 having less friction can be joined to the end portion of the panel member 11 so that the panel member 11 can be more freely deformed in rotation even when the end portion of the panel member 11 is formed in an arc shape .

Accordingly, the ductility of the arch structure can be induced by the free rotation of the panel member 11 at the boundary between the neighboring panel members 11.

The slip pad 112 may be provided over the entire end portion of the panel member 11 or may be provided at a portion of the end portion and may be provided at one or both ends of the panel member 11.

The slip pad 112 may serve as a permanent die when the panel member 11 is manufactured.

FIG. 11 is a perspective view of an arch assembly with a dowel bar, and FIG. 12 is a side view of an arch barrel formed by the arch assembly of FIG.

As shown in FIGS. 11 and 12, on the upper surface of the plurality of panel members 11, there may be provided a dowwheel 14 crossing in the longitudinal direction.

After completion of the construction of the arch structure, the dowwheel 14 is embedded in the gravel 3 or the concrete 4 placed on the arch barrel 1 'to reinforce the arch structure.

The dowwheel 14 is constructed to have an arcuate shape naturally along the panel members 11 in the state of completion of the construction of the arch structure by using a member capable of bending such as a reinforcing bar.

A guide hole 113 may be formed on the upper surface of the panel member 11 to restrict movement of the multiwall bar 14 in the width direction and the vertical direction.

The guide hole 113 allows longitudinal movement of the outrigger 12, but restricts movement in the width direction and the vertical direction.

Accordingly, when assembling the arch assembly (1), the multi-wall bar (14) is inserted into the guide hole (113) in advance and fixed to the upper surface of the panel member (11). When the arch assembly 1 is deformed from a straight shape to an arcuate shape when lifting the arch assembly 1, the multi-wall bars 14 inserted and fixed to the guide holes 113 are bent like the panel members 11, So that the shape can be smoothly formed.

The multi-wall bars 14 thus installed prevent the panel members 11 from falling in the width direction during lifting or installation of the arch assembly 1. [ In addition, it is possible to prevent displacement of the joint surfaces between the panel members 11 due to an unexpected external load.

In other words, the structure in which the multi-wall bars 14 are fixed to the upper portion of the panel member 11 not only improves the structural performance of the common middle structure but also improves the stability during construction.

The guide member 113 may be integrally formed by embedding the lower portion of the panel member 11 in the inverted U shape when the panel member 11 is manufactured. Although not shown in the drawing, the panel member 11 may be integrally formed It is possible.

13 is a side cross-sectional view of an arch structure using an arch assembly having an outrigger according to an embodiment of the present invention.

As shown in FIG. 13, an arch structure using an arch assembly having an outrigger according to the present invention includes a base 2 provided at both ends of a position where an arch structure is to be installed; An arch barrel (1 ') formed by deforming an arch assembly (1) provided with the outrigger (12) by its own weight in an arch shape so that both ends are respectively mounted on and supported on an upper portion of the foundation (2); And gravel (3) backfilled on top of the arch barrel (1 '); . ≪ / RTI >

The arch assembly 1 forming the arch barrel 1 'is an arch assembly 1 equipped with the outrigger of the present invention described above with reference to FIGS.

The arch barrel 1 'is formed by deforming into an arch shape by lifting the center of the arch assembly 1 upward.

The arch barrel 1 'may be installed in one or more rows depending on the width of the arch structure.

The waterproof layer may be formed on the upper surface of the panel member 11 before the gravel 3 is lifted to secure the waterproof performance.

The gravel 3 can be filled up to a portion between the panel member 11 and the outrigger 12.

14 is a side cross-sectional view of an arch structure using an arch assembly having an outrigger according to another embodiment of the present invention.

14, the arch structure using the arch assembly having the outrigger according to the present invention is such that the outrigger 12 is a plate-shaped steel plate having the same width as the panel member 11, and the outrigger 12 and the panel member 11 of the outriggers 12 are filled with concrete 4, and the gravels 3 are packed in the upper part of the outrigger 12.

4 and 5, when the outrigger 12 is formed of a plate-shaped steel plate, the concrete 4 is placed between the outrigger 12 and the panel member 11 to form the arch structure as a rigid structure .

In this case, when the concrete 4 is laid, the outrigger 12 and the panel member 11 act as a formwork, so that a separate construction such as a formwork is not required.

When the outrigger 12 is formed of a plate-like steel plate having the same width as that of the panel member 11 to cover the entire panel member 11, the gravel 3 can be directly supported on the top of the panel member 11, 3) floats on top of the outrigger (12).

A method of constructing an arch structure using an arch assembly having an outrigger according to the present invention is for constructing an arch structure using an arch assembly (1) provided with the outrigger (12), wherein (a) A plurality of panel members 11 are arranged in a line on the work surface and the eccentric link member 13 is provided on the upper part of the panel member 11 arranged in a row with the outriggers 12 Assembling the arch assembly (1) so as to cross the longitudinal direction; (b) mounting both ends of the arch barrel 1 ', which has been deformed into an arch shape, in the center of the arch assembly 1 to the upper part of the foundation 2; And (c) backfilling the gravel (3) on top of the arch barrel (1 '); And a control unit.

In the step (a), the construction (2) of the construction and arch assembly (1) can be carried out separately or sequentially.

After the completion of the foundation (2) construction and assembly of the arch (1) in the step (a), the arch-shaped arch barrel 1 ' .

Both ends of the arch barrel 1 'are mounted on the foundation 2 and supported thereon.

Thereafter, (c) the gravel 3 is floated on the upper part of the arch barrel 1 'to complete the construction.

If the arch barrel 1 'is composed of a plurality of columns according to the width of the arch structure, the soil 3 is backed up after the step (b) is sufficiently repeated.

When the outrigger 12 is formed of a plate-like steel plate having the same width as the panel member 11, the outrigger 12 and the panel member 11 before the embedding of the backfill 3 in the step (c) And the backfill 3 is filled in the upper part of the outrigger 12. The backfill 3 is filled with concrete 4,

15 is a view showing a construction process of an arch structure using tension wires.

15, in the step (b), both ends of the arch barrel 1 'are pulled together with the tension wire 5 to introduce a compressive force to the panel member 11, and a tensile force is applied to the outrigger 12 So that the tension bar 5 can be removed after the arch barrel 1 'is mounted on the base 2.

When arches with low rise, that is, arches with a radius of curvature larger than the radius of curvature of the shoulder part, or arches with very low toe height, are applied to the arches due to their weight or backlash, Compared with the introduced compressive force, the maximum moment can be largely affected.

At this time, if the cross-section of the outrigger 12 is too large to buckle and is held by the compressive force, a tensile force is generated between the lower panel members 11.

Therefore, under the above conditions, both ends of the arch barrel 1 'are pulled by the tension wire 5 before the backfilling step of the gravel 3 to introduce compressive force into the panel member 11 in advance. So that the panel member 11 can be configured not to generate a tensile force.

The compressive force can be introduced by pulling the tension wire 5 after coupling the wire girder 51 or the like into the tension wire 5.

16 is a side cross-sectional view showing the coupling detail of the bottom of the arch barrel and the foundation.

16, the upper surface of the foundation 2 is formed with an insertion groove 21 into which the lower end of the arch barrel 1 'is inserted, and in the step (b), the upper end of the arch barrel 1' After the arch barrel 1 'is mounted on the base 2 so that the lower end of the arch barrel 1' is inserted into the insertion groove 21 of the foundation 2, The wedge member 6 can be inserted.

In order to prevent the arch barrel 1 'from being restored to the outside after the removal of the tensile wire 5, the wedge member 6 is inserted outside both ends of the arch barrel 1' .

Therefore, the wedge member 6 is inserted into the space between the lower end of the arch barrel 1 'and the insertion groove 21 to support the arch barrel 1' so as not to be opened, and then the tension wire 5 is disassembled.

1: Arch assembly 1 ': Arch barrel
11: Panel member 111: Elastic pad
112: slip pad 113: guide hole
12: Outrigger 13: Eccentric connector
14: Da Walsa 2: Foundation
21: Insertion groove 3: Tosa
4: Concrete 5: Tension Wire
51: wire joiner 6: wedge member

Claims (16)

Are arranged in a row so as to be spaced apart from each other according to a distance calculated according to the curvature of the arch barrel 1 'so as to receive a compressive force, so that even if adjacent panel members 11 are joined at any angle, In order to enable the panel member 11 having the same shape to be used regardless of the radius of curvature of the arch structure by making it possible to maintain a constant ground plane, the one end in the longitudinal direction of the panel member 11 is convexly curved And the other end of the panel member 11 is concavely formed in an arc shape so as to correspond to the shape of the one end portion;
An outrigger (12) which is a strip-shaped steel plate or a plate-shaped steel plate having a predetermined width, which is a continuous shaft member provided on the plurality of panel members (11) and spaced apart from the panel member (11) by a predetermined distance in the longitudinal direction; And
The outrigger 12 is formed to have an inverted V-shape in which the lower portion of the outrigger 12 extends in the longitudinal direction. The upper end of the outrigger 12 is integrally fixed to the outrigger 12, The distance between the outrigger 12 and the panel member 11 is kept constant when the panel member 11 is rotated and the distance between the adjacent panel members 11 is increased, An eccentric connecting member 13 for preventing the eccentric joint 13 from being damaged; Lt; / RTI >
Wherein the outrigger (12), the panel member (11), and the eccentric connectors (13) on both sides are trapezoidal.
delete The method of claim 1,
Wherein the outrigger (12) is a plate-shaped steel plate having a constant width, and the outrigger (12) and the panel member (11) are joined by at least two rows of eccentric linking members (13).
delete The method of claim 1,
And an elastic pad (111) is coupled to both end portions of the panel member (11) in a longitudinal direction thereof.
delete The method of claim 1,
Wherein a slip pad (112) is coupled to both ends of the panel member (11) in the longitudinal direction along an end shape thereof.
The method of claim 1,
Wherein the panel members (11) are provided on the upper surface thereof with a plurality of longitudinal walls (14) extending across the panel members (11).
9. The method of claim 8,
And a guide hole (113) for restricting the movement of the multiwall bar (14) in a width direction and a vertical direction is coupled to an upper surface of the panel member (11).
A foundation (2) installed at both ends of the location where the arch structure is to be installed;
(10) according to any one of claims 1, 3, 5, 7 to 9, characterized in that both ends are respectively mounted on and supported on the base (2) An arch barrel 1 'formed by deforming the dragon assembly 1 into an arch shape by its own weight; And
Gypsum (3) backfilled on top of the arch barrel (1 '); And an outrigger disposed on the outer surface of the arch structure.
11. The method of claim 10,
The outrigger 12 is a plate-like steel plate having the same width as the panel member 11, and concrete 4 is filled between the outrigger 12 and the panel member 11. The soil 3 has an outrigger 12 Wherein the arch structure is supported on an upper portion of the arch structure.
An arch structure using an arch assembly (1) provided with an outrigger (12) according to claim 10,
(a) a foundation 2 is installed at both ends of a position at which an arch structure is to be installed, a plurality of panel members 11 are arranged in a line on a work surface, Assembling the arch assembly (1) by coupling the outrigger (12) with the eccentric connector (13) across the longitudinal direction;
(b) mounting both ends of the arch barrel 1 ', which has been deformed into an arch shape, in the center of the arch assembly 1 to the upper part of the foundation 2; And
(c) backfilling the gravel (3) on top of the arch barrel (1 '); Wherein the outrigger comprises an outrigger, and wherein the outrigger comprises an outrigger.
The method of claim 12,
The outrigger 12 is a plate-like steel plate having the same width as the panel member 11, and in the step (c), the concrete is sandwiched between the outrigger 12 and the panel member 11 before embedding of the backfill 3 4) and the backfill (3) is filled in the upper part of the outrigger (12).
The method of claim 12,
In the step (b), both ends of the arch barrel 1 'are pulled together with the tension wire 5 to introduce compressive force to the panel member 11 and tension force is applied to the outrigger 12, Is mounted on the base (2) and then the tension wire (5) is removed. The method of claim 1, wherein the tension wire (5) is removed.
The method of claim 14,
In the step (b), the lower end of the arch barrel 1 'is inserted into the bottom of the base 2 in the insertion groove 21 into which the lower end of the arch barrel 1' The wedge member 6 is inserted into the space between the lower end of the arch barrel 1 'and the insertion groove 21 after the arch barrel 1' is mounted on the base 2 so as to be inserted into the groove 21 Wherein the outrigger is provided with an outrigger. delete

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